KR20150138129A - Nuclear Waste Nuclear Power Plant reactors equipped with dual structure for high-speed growth of nuclear power plants - Google Patents

Abstract

The present invention relates to a dual structured fast breeder reactor nuclear reactor facility of a nuclear waste process nuclear power plant facility for nuclear power generation. Especially, the nuclear reactor facility has a nuclear radioactivity leakage control dual structure block tank precipitator, thereby restoring the reliability of power consumers and obtaining the best nuclear power safety and economic feasibility.

Description

[0001] The present invention relates to a nuclear reactor, and more particularly, to a nuclear reactor having a dual structure for a nuclear reactor,

[0001] The present invention relates to a dual-structure, high-speed multiprocessor nuclear reactor facility for a nuclear waste disposal nuclear power plant for nuclear power generation, and more particularly to a nuclear reactor leakage suppression dual structure block tank collector, The best nuclear safety and economical power generation nuclear reactors in the global nuclear power plant are mainly used for light water reactors. They include boiling water reactor facilities, pressurized water reactor facilities, gas cooling furnace reactor facilities, multipurpose hot gas furnace reactor facilities, It is necessary to prepare a plurality of nuclear reactor facilities by each of the reactor facilities and to control the nuclear radiation leakage of the reactor facilities nuclear waste disposal screening device for the nuclear power plant operation. With the installation of the individual reactor facilities in the double structure block tank dust collector, Connective structure of flood control station Prevention of sinking The installation of nuclear power plants in connection with the installation and distribution equipment of the construction equipment to replace the construction machinery and marine vessels, A dual structure storage tank constituting the nuclear fuel explosion prevention control article insertion storage and a dual structure block tank dust collector connection structure provided in the double structure storage tanks for nuclear operation of the nuclear waste processing shielding apparatus, The control of the nuclear radiation leakage which efficiently improves the operation of the nuclear reactors of a plurality of nuclear reactors by each nuclear power plant is provided inside the dual structure block tank dust collector simultaneously with the progress of the nuclear waste disposal by the nuclear radiation leakage control Nuclear reactor facilities, after safe operation, Nuclear power generation including hydroelectric power generation for wind turbine and thermal power generator to be put into production production Alternative power generation Nuclear power generation including dual power generation block tank pipeline dust collector block piping line connected with nuclear power plant Nuclear waste disposal The Nuclear Power Generation Equipment Division consists of a nuclear power generation nuclear power plant, a power generation unit, a traffic transportation unit of the construction machine that adjusts the position of the control shaft, and a power transmission unit that transmits power to the nuclear power generation nuclear power plant. And an electronic control regulating device and a construction machine control section. The present invention relates to a reactor structure for a high-speed multiplying reactor of a nuclear power plant for nuclear power generation.

Generally, the installation of conventional nuclear power plant's nuclear reactors installed according to the installation location of the inland river in the global village and coastal area of the coast is very weak in safety from natural disasters and the nuclear power generation operation is stopped or the nuclear power plant is exploded, , So that once the companies manufacturing these reactors have met the requirements of the containment vessel corresponding to the fourth wall of the recently developed reactor to meet the reliability of the power consumer and the fifth wall A plurality of through holes are formed at a predetermined angle of 45 ° in the upper part of the nuclear reactor building, and a machine cutter and a construction machine crane and a conveyor are machined in a drilling machine and a cutting machine rotary lathe machine. A number of safety valves are connected to the bolt and nut on the block piping line. The nuclear waste treatment storage block tanks and the radiation type connection structures are constructed in eight double structure block tanks each having a diameter twice the diameter of the reactor building along the circumference of the outer wall of the nuclear reactor building. Nuclear safety and economics are very severe and dangerous Reactor facility design process has been exposed and nuclear power safety and economics to recover the reliability of power consumers. Nuclear Radiation Leakage Control for the Equipment Nuclear Reactor Suitable for the Double Structure Block Tank Reactor Dust Collector The need to install nuclear waste disposal shielding device has been urgently required and the design and experiment for the safety and economical solution have been continued and research Global Nuclear Power Plant Nuclear reactors for nuclear reactors Operation of nuclear reactors Nuclear reactors for nuclear waste disposal system Nuclear radioactivity leakage control Dual structural block tank Dust collector Nuclear waste disposal for distribution and disposal Nuclear waste treatment Dual structure of nuclear power plant facilities Fast breeder reactor facility design Much effort has been devoted to finding the process.

However, since the demands of those skilled in the art have become more diverse, and a serious risk level has been expressed in terms of nuclear safety and economy, in order to solve the desire to recover the reliability of electric power consumers, nuclear waste treatment double structure block tank reactor Nuclear Radiation Leakage Control of a Nuclear Power Plant with Nuclear Power Plant Dual Structure Block Tank Nuclear Reactor Corresponding to the Fourth Walls of the Nuclear Reactor and the Nuclear Reactor Corresponding to the Fifth Wall A plurality of penetrating The hole is machined by a computer cutting machine, a construction machine crane and a conveyor in a drilling machine and a rotary machine of a cutting machine, and a block pipe line of a double pipe structure is formed in the plurality of through holes, while a plurality of safety valve connection structures are connected to a double pipe structure block pipe Gaskets rubber packing in bolts and nuts in line The flange connection structure is equipped with a hand tool hammer and a wrench and at the same time a double space structure block tank having a diameter twice the diameter of the reactor building along the circumference surface of the nuclear reactor building is provided with an empty space for a nuclear waste treatment storage block tank The double pipe structure piping line with multiple safety valve connection structures constituting a double pipe structure piping line in a plurality of through holes is provided with a radiation type connection structure and a plurality of reactor facilities of a marine power plant floating plant nuclear plant. Waste treatment shielding device and nuclear waste treatment for nuclear power plant Double structure block tank A double structure block reactor of a nuclear power plant equipped with a dust collector is a construction machine and a construction machine for the foundation of a floating power plant of a marine power plant Marine tunnels formed by replacing marine vessels The floating power plant of the marine power plant composed of the distribution device of the transportation device operates the nuclear plant power plant of the floating power plant of the marine power plant by operating the nuclear power plant nuclear reactor plant of the marine power plant at the sea bottom easily, Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant

A description will now be given of a plurality of nuclear reactor facilities for nuclear power generation of the prior art, which are installed in nuclear power plant inside the nuclear power plant reactor main body of a double structure high-speed propagation furnace for nuclear power generation nuclear power plant for nuclear power generation.

The conventional water reactor having various water reactors for nuclear power generation according to the prior art is formed of a boiling water reactor system 802 and a pressurized water reactor system 803, and a power reactor is mainly used for a light reactor Other than that, a gas cooling furnace reactor facility 804, a multi-purpose high temperature gas reactor facility 805 and a new conversion furnace reactor facility 806 are used. The boiler water reactor reactor facility 802 and the pressurized water reactor facility 803, A gas cooling furnace reactor installation 804 and a multi-purpose high temperature gas reactor installation 805, a new conversion furnace reactor installation 806 and a high-speed proliferation furnace installation 838, Level nuclear power plants.

Not only are the reserves of uranium as a raw material of nuclear energy limited, but also there is nuclear energy as an energy source that causes pollution less than fossil fuel. Therefore, this nuclear energy is attracting attention as a new power source in the future. The more serious problem is the disposal of nuclear waste.

Environmental pollution caused by nuclear waste can fatally destroy our only earth.

So, we have come up with a way to get energy without pollution, and today we want to get the answer from the sun and the sea.

There are many ways to get energy from the ocean. Tidal power to obtain energy using tidal and tide movements, Wave power to obtain energy using the power of waves, Sea water temperature to obtain energy using the temperature difference of seawater. By using various methods, we can provide an unlimited amount of pollution-free energy at sea.

The double structure block tank of the nuclear radiation leak control nuclear reactor construction for inserting into the nuclear reactor reactor double structure block for the treatment of nuclear waste tank In various types of reactor facilities of a nuclear power plant having a dust collector,

Nuclear power plant nuclear waste treatment double structure block tank Various kinds of reactor facilities of nuclear power plants equipped with reactor dust collectors are equipped with transport materials for control of nuclear fuel explosion prevention control to store and shield nuclear radioactive pollutants from outside the reactor. Using the shielding concept of in-depth defense concept of Nuclear Safety Engineering, it is possible to prevent leakage of nuclear fuel radiation and prevent nuclear explosion from outside of dual structure block tank dust collector. Prevention of nuclear fuel radiation leak and primary fuel explosion prevention. Double structure block tank reactor The nuclear waste treatment is controlled to the inside of the nuclear power plant, and at the same time, the secondary structure is composed of a plurality of nuclear reactor facilities of a nuclear power plant having a double structure block tank reactor dust collector, Outside of double structure block tank dust collector It is equipped with dual pipe structure block piping to control nuclear waste treatment, as well as dual pipe structure block piping system, including a pressure sensor sensor and a water pump connection structure to efficiently improve the operation of the nuclear power plant. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Which is equipped with a safety valve and water pumps to generate soap bubbles contained in cooling water. It uses a nuclear waste disposal device, which converts the energy of water into kinetic energy, Of a nuclear power plant equipped with dual structure block tank dust collector The facility is a double structure block tank. It is a connecting structure composed of the outer surface of the outer wall of the former reactor building in the form of an egg. It has a double structure block tank for the treatment of nuclear power generation nuclear waste. Operation of Nuclear Power Plants in Land and Ocean Nuclear Power Plants to Improve Operation of Nuclear Power Plants Having Significant Difference Between Nuclear Reactor Facilities and Nuclear Power Plants Having Nuclear Radiation Leakage Control of Nuclear Waste Treatment Shielding Equipment Is generally equipped with double pipe structure block pipes having the potential energy of water and is equipped with a safety pressure sensor and water supply pumps to generate cooling water and soap bubbles, In the form of a structural capsule, along the circumference of the outer wall of the former reactor building Nuclear Power Plant Nuclear Power Plant for Nuclear Power Generation Dual Structure of Nuclear Power Plant Facility It is manufactured with a remarkable difference from that of the existing reactor facility where the explosion of the existing nuclear fuel chamber occurred because the nuclear power plant is installed.

The present invention relates to a nuclear power plant having a double structure block tank dust collector for collecting all of a plurality of nuclear reactor facilities for nuclear power generation of the prior art, 672 of the present invention will be described with reference to the drawings as follows.

Referring to FIG. 1, there is shown a schematic diagram of a conventional boiling water reactor (802) nuclear power plant showing an essential constitution of a conventional boiling water reactor plant nuclear power plant according to an embodiment of the present invention. Nuclear Reactor Facilities (802) Outline of Nuclear Power Plant Side Lateral Construction Road,

As shown in Fig. 1, the conventional boiling water reactor equipment 802 constituted from among various types of reactor facilities of the conventional nuclear power plant 672,

The reactor structure of a nuclear power plant according to the prior art has a structure in which the five-folded protective walls are formed in a closed structure, and explosion occurs in any one of the five-folded protective walls. If the number of neutrons is large, When the energy exceeds the danger level and then a boiler reactor that exploits the fission chain reaction in an ideal state explodes, it can be recognized that the boiling water reactor (BWR) It is a reactor that can use water as a moderator and coolant and boil it to directly drive the turbine of the generator. The steam void in the moderator caused by boiling has a negative reaction effect. Half of positive The output of the reactor can be suppressed by controlling the flow rate of the cooling water by changing the flow rate of the cooling water in addition to the control rod. The boiling water reactor (802) power plant is simple in system, Can be said to be an easy plant.

The suppression of the output of the boiling water reactor assembly 802 is controlled not only by the control rod 798 but also by changing the flow rate of the cooling water 287 so that the output of the boiling water reactor assembly 802 is suppressed by the recirculation flow rate control system, Water reactor facility (802) The power plant is composed of a power plant with simple system and easy operation control.

Referring to FIG. 1A, a reactor boiler 688A and a turbine building 688A, which illustrate a conventional boiling water nuclear reactor nuclear power plant internal structure showing an essential constitution of an embodiment formed by a conventional boiling water reactor plant nuclear power plant according to the present invention, A diagonal configuration of the waste building 688G in the diesel generator building 688E and the nuclear fuel building 688F in the control building 688C and the auxiliary building 688D in the building 688B,

1A, a reactor building 688, which constitutes one embodiment of a conventional boiling water nuclear reactor nuclear power plant, includes a control building 688C and an auxiliary building 688D in a reactor building 688A and a turbine building 688B. (688E) in the diesel generator building (688E) and the waste building (688G) in the nuclear fuel building (688F) to provide an easy connection control structure for operation of the boiling water reactor (802) of the nuclear power plant (672) And a power plant.

Hereinafter, as shown in Figs. 1A to 1D, the constituent elements of a conventional boiling water nuclear reactor nuclear power plant according to an embodiment will be described as follows.

Referring to FIG. 1B, there is shown a conventional boiling water reactor (802) nuclear power plant according to an embodiment of the present invention. As shown in the figure,

      Referring to FIG. 1C, there is shown a schematic view of an elementary boiling water reactor plant nuclear power plant according to an embodiment of the present invention, which is constituted by a conventional boiling water reactor plant nuclear power plant, road,

       Referring to FIG. 1d, there is shown a side view of a conventional boiling water reactor plant nuclear power plant showing an essential constitution of one embodiment formed by the operation of a nuclear power plant of a conventional boiling water reactor plant nuclear power plant according to the present invention As a result,

       As shown in FIG. 1B, a conventional boiling water nuclear reactor (802) nuclear power plant is formed by a conventional boiling water reactor (802) nuclear power plant. The following describes the main structure inside the 1100 MWe boiling water reactor pressure vessel 813 as follows.

The boiling water reactor (802) is the first commercial reactor developed. The boiler water reactor (802) has a capacity of 1.2 million KW and the capacity of the boiler water reactor (802) Unlike the facility 803, the steam generator 810 is not required, but the steam 780 containing the radioactive material circulates to the turbine 267, A steam separator 818 and a steam dryer 786 are disposed on the core 791 and a steam guide 786 and the like are disposed on the core 791 composed of the assembly body 671 and the control rod 798. A control rod guide tube 798e And a control rod drive housing 798a. Around the core 791, there are a core shroud, a jet pump 325, and the like.

     The fuel assemblies 671 of the boiling water reactor equipment 802 are arranged in a square lattice of 88, for example, a total of 64 such as 62 fuel rods 689, one spacer supporting water rod and one water rod, It is surrounded by a zircalodian channel box.

     The fuel rod 689 has a structure in which a uranium hexafluoride fuel pellet 683, a plenum spring or the like is loaded into a zircaloy cladding tube 682, helium 176 is sealed, and both ends are welded and sealed with a plug. The plenum is a space that accommodates the fission product gas discharged from the fuel pellets in accordance with combustion and is set such that the internal pressure of the fuel rod 689 is not excessive.

     The control rod 798 of the boiling water reactor has a crisscross blade to move through the gap formed by the four fuel assemblies 671 and the control rod 798 is provided with a boron carbide B4C Hafnium (Hf), or other types using them in combination.

     Below the control rod 798, there is a falling speed limiter having an umbrella-type structure in order to limit the falling speed of the control rod 798 when the drop occurs.

      In addition, there is a socket for coupling with the control rod drive mechanism.

     As the drive mechanism for the control rod 798, there are a hydraulic lubrication type and an electric drive type. In both systems, the nitrogen gas pressure stored in the accumulator is used for rapid insertion of the control rod 798. However, The entire control rod 798 is inserted into the core 791 at the lower part of the core 791 to stop the reactor installation.

Since the boron-containing water injection system capable of stopping the reactor installation can be installed even when the entire control rod 798 can not be inserted, the boron absorbs the neutrons 675 well. Boron-containing water is stored in the tank, 791).

1C, the carbon steel containment vessel 808 to the boiling water reactor installation 802 has a steel thickness of 3 cm, the pressure vessel 813 has a steel thickness of 16 cm, and a concrete hangar (reinforced concrete) 225 has a thickness of 200 Cm < / RTI >

First, in the control of the output of the boiling water reactor installation 802, the boiling water reactor installation 802 uses the hard water 654a as the moderator 676 and the coolant 816, (Void) generated in the moderator 676 by boiling in addition to generating steam of about 70 kg / cm 2 under pressure, and the hard water 654a is used to control the use of light water, that is, ordinary water It says.

      Secondly, when the control rod 798 is drawn out, the reactivity of the reactor increases and the output increases.

     Thirdly, when the boiling is promoted and the void is increased, the density of the moderator 676 is decreased, and the deceleration efficiency of the neutrons 675 is lowered, so that the negative reaction is applied.

     In the fourth case, when the reactivity of the positive and the negative reactivity generated by the withdrawal of the control rod 798 are balanced, the reactor output is stabilized.

     In the fifth case, when the control rod 798 is inserted, the opposite phenomenon occurs. Therefore, as the void decreases and the density of the moderator 676 increases, the efficiency of decelerating the neutrons 675 increases and a positive reactivity is applied to the reactor .

     In the sixth case, when the reactor is balanced with the negative reactivity applied by the control rod 798, the reactor is stabilized at a new output. Thus, the boiling water reactor assembly 802 has self controllability by voids.

     Next, the heat generated in the fuel rod 689 in the core 791 is transferred to the coolant 816.

     Next, in the boiling water reactor installation 802, heat transfer in the boiling region is utilized.

     In the ninth, the size of the heat flux flowing due to the temperature difference between the heat transfer surface and the coolant 816 is obtained in a lot of experiments, and in the transition boiling region where boiling is vigorous, the heat transfer is lowered so that the fuel covering material 681 may be burned The operation is restricted so as not to reach the transition boiling region during normal operation and during operation and during the operation.

     The heat generated in the fuel rod 689 is transferred to the coolant 816 in the tenth.

    Since the cooling water 287 is recirculated and the flow rate of the cooling water 287 is increased to increase the flow rate of the refrigerant flowing through the core 791, (816) recirculation system is provided.

     The twelfth one is that when the reactor installation is combined with the turbine generator 772, the reactor installation output can follow the turbine load.

     In the boiling water reactor installation 802, if there is a change in the load at the final stage, the control device 798 first adjusts the reactor installation output by increasing or decreasing the flow rate of the insertion or recirculation of the control rod 798.

     In this state, when the output of the reactor installation and the load are shifted, the pressure of the reactor installation increases or decreases.

    Thus, the pressure of the reactor facility is controlled by adjusting the opening of the turbine add / drop valve.

     This method is called "(Reactor Master / Turbine Slave) reactor facility priority system".

     When the turbine 267 stops abnormally, the flow of the steam is interrupted to increase the reactor installation pressure, but the bypass valve of the turbine 267 is opened to suppress the increase of the reactor installation pressure.

     As shown in Fig. 1d, the engineering safety system in the boiling water reactor facility 802 will be described as follows.

     If the cooling water 287 of the core 791 is lost due to a breakage accident in the piping of the reactor cooling system, (ECCS) is installed in order to prevent the damage of the fuel. This system is composed of a high pressure core sprinkler system, an automatic decompression system, a low pressure core sprinkler system and a low pressure injection system, It is connected to engineering safety systems.

     If a fuel breakage occurs, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

     However, it is also true that there is a problem to be considered, such as the operation of the power plant by enlarging the operation of the boiling water reactor (BWR, 802), and the securing of personnel related to these power plants equipped with maintenance and maintenance, As a long-term task of nuclear power in the future, it is thought that the construction of the nuclear power plant concept that is close to Siam is necessary for the next generation reactor considering social acceptance due to the lack of workers' resources. do.

     In the following, the study of the simplified boiling water reactor (BWR, 802) is based on the concept of SBWR (Simplified BWR) (600 MWe) (BWR, 802), a combination of a static containment system such as a static containment vessel cooling system and a gravity falling ECCS, including a 1000 MW expansion, and a natural circulation core. (BWR, 802), which is composed of a large natural circulation core, a static containment vessel cooling system, and a gravity falling type ECCS, (791) can eliminate the current BWR recirculation system, the recirculation pump (239) and the MG set and connection to it (BWR, 802), it is necessary to meet the problems and necessity of natural circulation establishment in order to realize the research of simplified boiling water reactor (BWR, 802) That is, the problem of response to output control remains.

     Second, the static containment vessel cooling system of the simplified boiling water reactor (BWR) 802 eliminates the decay heat of the core 791 after an accident for a long period of time, and various designs have been proposed. However, I / C (Isolation Condenser), which is a condensation heat transfer method using a water-immersion type insulation tube, which has high applicability to the furnace, has been selected.

     Third, the static safety system such as the gravity-drop type ECCS of the simplified boiling water reactor (BWR, 802) has an emergency power supply to the core 791 in case of an accident, Power is not strong. However, the continuous drive system and the complex network of conventional pumps, motors, valves, piping, and auxiliary machinery systems together with the above-mentioned static containment cooling system are greatly simplified, which reduces human factors related to operation. (791) irrigation is possible by reflecting the interpretation result of the accident such as water supply pipe breakage etc. To the full capacity and the applicability of this method is suggested.

     Hereinafter, the following directional description of the simplified boiling water reactor installation (BWR, 802) will be described as follows.

     In the simplified BWR, since a large amount of water such as the pressure control pool 240 as the source of the ECCS is installed on the upper portion of the containment vessel, the center has become higher and the containment vessel 808 has been severely subjected to various tests. have.

     As described above, since the elementary technology of the simplified BWR is a good step to confirm its conformity, the static simplification is starting from the existing concept that it is intimate to the person and it can be suitable for the social situation of the world in the future Potential technologies are provided.

     Uranium 235 (812), plutonium 239 (801), and neutrons 675 in the nuclear reactor (BWR) 802 operation of the boiling water reactor (BWR) 802 are mixed to prepare a mixed reaction of atoms and other atoms with the neutrons 675 However, since the generated neutrons 675 become triggers for generating the above-described reactions, they are called chain reactions. In the end, the control of the neutrons 675, that is, the control of the chain reaction, to be.

    The core 791 melting and nuclear meltdown in the boiling water nuclear reactor facility (BWR 802) operation includes the dissolution of the fuel assembly 671 and the core 791 structure by nuclear fuel overheating, The spent fuel rod 689 is exposed to the air when the cooling water 287 is not present, or the fuel rod 689 exposed to the air is overheated while the temperature rises, Radiation leakage becomes inevitable.

     In the case of the conventional boiling water reactor (BWR, 802) operation of the above-mentioned nuclear power plant, in 1986, when the Chernobyl accident occurred, the radioactive water vapor rose to 30,000 feet (9144 m) and suffered a long time. At worst, At the same time, the amount of uranium 235 in the spent fuel was less than 1%, so the radioactive efflux was possible. However, because there was no possibility of a nuclear explosion, the nuclear fuel rod (689) It took 6 months to cool down, and at the same time, when the temperature exceeded 2,000 degrees centigrade, radioactive materials such as cesium and iodine contained in the fuel rod (689) provided vaporization. At the same time, zirconium and water vapor were mixed, And the hydrogen generators are used as the coolant 816 to provide a temperature control of a conventional boiling water reactor facility 802 Or

     Referring to FIG. 1E, the operation of the nuclear reactor of the Fukushima boiling water reactor system before the accident, which shows the essential constitution of one embodiment formed by the operation of the nuclear power plant of the conventional accident-occurred Fukushima boiling water reactor plant nuclear power plant, Elementary Boiling Water Reactor Facilities as shown in Fig.

     As shown in Fig. 1 (e), the operation of the nuclear reactor of the boiling water reactor (802) is a boiling water reactor (BWR) type in which the steam of water boiling in the core is directly sent to the power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

     However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats did not disclose detailed information, refused to provide US technical support, and at the same time, they poured seawater into a wreckage and drove fire trucks and helicopters into the building.

     Due to this method, various impurities mixed with seawater were converted into radioactive isotopes and contaminated, and the contaminated seawater evaporated, spread to the surrounding area, and flowed into the sea and contaminated vast areas with radioactivity.

      Hiroshima, Nagasaki Japan, which has been devastated by the atomic bombs, has ironically built many nuclear power plants. On March 11, 2011, an earthquake and tsunami hit the northeastern part of Japan, causing the Fukushima nuclear plant to melt its core and leak radioactivity.

     Referring to FIG. 1F, there is shown a conventional boiling water reactor (802) nuclear power plant having a boiler water reactor (802) showing the essential constitution of an embodiment formed by the operation of a nuclear power plant, As a side view,

       As shown in Fig. 1F, the operation of the boiler-type nuclear reactor 802 is controlled by the nuclear waste in the nuclear reactor 802 and the spent fuel rods 689 in the boiler- Substances that have undergone a reaction. Concentrated plutonium, and enriched uranium. Exposure to air causes a fission reaction and releases radioactive material. The zirconium coating on which the fuel rod is packed is oxidizing, causing a fire. Radioactive materials can spread to the atmosphere due to fire.

     At the time of the Soviet Chernobyl Nuclear Power Plant explosion in 1986, when the nuclear reactor of the boiling water reactor facility (802) started to operate, a military helicopter was used to shield a huge amount of radiation from nuclear fuel and graphite moderator (676) 2,400 tons of lead, 1,800 tons of sand and mud. The boron compound was to absorb the neutrons that caused the chain reaction, while the lead and mud were to shield the radiation.

     The safe operation of the nuclear reactor facility of the boiling water reactor 802 is limited to the deceleration of the coolant 816 and the neutrons 675. The nuclear reactor coolant of the Dreamy Island, Chernobyl, and Fukushima nuclear reactors The uranium fuel rod 689 can not be cooled with water and is exposed to the air and melted. When the uranium fuel rod 689 melts, Uranium flows out and risks increase.

     In this situation, the Drill Mile Island nuclear power plant of the boiling water reactor facility 802 is sprayed with boric acid water by the emergency sprayer installed above the nuclear reactor building 688 and the emergency cooling water 287 is restored. Fortunately, Respectively.

Referring to FIG. 1G, a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional pressurized water reactor type nuclear reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1G, the operation of the nuclear power plant of the pressurized water reactor (803) is performed by supplying water to the pressurized water reactor (803) through water stored at a high pressure And is a pressurized water reactor 803 in which heat is transferred from the core to the steam generator 810. The steam generator 810 provides a turbine 267 operation to produce electricity, while the pressurized water reactor type reactor 803 is the most widely used nuclear reactor facility in the world. The pressurized water reactor or water- It is also referred to as a type pressurized water channel.

      In the pressurized water reactor type nuclear reactor facility 803, the hard water of the coolant compilation is firstly used in the PWR for the designing and editing of the pressurized water reactor, but in the primary system, it is provided at about 315 degrees Celsius, (654a) at 2000 psig and 15 MPa and a pressure of 150 times the atmospheric pressure do not boil while at the same time the water in the primary system is in the secondary system in most designs, the temperature is 275 degrees Celsius and the pressure is 900 psig The water flowing at a pressure of about 6.2 MPa is made into steam and sent to the steam turbine 267.

     In the case of the commercial pressurized water reactor type reactor installation 803 of the pressurized water reactor type nuclear reactor 803, the amount of the coolant 816 is constant, but the reactor can adjust the flow of the coolant 816, Neutrons 675 are provided in a reactor and have a shape similar to that of a thermal reactor design. However, many water molecules are the same size as the neutrons 675, and when colliding with the neutrons 675, neutrons 675 While the neutron "deceleration" is better with a higher molecular number of the water molecules, while the pressurized cooling water 287 has a structure in which the hydrogen atoms in the water molecules control the velocity of the neutrons 675 The use of water is one of the main safeguards of light water reactors, consisting of a neutron reduction structure that regulates the speed of water as it rises and the density of water molecules is lowered, If the neutron (675) deceleration structure has a lower void effect and at the same time the reactor malfunctions, the deceleration rate of the neutrons (675) becomes lower, the neutron (675) deceleration structure becomes lower, The inherent stability is very stable in a pressurized water reactor type reactor (803).

     The pressurized water reactor (PWR) facility is a nuclear reactor facility that uses water as coolant and moderator for pressurized water reactor pressure. The name of this reactor facility is the name of the internal circulation system, The pressurized water reactor facility is the most common reactor facility in the world. About 230 nuclear reactors are used for power consumption and hundreds of reactors are used for propulsion. Korea's standard pressurized water reactor facility (803) is constructed in Koryeong Gwangseong.

     In the early days of editing, the Westinghouse Betis Lab developed a military pressurized water reactor (803) at Westinghouse.

     In the United States, the pressurized water reactor facility (803) program operated the reactor from 1954 to 1974, but the first two pressurized water reactors (803) operated the TMI-1 and TMI-2 At this time, the construction of the new power plant was stopped due to partial core melting in TMI-2 in 1979, and at the same time, the core and fuel assemblies of the pressurized water reactor facility 803, the control rod and the pressure vessel 813, 658), a primary system, a secondary system, a condenser, a turbine and a generator connection structure, and the pressurized light water reactor provides a reactor chain reaction operation.

     In the pressurized water reactor (PWR) facility, it is delivered to the primary system circulating between the fuel and the heat exchanger 658. The primary heat system, called the primary system hot steam generator 810, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser 790 and at the same time enter the steam generator 810 again while at the same time the turbine 267 of the secondary system provides power production in connection with the turbine generator 772, (PWR, 803) facilities are compared with two pressurized light water reactors and other reactors. In a pressurized light water reactor, there are two cooling water primary systems and a secondary system Gt; 267 < / RTI > Frequency electric power production arranged in connection with (772) and or, at the same time, the two flows of water (hard water). In contrast, in a boiling water reactor (BWR), there is no strain.

Referring to FIG. 1H, a conventional pressurized water reactor type nuclear reactor (803), a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant operating at a nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, As an elemental aspect of the operation,

As shown in Fig. 1H, in the pressurized water reactor type nuclear reactor (803) nuclear power plant, the water pressure of the coolant compilation is changed from the PWR to the first However, in the primary system, it is provided at about 315 degrees Celsius, and at the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light valve 654a at a pressure of 150 times the air pressure does not boil, In the primary system, water is sent to the steam turbine (267) in most designs, with water vapor at 275 degrees Celsius and 900 psig at 6.2 MPa.

     The stability of such a pressurized water reactor type reactor (803) is such that when the pressurized water reactor is provided with a very stable production, but when the RBMK (graphite reduction speed boiling water pressure tubular reactor) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, they are heated and sintered. However, at the same time, the production of ceramic pellets made of uranium dioxide is carried out. (Zirconia), helium is injected into the zirconia rods to help heat transfer, but the finished fuel rods are bundled with bundles of fuel-fuel assemblies, which are called aggregate bundle fuels, It is loaded.

    It is very important to prevent a chain reaction from occurring in the core of a nuclear reactor facility that does not allow a rapid chain reaction in a pressurized water reactor (803) of the nuclear power plant of the nuclear power plant. However, when the chain reaction occurs, , Or 200 to 300 fuel rods of a pressurized water reactor, 150 to 250 fuel assemblies, or simultaneously enter uranium at 80, It is maintained at 14X14,17X17 pieces of about 100 tons.

     The pressurized water reactor (803) fuel bundle of the nuclear power plant operating at the nuclear power plant is provided at about 4 meters, and at the same time, there are many pressurized light water reactors with many pressure vessel control of the pressurized light water reactor and many pressure vessel controls of the military primary pressurized water reactor Adjust it to positive.

     In the pressurized water reactor type nuclear reactor facility 803 for operating the nuclear power plant, since the neutron is absorbed immediately, the reactor system is controlled by reducing the chain reaction by the pressurized light reactor. Therefore, the control pump of the entire pressure relaxation system is included. Is to provide high concentration of neutrons in a large number of emergency stopping cooling water, but also CANDU is an auxiliary means to enable the boric acid to quench the chain reaction. .

     In addition, the control rod enters the fuel assembly from the pressure vessel and is usually used when the first nuclear power plant is started or when the nuclear power plant is shut down. At the same time, the fuel assembly is regulated to a height at the reactor plant, The fuel rod of the stabilized fuel pellets of the barrier wall and the first barrier pellet was burnt inside the radioactive material generated by the fuel rod. The second barrier wall was enclosed with the nuclear fuel pellets and put into a metal tube of a special alloy as a nuclear fuel rod The small amount of gas that is released is a reactor vessel provided with a 20 cm thick steel containing the nuclear fuel assemblies in the reactor vessel which is the third barrier wall at the same time to provide a seal to the second barrier wall.

     In addition, the shielded concrete wall, which is the fourth barrier wall, prevents the leakage of the radioactive material as a concrete wall surrounding the nuclear reactor facility. In the containment vessel of the fifth firewall, the safety system and the whole space At the same time, the biological shielding wall of the 5-1 barrier wall is provided with a final biological shielding wall as a thick building 70 to 100 cm outside the steel, and at the same time, It is a container and a dome form, and it is a safe nuclear building to prevent the leakage of radioactive material, but at the same time, it provides an external shielding of radioactive material in case of an accident.

     However, the Chernobile model, RBMK, with a graphite reduced-rate boiling water pressure tubular reactor (RBMK), has become increasingly unstable as the thermal response increases, but the choice of this graphite-slowing boiling water pressure tubular reactor (RBMK) .

Referring to FIG. 1I, a conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional nuclear power plant pressurized water reactor facility (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in Fig. 1 (i), in the pressurized water reactor (803) nuclear power plant, the operation of the nuclear power plant is such that during the pressurized water reactor installation (803) .

Uranium fission and reactor facilities As mentioned above, 99.3% of stable uranium 238 is contained in natural uranium, 0.7% of unstable uranium 235 which can cause fission, and at the same time, domestic nuclear reactor types are mainly PWR ) And pressurized water reactor (PHWR). At the same time, the water reactor is a type of conventional nuclear reactor (803) operated by Kori, Yonggwang and Uljin, mainly supplied by the United States. (H ₂ 0) as a moderator (676), which is a material promoting the fission reaction using concentrated uranium (U-235, 4-5%) as a fuel, and at the same time one year or one year and six months Once the reactor is shut down, the fuel must be replaced.

In the meantime, the heavy water type reactor is a type supplied from Canada, which is currently in operation in Wolsong. As a characteristic, the reactor is horizontal and uses natural uranium (U-235, 0.72%) as fuel, moderator (676) ₂ O) and a portion of the fuel can be replaced daily.

Referring to FIG. 1J, the conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant. In the conventional nuclear power plant, a pressurized water reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1J, the operation of the nuclear reactor of the water reactor (803) during the pressurization operation is the same as that of the pressurized water reactor In the comparison of water reactor equipment during pressurization, the distinction between pressurized water reactor (PWR) and pressurized heavy water reactor (PHWR) is rated power of 1 million kW and 70,000 kW. The reactor type is vertical type, and the pressure vessel is a horizontal pressure tube. The operating pressure is from 158.2 kg to 110 kg at the operating temperature of ~ 310 ° C and the fuel used is fuel for the use of low enriched uranium (U-235, 4 ~ 5%) and natural uranium (U-235, 0.72% 816) and moderator 676 (D ₂ O), and the period of preventive maintenance of the fuel replacement period is 1 year to 1.5 years. At the same time, Wolsung nuclear power plant in Korea is a Canadian type This reactor installation uses cheap natural uranium (about 0.7% U-235) as fuel and moderator (676) and coolant (816) as expensive heavy water D ₂ O) is used.

     If the heavy water of the water reactor 803 is boiled during the pressurization, the reactor installation system is pressurized to about 110 times to prevent boiling of the heavy water because the reactor 676 and the coolant do not act properly. Water heated to 300 degrees Celsius is sent to the steam generator 810 and then heated to heat water on the secondary side through heat exchange to generate a steam 780 for driving the turbine generator. At the same time, as in the case of the pressurized light water reactor, And the turbine equipment side are completely separated so that the secondary side is the same as the pressurized light water reactor type, and at the same time, the cooling side material (816), which is slightly different in shape from the primary side, Heating is provided by the heat generated by the fission through the inside of the equilibrium cylindrical reactor, while the pressurized light water reactor (803) provides the reactor with a vertical barrel The coolant 816 is circulated from the lower portion of the core 791 to the upper portion.

     Referring to FIG. 1K, the pressure of the pressurized water reactor installation 803 of a conventional nuclear power plant showing the essential constitution of an embodiment formed by the operation of the nuclear power plant of the conventional pressurized water reactor (803) Internal decomposition of the pressure vessel 813 of the water reactor installation 803 during elemental pressurization, shown as the internal decomposition side of the vessel 813,

      As shown in FIG. 1K, the operation of a nuclear power plant at the pressurized water reactor (803) nuclear power plant has a low probability of causing nuclear fission when natural uranium is used as the nuclear fuel. Therefore, it is necessary to separately install the moderator (676) system, which is a heavy water reactor which can sufficiently absorb the neutrons and contribute enough heat neutrons to the nuclear fission while effectively decelerating the high-speed neutrons generated during the nuclear fission. At the same time, Three of the nuclear fuel change are basic characteristics of the pressurized heavy water reactor.

     Referring to FIG. 11, there is shown a structural configuration of nuclear fission of uranium fuel 235 showing nuclear fission structure of nuclear fuel uranium 235 showing the essential constitution of an embodiment formed by operation of a nuclear power plant of a conventional nuclear power plant according to the present invention,

       As shown in FIG. 11, the structure of the nuclear fuel pellet 683 of the nuclear power plant constituting the reactor facility of the nuclear power plant having the double structural block tank dust collector for nuclear nuclear waste disposal is described in detail as follows I will explain.

      The electrons are composed of the nucleus 815 and the electrons surrounding the nucleus 815. The nucleus 815 is composed of a proton 674 and a nucleon 675, (815b) that are transversely driven by the coupling force between the two forces.

]쯤 이나 그 질량은 원자(784) 질량의 대부분을 차지한다.The radius of the nucleus 815 is about 10 ^-14 m and the neutron 675 of the nucleus 815 is electrically neutral and the mass is almost the same as the proton 674 and the diameter of the nucleus 815 is atomic 784)

], The mass occupies most of the atom (784) mass.

     The structure of nuclear power generation is the same as that of thermal power generation. Nuclear power generation also generates steam by rotating a steam turbine. Nuclear power generation and thermal power generation have different ways of generating steam. The thermal power plant rotates the steam turbine 267 by burning coal, oil and natural gas in the boiler 778 , The nuclear power generation generates nuclear fission in the reactor, and steam is generated from the heat to rotate the steam turbine (267).

      The structure of an atom or a helium atom is an atomic nucleus 815 in which a proton 674 and a neutron 675 are combined with each other. The atomic nucleus 815 refers to the amount of static electricity carried by the object of the electron 785, (+), The charge of the same sign repulses each other, and the charge of the other sign pulls each other.

The number of protons (674) in the nucleus (815) is equal to the number of neutrons (675). The number of protons in the hydrogen and isotopes of triple hydrogen is all one If the number of neutrons (675) combined with the number of protons (674) is called the mass number, the half life of uranium 238 is 4.51 × 10 ⁸ years, shorter than uranium 238.

      The atomic nucleus of uranium (815) is a model of a red bead, a neutron (675), which is a proton (674). Uranium 238 (uranium 238) and uranium 234 (isotope 234) are weighted according to the number of neutrons It is different. First, uranium 238 (653a) is the most abundant uranium, but unfortunately it can not fission. The following are uranium 235 (812) and uranium 234, which are only slightly contained in natural uranium, so it is uranium 235 (812) that is capable of fission.

      The atomic nucleus 815 formed by the collapse of the radiation nucleus 815 contains a property that it is unstable and stabilizes even a little bit. It is a natural collapse, that is, it becomes a stable atom by self-emission of gamma rays to alpha particles or beta particles. 235 (812) has the greatest property, so the main role of nuclear power is uranium 235 (812).

     This is because fission occurs in the form of collapse of radioactive materials.

     However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the electric charge of the atomic nucleus (815) of Ura 235 (812) is +. Again, when a proton having a charge of + is collided, it repels each other by the law of charge and tangles the proton 820.

      Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

      When the neutrons 675 collide, the uranium 235 breaks up into pale yellow barium or silver white barium which is well oxidized in the air and krypton is a slightly colorless odorless gas mixed with air, At this time, large energy is generated.

      Referring to FIG. 1m, there is shown a partial side view of a method of using a control rod for controlling a chain reaction of nuclear fuel fission in a nuclear reactor of a conventional nuclear power plant according to the present invention. And the lower drawing shows a reactor fuel production and a decomposition of the steam generator 810, the pressurizer 814, and the coolant 816 of the reactor steam take-off system 1073, which show the process of generating plutonium in the uranium 238, Straight configuration Road,

As shown in FIG. 1 m, the number of protons 820 in the nucleus 815 is equal to the number of neutrons 675. The isotopes of hydrogen, for example, are hydrogen atoms in water and deuterium. The number of protons (820) is the same as the number of neutrons (675). The number of neutrons (675) is different from that of hydrogen and heavy hydrogen. The number of neutrons (675) Speaking of the half-life of uranium-238 (679) is shorter than 4.51 × 10 ⁸ years of uranium 238 (679) in.

The atomic nucleus of uranium (815) is a model of a red bead that is a neutron (675), which is a proton, isotope uranium 238 (679), uranium 235 (812), and uranium 234 is a neutron (675) Uranium 238 (679) is the most abundant uranium, and unfortunately, it can not be fissioned. Therefore, uranium 235 (812) and uranium 234 are contained only in natural uranium, which means that uranium 235 812).

The atomic nucleus formed by the collapse of the radiation nucleus 815 contains a property that it becomes unstable to become even a little stable. It is a natural collapse, that is, it emits gamma rays to alpha particles or beta particles and becomes a naturally stable atom 784. Uranium 235 (812) has the greatest property. So the main role of nuclear power is uranium 235 (812).

Because nuclear fission now occurs in the form of the collapse of radiation.

However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the charge of the atomic nucleus (815) of uranium 235 is +. Again impinging the protons 674 having a charge of + will repel each other and tie the protons 674 by the law of charge.

Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

When the neutrons 675 collide, uranium 235 (812) is split into a colorless odorless gas that is barely oxidized in air or krypton is slightly mixed in the air, provided that the barium is either pale yellow or silver white barium, There are three bounces, which generate a large amount of energy.

Originally, uranium 235 (812) absorbs slow neutrons (675), but the neutrons (675) that are fresh from nuclear fission can not catch the neutrons (675) because of their high velocity. In order to slow down the velocity of fresh neutrons from nuclear fission Or a heavy water or graphite moderator 676 having a larger molecular weight than ordinary water is used.

If the particles collide with heavy objects, the neutrons 675 are splashed out. However, if the particles are of similar size, the neutrons 675 will eventually fall into thermal neutrons 675 because they are splashed. The thermal neutrons 675 are not hot, And the neutron 675 having an energy of less than leV (electron volt) is called a heat neutrality. The neutrons 675 collide with another uranium 235 (812) to divide and collide, . 1e V to 1k e V are called low-speed neutrons (812), and 100k e V to 10M e V are high-speed neutrons (675).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons may be increased when the chain reaction is finished, but that is not so. If the number of neutrons (675) is high, the chain reaction becomes excessive, and the energy generated when the nuclear fission breaks out exceeds the danger level, and then the reactor of the nuclear reactor in which the fission chain reaction proceeds in an ideal state is exploded.

In order to prevent such an explosion, a control rod 798 made of cadmium is inserted and controlled to control a chain reaction of the fission in the reactor, but since the control rod 798 eats the neutron 675 generated from the fission, Which slows down the neutron 675. In nuclear fission, the speed and number of neutrons (675) are controlled by the end of the running horse.

When 1 k g of uranium 235 (812) is cleaved, neutrons (812) protrude from barium and krypton, and their mass is lighter than 1 k g of original uranium 235 (812).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons (675) is probably good after the chain reaction, but that is not it. If the number of neutrons (675) is too high, the chain reaction will be excessive, and the energy generated when the nuclear explosion occurs will exceed the danger level. If this happens, a nuclear reactor will be exploded that will progress the fission chain reaction in an ideal state. In order to prevent such an explosion, In order to control the chain reaction, the control rod 798 made of cadmium is inserted and removed, and the control rod 798 eats the neutrons 675 generated from the fission, so that the moderator 676 lowers the speed of the neutrons. In nuclear fission, the velocity and number of the neutrons (675) are controlled by the endothelium, and when one kilogram of uranium 235 (812) breaks down, neutrons (675) protrude from barium and krypton, 812) It is lighter than 1kg compared with 1kg.

According to Einstein's formula E = mc ² , this lighter mass is converted to the kinetic energy of barium and krypton and neutrons (675). In theory, a mass of 1 g is the same heat as when about 2150 tons of oil are burned together. In fact, the energy of 1k g of uranium 235 (812) is calculated as 20 billion kcal of energy. If it is gasoline, it is enough to make 500 rounds of cars by car, 300 tons for coal, and 2 million liters for oil One neutron (675) divides one uranium nucleus into two or three neutrons (675).

Referring to FIG. 1, a conventional gas cooling furnace reactor 804 according to the present invention includes a gas cooling furnace reactor 804 of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, (804) side-by-side configuration of the elementary gas cooling furnace reactor,

1N, in the structure of the gas cooling furnace reactor facility 804, graphite is used as a moderator 676, carbon dioxide is used as a coolant 816 in the gas cooling furnace in the structure of the gas cooling furnace reactor facility 804 And the use of natural uranium and enriched uranium 235 as the fuel and the use of carbon dioxide as the coolant 816. At the same time, the thermal efficiency and the thermal efficiency equivalent to the thermal power of the high-temperature and high- And at the same time, the structure of the nuclear reactor furnace facility 804 is configured to perform nuclear power generation.

A nuclear reactor facility using gas as a coolant 816 to the gas-cooling furnace reactor facility 804, a calderhall type of graphite-retarded natural uranium fuel type, carbon dioxide gas (CO ₂ ) as its reforming type, and a high temperature gas- (CO ₂ ) is supplied to the cooler 816 as a cooler hole type reactor, which is a nuclear reactor type reactor with a deceleration natural uranium fuel type reactor, and an improved version thereof, while using helium (He 176) The generic name of the reactor used by. The structure of a gas-cooled furnace reactor (804), which is a typical reactor cooling furnace reactor developed in the UK, using natural uranium as fuel, graphite as a moderator 676, carbon dioxide gas as a coolant 816, and the like.

     Referring to FIG. 10, there is shown a conventional gas cooling furnace reactor facility 804 according to the present invention, an elemental conventional gas cooling furnace reactor facility 804 showing the construction of an embodiment formed of a nuclear power plant, As a side view,

    1O, a gas cooling furnace reactor facility 804 formed by the nuclear power plant operation of the nuclear power plant is provided with a coolant 816 inside the reactor pressure vessel 813 of the gas cooling furnace reactor facility 804, And carbon dioxide gas is supplied from the carbon dioxide gas 164 and the coolant 816 provided in the gas cooling furnace reactor facility 804 The helium 176 is provided as a coolant 816 and at the same time the connection structure inside the reactor pressure vessel 813 formed by the operation of the nuclear power plant is connected to the recirculation pump 239 and the water feed pump 241, The steam 780 and steam are cooled in the pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689 and the steam pipe 779 and the steam pipe 779, Which is a cooling device of the apparatus for making the reactor 790, the core 791, A control rod drive housing 798a provided inside the heat exchanger 793 and the control rod 798, a control rod drive shaft 798b and enriched uranium 812, and a gas cooling furnace reactor facility 804 ) To make nuclear power.

      Referring to FIG. 1P, there is shown a constitution of an embodiment of a steam generator 810 of a conventional nuclear power plant reactor according to the present invention. One elementary nuclear power plant reactor generator steam generator (810) Side construction of connecting structure Road,

      As shown in FIG. 1P, the structure of the steam generator 810, which is formed by the connection structure of the steam generator 810 of the reactor plant of the nuclear power plant, includes a steam outlet 810a and a water supply nozzle 810b to the turbine generator, The cooling water 810c, the vibration suppression rods 810d, the tubular support pipe 810e, the tubular lid 810f, the tubule bundle 810g, the tubular steel plate 810h, the separation plate 810i, the primary outlet 810j, A steam generator 810n and a steam generator internal body 810o as a connection structure of a steam generator 810 of a nuclear reactor nuclear reactor installation. The steam generator 810a includes a primary inlet 810k, a heat exchange tube 810l, a cooling water passage 810m, The formed steam generator 810 facility structures include the recirculation pump 239 and the feed pump 241, the circulating water pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689, A pipe 779 and a steam 780 and a cooling device 780 for cooling the water vapor into water, A control rod drive shaft 798a and a control rod drive shaft 798b and enriched uranium 812 provided inside the core 791 and the reheater 793 and the control rod 798, And a reactor facility (804) for nuclear power generation.

Referring to FIG. 1q, a conventional multipurpose hot gas furnace reactor 805 of a conventional nuclear power plant showing an essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the nuclear power plant 805 of the conventional multi-purpose hot gas furnace according to the present invention, Elementary gas cooling furnace reactor facility (804) side view configuration showing nuclear operation as external side view

As shown in FIG. 1Q, the multi-purpose high temperature gas furnace 805 is provided with a multipurpose hot gas and the reactor installation 805 is provided with graphite as a moderator 676, and the coolant 816 includes helium gas 176). At the same time, the fuel is composed of enriched uranium 235 and thorium, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation.

Referring to FIG. 1 r, a conventional multi-purpose high temperature gas furnace reactor 805 nuclear power plant (FIG. 1), which shows the construction of a conventional multi-purpose hot gas furnace reactor 805 nuclear power plant 672 according to the present invention, 672 in a side view of the nuclear reactors 805 side of the elemental multi-purpose high temperature gas reactor,

As shown in FIG. 1 (r), graphite is used as a moderator 676 in the structure of the nuclear reactor 672 multi-purpose high temperature gas reactor 805, and helium gas 176 is used as a coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, The operation method includes a water pump 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser The control rod 798 and the coolant 816 are connected to the reactor structure 805 as a multipurpose hot gas of the nuclear power plant 672 to constitute nuclear power generation.

 Referring to FIG. 1s, there is shown a constitutional example of a conventional multi-purpose hot gas furnace 805 nuclear power plant according to the present invention. The constituent conventional multi-purpose hot gas furnace 805 and the new conversion furnace 805, Nuclear reactor facility (806) Elementary multi-purpose high temperature gas reactor facility (805) and new conversion furnace reactor facility (806) showing side view of nuclear reactor operation of nuclear power plant.

The use of graphite as a moderator 676 is provided for the structure of the reactor facility 805 of the nuclear power plant 672 and the use of helium gas 176 is used for the coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, In the operating mode, the internal structure 805a of the Pebble-Bed type high-temperature gas path in which the primary cooling system is housed is provided with the heat shield 805b, the through-hole stopper 805c, the auxiliary circulator 805d, the control rod reservoir 805e, The control unit 805g and the auxiliary circulating unit 805h and the auxiliary heat exchanger 805i and the core support structure 805j and the prestressed concrete reactor vessel 805k and the PCRV safety valve 805l, A fuel inlet 805m, a helium circulation unit 805n, and PCRV The HTR-module reactor structure 805p includes a spherical fuel outlet pipe 805q, a boron refining furnace system 805r, a reflector region control rod 805s, A gas circulating unit 805w and a high temperature gas pipe 805x, a surface cooler 805y and a heat insulating material 805z, and at the same time, the fuel supply pipe 805t, the water supply pipe 805u, The use of enriched uranium 235 (812) and thorium and the heat of helium gas 176 are transmitted to water to generate nuclear power by steam generation. At the same time, 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser 790 and a control rod 798 and the coolant 816 to connect the reactor facility 805 to the multi-use hot gas of the nuclear power plant 672 At the same time, nuclear power plant (672) is operated as a nuclear power plant. In the new reactor type reactor structure (806), a new type of reactor power plant (806) And the steam is supplied to the steam turbine 267. The steam is supplied to the steam turbine 267 through the steam turbine 267, The heavy water 654b is used as the moderator 676 and the neutrons 675 are more absorbed than the hard water 654a so that the utilization efficiency of the uranium is increased so that the plutonium (ATR) as an example, the MOX fuel of "Fugen" is taken as an example, and the characteristics and specifications of the fuel for ATR and the manufacturing method thereof Do technology However, since the ATR is a water-cooled type, such as a heavy water reduction ratio, and a pressure tubular type, the fuel assembly has a circular section and is slightly lower in plutonium hatching than the MOX fuel for a light water reactor. However, Equivalent, PuO2 and UO2 powder adopts a two-phase combination method to prevent the generation of plutonium spots and scattering of plutonium hatching degree.

Referring to FIG. 1 (a), a nuclear power plant of a conventional nuclear power plant showing the essential constitution of one embodiment formed by the operation of a nuclear power plant of a nuclear power plant of a conventional new type conversion reactor 806 according to the present invention, New Transition Reactor Facilities (806)

As shown in Fig. 1 (t), the new conversion furnace 806 and the characteristics of the fuel are developed as a national project together with a fast breeder reactor as a Japanese independent reactor, and the use of heavy water as a moderator Therefore, it is a resource saving type power generation furnace capable of efficiently controlling the fuel combustion with a lower degree of enrichment than the light water reactor.

It is possible to freely load with MOX fuel and non-enriched uranium fuel because there is a relatively small influence on the reactor due to the kind of fuel. It is necessary to consider arrangement and control rod as in the case of using MOX fuel in light water reactor There is no.

Since the new type conversion reactor 806 is a heavy water reducing boiling water cooler and is a pressure tubular type, the fuel assembly has a circular section. In addition, there are SGHWR of UK and CANDU-BLW of Canada, There is no example in which a large number of fuel such as ATR is used.

The fuel of the new conversion furnace reactor 806 is slightly lower than the MOX fuel for the light-water reactor, but the fuel production method is almost the same, and the plutonium of the inner fuel rod whose neutron density is lowered Hatching degree is raised.

The structure and specifications of the fuel "Fugen" fuel of the new conversion furnace 806 include "Fugen" MOX fuel, in which 28 fuel rods are arranged concentrically with four inner layers, 8 middle layers and 16 outer layers, The upper and lower tie plates are placed on the upper and lower tie plates, respectively. In the middle, the fuel rods are maintained at appropriate intervals with twelve spacers at appropriate intervals. The main specifications of the fuel assembly and the fuel rods and the assembly are shown. Also, the plan has been discontinued, but the main specification of the 36-fuel assemblies developed as a fuel for the reactor facility (806) demonstration after the "Fugen" was also presented.

Fuel of the reactor plant 806 of the new type conversion furnace 806 is produced by mixing the PuO 2 powder and the UO 2 powder, press-molding them, and then sintering them to prepare pellets, filling them into cladding tubes to form fuel rods, And at the same time, this fuel processing method is almost the same as MOX fuel for fast breeder reactors and light water reactors, and the shape of the pellets is not limited to the corner chamfer used in BWR and the dish used for PWR And the fuel cell system 806 is provided with the fuel cell of the new type conversion reactor 806 adopting the both.

The fuel of the new conversion furnace reactor (806) is mixed with a lubricant to a particle size suitable for molding, and then molded into a green pellet by press molding. At the same time, this is pre-sintered at 800 ° C to evaporate the lubricant After disassembling, sintering is carried out at 1,650 ° C for 2 hours. At the same time, the sintered pellets are judged whether the whole water is passed through a diameter separator. If the diameter is large, the side of the cylinder is grinded with high accuracy by a centerless grinder, At the same time, unlike the case of high-speed fuel, plutonium hatching degree is low. Therefore, no-core grinding using ordinary water such as uranium fuel is provided. The pellets completed with the above-mentioned new type conversion reactor facility 806 are subjected to various analyzes and inspections, and passed through the inspection of the government office and passed to the fuel rod processing step, which is the next manufacturing step.

The pellet of the new conversion furnace reactor 806 is automatically filled by plugging the clad with a plug welded on one side. At this time, the end of the cladding tube is contaminated by contact with the pellet, A countermeasure for mounting a thin plate called a pipe mouth mask on the tube end is provided.

After plugging the pellet of the reactor installation 806 with the new type of conversion, a plug is attached to one of the remaining pipes and sealed and welded by TIG welding to provide a fuel rod. After that, the sealed fuel rod surface is carefully decontaminated, After making the draw from the box and then performing various nondestructive tests such as surface contamination, appearance, dimension, bending, and X-ray penetration test of the welded part, it is inspected by the government office and passed to the assembling process of fuel assemblage which is the next manufacturing process.

If the upper and lower tie plates and the twelve spacers are fixed in advance in a predetermined position of the automatic assembly apparatus, the fuel assembly assembly of the new type conversion reactor unit 806 can be automatically inserted Thereby completing the fuel assembly. The aggregate is inspected and cleaned by bending and twisting, passed the pre-use inspection of the government office, and shipped to the nuclear installation site.

Referring to FIG. 1U, a new type conversion reactor furnace 806 of a conventional nuclear power plant 672 according to the present invention is installed in a nuclear reactor main body of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment A dual structure block for treating nuclear waste according to the present invention. The present invention relates to a dual structure block tank for a nuclear power plant having a dust collector, a new conversion furnace facility (806) provided in a reactor facility, and an elementary nuclear Double Structure Block for Waste Treatment Nuclear Power Plant Reactor Facility Having a Tank Dust Collector In the present invention, a new reactor furnace facility (806)

As shown in FIG. 1U, the nuclear explosion-proof double structure block tank 598 in the form of a raw statistic of the nuclear power plant 627 is provided with a double structure block tank 598 among the plurality of reactor facilities for processing radioactive nuclear waste. A new type conversion reactor 806 in the structure of the nuclear reactor facility 806 which uses the light water 654a as the coolant 816 to increase the utilization of the nuclear fuel than the existing reactor And the steam is generated at the high temperature during the rising of the fuel, so that water and steam are separated from the steam drum, and the steam is sent to the steam turbine 267 to form an energy nuclear power. The heavy water (654b) The absorption efficiency of neutrons is lower than that of hard water, and the efficiency of utilization of uranium is increased. As fuel, nuclear power generation using plutonium and natural uranium is formed, A double-structure block tank is provided with a double-structure block tank dust collector for treating nuclear waste, which is in the form of raw statistics, in a nuclear reactor plant having a dust collector, Inside the reactor facility of the nuclear power plant, a new conversion reactor facility (806) consists of the input of the carrier construction machine.

Referring to FIG. 1 v, there is shown a cross-section of an elemental conventional nuclear power plant reactor building 688 showing the construction of an embodiment of a conventional nuclear power plant according to the present invention, and an elemental reactor building Sectional view of fuel rod 688 and detailed side configuration of fuel rod 689,

As shown in FIG. 1 v, in the section of the nuclear power plant reactor building 688 and in the fuel rod 689 facility, the facilities of the nuclear power plant reactor building 688 include reactor building 688A, turbine building 688B, The facility 688 of the nuclear power plant reactor 688 is provided with the building 688C and the auxiliary building 688D and the diesel generator building 688E and the nuclear fuel building 688F and the waste building 688G, The fuel bundle adjustment 689a and the upper nozzle 689b and the fuel rod adjustment 689c and the fuel rod 689d and the spring clip assembly 689e and the lower end nozzle 689f and the fuel rod rear end cap 689g, Plutonium (689h), hold down spring uranium (689i), and dioxid fuel pellets (689j), gas caps (689k) and zircaloy crowding (689l) are used to operate nuclear power plants.

Referring to FIG. 1w, a conventional high-speed multiprocess reactor (838) nuclear power plant according to the present invention includes a nuclear power plant, A lateral side view constituting an elemental side view,

As shown in FIG. 1w, in the structure of the fast breeder reactor facility 838, the high-speed breeder reactor facility 838 includes uranium enriched in about 20% of enriched uranium 235 at the central portion of the fuel rod 689, And plutonium 801 formed from uranium 238 (653a) is contained in the fuel rod 689. The plutonium 801 is taken out and used as the next fuel The coolant 816 does not contain the moderator 676 and the intermediate heat exchanger 657 does not contain the heat generated from the reactor in the intermediate heat exchanger 657 because the liquid metal sodium is used and the neutrons 675 need not be decelerated. Liquid metal sodium, while the heat exchanger 658 converts the water into steam by the heat of the liquid sodium so that the steam turbine 267 rotates to make nuclear power.

Referring to FIG. 1x, an elemental conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of one embodiment formed from a conventional fast breeder nuclear reactor facility 838 nuclear power plant, (838) disassembled lateral strabismus structure,

    Referring to FIG. 1 (a), an elementary conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of an embodiment formed from a conventional fast breeder nuclear reactor 838 nuclear power plant according to the present invention, As shown in the side view, an elemental fast breeder reactor facility (838)

       As shown in FIGS. 1x and 1y, the fast breeder reactor facility 838 generates nuclear energy by generating a nuclear fission reaction using a high-speed neutron and produces uranium, which is a non-fissile material that accounts for 99% of natural uranium 238 (653a) to uranium 239 (653), which is a fissionable material, and at the same time, it is a high-speed propagation furnace facility 838, so liquid sodium metal is used as a coolant 816. However, Because the neutron 675 rate is low because the uranium 235 (812) is focused on the fission, the fast reactor reactor 838 has a high neutron 675 velocity.

     It is common for the fast breeder reactor facility 838 to reduce the amount of fissile material, especially when burning the fuel within the reactor facility 838, where the breeder initially produces more plutonium 801 than the amount of plutonium 801 The plutonium 801 is consumed but the uranium is converted into plutonium through the reaction. As a result, plutonium 801 is consumed more plutonium 801 than plutonium 801, (801). However, if 1 g of uranium 238 is used at the same time, it will be propagated as 1.17 g of plutonium 239 in the reactor and used as fuel. If such a liquid metal is put into practical use, However, when the liquid sodium used as the coolant 816 is combined with the water air, The cause has the problem in a practical use very difficult to ensure the handling skills to easily corrode the pipe it stably.

     The Super Phosphorus in France and the Monju Fast Breeder Reactor in Japan to the fast breeder reactor facility 838 were able to continue to use the fuel that had already been used, It is called a "dream reactor" that produces fuel, "the more fuel it gets."

Existing light and heavy water reactors H2O and heavy water D2O are used as a moderator 676 and a coolant 816 in the reactor plant 838 to generate fission by using low energy thermal neutrons. While the sodium-cooled high-speed furnace uses a high-temperature liquid sodium (Na) as a coolant without a moderator 676, thereby providing a fission reaction using a high-speed neutron having a higher energy than that of the light water reactor and the heavy water reactor. Since the cross-sectional area of the neutron (675) is remarkably reduced, a high-concentration fuel is provided in order to generate the necessary amount of fission, and at the same time, the power density is high and the reactor size can be made smaller than that of the light- .

In order to overcome the disadvantages of the sodium coolant, there is a closed 'sodium intermediate system', which is designed to heat the water in the steam generator without direct contact between sodium and water. At the same time, all piping and walls through which sodium flows are double A system in which the sodium of sodium DHX (sodium-sodium heat exchanger), which seals the leak or is warmed by hot sodium, rises up the piping and cools it through an AHX (sodium-air heat exchanger) There is one more important story that is missing, worrying about waste and worrying about safety, more economical, more economical and not meeting the high-speed cooling roads, or if the fast breeder reactor facility (838) is provided, Rather, spent fuel that has been stored in the basement can be taken out and reused.

Hereinafter, the conventional nuclear waste disposal method and the cause of the nuclear explosion accident will be described as follows.

      Referring to FIG. 1Z, a conventional nuclear waste disposal method according to the present invention includes a disposal facility 1030 of a nuclear facility 1029, a nuclear waste disposal method 1040 according to a previous design of a plutonium disposal process 1040 in dismantling a nuclear weapon The construction of the conventional elemental nuclear waste disposal method showing the difference showing the construction,

      As shown in FIG. 1z, in the conventional constitution of the nuclear waste disposal method, uranium used as nuclear fuel for a nuclear power plant is purified by purifying natural uranium so that uranium 235 can be concentrated by 3 to 4% and used as a nuclear weapon Of uranium enriched to 95%. As a result of negotiations to reduce nuclear weapons in the 1990s, many nuclear weapons have been dismantled. However, with the remaining nuclear weapons, humanity has been wiped out several times, We have also made uranium for power generation by mixing an appropriate amount of uranium 235 from nuclear weapons into natural uranium. But these nuclear fuel rods are called MOX, but how does nuclear fission occur in reactors? It begins by striking the nucleus of uranium 235 with a neutron, which when hit with a neutron causes unstable uranium 235 to fission and turn into another stable element.

     In the above-mentioned conventional elementary nuclear waste disposal method, while releasing three neutrons with energy as much as the mass difference, the neutrons hit the other uranium 235 to cause nuclear fission, so that the fission occurs sequentially, (675), and then grasps the neighboring fangs, and then the fellow next to it fissures and squeezes the neutrons (675) to squeeze them beside them .

     The conventional elemental nuclear waste disposal method does not divide uranium 235 into neutrals 675 into a nuclear reactor facility, disintegrate and heat the nuclear reactor 675, and crack neutrons 675 at the same time, At the same time, the Uranium 238 gladly does not know the neutrons (675), accepts the neutrons (675) and turns them into my family, then turns into a plutonium (801), and at the same time keeps neutrons Because it is too hot, the cadmium rod is inserted between the fuel rods to absorb and reduce the neutrons (675), and the boron acid is added to the reactor coolant to slow down and calm the neutrons (675).

      As shown in FIG. 1z, in the constitutional arrangement of the conventional nuclear waste disposal method, the plutonium disposal process 1040 in the dismantling of the nuclear weapon includes the nucleus 1029, the dismantling facility 1030, And a deep underground cave 1038 in the MOX processing 1032 and the MOX combustion furnace 1033 and the mixed glass solid 1034 and the high level waste 1035 and the final repository 1036 and the long term storage 1037, The fuel rods 683a and 683c are provided with fuel rods 683a and 683c in the fuel rods 683 and 683a, The lower end nozzle 683f and the fuel rod rear end cap 683g and the plunger 683h and the hold down spring 683i and the uranium dioxide fuel pellet 683j and the gas cap 683k) and zircaloy crowding (683l) and consists of nuclear waste disposal methods of nuclear fuel (683) There is.

     As shown in FIG. 1 (a), in the conventional method for treating nuclear waste, the difference between an atomic bomb and a nuclear reactor is that the fuel of a nuclear reactor containing a small amount of uranium 235 is less likely to be fissioned by a neutron generated by fission, There is no intense chain reaction such as a bomb, the atomic bomb explodes at once, and the nuclear power plant burns low enriched uranium (812) by letting it burn slowly by regulating the fuel (683) with diluted uranium 235 (812) The fuel filler 683 is a nuclear fuel rod 689 filled with a pellet 683 and a zircaloy pipe 682 which is a cladding tube 682. The fuel rod 689 is formed into a square bundle If the number of neutrons 821 is large due to earthquake and tsunami during operation of the nuclear power plant, the chain reaction will be excessive, If the energy exceeds the danger level and the nuclear fission chain reaction proceeds in an idealized state, then many nuclear reactors will explode like atomic bombs, (683) is a key cause of the explosion.

As shown in FIG. 1Z, in the conventional nuclear waste disposal method of the related art, a plurality of existing nuclear reactors include a dust collector 794 of an exhaust gas (171) facility and an exhaust gas 171, In view of the lack of exit and entrance, the explosion of Fukushima Dai-ichi Nuclear Power Plant, caused by a failure of the cooling system caused by the tsunami on March 13, 2011, is a reactor that can not accommodate the high temperature and high pressure inflation and expansion liquid inside the reactor. As a direct cause of the accident, the water, which is the inflating liquid of high temperature and high pressure after the failure of the cooling system, turns into steam, and the steam of high temperature and high pressure is combined with the high temperature high pressure inflation gas at the moment of chemical decomposition of oxygen and hydrogen. At the same time, an electronic flame generated by air friction due to an earthquake is generated, so that its electron flame is ignited by high temperature and high pressure oxygen and hydrogen, The secondary explosion after a primary explosion outside the on-pressure vessel and inside the nuclear reactor building is caused by the explosion of the reactor in the core of the nuclear fuel vessel inside the pressure vessel, causing the explosion of a nuclear explosive It is recognized as a key cause of the nuclear explosion of the first nuclear reactor, recognizing that it has an abrupt chain explosive shape.

As shown in FIG. 1 (a), the above-mentioned conventional elementary nuclear waste disposal method includes a nuclear disaster of a conventional nuclear submarine and a nuclear-powered aircraft carrier, and an explosion of a reactor engine until now, (688), which is the fifth protection wall made of concrete, among the ones equipped with a plurality of nuclear reactor facilities installed inside the body of the hull deck deck of the barge, because it can carry out the construction Since the barge hull 591 itself formed of the double structure block tanks 598 itself corresponds to the fifth protection wall, the reactor building 688 formed of concrete in the past has the reinforcing concrete mat 225 generated at the time of explosion of the reactor, Waste ([<<<, >>>], 224) is a cause of environmental pollution by turning into detonated explosives combined, There deulsu that you meet the hellish chain of explosions explosives shaped like the reactors in operation in the transition to a hydrogen bomb atomic bomb reason, be recognized as a key cause of the explosion of the first nuclear reactor.

As shown in FIG. 1Z, in the conventional method for treating nuclear waste, the conventional nuclear reactors of various types have been equipped with a dust collector and an exhaust gas outlet of an exhaust gas facility, The explosion accident at the Fukushima Dai-ichi Nuclear Power Plant caused by the failure of the cooling system caused by the tsunami on March 13 is a reactor that can not cope with the high-temperature high-pressure inflation gas and the expansion liquid inside the reactor. After the failure of the cooling system, the water, which is the inflating liquid of high temperature and high pressure, turns into steam, and the steam of high temperature and high pressure is combined with the inflation gas of high temperature and high pressure at the moment of chemical decomposition of oxygen and hydrogen, The electronic flame is ignited by oxygen and hydrogen at high temperature and high pressure to cause hydrogen explosion, The secondary explosion after the primary explosion on the outside of the vessel and inside the nuclear reactor building is due to the nuclear explosion in the core of the fuel vessel inside the pressure vessel, In the present invention, in contrast to the conventional nuclear reactors, the double-structure block tank reinforced with the concept of defense in depth, the nuclear power plant of the nuclear and hydroelectric power plants of the offshore and offshore, Nuclear Radiation Leakage Control of Nuclear Reactor Facilities of Waste Treatment Shielding Unit Double structure block tank Double pipe structure piping using energy of water composed of distributing device of dust collector and equipped with safety pressure valve and water pumps as temperature pressure sensor, By selecting the method of automatically injecting the mixture of yellow loess that generates soap bubbles, And the nuclear waste shielding method of the dispensing device of the apparatus for controlling fuel and fuel explosion.

Referring to FIG. 2, a nuclear reactor power plant having a dual structure block tank reactor for nuclear waste treatment according to the present invention is provided with a power generation facility connection structure equivalent to the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 The thermal power plant 626 of the conventional thermal power plant 626 showing the essential constitution of an embodiment formed by the thermal power generation operation of the conventional thermal power plant 626 has the operation mode of operation of the thermal power generator 772 of the thermal power plant 626, Thermal power generator (772) Operation method Elementary side profile Straight configuration Road,

As shown in FIG. 2, the thermal power generator 772 of the conventional thermal power plant 626, which shows the essential constitution of an embodiment formed by the thermal power generation operation of the thermal power plant 626, The conventional operation method of the thermal power generator 772 of the thermal power plant 626 shown in FIG. 7 is similar to that of the conventional nuclear power plant of the world-wide nuclear power plant in that the boiler and the reactor of the thermal power plant are technically differentiated, In order to understand the structure of nuclear power, it is necessary to understand the structure of the boiler (778) and the melting furnace (783) to dissolve the metal. In order to understand the structure of nuclear power generation, (1) of a nuclear power plant having a structural block tank dust collector to control the operation of the nuclear power plant of the nuclear power generation facility (811) It handles all the tasks of a central control station (781) is equivalent to the computer.

On the other hand, coal-fired power plants are constructed on coastal areas or coasts where there is usually a large demand for electric power, and due to the exhaust gas emitted from the stack, the order of the ecosystem is broken, and dusts such as soot, The natural disaster has reached a serious level due to the global warming phenomenon due to the increase of the discharge, etc. The countermeasure against this is that the inventor of the present invention installs a seesaw-type wind turbine hydropower generator of the nuclear- , Which is a means of solving human anxieties with endless production of environmentally friendly energy.

The thermal power generation unit of the post-thermal power plant 626 before the failure recovery of the nuclear power generation facility 811 into the reactor main body 1 of the conventional nuclear power plant includes the above- The thermal power generation apparatus of the nuclear power plant includes a steam turbine 267 which generates steam by burning fuel in the boiler so as to produce steam by the heat to rotate the steam turbine 267 to produce power, A rotating rotor electromagnet coil 774 for the thermal power generator installed along the circumference of the rotating shaft 198 connecting the steam turbine 267 and the thermal power generator 772, A non-rotating armature coil 773 for a thermal power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for the thermal power generator, and a non-rotating armature coil 773 mounted on the steam turbine 267, It is formed to be made to develop seolbibu 811 when after any reactor plant safety operation i and reactor equipment failure recovery before and after the thermal power during which includes a frame 775 for fixing the rotary shaft 198 integrally.

Referring to FIG. 2A, a conventional high-speed breeder reactor facility 838 of the nuclear power plant 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (838) Elementary fast breeder reactors facility (838) showing disassembled side view of nuclear operation of nuclear power plants Nuclear reactor construction (838) Disassembled lateral strainer configuration Road ,

As shown in FIG. 2A, the fast propagating furnace reactor facility 838 generates uranium 238 (653a), which is a non-fissile material that generates energy by generating a fission reaction using a high-speed neutron and occupies 99% ) Is converted to a fissile material, uranium 239 (653), and at the same time, the liquid fuel metal 838 is used as a coolant 816 because it is a high-speed propagation furnace facility 838. However, 812), the speed of the neutron 675 is high in the reactor plant 838 of the fast breeder reactor, while the speed of the neutron generator 675 is low.

Referring to FIG. 2B, in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, a nuclear power plant 811, A nuclear waste disposal system is provided to provide a nuclear waste disposal system to restore the nuclear power plant. A nuclear waste disposal system is used to operate a nuclear power plant. A nuclear waste disposal system A side view of the apparatus, a nuclear waste disposal apparatus for operation of nuclear power plants of a conventional nuclear power plant,

As shown in FIG. 2B, in the conventional method of treating nuclear waste generated from a nuclear power plant for nuclear power plant nuclear power plant operation of a nuclear power plant, ventilation inside the building and air contained in water inside the reactor In the case of a gas, purified air is exhausted to the outside by an activated film type gas hold-up device 213 which weakens the radioactivity when the pressurized water reactor system is operated. However, ventilation of the power plant is performed by a plurality of symmetrical filters 214 And discharges all of the ventilated air from the exhaust tower 215 to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

In addition, when the inside of the nuclear power plant is solid and the paper, cloth, work clothes, shoes, and so on are solid in the inside of the nuclear power plant 672, the filter sludge and the used resin liquid are stored in the storage tank 216, and then filled in the drum 220. The paper and the cloth are compressed to reduce the volume and attenuate them. All of them are filled with concrete into the drum 220, and the nuclear waste 224 to move the nuclear waste storage building 332 and monitoring monitoring post 219 to a nuclear waste disposal facility, To prevent radioactive contamination.

When the regenerated liquid of the ion exchange resin is liquid in the water leaking from the valve of the nuclear power plant 672 and the water in the building into the nuclear power plant 672, the washing water is collected in the storage tank 216 and filtered with the filter 217 After measuring the radiation level by the radioactivity measuring device 218, it is confirmed that there is no harm, and then it is sent to the sea together with the seawater for cooling. The water other than the washing water is purified by the filter 217, and the filtered water, distilled water, And is provided with monitoring posts 219 for monitoring at the same time to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2C, in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a nuclear power plant 811, Nuclear power plants operating nuclear reactors providing nuclear waste disposal facilities to provide for post-war reconstruction Deep safety Nuclear power plant 5 Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant , Nuclear power plant operation of elemental conventional nuclear power plant shown in cross section in-depth safety Fifth barrier side lateral diagonal construction road,

     As shown in FIG. 2C, the control rod 798 is inserted into the fuel assembly 671 from the pressure vessel 813 in the fifth-level safety barrier for operating the nuclear power plant of the conventional nuclear power plant, At the same time, the fuel assemblies 671 are adjusted to the height of the fuel assemblies 671 at the height of the nuclear reactor facility, and at the same time, the fuel assemblies 671 are used to stabilize the pellets 683 The nuclear fuel pellet 683 is enclosed in the covering material 681 as the second barrier wall and is put into the metal tube of the special alloy as the fuel rod 689 as the fuel rod 689. [ At the same time, in the reactor pressure vessel 813, which is the third barrier wall, a small amount of gas discharged from the nuclear fuel assembly 671 provides a seal to the second barrier wall, Is a facility pressure vessel 813.

     In the shielded concrete wall as the fourth barrier wall, the radioactive material is prevented from leaking as a concrete wall surrounding the nuclear reactor facility. In the containment vessel 808 as the fifth barrier wall, a safety system and a system At the same time, the facilities of the biological shielding wall, which is the 5-1 barrier wall, are provided with a final biological shielding wall as a thick building of 70 to 100 cm outside the steel, , And at the same time a containment vessel (808) and a dome-shaped, secure nuclear building that provides protection against leakage of radioactive material, while at the same time providing emergency shutdown of radioactive material in the event of an accident.

However, since the conventional nuclear reactor power plant is constructed so that the deep-safety nuclear reactor facility can not cope with a stronger earthquake than 5, it is urgently necessary to take measures against it.

Referring to FIG. 2d, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, Nuclear Power Plant Operation Having the Evaporator Structure 1005 of the Steam Generator, the Steam Generator 810, and the Intermediate Heat Exchanger 657 During the operation of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment, The steam generator 810 and the intermediate heat exchanger 657 are separated from each other in a side view in section, and the steam generator 810 and the intermediate heat exchanger 657 of the steam generator are connected to each other. The evaporator structure 1005 of the generator, the steam generator 810 and the intermediate heat exchanger 657,

As shown in FIG. 2D, the facility structure of the nuclear reactor nuclear power plant 811 of the nuclear power plant, the vapor generator structure 1005 of the steam generator, the steam generator 810, and the intermediate heat exchanger 657 is first subjected to intermediate heat exchange The apparatus 657 includes a secondary cooling system outlet 657a, a low temperature head 657b, a secondary cooling material inlet 657c, a support plate 657d, a central pipe 657e, an outer annular portion 657f, And the heat insulating material 657h and the high temperature head 657i and the mixer 657j and the primary system gas inlet 657k and the primary system gas outlet 657l and the single pipe 657m pressure vessel 657n, 657o, 657p, 657p, 657r, 657r, 657s, 657t, 657u, 657v, and 657w, respectively, The steam generator 810 is provided with a steam outlet 810a and a water supply nozzle 810b and a secondary cooling water 810c and a vibration suppression rod 810d ) customs A tubular shell 810f and a tubular shell 810g and a tubular steel plate 810h and a separating steel plate 810i and a primary outlet 810j and a primary inlet 810k and a heat exchange tubular 8101, And the steam generator internal tubular body 810o and the evaporator structure 1005 of the steam generator are provided with the steam outlet pipe 1006 and the steam outlet body external appearance A connection pipe 1013 and a cooling water leakage detecting pipe 1014 and a hygrometer pipe 1008, a steam outlet pipe 1009, a liquid level pipe 1010, a sodium cooling water inlet pipe 1011, an upper plate 1012, A secondary argon gas pipe 1015, a skirt 1016, a spiral heat exchanger tube 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a water drain pipe 1020 and a cover 1021, Water reaction product discharge pipe 1024 and an inner pipe 1025 and a monitoring inlet pipe 1026 and a water inlet pipe plate 1027 and a water inlet pipe 1010, 28) and a water supply inlet chamber (1028a) connection structure to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2E, the boiling water reactor unit 802 of the nuclear power plant 811 and the pressurized water reactor 802 of the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, Type nuclear reactor (803) Nuclear power generation facility (811) is installed inside a nuclear reactor main body (1) of a conventional nuclear power plant shown in a cross section of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operation of a nuclear power plant ) Of the boiler water reactor (802) and the pressurized water reactor (803) of the nuclear power plant,

     As shown in FIG. 2E, the operation of the boiling water nuclear reactor 802 is a boiling water reactor (BWR) type in which water vapor of water boiling in the core is directly sent to a power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats hid their details without disclosing details, refused to provide US technical support, and at the same time, they poured seawater into a wreckage, drove a fire engine and used a helicopter to put it into the building, In the reactor (PWR, 803) facility, there is provided a primary system transfer that circulates between the fuel and the heat exchanger 658, and at the same time, a heat system, called the hot system steam generator 810 of the primary system, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser The turbine 267 of the secondary system is connected to the turbine generator 772 to generate electric power at the same time. (PWR, 803) facilities are compared with two pressurized water reactors and other reactors. In the pressurized water reactor, there are two cooling water 1 In the boiling water reactor (BWR), the turbine (267) of the secondary system and the secondary system provides electric power production in connection with the turbine generator (772), while at the same time water none.

In the pressurized water reactor type nuclear reactor (803) nuclear power plant, in the pressurized water reactor type nuclear reactor facility (803), the hard water of the coolant is designed for the primary use in the PWR, , And 315 degrees Celsius. At the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light pressure (654a) at a pressure of 150 times the pressure does not boil. At the same time, The water is steamed at a temperature of 275 degrees Celsius and a pressure of 900 psig and a pressure of about 6.2 MPa, and is sent to the steam turbine 267.

     The stability of such a pressurized water reactor type reactor (803) is such that a pressurized water reactor is provided with a very stable production. However, when the graphite deceleration boiling water pressure tubular reactor (RBMK) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, the heat and sintering of the phenomenon to be used are provided, and at the same time, the production of ceramic pellets made of uranium dioxide is provided, and the pellets made of such a cylinder are made into a zirconium alloy Zirconia), and helium is injected into the zirconia bar to help heat transfer, but the finished fuel rod is bundled with bundles of fuel assemblies, which are called bundle bundles of fuel, which are loaded into the reactor core do.

Referring to FIG. 2F, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant (1) (1) of a conventional nuclear power plant showing the operation method of a nuclear power plant of a conventional nuclear power plant, showing the configuration of the nuclear power plant of the nuclear power plant (811)

As shown in FIG. 2F, the nuclear plant power plant of the nuclear power plant 811 includes a safety valve 472, a for-spiff safety valve 475 for steam, an air vent valve 481, The reactor pressure vessel 813 is connected to the pressure vessel container 813a and the pressure vessel 813a by the air air exhaust valve 482 and the nichrome wire 659 and the steam generator 810, A pressure vessel cylindrical top end portion 813d and a pressure vessel cylindrical top end portion 813e, an inlet nozzle 813f and a deflector steel plate 813h, which form a position in the top cover lower portion 813b and the pressure vessel cylindrical cover 813c, A pressure vessel cylindrical top cover for providing a position in the air chamber chamber 813i, the baffle plate 813j, the water 813k, the spray pool 8131, the vent five 813m and the fuel assembly 813n, (813p) is provided with a dry wall (813q), a pressure vessel cylindrical cover bottom assembly (813s) and a pressure vessel cylindrical cover top And a connection structure of the control rod guide tube assembly 813z of the reactor core assembly 813y and the outlet nozzle 813w and the core assembly 813y of the nuclear fuel assembly 811t, the fuel rod steel plate 813v, It is structured to prevent nuclear radiation pollution both inside and outside of the operation equipment.

      Referring to FIG. 2G, the nuclear power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention includes the nuclear power generation facility 811 intermediate heat exchanger 657, The structure of a nuclear power plant having a structure 1005 and a steam generator 810 is shown in a schematic view of an elemental conventional nuclear power plant operating at the nuclear power plant 811 and an intermediate heat exchanger 657 and a steam generator The structure of the evaporator 1005 and the steam generator 810 are shown in side elevation and in cross section in the nuclear reactor of the conventional nuclear power plant and the evaporator structure of the steam generator in the nuclear power plant 811 intermediate heat exchanger 657 1005) and the steam generator (810)

As shown in FIG. 2G, the inside of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the nuclear power generation facility 811 intermediate heat exchanger 657 and the vapor generator structure of the steam generator 1005 and the steam generator 810, the structure of the intermediate heat exchanger 657 includes a secondary cooling system outlet 657a, a low temperature head 657b and a secondary cooling system inlet 657c and a support 657d and a central piping 657e and an outer annular portion 657f and a pressure vessel 657g and a heat insulating material 657h and a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k ), A primary system gas outlet (657l), a single pipe (657m), an internal pressure pipe (657n), a heat insulating layer (657o), a high temperature gas passage (657p), a liner (657q), a double pipe (657r) A gas pipe 657t and an inner pipe 657u and a hot gas passage 657v and a liner 657w and a heat insulating layer 657x. A tubular lid 810a connected to the turbine generator, a water supply nozzle 810b, a secondary cooling water 810c and a vibration damping rod 810d, a tubular supporting pipe 810e, a tubular lid 810f, a tubule bundle 810g, And the steam generator 810n and the steam generator internal fuselage 810i and the steam generator internal pipe 810i and the steam generator internal pipe 810i, the primary pipe outlet 810j, the primary pipe inlet 810k, the heat exchange pipe 8101, the cooling water passage 810m, The steam outlet pipe 1006 and the steam outlet body 1007 are connected to the hygrometer pipe 1008 and the steam outlet pipe 1009 and the liquid level sensor A cooling water leakage detection pipe 1014, a secondary argon gas pipe 1015, a skirt 1016, and a spiral heat exchange tubular pipe 1010, a sodium cooling system inlet pipe 1011, an upper flat plate 1012, a connecting rod 1013, 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a drain water pipe 1020, a cover body 1021, a body outer pipe 1022, a sodium channel 1023, and a sodium- A water inlet pipe plate 1027, a water inlet pipe 1028, and a water inlet chamber external pipe 1028a connecting structures to the inside of the nuclear power plant 1024, the inner pipe 1025, the monitoring inlet pipe 1026, the water inlet pipe plate 1027, (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste of a nuclear power plant, and a nuclear power plant (811) intermediate heat exchanger (657) and an evaporator of a steam generator The construction of the structure 1005 and the steam generator 810 can be configured to prevent nuclear radiation pollution both inside and outside the nuclear power plant operating the nuclear power plant.

Referring to FIG. 2H, a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant The nuclear power plant of the conventional nuclear power plant showing the configuration of the embodiment of the nuclear power plant in operation of the nuclear power plant, the nuclear power plant of the conventional nuclear power plant showing the side view of the steam generator 810 of the nuclear power generation facility 811, (811) Steam Generator (810) Side Construction Road,

The steam generator 810 of the nuclear power plant 811 includes a steam outlet 810a connected to the turbine generator and a steam generator 810a connected to the turbine generator 810, The tubular lid 810f, the tubular bundle 810g, the tubular steel plate 810h and the separated steel plate 810i, the water supply nozzle 810b, the secondary cooling water 810c, the vibration suppression bar 810d, A primary side inlet 810k, a heat exchange tubular 810l, a cooling water flow channel 810m, a steam generator tubular tube 810n and a steam generator internal body 810o, The safety valve 474 and the intermediate heat exchanger 657 are structured such that the secondary cooling system outlet 657a, the low temperature head 657b, the secondary cooling material inlet 657c, the support plate 657d and the central pipe 657e, A heat exchanger 657h, a heat insulating material 657h, a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k and a primary system gas outlet 657l, (657m), a pressure insulation pipe (657n), a heat insulation layer (657o), a high temperature gas pipe (657p), a liner (657q), a double pipe (657r), a pressure pipe (657s), a low temperature gas pipe (657t) (657v), a liner (657w), a heat insulating layer (657x), and a reheater (793), and at the same time, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste 1) Nuclear power plant (811) inside Nuclear power plant (811) Nuclear power plant with intermediate heat exchanger (657) and connecting structure of steam generator evaporator structure (1005) and steam generator (810) As shown in FIG.

Referring to FIG. 2I, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention (1) Nuclear waste treatment is performed inside the production power central control room (781) Operation of a Nuclear Power Plant Having a Cutter and a Robot 912 by Remote Control of the Apparatus In an elemental conventional nuclear power plant showing the construction of a nuclear power plant during operation of the nuclear power plant, (912) of the nuclear waste disposal apparatus remote control nuclear power plant nuclear waste disposal method of the nuclear power plant nuclear waste disposal method of the elemental conventional nuclear power plant operating nuclear power plant nuclear power generation facility 811) Production power Central control room (781) Inside Nuclear waste processing device Remote control Cutting machine and robot (912) Nuclear power plant Nuclear waste disposal side In addition,

As shown in FIG. 2 (i), the piping line of the nuclear reactor facility is connected to the safety valve 472 in preparation for a period of three months or longer for the repair work of the inside of the reactor facility of the nuclear power plant 672, The boiler 783 of the thermal power plant is operated at the same time, and the connection structure is formed in the reactor power generation facility 811 to supply the steam of high temperature and high pressure and further emergency power generation operation is performed. In order to secure the safety of the nuclear power plant by safe and continuous operation of the nuclear power plant inside the nuclear power plant by replacing the electric power supply with the thermal power generation facility during the work period and to prevent the radioactive contamination during the renovation of the reactor facility, At the same time, during the operation of nuclear power plants, the production power central control room 78 of the nuclear power generation facility 811 1) Nuclear power plant nuclear power plant equipped with cutter and robot (912) device by remote control of nuclear waste treatment device inside It is provided with nuclear waste disposal method to guarantee the repair of nuclear reactor.

Referring to FIG. 2J, there is shown a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The reactor core 1 includes a nuclear power plant 1071 having a nuclear fuel industry cycle 1077 of the nuclear power generation facility 811, The nuclear fuel cycle of the nuclear power plant 811 in the operation of the nuclear power plant of the conventional nuclear power plant showing the configuration of the nuclear power plant of the power plant is shown in a side view and a cross-sectional view Nuclear Power Plant (811) Nuclear Fuel Industry Cycle (1077) Nuclear Fuel Transfer Process and Revision of Revision Scene Disassembly of the Scene Scenery Construction of roads,

As shown in FIG. 2J, the nuclear fuel cycle 1077 of the nuclear power plant 811 is transferred into the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment The spent nuclear fuel 683 consumed in the nuclear power plant 672 and the remaining uranium 812 are processed in the reprocessing plant 228 and then converted into uranium fluoride 812 in the conversion plant 229 to be concentrated in the concentrating plant 230 to convert the uranium fluoride 812 to uranium dioxide at the conversion plant 229 and process it into pellets 683 to form the fuel rods 689 and process them in the reprocessing plant Plutonium 801 is produced at the conversion and processing plant 231 and fuel rods 689 are produced so that these reprocessed fuel rods 689 are moved back to the nuclear power plant 672 and the fuel 683 is transferred to the nuclear power plant 672 The concentrating plant 230 in the reprocessing plant 228, The conversion plant 229 and the conversion processing plant 231 prepare nuclear waste 224 as a nuclear fuel cycle of the nuclear fuel industry on the top surface of the sinking prevention type barge deck 40 m above the sea surface of the ocean, 672) The nuclear fuel cycle of the Edo nuclear fuel industry is constructed so as to prevent nuclear radiation contamination both inside and outside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment.

In addition, the long half-life nuclear waste 224 generated from the reprocessing process at the nuclear power plant 672 inside the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste has a half- Heavy construction equipment heavy equipment hire (877) and excavators (845), which provide shelter for thousands of years because of their long shelf life, while at the same time providing for the permanent disposal of long-term waste, Comprising the steps of constructing the waste to be treated with a device of a permanent disposal method of a long-term nuclear waste,

The nuclear waste treatment includes the steps of fissioning in the nuclear reactor facility to construct a conversion into another material,

The nuclear waste disposal includes the step of constructing a deep burial site by having a construction machinery heavy equipment hoeing 877 and an excavator 845 in a stratum or ocean,

The nuclear waste disposal includes the steps of constructing a double tubular drum (220) having a sinking prevention vessel and containing nuclear waste to be transported to a buried area,

In the nuclear waste disposal, a dual tubular drum 220 containing nuclear waste is mounted on the space rocket 612 at the position of the upper end of the barge deck deck 591 provided with the space rocket 612 and the space rocket launching rods 646 (224) containing nuclear waste (224) comprising steps constituting transmission to the outer space of a nuclear power plant having a dual structure block tank dust collector for the treatment of nuclear waste (1) To make the treatment of the nuclear waste with the devices of the permanent disposal method of the nuclear waste.

Referring to Figure 2K, there is shown a structural and engine side view of an elemental configuration of an embodiment of a nuclear power station of a TVA Paradise Power Plant Steam Turbine Generator in the vicinity of the prior art Paradise in Kentucky, Generator and engine side Elementary strap configuration Road,

As shown in FIG. 2K, the following is a detailed description of the energy conversion of the translation of the contents of the American Science Series of the energy and power of the modern science in the late 1960's.

TVA's Paradise Power Plant Steam Turbine Generator in the vicinity of Paradise, Kentucky, has a capacity of 1,150 MW. When it first started operation in February 1970, it was the largest power plant in the world. The turbine, which is produced by General Electric Company, first enters the high-pressure turbine under the right-angled pipe on the left, and flows through the rectangular pipe in turn to the intermediate-pressure turbine (the rear lid) and the low-pressure turbine (the front lid). The high pressure turbine is connected to one generator (gray box on the left) and the other two turbines are connected to a second generator (front box) with the same capacity. The entire plant is run by 3.6 million kg of water vapor per hour, which enters the high pressure turbine at a pressure of 1,650 kg per square inch and 427 ° C. The coal consumption per day is 10,572 tons, enough to fill 210 coal cargoes. The net heat efficiency of this facility is 39.3%. Two small turbine generators, each with 704 MW, are visible at the rear.

<Efficiency of household stoves, steam turbines, automobile engines and bulbs helps to determine energy demand. What is primarily needed is a kind of energy source that does not increase the earth's heat load.>

Modern industrial societies can be seen as a complex machine that emits the energy necessary to create numerous goods and services, while at the same time, the high quality energy is reduced to waste heat. Last year, the United States achieved a gross national product of just over $ 1,000 trillion using 69 × 10 ¹⁵ Btu, of which fossil fuels accounted for 95.9 percent of the energy, 3.8 percent of water falls, and 0.3 percent of the U ²³⁵ split Respectively. The consumption of 340 million Btu per person is equivalent to the energy contained in about 13 tons of coal, or 2,700 grams of gasoline if followed recently by the most frequently used method. It can be estimated that in 1900-70, the efficiency of the spent fuel for all purposes was improved by a factor of four. Without this efficiency improvement, the US economy in 1971 would already be consuming as much energy as it would have expected in 2025 or at that time.

GNP could be increased at an annual rate of 3.25% while fuel consumption increased only 2.7% per year in 1890-1960, as the efficiency of converting energy into useful heat, light, and work continued to improve. However, it seems that this favorable phenomenon is no longer persistent. Since 1967, the annual increase in fuel consumption has been faster than GNP growth, making fuel economy more difficult to improve and new products and services requiring more energy input and costs than in the past. Given the expected increase in fuel use for power generation, it is clear that a significant portion of the fuel to be consumed in the 1980s and 1990s will be transformed into a useful form with a lower efficiency than today's fossil fuels. This is because current nuclear power plants convert only about 30% of the fuel's energy into electricity, compared to about 40% efficiency of the most efficient fossil fuel power plants.

It is understandable that engineers try to improve the efficiency of converting the energy of a fuel into another more useful form. Improving efficiency in industry means reduction of production cost, lowering price for consumers, and reducing pollution of air and water quality to all people. Electric utilities have long known that it can stimulate consumption by lowering the price of energy for many users. The recent campaign by the utility, <1W Save>, represents a significant reversal of corporate philosophy. The difficulty of selecting a suitable new power plant site not only indicates the need for efficiency of consumption, but also the saving of consumption. In addition, we can not but emphasize that even with this much improvement in efficiency, we can expect only a slight effect in extending the life of fossil fuels and fuel supplies. I would like to elaborate on this point from the back of this article.

<Figure 8-1> The transformation path connects many familiar forms of energy. The four black markings are important energy sources of today, and potentially important energy sources for solar energy. The dashed lines represent unusual, accidental, or theoretically useful transformations. The white line represents the fate of intermediate form energy. Most of the energy is converted into mechanical energy, except for the thermal energy used for heating. Mechanical energy is used for direct traffic (see Figure 8-2) or used for power generation. And electrical energy is used for lighting, heating and mechanical work. As a secondary form, chemical energy can be found in batteries and chargers. Most of the radiant energy produced by the bulb is lost as heat.>

Figure 8-2 shows the path to the final destination for the three major energy sources. The most direct and most efficient conversion is from falling water to mechanical energy, which is then converted back to electrical energy. Energy trapped in fossil fuels and nuclear fuel is first released in the form of heat energy, then converted to mechanical energy, and then converted to electrical energy if desired. Losses in conversion and transmission include the use of various non-energy sources of fossil fuels, such as the use of fossil fuels for the production of lubricants or the conversion of coal to coke. However, the greatest loss is due to power generation with an average efficiency of 32.5%.

The efficiency of converting the energy contained in a fuel into a useful form varies depending on the conversion method and the desired end use. When burning wood or coal in an open fireplace, less than 20% of that energy is emitted into the room. All the rest are lost to the chimney. On the other hand, a well designed home stove can capture 75% of the energy of the fuel and use it for heating. The average efficiency of fossil fuel conversion for heating is now 50-55%, which is three times higher than that of today. In 1900, more than half of all the fuel consumed in the United States was spent on heating, but today less than one third of it is spent on it.

Sadi Carnot, 1796-1832)는 1824년 증기터빈이나 다른 열기관의 이론적 최대효율을 계산하는 방법을 발표하였다. 가능한 최대효율은 (T ₁-T ₂)/T ₁로써 표현되는데 여기서 T ₁은 열기관으로 들어가는 작용액체의 절대온도이며, T ₂는 기관 밖으로 나오는 액체의 온도이다. 이들의 온도는 보통 켈빈 도수(degrees Kelvin)로 표현되는데, 이 온도는 섭씨온도에 절대냉도와 섭씨 0°와의 차이인 273을 더한 것이다. 현대의 증기터빈에서 T ₁은 전형적인 811°K(=573.7℃)이며 T ₂는 311°K(=37.8℃)이다. 따라서 (까르노)의 식에 의하면 이 열기관의 이론적 최고효율은 약 60％이다. 그러나 수증기의 순환 자체가 가진 성질로 인하여 항상 이러한 상한 온도로 유지할 수 없기 때문에 이론적 최고효율은 60％가 아니라 53％일 가능성이 더 크다. 현대의 증기터빈은 이 값의 약 89％, 즉 순 47％ 정도를 달성하고 있다.The most significant improvement in fuel conversion efficiency for this century was achieved by the power generation business. In 1900, less than 5% of the fuel's energy had been converted to electricity. Today, the average efficiency is around 33%. This increase was mainly due to the increase in the temperature of the steam entering the turbine that drives the generator and the construction of larger-scale power plants. In 1910, the typical incident water vapor temperature was 260 ° C, but today the facility uses steam heated at a high temperature of 574 ° C (Nicolas Carnot; Nicolas

Sadi Carnot, 1796-1832) published a method to calculate the theoretical maximum efficiency of a steam turbine or other heat engine in 1824. The maximum possible efficiency is expressed as ( T ₁ - T ₂ ) / T ₁ where T ₁ is the absolute temperature of the working liquid entering the heat engine and T ₂ is the temperature of the liquid exiting the engine. Their temperature is usually expressed in degrees Kelvin, which is the difference between absolute cold and 0 ° C, plus 273 degrees Celsius. In modern steam turbines, T ₁ is typically 811 ° K (= 573.7 ° C) and T ₂ is 311 ° K (= 37.8 ° C). Therefore, according to (Carnot) equation, the theoretical maximum efficiency of the heat pump is about 60%. However, due to the nature of the water vapor circulation itself, it is not always possible to maintain this upper limit temperature, so the theoretical maximum efficiency is more likely to be 53% than 60%. Modern steam turbines achieve about 89% of this value, or about 47%.

To determine the overall efficiency of a steam turbine plant, this value should be multiplied by the efficiency of the other energy converters in the chain from fuel to power. Modern boilers convert about 88% of the chemical energy of the fuel into heat. The generator can convert up to 99% of the mechanical energy produced by the steam turbine into electricity. Thus, this overall efficiency is 88 × 47 (efficiency of the turbine) × 99, ie about 41%.

(See also Lord Kelvin, William Thomson, 1824-1907)

[Figure 8-3] Energy converter efficiency is from less than 5% of normal incandescent lamps to 99% of large generators. The efficiency shown here is an alternative maximum value that can be reached with current technology. A figure of 47% of the kit with liquid fuel was calculated for the liquefied hydrogen engine used in the Salton lunar spacecraft. The efficiency of fluorescent lamps and incandescent lamps is not a theoretical value of 220 lumens per V of fully flat white light, but is assumed to be about 400 lumens per W for the maximum efficiency that white light that can be tolerated can reach.

Nuclear power plants are less efficient because their current reactors can not be as hot as boilers burning fossil fuels. The temperature produced by the water boiling reactor is around 350 ° C, which means that T ₁ is 623 ° K in the Karno equation. In a complete cycle from fuel to power, the efficiency of a nuclear power plant is reduced to about 30%. This means that about 70% of the energy of the fuel used by the nuclear power plant is waste heat, which is discharged to the surrounding atmosphere when using adjacent water bodies or cooling towers. In fossil fuel power plants, this waste of heat amounts to about 60% of the energy of the fuel.

However, the actual waste heat load on water or air is much higher than the figure of 60% or 70%. For power plants with the same kilowatt output, nuclear power plants generate about 50% more waste heat than fossil fuel power plants. The reason is that a nuclear power plant must burn about one-third more fuel than a fossil fuel plant to produce 1 kW / h of power, and many more B.t.u. And 70% of the input is wasted.

Of course, there is no thermodynamic rule that heat emitted by nuclear power plants or fossil fuel power plants must be wasted. The problem is to find useful things that can be done by this much amount of low energy. Many applications have been proposed, but all of them are facing economic constraints. For example, low pressure water vapor emitted from a steam turbine can be used for heating. In some communities, especially in New York City, New York (Consolidated Edison, Inc.) supplies a lot of water vapor. Many chemical plants and refineries use low-pressure steam from turbines as water vapor for the treatment process.

[Figure 8-4] Three of the fastest growing energy consumption appliances are electrical appliances, automobiles, and aircraft. These three now consume about 40% of all energy consumed in the United States. By 1940, they were much smaller than now, accounting for 18% of total energy consumption. Fuel demand for aircraft has more than tripled in ten years.

There was also a suggestion that heated water released from the power plant would help promote fish and shellfish growth in some areas. But nationwide, waste heat from current fossil fuel power plants or waste heat from dozens of new nuclear power plants in the near future seems to have no attractive use. The problem is to limit the harmful effects of this waste heat on the environment.

In the discussion above, it can be seen that the use of electric power for home heating (which is still actively recommended by some electric companies) is an inefficient use of chemical fuels. Domestic luxury oil stoves and gas stoves typically exhibit at least twice the efficiency of power plants. In some regions, however, despite the low efficiency at the annual price of electric heating, it is likely to compete with direct heating by fossil fuels. In such anomalous cases, various factors are involved. The higher the temperature, the lower the consumption. Electric heating is usually installed in a new building with good thermal insulation. In some areas, finding natural gas is a bit difficult and expensive. The supply of oil is not always reliable. As chemical fuels become more prevalent, their value will be higher and nuclear power generation will increase. Unfortunately, despite the inefficient use of fuel, we can not help but expect that more of our fuel resources, especially nuclear fuel, will be used for power heating.

[Figure 8-5] The efficiency of fossil fuel power plants in the United States has improved nearly 10 times from 3.6% in 1900 to 32.5% in 1970. This improvement was made possible by increasing the operating temperature of the steam turbine and increasing the size of the power plant.

The most widespread of all prime movers is the piston engine. Many American household garages have two piston engines, even if they do not include power mowers, snow throwers, chain saws, and the like. The output of piston engines in more than 100 million cars in the United States is estimated to be more than 17 billion horsepower, or more than 95% of all prime movers (defined as engines that convert fuel into mechanical energy). Although this massive output is not used most of the time, it accounts for more than 16% of the fossil fuel consumed in the United States. All forms of transportation - consuming a million tons of coal from ships, accounting for 16% of the total energy demand in the country. According to estimates by the energy consultant John Hume, the railroad delivered 54% more traffic (measured as an index of transport performance) as 1/6 of B.t.u. than in 1920. This increase in efficiency has reduced the share of the nation's total energy budget from 16% to about 1%, with the role of the railway in the national economy declining. But the curves for total energy consumption in 1920-67 show little or no impact of this tremendous change.

<Figure 8 - 8> The efficiency of the lamp depends on the quality of the light which each thinks is good. For perfectly flat white light, the theoretical efficiency is 220 lumens per Watt. You can get up to about 400 lumens per W by slightly boosting the light in the middle of the spectrum. Current fluorescent lamps can be 36% efficiency or 20% efficiency.>

An important use for the least efficient use of power is probably to supply light. (General Electric Company) estimates that lighting consumes about 24% of total electricity generation, or 6% of total national energy budget. It is well known that filaments of ordinary 100W incandescent lamps produce much more heat than light. Actually, it appears as infrared rays of 95% or more of power input, and only 5% or less is emitted as visible light. Nevertheless, this is more than five times the light emitted by a 100W bulb in 1900. Modern fluorescent lamps convert about 20% of the power consumption to light.

[Figure 8 - 9] Power generators currently in use utilize energy from falling water, fossil fuels or nuclear fuel. A hydro turbine generator (1) converts the potential kinetic energy into electricity. In a fossil fuel steam turbine generator (2), the boiler produces water vapor, which circulates the turbine, which turns the generator. At the nuclear power plant (3), a split of U ²³⁵ releases energy and creates water vapor, which is then passed through the circuit as in a fossil fuel power plant. In the currently undergoing nuclear proliferation furnace (4), surplus neutrons are captured by a coating of U ²³⁸ or Th ²³² atoms that can not divide and converted to Pu ²³⁹ or U ²³⁸ , which these atoms can divide. The heat of this reactor is carried by liquid sodium.>

This value is not a complete white light, but is based on a practical upper limit of 400 lumens per watt, assuming acceptable white light. The maximum theoretical output is reduced to 220 lumens per watt if the spectrum is limited to fully flat white light. Theoretically, you can reach 680 lumens per watt if you can be satisfied with the light of the shortest wavelength (550 nm), which is most sensitive to human eyes.

General Electric currently owns about 70 percent of the nation's total lighting, while the remaining incandescent light bulbs and high-end electric propulsion systems, locomotives and aircraft - consume about 25 percent of the nation's energy budget.

[Figure 8-6] The efficiency of a locomotive can be expressed as the amount of energy required to represent the unit <transport performance> in the US railway. The dramatic improvement in the 1950s reflects the fact that steam locomotives were almost completely replaced by diesel locomotives.

Automotive engineers estimate that the average efficiency of automotive engines has improved by roughly 10% over the past 50 years, from 22% to 25%. But the distance that you can run with 1gal of fuel is actually smaller. From 1920 until World War II, passenger cars typically traveled about 21.6 kilometers per gram of fuel. Over the last 25 years this average has been gradually shortened to about 20.5 km per gallon. This decline is due to the fact that the car is heavier, has a much faster engine speed, and has a powerful engine. It takes about eight times more energy to run a vehicle at 96 kilometers per hour than at 48 kilometers per hour. An amount of energy equal to the energy needed to accelerate the car's weight to 96 km / h should be absorbed by the brakes, mainly as heat, when the vehicle is stopped. Thus, much of the engine efficiency improvement is lost due to the way humans use the machine. Air conditioning of passenger cars also caused a decrease in the number of kilometers per gallon. This number of kilometers will soon improve as consumers change their preference for compact cars. However, the efficiency of the basic piston engine can no longer be greatly improved.

[Figure 8-7] The efficiency of an automobile engine is not perfect due to its weight and speed increase, but it is reflected in the number of miles per gram of fuel. Car makers say that the engine's thermal efficiency in the 1920s was about 22 percent. Today this is about 25%.

Even if all the cars in 2000 were powered by a charger charged with power from a central powerhouse, there would be no change in the overall fuel demand in the United States. The initial conversion efficiency at the power plant would be 35% compared to 25% of the piston engine, but it would be lost to convert the power into electrical energy (within the charger) and convert it back to power to drive the wheels Because. Current chargers have little room to improve their overall efficiency from 70% to 75%. Anyone who believes that all passenger cars are beneficial to power operation by everyone should consider the problem of increasing national power generation by about 75% as a necessary measure to run 100 million vehicles.

It is difficult to trace the savings made by the difference in efficiency of energy conversion, even if the difference is large, after the rail has been converted from a steam locomotive (10% maximum thermal efficiency) to a diesel locomotive (35% thermal efficiency) I can see that this happened. In 1920, the railroad is estimated to be about 135 million yuan. The efficiency of such a challenge is comparable to that of fluorescent lamps, and sometimes it is more efficient. This distribution means that the average efficiency of converting power to light is about 13%. To calculate the overall efficiency of converting chemical (or nuclear) energy into visible light, this percentage should be multiplied by the average efficiency of the power generation (33%), so the net conversion efficiency is typically 4%. Nevertheless, due to the increase in use of fluorescent lamps and famous lamps, the consumption of lighting in the country during the 1960s and 1970s was only doubled, and the consumption of lighting could triple.

[Fig. 8 - 10] The propulsion machine converts the energy of the liquid fuel into mechanical energy or kinetic energy, which is used for work and traffic. In the piston engine 5, the compressed fuel and air are exploded by electric ignition. The inflated gas pushes the piston, which is transmitted to the crankshaft. In the diesel engine 6, compression alone is sufficient to ignite the mixture of fuel and air. In the airplane gas turbine (7), the hot gases from the combustion chamber continue to expand and rotate the multi-stage air compressor as it flows through the turbine. The hot gases from the turbine provide kinetic energy for propulsion. The liquid fuel rou- tine 8 has an oxidant in addition to the fuel and does not depend on the air supply. Locate exhaust provides kinetic energy>

<Figure 8-11> New energy converters are being designed to use various energy sources. The fuel cell 9 converts the energy of the hydrogen or liquid fuel directly into electricity. This combustion of the fuel takes place in the porous electrode. In the recently proposed solar power plant 10, the sunlight reaches the specially coated light receiving plate, raising the temperature of the liquid metal to 500 캜. The heat thus collected is transferred to water vapor by a heat exchanger, which rotates the turbine generator as in a conventional power plant. It stores enough heat in the salt heat reservoir so that it can continue to generate water vapor even when the sun is covered by night or clouds. The NHD <turbine> (11) converts the energy of the hot, electrically conductive gas into direct power. In order to improve the electrical conduction of this hot gas, a small amount of <seed> substance such as potassium carbonate should be injected into the flame. Electricity is generated when the charged particles of this gas pass through a magnetic field by external magnetic force. The long-term goal is a thermonuclear reactor (12) where the atom of a light element fuses into a heavy element and releases energy. It is possible to capture high-speed charged particles produced by thermal nuclear reactions to produce power directly.

By simply looking at changes in ideal energy conversion efficiency, you will have some insight into the expected effects of a new energy conversion system under development. Two devices that have received much attention are fuel cells and MHD (magnetohydrodynamic) generators. Fuel cells convert chemical energy directly into electricity and the latter has the potential to be used as a high-temperature topping device that works with steam turbines and generators in power generation. A fuel cell has been developed which can <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> combustion < The output of the hydrogen-oxygen fuel cell produced by the Pratt & Whitney division of United Aircraft, used in the Apollo space program, was 20.5 V DC, 2.3 kW.

MHD generators have been developed as energy converters for the future for 10 years. In this machine, the fuel is burned at a high temperature, and a fuel such as potassium carbonate is sprayed to make the combustion products of the gas have electrical conductivity. This electrically conductive gas passes through the magnetic field at high speed and causes a flow of DC in the process (see Figure 8-11). If this MHD engineering can be developed, it will be possible to design a fossil fuel power plant with an efficiency of 45-50%. Because MHD requires very high temperatures, it is not suitable for reactors that form working liquids that are much lower in temperature than the working liquid temperature that can be obtained with a combustion chamber using fossil fuels.

If an energy source is developed at the right time, it is nuclear. There are currently 22 nuclear power plants operating in the United States. In addition, there are 55 nuclear power plants under construction and more than 40 orders have been placed. This year, the United States will produce 1.4% of its total power by nuclear fission, which will reach 25% in 1980 and 50% in 2000.

[Figure 8-12] The diagonal curve (left) bends exponentially over time. This curve shows how many times a doubling interval is needed to achieve a certain amount of increase. That is, if power demand continues to be doubled every 10 years, the demand for electric power will increase 8 times after three triple times, in 2001. An exponential growth curve is plotted on the opposite scale (right). If we reduce power consumption by half in the period A and then keep it for 10 years and return to the previous growth rate, the time required to reach the constant size demand B is twice the doubling period, It will not extend outside.

A nuclear power plant with an output of 1,000 MW is 10% more expensive than a fossil fuel plant ($ 280 million versus $ 250 million), but nuclear fuel is already cheaper than fossil fuel. According to some estimates, the value of coal is likely to double from now to 1980. One reason is that the new tonnages of coal produced per capita per day have been reduced to less than 15 tons from 20 tons already reached in 1969 due to federal safety regulations.

The electrical industry is characterized by its basic load, intermediate load (which is roughly equivalent to the sum of all the work done by people at home and work from 7 am to midnight), and peak load (seasonal load only a few percent of total demand) Is a new era in which we must rethink the way we should pay for it. In the past, the electrical industry used the newest and most efficient facilities to cover basic loads, and older and smaller facilities were used to cover the daily needs of the day. However, in the future when more new facilities will emerge, the facilities that currently cover the basic load are too large to easily operate and can not easily be downgraded to accommodate intermittent use because it is difficult to stop.

Therefore, there is a need to build a new type of flexible power generation facility that links industrial gas turbines to generators that produce low-pressure steam that is required for the combination of steam turbines and power plants using waste heat from gas turbines. (General Electric and Westinghouse Electric Company) are currently recommending this type of combination. Gas turbine facilities can reach maximum loads in less than an hour, although they are slightly less efficient than the most efficient conventional large facilities, and can be constructed at a lower cost per kWh. To meet the short-term peak demand, the electrical industry is increasingly turning to gas turbines (gas turbines can be fully operational in minutes if there is no waste heat boiler) and pumped hydro power generation systems. In the latter case, the electricity produced when not in peak demand can raise water to a reservoir at a higher location and release it when needed to produce electricity.

(Westinghouse Inc.) recently estimated that in 1970-90 the US power industry would have to build a new facility three times more than the current facility output of 1,000 GW (10 ⁹ W), or about 300 GW. Of this new facility output, 500 GW, or half, will be used to cover the expected increase in base load, and 75% of this 500 GW will be due to nuclear power. More than 400 GW will be used to cover the ever-increasing intermediate load, and a significant portion of that will be supplied by the gas turbine. The new maximum demand of around 170 GW is believed to be supplied by the gas turbine and the pumped storage system at a 10: 7 ratio (Westinghouse Inc.).

[Figure 8-13] The exhaustion of a resource can be read in the curve on the left. That is, if 0.1% of the world's oil resources are currently used, if the doubling period is 10 years, all of the oil resources will be exhausted within 10 doubles, ie, less than 100 years. According to the table on the right side, although there is a big difference in the estimated amount of resources used so far, the ultimate exhaustion period does not change much.

This expectation can be thought of as wisdom. If so, what can innovative wisdom offer in the 1990s, or what might be the new effects that will affect power generation in 2000? First and foremost, there are optimists who believe that a prototype nuclear fusion plant will be built in the 1980s and a full scale will be built in the 1990s. In a sense, however, this is merely a view of the conventional wisdom as an accelerated time unit. Those who really want to try innovative approaches ask why we do not start to develop the technology to get energy from the sun, wind or tide.

Many are still recalling the 1930s (Passamquoddy) plan, which is being discussed again, and the new plan is the Bay of Fundy between Maine and Canadier, (Less than 1/3 of the turbine generator output) using an average of 5.4 m of tidal power. A 240MW tidal power plant, currently in operation, was recently launched by the French government on the estuary of the Languedoc River, with an average of 8 meters in tidal range. How many tidal energies would you get if you developed both of the appropriate bays and estuaries in the United States? All estimates should be accompanied by sufficient evidence, but by relatively modest estimates it is thought to be around 100 GW. But I have just seen that the electrical industry has to increase this output by 10 times to meet the demand in 1990. We can conclude that tidal energy is not qualified to be a major innovative energy source.

The energy that the square feet of the American land receives from the sun will be the same amount of power output in the next 100 years, when power demand is doubled every decade.

[Figure 8-15] Three incremental curves were compared. Curve A is an exponential increase curve. Curve B is an extension of the doubling period by 20%. In curve C, the amount of increase during this doubling period is always constant.

What about the wind? A study by authors a few years ago (Occluder State University) found that wind in Orcler Homeric region is about 18.5 W per square foot of ground when it is in a direction perpendicular to the wind. This is roughly equivalent to the amount of solar energy per square foot of Ohl K. Homer's average of 24 hours a day under all weather conditions, all seasons. Turbines rotated by propellers can convert wind power into electric power with an efficiency of 60 to 80%. Like tidal energy and other forms of hydropower, wind power has the great advantage that it does not release waste heat into the living quarters.

The difficulty in using wind power results in the problem of energy storage. Of all natural energy sources, wind is the most variable. If you want a power plant with a constant output, you must acquire and save that energy when the wind is blowing. Unfortunately, no technology has been developed to produce practical energy storage media. The charger is not a problem either.

One of the promising plans is to decompose water into hydrogen and oxygen using the variable electrical output produced by the wind turbine. These gases are stored under high pressure and recombined at a constant rate in the fuel cell to produce power (see Figure 8-16). Instead, this hydrogen can be burned in a gas turbine to rotate conventional generators. (Rocketdyne Division, North American Rockwell, Northamerica Rockwell), a hydrogen-fueled rocket engine made by the company for the Saturn Moon spacecraft, Which can be used to generate the required hot gas ejection required to power the turbine. In the Rakiddainbu, water-cooled gas turbines can operate at higher temperatures than conventional fuel-burning gas turbines and predict that the overall efficiency of the plant can reach 55%. If the Rakidyne method is successful, you can use any source of hydrogen. Wind-driven hydrogen kits Gas turbine power plants will be innovative enough to please even the most exotic people.

<Figure 8-16> Winds as energy sources are attractive because they do not add extra heat to the environment, as is the case for fossil fuels or energy from nuclear fuel. Like capturing solar energy, wind is available anywhere, other than hydropower or tidal energy. Unfortunately, however, the wind is also too much change. In order to use this effectively, it is necessary to store the energy captured when the wind is blowing and release it continuously somewhat. One way is to break down water by electrolysis using the power produced by the wind. Then, the stored hydrogen and oxygen can be supplied to the electrolysis tank at a constant rate to produce DC. This direct current is converted into alternating current and supplied to the electric wire. The electricity produced outside the peak demand period elsewhere can be used for electrolysis by supplying it to the electrolysis tank whenever there is no wind.

On the other hand, most of the proposals using solar energy seem really monotonous. Recently, Arizona University has made considerable direct proposals to the Arizona Power Authority, the Elden Mayen and Marjorie Mayen of the Optical Science Center. They suggested that if they efficiently collected sunlight reaching 14% of the western desert region of the United States, it would translate it to 1,000 GW, that is, energy equivalent to an increase in energy demand, typically between 1990 and 1990. They believe that within the current technology range, they can design a mass storage system that stores solar energy as heat at 574 ° C, which can translate into a total efficiency of 30%.

The key to this plan is in recently developed surface coatings, which are highly absorbent to sunlight and emit little of the infrared portion of the spectrum. The heat collected during the day to resume energy release for 24 hours a day resists the molten salt at 574 ° C. The heat exchanger transfers this stored energy to steam at the same temperature. A thermal storage tank for a 1000 MW power plant will have a capacity of about 300,000 gal. (May 25th) suggests that the electricity industry and the government should immediately design and construct a demonstration plant with 100MW output near Arizona Humor (Yuma). The width of the light plate required for this level of power plant will be 3.6 million square meters (slightly larger than 1 square mile). After the necessary developments are made, it is estimated that it will be possible to build a solar power plant with an output of about $ 1.1 billion, which is about four times the cost of the current nuclear power plant and a power output of 1,000 MW. As they pointed out, "The solar power has an economic problem of purchasing by facility funds, not by operating expenses." Nonetheless, 40-year-old solar power plants cost an average of 1/2 cent per kW / h They are estimating that they can produce power.

[Fig. 8 - 17] Peter Glazer of Arthur D. Little proposed a solar collector on a rectified orbit. The space station, which is 29,000km above the equator, is fixed relative to the ground station. An 8 × 8 km light receiving plate will accept about 8.5 × 10 ⁷ kW of solar radiation. A solar cell with an efficiency of about 18% converts it to a power of 1.5 x 10 ⁷ kW, which is converted to microwaves and sent to Earth. On Earth, this translates back to 10 ⁷ net kW, or enough power in New York City. The coverage area of the receiving antenna will be about 6 times as wide as required for a coal-fired power plant with the same output, or about 20 times as wide as required for a nuclear power plant.

A more exotic plan for exploiting solar power has been developed by Peter E. Glaser of Arthur D. Little, Inc. His idea is to put a lightweight solar panel on a synchronous orbit about 3,500 km from the Earth and keep it on for 24 hours a day. Solar cells (under development) collect radiant energy and convert it to power at 15-20% efficiency. This power is converted electronically into 85% of the microwave energy in orbit, which is still possible today. This microwave will be chosen as the wavelength that can pass through the cloud with little or no loss and will be collected by a suitable antenna on the ground. With current technology, microwave energy can be converted to power with an efficiency of about 70%, and it can reach 80 ~ 85% efficiency. (Glazer) estimates that a 10,000 MW (= 10 GW) output power plant in New York City would require an 8 km2 light receiving plate. The receiving antenna on the ground is slightly larger than 9.6km2. The microwave energy of this beam will be no harm because it is comparable to the intensity of sunlight. Glazer believes that this system will cost about $ 500 per kilowatt, or about twice the price of a nuclear power plant, assuming that round-trip space travel is possible for the construction of these satellites. The entire space station is 2,265 t, which is slightly lighter than the kit at launch time.

To meet the expected total electricity demand of 2,500 GW in 2000, 250 space stations of this size would be needed.

The great advantage of energy plans based on solar energy collected from the wind or the Earth's surface is that it may sound like an overpower today, but it does not add heat to the ecosystems of the earth. They say it's an invariant energy system. . The solar energy collected in the orbit is not a constant energy system in strict sense because most of the radiant energy blocked at 3,500 km altitude is a radiant energy that otherwise would not reach the earth. Only the energy collected when the sun's light-receiving plate is in line with the sun and the center of the earth does not heat up the earth's heat. On the other hand, the receiving plates in outer space will emit much less waste heat to the environment than fossil fuel or nuclear power plants. All but 20% of the total energy of the microwave to the Earth is converted to useful power. Of course, when this power is consumed, it is released into heat.

Recognizing the macroscopic nature of invariant energy system development, one has to be aware of what a certain amount of exponential growth means. The doubling process is a dreaded phenomenon. The amount of increase during any one doubling period - whether it is energy consumption, population, or land area occupied by freeways - is the same amount that it increased during its past past. For example, the next boats will contain as much fossil fuel as all the fossil fuels that have been mined on the Earth so far. Over the next decade, the United States will produce the same amount of power that has been produced since the beginning of the era of electricity.

The curve of this exponential increase is usually indicated on the opposite scale to indicate the whole. By specifying an appropriate value for both axes of the opposite scale, we can obtain a curve representing the number of boats required to reach saturation, or depletion, from the position of any known or imaginary percentage (see Figure 8-13 on the left) ) As an example, let's assume that 0.1% of the total fossil fuel reserves in the Earth have been mined so far, and that this amount has been doubled every 10 years. If this speed continues, you will be able to digest all of this fuel within a doubling period of ten times, in less than a hundred years. Of course, we do not know for sure how much of the total fossil fuel reserves have been mined so far. Let's assume that it is relatively small and 0.01% is mined, not 0.1% so far. According to this curve, in this case, all of them will be mined 100% within a period of 13.3 times, 133 years. In other words, even if there is a difference of 10, 1,000 or 100,000 times the amount of fuel mined to this moment, the timing of complete exhaustion does not differ much. Thus, even if only 1% (1%) of the total fossil fuel reserves of the Earth have been mined, even if the amount is doubled every 10 years, the total reserves will be exhausted in 266 years (Figure 8-13 See figure at right). It should be pointed out that the actual amount of mining depends on the type of fossil fuel, and that the 10-year period is only an example.

The key factor in estimating how many times the United States will tolerate a doubling of electricity demand every two decades (which is the actual rate of increase) is probably due to the fact that fuel supply - If so, it is almost infinite - not heat, but the effect of the environment on the conversion of fuel to electricity and ultimately to power. For the sake of discussion, let's consider only the heat content of the power actually consumed, ignoring the burden of waste heat from fossil fuel or nuclear power plants. By 2000, most of the power would be produced in a huge power plant for miles away from the coast, and it would be possible to imagine a game that would be able to release waste heat to the surrounding sea without damaging it (at least for some period of time).

In 1970, the United States consumed 1.55 billion kWh / h. If this were transformed into heat (and indeed it was) and evenly distributed throughout the land of the United States (which was not really the case), the energy released was 0.017 W per square foot. At the present rate of doubling, power consumption is increased ten times every 33 years. After the next 99 years, or ten times the number of doubles, the amount of heat released will be slightly less than 17 watts per square foot, or 18 to 19 watts per square foot, the average energy the United States receives from the sun 24 hours a day. Before doing so, you will need to change your current energy consumption pattern or develop the necessary technologies for an invariant energy system.

Let's examine what would happen if we changed the increasing pattern of energy in a way that seemed to be quite pronounced. Consider an incremental curve with an extension of 20% for each doubling period (see Figure 8-14). In the exponential growth curve, the energy consumption is increased by a factor of 10 by a factor of 3.32 times, or 33 years. The same increase in the curve of the increase rate is 10 times, which takes five times, that is, 50 years. In other words, it is only 17 years. The extension of consumption to 100 times is only 79 years (ie the difference between 145 and 66 years).

Another way is to significantly reduce current consumption levels and keep them at a low level for a certain period of time so that they do not increase and then return to the current rate of increase. If you reduce power consumption by half immediately, keep it for 10 years, and then regain the same growth rate as before, the time it takes for a 100-fold increase in consumption is only 20 years, extending from 66 to 86 years (See Figure 8-12, right).

In order to expect a long-term effect, the amount of increase needs to be the same curve, that is, a curve that increases by the same amount every original doubling period. On these curves, it would take nearly 1,000 years, not 100 years, to be predicted as a doubling every ten years for power output to reach the same level as the radiation received from the sun. As long as the invariable energy system does not supply much of the electricity demand, it is almost certain that the current rate of doubling can not continue for another 100 years, but how this system will look is still a problem hidden in the future.

As described above, the present invention provides a method and means for installing a nuclear waste disposal double-structure block tank marine tunnel transportation device (941) including marine deuteromagnetism in the marine environment so as to satisfy electric power demand with an invariable energy system, The means of eco-friendly energy production of the present generation and all the so-called business people who have made the best efforts to extend exhausted resources should be accompanied by cooperation and efforts to join them for their descendants.

The present invention is based on the idea that even when the sea floor depth of the ocean is 10 meters, the raft or the marine vessel which is sunked by the typhoon and the waved wave, and the deep sea area where the sea floor depth is about 10 km, In the bottom layer, a dam hydroelectric turbine generator is combined with a water turbine tidal power or submersible control system. The turbine generator is connected to the submarine water depth gauge, or the turbine of thermal power generation turbine is combined with other power generation facilities. (2) Nuclear power plant (811) inside reactor body (1) of nuclear power plant equipped with dual structure block tank dust collector (811) Permanent disposal method of long-term nuclear waste with anti- To implement the waste treatment of the nuclear waste.

Referring to FIG. 21, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is installed in the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. (Nuclear Power Plant) Operation of Nuclear Power Plant Nuclear power generation facility (811) of elementary conventional nuclear power plant showing construction of one embodiment Example of conventional nuclear power plant showing decommissioning aspect of thermal power generation operation method of conventional thermal power plant Nuclear power plant Operation of nuclear power plant Thermal power generation of thermal power plant Disassembly aspect of operating method Construction of road,

Referring to FIG. 2m, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is provided inside the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. Nuclear power generation facility of nuclear power plant (811) The nuclear power plant of the conventional nuclear power plant (811) The nuclear power plant of the conventional thermal power plant The operation of the turbine rotary blade (267) and the steam locomotive (1) of the nuclear power plant showing the operation mode as a side view, the operation of the thermal power generation operation of the thermal power plant of the nuclear power generation facility (811)

Referring to FIG. 2n, a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention includes a nuclear reactor main body 1, a nuclear power plant 1, Nuclear Power Plant Operation of Nuclear Power Plants In a nuclear power plant of a conventional nuclear power plant showing the essential constitution of the embodiment, a nuclear power plant unit 811, a steam pipe 779, and a high-temperature high-pressure steam inlet 780 of steam or a strong gas, The nuclear reactor 783 is decomposed into a side view and a cross-sectional view of the nuclear reactor of the conventional nuclear power plant. The nuclear power generation facility 811 is disassembled. The thermal power generation operation of the side power generation plant.

Referring to FIG. 2O, in the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, The nuclear power generation facility 811 is connected to the conventional production power central control room 781 and the transmission measuring room transformer room 782 through a connection structure The thermal power generation of the thermal power plant showing the operation methods of the thermal power generation and the operation of the nuclear power plant,

As shown in FIGS. 2L and 2M, in the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste, the conventional nuclear reactor of the nuclear power generation facility 811 is operated before and after failure A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and a condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and a core 791, a drum 792 and a reheater 793, a dust collector 794 of a thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

As shown in FIG. 2n and FIG. 2o, in the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the conventional nuclear power plant of the nuclear power generation facility 811 is operated A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and the condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and the core 791, the drum 792 and the reheater 793, the dust collector 794 of the thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

Referring to FIG. 2P, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Nuclear power plant (811) Nuclear power plant road,

As shown in FIG. 2P, in the reactor installation of the nuclear power generation facility 811 during the operation of the nuclear power plant, a double structure inner block tank 596 for treating nuclear waste is connected to an iron plate 597 of high strength stainless steel, The steam 780 containing the radiation material into the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector 794 provided as a tank 599 and provided in the form of a dual structure block tank 598, And the reactor pressure vessel 813 is provided with a nose 791 on the core 791 centered on the core 791 composed of the fuel assembly 671 and the control rod 798. In the reactor pressure vessel 813, A control rod guide tube 798e and a control rod drive housing 798a are disposed under the core 791 and a plurality of core shrouds and a plurality of jet pumps 325 are disposed around the core 791. [ There are all kinds of irrigation facilities. Uigae construction machinery transporter committed to being composed of nuclear power seolbibu 811 is connected to the reactor construction equipment,

Referring to FIG. 2Q, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, The nuclear power plant 811 of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment is divided into the nuclear power plant 811 of the elementary conventional nuclear power plant, Decomposition side strap configuration Road,

     As shown in FIG. 2Q, in the nuclear reactor power plant of the conventional nuclear power plant, the nuclear reactor power plant of the nuclear power generation plant 811 is reliably stopped in the boiling water reactor plant 802 when the engineering safety system is abnormal If an accident occurs in the piping of the reactor cooling system and the cooling water 287 of the core 791 is lost (coolant loss accident), an emergency core cooling system (ECCS) is installed to prevent the fuel from being damaged The system consists of a high-pressure core sprinkler system, an automatic decompression system, a low-pressure core sprinkler system, and a low-pressure sprinkler system connected to engineering safety systems in a boiling water reactor facility (802).

      In case of fuel breakage, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged to the outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

Referring to FIG. 2r, the nuclear reactor main body (1) of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, The diesel engine and the generator according to the operation of the hydroelectric power plant showing the conventional configuration of the hydroelectric power plant that provides the recovery, the diagonal configuration of the electric motor pump for supplying the power of each compressor and the pump,

As shown in FIG. 2 (r), the nuclear power plant (1) of the nuclear power plant, the nuclear power plant (811) of the nuclear power plant, and the hydrothermal power plant (943) A hydro turbine pump turbine 943a, a large hydroelectric turbine Pelton turbine 943b and a large hydroelectric turbine Francis turbine 943c are connected to a large hydraulic power generator seesaw hydroelectric power plant 944, And at the same time the marine seesaw hydropower plant 943 facility of the hydroelectric power plant is connected to the power line 95, the transformer 96, the power line 71, the air compressor 80, the high pressure storage tank 145, The motor shaft of the nuclear power plant is divided into a connecting shaft and a distributing shaft of a motor motor body 192, a compressor body 263, a turbine 267, an engine 268, an intake port 269, a watertight passage 270, Nuclear reactor facility main body (1) Internal nuclear power generation facility (811) It is made up of marine seesaw hydroelectric power station (943) connected to the structure of the equipment to provide a hydroelectric power station at the time of recovery after failure of the entire nuclear power plant operation.

Conventional Nuclear Power Plant Reactor Facility Main Unit (1) Inside Nuclear Power Generation Facility (811) Hydroelectric power plant's hydropower distribution facility is composed of dams constructed to control flood and drought in the reservoirs and rivers of highlands The distal end portion of the introducing pipe 191 having a water pressure located at the intermediate position between the multipurpose dam 680 and the multi-purpose dam 680 storing the water of the flood control equipment such as an underwater dam is connected to the through hole of the dam 680 And a rear end portion of the introduction pipe 191 is connected to a suction port 269 of the head tank 189 having a pressure and a plurality of introduction pipes 191 are connected to the discharge port 270 located at the rear end of the head tank 189, And the flow rate of the pressure, which is supplied to the inside of each of the plurality of hydraulic generators, is moved inside the hydroelectric power plant located at the lower end of the multipurpose dam 680, It consists of a hydro generator equipment for production.

Referring to FIG. 2, the nuclear reactor main body (1) of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention comprises an internal nuclear power generation facility (811) The hydro-electric generator inside the hydroelectric power plant showing the conventional structure composed of the hydro-electric power production control unit for restoration, the pump aberration in the Francis aberration and the Pelton aberration, and the constitution diagram of the turbine and the guide vein inner- ,

As shown in FIG. 2S, the nuclear power plant (1) of the nuclear power plant is equipped with an internal nuclear power plant (811). The nuclear power plant (943) of the hydroelectric power plant The power generation facilities of the marine seesaw hydroelectric power plant 943 include a hydraulic aquifer 943a for a hydroelectric power plant, a Phelpton aberger 943b for a large hydroelectric power plant, and a Francis turbine 943c for a large hydroelectric power plant. At the same time, large-scale hydropower generator Shizuo hydroelectric power plant (944) generates hydroelectric power by generating hydraulic pressure inside the generator (944) to generate mechanical energy. A plurality of aberrons and turbines 267 for rotating the turbine 267 to produce power, a generator 944 for providing the power conversion produced from the aberrations and turbines 267, A plurality of turbines 267 and a generator 944 are connected to an upper end of a rotating shaft 198. The turbine 267 and the generator 944 are connected to each other by an electric motor A lower portion of the upper rotary bearing 944d is positioned at a lower portion of the device 944b for pushing the ring tubular feathers and a stator coil 944f and a lower portion of a stator 944e are provided below the device 944e, The frame 944g and the central stator 944h are positioned and the electric wire 71 is sandwiched between the central stator 944h and the fan 195 is positioned below the central stator 944h and the fan 195 A low speed cooler 944i is provided below the braking device ring 944j and the braking device jack 944k and the low speed rotation bearing 944l and the engine generator 944m, the turbine rotation support 944n, (944p) The rotation axis (198) An armature coil for a generator, which is a non-rotating coil provided along the circumferential surface of the rotor coil, and a plurality of aberrators and a turbine 267 for providing a position to the lower end of the rotating shaft 198 And the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydroelectric power connection structure power production control unit 811b and at the same time the Francis turbine 943c The Peltton turbine 943b has a turbine 267 and a suction port 269 and a discharge port 270. The inlet port 269 and the discharge port 270 communicate with each other in the casing 141 and with a pressurized flow rate within the hydraulic power generator 944, The pump turbine 943a can control the distribution to the respective industries by adjusting the voltage in the substation of the transformer 96 of the substation, which is the power transmission unit, while generating hydroelectric power by rotating the aberration, The main pump 265 is controlled by opening and closing the main valve 265 to operate the pump water turbine 943a while generating hydroelectric power and move the water to the water storage dam 680 located at the upper part of the power plant (811) of the nuclear reactor facility main body (1) of the nuclear power plant, and at the same time, the nuclear reactor facility (811) of the reactor main body (1) of the nuclear power plant is provided with the hull position Control of the construction construction machinery and the hydro-hydro power production control unit of the hydro-hydro power generation, control of the power transmission, prevention of the harmful red tide prevention control, prevention of disaster prevention, control of the fish and shell scattering control unit, and control of the hydrological control of the dam. Connection axis connection structures.

(943b) for a large hydroelectric power plant and a Francis turbine (943c) for a large hydroelectric power plant are provided in a pump aberration (943a) for a hydroelectric power plant constituted by an offshore hydroelectric power plant (943) A head tank 189 serving as a pressure tank for providing a position above the power generation plant 943 and a suction port 269 located in front of the head tank 189 are provided with a connection structure with a head tank 189, The turbine 264 and the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydraulic power connection structure power production control unit 811b The turbine 267 is different in shape from the Francis aberration 943c to the Pelton aberration 943b to the marine seesaw hydroelectric power plant 943 while the suction port 269 and the discharge port 270 are connected to the inside of the casing 141 And pressurized flow provide for movement within hydraulic power generator 944 The pump aberration 943a can control the flow rate of the flow rate stored in the stream by adjusting the flow rate of the flow rate stored in the stream, The hydraulic pump 943a is operated by controlling the opening and closing of the main valve 265 by the electric power supplied from the nuclear power plant while simultaneously generating hydroelectric power to the marine seesaw hydroelectric power plant 943, 680 of the reactor main body 1 of the nuclear power plant, or by the dispensing apparatuses of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant, The hydroelectric power generation unit 941 may be connected to the hydroelectric power generation unit 944 in the power generation facility unit 811, The impeller 143 may be attached to the end of the rotating shaft 192 of the motor body 192 and may be formed of a prime mover having a connection structure with the power pump 304. At the same time, To the distribution apparatuses of the nuclear reactor main body 1 of the nuclear power plant 1 and the internal nuclear power generation facility 811 of the nuclear reactor main body which are formed by the distributing and inputting apparatuses of the internal nuclear power generation facility 811 as the urine site equipment.

Referring to FIG. 2, a conventional diesel engine unit (1) of a nuclear reactor plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention comprises a diesel engine External Dimensions and Power Motors Model Construction of Internal Disassembly and Assembly of the Motor Body (192)

The power motor motor body 192 provided in the nuclear reactor main body 811 of the nuclear reactor main body 1 of the nuclear power plant is provided with a hood 193 and a fan 195 and the body frame 196 are provided with a body front reinforcing steel plate 197, a rotary shaft 198, a rotor assembly 199, a front rotary support 200, a stator assembly 201, a motor protection casting frame 202, A terminal box 203, a lifting bolt 204, a terminal box cover 205, a rear rotation bearing 206, a rear reinforcing steel plate 207, a gap 208, a fan protection cover 209 and a rotor iron core 210 And a stator core 211 and a stator winding 212. The hydroelectric power generation is generated by a power transmission unit and a diesel engine generator 268 and is wound around the pump and the compressor by a rope It is equipped with a tackle winch (137) for connection and disconnection of the gate with a chain, Consists reactor equipment body (1) connected to the dispensing coupling input device connection structure of the internal atomic power seolbibu 811.

The electric motor body 192 of the distribution and connection device connecting structure of the internal nuclear power plant 811 of the main body 1 is provided with a hood 193 and a fan 195 and a body 192 in a snap ring 194 The cast body body frame 196 is provided with a body front racket 197 and a center rotary shaft 198 along the periphery of the rotor assembly 199 and a forward bearing 200 And the stator assembly 201 is formed inside the body frame, the terminal box 203 and the motor body 192 are fixed to the outer side surface of the casting frame 202 for protecting the motor, After the threaded tabs 167 having a predetermined dimension are formed in consideration of the weight of the object by the electromagnetism force so that the lifting bolts 204 can be lifted to lift the object, the lifting bolts 204 in the form of O- The terminal box 203 is provided with an attachment bond to the tab 167, The terminal box cover 205 is attached after the screw tabs are installed at four positions and a gap 208 is formed in the rear bearing 206 and the rear racket 207 at the rear of the rotary shaft 198 and a fan cover 209 are mounted on a fixed pinhole 20 at a forward portion of the rotary shaft in a link band 249 connecting the crank 248 and the crank 248 attached to the rotary body, (Square × 6 mm × 6 mm, length: 60 mm, 254) is fixed to a pin hole (width × length × height × A length of 3 mm x 3 mm x 3 mm x 80 mm, 20) is machined in half by a fixing pin dimension of the rotary shaft fixing pin hole and the fixing pinhole, the fixing pin 254 is screwed into the fixing pin hole By means of the Lena group, the individual bearings and bearings provide for disassembly and assembly, but at the same time they are fixed to the motor body 192 facility And the stator core 211 and the stator winding 212 are attached to the inner surface of the body frame and are provided with the electric motor pump formed to be attached to the processing hole 20 of the fixing pin 254 of the impeller 143 without the plow 250, 251 and the belt 252 are mounted on the circumference of the piston 127 with a plurality of cylinders 126 separated by a compressor to form a pump and a compressor. to be.

: 상기 형태, 129)로 뺑글뺑글 앞산 계곡으로부터 출발하여 360°로 회전시켜서 다시 앞산 계곡으로 설치되되, 단 산정상 산맥을 따라 지나는 소방방재배관라인(168)에는 상기 빗장걸이 장금장치(129) 형태의 방재수로(17)의 집수정탱크(34) 하부 위치에 레듀사(35)와 배관연결부속엘보 또는 티이엘보(44)로 방재배관라인(168)에 연결된다.As described above, according to the operation of the impeller of the motor motor rotary shaft 198, the booster pump control box 2 installed at the left side of the pump and the booster pump control box 2 installed in the industrial machine room in which the water pressure of the incoming fire water is compressed and stored, 3) and the discharge joint pipe 4 made of a material capable of withstanding high pressure is referred to as a manifold or a head tank 189 and a predetermined amount of fire-fighting water conveying means (for example, High mountain top to low mountain as an agate methane type plastic vinyl coating material, 350mm diameter flow tube can be transported by manpower, light and long life after being selected. 14) is formed and the piping 14 is connected to the piping 14 and the disaster prevention system 14 by a predetermined standard (width × height × width × height = 1 × × 1M) The bolt locks on the door (17) at a constant angle of inclination (16) 1 ° ((

The fire-fighting piping line 168, which is installed along the mountain-top mountain range, is installed in the form of a bolt latching device 129 Is connected to the disaster prevention pipe line (168) by a reducer (35) and a piping connection attached elbow or tee elbow (44) at the lower position of the water collecting tank (34)

Referring to FIG. 2U, a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention includes a main body 1 of a nuclear power plant, an internal nuclear power plant 811, The control block diagram and BF model are shown in the schematic block diagram of the pump front and front view and the cross-sectional multi-stage pump system concept; Speed control method, and 3-pump direct-injection-start-type system.

As shown in FIG. 2U, a distributing and inputting device for a nuclear reactor installation of a nuclear power plant constituting the nuclear reactor internal power generating unit 811 of the nuclear reactor facility main body 1 of the nuclear power plant is provided with a control block The pump power source 272 is divided into the control power sources 273 and the control power source 273 is operated in the emergency operation mode. (M / C) switch contact of the pump power source 272 and the inverter contact of the inverter 47 after being contacted with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontrol unit 276 by the micropower supply circuit 275 of the control power source 273 so that the microcontroller 277 and the switch input circuit 58 are connected When the input setting And the motor overload signal input circuit 280 outputs a signal to the (M / C) drive signal contact output circuit 279 and the motor overload signal input circuit 280, MCC B + T HR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the micro control unit 276, And a discharge pressure transmitter 284 is connected to the pressure sensing circuit 282 and connected to the inside of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal after connection, After the intake / discharge pressure switch 285 is connected to the external state input circuit 283 and the input circuit 283 is again connected to the microcontroller unit 286, Lt; RTI ID = 0.0 &gt; 276 & Type multi-stage pump operation modes is provided as an automation is composed of a nuclear power station connected to the distribution chute of a nuclear reactor plant having a structure of double nuclear waste disposal building block tank for the dust collector.

Referring to FIG. 2 (b), a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention has a conventional multi-stage multi- In the control system using the microcomputer of the pump and the inverter system of the digital pID control system, an unmanned camera of the control system is installed, and the inverter system in which the fire water is discharged from the injection nozzle is combined with the equipment of the control system. Operation Configuration Road,

As shown in FIG. 2 (b), the distribution input device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor installation main body 1 of the nuclear power plant is provided with the disaster- An inverter system in which an unmanned camera 184 of a control system is installed in an inverter system of a control method using a microcomputer and a digital pID control system of the preventive and controllable multi-stage pump 8 and fire water is discharged from the injection nozzle, (1) of a nuclear power plant to which the equipment of the fire extinguisher is attached, a fire body (166) in which a flood control process is formed is burned, and fire water in the fire body nozzle body is held inside the fire extinguisher, Stored in the fire extinguisher body 164 is stored and discharged simultaneously to the outside of the extinguisher body, The unmanned camera (not shown) installed at the height of the electric pole around the fire scene when the discharge pouring water 38 and the discharge pouring water curtain water film 39 are burned out at a moment when the burning pillar 237 is removed, 184 in order to display the situation at the time of fire on the monitor 52 through the information detection function of the pump control server 51 of the multi-stage multi-stage pump 8 control system 150, 8) is characterized by a digital control system and an inverter (47) consisting of a distributing and inputting device connection structure of a nuclear reactor plant including a speed control system and an algebraic control system.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor installation of the nuclear power plant has disaster prevention water, disaster prevention water, The control material or the disaster prevention material replacing the disaster prevention yarn is a natural loess or powdered yellow loam, and is a transportation equipment for transporting disaster prevention material, such as a fire fighting helicopter and a fire truck. The transportation equipment uses a basket (42) Disaster prevention waterways (17) in river streams with abundant disaster prevention materials or reservoirs or reservoirs that have a certain amount of disaster prevention water are transported and transported a number of times in order to evacuate the national disaster prevention fire. It is fortunate that if the initial evolution is carried out at this time, it will be declared as a disaster area if the evolving activity proceeds for more than a week. As a result of the need for prevention of disasters caused by disasters, which is a collective term for all disasters that are not declared as a disaster area, the development of disaster prevention has been progressed by the research and development of double structure block tank dust collector Research and development are underway in the distribution shaft and the connection shaft which are formed in the nuclear reactor main body (1) and the internal nuclear power generation equipment section (811) of the nuclear power plant.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor facility of the above nuclear power plant is designed to protect the life, The present invention provides the disaster prevention technology of the disaster prevention system of the present invention, and it is possible to provide the disaster prevention technology of the present invention by using the conventional fire fighting equipment, communication equipment and transportation equipment as advantages and disadvantages, Of the above-mentioned fire fighting equipment, an air balloon rubber air hose, a rubber hose to a wire rope, and other equipment to prevent a large-sized fire, And a tube nozzle processing hole formed by a hose and a nozzle body of a double pipe structure.

As shown in FIG. 2 (b), in the high-pressure type multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant, the fire nozzle (10) The disaster prevention nozzle is a small size pipe (14), a disaster prevention hose (9) that is made of a mixture of air (gas) and liquid, and a disaster prevention nozzle ), A disaster prevention nozzle (10) connected to the rear end of the piping of the high pressure multi-stage pump (8), a cable type disaster prevention nozzle (10), and a disaster prevention nozzle (10) A nozzle 18 is attached to the nozzle support frame 11 and the hook 13 and a spring 186 is attached to the wire rope 19 so as to impact the lug 21 and the shackle 23 for the safety pin, The nut 25 and the washer 26 as the bolts 24, The system including the high performance submersible pump 36 and the high pressure bottom-up pump control device by the mobile phone 82 of the communication means and the cable car 256 engine 226 after assembling the plate 165 and the flange 28 (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste.

As shown in FIG. 2V, the high-pressure multi-stage multi-stage pump 8 of the nuclear reactor plant includes a plurality of ejection nozzles 38 ejected into the nozzle gap 15, A partition wall 39, a water film or a plurality of radiation curtain water films 39 are arranged in a reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for providing fire suppression for life- ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the multi-stage, multi-stage multi-stage pump (8) of the high pressure multi-stage multi-stage pump (8) for connecting the distributing and inputting apparatus of the reactor plant of the nuclear power plant has fire water The conventional high-pressure type multi-stage pump is a water supply system for supplying water from a low place to a high place by watering. In a step drive system in which each pump is controlled to be turned on and off, It is a trend to change to an inverter drive method for drive control. The control system for efficiently controlling the driving of the multi-stage multi-stage pump of high pressure is such that the high-pressure multi-stage multi-stage pump 8, as shown in the figure, The pump 8 is equipped with a double structure block tank dust collector for treatment of nuclear waste, in which a plurality of high performance submerged pumps 36 are provided at intervals of 160 meters in a stepwise manner after the elevation of the elevator (1) of a nuclear power plant.

As shown in FIG. 2 (b), the high-pressure three-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor installation of the nuclear power plant is equipped with such a high- If so,

Firstly, most of them are monitored and controlled independently in the off-line. Therefore, the burden on the operation of the high-pressure type multi-stage pump is increased in the place where the worker or the worker is difficult to access and in a dangerous place. Secondly, since the switch button is used, And the third is that it is difficult to apply the system for managing the entire system when the system is dispersed in a plurality of places. In the fourth place, a plurality of high-pressure multi-stage multi-stage pump 8 control system 150 is manufactured and installed It is time consuming and costly to perform the independent test for setting the initial value and initializing the program.

In some prior arts for solving the above problem, firstly, in a high-pressure type multi-stage pump remote control system using a public telephone network, an alarm signal is transmitted to a central control server While the unmanned camera 184 at the same distance as the installation position of the electric pole is spaced apart by 50 meters outside the pipe nozzle industrial site, In the inline high-pressure bottom-up type in which the motor has communication means of the circulating water supply device, a large number of neighbors A high-pressure bottom-up type wired / wireless communication unit is provided and connected to the control system 150 And a helium (176) gas is formed into a plurality of hoses through the intake port and the exhaust port into the above-described advection balloon (77) and the airship (78), so that a nuclear power plant having a dual structural block tank dust collector In the "pressurized water supply operation management system", the load distribution of the reactor installation main body 1 is provided. At the same time, in the "pressurized water supply operation management system", the operation of the pneumatic water supply operation facility is grasped by using the Internet network 50, A management sub-system for providing information on the operation status of the water supply operating facility of the pneumatic conveyance transmitted through the network is provided on a date basis, and a portable wireless communication terminal Pressure multi-stage pump control system (not shown) that provides various services to the monitor 52 through the portable wireless communication terminal 82 (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste through wireless network (1) Nuclear power plant equipment (1) Equipment to be formed in the nuclear power plant (811). Ad-hoc or infrastructural Establish network construction.

In the high pressure stage multi-stage pump 8 installed in the interior of the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, And a motor is installed in the motor, a motor is constantly rotated by electricity supply, and the motor 127, which generates a very high pressure by reciprocating operation and operation, is referred to as a high-pressure multi-stage multi-stage pump, The pump module is equivalent to the engine module and is coupled with the pump module which is a mechanical value. In the inside of the three-stage multi-stage pump, the fluid flow in the impeller 143 is uniformly provided and the loss due to friction, vortex, etc. of water flowing out from the impeller 143 is reduced And is made to be guided.

The high pressure stage multi-stage pump (8) installed in the interior of the machine room formed in the internal nuclear power plant (811) of the reactor facility main body (1) of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, A power line for sensing sensor, and an electronic line for electronic control, and connected to the overcurrent breaker brake 61 and the main switch button 66 by the monitor 52 and the power supply 62, The check valve 6 is connected to the isolation valve 5 formed outside the pump body which is connected to the control device with the operation-on and the operation-off respectively, and the regulator 136, which is constantly reduced in pressure, And an electronic control unit 88 formed by a plurality of pumps in a plurality of valves and an electronic control unit such as an emergency valve 84 and a pressure check sensor in the low-pressure shut-off valve 83 are installed with a plurality of switch buttons , The above- A short distance wireless communication antenna 54 and a short distance wireless communication control module 54 are connected to a power supply 46 which is a power supply unit and a three stage multi-stage pump control board 53 of a high voltage down- The portable radio terminal 82 of the communication means or the electronic control device connected to the public telephone communication network is installed inside the multi-stage multi-stage pump control box 2, ), When the signal is wirelessly received by the electronic control unit module and the "switch button-on" inside the control room, the display screen 63 of the monitor 52 is installed so that it can be visually recognized in the control room, Communication valves belonging to the electronic control device and the isolation valve 5 on the front and rear sides of the three-stage multi-stage pump, the low-pressure shut-off valve 83 and the low-pressure shut- Electronics Which is a disaster prevention material including a wired / wireless communication device and an electronic control device which are connected to a solenoid valve 76 and an air compressor 80 of an air conditioning system via a collecting nozzle 34 and a dust collecting line 89, And it is a device installed on the roof of a lot of forest fires and dwellings in the shape of a discharge water jetting or a curtain water film, and the fire extinguishing material having a constant water pressure is fired into a plurality of nozzles gap and a plurality of nozzle gap machining holes. (1) Nuclear power plant reactor main body having a dual structural block tank dust collector for nuclear waste disposal with fire fighting and disaster prevention measures for life saving purposes (1) The pump 8 is provided with a connection structure.

In the high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811, a detection sensor 104 for checking the amount of arson at a low water level on the inner wall of the water collecting compartment is connected to the first ignition sense wire The multi-stage pump control box 2 of the high pressure inside the machine room is delivered to the electronic control sensor for checking the level of the disaster prevention water, and when the disaster prevention water reaches a certain level after the pump operation is stopped, The bevel tap 499 of the original type is attached to the inner wall of the collecting wall by a small thin wire serving as a lever to cause the bevel tap 499 to operate at a lower position, The operation of the sensing wire 41 is performed at an angle of 90 ° or 120 °, and a high mountain In the case of the low-acid collecting tank, it is necessary to install the collecting tank (34) inside the collecting tank (34) so that the height of the collecting tank can be adjusted before the disaster, (2) A double structure block tank for the treatment of nuclear waste, which provides simple solution within one second for the normal fire separated by A fire. (1) Nuclear power plant main body of nuclear power plant with dust collector Pressure multistage multistage pump 8 installed inside the machine room formed in the main body 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is such that a machining hole 20 (not shown) is formed in the stopper steel plate 165 on the flange- The filtering water is filtered by the isolation valve 5 and the check valve 6 so as to pass through the suction and return pipe 3, ). At the same time, the detection sensor integrally includes a meter 105 for checking the flow rate of the water, a ball tower 104 for sensing the water level, A high pressure isolation valve is installed in the middle of the meter 105 and the pump suction connection flange 28 at the upper end of the piping in front of the pump suction port 269 and a high pressure isolation valve 5) This is an automatic control valve that controls the transmission. The control unit is a magnetically controlled valve and a solenoid operated control valve. The solenoid valve 76 or the butterfly butterfly valve (305) is formed in the disaster prevention piping line (89), and a nuclear power plant having a double structural block tank dust collector for nuclear waste treatment is installed in the nuclear power plant (811) Stage type multi-stage pump (8).

The connection structure of the high-pressure three-stage multi-stage pump 8 formed in the nuclear power generation facility unit 811 is such that the basket 42 or the plastic pack 43 is connected to the ground surface 292 by the fire 292 or the spark 293, The control unit, which is a sensing sensor at the top of the valve, detects a fire, the valve is opened, the water is held at the top of the upper part and the water is held in the disaster prevention pipe, and the water having a constant water pressure passes through the valve opened to the disaster prevention pipe, And reaches the plurality of injection nozzles 10 in the region. The injection nozzle 38 discharges the water by the constant water pressure of the water pressure of the diverging nozzle. Accordingly, the disaster prevention piping 89 is provided at the lower end of the high pressure multi-stage pump inside the machine room, and the joint connection site emergency valve 84 and the hydraulic pressure control reducing valve 85 of the head tank 189, The first pressure check sensor 86, which is a detection sensor attached to the multi-stage pump control box 53, is connected to the inner multi-stage pump control box internal control board 53. After the pump is operated again to maintain the hydraulic pressure of a certain standard, At the same time, the disaster prevention piping line 89 is provided with a double structure block tank dust collector for processing nuclear waste, which is provided with a water pressure sensing regulating valve 85 at a constant distance from the machine room floor surface (MFG) Pressure multi-stage multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant provided with a connection structure.

The high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811 is configured such that pressure suction is performed to the left and right sides around the suction port around the impeller 143 inside the protective cover of the multi- And the discharge piping 3 and 4 are referred to as a head tank 189. The head tank 189 has a very high and high pressure and the water pressure of the fire water rises. At this time, the head tank has a capacity of 8 liters, When the pressure is reached, the pump inlet or pump discharge port in front of the head tank and the large pipe (14) of a certain standard size and the pipe connection fitting corresponding to the elbow or tee elbow (44) having a double structure block tank for treating nuclear waste, which is provided with a suitable material to withstand a high pressure, (1) providing a connection structure for Vertical multi-stage pump 8, the high pressure that would be installed in a machine room inside are formed in the atomic power seolbibu 811.

The high-pressure multi-stage multistage pump 8 connecting structure of the nuclear power plant 811 has a flange connection on the junction of the disaster pump connection port and a flange 28 and a flange 28 on the flange connection. (1) and (2), consisting of a nozzle nozzle (10) and a fire hose (9) connected to each other by bolts and nuts, Pressure pump may be installed in the head tank 189. However, the high-pressure head tank (high pressure tank) may be connected to the high-pressure head tank 189), there is a lack of realism and an uneconomical problem. In addition, the injection nozzle body (B), which is the injection nozzle (10), is divided into basic 1 type and basic 2 type "Title 100" ( 240 " to " NAME 50 "238 and" NAME 40 "239 to" NAME 75 "236 and" NAME 65 "237 to" NAME 90 "235, (10) Body (B) to be detached and connected to a standard type fire hose connection is a nuclear-power plant having a double structure block tank dust collector for nuclear waste treatment provided in a basic type 1. Pressure multi-stage multi-stage pump 8 installed in the machine room formed in the multi-stage pump 811.

The multistage multi-stage pump 8 connecting structure of the nuclear power plant 811 includes a water inlet 169 of the fire and disaster prevention line inside the multi-stage pump 8 and the collecting tank 34 inside the pump extinguisher body. The float 315 on the upper part of the manhole cover 152 and the float 315 on the lower part of the manhole are connected to the lower end of the manhole cover 169 by the water supply port 168, the water supply port 168 and the waterproof port 169, The float 315 is attached to the float 315 at four places around the processing hole 20 of the outer wall of the tank so as to fill the inside of the manhole 152 to fill the inside of the manhole 152. [ Is coupled to the square flange 28 of the louver cover 550 body so as to be formed of a separate louver cover 550 and a float retainer switch 551 and then inserted into the tank outer wall machining hole 20, Fill the nuts (25) after binding to the four places, The key wrench is used to separate and separate. Meanwhile, as shown in the figure, the upper portion of the bed frame 286 is fixed to the upper portion of the bed frame 286 above the upper surface of the bed frame 286 above the ground surface GLL, A pump 259 attached to the pump 308 with an upper tee elbow 44 is connected to the valve 114 via a flange 28 at the left side of the valve 114, A bass canceller alarm 543, a remote control alarm 544 and an alarm reset button 545 and a low level switch 546 at a low position inside the tank are connected to the switch 541 and the high level alarm 542, And is installed inside and outside the control board 53.

The centrifugal pump unit 308 has a structure in which the rotary shaft 198 which is the center shaft 198 of the motor 192 is connected to the high- A guide vane 142 is attached to the impeller 143 inside the casing 141 which is a body of the pump 308 so as to be closely attached to the previous pump driving yaw member and is mounted on the circumference of the rotating shaft 198 located at the center line of the casing 141 A balance hole 376 is formed in the septum seal 156 and the partition wall 372 of the shaft seal device so that the axial seal portion 390 is formed in such a manner that the cooling method 391 of the cylindrical seal is largely changed. The control box of the board 53 is configured such that the flow rate check flow meter 105 and the overpressure prevention switch 108 function as a stop valve at the upper part of the water line 169 line pipe 114 and a pipeline line sensor formed by a separate tee elbow 44 in the line piping 168 Is detected.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 is connected to a disaster prevention pipe 14 for disaster prevention next to the water supply pipe 14, The name "100 × 90 (241), 90 × 75 (242), and 75 × 65 (243)" are used for the seven standard types of the standard specifications formed by the piping bodies so that the standard can be adjusted by the connecting subsidiary reducers (35) The injection nozzle body is connected to the spray nozzle body in an antenna type so that installation is possible in the order of nominal 4 × 25 "(246) to nominal 50 × 40 (245) of 65 × 50 (244) And the pipe 14 of the injection nozzle body is joined to or connected to the pipe 14 of the injection nozzle body one by one so as to be connected to the rear end of the pipe bottom surface of the machine room. ) Are classified by designation and are connected by piping connection lead (35) And the piping 14 and then the piping connection reducer 35 are connected in this order so that the coupling and separation are performed in the reverse order and the bolts 24 and the nuts 25 for connecting the injection nozzles are connected to the washer 26 by the dis- The nozzle body (B) is connected to the flange connection processing hole (20) inside the flange (28) and connected to a recess formed between the flange (28) and the flange Is a high-pressure type multi-stage pump (1) installed in the interior of a machine room formed in an internal nuclear power plant (811) of a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector 8).

The high-pressure type multi-stage pump 8 connecting structure of the nuclear power plant 811 has a structure in which a bolt nut (not shown) can be easily disassembled and assembled so that the washer 26 can be adjusted to 0.5 millimeter or 5 millimeter at an intermediate portion between the flange and the flange. The discharge jetting number 38 can be set such that the operation of the radiation curtain water film 39 or the straight discharge jetting number of the valve and the high pressure stage type multi-stage pump 8, which are control devices, The discharge jet 38 that continuously and continuously discharges into the nozzle gap 15 is applied to a multipurpose range of preventive measures to prevent the spread of a large-sized fire and to prevent disasters. A plurality of airships 78 and an ad hoc balloon 77 are connected to the air hose 109 through the nozzle hose in the form of a multi- (1) of a reactor plant main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, including a method of using disaster prevention equipment for transferring air generated in an air compressor (80) And a connection structure is provided to a high-pressure type multi-stage pump (8) installed inside the machine room formed in the nuclear power generation facility unit (811).

The nozzle gap 15 formed around the periphery of the pipe 14 of the injection nozzle body 10 has a plurality of linearly arranged plurality of nozzles As the water film ejection number 38 rapidly evolves the flame 292 and the flame 293 gradually and precisely and evolves to prevent a large fire as a result, In the rice fields around the mountains and on the roads and neighboring houses, a straight nozzle gap is formed in two places on the pipe as in the arrangement of telephone poles. Small pipes are used as disaster prevention water transport means by using large and small pipes. The piping is slightly larger than the small piping to the top of the piping, and the piping parts are joined together by using a bolt or a nut and a nozzle gap (15) of a straight line with a piping length of 4 meters As a result, the discharge jet 38 was ejected from the two high-pressure multi-stage multi-stage pumps 8, and the performance was tested 20 times by adjusting the gap 15 again. The fire wall nozzle is formed in such a way that the fire wall nozzle is formed so as to prevent the road from freezing in winter due to the weather condition due to the installation length depending on the installation height of the water film curtain of the triangle, In order to improve the quality of life of the working environment, the fog is removed around the surface of the road and the view of the front of the road is widened so as to smoothly communicate with the traffic vehicle for safe driving of the driver. For farmers engaged in agriculture, it is necessary to protect and cultivate the crops of the vinyl house, On the day of precaution and rainy weather, the disaster prevention waterway (17) of the steep slope angle (91) and the constant slope angle (91) of the ridge line in the drought And disaster prevention pipelines. In order to prevent hail damage in the summer, it is necessary to keep the water properly in the vicinity of the disaster prevention pipe. It is a holiday resort on the sandy beach of the resort area. It cools the heat on the hot day on the coastline. It is a means of ejecting from the gap between the straight nozzles and the cold air. The fog is removed and the traffic is smoothly made. The fall harvesting sparrow prevents the grasshopper from being in proximity to prevent the loss of grain, In order to preserve large-scale bridge management, which is a first-class steel structure for the preservation of buildings, To establish a non-disaster world village in the international society in addition to the opening zone (sovereignty zone) in the multi-racial format, or in order to achieve peaceful coexistence in Northeast Asia, it was installed as the central axis of the center line of the Pyungang River, Cheorwon (2) A double structure block tank for the treatment of nuclear waste having a pipe nozzle-moving type fire sensor pump installed in a 1200-kilometer radius of 3000 Lane. (1) Nuclear reactor main body (1) It is necessary to cooperate with all the people of the respective countries in the creation of the global village without disaster by exercising the diplomatic capacity of reconciliation and goodwill of the international community to provide the connection structure to the high pressure multi-stage pump (8) installed inside the machine room.

The multistage multi-stage pump 8 connection structure of the high-pressure type formed in the nuclear power generation facility 811 is constructed such that the discrete multi-stage pump 8 and the high-performance submerged pump 36 are connected to the disaster prevention hose 9 of the disaster prevention nozzle 10, A pipeline 14 and a portable wireless communication terminal 82 of a multi-stage multi-stage pump system, a switch button for controlling the operation of the disaster prevention material transporting device and the pipe nozzle body, and a high pressure multi- The multi-stage pump control board 53 and the power source 46 as the power source are installed inside the multi-stage pump control box 2, and the power cable 80 is connected to the inverter 47 and a power supply unit 62 and a power cable 80 as an overcurrent breaker brake 61. The switch button is provided inside the control room and the machine room as a switch button for on / ) In close cooperation with the crew, As shown in the figure, the high-pressure isolating valve 5, the check valve 6 for preventing the backflow, and the emergency valve 84 are reciprocally operated by the piston. The plunger pump 148 is a reciprocating pump installed with a plunger for isolating the high-pressure isolating valve 5 and the check valve 6 for checking the backflow prevention. Pressure tubular multi-stage pump 8 installed in the interior of the machine room formed in the nuclear reactor main body 1 of the nuclear reactor main body 1 of the nuclear power plant having the block tank dust collector.

The disaster prevention nozzle is separated from the disaster prevention nozzle upper support frame 11, the lower support frame 11 and the vertical support frame 11 by the connection structure of the high pressure multi-stage pump 8 formed in the nuclear power plant 811 And the injection nozzle claw 13 and the hook hook 18 or the hook hook hook frame 11 and the hook hook hook engaging hole 20 are formed in order to protect the injection nozzle and the nozzle hose, The wire rope knot hooking hole 20 and the wire rope knot hooking hole 20 are used to protect the injection nozzle and the nozzle hose by being attached to each other so that the connecting hooking lug 21 and the connecting hooking lug working hole 20 or the connecting hooking safety hook shackle 23, Is used for disassembling the injection nozzle and the nozzle hose and is connected to the nozzle hose by means of the coupling 29 of the disaster prevention equipment and the evapotranspiration equipment coupling element thread body 30 and the disaster prevention equipment coupling A threaded body 31 is fabricated and a coupling seal rubber packing 32 is provided at an intermediate portion inside the female thread. Then, a paraffin stopper for a fire occurrence detection sensor is attached as a nozzle replacement to replace the packing 32, If you change the production method of existing fire extinguishing equipment to suppress the fire and flame at the time of occurrence, it will lead to the least cost or environment-friendly way in consideration of the difficulty of financing the source due to the small change due to the new production technology (8) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment which provides a technological progress. (1) A high pressure multi-stage pump (8) installed inside a machine room formed in an internal nuclear power generation facility (811) Thereby providing a connection structure.

The connection structure of the high pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 uses the air hose 109 and the high pressure hose 190 for the air balloon 77 and the airship 78, Fire and other functions of fire protection are used for the protection of forest protection. (158) Air is generated from air compressors for disaster prevention. Cold air and hot air are always separated and separated by compressed air. Air is supplied and fixed by wire rope and frame. , An active and passive disaster prevention means of domino type is used in which the disaster prevention material is controlled by the equipment inside the body of the pump fire extinguisher body formed according to the meteorological condition, . In addition, the mixer section at the rear of the disaster prevention pump uses a carbon dioxide (174) gas cylinder 171 as a teel elbow coupling gas inlet, and the carbon dioxide evolves 15 times faster than the fire water as a powder and compressed liquid gas, A gas cylinder 171 is installed in the monohull gas supply pipe 175 to construct a pipeline line 89 at the end of a high pressure multistage multistage pump formed by the gas inlet mix mixer 191 to perform a PORT injection And the port injection method is a method of injecting an injection liquid into a blood vessel of a human body and a dual structural block tank dust collector for treatment of nuclear waste, And a connection structure is provided to a high-pressure stage multi-stage pump 8 installed inside the machine room formed in the facility unit 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is applied in case of a large-scale fire incapability, but it is a general tendency to be applied to a conventional industrial site. (9) inside the disaster prevention hose (9), and then a collecting tank (34) built on the roof of a large number of mountains and a large number of large buildings together with a connecting part and an elevator (1) internal nuclear power generation facility (811) of a reactor facility main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, which is connected to a speed reducer (251) motor.

As shown in FIG. 2 (b), the pipe-type multi-stage high-pressure pump (8) of the reactor installation of the reactor plant of the nuclear power plant is equipped with a pipe nozzle type fire extinguisher It is a flow chart of the entire fire fighting equipment belonging to the inside of the center pump body. It is a flow chart showing the whole of the fire fighting equipment belonging to the inside of the center pump body, the industrial safety control room using the high pressure multi-stage pump and communication equipment using carbon dioxide and halon gas as disaster prevention materials, The carbon dioxide 174 and the halon gas 175 may be mixed with the natural earth or the loess soil 158 in appropriate proportions using the disaster prevention material carbon dioxide 174 and the halon gas 175. Alternatively, Gas and natural loess 158 are necessary for explaining the constitution in the present invention. The. The above-mentioned natural loess (158) is a reality that is used today as a ship and helicopter relief equipment for pest control by dispersing and dispersing liquid by a helicopter. Such a control activity is a phenomenon that can not prevent the work from being stopped by a hummi In addition, there is a dual structure block tank dust collector for the nuclear waste disposal that supplies the firepower disaster prevention device to the firepower power generator in the first place without the production electric power. In addition, the reactor of the nuclear power plant having the dust collector Pressure multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the facility main body 1.

The piping body of the firefighting nozzle installed at each location of the high and low mountains, valleys, roadsides and neighboring buildings was standardized with a total length of 2100mm to be separated into 7 segments with a distance of 300mm for the multi- Nozzle Nozzle Nozzle Cutting Hole Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz With The height is adjusted according to the shape of the building and the forest, and the elevation of the hose and the pipe body of the double pipe structure is adjusted to the elevation of the transportation equipment adver- tune and the unmanned airship To disrupt many disaster disasters, and as a disaster prevention and control system, air and carbon dioxide After the installation of the liquid fire water, the solid ocher powder and the sand as the lighter oxygen and helium than the air or the air, the fire pump and the air compressor were operated immediately after the detection sensor sensed the heat, and a lot of discharge jet was discharged outside the pipe nozzle. Unmanned camera or mobile service to reliably extinguish flame and pillar of fireworks, display of score on monitor by calculation of control server of multi-stage pump control system received from mobile phone terminal Firefighting with firefighting equipment The pipe nozzle of the sensor pump is fixed to the roof of each corner and the building roof of each spot, and the disaster prevention material mixed with the liquid and the gas solidly on the valley or the beach road is firstly fired In a period of 1 second, the incombustible gas (Oxygen) to prevent the combustion by preventing the combustion of air and oxygen (combustion) to reduce the temperature of the combustion to below the temperature of the cooling function and the hose as a cooling effect to put water with the early evolution of the life saving No-accident fire prevention sensor pump that guarantees life-saving structure and early evolution from seasonal fire and large-scale fire is surely installed Fire damage sensor A double structure block tank for supplying electric power to the pump tank reactor main body 1 of a nuclear power plant having a dust collector a high pressure multi-stage pump installed inside a machine room formed in an internal nuclear power plant 811 8).

The fire-fighting nozzle formed by the double pipe structure which supplies a lot of disaster prevention materials is installed in the water supply piping line of the water supply water pump of the water supply construction of the former water supply corporation and the neighboring living place where the building with the lower mountain is located, In order to keep the line from being extended, and to go further, sleeping, sleeping, and sleeping so that the forest fire does not evolve, the air tubing is added together with the water piping line by combining it with the weather forecast. In order to use the correction tank equipment efficiently, it is necessary to connect the air compressor, the high-performance submersible pump and the multi-stage pump electronic control unit and the portable wireless communication terminal to the wireless communication device, A system for enabling a disaster, It is about disaster prevention method and disaster prevention means to prevent disaster loss which flies like a snowball more quickly by judging dan more quickly, and furthermore how to control disaster through Internet. Fire hose connection port before and after the fire without the personnel approaching. Connection of the male and female hose connections. Piping nozzle is connected to the hose connection node. Nozzle fire prevention sensor pipe which is longer than the previous evolution hose used. (1) a reactor structure main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment provided with an air tube type collecting tank having a double pipe structure for rapidly accelerating the lifespan and the initial evolution by the fire fighting / ) The high-pressure (low-pressure) high-pressure And the type multistage pump (8) provide a connection structure.

In order to cope with the sudden occurrence of frequent occurrences without distinction of day and night, the large fire and large fire are not caused by the advance notice. For disposal of nuclear waste to set up a hydraulic pump capable of pumping up to 50 times of free fall by using the water hammer action to make the forest fire evolve within 1 second by the membrane pump (diaphragm pump) Pressure tubular multi-stage pump 8 installed in the interior of a machine room formed in an internal nuclear power plant 811 of a reactor facility main body 1 of a nuclear power plant having a dual structure block tank dust collector.

The previous large-sized fire is delayed due to the delay of dispatch of the fire-fighting vehicle according to the circumstances of the residential living area. As a result, the small fire spreads and the fire pillar becomes large, resulting in a large fire. In such a large area of the neighboring living area, there is a considerable difficulty in entering the fire truck into the production plant and the market. In this case, the fire is generated at the bottom of the building, and the toxic gas- In order to solve this problem, it is a sad situation that gas leakage is caused due to gas choking caused by a fire caused by gas infiltration into the upper floor of a residential area through a one-way passage. It is possible to prevent a large-scale disaster of a large number of water films ejected by a plurality of nozzle gaps of

As described above, fire extinguishment in this way is the same as that in the fire-fighting house, because fire-fighting vehicles are usually dispatched after the previous fire, . The apparatus of the non-emergency pump extinguisher for the early evolution and lifesaving of the large-sized fire according to the present invention comprises a nozzle body (B) for use in accordance with the specifications of the fire hose name used in the standard firefighter window specification, ) Are precisely standardized on the joint nozzle so as to form a basic 1-type and a basic 2-type

The above-mentioned initial ignition sources were ignited by fire, fire and fire due to friction of light flame, fire of lightning, and fire of flint among fireplace park, match fire and candle A large fire is caused by the generation of flame material. At the same time, a large fire is a public building of a building in a commercial building, a wooden building, and fire suppression within a range of a fire belonging to a kind of fire. In order to ensure the early evolution and to guarantee the life structure, it is necessary to precisely set the open / close position and the open / close position of the multiple open / close nozzles at each ignition site so that there is no damage to human life. Is set as follows

A fire such as the above-mentioned building A fire usually causes fire of general combustible materials such as wood (forest) and paper (fiber) to be high, low mountains, thorny bush of grassland, grass, The best way to prevent the fire is to fire the cable car arocarbons and ocher powder on the top of the machine room and on the mountain top of the large building. It mixes with the fire water in the field and surrounds the combustible with combustible gas within 1 second so as not to escape from the safe area of the fire. Painting section) The natural swamp composition was formed at the disaster prevention channel of the ridge line.

In this way, the dislodged material and the ignition material are set to the exact closing position to cancel the hostile relationship and to maintain the bridge relation of the stilts so as to suppress the ignition of the ignited material.

The large-sized fire is limited to occur in a vast and wide area of neighborhood life without prior notice, and due to the diversification of frequency of occurrence outside the closed space,

In the fire fighting and fire fighting equipment system, which is mobilized by the ignition source providing material and the substance for suppressing the ignition, as described above, various tube nozzle holes are installed in the building and the exterior to the inside with a large number of obstacles, Paraffin sensor used as a detection sensor for active disaster prevention and active disaster prevention equipment Nuclear waste disposal to provide installation of pipe nozzle to the outside of water tank of double pipe structure at the position where many pipe nozzle holes are formed by paraffin stopper of pipe nozzle (1) of a nuclear power plant having a dual structure block tank dust collector.

As shown in FIG. 2 (b), the problems of the prior art are improved in the high-pressure multi-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant. However, In the event of fire, before and after the occurrence of the fire, all communications equipment of the Internet control system, the multi-stage pump and the pump electronic control unit, and the air storage tank of the air compressor and the wire rope of the air compressor It is possible to quickly and accurately mix piping nozzles with solid nozzle nozzles and mix them with liquid and solid disaster prevention materials by mixing the facilities including the fire fighting disaster prevention countermeasure fire fighting equipment formed on the cable car body, As the pipe nozzle is changed, the gap between the nozzle of the radiation type and the gap formed by the straight gap is partitioned The fire water is separated into a plurality of radiological curtain water films and a plurality of linear straight curtain water films by nozzles and then discharged or ejected, and the gas which is generated in the case of fire is discharged from the dioxins and flame materials, It has evolved within one second from forest fires and large fires, resolved the priority of life-saving, prepared for floods and droughts, set up thorough measures to prevent landslides and roads, and distributed the distribution of nuclear facilities It is designed to eliminate many disasters at the same time by means of input devices. At the same time, it is necessary to calmly cope with the crisis and to overcome the disasters of the earth. Paraffin sensor installed in fire-fighting nozzle The fire sensor installed in the mountains and the building to prevent fire. The fire pump installed in the marine to prevent the disasters from occurring in the world. 591) Nuclear waste disposal at the bottom of the Otaei Daejangju Double Structure Block Tank Marine Tunnel Traffic System (941) In the station where the electric train (771) is installed, a number of fire fighting equipment for each type of fire is installed in the double structure block tank And installed in the nuclear reactor main body 1 of the nuclear power plant having the dust collector.

The pipe-nozzle type fire-fighting sensor pump of the non-emergency fire fighting and disinfection countermeasure product for the marine power plant is provided with an electric motor body inside the fire-fighting sensor pump and a center portion circle of a shaft, which is a motor center shaft formed on the horizontal center line (MBCL) The impeller which is a rotating body to the surface portion, a piston attached to a guide vane pump on both sides of the impeller, and a prime mover pump which is assembled to be detachable from the turbine. The pump body is provided with an isolation valve and a check valve, Flow control sensor that adjusts the direction control automatically and sensor switch that controls gas, liquid and solid in the pressure sensor and controls the flow inside the pipe. Power cable that supplies power energy and A fuse suitable for fire It can be used as a flammable gas such as fire water, loess, fireproof gas, carbon dioxide gas, carbon dioxide halon gas The tank is installed in a high-pressure tank and a collection tank in a closed tank and an open-flow type plastic bag or a tent tent. The nozzle of the nozzle is moved in the form of a moving boat for disaster prevention, Sensor pump installation is done

The tube nozzle moving type is divided into a basic type 1 and a basic type 2 according to a standard fire hose standard. A flange joint is formed by a firepipe nozzle and a coupling joint firepipe nozzle. The pipe nozzle is connected to a fire cable car, It is separated into a fixed fire-fighting nozzle fixed at 50m distance of installation with the same angle of inclination of the ridge of each corner at the bottom of the normal mountain range (GLL). At this time, High and low building in the beach near the seaside beach Build up a fire tower for firefighting cable car at each point of the rooftop and nearby mountain peaks, fix it with an anchor bolt by a hand tool, And the pylons were installed, and the top of the pylon was erected and the top of the tower was erected. A firefighter nozzle connected to a fire hose connection node of a disaster prevention material transfer device mounted on the firefighting cable car, a mobile firefighter nozzle having a plurality of pipe nozzle holes formed on the circumference of the pipe body, After receiving the power source generated from the generator through a power supply line of a transformer and a telephone pole connected by a plurality of electric wires, each pump motor motor and each compressor motor motor receives rotational power of the angular accelerator by sensor detection of each solenoid valve The impeller or the piston is used as a plunger pump to return the fire water to the top of the high acid and the backwash water is returned to the top of the high acid by the non-powered pump without receiving the power supply from the generator or the engine generator of the power plant, There is an appropriate level of normal fire such as buildings belonging to different types of fire Nuclear power plants with a double structure block tank dust collector for treating nuclear wastes that evolve early and evacuate lives in the wood, forest, and paper with fire and flaming pellets in less than one second ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading apparatus of the reactor plant of the nuclear power plant has a plurality of fire- A multi-pipe hose formed by a tank, and an electronic heat sensing sensor and a flow control valve, a manometer-level hose provided with an air compressor in a piping nozzle and installed in a fire disaster prevention piping line, and a fire- And the number of discharging water droplets and the number of curtain water films surrounded by the flammable gas together with the incombustible gas to block the supply of air to prevent the combustion and the cooling action to lower the temperature of the combustible material to the temperature below the ignition point are performed in the fire hose pipe processing The above-mentioned cooling action fire-fighting method which puts muddy water ejected to the space between the holes is a method in which, at the beginning of the fire, The above-mentioned adverbons and airships, which are designed to evacuate the refugees to the firefighting cable car security area by dispersing the load of the body of the fire sensor pump body, ensure the safety of the pump body, (Standard point) is set as one point of the triangular boundary line of the iron, which is the ceiling line of the silence, and then the standard point is set. In the land of the ancient ancestor and the territorial sea of the silent descendants in the land of 2400km diameter to the east, west and north of Kangsu Kangshan, the primary non-motorized pump of the multi- Nuclear power plant with double structure block tank dust collector for nuclear waste disposal providing turn-type fire-fighting nozzle and fire-fighting piping line And is formed in the nuclear reactor main body 1 of the nuclear reactor facility 811.

In the following, the same reference numerals are applied to the same formation as in the drawings, and the present inventor emphasizes that the pipe nozzle moving type fire pump sensor pump is not limited to the fire prevention according to the fire type A fire, the B fire type, The fire sensor pump of this nuclear power plant (811) was first coated with vinyl coating on KSD 3507 general piping rolled steel, and connected with nozzle body by KSD 2331 aluminum alloy for die casting. Plasma flow tube or KSD 3699 hot rolled stainless steel coil. The temperature sensor is replaced with a bimetal or bourdon tube to paraffin sensor type. It is used for diesel engine, fire pump, solenoid solenoid valve and other Standardized general purpose hose pipes are equipped with a double pipe structure type of liquid and gas The sizes of the pipe nozzles to be supplied to the city are classified into seven types according to the types of fire hose connection types: "Tubular Nozzle 1" Diameter of 200 mm, 180 mm, 150 mm, 130 mm, 100 mm, 80 mm, (150x150) mm, (150x130) mm, (130x100) mm, (100x80) mm, (80x50) It is formed by the tube nozzle connected to the hose connection part and the tube nozzle of the multiple straight line type crevice hole, so that it can be used as a demilitarized zone in building, Has evolved from fire and forest fire of general combustible materials such as wood, forest, paper and duvets such as buildings belonging to different fire classifications or large fire of neighboring living area, With this many adverbons and airships, , And at the same time, the center line of the center line of the triangular barriers of the Demilitarized Zone, which was intended to destroy many disaster disasters, was established. Nuclear Power Plant's reactor main body with a double structure block tank dust collector for nuclear waste disposal that ensures the installation position in multi-tiered form and allows the installation location to be determined beyond the border line of the non-disaster global village that ensures the peaceful coexistence of Northeast Asia 1) The equipment formed in the internal nuclear power generation facility 811 makes the configuration of the internal nuclear power generation facility 811 of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste reasonable.

The hose 9 and the piping 14 which are processed into a plurality of double pipe structures in the inside of the fire sensor pump body of the nuclear reactor main body 811 of the reactor facility main body 1 of the nuclear power plant and the injection nozzle 10 gap 15 and the processing hole 20 of the nozzle 10 are 300 mm in the distance of one body of the pipe 14 so that the bolts 24 and the nuts 25 in the total number of 7 are filled with the washer 26, And a plurality of processing holes 20 having a diameter of 5 mm or less are provided along the circumference of the pipe in the form of a cylindrical body of the pipe body. There are 498 total machining hole gaps. The injection nozzle body (B) has a multi- The two flanges 28 attached to the main body of the injection nozzle body A are connected to a single pipe which is a pipe body with eight machining holes at a predetermined inclination angle 16 of 45 degrees, (28) A stopper plate (165) is attached to the upper end (A) of the flange (28) by a stopper cap disk (165) The stopper cap 165 is disposed under the flange of the lower end A of the body so that carbon dioxide 174, halon gas 175, helium 176, fuel 131, The body 29 of the coupling 29 to the center position is inserted into the through hole 20 in which the small water tube 29 of the fire hose and the wire rope 19 are formed inside the coupling body 30 and the coupling body The wire rope 19 formed by a pumping pipe 89 for supplying the above-mentioned disaster prevention material, which is standardized to have a total length of 2100 mm and a total length of 7 mm, which is detachably assembled by a hand tool monkey spanner, And is bound to the inside of the fire hose 9

After the fuel piping line and the gas disposal material piping line are united together with the piping line of the liquid, the fire-fighting nozzle 10, which calls the nozzle formed of the pipe nozzle and the piping body in an orderly double- A spray nozzle body (B) detachably assembled to a nozzle body upper end portion (C) above a lower end portion of the body and a lower end portion (C) of the nozzle body; 2500 mm × 2500 mm × 2000 mm, which is made of a wire rope or a rope, is installed. Inside the basket 42, fuel supplied from the gas fuel supply pipe line is supplied to the ground or burner 173 ) Is adhered to the lower part of a vinyl tent (77) of an adverb (a cross-length × length × diameter: 10M × 10M × 10M, formed in a double structure in a circular shape), and a gas burner 173 for cooking used at this time is connected to an unmanned igniter 187 are installed and wrapped around the outer circumferential surface of the adobe with the wire rope 19 or the rope 131 and bound to the lower part of the adobe together with the rope 131 and then the unmanned camera 184 A radiosonde 134 as a meteorological observation device for observing the diurnal state of the farther farther from a higher position is mounted and the lower part of the injection nozzle body B is connected to the lower end of the integral multi- A multi-stage pump 8 as a device of the electronic control unit 8, a disaster prevention pipe line 89, a disaster prevention waterway 17, a double tube structure collecting tank 34, a fire fighting unit 40, A plurality of valves and an air compressor 80 for interrupting the flow of the microcomputer system, the communication equipment system and the piping internal flow rate, the generator 124, the engine 144, the air cylinder 138 formed in the doctor ventilation, An air trowel winch 137, a combined life-structure bed The iron structure 143 and the pump inner impeller 143 are connected to the nozzle 172, the hydrant 179, the grid drive 185, the air tube 188, the head tank 189 and the high pressure hose 190, The entire area where the pyrotechnic material and other gases such as the flue gas 292, the flame 293 and the pyrethrum 294 are generated is referred to as a fire sensor pump body and the reactor facility main body 1 of the nuclear power plant, Inside the nuclear power plant (811), the whole equipment of the fire-fighting and disaster prevention industrial goods necessary for the entire life span and the early evolution is included.

The fire-fighting nozzle 10 used as a plurality of pipe nozzles of the nuclear power plant 811 inside the reactor facility main body 1 of the nuclear power plant is made of KSD 3507, KSD 2331 and KSD 3699, In the case of the 7-bar basic type 1, when the nozzle is vertically installed at a height of more than the height of the main body, the nozzle joint portion is set in 7 stages. The basic 1-type nozzle is referred to as "nominal 100" (234), "nominal 90" The fire-fighting nozzle 10 is divided into the "name 50" 238, the "name 40" 239, and the "name 25" 240 separated by "name 75" 236 and "name 65" The pipe nozzle (10) is attached to a plurality of fire-fighting disaster prevention piping lines (168) formed along the mountainous mountain range and formed on the elbow or tee elbow (44). The pipeline (diameter: φ350 mm, Quot; 50 x 40 "to the " nominal 100 x 9" 241, the " nominal 90 x 75 "242, the " nominal 75 x 65" 243, (245) and " When a firefighter nozzle is formed at a position higher than that of the basic type 1 by 40 x 25 '' (246), the tip of the spray nozzle is positioned at the uppermost position of the spray nozzle A plurality of 8-joint gap 15 machining holes 20 are formed in the joint between the flange 28 and the flange 28 to form an 8-nozzle gap therebetween and connected to the joint at the lower end of the flange 28 when the 50- The nozzle 10 is fastened to the shale 23 and the bolt 24 so as not to be temporarily detached from the shale 23 and the bolt 24 with the nut 25 at two places of the tee elbow 44, After connecting the rope to the upper part of the body, pull it from both sides of the shackle (23) opposite to the binding position and disassemble the rope (137) after the bolting work. However, the worker should go up to the height of the poles, By using the spur winch 137, The firefighter nozzle 10 is provided with a plurality of firefighting nozzles 10 attached to a 15 m firefighting hose and connected to a plurality of firefighting nozzles 10 to form a length of 1 km, (1) of the nuclear reactor plant (1) of the nuclear power plant.

The head tank 189 of the nuclear power generation facility unit 811, the solenoid valve 76, the fire water 7, the loam 158 and the arsonization chamber 159 of the nuclear reactor facility main body 1 of the nuclear power plant, A power source 46 as a unitary power source for the pump control system 150, a high-pressure multi-stage pump control box 2, a high-pressure multi-stage pump control box 2, A switch button 66 for operating the pump on the wire rope 19 to the control board 53 inside the control box and the power supply unit 62 to the control server 51 and the control server 51, The radio communication antenna 54 and the portable communication terminal 82 are connected to the collecting tank 34 serving as a storage tank, the piping connection connecting adjunct 35 and the high-performance submersible pump 36, A plastic bag 43 and a hooking lug 18 are attached to the computer network input 68 and the elbow or tee elbow 44 connected to the disaster prevention pipe and the monitor 52, Apparatus in which the brakes (61) installation is conventional soy and accompanied.

The spiral casing 141 and the impeller 143 are provided in the guide vane 142 as a protection cover for the body of a plurality of the pump 8 of the nuclear power generation facility 811 inside the reactor facility body 1 of the nuclear power plant, The type and characteristics of the pump attached to the central axis of the rotating shaft 198 of the body 192 and the countermeasures against the main problems during the driving of the pump and the calculation of the pump according to the existing selection of the pump, , The pump shaft device, the countermeasures against the vibration of the pump, and the handling of compressors to compress the gas. It is a fire-fighting and disaster prevention countermeasure device that is formed on the body of the offshore power plant. Explain as follows.

As described above, in the inside of the nuclear reactor facility main body 1 of the nuclear power plant, there are provided a plurality of fire hose 9 and the pipe body 14 in the nuclear power generation facility 811, A paraffin tape 177 for a fire detection sensor and a nozzle stopper 100 for connecting a paraffin type pipe jointing nozzle with a processing hole 20 are formed by a combination of high and low mountains 395, (333) Roof rope (19) Fire cable cable (256) type No-accident fire prevention disaster prevention article pipe nozzle Movable type fire sensor After installing the pump, When a fire in a wooden building (332) and a forest (266) of a fire occurs, a fire of a general combustible material such as paper and a duvet is generated. In the past, a fire engine such as a helicopter and a fire truck started to fire with a siren, A streetcar The fire helicopter in the mountain and the obstacle such as the parking lot of the car is revived again at the moment when the helicopter is turned on and off to carry the fire water, and the digestion activity of the fire scene is disputed for a moment. In order to solve the danger of losing to life in an imminent situation, the pipe-nozzle-type fire-extinguishing sensor pump, which provides a simple initial evolution just before the start of a fire or a helicopter, (1) Inside is the nuclear power plant (811) fire fighting system.

The hose 9 of the sensor pump 811 of the nuclear power plant 811 and the plurality of the non-hazardous paraffin nozzle plugs 100 and the paraffin tape 177 formed inside the nozzle body 10 are installed inside the reactor facility body 1 of the nuclear power plant Closed multi-pipe nozzles Opening the crevice hole Fire heat sensor Paraffin burning flame and flame on ignition object due to match fire (166) and detection of low temperature of candle can not easily spread to large fire, The inventive non-hazardous-pipe nozzle-moving type fire-fighting sensor pump of the present invention is a fire extinguishing material of the pump fire extinguisher 124e to the acid alkali fire extinguisher 124b and the foam fire extinguisher 124b adapted to A fire, It is a non-flammable gas of non-combustible gas that surrounds combustible material to block the supply of air (oxygen) to prevent combustion, and to reduce the temperature of combustible material to below the ignition point. It is a fire extinguishing fire extinguisher that can guarantee the rescue and early evolution from large-scale fire and large fire caused by the seasons. It is a pipe fire extinguisher The air circulation pump 124 is connected to the membrane pump 144 and the air compressor 80 through the hopper 73, which is a mixer, into the water collection tank 34 through the fire water 7 and the loess 158, Is formed by a fire device of the intercooler (170).

The ignition object 166 of the nuclear power generation facility unit 811 is burned into the nuclear reactor facility main body 1 of the nuclear power plant while being stored inside the fire fighting nozzle nozzle body together with the fire water whose internal pressure of the fire hose is held, The incombustible gas 164 is stored and discharged to the outside of the fire extinguisher body at the same time so that the fire ejection water 38 and the curtain water film 39 are burned in a plurality of openings 294 in the gap 15 of the fire- When this is removed at the moment of departure, this scene is transmitted to the unmanned camera 184 installed at the height of the telephone pole around the fire scene, and the information detection function of the pump control server 51 of the multi-stage multi- The characteristics of the microcomputer control of the pump 8, which is configured to display the state of the fire at the time of the fire on the monitor 52, include a digital control method, an inverter 47 speed control method and an algebraic control method Chiyida.

The configuration of the multi-stage pump 8 is as follows.

Multistage Pump Specification

Details of the control method of such a three-stage multi-stage pump system are as follows.

· Pressure control method (Figure 1)

The operating range of the system is formed from the operating point (Pon) of all the pumps to the operating stop point (Poff1) of the maximum load operation pump and the operation stop point (Poff2) of the law firm. After the operation stop point of Poff2 of the pressure control type system is reached, it stops completely after the minimum operation between 180 seconds to 210 seconds (CO-CR) and 0 to 120 seconds (CO-ER). Although the width of ΔP can not be kept narrower than the inverter control method, it is mainly used for absorption pressure of the low layer by detecting input change of about 1 bar.

· Frequency modulation control decoration (Figure 2)

The operating range of the system maintains the adjustment value range.

When the flow rate of each operating pump reaches 100%, and the pressure of the operation standby pump is the operating point Pon and the pressure of the individual maximum operation pump is the stop point Poff before stopping.

Therefore, the frequency modulation method can maintain the narrow width of ΔP and control the rotation speed of the main pump with the frequency modulator, so that the system compensates the sudden pressure change occurring when the operation standby pump is in operation or when the operation pump is stopped do.

When the pressure of the system is lowered to the vicinity of the operating point, the main pump is slowly operated by the frequency modulator control, and if there is no change in the flow rate, the controller stops the pressure fluctuation due to the system hunting.

The details of the main functions of the three-stage multi-stage pump will be described as follows.

As described above, in the multi-stage pump of the present invention, the main function is described in detail inside the body of the pump-like gap type pump fire extinguisher, which is a urinal part, which is an urinal part, so that anyone can easily pumped without being close to the fire scene or near the pump machine when a fire occurs. (At the time of going to bed), as a result of the structure of the present invention, the fire-fighting helicopter of the fire-fighting vehicle according to the life structure and the advance prevention is made to evolve within one second before the arrival of the fire scene. At the same time, the distributing and loading device connecting structure of the reactor installation of the nuclear power plant is provided with the pressure tank 189, the collecting tank 34, Inverter 47 and the associated line relationship of the control inverter 47 and the collecting tank 34, The suction port 269 is formed in such a manner that the air shutoff prevention device 271 and the check valves of the respective pumps can be controlled to be fully closed and expanded by the inverter 47, The pressure tank 189 and the control unit inverter 47 are connected to the discharge confluence pipe 5 after the mounting position is clearly set in front of the separation valve 8 and the isolation valve (Isolating Vavle, Ballo-2 Butterfly 5) Which is a discharge port 270, is controlled by a first pressure check sensor 86 as a discharge pressure check sensor and an overpressure prevention switch 108 as an integral part of the second pressure check sensor 87 on the line (4) A plurality of fire nozzles 10 injects loess 158 into the mixer 73 so that each fire A is cooled and suffocated within one second with a fire within a second. Residential firefighting cable car (25 6) is formed by a plurality of high and low mountain peaks and a plurality of buildings having different height. Each of the plurality of fire hoses (9) is connected to a safety net (hose of a net including a wire rope of a cross shape or a well- ) Type hose 9 is a technical feature.

As shown in FIG. 2V, according to the configuration of the multi-stage pump operation mode of the control block diagram and the VFM model, the control power source 273 is separately divided into the pump power source 272 and the control power source 273 is operated in an emergency The sequence circuit 274 is brought into contact with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontroller 276 by a decoupling power supply circuit 275 of the control power supply 273 so that the microcontroller 276 is connected to the M / C switch contact and the circuit contact of the inverter 47, A setting circuit 277 and a switch input circuit 58 are input to the unit 276 and signals L and D are supplied to the LED display circuit 278 and the M / C drive signal contact output circuit 279, And the motor overload signal input circuit 280 is connected to the unit 276 and the pump &lt; RTI ID = 0.0 &gt; (MCCB + THR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the microcontroller unit 276, And a discharge pressure transmitter (transmitter) 284 is connected to the pressure sensing circuit 282 so that the circuit 282 is again set to be input to the unit 276, The pressure switch 285 is input to the microcontrol unit 276 via the external state input circuit 283 and then inputted to the microcontroller 276 again. (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste (1) It is the equipment to be formed in internal nuclear power plant (811).

The impeller 143 is coupled to the motor shaft 198 so that a predetermined amount of the disaster prevention material formed by the impeller 143 is introduced into the inside of the spiral casing 310 of the plurality of the pump- A plurality of fire fighting and disinfecting piping lines 168 of a predetermined amount of fire fighting water 7 transferring device and a left and right side head tank 189 for compressing and storing the water pressure of the inflowing fire water 7, A collecting tank 34 having a double structure in which disaster prevention waterways 17 of a certain standard are installed at intervals of a predetermined distance from the disaster prevention waterway 17 at constant inclination angles 16, A fillet tap 499 as a sensing sensor which senses the level of the flammable water into the correction tank 34 and a flange stopper for the plug filter 269 for blocking inflow of foreign substances into the condensate tank 34. [ (28), a switch button- A plurality of solenoid valves 76 which are closed at the time of the switch button turn-off and a plurality of solenoid valves 76 connected to the tee elbow 44 of the binding apparatus so that the disaster prevention material carbon dioxide 164 and the halon gas 175 are introduced into the rear of the head tank 189 And a mixer (hopper) 73 for mixing the disaster prevention material carbon dioxide 164 and the natural loamy soil 158. The low pressure shutoff valve 83 is connected to the disaster prevention piping 14, The multifunctional piping 14 is connected to the flange 28 of the discharge pipe 35 and the discharge pipe 35. The discharge pipe 14 is connected to the discharge pipe 35 through the flange 28, And a gap 15 between a plurality of flange 28 junctions formed between the processing hole 20 and a gap 15 around a plurality of pipe circumferences connected to the nozzle hose 9. [

In this way, the fire water 7 has the shape of the jet ejection 38 (380) of 490 circular dots or the shape of the curtain water film 39, and the eight water films at the higher and higher positions are flushed by the buoyancy of the adevolunes 77 and the airships 78 The life of the facility is extended by dispersing the body load of the cable car (256). After the safety is secured, the mixture of the loess is ejected to the pipe nozzle (10), causing disasters such as forest fires and large fires inside and outside the building The pump is a non-powered pump (393) that can be pumped up to about 50 times as much as the freezing pump due to the movement of the fluid, which is preheated at a time before and after 1 second. The air compressor And a two-stage squeegee air compressor 80 in which heat is dispersed to the oil cooler 157 without an intercooler 170 and an aftercooler 182 are integrally connected to each other through a suction port 269 and a discharge port (270) Which is installed in the air tub 730 formed by the fire extinguisher 710 and the bed jacket 172 of the lifesaving structure, The check valve 6 is provided so that the fluid can be movably transferred to the pressure tank (high-pressure bowl tank 303) inside the non-powered pump 393 so that the fluid can be transferred to the control valve 50 times as much as the drop. And an isolation valve (5), and the function of a plurality of expansion and full functions is ensured in the interior of the marine power plant body Double structure block tank for nuclear waste disposal provided as a system connection device for valves classified as flow control valves in valves and directional control valves Nuclear power plant reactor main body with a dust collector (1) Internal nuclear power plant (81 1).

As shown in FIG. 2V, a first pressure check sensor (not shown) installed in front of the isolation valve 5 as described above is installed in the high-pressure multi-stage pump 8 facility of the distribution and input device of the reactor installation of the nuclear power plant, 86);

A second pressure check sensor (87) installed integrally with the pressure reducing valve;

A bypass disruption piping line (168) installed to bypass the isolation valve (5) by connecting the front and rear sides of the isolation valve (5) and bypassing the isolation valve (5);

An emergency valve (84) installed in the bypass pipe line (168) so as to open and close as opposed to the isolation valve (5);

An electronic control unit (88) integrally controlling the operation of the emergency valve (84) by checking a pressure value from the first pressure check sensor (86) and the second pressure check sensor (87);

The solenoid valve 76 at the joint portion of the intake manifold 3 flange 28 at the upper end of the ground surface at the lower end of the stage multi-stage pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine chamber, An air hose 109 installed inside the nozzle hose 9 and an air nipple 109 for receiving and releasing the air from the air hose 109, And an engine generator 226 at the upper end of the engine compartment in such a manner that the airship 78 is mounted on the upper end of the upper surface of the ground surface. 46 is supplied to the air compressor 80 power motor control module 106 and then the air generated by the operation of the air compressors is stored in the air receiver high pressure storage tank 145 so that air of constant pressure is stored. Tank( 145, air pressure is constantly generated in the inside of the building, and the emergency valve (84) of the disaster prevention air piping line (181) is deployed when the disaster occurs and air is blown into the building and attached to the piping frame outside the building

Therefore, when the air balloon is lifted up to the top of the upper surface of the surface of the outdoor building so that air is stored in the rubber tubes of a plurality of container sizes and at the same time the life structure is formed, It is installed in fire-fighters nozzles as a whole with equipment for manufacturing and installing facilities and lifesaving means. It is installed in mountains and buildings with a parapet sensor nozzle stopper (100). It is used for fire prevention purposes. In case of disasters other than that, it is extended to the fire fence (40) and fire hydrant (179) The air pipe line 181 is connected to each of the pumps and each valve, 56 are constructed such that the flame 293 and the pillar 294 are simply annihilated and removed in less than one second by using a pump extinguisher 124.

Referring to FIG. 2w, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention, Partial strapless configuration diagrams of compressors moving compressors, stationary compressors and multi-stage screw compressors, as well as operating configurations of the front section for fixing underground anchor bolts,

As shown in FIG. 2w, the distributing and inputting device for the reactor installation of the nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant is provided with a multi- The solenoid valve 76 at the joint portion of the flange 28 of the lower end road surface upper surface suction confluent pipe 3 of the pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine room are connected to the fire- An air hose 109 installed inside the nozzle hose 9 and an air nipple 110 for a socket connected to the air hose 109 at a connection portion, And a diesel engine generator 268 at the upper part of the inside of the machine room for driving the airship 78 to the upper end of the surface of the ground are operated and the power source 46 ) The air generated by the operation of the electric motor 192 of the prime mover 80 supplied to the motor control module 106 of the synchronous motor 80 is supplied to the receiver high pressure storage tank 145 before the occurrence of the disaster Air pressure is constantly maintained in the receiver high pressure storage tank 145. At the same time, when a disaster occurs, the emergency valve 84 of the disaster prevention air piping line 181 is expanded, air is blown into the building, The pressure gauge 101 and the pressure switch 104 are provided with the overpressure prevention switch box 108 of the motor control module 106 and the crank 248 and the linkage 249, A safety operation is provided while connecting the wheel 250 and the V-belt 252 included in the speed reducer 251 to the prime mover 80 and the motor 192 to which the knob handle, the piston 127 and the cylinder 126 are attached At the same time, the belt cover 261 is moved to the feeder 250, A suction filter 262 installed on the circumference of the V-belt 252 to adjust the rotational speed of the prime mover 80 and to attract foreign substances to the air inlet 269 to the upper end of the compressor main body 263, The piston 127 of the main body 263 and the air discharge port 270 to which the cylinder 126 is attached are connected to the receiver high pressure storage tank 145 and are connected to the high pressure storage tank 145 at 6 kg per 1 cm 2 of air pressure When pressure is applied, the pressure gauge 101 and the pressure switch 104 connected to the safety valve 258 cut off the operation of the electric motor 192 and when the pressure in the high-pressure storage tank 145 falls below 6 kg per 1 cm 2 of air pressure, Pressure reservoir tank 145 is provided with an air valve 257 and a drain valve 60 at the automatic valve 259 while simultaneously operating the air hose 109 and the air hose connection device nipple 110 ) And the piston is reciprocally operated simultaneously Stage type screw cooler 147 in which heat is dispersed to the oil cooler 157 without the internal cooler 170 and the after cooler 182. The inlet port 269 and the outlet port 269 are connected to each other by a connecting device, And the disposal adjustment devices of the nuclear facility tubing 130, the basket 42, the bed nozzle 172 combined with the lifesaving structure, and the distribution and input devices of the reactor facility of the nuclear power plant, Nuclear reactor facility of power plant (1) Nuclear power plant's reactor facilities consist of connection structures of hydrological control regulator of dam of internal nuclear power plant (811).

As shown in FIG. 2w, the distributing and inputting device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a collecting tank (width × length × A plurality of disaster prevention pipes (not shown) connected directly to the disaster prevention water passage 17 and connected to the lower portion of the tank 34 are provided in the intake port 269 of the cement cone type with a height of 10M x 10M x 1M, Line (168) pulls overflowing valleys and immediately floods the floods to the Sea of the East Sea and the Sea of West Sea of the South Sea to the artificial waterfalls like the waterfall of Jeongbang, which is a natural waterfall of Jeju Island. In this case, the air compressor (80) and the diaphragm pump (144) are operated at the same time so that the valley water is not flooded. (43) was installed in the area of disaster prevention as appropriate for the case of 150mm or 300mm rainfall per hour, despite the fact that the damage was restored. In order to reduce the landslide damage, the double vinyl (43) However, even if the trenches are lost and the bridges are cut off and the other side of the valley is followed by the resettlement of the refugees, there will be a tug-of-war (139) in the valley to rescue the refugees isolated in the mountain valley. (1) The single-pipe small-sized pipe is formed in the bottom of the valley with a diameter of 100 mm and a length of 10M or less, and then the single- After installing it in such a way as to allow passage of fish, the plastic bag (size: length × length: 49kg, 60mm × 1M, firewood and loess, 180) After having been laid on the upper part of the bag 180 to a size of 200 mm in diameter and 7 m in length or less, the bag was again packed with the gravel and sand in the upper part of the middle pipe, A large-diameter pipe with a diameter of 300 mm or more and a length of 5 M is formed thereon, and a wire netting 139 formed of a net-like wire rope 19 is covered in each stepwise layer unit, and then a sharp- 185) or an O-ring bolt (204) and an anchor bolt (133) are installed, the knot is attached to the torpedo so that it can not be floated on the rapids. (It is recognized that there is no disaster when there are a lot of pine trees in the mountain fire prevention condition of the present invention).

Referring to FIG. 2x, a conventional structure of a nuclear reactor power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is shown in FIG. A gear drive 290 in which a tank is adhered, and a squeegee compressor connected to the motor.

As shown in FIG. 2x, the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant composed of the above- The apparatus for dispensing the nuclear reactor facility of the present invention includes a gear train 290 to which an oil separation tank 288 of a conventional nuclear power generation facility unit 811 is attached to prevent disaster prevention and control, And is connected to the air intake port 269 of the receiver high pressure storage tank 145 by disassembly and assembling with the inlet valve 263 and the suction valve 289 so that the distribution input devices of the nuclear power generation facility can be connected to the water inlet port 269 of the receiver high pressure storage tank 145, To be able to adjust the angle of view.

Referring to FIG. 2 (a) and FIG. 2 (b), a rear structure of a conventional nuclear waste disposal system for nuclear waste processing according to the present invention is shown in FIG. The suction filter 262 attached inside the air dryer and the suction filter attached to the inside of the air dryer 291,

As shown in FIG. 2 (a), a distributing and inputting device for a reactor installation of a nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant The apparatus for dispensing the nuclear reactor facility is provided with a suction filter 262 and a drier 291 which are installed inside the rear gate cooler 182 and the inside of the dryer 291, The suction filters 262 are attached to the distributing and inputting devices of the nuclear power plant to form connection structures so as to adjust the internal wastage of the nuclear power plant's nuclear power plant main body 1.

Referring to FIG. 2Z, a conventional fire hydrant system (conventional fire extinguisher system) shown in FIG. 2 (a) shows a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste processing according to the present invention, (179a) of an underground fire extinguisher (179a) and an underground fire extinguisher (179b) of an underground fire hydrant box at the lower part of the road surface. And is a front view of the fire extinguisher container and the fire hydrant box inside the fire hydrant box 161 and the fire hydrant box 160. The fire hydrant 179 is attached to the water feed port 168 of the connection and water pipe and the water- Sectional configuration and perspective view showing the construction of the fire hydrant system shown in FIG. 1 (a), (b) and (c) of FIG. Minute road-side configuration,

As shown in FIG. 2 (2), the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a conventional distribution device Prevention of disaster prevention at the flood control section (811) Underground fire hydrant (179a) and subterranean fire hydrant (179b) at the bottom of the ground surface Underground hydrant fire hydrant The firebox manhole is partly constituted and the fire extinguisher (161) and the fire hydrant box inside the fire hydrant box (160) are equipped with the fire extinguisher accessories and the fire hydrant box, and the fire extinguisher (179) (A) of the indoor fire hydrant piping system and (b) a small scale fire hydrant facility, A is composed of a connecting structure to adjust the reactor equipment body (1) inside the flood of a nuclear power plant.

Referring to FIG. 3, the reactor main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore power plant Straight road,

Referring to FIG. 3A, the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore Power Plant Side Construction Road,

Referring to FIG. 3B, the reactor main body 1 of the nuclear power plant having the double structural block tank dust collector for treating nuclear waste according to the present invention (1) The reactor main body 1 of the nuclear power plant, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Sectional configuration of offshore power plant roads,

As shown in FIG. 3, FIG. 3A and FIG. 3B, the atomic power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment according to the present invention, The position of the hull of the marine power plant floating ship with the connection structure with the hydroelectric power station of the land and the landing tunnel (672a) of the stepped dam revolving road which provides the position of the nuclear power plant (811) Hull Location of the Controlled Marine Power Plant Construction Machinery Control Section Marine Dock Body Dock The pipe bridge (928), which shows the arrangement of the hull displacement control and the position of the construction machine in the marine hydroelectric power plant floodplain (593,594,595) (771) inside the marine tunnel transport device to the inside of the marine tunnel transport device (941) to the pipe bridge (937) The hydraulic pumps 593, 594 and 595 of both hydroelectric power plants are connected to a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, The portable lug 607 and the portable lug pin 604 are connected to the vertical partition wall 605 and the pin linking shaft 606 for connection to the portable lug by the distributing and inputting apparatuses of the flood control machine provided with the door 624 for the hydraulic cylinder, 608) to the inside of the marine tunnel traffic device 941 to the construction machine connection structure and bridge bridge 928 and the pipe bridge 937 to the drilling machine 908 to the crude oil drilling machine 908, (928) and a pipe bridge (937) to the inside of the marine tunnel traffic device (941) for the nuclear waste disposal. The marine tunnel traffic device internal train (771) facility is connected to the marine hydroelectric power station floating ship (593,594,595) Location control and control of construction machine position Construction machine connection structure and disassembly (2) Nuclear power plant nuclear waste disposal facility (1) Nuclear power plant construction (811) Nuclear power plant nuclear power plant nuclear power plant nuclear waste disposal system Double structure Block tank Tank inside of marine tunnel traffic device (941) Marine tunnel Internal traffic train (771) Equipment Dual structure block tank for nuclear waste disposal by water pollution control facility Nuclear power plant reactor main body with dust collector And is further configured in the nuclear power plant 811,

(593, 594, 595) of the nuclear power plant's nuclear reactor facility installation and disposal unit (593, 594, 595) constituting the nuclear power plant section (811) inside the nuclear reactor facility main body (1) of the nuclear power plant are classified into rack and pinion type And the distribution of the nuclear reactor power plant provided with the butterfly valve 622 for controlling the buoyancy force of the band guide 621 and the door 624 for the hydraulic cylinder in the hydraulic cylinder hydraulic oil pressure 623 A large flange connection connection joint portion machining hole 615 to the portable lug 607 and the portable lug pin 608 to the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling with the insertion devices, (908) hydroelectric power plant construction machine connection structure and disassembly and disassembly combined with double structure block for nuclear waste disposal Tank Haze (771) inside the tunnel transport device (941) Internal tunnel of the water transport facility (771) Nuclear power plant reactor with double structure block tank dust collector for treatment of nuclear waste by the flood control facility (1) Internal nuclear power plant (811 ). &Lt; / RTI &gt;

Referring to FIG. 3C, there is shown a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. The construction of the sprinkler head pipe 111 of the sprinkler installation piping system sprinkler system and the torsion configuration of the trench head and the vibration alarm device 300 is shown in FIG.

3C, a plurality of drencher heads 299a, b, c, and d are installed on the sprinkler head 111 of the trench head in the sprinkler installation for preventing and preventing disaster of the nuclear power plant 811, The metal tube 113 for the fuse and the water valve 114 for the stop valve are connected to the reflector 112 by the underground pipes 115 and at the same time, A double structure block tank dust collector for nuclear waste treatment equipped with switch 118, bell 119, alarm valve 120, test valve 121, high pressure water pump 122 and vibration alarm device 300 Nuclear Power Plant Reactor Facility (1) Internal Nuclear Power Facility (811) Disaster Prevention Preventive Control Connected structures.

Referring to FIG. 3D, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention, Is a partial side view showing the operation of the piston pump 127 in a side view and a partial plunger pump 148 operating configuration diagram showing the manner in which the plunger pump 148 is partially actuated by the plunger 253, A partial side view showing the side surface of the pump 311 and the toe empty pump 140 and a driving side surface configuration showing the installation state of the waste water pump 309 as a side view,

The operation mode of the reciprocating pump piston pump 127 and the operation mode of the plunger 253 are connected to the rotational axis of the electric motor 192 in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, And the turbine pump 140 and the wing pump 327 of the rotary pump simultaneously move the handle in the left and right directions. , And it is equipped with a suction pump and a discharging pump in two chambers, respectively. The pump is equipped with a simple pump which can be easily mounted on a wall, 309) Nuclear power plants with a dust collector Unit main body (1) Internal distribution of nuclear power generation facilities (811) Discharging unit Disaster prevention Preventive control part Connection structure It can control.

As shown in FIG. 3D, the disaster prevention preventive control unit of the nuclear power generation facility unit 811 includes a closed position in the positive displacement pump formed by the preferred embodiment according to the detailed description of the type and characteristics of the pump, In a guaranteed function of the pump, in which the deployment position is clearly defined, a certain amount of fluid is delivered in the same manner as when dispensing fluid.

Therefore, a predetermined amount of liquid is sucked up by using a piston or a plunger of a reciprocating pump, and is sent out by pushing up.

First, get a high pressure even in a compact And is available for small flow rates of high viscosity.

Secondly, the pumping action is intermittent, so there is pulsation. To reduce this, a fly wheel to keep the rotating speed constant, or an air chamber (402) Accumulator) and the like

Thirdly, since the discharge amount of one stroke (stroke) is constant, it is possible to dispense and deliver a fixed amount.

Next, even if the number of revolutions is changed, the change of the discharge pressure is not as severe as that of the centrifugal pump. Therefore, there is always a suction / discharge valve to increase the number of parts, and the failure of the valve is fatal. In order to convert the rotational motion of the power into the reciprocating motion It is necessary to use a crank method or an exen method, which may complicate the components or cause vibration.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power plant unit 811, there are the following kinds of reciprocating pumps.

First, the piston pump has a seal line (packing) and a valve attached to the piston,

Second, the plunger pump differs from the piston pump in that the seal line is fixed to the pump body and is not attached to the reciprocating plunger. Therefore, the plunger 253 is easy to replace the packing, and a very high pressure can be obtained.

The pump is connected to a speed reducer 251 motor 192 and a wire rope 19 of a tug winch 137 to various motors in a rooftop collection tank 34 inside a machine room roof of a large building It is operated by pushing the top and bottom of the building with the switch button. The disaster prevention water (7) of the line of the fire prevention disaster prevention pipeline (168) is integrated into the equipment inside the pump fire extinguisher body, ) And firefighter (159) to the diaphragm pump (144).

In this way, the diaphragm pump (membrane pump 144) can pump water containing a large amount of fluid, mud or sand, and the suction or discharge is performed by moving the rubber membrane or the Teflon membrane 538 up and down . The feature that the crank 248 and the link belt 249 are formed on the rubber film 538 on the upper surface of the pump 144 and is not easily worn or closed with a fluid containing slurry (particle) It is composed of prevention of evolution. Therefore, it is suitable for chemical and harmful fluids because it can be completely leak-proofed without grand packing. It is suitable for fire disaster prevention in case of fire and other disasters.

And the wing pump (paddle pump) is a simple pump that moves the handle to the left and right to allow suction and discharge in two chambers. It can be easily mounted on the wall to transfer the oil from the drum, It is often used when you publish or publish.

As shown in FIG. 3D, in order to smoothly utilize the movement of the equipment installed in the past, the fire fighting cable control unit 256 of the nuclear power generation facility unit 811 A plurality of pumps are attached to the fire sensor pump body, and the tackle winch 137 described above is supplied with air supplied from the air compressor 80 to open (open) the air shutoff valve, A folding winch 137 is used in the rooftop fire-fighting cabin 394 and the steel tower 116 of the high and low mountains 395, The disc brake 399 serving as a brake is formed while winding the gears and the wire rope of the transmission 398 and the motor speed and the speed com- mer 397 so as to be able to perform the speed com- mer 397, (126) and electric A motor 192 and a switch are formed.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, a rotary pump Rothermal pump 357 is connected to the rotary pump 357 when one of the positive displacement pumps rotates The fluid is pushed and discharged between the main body (casing) and the rotor. The characteristic feature of this centrifugal pump is that it is not confused with centrifugal pump using centrifugal force. First of all, there is no suction / discharge valve such as reciprocating pump, continuous discharge and less pulsation. Secondly, high pressure discharge is possible. (Oil, oil, tar, pitch, paint, etc.), but at this time, the larger the viscosity, the smaller the number of revolutions and select the one with larger power. In the case of high pressure, it is sensed that a safety valve is installed, and that a liquid having no viscosity is good for a centrifugal pump. However, the gear pump is a type in which two types of gears are meshed, The second feature is that it is suitable for high-pressure use. Even if the discharge pressure is changed, the discharge amount does not change much. Thirdly, the liquid such as centrifugal pump is severely damaged The fourth is that the structure is simple, and it is easy to decompose, sift and clean, and the fifth is that the abrasion is promoted by the liquid containing the particles, so that it can not be used for the liquid containing solid particles, In addition, the spur gears are simple in structure, easy to process, costly, and widely used. However, there are noise and vibration, And the durability is weak.

In the rotary pump 357, the double helical gear for canceling the thrust (the force to be pushed in the axial direction) of the helical gear or the helical gear having a tilted inclination is difficult to process and the cost is high There is no noise or vibration.

The external gear pump 326a and the internal gear pump 326b are classified according to the shape of the gear and the reference for the sealing and cavitation by the gear tooth of the gear pump 326 Explain as follows.

In the pump of the rotary pump 357, the involute gear is in contact with the two points when the gears are engaged with each other, so that the liquid contained therebetween is hardly compressed and forms a very high high pressure, The rotation of the pump is a serious obstacle to the rotation of the pump, which causes an increase in the shaft force, breakage of the bearing, noise and vibration. However, in the rotary pump 357, If the two points are in contact, the liquid outside of the two points of the gear can not be inserted. In the space between the two points, a very large negative pressure is formed. If one point is in contact with the point, It collapses and makes a large noise, generates bubbles and causes vibration, which significantly reduces the durability of the pump. In order to prevent cavitation, first, the finishing should be very precise, the material should be carefully selected, so the price is very expensive. Secondly, the structure is complicated, so it is difficult to exchange or assemble. If it does not go through the angles, it will get caught soon, and the sixth can not be clamped on the way like gland packing, and once it is exchanged or wrapped, If you do not eliminate the vibration by connecting the power of the pump well, you will shorten the life of the seal. However, it is the most excellent sealing method at present. It is important to be able to avoid.

First, the type of mechanical seal is an inside-out type according to the set type, a single-seal type according to the seal type, and an unbalance type and a balance type according to the double seal type surface pressure balance type.

First, the inside (inside) type is the one commonly used in the way that the fixed side is on the pump side.

Secondly, the outside type of the outside is the case where there is a problem of the corrosion resistance of the structural material and the spring material in the way that the rotation is on the pump side. When the viscous coefficient is high viscosity liquid exceeding 100 cp, Is usually used when it is high vacuum.

Third, a single mechanical seal type is a general method in which the sliding surfaces are sealed together.

Fourth, double mechanical seal type is a type that has two sliding surfaces. It is used when it is a toxic liquid or a flammable liquid, when it needs to keep warm and cold, when it leaks, when it solidifies, when it is solid, when it is high vacuum, And is also effective for a liquid containing slurry which is a disadvantage of a high-temperature or low-temperature liquid or a mechanical seal.

Fifth, the unblanced type is generally used as a sealing method in which the pressure in the pump is directly applied to the sliding surface of the seal. Fluid pressure is less than 4kg / ㎠ (depending on the product, less than about 7kg / ㎠ for liquid with good lubricity and less than 2.5kg / ㎠ for liquid with bad lubricity).

Sixth, the blance type is a method that makes the pressure on the sliding surface of the seal not to be applied when the pressure in the pump is large. When the pressure is 4 to 5kg / ㎠ or more, It is used.

In the case of the ordinary mechanical seal, the spring is a spring that pushes the rotating ring of the sliding surface. When the liquid pressure is applied to the rotating ring, the contact force of the sealing section is added to prevent leakage. However, when the contact pressure is too high, the abrasion of the sliding surface is promoted. Therefore, when the internal pressure is high, this pressure is balanced to adjust the contact pressure.

The following cooling and lubrication is the frictional heat of the liquid or the sliding surface of the liquid. When the temperature rises due to the heat of the liquid, the material wears and corrodes or the packing seals. Therefore, the cooling and lubrication functions As shown in the drawing, a quadrangle 268 is formed above the shaft bar 390 and a flashing hole 361 is formed in the culver 367 in the cornering method 391 of the mechanical seal.

First, flushing is the most common method. In this method, liquid is injected and extracted from the outside of the high-pressure side liquid of the shaft end to maintain the temperature of the seal appropriately. Thus, vaporization of the sealing end face is prevented to improve lubrication, It also prevents accumulation on the shaft bar.

Second, quenching is a method of injecting a coolant into the sealing section of the seal so that the fluid does not flow to the high-pressure side of the shaft. When the fluid comes into contact with volatile fluids or air, If leaking fluid is washed out, dilute and recover. In addition, it is a device formed in the nuclear reactor main unit (1) 811 of the reactor main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for isolating air from the sealing end and preventing oxidation.

For example, in the case of handling (LPG) or the like, the cooling water is flowed outside the seal face so that it can be washed away.

Third, cooling is a method of cooling the outer periphery of the seal rather than a sealing cross section, which has a cooling effect lower than that of quenching, but does not require leakage to the atmospheric side, and there is no need to pay attention to the purity of cooling water.

In the material of the mechanical seal, the material of the seal varies depending on the type of the sealed liquid, the temperature, the pressure, the presence of foreign matter, the speed, the degree of leakage, and the like, but is known to the general public as stainless steel and Kaibon graphite It is a combination. Carabong graphite is self-lubricating, does not fuse with metals, has low friction, and is resistant to chemicals. In addition to stainless steel, stainless steel, ceramics, cemented carbide is added or heat treated. Dual structure block tank for treatment of nuclear waste to provide sufficient corrosion resistance and abrasion resistance Nuclear power plant with dust collector Main body (1) Internal nuclear power plant 811).

Examples of combining materials of the mechanical seal are as follows.

In the reactor installation of a nuclear power plant equipped with a double structure block tank dust collector for treating nuclear waste according to the present invention, there are one or a plurality of factors superimposed on the vibration of the pump.

First, according to the hydrostatic vibration, the vibration by the cavitation: the cycle of about 600 to 25,000 cycles brings about the rapid vibration and the noise. Second, the vibration by the surging phenomenon: Cavitation occurs when the discharge amount is large, The vibration due to the water hammer (water hammer) and the vibration due to the unbalance of the flow in the pump 4 and the vibration caused by the mechanical vibration firstly have a long period of about 10 to 0.1 cycle, The vibration due to the unbalance of the rotating body and the vibration due to the dangerous speed cause a severe vibration caused when the rotational speed of the shaft resonates with the natural frequency of the rotating body. Vibration due to solid friction is a kind of self-excited vibration, and there is a shortage of lubricating oil on the rotating shaft, And fourthly, the vibration caused by the hydraulic pressure of the bearing is a vibration generated due to the oil pressure of the bearing part when the rotary shaft rotates at an angular speed about twice as high as the dangerous speed, In particular, the vibration caused by the natural frequency of the pump is a problem in the vertical shaft pump. In the sixth place, the vibration due to the centering failure is a serious factor when the centering failure is caused. And the seventh is hydrodynamic vibration to the reactor facility of a nuclear power plant equipped with a double structure block tank dust collector for nuclear waste disposal which occurs due to the vibration caused by the prime mover and the eighth foundation weakness

The output definition for the use of the diesel engine 226 will be described as follows.

First, the term commercial refers to the generator The term "emergency" refers to the output (equivalent to ISO 8528 ESP) applicable to emergency generators used for a limited period of time in the event of a mains failure, while the engine model is referred to as a cooling fan And a flywheel 268 and a V-belt 252 are attached to the cylinder 250 and the cylinder 250, respectively. As shown in the figure,

As shown in the above table, the output tolerance is ± 5%. The description of the specification of the engine 226 is the same as the specification of the engine specification of the right side.

<Engine Specification>

Finally, the precautions for handling the compressor are described in detail as follows.

First, in general precautions concerning the handling of compressors,

First, the compressor is always kept clean and the surroundings are cleaned and arranged thoroughly.

Second, when the operation of the compressor is shut down, the engine is operated for a short time only once a day for a short period of time.

However, in case of long-term shutdown, disassemble and clean, replace worn, damaged parts or lubricating oil with new ones, drain all cooling water (drain) and prevent corrosion.

Third, each axis is checked and adjusted every opportunity.

Fourth, valves, pressure gauges, regulators, filters, etc. are prevented from malfunctioning by regular inspections and daily inspections.

Fifth, cool water uses clean water. Cooling tube is disassembled every June or year. It is cleaned with water vapor. If the weight is decreased by 10% or more, it is corroded or worn.

Sixth, always pay attention to the gas leak of each part, and the toxic and flammability should be detected with a small amount of detector, and proper measures should be taken.

Seventh, oil is selected with the help of the manufacturer.

The eighth, if there is an abnormality, stop driving immediately, notify the manufacturer and ask for repair.

In the following notes on starting,

Be sure to check that bolts, nuts and other screws are tight.

Next, fill the crankcase with a specified amount of lubricating oil and check the lubrication condition.

Pass the third cooling water and check whether the cooling water circulates.

Next, open the pressure gauge, pressure regulating valve, drain valve, etc. to check the pressure indication.

Next, the small compressor should be rotated by hand with no load. Check the connection of the electric motor by inserting the hand switch after checking the switch, and check whether the foreign substance is not caught in the cylinder.

The sixth suction valve is closed and the switch is opened with the bypass or drain valve open.

Next, when the normal rotation is performed, the drain valve and the bypass valve are closed from the first stage to the next stage, and at the same time, the suction valve is opened.

Finally, pay attention to pressure, lubricating oil, temperature, noise, vibration leakage at each stage.

Then, in the notes during driving,

The pressure, leakage, vibration, temperature, abnormal noise of each stage, the quantity and temperature of the cooling water, the temperature and pressure of the lubricating oil and the load of the motor are checked.

In particular, pay attention to abnormal increase or decrease in temperature or pressure, and never tighten or hammer the bolt during operation with leakage.

This is divided into the following.

First, regarding handling of reciprocating compressors

First, whether there is abnormality in the scale of the pressure gauge and the suction / discharge gas temperature at each end

Second, the change of bearing temperature and the abnormal rise

Third, keep a watch on the change of the cooling water temperature and adjust the quantity if necessary.

Fourth, watch the oiling situation of the cylinder lubricator, adjust the flow rate, and supply oil to the lubricator.

Fifth, the state of change of external flow or hydraulic pressure

Sixth, the piston rod packing leakage and temperature rise

The seventh is whether the color of the drain is rapidly blackened

Eighth, are there any differences in the sounds and vibrations of each part from normal?

Ninth Valves or flange joints such as safety valves, drain valves, etc. · Are there any gas leaks on other tight surfaces?

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

The following is the handling of Turbo Compressor

First, the lubricating oil pressure of the bearing lubricant or the temperature of the returned oil

Second, the oil pressure or return oil pressure for the shaft bar or the differential pressure or leakage flow

Third, whether vibration of each part such as main body, bearing,

Fourth, abnormality of bearing water temperature

Fifthly, the change of the cooling water temperature is monitored, and the quantity of water is adjusted when necessary.

Sixth, there is no leakage of gas from valve or flange joint of piping system or other tight surface

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

In the note of the fourth stop,

First, switch off the electric motor and close the intake valve.

Second, check the pressure drop and close the discharge valve. Observe the abnormal sound or vibration until stop.

Next, close the coolant valve to cut off the coolant and drain all water from the water jacket or cooling tube.

Finally, discharge any other condensate or oil.

In the notes on the fifth disassembly and inspection,

Firstly, when disassembling and checking, make sure that the machine is disconnected from the power source so that it does not operate.

Secondly, if the gas inside is toxic or flammable, it should be completely insulated and replaced with inert gas.

The following should be done after confirming that there is no pressure at each end of the decomposition operation.

Finally, when the cylinder head is disassembled, the bolt alternates in the order of the opponent facing each other, gradually releasing it to the two relatively positioned positions (of course, confirming that there is no abnormality,

As described above, each of the prime movers and the compressors are connected to each other by an electric motor and are connected to each other to show the conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment. As for the selection of the model in the separation process, the damage to the fire caused by the fire occurring in the blink of an eye for 1 second as described above clearly according to the type of fire by the type of fire as a fire-fighting disaster prevention countermeasure is impossible. Therefore, the fire should be selected as the most appropriate place for the initial site precaution.

Referring to FIG. 3E, there is shown a conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, (459) Each valve configuration providing the land and off-shore reactor facilities of the faucet (496) of the faucet type of the integral type and the piping accessories,

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, The control valve 459 is integrally connected to the pressure reducing valve 460 and the pilot operated pressure reducing valve (not shown) in the distribution input device of the nuclear plant installed in the offshore of the general faucet 496, A main valve 466, a main valve spring 467, an adjusting spring 468, and a control valve 468 are connected to the main valve 461 and the magnetic pressure reducing valve 461, A spring type safety valve 473 and a relief type safety valve 474 and a screw type pressure regulating valve 471b and a screw type automatic pressure regulating valve 470a, a flange type pressure regulating valve 471b, a safety valve 472, A steam-type pop-spring-type safety valve 475, a PFO-type safety valve 476, The automatic level adjuster 478 and the automatic level adjuster 479a as well as the automatic level adjuster 480 and the air vent valve 481 and the thermal type automatic air vent valve 482 and the bucket Type hot air type automatic air exhaust valve 483, a refrigerant pipe valve 484, a refrigerant stop valve 485, a feed valve 486, a bellows type charge valve 487, and a diaphragm-type charge valve 488, an expansion valve 489, a diaphragm-type expansion valve 490, a bellows-type expansion valve 491, a rich valve 492, a refrigerant pressure regulating valve 493 and a solenoid valve 494 The water supply type common faucet 496 of the piping accessories is composed of the faucet body 529, the packing box 530, the packing press 531, the faucet 532, A disk 534, a disk packing 535, a water-resistant packing 536, an aging resistant packing 537, And Teflon membranes 538, which are installed in the reactor installation of the nuclear power plant, and the disruption prevention preventive control connection structures of the nuclear power generation facility 811 of the nuclear power plant.

The ground level load (GLL), the ground level load on the upper (GLL), and the ground level load (GLL) Abbreviated as GLD).

On the right side of the valley, the wire rope 19 for the 5000 kg overhead crane for the industrial site or the rope 131 at the point A and B of the valley at the bottom of the valley, The ropes 19 and 131 are connected to the hooking hooks 18 by the shackle 23 and the driving wheel rollers 135 by the hoisting ropes 135 at the points C and D, The lifting baskets 42 and the injection nozzles 10 are connected to each other by a 15-m-long fire hose at the cable car (256) The length of the injection nozzle is set so that the length of the injection nozzle is set to a predetermined value after the collecting tank 34, which is a bucket of a movable dual structure, and the pump 71 are installed together in the cable car 256, (A), (B), (C), and (D) according to the length of the nuclear waste (451) showing the conventional construction constituted in the nuclear reactor main body (811) of the nuclear reactor main body (1) of the nuclear power plant having the double structure block tank dust collector and the general type faucet (496 ) Of nuclear power plants and nuclear reactors equipped with respective valves to provide the land and ocean reactor facilities, and the operation of nuclear power plants is carried out on land and in the oceans of the world.

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, (496) of the faucet of the faucet of the faucet of the accessory, and the distribution apparatus of the reactor facility of the nuclear power plant installed in the sea,

(Sluice valve), stop valve, glove valve, angle valve, check valve, and reduction valve are used to control the fluid and flow rate of steam or water. A reducing valve, a cock, etc. may be used depending on the purpose of use.

Table 2-1 shows the valve configuration, Table 2-2 lists the valves, and Table 2-3 lists the (KS) specifications of the valves.

<Table 2-1> Configuration of valve

<Table 2-2> Classification of Valve

<Table 2-3> Valve KS specification list

As shown in FIG. 3E, the following describes the slew-valve device in the disaster prevention preventive control section connection structure of the nuclear power plant section 811

The valve is also referred to as a gate valve 296 by opening and closing the valve by a screw bar in parallel with the cross section of the pipe. When the valve is fully opened, the resistance of the fluid flow is very small compared to other valves. Fluid is not left in the valve chamber, the diameter is usually 50mm or 1,000mm, and the large size is operated by power. However, there is a drawback that the valve is expensive and takes time to open and close the valve. Therefore, when the diameter of the water pipe of the power plant 267 and the water pipe of the water supply pipe are large and it is not necessary to frequently open and close the valve, various accessories formed on the slow valve valve 403 are attached, The valve 403 is connected to the valve cover 405 and the slow valve 406 by the packing press 407 and the packing press nut 408 as shown in the figure, The valve seat 409, the handle 410, the handle nut 411 and the packing 412 are attached.

As shown in FIG. 3E, in the specification table of the slow valve on the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811,

The kind of the slew valves includes a wedge gate valve, a parallel slide valve, a double disk gate valve, a wiping valve, and the like depending on the structure of the disk.

As shown in FIG. 3E, in the apparatus configuration of the wedge gate valve 413 in the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811,

The wedge gate valve 413 is divided into a single valve 414 and a flexible valve 415.

As shown in the figure, the unit type is a wedge-shaped valve, and the angle of the wedge is usually 6 ° to 8 °, while the bronze small valve has a wedge angle of 8 °.

As shown in the figure, the flexible valve 415 is provided with a groove at its center, so that the flexible valve 415 absorbs the influence of heat on the valve seat in the high-temperature pipe or the like by using the flexible.

Second, in the device configuration of the parallel slide valve 416,

The parallel slide valve has a spring inserted between two parallel valve bodies so that the valve is pressed against the valve seat by fluid pressure.

As shown in FIG. 3E, there is a gap between the valve body and the disk in the disconnection prevention preventive control connection structure of the nuclear power plant 811, so that there is little friction on the valve side and is not affected by thermal expansion. .

The valve disc and the valve seat act as a slide, so the valve seat uses a hard metal. This valve is suitable for high temperature and high pressure when vertically mounted.

Next, in the device configuration of the double disk gate valve 417,

The wedge type valve is difficult to be completely opened and closed due to deformation of the valve seat due to frictional resistance and thermal expansion. In order to prevent this, the valve body is divided into two, and the valve disk is widened by the thrust of the valve step to press the valve seat against the valve seat.

The structure adopting the advantages of the wedge gate valve 413 and the parallel gate valve 416 has a relatively small influence on the deformation due to temperature and pressure.

As shown in FIG. 3E, a detailed description of the device configuration of the stop valve 418 in the disaster prevention preventive control connection structure of the nuclear power plant unit 811 is as follows.

It is called the glow valve that the inlet and the outlet are in a straight line according to the flow direction of the fluid and the angle valve is the angle of the inlet and the outlet. The connection method of pipe is screwed joint and flange joint method. The material is made of forged steel for bronze high temperature and high pressure when it is used for small medium pressure, and cast iron is used for large type. The opening / closing spherical surface of the valve has a flat sheet, a conical sheet, a spherical sheet, and a stud sheet, which have a large resistance loss against the flow of fluid and are prone to collect dust in the water bodies. This is the most widely used type of valve because it is easy to make valve and valve seat when the lift is small and the valve opening and closing is fast.

Valves and valve stems are connected by packing glands and valves and rods are in the form of cylinders.

The Y-shaped glow 419 is used for applications such as glow valves, and is designed such that the valve cylinder is inclined by 45 to 60 degrees with respect to the center line for the purpose of reducing the resistance.

The angle valve 420 has the same function as the glow valve 419, but is used to change the flowing direction of the fluid at right angles.

As shown in FIG. 3E, the needle valve in the connection structure of the preventive shut-off control part of the nuclear power generation facility 811 has a conical needle 15 to 16 mm used for flow control, (Bonnet) 422, the disk 423, and the lid-attaching valve seat 424 are attached to the valve body 421 as shown in the figure, The packing presser 429 and the valve presser 426 are pushed into the screw fitting 431 and the cover bolt 432 in the packing presser ring 429 and the packing presser 430 in the handle 427 and the cover fitting ring 428, A cover bolt nut 435 is attached to the pin bolt 433 and the pin 434 and a detent screw 438 is attached to the handle nut 437. A gasket 441 is attached to the washer 439 and the packing 440, Device.

3E, the specification sheet (flange type glow valve and angle valve) of the valve to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811,

As shown in FIG. 3E, the cock in the connection structure of the preventive control section of the nuclear power plant 811 is classified into a cock 1 type 443 and a cock 2 type 444, and a cock 1 type 443 are formed with a bronze threading main cock 445 and a bronze threaded gland cock 447 in a cast iron flange type gland type 446 and the cock 2 type 444 is formed of a trunk 448 and a four- (449). However, when the fluid flows in a straight line and the cock is rotated 1/4, the passage is opened completely, so that the opening and closing is fast. There are many cast iron and bronze materials, and small diameter low pressure springs are used for drainage.

The cock may be a one-way stream of two-way cocks and a two-way stream of three-way cocks.

The main cock is (a) fastened with a nut under the plug 458 as shown in the same figure, and the gland cock is pressed by the packing as shown in (b) and (c).

3E, the swing type check valve 452 and the lift type check valve 453 are connected to the check valve 451 of the connection structure of the nuclear power generation facility part 811 to prevent the disaster, It is used to automatically close the valve when the flow of the fluid flows in one direction. It has a swing type and a lift type.

3E, the swing type check valve 452 on the connection structure of the disaster prevention preventive control unit of the nuclear power generation facility unit 811 is opened and closed by rotating the pin 457, so that the frictional resistance Can be used for any piping that is less horizontal than vertical type.

The lift-type check valve 453 has a structure of a valve seat such as a glow valve. As shown in the drawing, the valve is vertically lifted by the pressure of the fluid. The lift of the valve is about ¼ of the diameter and the friction resistance against the flow is large. A check valve 451 is formed and a disk 456 and a disk pin 457 and a plug 458 are attached to the body 454 and the cover 455. The check valve

A check list

In addition, the lift type check valve 453 has a Sumorenski type which has a wing to mitigate the impact.

The check valve is designed to flow only in a certain direction, so pay attention to the flow direction of the fluid when installing. Bronze screw type of 10A or 15A or cast iron or cast steel flange type of 50A or 200A is used.

The control valve 459 is connected to the pressure reducing valve 460 and the safety valve 472 via the temperature control valve 477 and the temperature control valve 472 to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The pressure reducing valve (460) is installed between the high-pressure pipe and the low-pressure pipe so that the lift of the valve is braked by an appropriate device, the pressure on the high-pressure side And the pressure of the low-pressure side is kept substantially constant regardless of the change of the steam consumption amount and the change of the steam consumption amount.

The actuation of the valve is usually done with a bellows, diaphragm 463 or piston 127.

When the pressure ratio of the high-low pressure is within 2: 1 and the pressure ratio of the high-low pressure is exceeded, it is better to use the two pressure-reducing valves 460 in series to perform the two-stage pressure reduction. The structure is generally composed of an adjustment spring 468, a diaphragm 463, a pilot valve 464, a piston 127, a main valve 466, and the like as shown in the same figure.

3E, a secondary-side sensing hole 462 and a diaphragm 463 are provided in a pyrotechnic-operated pressure reducing valve (magnetic force type) 461 in a disaster prevention preventive control connection structure of the nuclear power plant 811, A main valve spring 467 is attached to the pilot valve 464 and the piston 127 and the main valve 466 and a screw-type (½~1½ inch) (2 to 6 inch) pressure regulating valve 471b and a flange type

3E, a spring type safety valve 473 and a relief type safety valve 474 are connected to the safety structure of the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811, And is separated into a Pope spring type safety valve 475 and a Pope type safety valve 476.

The closing mechanism of the fluid is the same as the glow valve 419 and the glow valve 419 is opened or closed by an external force. However, the safety valve is closed by the force of the spring on the external force sensor or the weight of the valve stem and the weight of the lever Is opened and closed.

As shown in FIG. 3E, the safety valve to the connection structure for preventing and preventing disaster of the nuclear power generation facility 811 is installed in a pipe for handling a pressure vessel such as a boiler and a high-pressure fluid, When the specified limit is reached, the internal energy is automatically released to the outside to keep the pressure in the container at a safe level at all times.

It is a safety device that must be attached to pressure vessels with large accumulation energy such as boilers. One type of safety valve is a relief valve. It is used as a valve connected directly to a pipe line of a pipe through which a pressure fluid flows, and is used for the purpose of warning while adjusting the pressure of the pipe constantly.

The performance of the valve is determined by the accuracy of the ejection pressure, the pressure at the ejection stop, the pressure difference in the ejection, and the ejection volume. When the valve is opened and the steam is spouted, the pressure at the inlet side is referred to as the ejection pressure, the pressure at the inlet side is referred to as the ejection stop pressure when the valve is closed, and the difference between the ejection pressure and the ejection stop pressure is referred to as the ejection difference pressure.

As shown in FIG. 3E, the temperature control valve 477 in the connection structure of the disaster prevention preventive control unit of the nuclear power plant 811 has the same configuration as the auto temperature control valve 477, It is an oto control valve which is opened and closed by the action of bellows which is very sensitive to temperature change and automatically adjusts the flow rate of heating steam or cooling water. It is used for heat exchanger and heavy oil heater.

3E, an automatic level regulator 480 is additionally formed in the automatic water dispenser 479 in the disaster prevention preventive regulating connection structure of the nuclear power generation facility unit 811. The automatic water leveler 479 and the regulator 480) is to automatically level the level of the autosappler boiler to its maximum efficiency point, where the level difference is always derived at abundance, thereby preventing the risk caused by the shortage of the boiler water supply.

3E, the ventilation valve 481 belonging to the regulating valve 459 to the disaster prevention preventive control connection structure of the nuclear power generation facility unit 811 is provided with an oto-air exhaust valve thermostat (for steam, 533 mm x 68 mm, 483) to the dimensions of the exhaust valve (width x length; 53 mm x 56 mm, 482) And the air vent valve for the air is either an inferior type or a thermostatic float type, and a float type valve is adopted as a warm air vent valve. The fuselage is made of bronze bronze, bronze bronze, and brass.

3e, a float valve 484 belonging to the refrigerant stop valve 485 and a pack valve 486 belonging to the refrigerant stop valve 485 are connected to the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811, (Diaphragm type) 488 is formed by a refrigerant stop valve 485 and a diaphragm type expansion valve 490 and a bellows type expansion valve 491 are formed in the expansion valve 489 And is formed as a refrigerant pipe valve 484 integrally with a solenoid valve 492 and a pressure regulating valve (for refrigerant 493) integrally with a solenoid valve 494 and an oto water feed valve (not shown).

As shown in FIG. 3E, the emergency valve 486 belonging to the refrigerant stop valve 485 and the valves 487 and 488, which are connected to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The valve 485 has a structure of a valve seat and a valve seat similar to those of the above-described glow valve. In order to prevent refrigerant from leaking from the valve body side through-passages, a ground packing type (phone net type) And a diaphragm type in which a shaft is sealed by a diaphragm and a diaphragm type which is sealed by a bellows and can not be manufactured by a bellows or a diaphragm. The Grand type has all shaft caps (bonnets, caps) and is now mostly packed type to prevent the exchange of bellows, packs or packing tightenings, and to prevent leakage when the valve is opened.

As shown in FIG. 3E, in the connection structure of the disaster prevention preventive control section of the nuclear power generation facility 811, the large body is a pouring agent or a cast iron agent, The sheet is made of Nerunel metal.

Valve material should be harder than valve seat material to prevent abrasion.

The expansion valve 489 is formed by separating the diaphragm-type expansion valve 490 and the bellows-type expansion valve 491

Generally, the installation of conventional nuclear power plant's nuclear reactors installed according to the installation location of the inland river in the global village and coastal area of the coast is very weak in safety from natural disasters and the nuclear power generation operation is stopped or the nuclear power plant is exploded, , So that once the companies manufacturing these reactors have met the requirements of the containment vessel corresponding to the fourth wall of the recently developed reactor to meet the reliability of the power consumer and the fifth wall A plurality of through holes are formed at a predetermined angle of 45 ° in the upper part of the nuclear reactor building, and a machine cutter and a construction machine crane and a conveyor are machined in a drilling machine and a cutting machine rotary lathe machine. A number of safety valves are connected to the bolt and nut on the block piping line. The nuclear waste treatment storage block tanks and the radiation type connection structures are constructed in eight double structure block tanks each having a diameter twice the diameter of the reactor building along the circumference of the outer wall of the nuclear reactor building. Nuclear safety and economics are very severe and dangerous Reactor facility design process has been exposed and nuclear power safety and economics to recover the reliability of power consumers. Nuclear Radiation Leakage Control for the Equipment Nuclear Reactor Suitable for the Double Structure Block Tank Reactor Dust Collector The need to install nuclear waste disposal shielding device has been urgently required and the design and experiment for the safety and economical solution have been continued and research Global Nuclear Power Plant Nuclear power plants with multiple reactors Nuclear power plants Nuclear reactors for reactor shielding Nuclear radioactivity leakage control Dual structure block tank Dust collector Nuclear power plant forming a distribution device Nuclear power plant Nuclear power plant with double structure block tank for nuclear waste treatment Nuclear power plant with nuclear reactor Much effort has been devoted to finding the reactor design process.

However, since the demands of those skilled in the art have become more diverse, and a serious risk level has been expressed in terms of nuclear safety and economy, in order to solve the desire to recover the reliability of electric power consumers, nuclear waste treatment double structure block tank reactor Nuclear Radiation Leakage Control of a Nuclear Power Plant with Nuclear Power Plant Dual Structure Block Tank Nuclear Reactor Corresponding to the Fourth Walls of the Nuclear Reactor and the Nuclear Reactor Corresponding to the Fifth Wall A plurality of penetrating The hole is machined by a computer cutting machine, a construction machine crane and a conveyor in a drilling machine and a rotary machine of a cutting machine, and a block pipe line of a double pipe structure is formed in the plurality of through holes, while a plurality of safety valve connection structures are connected to a double pipe structure block pipe Gaskets rubber packing in bolts and nuts in line The flange connection structure is equipped with a hand tool hammer and a wrench and at the same time a double space structure block tank having a diameter twice the diameter of the reactor building along the circumference surface of the nuclear reactor building is provided with an empty space for a nuclear waste treatment storage block tank The double pipe structure piping line with multiple safety valve connection structures constituting a double pipe structure piping line in a plurality of through holes is provided with a radiation type connection structure and a plurality of reactor facilities of a marine power plant floating plant nuclear plant. Waste treatment shielding device and nuclear waste treatment for nuclear power plant Double structure block tank A double structure block reactor of a nuclear power plant equipped with a dust collector is a construction machine and a construction machine for the foundation of a floating power plant of a marine power plant Marine tunnels formed by replacing marine vessels The floating power plant of the marine power plant composed of the distribution device of the transportation device operates the nuclear plant power plant of the floating power plant of the marine power plant by operating the nuclear power plant nuclear reactor plant of the marine power plant at the sea bottom easily, The reactor main body of the nuclear power plant having the double structural block tank dust collector for the nuclear power generation nuclear waste disposal is constituted so that the safe operation of the nuclear reactor nuclear plant can be further performed by further inputting the barge hull position movement control device and the throttle control device.

A plurality of nuclear reactor facilities for nuclear power generation of the prior art, which are installed in the reactor main body of a nuclear power plant having the double structure block tank dust collector for treating nuclear waste, provided with nuclear energy will be described.

The conventional water reactor having various water reactors for nuclear power generation according to the prior art is formed of a boiling water reactor system 802 and a pressurized water reactor system 803, and a power reactor is mainly used for a light reactor Other than that, a gas cooling furnace reactor facility 804, a multi-purpose high temperature gas reactor facility 805 and a new conversion furnace reactor facility 806 are used. The boiler water reactor reactor facility 802 and the pressurized water reactor facility 803, A gas cooling furnace reactor installation 804 and a multi-purpose high temperature gas reactor installation 805, a new conversion furnace reactor installation 806 and a high-speed proliferation furnace installation 838, Level nuclear power plants.

Not only are the reserves of uranium as a raw material of nuclear energy limited, but also there is nuclear energy as an energy source that causes pollution less than fossil fuel. Therefore, this nuclear energy is attracting attention as a new power source in the future. The more serious problem is the disposal of nuclear waste.

Environmental pollution caused by nuclear waste can fatally destroy our only earth.

So, we have come up with a way to get energy without pollution, and today we want to get the answer from the sun and the sea.

There are many ways to get energy from the ocean. Tidal power to obtain energy using tidal and tide movements, Wave power to obtain energy using the power of waves, Sea water temperature to obtain energy using the temperature difference of seawater. By using various methods, we can provide an unlimited amount of pollution-free energy at sea.

The double structure block tank of the nuclear radiation leak control nuclear reactor construction for inserting into the nuclear reactor reactor double structure block for the treatment of nuclear waste tank In various types of reactor facilities of a nuclear power plant having a dust collector,

Nuclear power plant nuclear waste treatment double structure block tank Various kinds of reactor facilities of nuclear power plants equipped with reactor dust collectors are equipped with transport materials for control of nuclear fuel explosion prevention control to store and shield nuclear radioactive pollutants from outside the reactor. Using the shielding concept of in-depth defense concept of Nuclear Safety Engineering, it is possible to prevent leakage of nuclear fuel radiation and prevent nuclear explosion from outside of dual structure block tank dust collector. Prevention of nuclear fuel radiation leak and primary fuel explosion prevention. Double structure block tank reactor The nuclear waste treatment is controlled to the inside of the nuclear power plant, and at the same time, the secondary structure is composed of a plurality of nuclear reactor facilities of a nuclear power plant having a double structure block tank reactor dust collector, Outside of double structure block tank dust collector It is equipped with dual pipe structure block piping to control nuclear waste treatment, as well as dual pipe structure block piping system, including a pressure sensor sensor and a water pump connection structure to efficiently improve the operation of the nuclear power plant. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Which is equipped with a safety valve and water pumps to generate soap bubbles contained in cooling water. It uses a nuclear waste disposal device, which converts the energy of water into kinetic energy, Of a nuclear power plant equipped with dual structure block tank dust collector The facility is a double structure block tank. It is a connecting structure composed of the outer surface of the outer wall of the former reactor building in the form of an egg. It has a double structure block tank for the treatment of nuclear power generation nuclear waste. Operation of Nuclear Power Plants in Land and Ocean Nuclear Power Plants to Improve Operation of Nuclear Power Plants Having Significant Difference Between Nuclear Reactor Facilities and Nuclear Power Plants Having Nuclear Radiation Leakage Control of Nuclear Waste Treatment Shielding Equipment Is generally equipped with double pipe structure block pipes having the potential energy of water and is equipped with a safety pressure sensor and water supply pumps to generate cooling water and soap bubbles, In the form of a structural capsule, along the circumference of the outer wall of the former reactor building The reactor structure of the nuclear power plant equipped with the double structure block tank dust collector for the nuclear power generation nuclear power generation is manufactured, and it is manufactured at a remarkable difference from the reactor facility in which the existing nuclear fuel cell explosion occurred.

The present invention relates to a nuclear power plant having a double structure block tank dust collector for collecting all of a plurality of nuclear reactor facilities for nuclear power generation of the prior art, 672 of the present invention will be described with reference to the drawings as follows.

Referring to FIG. 1, there is shown a schematic diagram of a conventional boiling water reactor (802) nuclear power plant showing an essential constitution of a conventional boiling water reactor plant nuclear power plant according to an embodiment of the present invention. Nuclear Reactor Facilities (802) Outline of Nuclear Power Plant Side Lateral Construction Road,

As shown in Fig. 1, the conventional boiling water reactor equipment 802 constituted from among various types of reactor facilities of the conventional nuclear power plant 672,

The reactor structure of a nuclear power plant according to the prior art has a structure in which the five-folded protective walls are formed in a closed structure, and explosion occurs in any one of the five-folded protective walls. If the number of neutrons is large, When the energy exceeds the danger level and then a boiler reactor that exploits the fission chain reaction in an ideal state explodes, it can be recognized that the boiling water reactor (BWR) It is a reactor that can use water as a moderator and coolant and boil it to directly drive the turbine of the generator. The steam void in the moderator caused by boiling has a negative reaction effect. Half of positive The output of the reactor can be suppressed by controlling the flow rate of the cooling water by changing the flow rate of the cooling water in addition to the control rod. The boiling water reactor (802) power plant is simple in system, Can be said to be an easy plant.

The suppression of the output of the boiling water reactor assembly 802 is controlled not only by the control rod 798 but also by changing the flow rate of the cooling water 287 so that the output of the boiling water reactor assembly 802 is suppressed by the recirculation flow rate control system, Water reactor facility (802) The power plant is composed of a power plant with simple system and easy operation control.

Referring to FIG. 1A, a reactor boiler 688A and a turbine building 688A, which illustrate a conventional boiling water nuclear reactor nuclear power plant internal structure showing an essential constitution of an embodiment formed by a conventional boiling water reactor plant nuclear power plant according to the present invention, A diagonal configuration of the waste building 688G in the diesel generator building 688E and the nuclear fuel building 688F in the control building 688C and the auxiliary building 688D in the building 688B,

1A, a reactor building 688, which constitutes one embodiment of a conventional boiling water nuclear reactor nuclear power plant, includes a control building 688C and an auxiliary building 688D in a reactor building 688A and a turbine building 688B. (688E) in the diesel generator building (688E) and the waste building (688G) in the nuclear fuel building (688F) to provide an easy connection control structure for operation of the boiling water reactor (802) of the nuclear power plant (672) And a power plant.

Hereinafter, as shown in Figs. 1A to 1D, the constituent elements of a conventional boiling water nuclear reactor nuclear power plant according to an embodiment will be described as follows.

Referring to FIG. 1B, there is shown a conventional boiling water reactor (802) nuclear power plant according to an embodiment of the present invention. As shown in the figure,

      Referring to FIG. 1C, there is shown a schematic view of an elementary boiling water reactor plant nuclear power plant according to an embodiment of the present invention, which is constituted by a conventional boiling water reactor plant nuclear power plant, road,

       Referring to FIG. 1d, there is shown a side view of a conventional boiling water reactor plant nuclear power plant showing an essential constitution of one embodiment formed by the operation of a nuclear power plant of a conventional boiling water reactor plant nuclear power plant according to the present invention As a result,

       As shown in FIG. 1B, a conventional boiling water nuclear reactor (802) nuclear power plant is formed by a conventional boiling water reactor (802) nuclear power plant. The following describes the main structure inside the 1100 MWe boiling water reactor pressure vessel 813 as follows.

The boiling water reactor (802) is the first commercial reactor developed. The boiler water reactor (802) has a capacity of 1.2 million KW and the capacity of the boiler water reactor (802) Unlike the facility 803, the steam generator 810 is not required, but the steam 780 containing the radioactive material circulates to the turbine 267, A steam separator 818 and a steam dryer 786 are disposed on the core 791 and a steam guide 786 and the like are disposed on the core 791 composed of the assembly body 671 and the control rod 798. A control rod guide tube 798e And a control rod drive housing 798a. Around the core 791, there are a core shroud, a jet pump 325, and the like.

     The fuel assemblies 671 of the boiling water reactor equipment 802 are arranged in a square lattice of 88, for example, a total of 64 such as 62 fuel rods 689, one spacer supporting water rod and one water rod, It is surrounded by a zircalodian channel box.

     The fuel rod 689 has a structure in which a uranium hexafluoride fuel pellet 683, a plenum spring or the like is loaded into a zircaloy cladding tube 682, helium 176 is sealed, and both ends are welded and sealed with a plug. The plenum is a space that accommodates the fission product gas discharged from the fuel pellets in accordance with combustion and is set such that the internal pressure of the fuel rod 689 is not excessive.

     The control rod 798 of the boiling water reactor has a crisscross blade to move through the gap formed by the four fuel assemblies 671 and the control rod 798 is provided with a boron carbide B4C Hafnium (Hf), or other types using them in combination.

     Below the control rod 798, there is a falling speed limiter having an umbrella-type structure in order to limit the falling speed of the control rod 798 when the drop occurs.

      In addition, there is a socket for coupling with the control rod drive mechanism.

     As the drive mechanism for the control rod 798, there are a hydraulic lubrication type and an electric drive type. In both systems, the nitrogen gas pressure stored in the accumulator is used for rapid insertion of the control rod 798. However, The entire control rod 798 is inserted into the core 791 at the lower part of the core 791 to stop the reactor installation.

Since the boron-containing water injection system capable of stopping the reactor installation can be installed even when the entire control rod 798 can not be inserted, the boron absorbs the neutrons 675 well. Boron-containing water is stored in the tank, 791).

1C, the carbon steel containment vessel 808 to the boiling water reactor installation 802 has a steel thickness of 3 cm, the pressure vessel 813 has a steel thickness of 16 cm, and a concrete hangar (reinforced concrete) 225 has a thickness of 200 Cm &lt; / RTI &gt;

First, in the control of the output of the boiling water reactor installation 802, the boiling water reactor installation 802 uses the hard water 654a as the moderator 676 and the coolant 816, (Void) generated in the moderator 676 by boiling in addition to generating steam of about 70 kg / cm 2 under pressure, and the hard water 654a is used to control the use of light water, that is, ordinary water It says.

      Secondly, when the control rod 798 is drawn out, the reactivity of the reactor increases and the output increases.

     Thirdly, when the boiling is promoted and the void is increased, the density of the moderator 676 is decreased, and the deceleration efficiency of the neutrons 675 is lowered, so that the negative reaction is applied.

     In the fourth case, when the reactivity of the positive and the negative reactivity generated by the withdrawal of the control rod 798 are balanced, the reactor output is stabilized.

     In the fifth case, when the control rod 798 is inserted, the opposite phenomenon occurs. Therefore, as the void decreases and the density of the moderator 676 increases, the efficiency of decelerating the neutrons 675 increases and a positive reactivity is applied to the reactor .

     In the sixth case, when the reactor is balanced with the negative reactivity applied by the control rod 798, the reactor is stabilized at a new output. Thus, the boiling water reactor assembly 802 has self controllability by voids.

     Next, the heat generated in the fuel rod 689 in the core 791 is transferred to the coolant 816.

     Next, in the boiling water reactor installation 802, heat transfer in the boiling region is utilized.

     In the ninth, the size of the heat flux flowing due to the temperature difference between the heat transfer surface and the coolant 816 is obtained in a lot of experiments, and in the transition boiling region where boiling is vigorous, the heat transfer is lowered so that the fuel covering material 681 may be burned The operation is restricted so as not to reach the transition boiling region during normal operation and during operation and during the operation.

     The heat generated in the fuel rod 689 is transferred to the coolant 816 in the tenth.

    Since the cooling water 287 is recirculated and the flow rate of the cooling water 287 is increased to increase the flow rate of the refrigerant flowing through the core 791, (816) recirculation system is provided.

     The twelfth one is that when the reactor installation is combined with the turbine generator 772, the reactor installation output can follow the turbine load.

     In the boiling water reactor installation 802, if there is a change in the load at the final stage, the control device 798 first adjusts the reactor installation output by increasing or decreasing the flow rate of the insertion or recirculation of the control rod 798.

     In this state, when the output of the reactor installation and the load are shifted, the pressure of the reactor installation increases or decreases.

    Thus, the pressure of the reactor facility is controlled by adjusting the opening of the turbine add / drop valve.

     This method is called "(Reactor Master / Turbine Slave) reactor facility priority system".

     When the turbine 267 stops abnormally, the flow of the steam is interrupted to increase the reactor installation pressure, but the bypass valve of the turbine 267 is opened to suppress the increase of the reactor installation pressure.

     As shown in Fig. 1d, the engineering safety system in the boiling water reactor facility 802 will be described as follows.

     If the cooling water 287 of the core 791 is lost due to a breakage accident in the piping of the reactor cooling system, (ECCS) is installed in order to prevent the damage of the fuel. This system is composed of a high pressure core sprinkler system, an automatic decompression system, a low pressure core sprinkler system and a low pressure injection system, It is connected to engineering safety systems.

     If a fuel breakage occurs, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

     However, it is also true that there is a problem to be considered, such as the operation of the power plant by enlarging the operation of the boiling water reactor (BWR, 802), and the securing of personnel related to these power plants equipped with maintenance and maintenance, As a long-term task of nuclear power in the future, it is thought that the construction of the nuclear power plant concept that is close to Siam is necessary for the next generation reactor considering social acceptance due to the lack of workers' resources. do.

     In the following, the study of the simplified boiling water reactor (BWR, 802) is based on the concept of SBWR (Simplified BWR) (600 MWe) (BWR, 802), a combination of a static containment system such as a static containment vessel cooling system and a gravity falling ECCS, including a 1000 MW expansion, and a natural circulation core. (BWR, 802), which is composed of a large natural circulation core, a static containment vessel cooling system, and a gravity falling type ECCS, (791) can eliminate the current BWR recirculation system, the recirculation pump (239) and the MG set and connection to it (BWR, 802), it is necessary to meet the problems and necessity of natural circulation establishment in order to realize the research of simplified boiling water reactor (BWR, 802) That is, the problem of response to output control remains.

     Second, the static containment vessel cooling system of the simplified boiling water reactor (BWR) 802 eliminates the decay heat of the core 791 after an accident for a long period of time, and various designs have been proposed. However, I / C (Isolation Condenser), which is a condensation heat transfer method using a water-immersion type insulation tube, which has high applicability to the furnace, has been selected.

     Third, the static safety system such as the gravity-drop type ECCS of the simplified boiling water reactor (BWR, 802) has an emergency power supply to the core 791 in case of an accident, Power is not strong. However, the continuous drive system and the complex network of conventional pumps, motors, valves, piping, and auxiliary machinery systems together with the above-mentioned static containment cooling system are greatly simplified, which reduces human factors related to operation. (791) irrigation is possible by reflecting the interpretation result of the accident such as water supply pipe breakage etc. To the full capacity and the applicability of this method is suggested.

     Hereinafter, the following directional description of the simplified boiling water reactor installation (BWR, 802) will be described as follows.

     In the simplified BWR, since a large amount of water such as the pressure control pool 240 as the source of the ECCS is installed on the upper portion of the containment vessel, the center has become higher and the containment vessel 808 has been severely subjected to various tests. have.

     As described above, since the elementary technology of the simplified BWR is a good step to confirm its conformity, the static simplification is starting from the existing concept that it is intimate to the person and it can be suitable for the social situation of the world in the future Potential technologies are provided.

     Uranium 235 (812), plutonium 239 (801), and neutrons 675 in the nuclear reactor (BWR) 802 operation of the boiling water reactor (BWR) 802 are mixed to prepare a mixed reaction of atoms and other atoms with the neutrons 675 However, since the generated neutrons 675 become triggers for generating the above-described reactions, they are called chain reactions. In the end, the control of the neutrons 675, that is, the control of the chain reaction, to be.

    The core 791 melting and nuclear meltdown in the boiling water nuclear reactor facility (BWR 802) operation includes the dissolution of the fuel assembly 671 and the core 791 structure by nuclear fuel overheating, The spent fuel rod 689 is exposed to the air when the cooling water 287 is not present, or the fuel rod 689 exposed to the air is overheated while the temperature rises, Radiation leakage becomes inevitable.

     In the case of the conventional boiling water reactor (BWR, 802) operation of the above-mentioned nuclear power plant, in 1986, when the Chernobyl accident occurred, the radioactive water vapor rose to 30,000 feet (9144 m) and suffered a long time. At worst, At the same time, the amount of uranium 235 in the spent fuel was less than 1%, so the radioactive efflux was possible. However, because there was no possibility of a nuclear explosion, the nuclear fuel rod (689) It took 6 months to cool down, and at the same time, when the temperature exceeded 2,000 degrees centigrade, radioactive materials such as cesium and iodine contained in the fuel rod (689) provided vaporization. At the same time, zirconium and water vapor were mixed, And the hydrogen generators are used as the coolant 816 to provide a temperature control of a conventional boiling water reactor facility 802 Or

     Referring to FIG. 1E, the operation of the nuclear reactor of the Fukushima boiling water reactor system before the accident, which shows the essential constitution of one embodiment formed by the operation of the nuclear power plant of the conventional accident-occurred Fukushima boiling water reactor plant nuclear power plant, Elementary Boiling Water Reactor Facilities as shown in Fig.

     As shown in Fig. 1 (e), the operation of the nuclear reactor of the boiling water reactor (802) is a boiling water reactor (BWR) type in which the steam of water boiling in the core is directly sent to the power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

     However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats did not disclose detailed information, refused to provide US technical support, and at the same time, they poured seawater into a wreckage and drove fire trucks and helicopters into the building.

     Due to this method, various impurities mixed with seawater were converted into radioactive isotopes and contaminated, and the contaminated seawater evaporated, spread to the surrounding area, and flowed into the sea and contaminated vast areas with radioactivity.

      Hiroshima, Nagasaki Japan, which has been devastated by the atomic bombs, has ironically built many nuclear power plants. On March 11, 2011, an earthquake and tsunami hit the northeastern part of Japan, causing the Fukushima nuclear plant to melt its core and leak radioactivity.

     Referring to FIG. 1F, there is shown a conventional boiling water reactor (802) nuclear power plant having a boiler water reactor (802) showing the essential constitution of an embodiment formed by the operation of a nuclear power plant, As a side view,

       As shown in Fig. 1F, the operation of the boiler-type nuclear reactor 802 is controlled by the nuclear waste in the nuclear reactor 802 and the spent fuel rods 689 in the boiler- Substances that have undergone a reaction. Concentrated plutonium, and enriched uranium. Exposure to air causes a fission reaction and releases radioactive material. The zirconium coating on which the fuel rod is packed is oxidizing, causing a fire. Radioactive materials can spread to the atmosphere due to fire.

     At the time of the Soviet Chernobyl Nuclear Power Plant explosion in 1986, when the nuclear reactor of the boiling water reactor facility (802) started to operate, a military helicopter was used to shield a huge amount of radiation from nuclear fuel and graphite moderator (676) 2,400 tons of lead, 1,800 tons of sand and mud. The boron compound was to absorb the neutrons that caused the chain reaction, while the lead and mud were to shield the radiation.

     The safe operation of the nuclear reactor facility of the boiling water reactor 802 is limited to the deceleration of the coolant 816 and the neutrons 675. The nuclear reactor coolant of the Dreamy Island, Chernobyl, and Fukushima nuclear reactors The uranium fuel rod 689 can not be cooled with water and is exposed to the air and melted. When the uranium fuel rod 689 melts, Uranium flows out and risks increase.

     In this situation, the Drill Mile Island nuclear power plant of the boiling water reactor facility 802 is sprayed with boric acid water by the emergency sprayer installed above the nuclear reactor building 688 and the emergency cooling water 287 is restored. Fortunately, Respectively.

Referring to FIG. 1G, a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional pressurized water reactor type nuclear reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1G, the operation of the nuclear power plant of the pressurized water reactor (803) is performed by supplying water to the pressurized water reactor (803) through water stored at a high pressure And is a pressurized water reactor 803 in which heat is transferred from the core to the steam generator 810. The steam generator 810 provides a turbine 267 operation to produce electricity, while the pressurized water reactor type reactor 803 is the most widely used nuclear reactor facility in the world. The pressurized water reactor or water- It is also referred to as a type pressurized water channel.

      In the pressurized water reactor type nuclear reactor facility 803, the hard water of the coolant compilation is firstly used in the PWR for the designing and editing of the pressurized water reactor, but in the primary system, it is provided at about 315 degrees Celsius, (654a) at 2000 psig and 15 MPa and a pressure of 150 times the atmospheric pressure do not boil while at the same time the water in the primary system is in the secondary system in most designs, the temperature is 275 degrees Celsius and the pressure is 900 psig The water flowing at a pressure of about 6.2 MPa is made into steam and sent to the steam turbine 267.

     In the case of the commercial pressurized water reactor type reactor installation 803 of the pressurized water reactor type nuclear reactor 803, the amount of the coolant 816 is constant, but the reactor can adjust the flow of the coolant 816, Neutrons 675 are provided in a reactor and have a shape similar to that of a thermal reactor design. However, many water molecules are the same size as the neutrons 675, and when colliding with the neutrons 675, neutrons 675 While the neutron "deceleration" is better with a higher molecular number of the water molecules, while the pressurized cooling water 287 has a structure in which the hydrogen atoms in the water molecules control the velocity of the neutrons 675 The use of water is one of the main safeguards of light water reactors, consisting of a neutron reduction structure that regulates the speed of water as it rises and the density of water molecules is lowered, If the neutron (675) deceleration structure has a lower void effect and at the same time the reactor malfunctions, the deceleration rate of the neutrons (675) becomes lower, the neutron (675) deceleration structure becomes lower, The inherent stability is very stable in a pressurized water reactor type reactor (803).

     The pressurized water reactor (PWR) facility is a nuclear reactor facility that uses water as coolant and moderator for pressurized water reactor pressure. The name of this reactor facility is the name of the internal circulation system, The pressurized water reactor facility is the most common reactor facility in the world. About 230 nuclear reactors are used for power consumption and hundreds of reactors are used for propulsion. Korea's standard pressurized water reactor facility (803) is constructed in Koryeong Gwangseong.

     In the early days of editing, the Westinghouse Betis Lab developed a military pressurized water reactor (803) at Westinghouse.

     In the United States, the pressurized water reactor facility (803) program operated the reactor from 1954 to 1974, but the first two pressurized water reactors (803) operated the TMI-1 and TMI-2 At this time, the construction of the new power plant was stopped due to partial core melting in TMI-2 in 1979, and at the same time, the core and fuel assemblies of the pressurized water reactor facility 803, the control rod and the pressure vessel 813, 658), a primary system, a secondary system, a condenser, a turbine and a generator connection structure, and the pressurized light water reactor provides a reactor chain reaction operation.

     In the pressurized water reactor (PWR) facility, it is delivered to the primary system circulating between the fuel and the heat exchanger 658. The primary heat system, called the primary system hot steam generator 810, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser 790 and at the same time enter the steam generator 810 again while at the same time the turbine 267 of the secondary system provides power production in connection with the turbine generator 772, (PWR, 803) facilities are compared with two pressurized light water reactors and other reactors. In a pressurized light water reactor, there are two cooling water primary systems and a secondary system Gt; 267 &lt; / RTI &gt; Frequency electric power production arranged in connection with (772) and or, at the same time, the two flows of water (hard water). In contrast, in a boiling water reactor (BWR), there is no strain.

Referring to FIG. 1H, a conventional pressurized water reactor type nuclear reactor (803), a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant operating at a nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, As an elemental aspect of the operation,

As shown in Fig. 1H, in the pressurized water reactor type nuclear reactor (803) nuclear power plant, the water pressure of the coolant compilation is changed from the PWR to the first However, in the primary system, it is provided at about 315 degrees Celsius, and at the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light valve 654a at a pressure of 150 times the air pressure does not boil, In the primary system, water is sent to the steam turbine (267) in most designs, with water vapor at 275 degrees Celsius and 900 psig at 6.2 MPa.

     The stability of such a pressurized water reactor type reactor (803) is such that when the pressurized water reactor is provided with a very stable production, but when the RBMK (graphite reduction speed boiling water pressure tubular reactor) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, they are heated and sintered. However, at the same time, the production of ceramic pellets made of uranium dioxide is carried out. (Zirconia), helium is injected into the zirconia rods to help heat transfer, but the finished fuel rods are bundled with bundles of fuel-fuel assemblies, which are called aggregate bundle fuels, It is loaded.

    It is very important to prevent a chain reaction from occurring in the core of a nuclear reactor facility that does not allow a rapid chain reaction in a pressurized water reactor (803) of the nuclear power plant of the nuclear power plant. However, when the chain reaction occurs, , Or 200 to 300 fuel rods of a pressurized water reactor, 150 to 250 fuel assemblies, or simultaneously enter uranium at 80, It is maintained at 14X14,17X17 pieces of about 100 tons.

     The pressurized water reactor (803) fuel bundle of the nuclear power plant operating at the nuclear power plant is provided at about 4 meters, and at the same time, there are many pressurized light water reactors with many pressure vessel control of the pressurized light water reactor and many pressure vessel controls of the military primary pressurized water reactor Adjust it to positive.

     In the pressurized water reactor type nuclear reactor facility 803 for operating the nuclear power plant, since the neutron is absorbed immediately, the reactor system is controlled by reducing the chain reaction by the pressurized light reactor. Therefore, the control pump of the entire pressure relaxation system is included. Is to provide high concentration of neutrons in a large number of emergency stopping cooling water, but also CANDU is an auxiliary means to enable the boric acid to quench the chain reaction. .

     In addition, the control rod enters the fuel assembly from the pressure vessel and is usually used when the first nuclear power plant is started or when the nuclear power plant is shut down. At the same time, the fuel assembly is regulated to a height at the reactor plant, The fuel rod of the stabilized fuel pellets of the barrier wall and the first barrier pellet was burnt inside the radioactive material generated by the fuel rod. The second barrier wall was enclosed with the nuclear fuel pellets and put into a metal tube of a special alloy as a nuclear fuel rod The small amount of gas that is released is a reactor vessel provided with a 20 cm thick steel containing the nuclear fuel assemblies in the reactor vessel which is the third barrier wall at the same time to provide a seal to the second barrier wall.

     In addition, the shielded concrete wall, which is the fourth barrier wall, prevents the leakage of the radioactive material as a concrete wall surrounding the nuclear reactor facility. In the containment vessel of the fifth firewall, the safety system and the whole space At the same time, the biological shielding wall of the 5-1 barrier wall is provided with a final biological shielding wall as a thick building 70 to 100 cm outside the steel, and at the same time, It is a container and a dome form, and it is a safe nuclear building to prevent the leakage of radioactive material, but at the same time, it provides an external shielding of radioactive material in case of an accident.

     However, the Chernobile model, RBMK, with a graphite reduced-rate boiling water pressure tubular reactor (RBMK), has become increasingly unstable as the thermal response increases, but the choice of this graphite-slowing boiling water pressure tubular reactor (RBMK) .

Referring to FIG. 1I, a conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional nuclear power plant pressurized water reactor facility (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in Fig. 1 (i), in the pressurized water reactor (803) nuclear power plant, the operation of the nuclear power plant is such that during the pressurized water reactor installation (803) .

Uranium fission and reactor facilities As mentioned above, 99.3% of stable uranium 238 is contained in natural uranium, 0.7% of unstable uranium 235 which can cause fission, and at the same time, domestic nuclear reactor types are mainly PWR ) And pressurized water reactor (PHWR). At the same time, the water reactor is a type of conventional nuclear reactor (803) operated by Kori, Yonggwang and Uljin, mainly supplied by the United States. (H ₂ 0) as a moderator (676), which is a material promoting the fission reaction using concentrated uranium (U-235, 4-5%) as a fuel, and at the same time one year or one year and six months Once the reactor is shut down, the fuel must be replaced.

In the meantime, the heavy water type reactor is a type supplied from Canada, which is currently in operation in Wolsong. As a characteristic, the reactor is horizontal and uses natural uranium (U-235, 0.72%) as fuel, moderator (676) ₂ O) and a portion of the fuel can be replaced daily.

Referring to FIG. 1J, the conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant. In the conventional nuclear power plant, a pressurized water reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1J, the operation of the nuclear reactor of the water reactor (803) during the pressurization operation is the same as that of the pressurized water reactor In the comparison of water reactor equipment during pressurization, the distinction between pressurized water reactor (PWR) and pressurized heavy water reactor (PHWR) is rated power of 1 million kW and 70,000 kW. The reactor type is vertical type, and the pressure vessel is a horizontal pressure tube. The operating pressure is from 158.2 kg to 110 kg at the operating temperature of ~ 310 ° C and the fuel used is fuel for the use of low enriched uranium (U-235, 4 ~ 5%) and natural uranium (U-235, 0.72% 816) and moderator 676 (D ₂ O), and the period of preventive maintenance of the fuel replacement period is 1 year to 1.5 years. At the same time, Wolsung nuclear power plant in Korea is a Canadian type This reactor installation uses cheap natural uranium (about 0.7% U-235) as fuel and moderator (676) and coolant (816) as expensive heavy water D ₂ O) is used.

     If the heavy water of the water reactor 803 is boiled during the pressurization, the reactor installation system is pressurized to about 110 times to prevent boiling of the heavy water because the reactor 676 and the coolant do not act properly. Water heated to 300 degrees Celsius is sent to the steam generator 810 and then heated to heat water on the secondary side through heat exchange to generate a steam 780 for driving the turbine generator. At the same time, as in the case of the pressurized light water reactor, And the turbine equipment side are completely separated so that the secondary side is the same as the pressurized light water reactor type, and at the same time, the cooling side material (816), which is slightly different in shape from the primary side, Heating is provided by the heat generated by the fission through the inside of the equilibrium cylindrical reactor, while the pressurized light water reactor (803) provides the reactor with a vertical barrel The coolant 816 is circulated from the lower portion of the core 791 to the upper portion.

     Referring to FIG. 1K, the pressure of the pressurized water reactor installation 803 of a conventional nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional pressurized water reactor (803) Internal decomposition of the pressure vessel 813 of the water reactor installation 803 during elemental pressurization, shown as the internal decomposition side of the vessel 813,

      As shown in FIG. 1K, the operation of a nuclear power plant at the pressurized water reactor (803) nuclear power plant has a low probability of causing nuclear fission when natural uranium is used as the nuclear fuel. Therefore, it is necessary to separately install the moderator (676) system, which is a heavy water reactor which can sufficiently absorb the neutrons and contribute enough heat neutrons to the nuclear fission while effectively decelerating the high-speed neutrons generated during the nuclear fission. At the same time, Three of the nuclear fuel change are basic characteristics of the pressurized heavy water reactor.

     Referring to FIG. 11, there is shown a structural configuration of nuclear fission of uranium fuel 235 showing nuclear fission structure of nuclear fuel uranium 235 showing the essential constitution of an embodiment formed by operation of a nuclear power plant of a conventional nuclear power plant according to the present invention,

       As shown in FIG. 11, the structure of the nuclear fuel pellet 683 of the nuclear power plant constituting the reactor facility of the nuclear power plant having the double structural block tank dust collector for nuclear nuclear waste disposal is described in detail as follows I will explain.

      The electrons are composed of the nucleus 815 and the electrons surrounding the nucleus 815. The nucleus 815 is composed of a proton 674 and a nucleon 675, (815b) that are transversely driven by the coupling force between the two forces.

]쯤 이나 그 질량은 원자(784) 질량의 대부분을 차지한다.The radius of the nucleus 815 is about 10 ^-14 m and the neutron 675 of the nucleus 815 is electrically neutral and the mass is almost the same as the proton 674 and the diameter of the nucleus 815 is atomic 784)

], The mass occupies most of the atom (784) mass.

     The structure of nuclear power generation is the same as that of thermal power generation. Nuclear power generation also generates steam by rotating a steam turbine. Nuclear power generation and thermal power generation have different ways of generating steam. The thermal power plant rotates the steam turbine 267 by burning coal, oil and natural gas in the boiler 778 , The nuclear power generation generates nuclear fission in the reactor, and steam is generated from the heat to rotate the steam turbine (267).

      The structure of an atom or a helium atom is an atomic nucleus 815 in which a proton 674 and a neutron 675 are combined with each other. The atomic nucleus 815 refers to the amount of static electricity carried by the object of the electron 785, (+), The charge of the same sign repulses each other, and the charge of the other sign pulls each other.

The number of protons (674) in the nucleus (815) is equal to the number of neutrons (675). The number of protons in the hydrogen and isotopes of triple hydrogen is all one If the number of neutrons (675) combined with the number of protons (674) is called the mass number, the half life of uranium 238 is 4.51 × 10 ⁸ years, shorter than uranium 238.

      The atomic nucleus of uranium (815) is a model of a red bead, a neutron (675), which is a proton (674). Uranium 238 (uranium 238) and uranium 234 (isotope 234) are weighted according to the number of neutrons It is different. First, uranium 238 (653a) is the most abundant uranium, but unfortunately it can not fission. The following are uranium 235 (812) and uranium 234, which are only slightly contained in natural uranium, so it is uranium 235 (812) that is capable of fission.

      The atomic nucleus 815 formed by the collapse of the radiation nucleus 815 contains a property that it is unstable and stabilizes even a little bit. It is a natural collapse, that is, it becomes a stable atom by self-emission of gamma rays to alpha particles or beta particles. 235 (812) has the greatest property, so the main role of nuclear power is uranium 235 (812).

     This is because fission occurs in the form of collapse of radioactive materials.

     However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the electric charge of the atomic nucleus (815) of Ura 235 (812) is +. Again, when a proton having a charge of + is collided, it repels each other by the law of charge and tangles the proton 820.

      Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

      When the neutrons 675 collide, the uranium 235 breaks up into pale yellow barium or silver white barium which is well oxidized in the air and krypton is a slightly colorless odorless gas mixed with air, At this time, large energy is generated.

      Referring to FIG. 1m, there is shown a partial side view of a method of using a control rod for controlling a chain reaction of nuclear fuel fission in a nuclear reactor of a conventional nuclear power plant according to the present invention. And the lower drawing shows a reactor fuel production and a decomposition of the steam generator 810, the pressurizer 814, and the coolant 816 of the reactor steam take-off system 1073, which show the process of generating plutonium in the uranium 238, Straight configuration Road,

As shown in FIG. 1 m, the number of protons 820 in the nucleus 815 is equal to the number of neutrons 675. The isotopes of hydrogen, for example, are hydrogen atoms in water and deuterium. The number of protons (820) is the same as the number of neutrons (675). The number of neutrons (675) is different from that of hydrogen and heavy hydrogen. The number of neutrons (675) Speaking of the half-life of uranium-238 (679) is shorter than 4.51 × 10 ⁸ years of uranium 238 (679) in.

The atomic nucleus of uranium (815) is a model of a red bead, which is a neutron (675). The bean is a proton, isotope uranium 238 (679), uranium 235 (812) and uranium 234 is a neutron (675) Uranium 238 (679) is the most abundant uranium, and unfortunately, it can not be fissioned. Therefore, uranium 235 (812) and uranium 234 are contained only in natural uranium, which means that uranium 235 812).

The atomic nucleus formed by the collapse of the radiation nucleus 815 contains a property that it becomes unstable to become even a little stable. It is a natural collapse, that is, it emits gamma rays to alpha particles or beta particles and becomes a naturally stable atom 784. Uranium 235 (812) has the greatest property. So the main role of nuclear power is uranium 235 (812).

Because nuclear fission now occurs in the form of the collapse of radiation.

However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the charge of the atomic nucleus (815) of uranium 235 is +. Again impinging the protons 674 having a charge of + will repel each other and tie the protons 674 by the law of charge.

Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

When the neutrons 675 collide, uranium 235 (812) is split into a colorless odorless gas that is barely oxidized in air or krypton is slightly mixed in the air, provided that the barium is either pale yellow or silver white barium, There are three bounces, which generate a large amount of energy.

Originally, uranium 235 (812) absorbs slow neutrons (675), but the neutrons (675) that are fresh from nuclear fission can not catch the neutrons (675) because of their high velocity. In order to slow down the velocity of fresh neutrons from nuclear fission Or a heavy water or graphite moderator 676 having a larger molecular weight than ordinary water is used.

If the particles collide with heavy objects, the neutrons 675 are splashed out. However, if the particles are of similar size, the neutrons 675 will eventually fall into thermal neutrons 675 because they are splashed. The thermal neutrons 675 are not hot, And the neutron 675 having an energy of less than leV (electron volt) is called a heat neutrality. The neutrons 675 collide with another uranium 235 (812) to divide and collide, . 1e V to 1k e V are called low-speed neutrons (812), and 100k e V to 10M e V are high-speed neutrons (675).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons may be increased when the chain reaction is finished, but that is not so. If the number of neutrons (675) is high, the chain reaction becomes excessive, and the energy generated when the nuclear fission breaks out exceeds the danger level, and then the reactor of the nuclear reactor in which the fission chain reaction proceeds in an ideal state is exploded.

In order to prevent such an explosion, a control rod 798 made of cadmium is inserted and controlled to control a chain reaction of the fission in the reactor, but since the control rod 798 eats the neutron 675 generated from the fission, Which slows down the neutron 675. In nuclear fission, the speed and number of neutrons (675) are controlled by the end of the running horse.

When 1 k g of uranium 235 (812) is cleaved, neutrons (812) protrude from barium and krypton, and their mass is lighter than 1 k g of original uranium 235 (812).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons (675) is probably good after the chain reaction, but that is not it. If the number of neutrons (675) is too high, the chain reaction will be excessive, and the energy generated when the nuclear explosion occurs will exceed the danger level. If this happens, a nuclear reactor will be exploded that will progress the fission chain reaction in an ideal state. In order to prevent such an explosion, In order to control the chain reaction, the control rod 798 made of cadmium is inserted and removed, and the control rod 798 eats the neutrons 675 generated from the fission, so that the moderator 676 lowers the speed of the neutrons. In nuclear fission, the velocity and number of the neutrons (675) are controlled by the endothelium, and when one kilogram of uranium 235 (812) breaks down, neutrons (675) protrude from barium and krypton, 812) It is lighter than 1kg compared with 1kg.

According to Einstein's formula E = mc ² , this lighter mass is converted to the kinetic energy of barium and krypton and neutrons (675). In theory, a mass of 1 g is the same heat as when about 2150 tons of oil are burned together. In fact, the energy of 1k g of uranium 235 (812) is calculated as 20 billion kcal of energy. If it is gasoline, it is enough to make 500 rounds of cars by car, 300 tons for coal, and 2 million liters for oil One neutron (675) divides one uranium nucleus into two or three neutrons (675).

Referring to FIG. 1, a conventional gas cooling furnace reactor 804 according to the present invention includes a gas cooling furnace reactor 804 of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, (804) side-by-side configuration of the elementary gas cooling furnace reactor,

1N, in the structure of the gas cooling furnace reactor facility 804, graphite is used as a moderator 676, carbon dioxide is used as a coolant 816 in the gas cooling furnace in the structure of the gas cooling furnace reactor facility 804 And the use of natural uranium and enriched uranium 235 as the fuel and the use of carbon dioxide as the coolant 816. At the same time, the thermal efficiency and the thermal efficiency equivalent to the thermal power of the high-temperature and high- And at the same time, the structure of the nuclear reactor furnace facility 804 is configured to perform nuclear power generation.

A nuclear reactor facility using gas as a coolant 816 to the gas-cooling furnace reactor facility 804, a calderhall type of graphite-retarded natural uranium fuel type, carbon dioxide gas (CO ₂ ) as its reforming type, and a high temperature gas- (CO ₂ ) is supplied to the cooler 816 as a cooler hole type reactor, which is a nuclear reactor type reactor with a deceleration natural uranium fuel type reactor, and an improved version thereof, while using helium (He 176) The generic name of the reactor used by. The structure of a gas-cooled furnace reactor (804), which is a typical reactor cooling furnace reactor developed in the UK, using natural uranium as fuel, graphite as a moderator 676, carbon dioxide gas as a coolant 816, and the like.

     Referring to FIG. 10, there is shown a conventional gas cooling furnace reactor facility 804 according to the present invention, an elemental conventional gas cooling furnace reactor facility 804 showing the construction of an embodiment formed of a nuclear power plant, As a side view,

    1O, a gas cooling furnace reactor facility 804 formed by the nuclear power plant operation of the nuclear power plant is provided with a coolant 816 inside the reactor pressure vessel 813 of the gas cooling furnace reactor facility 804, And carbon dioxide gas is supplied from the carbon dioxide gas 164 and the coolant 816 provided in the gas cooling furnace reactor facility 804 The helium 176 is provided as a coolant 816 and at the same time the connection structure inside the reactor pressure vessel 813 formed by the operation of the nuclear power plant is connected to the recirculation pump 239 and the water feed pump 241, The steam 780 and steam are cooled in the pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689 and the steam pipe 779 and the steam pipe 779, Which is a cooling device of the apparatus for making the reactor 790, the core 791, A control rod drive housing 798a provided inside the heat exchanger 793 and the control rod 798, a control rod drive shaft 798b and enriched uranium 812, and a gas cooling furnace reactor facility 804 ) To make nuclear power.

      Referring to FIG. 1P, there is shown a constitution of an embodiment of a steam generator 810 of a conventional nuclear power plant reactor according to the present invention. One elementary nuclear power plant reactor generator steam generator (810) Side construction of connecting structure Road,

      As shown in FIG. 1P, the structure of the steam generator 810, which is formed by the connection structure of the steam generator 810 of the reactor plant of the nuclear power plant, includes a steam outlet 810a and a water supply nozzle 810b to the turbine generator, The cooling water 810c, the vibration suppression rods 810d, the tubular support pipe 810e, the tubular lid 810f, the tubule bundle 810g, the tubular steel plate 810h, the separation plate 810i, the primary outlet 810j, A steam generator 810n and a steam generator internal body 810o as a connection structure of a steam generator 810 of a nuclear reactor nuclear reactor installation. The steam generator 810a includes a primary inlet 810k, a heat exchange tube 810l, a cooling water passage 810m, The formed steam generator 810 facility structures include the recirculation pump 239 and the feed pump 241, the circulating water pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689, A pipe 779 and a steam 780 and a cooling device 780 for cooling the water vapor into water, A control rod drive shaft 798a and a control rod drive shaft 798b and enriched uranium 812 provided inside the core 791 and the reheater 793 and the control rod 798, And a reactor facility (804) for nuclear power generation.

Referring to FIG. 1q, a conventional multipurpose hot gas furnace reactor 805 of a conventional nuclear power plant showing an essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the nuclear power plant 805 of the conventional multi-purpose hot gas furnace according to the present invention, Elementary gas cooling furnace reactor facility (804) side view configuration showing nuclear operation as external side view

As shown in FIG. 1Q, the multi-purpose high temperature gas furnace 805 is provided with a multipurpose hot gas and the reactor installation 805 is provided with graphite as a moderator 676, and the coolant 816 includes helium gas 176). At the same time, the fuel is composed of enriched uranium 235 and thorium, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation.

Referring to FIG. 1 r, a conventional multi-purpose high temperature gas furnace reactor 805 nuclear power plant (FIG. 1), which shows the construction of a conventional multi-purpose hot gas furnace reactor 805 nuclear power plant 672 according to the present invention, 672 in a side view of the nuclear reactors 805 side of the elemental multi-purpose high temperature gas reactor,

As shown in FIG. 1 (r), graphite is used as a moderator 676 in the structure of the nuclear reactor 672 multi-purpose high temperature gas reactor 805, and helium gas 176 is used as a coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, The operation method includes a water pump 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser The control rod 798 and the coolant 816 are connected to the reactor structure 805 as a multipurpose hot gas of the nuclear power plant 672 to constitute nuclear power generation.

 Referring to FIG. 1s, there is shown a constitutional example of a conventional multi-purpose hot gas furnace 805 nuclear power plant according to the present invention. The constituent conventional multi-purpose hot gas furnace 805 and the new conversion furnace 805, Nuclear reactor facility (806) Elementary multi-purpose high temperature gas reactor facility (805) and new conversion furnace reactor facility (806) showing side view of nuclear reactor operation of nuclear power plant.

The use of graphite as a moderator 676 is provided for the structure of the reactor facility 805 of the nuclear power plant 672 and the use of helium gas 176 is used for the coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, In the operating mode, the internal structure 805a of the Pebble-Bed type high-temperature gas path in which the primary cooling system is housed is provided with the heat shield 805b, the through-hole stopper 805c, the auxiliary circulator 805d, the control rod reservoir 805e, The control unit 805g and the auxiliary circulating unit 805h and the auxiliary heat exchanger 805i and the core support structure 805j and the prestressed concrete reactor vessel 805k and the PCRV safety valve 805l, A fuel inlet 805m, a helium circulation unit 805n, and PCRV The HTR-module reactor structure 805p includes a spherical fuel outlet pipe 805q, a boron refining furnace system 805r, a reflector region control rod 805s, A gas circulating unit 805w and a high temperature gas pipe 805x, a surface cooler 805y and a heat insulating material 805z, and at the same time, the fuel supply pipe 805t, the water supply pipe 805u, The use of enriched uranium 235 (812) and thorium and the heat of helium gas 176 are transmitted to water to generate nuclear power by steam generation. At the same time, 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser 790 and a control rod 798 and the coolant 816 to connect the reactor facility 805 to the multi-use hot gas of the nuclear power plant 672 At the same time, nuclear power plant (672) is operated as a nuclear power plant. In the new reactor type reactor structure (806), a new type of reactor power plant (806) And the steam is supplied to the steam turbine 267. The steam is supplied to the steam turbine 267 through the steam turbine 267, The heavy water 654b is used as the moderator 676 and the neutrons 675 are more absorbed than the hard water 654a so that the utilization efficiency of the uranium is increased so that the plutonium (ATR) as an example, the MOX fuel of "Fugen" is taken as an example, and the characteristics and specifications of the fuel for ATR and the manufacturing method thereof Do technology However, since the ATR is a water-cooled type, such as a heavy water reduction ratio, and a pressure tubular type, the fuel assembly has a circular section and is slightly lower in plutonium hatching than the MOX fuel for a light water reactor. However, Equivalent, PuO2 and UO2 powder adopts a two-phase combination method to prevent the generation of plutonium spots and scattering of plutonium hatching degree.

Referring to FIG. 1 (a), a nuclear power plant of a conventional nuclear power plant showing the essential constitution of one embodiment formed by the operation of a nuclear power plant of a nuclear power plant of a conventional new type conversion reactor 806 according to the present invention, New Transition Reactor Facilities (806)

As shown in Fig. 1 (t), the new conversion furnace 806 and the characteristics of the fuel are developed as a national project together with a fast breeder reactor as a Japanese independent reactor, and the use of heavy water as a moderator Therefore, it is a resource saving type power generation furnace capable of efficiently controlling the fuel combustion with a lower degree of enrichment than the light water reactor.

It is possible to freely load with MOX fuel and non-enriched uranium fuel because there is a relatively small influence on the reactor due to the kind of fuel. It is necessary to consider arrangement and control rod as in the case of using MOX fuel in light water reactor There is no.

Since the new type conversion reactor 806 is a heavy water reducing boiling water cooler and is a pressure tubular type, the fuel assembly has a circular section. In addition, there are SGHWR of UK and CANDU-BLW of Canada, There is no example in which a large number of fuel such as ATR is used.

The fuel of the new conversion furnace reactor 806 is slightly lower than the MOX fuel for the light-water reactor, but the fuel production method is almost the same, and the plutonium of the inner fuel rod whose neutron density is lowered Hatching degree is raised.

The structure and specifications of the fuel "Fugen" fuel of the new conversion furnace 806 include "Fugen" MOX fuel, in which 28 fuel rods are arranged concentrically with four inner layers, 8 middle layers and 16 outer layers, The upper and lower tie plates are placed on the upper and lower tie plates, respectively. In the middle, the fuel rods are maintained at appropriate intervals with twelve spacers at appropriate intervals. The main specifications of the fuel assembly and the fuel rods and the assembly are shown. Also, the plan has been discontinued, but the main specification of the 36-fuel assemblies developed as a fuel for the reactor facility (806) demonstration after the "Fugen" was also presented.

Fuel of the reactor plant 806 of the new type conversion furnace 806 is produced by mixing the PuO 2 powder and the UO 2 powder, press-molding them, and then sintering them to prepare pellets, filling them into cladding tubes to form fuel rods, And at the same time, this fuel processing method is almost the same as MOX fuel for fast breeder reactors and light water reactors, and the shape of the pellets is not limited to the corner chamfer used in BWR and the dish used for PWR And the fuel cell system 806 is provided with the fuel cell of the new type conversion reactor 806 adopting the both.

The fuel of the new conversion furnace reactor (806) is mixed with a lubricant to a particle size suitable for molding, and then molded into a green pellet by press molding. At the same time, this is pre-sintered at 800 ° C to evaporate the lubricant After disassembling, sintering is carried out at 1,650 ° C for 2 hours. At the same time, the sintered pellets are judged whether the whole water is passed through a diameter separator. If the diameter is large, the side of the cylinder is grinded with high accuracy by a centerless grinder, At the same time, unlike the case of high-speed fuel, plutonium hatching degree is low. Therefore, no-core grinding using ordinary water such as uranium fuel is provided. The pellets completed with the above-mentioned new type conversion reactor facility 806 are subjected to various analyzes and inspections, and passed through the inspection of the government office and passed to the fuel rod processing step, which is the next manufacturing step.

The pellet of the new conversion furnace reactor 806 is automatically filled by plugging the clad with a plug welded on one side. At this time, the end of the cladding tube is contaminated by contact with the pellet, A countermeasure for mounting a thin plate called a pipe mouth mask on the tube end is provided.

After plugging the pellet of the reactor installation 806 with the new type of conversion, a plug is attached to one of the remaining pipes and sealed and welded by TIG welding to provide a fuel rod. After that, the sealed fuel rod surface is carefully decontaminated, After making the draw from the box and then performing various nondestructive tests such as surface contamination, appearance, dimension, bending, and X-ray penetration test of the welded part, it is inspected by the government office and passed to the assembling process of fuel assemblage which is the next manufacturing process.

If the upper and lower tie plates and the twelve spacers are fixed in advance in a predetermined position of the automatic assembly apparatus, the fuel assembly assembly of the new type conversion reactor unit 806 can be automatically inserted Thereby completing the fuel assembly. The aggregate is inspected and cleaned by bending and twisting, passed the pre-use inspection of the government office, and shipped to the nuclear installation site.

Referring to FIG. 1U, a new type conversion reactor furnace 806 of a conventional nuclear power plant 672 according to the present invention is installed in a nuclear reactor main body of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment A dual structure block for treating nuclear waste according to the present invention. The present invention relates to a dual structure block tank for a nuclear power plant having a dust collector, a new conversion furnace facility (806) provided in a reactor facility, and an elementary nuclear Double Structure Block for Waste Treatment Nuclear Power Plant Reactor Facility Having a Tank Dust Collector In the present invention, a new reactor furnace facility (806)

As shown in FIG. 1U, the nuclear explosion-proof double structure block tank 598 in the form of a raw statistic of the nuclear power plant 627 is provided with a double structure block tank 598 among the plurality of reactor facilities for processing radioactive nuclear waste. A new type conversion reactor 806 in the structure of the nuclear reactor facility 806 which uses the light water 654a as the coolant 816 to increase the utilization of the nuclear fuel than the existing reactor And the steam is generated at the high temperature during the rising of the fuel, so that water and steam are separated from the steam drum, and the steam is sent to the steam turbine 267 to form an energy nuclear power. The heavy water (654b) The absorption efficiency of neutrons is lower than that of hard water, and the efficiency of utilization of uranium is increased. As fuel, nuclear power generation using plutonium and natural uranium is formed, A double-structure block tank is provided with a double-structure block tank dust collector for treating nuclear waste, which is in the form of raw statistics, in a nuclear reactor plant having a dust collector, Inside the reactor facility of the nuclear power plant, a new conversion reactor facility (806) consists of the input of the carrier construction machine.

Referring to FIG. 1 v, there is shown a cross-section of an elemental conventional nuclear power plant reactor building 688 showing the construction of an embodiment of a conventional nuclear power plant according to the present invention, and an elemental reactor building Sectional view of fuel rod 688 and detailed side configuration of fuel rod 689,

As shown in FIG. 1 v, in the section of the nuclear power plant reactor building 688 and in the fuel rod 689 facility, the facilities of the nuclear power plant reactor building 688 include reactor building 688A, turbine building 688B, The facility 688 of the nuclear power plant reactor 688 is provided with the building 688C and the auxiliary building 688D and the diesel generator building 688E and the nuclear fuel building 688F and the waste building 688G, The fuel bundle adjustment 689a and the upper nozzle 689b and the fuel rod adjustment 689c and the fuel rod 689d and the spring clip assembly 689e and the lower end nozzle 689f and the fuel rod rear end cap 689g, Plutonium (689h), hold down spring uranium (689i), and dioxid fuel pellets (689j), gas caps (689k) and zircaloy crowding (689l) are used to operate nuclear power plants.

Referring to FIG. 1w, a conventional high-speed multiprocess reactor (838) nuclear power plant according to the present invention includes a nuclear power plant, A lateral side view constituting an elemental side view,

As shown in FIG. 1w, in the structure of the fast breeder reactor facility 838, the high-speed breeder reactor facility 838 includes uranium enriched in about 20% of enriched uranium 235 at the central portion of the fuel rod 689, And plutonium 801 formed from uranium 238 (653a) is contained in the fuel rod 689. The plutonium 801 is taken out and used as the next fuel The coolant 816 does not contain the moderator 676 and the intermediate heat exchanger 657 does not contain the heat generated from the reactor in the intermediate heat exchanger 657 because the liquid metal sodium is used and the neutrons 675 need not be decelerated. Liquid metal sodium, while the heat exchanger 658 converts the water into steam by the heat of the liquid sodium so that the steam turbine 267 rotates to make nuclear power.

Referring to FIG. 1x, an elemental conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of one embodiment formed from a conventional fast breeder nuclear reactor facility 838 nuclear power plant, (838) disassembled lateral strabismus structure,

    Referring to FIG. 1 (a), an elementary conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of an embodiment formed from a conventional fast breeder nuclear reactor 838 nuclear power plant according to the present invention, As shown in the side view, an elemental fast breeder reactor facility (838)

       As shown in FIGS. 1x and 1y, the fast breeder reactor facility 838 generates nuclear energy by generating a nuclear fission reaction using a high-speed neutron and produces uranium, which is a non-fissile material that accounts for 99% of natural uranium 238 (653a) to uranium 239 (653), which is a fissionable material, and at the same time, it is a high-speed propagation furnace facility 838, so liquid sodium metal is used as a coolant 816. However, Because the neutron 675 rate is low because the uranium 235 (812) is focused on the fission, the fast reactor reactor 838 has a high neutron 675 velocity.

     It is common for the fast breeder reactor facility 838 to reduce the amount of fissile material, especially when burning the fuel within the reactor facility 838, where the breeder initially produces more plutonium 801 than the amount of plutonium 801 The plutonium 801 is consumed but the uranium is converted into plutonium through the reaction. As a result, plutonium 801 is consumed more plutonium 801 than plutonium 801, (801). However, if 1 g of uranium 238 is used at the same time, it will be propagated as 1.17 g of plutonium 239 in the reactor and used as fuel. If such a liquid metal is put into practical use, However, when the liquid sodium used as the coolant 816 is combined with the water air, The cause has the problem in a practical use very difficult to ensure the handling skills to easily corrode the pipe it stably.

     The Super Phosphorus in France and the Monju Fast Breeder Reactor in Japan to the fast breeder reactor facility 838 were able to continue to use the fuel that had already been used, It is called a "dream reactor" that produces fuel, "the more fuel it gets."

Existing light and heavy water reactors H2O and heavy water D2O are used as a moderator 676 and a coolant 816 in the reactor plant 838 to generate fission by using low energy thermal neutrons. While the sodium-cooled high-speed furnace uses a high-temperature liquid sodium (Na) as a coolant without a moderator 676, thereby providing a fission reaction using a high-speed neutron having a higher energy than that of the light water reactor and the heavy water reactor. Since the cross-sectional area of the neutron (675) is remarkably reduced, a high-concentration fuel is provided in order to generate the necessary amount of fission, and at the same time, the power density is high and the reactor size can be made smaller than that of the light- .

In order to overcome the disadvantages of the sodium coolant, there is a closed 'sodium intermediate system', which is designed to heat the water in the steam generator without direct contact between sodium and water. At the same time, all piping and walls through which sodium flows are double A system in which the sodium of sodium DHX (sodium-sodium heat exchanger), which seals the leak or is warmed by hot sodium, rises up the piping and cools it through an AHX (sodium-air heat exchanger) There is one more important story that is missing, worrying about waste and worrying about safety, more economical, more economical and not meeting the high-speed cooling roads, or if the fast breeder reactor facility (838) is provided, Rather, spent fuel that has been stored in the basement can be taken out and reused.

Hereinafter, the conventional nuclear waste disposal method and the cause of the nuclear explosion accident will be described as follows.

      Referring to FIG. 1Z, a conventional nuclear waste disposal method according to the present invention includes a disposal facility 1030 of a nuclear facility 1029, a nuclear waste disposal method 1040 according to a previous design of a plutonium disposal process 1040 in dismantling a nuclear weapon The construction of the conventional elemental nuclear waste disposal method showing the difference showing the construction,

      As shown in FIG. 1z, in the conventional constitution of the nuclear waste disposal method, uranium used as nuclear fuel for a nuclear power plant is purified by purifying natural uranium so that uranium 235 can be concentrated by 3 to 4% and used as a nuclear weapon Of uranium enriched to 95%. As a result of negotiations to reduce nuclear weapons in the 1990s, many nuclear weapons have been dismantled. However, with the remaining nuclear weapons, humanity has been wiped out several times, We have also made uranium for power generation by mixing an appropriate amount of uranium 235 from nuclear weapons into natural uranium. But these nuclear fuel rods are called MOX, but how does nuclear fission occur in reactors? It begins by striking the nucleus of uranium 235 with a neutron, which when hit with a neutron causes unstable uranium 235 to fission and turn into another stable element.

     In the above-mentioned conventional elementary nuclear waste disposal method, while releasing three neutrons with energy as much as the mass difference, the neutrons hit the other uranium 235 to cause nuclear fission, so that the fission occurs sequentially, (675), and then grasps the neighboring fangs, and then the fellow next to it fissures and squeezes the neutrons (675) to squeeze them beside them .

     The conventional elemental nuclear waste disposal method does not divide uranium 235 into neutrals 675 into a nuclear reactor facility, disintegrate and heat the nuclear reactor 675, and crack neutrons 675 at the same time, At the same time, the Uranium 238 gladly does not know the neutrons (675), accepts the neutrons (675) and turns them into my family, then turns into a plutonium (801), and at the same time keeps neutrons Because it is too hot, the cadmium rod is inserted between the fuel rods to absorb and reduce the neutrons (675), and the boron acid is added to the reactor coolant to slow down and calm the neutrons (675).

      As shown in FIG. 1z, in the constitutional arrangement of the conventional nuclear waste disposal method, the plutonium disposal process 1040 in the dismantling of the nuclear weapon includes the nucleus 1029, the dismantling facility 1030, And a deep underground cave 1038 in the MOX processing 1032 and the MOX combustion furnace 1033 and the mixed glass solid 1034 and the high level waste 1035 and the final repository 1036 and the long term storage 1037, The fuel rods 683a and 683c are provided with fuel rods 683a and 683c in the fuel rods 683 and 683a, The lower end nozzle 683f and the fuel rod rear end cap 683g and the plunger 683h and the hold down spring 683i and the uranium dioxide fuel pellet 683j and the gas cap 683k) and zircaloy crowding (683l) and consists of nuclear waste disposal methods of nuclear fuel (683) There is.

     As shown in FIG. 1 (a), in the conventional method for treating nuclear waste, the difference between an atomic bomb and a nuclear reactor is that the fuel of a nuclear reactor containing a small amount of uranium 235 is less likely to be fissioned by a neutron generated by fission, There is no intense chain reaction like bombs, the atomic bombs explode at once, and the nuclear power plant burns low enriched uranium (812) by letting it burn slowly by regulating the fuel (683) with diluted uranium 235 (812) The fuel filler 683 is a nuclear fuel rod 689 filled with a pellet 683 and a zircaloy pipe 682 which is a cladding tube 682. The fuel rod 689 is formed into a square bundle If the number of neutrons 821 is large due to earthquake and tsunami during operation of the nuclear power plant, the chain reaction will be excessive, If the energy exceeds the danger level and the nuclear fission chain reaction proceeds in an idealized state, then many nuclear reactors will explode like atomic bombs, (683) is a key cause of the explosion.

As shown in FIG. 1Z, in the conventional nuclear waste disposal method of the related art, a plurality of existing nuclear reactors include a dust collector 794 of an exhaust gas (171) facility and an exhaust gas 171, In view of the lack of exit and entrance, the explosion of Fukushima Dai-ichi Nuclear Power Plant, caused by a failure of the cooling system caused by the tsunami on March 13, 2011, is a reactor that can not accommodate the high temperature and high pressure inflation and expansion liquid inside the reactor. As a direct cause of the accident, the water, which is the inflating liquid of high temperature and high pressure after the failure of the cooling system, turns into steam, and the steam of high temperature and high pressure is combined with the high temperature high pressure inflation gas at the moment of chemical decomposition of oxygen and hydrogen. At the same time, an electronic flame generated by air friction due to an earthquake is generated, so that its electron flame is ignited by high temperature and high pressure oxygen and hydrogen, The secondary explosion after a primary explosion outside the on-pressure vessel and inside the nuclear reactor building is caused by the explosion of the reactor in the core of the nuclear fuel vessel inside the pressure vessel, causing the explosion of a nuclear explosive It is recognized as a key cause of the nuclear explosion of the first nuclear reactor, recognizing that it has an abrupt chain explosive shape.

As shown in FIG. 1Z, in the conventional method for treating nuclear waste, the conventional nuclear reactors of various types have been equipped with a dust collector and an exhaust gas outlet of an exhaust gas facility, The explosion accident at the Fukushima Dai-ichi Nuclear Power Plant caused by the failure of the cooling system caused by the tsunami on March 13 is a reactor that can not cope with the high-temperature high-pressure inflation gas and the expansion liquid inside the reactor. After the failure of the cooling system, the water, which is the inflating liquid of high temperature and high pressure, turns into steam, and the steam of high temperature and high pressure is combined with the inflation gas of high temperature and high pressure at the moment of chemical decomposition of oxygen and hydrogen, The electronic flame is ignited by oxygen and hydrogen at high temperature and high pressure to cause hydrogen explosion, The secondary explosion after the primary explosion on the outside of the vessel and inside the nuclear reactor building is due to the nuclear explosion in the core of the fuel vessel inside the pressure vessel, In the present invention, in contrast to the conventional nuclear reactors, the double-structure block tank reinforced with the concept of defense in depth, the nuclear power plant of the nuclear and hydroelectric power plants of the offshore and offshore, Nuclear Radiation Leakage Control of Nuclear Reactor Facilities of Waste Treatment Shielding Unit Double structure block tank Double pipe structure piping using energy of water composed of distributing device of dust collector and equipped with safety pressure valve and water pumps as temperature pressure sensor, By selecting the method of automatically injecting the mixture of yellow loess that generates soap bubbles, And the nuclear waste shielding method of the dispensing device of the apparatus for controlling fuel and fuel explosion.

Referring to FIG. 2, a nuclear reactor power plant having a dual structure block tank reactor for nuclear waste treatment according to the present invention is provided with a power generation facility connection structure equivalent to the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 The thermal power plant 626 of the conventional thermal power plant 626 showing the essential constitution of an embodiment formed by the thermal power generation operation of the conventional thermal power plant 626 has the operation mode of operation of the thermal power generator 772 of the thermal power plant 626, Thermal power generator (772) Operation method Elementary side profile Straight configuration Road,

As shown in FIG. 2, the thermal power generator 772 of the conventional thermal power plant 626, which shows the essential constitution of an embodiment formed by the thermal power generation operation of the thermal power plant 626, The conventional operation method of the thermal power generator 772 of the thermal power plant 626 shown in FIG. 7 is similar to that of the conventional nuclear power plant of the world-wide nuclear power plant in that the boiler and the reactor of the thermal power plant are technically differentiated, In order to understand the structure of nuclear power, it is necessary to understand the structure of the boiler (778) and the melting furnace (783) to dissolve the metal. In order to understand the structure of nuclear power generation, (1) of a nuclear power plant having a structural block tank dust collector to control the operation of the nuclear power plant of the nuclear power generation facility (811) It handles all the tasks of a central control station (781) is equivalent to the computer.

On the other hand, coal-fired power plants are constructed on coastal areas or coasts where there is usually a large demand for electric power, and due to the exhaust gas emitted from the stack, the order of the ecosystem is broken, and dusts such as soot, The natural disaster has reached a serious level due to the global warming phenomenon due to the increase of the discharge, etc. The countermeasure against this is that the inventor of the present invention installs a seesaw-type wind turbine hydropower generator of the nuclear- , Which is a means of solving human anxieties with endless production of environmentally friendly energy.

The thermal power generation unit of the post-thermal power plant 626 before the failure recovery of the nuclear power generation facility 811 into the reactor main body 1 of the conventional nuclear power plant includes the above- The thermal power generation apparatus of the nuclear power plant includes a steam turbine 267 which generates steam by burning fuel in the boiler so as to produce steam by the heat to rotate the steam turbine 267 to produce power, A rotating rotor electromagnet coil 774 for the thermal power generator installed along the circumference of the rotating shaft 198 connecting the steam turbine 267 and the thermal power generator 772, A non-rotating armature coil 773 for a thermal power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for the thermal power generator, and a non-rotating armature coil 773 mounted on the steam turbine 267, It is formed to be made to develop seolbibu 811 when after any reactor plant safety operation i and reactor equipment failure recovery before and after the thermal power during which includes a frame 775 for fixing the rotary shaft 198 integrally.

Referring to FIG. 2A, a conventional high-speed breeder reactor facility 838 of the nuclear power plant 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (838) Elementary fast breeder reactors facility (838) showing disassembled side view of nuclear operation of nuclear power plants Nuclear reactor construction (838) Disassembled lateral strainer configuration Road ,

As shown in FIG. 2A, the fast propagating furnace reactor facility 838 generates uranium 238 (653a), which is a non-fissile material that generates energy by generating a fission reaction using a high-speed neutron and occupies 99% ) Is converted to a fissile material, uranium 239 (653), and at the same time, the liquid fuel metal 838 is used as a coolant 816 because it is a high-speed propagation furnace facility 838. However, 812), the speed of the neutron 675 is high in the reactor plant 838 of the fast breeder reactor, while the speed of the neutron generator 675 is low.

Referring to FIG. 2B, in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, a nuclear power plant 811, A nuclear waste disposal system is provided to provide a nuclear waste disposal system to restore the nuclear power plant. A nuclear waste disposal system is used to operate a nuclear power plant. A nuclear waste disposal system A side view of the apparatus, a nuclear waste disposal apparatus for operation of nuclear power plants of a conventional nuclear power plant,

As shown in FIG. 2B, in the conventional method of treating nuclear waste generated from a nuclear power plant for nuclear power plant nuclear power plant operation of a nuclear power plant, ventilation inside the building and air contained in water inside the reactor In the case of a gas, purified air is exhausted to the outside by an activated film type gas hold-up device 213 which weakens the radioactivity when the pressurized water reactor system is operated. However, ventilation of the power plant is performed by a plurality of symmetrical filters 214 And discharges all of the ventilated air from the exhaust tower 215 to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

In addition, when the inside of the nuclear power plant is solid and the paper, cloth, work clothes, shoes, and so on are solid in the inside of the nuclear power plant 672, the filter sludge and the used resin liquid are stored in the storage tank 216, and then filled in the drum 220. The paper and the cloth are compressed to reduce the volume and attenuate them. All of them are filled with concrete into the drum 220, and the nuclear waste 224 to move the nuclear waste storage building 332 and monitoring monitoring post 219 to a nuclear waste disposal facility, To prevent radioactive contamination.

When the regenerated liquid of the ion exchange resin is liquid in the water leaking from the valve of the nuclear power plant 672 and the water in the building into the nuclear power plant 672, the washing water is collected in the storage tank 216 and filtered with the filter 217 After measuring the radiation level by the radioactivity measuring device 218, it is confirmed that there is no harm, and then it is sent to the sea together with the seawater for cooling. The water other than the washing water is purified by the filter 217, and the filtered water, distilled water, And is provided with monitoring posts 219 for monitoring at the same time to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2C, in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a nuclear power plant 811, Nuclear power plants operating nuclear reactors providing nuclear waste disposal facilities to provide for post-war reconstruction Deep safety Nuclear power plant 5 Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant , Nuclear power plant operation of elemental conventional nuclear power plant shown in cross section in-depth safety Fifth barrier side lateral diagonal construction road,

     As shown in FIG. 2C, the control rod 798 is inserted into the fuel assembly 671 from the pressure vessel 813 in the fifth-level safety barrier for operating the nuclear power plant of the conventional nuclear power plant, At the same time, the fuel assemblies 671 are adjusted to the height of the fuel assemblies 671 at the height of the nuclear reactor facility, and at the same time, the fuel assemblies 671 are used to stabilize the pellets 683 The nuclear fuel pellet 683 is enclosed in the covering material 681 as the second barrier wall and is put into the metal tube of the special alloy as the fuel rod 689 as the fuel rod 689. [ At the same time, in the reactor pressure vessel 813, which is the third barrier wall, a small amount of gas discharged from the nuclear fuel assembly 671 provides a seal to the second barrier wall, Is a facility pressure vessel 813.

     In the shielded concrete wall as the fourth barrier wall, the radioactive material is prevented from leaking as a concrete wall surrounding the nuclear reactor facility. In the containment vessel 808 as the fifth barrier wall, a safety system and a system At the same time, the facilities of the biological shielding wall, which is the 5-1 barrier wall, are provided with a final biological shielding wall as a thick building of 70 to 100 cm outside the steel, , And at the same time a containment vessel (808) and a dome-shaped, secure nuclear building that provides protection against leakage of radioactive material, while at the same time providing emergency shutdown of radioactive material in the event of an accident.

However, since the conventional nuclear reactor power plant is constructed so that the deep-safety nuclear reactor facility can not cope with a stronger earthquake than 5, it is urgently necessary to take measures against it.

Referring to FIG. 2d, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, Nuclear Power Plant Operation Having the Evaporator Structure 1005 of the Steam Generator, the Steam Generator 810, and the Intermediate Heat Exchanger 657 During the operation of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment, The steam generator 810 and the intermediate heat exchanger 657 are separated from each other in a side view in section, and the steam generator 810 and the intermediate heat exchanger 657 of the steam generator are connected to each other. The evaporator structure 1005 of the generator, the steam generator 810 and the intermediate heat exchanger 657,

As shown in FIG. 2D, the facility structure of the nuclear reactor nuclear power plant 811 of the nuclear power plant, the vapor generator structure 1005 of the steam generator, the steam generator 810, and the intermediate heat exchanger 657 is first subjected to intermediate heat exchange The apparatus 657 includes a secondary cooling system outlet 657a, a low temperature head 657b, a secondary cooling material inlet 657c, a support plate 657d, a central pipe 657e, an outer annular portion 657f, And the heat insulating material 657h and the high temperature head 657i and the mixer 657j and the primary system gas inlet 657k and the primary system gas outlet 657l and the single pipe 657m pressure vessel 657n, 657o, 657p, 657p, 657r, 657r, 657s, 657t, 657u, 657v, and 657w, respectively, The steam generator 810 is provided with a steam outlet 810a and a water supply nozzle 810b and a secondary cooling water 810c and a vibration suppression rod 810d ) customs A tubular shell 810f and a tubular shell 810g and a tubular steel plate 810h and a separating steel plate 810i and a primary outlet 810j and a primary inlet 810k and a heat exchange tubular 8101, And the steam generator internal tubular body 810o and the evaporator structure 1005 of the steam generator are provided with the steam outlet pipe 1006 and the steam outlet body external appearance A connection pipe 1013 and a cooling water leakage detecting pipe 1014 and a hygrometer pipe 1008, a steam outlet pipe 1009, a liquid level pipe 1010, a sodium cooling water inlet pipe 1011, an upper plate 1012, A secondary argon gas pipe 1015, a skirt 1016, a spiral heat exchanger tube 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a water drain pipe 1020 and a cover 1021, Water reaction product discharge pipe 1024 and an inner pipe 1025 and a monitoring inlet pipe 1026 and a water inlet pipe plate 1027 and a water inlet pipe 1010, 28) and a water supply inlet chamber (1028a) connection structure to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2E, the boiling water reactor unit 802 of the nuclear power plant 811 and the pressurized water reactor 802 of the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, Type nuclear reactor (803) Nuclear power generation facility (811) is installed inside a nuclear reactor main body (1) of a conventional nuclear power plant shown in a cross section of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operation of a nuclear power plant ) Of the boiler water reactor (802) and the pressurized water reactor (803) of the nuclear power plant,

     As shown in FIG. 2E, the operation of the boiling water nuclear reactor 802 is a boiling water reactor (BWR) type in which water vapor of water boiling in the core is directly sent to a power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats hid their details without disclosing details, refused to provide US technical support, and at the same time, they poured seawater into a wreckage, drove a fire engine and used a helicopter to put it into the building, In the reactor (PWR, 803) facility, there is provided a primary system transfer that circulates between the fuel and the heat exchanger 658, and at the same time, a heat system, called the hot system steam generator 810 of the primary system, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser The turbine 267 of the secondary system is connected to the turbine generator 772 to generate electric power at the same time. (PWR, 803) facilities are compared with two pressurized water reactors and other reactors. In the pressurized water reactor, there are two cooling water 1 In the boiling water reactor (BWR), the turbine (267) of the secondary system and the secondary system provides electric power production in connection with the turbine generator (772), while at the same time water none.

In the pressurized water reactor type nuclear reactor (803) nuclear power plant, in the pressurized water reactor type nuclear reactor facility (803), the hard water of the coolant is designed for the primary use in the PWR, , And 315 degrees Celsius. At the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light pressure (654a) at a pressure of 150 times the pressure does not boil. At the same time, The water is steamed at a temperature of 275 degrees Celsius and a pressure of 900 psig and a pressure of about 6.2 MPa, and is sent to the steam turbine 267.

     The stability of such a pressurized water reactor type reactor (803) is such that a pressurized water reactor is provided with a very stable production. However, when the graphite deceleration boiling water pressure tubular reactor (RBMK) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, the heat and sintering of the phenomenon to be used are provided, and at the same time, the production of ceramic pellets made of uranium dioxide is provided, and the pellets made of such a cylinder are made into a zirconium alloy Zirconia), and helium is injected into the zirconia bar to help heat transfer, but the finished fuel rod is bundled with bundles of fuel assemblies, which are called bundle bundles of fuel, which are loaded into the reactor core do.

Referring to FIG. 2F, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant (1) (1) of a conventional nuclear power plant showing the operation method of a nuclear power plant of a conventional nuclear power plant, showing the configuration of the nuclear power plant of the nuclear power plant (811)

As shown in FIG. 2F, the nuclear plant power plant of the nuclear power plant 811 includes a safety valve 472, a for-spiff safety valve 475 for steam, an air vent valve 481, The reactor pressure vessel 813 is connected to the pressure vessel container 813a and the pressure vessel 813a by the air air exhaust valve 482 and the nichrome wire 659 and the steam generator 810, A pressure vessel cylindrical top end portion 813d and a pressure vessel cylindrical top end portion 813e, an inlet nozzle 813f and a deflector steel plate 813h, which form a position in the top cover lower portion 813b and the pressure vessel cylindrical cover 813c, A pressure vessel cylindrical top cover for providing a position in the air chamber chamber 813i, the baffle plate 813j, the water 813k, the spray pool 8131, the vent five 813m and the fuel assembly 813n, (813p) is provided with a dry wall (813q), a pressure vessel cylindrical cover bottom assembly (813s) and a pressure vessel cylindrical cover top And a connection structure of the control rod guide tube assembly 813z of the reactor core assembly 813y and the outlet nozzle 813w and the core assembly 813y of the nuclear fuel assembly 811t, the fuel rod steel plate 813v, It is structured to prevent nuclear radiation pollution both inside and outside of the operation equipment.

      Referring to FIG. 2G, the nuclear power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention includes the nuclear power generation facility 811 intermediate heat exchanger 657, The structure of a nuclear power plant having a structure 1005 and a steam generator 810 is shown in a schematic view of an elemental conventional nuclear power plant operating at the nuclear power plant 811 and an intermediate heat exchanger 657 and a steam generator The structure of the evaporator 1005 and the steam generator 810 are shown in side elevation and in cross section in the nuclear reactor of the conventional nuclear power plant and the evaporator structure of the steam generator in the nuclear power plant 811 intermediate heat exchanger 657 1005) and the steam generator (810)

As shown in FIG. 2G, the inside of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the nuclear power generation facility 811 intermediate heat exchanger 657 and the vapor generator structure of the steam generator 1005 and the steam generator 810, the structure of the intermediate heat exchanger 657 includes a secondary cooling system outlet 657a, a low temperature head 657b and a secondary cooling system inlet 657c and a support 657d and a central piping 657e and an outer annular portion 657f and a pressure vessel 657g and a heat insulating material 657h and a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k ), A primary system gas outlet (657l), a single pipe (657m), an internal pressure pipe (657n), a heat insulating layer (657o), a high temperature gas passage (657p), a liner (657q), a double pipe (657r) A gas pipe 657t and an inner pipe 657u and a hot gas passage 657v and a liner 657w and a heat insulating layer 657x. A tubular lid 810a connected to the turbine generator, a water supply nozzle 810b, a secondary cooling water 810c and a vibration damping rod 810d, a tubular supporting pipe 810e, a tubular lid 810f, a tubule bundle 810g, And the steam generator 810n and the steam generator internal fuselage 810i and the steam generator internal pipe 810i and the steam generator internal pipe 810i, the primary pipe outlet 810j, the primary pipe inlet 810k, the heat exchange pipe 8101, the cooling water passage 810m, The steam outlet pipe 1006 and the steam outlet body 1007 are connected to the hygrometer pipe 1008 and the steam outlet pipe 1009 and the liquid level sensor A cooling water leakage detection pipe 1014, a secondary argon gas pipe 1015, a skirt 1016, and a spiral heat exchange tubular pipe 1010, a sodium cooling system inlet pipe 1011, an upper flat plate 1012, a connecting rod 1013, 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a drain water pipe 1020, a cover body 1021, a body outer pipe 1022, a sodium channel 1023, and a sodium- A water inlet pipe plate 1027, a water inlet pipe 1028, and a water inlet chamber external pipe 1028a connecting structures to the inside of the nuclear power plant 1024, the inner pipe 1025, the monitoring inlet pipe 1026, the water inlet pipe plate 1027, (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste of a nuclear power plant, and a nuclear power plant (811) intermediate heat exchanger (657) and an evaporator of a steam generator The construction of the structure 1005 and the steam generator 810 can be configured to prevent nuclear radiation pollution both inside and outside the nuclear power plant operating the nuclear power plant.

Referring to FIG. 2H, a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant The nuclear power plant of the conventional nuclear power plant showing the configuration of the embodiment of the nuclear power plant in operation of the nuclear power plant, the nuclear power plant of the conventional nuclear power plant showing the side view of the steam generator 810 of the nuclear power generation facility 811, (811) Steam Generator (810) Side Construction Road,

The steam generator 810 of the nuclear power plant 811 includes a steam outlet 810a connected to the turbine generator and a steam generator 810a connected to the turbine generator 810, The tubular lid 810f, the tubular bundle 810g, the tubular steel plate 810h and the separated steel plate 810i, the water supply nozzle 810b, the secondary cooling water 810c, the vibration suppression bar 810d, A primary side inlet 810k, a heat exchange tubular 810l, a cooling water flow channel 810m, a steam generator tubular tube 810n and a steam generator internal body 810o, The safety valve 474 and the intermediate heat exchanger 657 are structured such that the secondary cooling system outlet 657a, the low temperature head 657b, the secondary cooling material inlet 657c, the support plate 657d and the central pipe 657e, A heat exchanger 657h, a heat insulating material 657h, a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k and a primary system gas outlet 657l, (657m), a pressure insulation pipe (657n), a heat insulation layer (657o), a high temperature gas pipe (657p), a liner (657q), a double pipe (657r), a pressure pipe (657s), a low temperature gas pipe (657t) (657v), a liner (657w), a heat insulating layer (657x), and a reheater (793), and at the same time, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste 1) Nuclear power plant (811) inside Nuclear power plant (811) Nuclear power plant with intermediate heat exchanger (657) and connecting structure of steam generator evaporator structure (1005) and steam generator (810) As shown in FIG.

Referring to FIG. 2I, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention (1) Nuclear waste treatment is performed inside the production power central control room (781) Operation of a Nuclear Power Plant Having a Cutter and a Robot 912 by Remote Control of the Apparatus In an elemental conventional nuclear power plant showing the construction of a nuclear power plant during operation of the nuclear power plant, (912) of the nuclear waste disposal apparatus remote control nuclear power plant nuclear waste disposal method of the nuclear power plant nuclear waste disposal method of the elemental conventional nuclear power plant operating nuclear power plant nuclear power generation facility 811) Production power Central control room (781) Inside Nuclear waste processing device Remote control Cutting machine and robot (912) Nuclear power plant Nuclear waste disposal side In addition,

As shown in FIG. 2 (i), the piping line of the nuclear reactor facility is connected to the safety valve 472 in preparation for a period of three months or longer for the repair work of the inside of the reactor facility of the nuclear power plant 672, The boiler 783 of the thermal power plant is operated at the same time, and the connection structure is formed in the reactor power generation facility 811 to supply the steam of high temperature and high pressure and further emergency power generation operation is performed. In order to secure the safety of the nuclear power plant by safe and continuous operation of the nuclear power plant inside the nuclear power plant by replacing the electric power supply with the thermal power generation facility during the work period and to prevent the radioactive contamination during the renovation of the reactor facility, At the same time, during the operation of nuclear power plants, the production power central control room 78 of the nuclear power generation facility 811 1) Nuclear power plant nuclear power plant equipped with cutter and robot (912) device by remote control of nuclear waste treatment device inside It is provided with nuclear waste disposal method to guarantee the repair of nuclear reactor.

Referring to FIG. 2J, there is shown a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The reactor core 1 includes a nuclear power plant 1071 having a nuclear fuel industry cycle 1077 of the nuclear power generation facility 811, The nuclear fuel cycle of the nuclear power plant 811 in the operation of the nuclear power plant of the conventional nuclear power plant showing the configuration of the nuclear power plant of the power plant is shown in a side view and a cross-sectional view Nuclear Power Plant (811) Nuclear Fuel Industry Cycle (1077) Nuclear Fuel Transfer Process and Revision of Revision Scene Disassembly of the Scene Scenery Construction of roads,

As shown in FIG. 2J, the nuclear fuel cycle 1077 of the nuclear power plant 811 is transferred into the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment The spent nuclear fuel 683 consumed in the nuclear power plant 672 and the remaining uranium 812 are processed in the reprocessing plant 228 and then converted into uranium fluoride 812 in the conversion plant 229 to be concentrated in the concentrating plant 230 to convert the uranium fluoride 812 to uranium dioxide at the conversion plant 229 and process it into pellets 683 to form the fuel rods 689 and process them in the reprocessing plant Plutonium 801 is produced at the conversion and processing plant 231 and fuel rods 689 are produced so that these reprocessed fuel rods 689 are moved back to the nuclear power plant 672 and the fuel 683 is transferred to the nuclear power plant 672 The concentrating plant 230 in the reprocessing plant 228, The conversion plant 229 and the conversion processing plant 231 prepare nuclear waste 224 as a nuclear fuel cycle of the nuclear fuel industry on the top surface of the sinking prevention type barge deck 40 m above the sea surface of the ocean, 672) The nuclear fuel cycle of the Edo nuclear fuel industry is constructed so as to prevent nuclear radiation contamination both inside and outside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment.

In addition, the long half-life nuclear waste 224 generated from the reprocessing process at the nuclear power plant 672 inside the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste has a half- Heavy construction equipment heavy equipment hire (877) and excavators (845), which provide shelter for thousands of years because of their long shelf life, while at the same time providing for the permanent disposal of long-term waste, Comprising the steps of constructing the waste to be treated with a device of a permanent disposal method of a long-term nuclear waste,

The nuclear waste treatment includes the steps of fissioning in the nuclear reactor facility to construct a conversion into another material,

The nuclear waste disposal includes the step of constructing a deep burial site by having a construction machinery heavy equipment hoeing 877 and an excavator 845 in a stratum or ocean,

The nuclear waste disposal includes the steps of constructing a double tubular drum (220) having a sinking prevention vessel and containing nuclear waste to be transported to a buried area,

In the nuclear waste disposal, a dual tubular drum 220 containing nuclear waste is mounted on the space rocket 612 at the position of the upper end of the barge deck deck 591 provided with the space rocket 612 and the space rocket launching rods 646 (224) containing nuclear waste (224) comprising steps constituting transmission to the outer space of a nuclear power plant having a dual structure block tank dust collector for the treatment of nuclear waste (1) To make the treatment of the nuclear waste with the devices of the permanent disposal method of the nuclear waste.

Referring to Figure 2K, there is shown a structural and engine side view of an elemental configuration of an embodiment of a nuclear power station of a TVA Paradise Power Plant Steam Turbine Generator in the vicinity of the prior art Paradise in Kentucky, Generator and engine side Elementary strap configuration Road,

As shown in FIG. 2K, the following is a detailed description of the energy conversion of the translation of the contents of the American Science Series of the energy and power of the modern science in the late 1960's.

TVA's Paradise Power Plant Steam Turbine Generator in the vicinity of Paradise, Kentucky, has a capacity of 1,150 MW. When it first started operation in February 1970, it was the largest power plant in the world. The turbine, which is produced by General Electric Company, first enters the high-pressure turbine under the right-angled pipe on the left, and flows through the rectangular pipe in turn to the intermediate-pressure turbine (the rear lid) and the low-pressure turbine (the front lid). The high pressure turbine is connected to one generator (gray box on the left) and the other two turbines are connected to a second generator (front box) with the same capacity. The entire plant is run by 3.6 million kg of water vapor per hour, which enters the high pressure turbine at a pressure of 1,650 kg per square inch and 427 ° C. The coal consumption per day is 10,572 tons, enough to fill 210 coal cargoes. The net heat efficiency of this facility is 39.3%. Two small turbine generators, each with 704 MW, are visible at the rear.

<Efficiency of household stoves, steam turbines, automobile engines and bulbs helps to determine energy demand. What is primarily needed is a kind of energy source that does not increase the earth's heat load.>

Modern industrial societies can be seen as a complex machine that emits the energy necessary to create numerous goods and services, while at the same time, the high quality energy is reduced to waste heat. Last year, the United States achieved a gross national product of just over $ 1,000 trillion using 69 × 10 ¹⁵ Btu, of which fossil fuels accounted for 95.9 percent of the energy, 3.8 percent of water falls, and 0.3 percent of the U ²³⁵ split Respectively. The consumption of 340 million Btu per person is equivalent to the energy contained in about 13 tons of coal, or 2,700 grams of gasoline if followed recently by the most frequently used method. It can be estimated that in 1900-70, the efficiency of the spent fuel for all purposes was improved by a factor of four. Without this efficiency improvement, the US economy in 1971 would already be consuming as much energy as it would have expected in 2025 or at that time.

GNP could be increased at an annual rate of 3.25% while fuel consumption increased only 2.7% per year in 1890-1960, as the efficiency of converting energy into useful heat, light, and work continued to improve. However, it seems that this favorable phenomenon is no longer persistent. Since 1967, the annual increase in fuel consumption has been faster than GNP growth, making fuel economy more difficult to improve and new products and services requiring more energy input and costs than in the past. Given the expected increase in fuel use for power generation, it is clear that a significant portion of the fuel to be consumed in the 1980s and 1990s will be transformed into a useful form with a lower efficiency than today's fossil fuels. This is because current nuclear power plants convert only about 30% of the fuel's energy into electricity, compared to about 40% efficiency of the most efficient fossil fuel power plants.

It is understandable that engineers try to improve the efficiency of converting the energy of a fuel into another more useful form. Improving efficiency in industry means reduction of production cost, lowering price for consumers, and reducing pollution of air and water quality to all people. Electric utilities have long known that it can stimulate consumption by lowering the price of energy for many users. The recent campaign by the utility, <1W Save>, represents a significant reversal of corporate philosophy. The difficulty of selecting a suitable new power plant site not only indicates the need for efficiency of consumption, but also the saving of consumption. In addition, we can not but emphasize that even with this much improvement in efficiency, we can expect only a slight effect in extending the life of fossil fuels and fuel supplies. I would like to elaborate on this point from the back of this article.

<Figure 8-1> The transformation path connects many familiar forms of energy. The four black markings are important energy sources of today, and potentially important energy sources for solar energy. The dashed lines represent unusual, accidental, or theoretically useful transformations. The white line represents the fate of intermediate form energy. Most of the energy is converted into mechanical energy, except for the thermal energy used for heating. Mechanical energy is used for direct traffic (see Figure 8-2) or used for power generation. And electrical energy is used for lighting, heating and mechanical work. As a secondary form, chemical energy can be found in batteries and chargers. Most of the radiant energy produced by the bulb is lost as heat.>

Figure 8-2 shows the path to the final destination for the three major energy sources. The most direct and most efficient conversion is from falling water to mechanical energy, which is then converted back to electrical energy. Energy trapped in fossil fuels and nuclear fuel is first released in the form of heat energy, then converted to mechanical energy, and then converted to electrical energy if desired. Losses in conversion and transmission include the use of various non-energy sources of fossil fuels, such as the use of fossil fuels for the production of lubricants or the conversion of coal to coke. However, the greatest loss is due to power generation with an average efficiency of 32.5%.

The efficiency of converting the energy contained in a fuel into a useful form varies depending on the conversion method and the desired end use. When burning wood or coal in an open fireplace, less than 20% of that energy is emitted into the room. All the rest are lost to the chimney. On the other hand, a well designed home stove can capture 75% of the energy of the fuel and use it for heating. The average efficiency of fossil fuel conversion for heating is now 50-55%, which is three times higher than that of today. In 1900, more than half of all the fuel consumed in the United States was spent on heating, but today less than one third of it is spent on it.

Sadi Carnot, 1796-1832)는 1824년 증기터빈이나 다른 열기관의 이론적 최대효율을 계산하는 방법을 발표하였다. 가능한 최대효율은 (T ₁-T ₂)/T ₁로써 표현되는데 여기서 T ₁은 열기관으로 들어가는 작용액체의 절대온도이며, T ₂는 기관 밖으로 나오는 액체의 온도이다. 이들의 온도는 보통 켈빈 도수(degrees Kelvin)로 표현되는데, 이 온도는 섭씨온도에 절대냉도와 섭씨 0°와의 차이인 273을 더한 것이다. 현대의 증기터빈에서 T ₁은 전형적인 811°K(=573.7℃)이며 T ₂는 311°K(=37.8℃)이다. 따라서 (까르노)의 식에 의하면 이 열기관의 이론적 최고효율은 약 60％이다. 그러나 수증기의 순환 자체가 가진 성질로 인하여 항상 이러한 상한 온도로 유지할 수 없기 때문에 이론적 최고효율은 60％가 아니라 53％일 가능성이 더 크다. 현대의 증기터빈은 이 값의 약 89％, 즉 순 47％ 정도를 달성하고 있다.The most significant improvement in fuel conversion efficiency for this century was achieved by the power generation business. In 1900, less than 5% of the fuel's energy had been converted to electricity. Today, the average efficiency is around 33%. This increase was mainly due to the increase in the temperature of the steam entering the turbine that drives the generator and the construction of larger-scale power plants. In 1910, the typical incident water vapor temperature was 260 ° C, but today the facility uses steam heated at a high temperature of 574 ° C (Nicolas Carnot; Nicolas

Sadi Carnot, 1796-1832) published a method to calculate the theoretical maximum efficiency of a steam turbine or other heat engine in 1824. The maximum possible efficiency is expressed as ( T ₁ - T ₂ ) / T ₁ where T ₁ is the absolute temperature of the working liquid entering the heat engine and T ₂ is the temperature of the liquid exiting the engine. Their temperature is usually expressed in degrees Kelvin, which is the difference between absolute cold and 0 ° C, plus 273 degrees Celsius. In modern steam turbines, T ₁ is typically 811 ° K (= 573.7 ° C) and T ₂ is 311 ° K (= 37.8 ° C). Therefore, according to (Carnot) equation, the theoretical maximum efficiency of the heat pump is about 60%. However, due to the nature of the water vapor circulation itself, it is not always possible to maintain this upper limit temperature, so the theoretical maximum efficiency is more likely to be 53% than 60%. Modern steam turbines achieve about 89% of this value, or about 47%.

To determine the overall efficiency of a steam turbine plant, this value should be multiplied by the efficiency of the other energy converters in the chain from fuel to power. Modern boilers convert about 88% of the chemical energy of the fuel into heat. The generator can convert up to 99% of the mechanical energy produced by the steam turbine into electricity. Thus, this overall efficiency is 88 × 47 (efficiency of the turbine) × 99, ie about 41%.

(See also Lord Kelvin, William Thomson, 1824-1907)

[Figure 8-3] Energy converter efficiency is from less than 5% of normal incandescent lamps to 99% of large generators. The efficiency shown here is an alternative maximum value that can be reached with current technology. A figure of 47% of the kit with liquid fuel was calculated for the liquefied hydrogen engine used in the Salton lunar spacecraft. The efficiency of fluorescent lamps and incandescent lamps is not a theoretical value of 220 lumens per V of fully flat white light, but is assumed to be about 400 lumens per W for the maximum efficiency that white light that can be tolerated can reach.

Nuclear power plants are less efficient because their current reactors can not be as hot as boilers burning fossil fuels. The temperature produced by the water boiling reactor is around 350 ° C, which means that T ₁ is 623 ° K in the Karno equation. In a complete cycle from fuel to power, the efficiency of a nuclear power plant is reduced to about 30%. This means that about 70% of the energy of the fuel used by the nuclear power plant is waste heat, which is discharged to the surrounding atmosphere when using adjacent water bodies or cooling towers. In fossil fuel power plants, this waste of heat amounts to about 60% of the energy of the fuel.

However, the actual waste heat load on water or air is much higher than the figure of 60% or 70%. For power plants with the same kilowatt output, nuclear power plants generate about 50% more waste heat than fossil fuel power plants. The reason is that a nuclear power plant must burn about one-third more fuel than a fossil fuel plant to produce 1 kW / h of power, and many more B.t.u. And 70% of the input is wasted.

Of course, there is no thermodynamic rule that heat emitted by nuclear power plants or fossil fuel power plants must be wasted. The problem is to find useful things that can be done by this much amount of low energy. Many applications have been proposed, but all of them are facing economic constraints. For example, low pressure water vapor emitted from a steam turbine can be used for heating. In some communities, especially in New York City, New York (Consolidated Edison, Inc.) supplies a lot of water vapor. Many chemical plants and refineries use low-pressure steam from turbines as water vapor for the treatment process.

[Figure 8-4] Three of the fastest growing energy consumption appliances are electrical appliances, automobiles, and aircraft. These three now consume about 40% of all energy consumed in the United States. By 1940, they were much smaller than now, accounting for 18% of total energy consumption. Fuel demand for aircraft has more than tripled in ten years.

There was also a suggestion that heated water released from the power plant would help promote fish and shellfish growth in some areas. But nationwide, waste heat from current fossil fuel power plants or waste heat from dozens of new nuclear power plants in the near future seems to have no attractive use. The problem is to limit the harmful effects of this waste heat on the environment.

In the discussion above, it can be seen that the use of electric power for home heating (which is still actively recommended by some electric companies) is an inefficient use of chemical fuels. Domestic luxury oil stoves and gas stoves typically exhibit at least twice the efficiency of power plants. In some regions, however, despite the low efficiency at the annual price of electric heating, it is likely to compete with direct heating by fossil fuels. In such anomalous cases, various factors are involved. The higher the temperature, the lower the consumption. Electric heating is usually installed in a new building with good thermal insulation. In some areas, finding natural gas is a bit difficult and expensive. The supply of oil is not always reliable. As chemical fuels become more prevalent, their value will be higher and nuclear power generation will increase. Unfortunately, despite the inefficient use of fuel, we can not help but expect that more of our fuel resources, especially nuclear fuel, will be used for power heating.

[Figure 8-5] The efficiency of fossil fuel power plants in the United States has improved nearly 10 times from 3.6% in 1900 to 32.5% in 1970. This improvement was made possible by increasing the operating temperature of the steam turbine and increasing the size of the power plant.

The most widespread of all prime movers is the piston engine. Many American household garages have two piston engines, even if they do not include power mowers, snow throwers, chain saws, and the like. The output of piston engines in more than 100 million cars in the United States is estimated to be more than 17 billion horsepower, or more than 95% of all prime movers (defined as engines that convert fuel into mechanical energy). Although this massive output is not used most of the time, it accounts for more than 16% of the fossil fuel consumed in the United States. All forms of transportation - consuming a million tons of coal from ships, accounting for 16% of the total energy demand in the country. According to estimates by the energy consultant John Hume, the railroad delivered 54% more traffic (measured as an index of transport performance) as 1/6 of B.t.u. than in 1920. This increase in efficiency has reduced the share of the nation's total energy budget from 16% to about 1%, with the role of the railway in the national economy declining. But the curves for total energy consumption in 1920-67 show little or no impact of this tremendous change.

<Figure 8 - 8> The efficiency of the lamp depends on the quality of the light which each thinks is good. For perfectly flat white light, the theoretical efficiency is 220 lumens per Watt. You can get up to about 400 lumens per W by slightly boosting the light in the middle of the spectrum. Current fluorescent lamps can be 36% efficiency or 20% efficiency.>

An important use for the least efficient use of power is probably to supply light. (General Electric Company) estimates that lighting consumes about 24% of total electricity generation, or 6% of total national energy budget. It is well known that filaments of ordinary 100W incandescent lamps produce much more heat than light. Actually, it appears as infrared rays of 95% or more of power input, and only 5% or less is emitted as visible light. Nevertheless, this is more than five times the light emitted by a 100W bulb in 1900. Modern fluorescent lamps convert about 20% of the power consumption to light.

[Figure 8 - 9] Power generators currently in use utilize energy from falling water, fossil fuels or nuclear fuel. A hydro turbine generator (1) converts the potential kinetic energy into electricity. In a fossil fuel steam turbine generator (2), the boiler produces water vapor, which circulates the turbine, which turns the generator. At the nuclear power plant (3), a split of U ²³⁵ releases energy and creates water vapor, which is then passed through the circuit as in a fossil fuel power plant. In the currently undergoing nuclear proliferation furnace (4), surplus neutrons are captured by a coating of U ²³⁸ or Th ²³² atoms that can not divide and converted to Pu ²³⁹ or U ²³⁸ , which these atoms can divide. The heat of this reactor is carried by liquid sodium.>

This value is not a complete white light, but is based on a practical upper limit of 400 lumens per watt, assuming acceptable white light. The maximum theoretical output is reduced to 220 lumens per watt if the spectrum is limited to fully flat white light. Theoretically, you can reach 680 lumens per watt if you can be satisfied with the light of the shortest wavelength (550 nm), which is most sensitive to human eyes.

General Electric currently owns about 70 percent of the nation's total lighting, while the remaining incandescent light bulbs and high-end electric propulsion systems, locomotives and aircraft - consume about 25 percent of the nation's energy budget.

[Figure 8-6] The efficiency of a locomotive can be expressed as the amount of energy required to represent the unit <transport performance> in the US railway. The dramatic improvement in the 1950s reflects the fact that steam locomotives were almost completely replaced by diesel locomotives.

Automotive engineers estimate that the average efficiency of automotive engines has improved by roughly 10% over the past 50 years, from 22% to 25%. But the distance that you can run with 1gal of fuel is actually smaller. From 1920 until World War II, passenger cars typically traveled about 21.6 kilometers per gram of fuel. Over the last 25 years this average has been gradually shortened to about 20.5 km per gallon. This decline is due to the fact that the car is heavier, has a much faster engine speed, and has a powerful engine. It takes about eight times more energy to run a vehicle at 96 kilometers per hour than at 48 kilometers per hour. An amount of energy equal to the energy needed to accelerate the car's weight to 96 km / h should be absorbed by the brakes, mainly as heat, when the vehicle is stopped. Thus, much of the engine efficiency improvement is lost due to the way humans use the machine. Air conditioning of passenger cars also caused a decrease in the number of kilometers per gallon. This number of kilometers will soon improve as consumers change their preference for compact cars. However, the efficiency of the basic piston engine can no longer be greatly improved.

[Figure 8-7] The efficiency of an automobile engine is not perfect due to its weight and speed increase, but it is reflected in the number of miles per gram of fuel. Car makers say that the engine's thermal efficiency in the 1920s was about 22 percent. Today this is about 25%.

Even if all the cars in 2000 were powered by a charger charged with power from a central powerhouse, there would be no change in the overall fuel demand in the United States. The initial conversion efficiency at the power plant would be 35% compared to 25% of the piston engine, but it would be lost to convert the power into electrical energy (within the charger) and convert it back to power to drive the wheels Because. Current chargers have little room to improve their overall efficiency from 70% to 75%. Anyone who believes that all passenger cars are beneficial to power operation by everyone should consider the problem of increasing national power generation by about 75% as a necessary measure to run 100 million vehicles.

It is difficult to trace the savings made by the difference in efficiency of energy conversion, even if the difference is large, after the rail has been converted from a steam locomotive (10% maximum thermal efficiency) to a diesel locomotive (35% thermal efficiency) I can see that this happened. In 1920, the railroad is estimated to be about 135 million yuan. The efficiency of such a challenge is comparable to that of fluorescent lamps, and sometimes it is more efficient. This distribution means that the average efficiency of converting power to light is about 13%. To calculate the overall efficiency of converting chemical (or nuclear) energy into visible light, this percentage should be multiplied by the average efficiency of the power generation (33%), so the net conversion efficiency is typically 4%. Nevertheless, due to the increase in use of fluorescent lamps and famous lamps, the consumption of lighting in the country during the 1960s and 1970s was only doubled, and the consumption of lighting could triple.

[Fig. 8 - 10] The propulsion machine converts the energy of the liquid fuel into mechanical energy or kinetic energy, which is used for work and traffic. In the piston engine 5, the compressed fuel and air are exploded by electric ignition. The inflated gas pushes the piston, which is transmitted to the crankshaft. In the diesel engine 6, compression alone is sufficient to ignite the mixture of fuel and air. In the airplane gas turbine (7), the hot gases from the combustion chamber continue to expand and rotate the multi-stage air compressor as it flows through the turbine. The hot gases from the turbine provide kinetic energy for propulsion. The liquid fuel rou- tine 8 has an oxidant in addition to the fuel and does not depend on the air supply. Locate exhaust provides kinetic energy>

<Figure 8-11> New energy converters are being designed to use various energy sources. The fuel cell 9 converts the energy of the hydrogen or liquid fuel directly into electricity. This combustion of the fuel takes place in the porous electrode. In the recently proposed solar power plant 10, the sunlight reaches the specially coated light receiving plate, raising the temperature of the liquid metal to 500 캜. The heat thus collected is transferred to water vapor by a heat exchanger, which rotates the turbine generator as in a conventional power plant. It stores enough heat in the salt heat reservoir so that it can continue to generate water vapor even when the sun is covered by night or clouds. The NHD <turbine> (11) converts the energy of the hot, electrically conductive gas into direct power. In order to improve the electrical conduction of this hot gas, a small amount of <seed> substance such as potassium carbonate should be injected into the flame. Electricity is generated when the charged particles of this gas pass through a magnetic field by external magnetic force. The long-term goal is a thermonuclear reactor (12) where the atom of a light element fuses into a heavy element and releases energy. It is possible to capture high-speed charged particles produced by thermal nuclear reactions to produce power directly.

By simply looking at changes in ideal energy conversion efficiency, you will have some insight into the expected effects of a new energy conversion system under development. Two devices that have received much attention are fuel cells and MHD (magnetohydrodynamic) generators. Fuel cells convert chemical energy directly into electricity and the latter has the potential to be used as a high-temperature topping device that works with steam turbines and generators in power generation. A fuel cell has been developed which can <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> combustion < The output of the hydrogen-oxygen fuel cell produced by the Pratt & Whitney division of United Aircraft, used in the Apollo space program, was 20.5 V DC, 2.3 kW.

MHD generators have been developed as energy converters for the future for 10 years. In this machine, the fuel is burned at a high temperature, and a fuel such as potassium carbonate is sprayed to make the combustion products of the gas have electrical conductivity. This electrically conductive gas passes through the magnetic field at high speed and causes a flow of DC in the process (see Figure 8-11). If this MHD engineering can be developed, it will be possible to design a fossil fuel power plant with an efficiency of 45-50%. Because MHD requires very high temperatures, it is not suitable for reactors that form working liquids that are much lower in temperature than the working liquid temperature that can be obtained with a combustion chamber using fossil fuels.

If an energy source is developed at the right time, it is nuclear. There are currently 22 nuclear power plants operating in the United States. In addition, there are 55 nuclear power plants under construction and more than 40 orders have been placed. This year, the United States will produce 1.4% of its total power by nuclear fission, which will reach 25% in 1980 and 50% in 2000.

[Figure 8-12] The diagonal curve (left) bends exponentially over time. This curve shows how many times a doubling interval is needed to achieve a certain amount of increase. That is, if power demand continues to be doubled every 10 years, the demand for electric power will increase 8 times after three triple times, in 2001. An exponential growth curve is plotted on the opposite scale (right). If we reduce power consumption by half in the period A and then keep it for 10 years and return to the previous growth rate, the time required to reach the constant size demand B is twice the doubling period, It will not extend outside.

A nuclear power plant with an output of 1,000 MW is 10% more expensive than a fossil fuel plant ($ 280 million versus $ 250 million), but nuclear fuel is already cheaper than fossil fuel. According to some estimates, the value of coal is likely to double from now to 1980. One reason is that the new tonnages of coal produced per capita per day have been reduced to less than 15 tons from 20 tons already reached in 1969 due to federal safety regulations.

The electrical industry is characterized by its basic load, intermediate load (which is roughly equivalent to the sum of all the work done by people at home and work from 7 am to midnight), and peak load (seasonal load only a few percent of total demand) Is a new era in which we must rethink the way we should pay for it. In the past, the electrical industry used the newest and most efficient facilities to cover basic loads, and older and smaller facilities were used to cover the daily needs of the day. However, in the future when more new facilities will emerge, the facilities that currently cover the basic load are too large to easily operate and can not easily be downgraded to accommodate intermittent use because it is difficult to stop.

Therefore, there is a need to build a new type of flexible power generation facility that links industrial gas turbines to generators that produce low-pressure steam that is required for the combination of steam turbines and power plants using waste heat from gas turbines. (General Electric and Westinghouse Electric Company) are currently recommending this type of combination. Gas turbine facilities can reach maximum loads in less than an hour, although they are slightly less efficient than the most efficient conventional large facilities, and can be constructed at a lower cost per kWh. To meet the short-term peak demand, the electrical industry is increasingly turning to gas turbines (gas turbines can be fully operational in minutes if there is no waste heat boiler) and pumped hydro power generation systems. In the latter case, the electricity produced when not in peak demand can raise water to a reservoir at a higher location and release it when needed to produce electricity.

(Westinghouse Inc.) recently estimated that in 1970-90 the US power industry would have to build a new facility three times more than the current facility output of 1,000 GW (10 ⁹ W), or about 300 GW. Of this new facility output, 500 GW, or half, will be used to cover the expected increase in base load, and 75% of this 500 GW will be due to nuclear power. More than 400 GW will be used to cover the ever-increasing intermediate load, and a significant portion of that will be supplied by the gas turbine. The new maximum demand of around 170 GW is believed to be supplied by the gas turbine and the pumped storage system at a 10: 7 ratio (Westinghouse Inc.).

[Figure 8-13] The exhaustion of a resource can be read in the curve on the left. That is, if 0.1% of the world's oil resources are currently used, if the doubling period is 10 years, all of the oil resources will be exhausted within 10 doubles, ie, less than 100 years. According to the table on the right side, although there is a big difference in the estimated amount of resources used so far, the ultimate exhaustion period does not change much.

This expectation can be thought of as wisdom. If so, what can innovative wisdom offer in the 1990s, or what might be the new effects that will affect power generation in 2000? First and foremost, there are optimists who believe that a prototype nuclear fusion plant will be built in the 1980s and a full scale will be built in the 1990s. In a sense, however, this is merely a view of the conventional wisdom as an accelerated time unit. Those who really want to try innovative approaches ask why we do not start to develop the technology to get energy from the sun, wind or tide.

Many are still recalling the 1930s (Passamquoddy) plan, which is being discussed again, and the new plan is the Bay of Fundy between Maine and Canadier, (Less than 1/3 of the turbine generator output) using an average of 5.4 m of tidal power. A 240MW tidal power plant, currently in operation, was recently launched by the French government on the estuary of the Languedoc River, with an average of 8 meters in tidal range. How many tidal energies would you get if you developed both of the appropriate bays and estuaries in the United States? All estimates should be accompanied by sufficient evidence, but by relatively modest estimates it is thought to be around 100 GW. But I have just seen that the electrical industry has to increase this output by 10 times to meet the demand in 1990. We can conclude that tidal energy is not qualified to be a major innovative energy source.

The energy that the square feet of the American land receives from the sun will be the same amount of power output in the next 100 years, when power demand is doubled every decade.

[Figure 8-15] Three incremental curves were compared. Curve A is an exponential increase curve. Curve B is an extension of the doubling period by 20%. In curve C, the amount of increase during this doubling period is always constant.

What about the wind? A study by authors a few years ago (Occluder State University) found that wind in Orcler Homeric region is about 18.5 W per square foot of ground when it is in a direction perpendicular to the wind. This is roughly equivalent to the amount of solar energy per square foot of Ohl K. Homer's average of 24 hours a day under all weather conditions, all seasons. Turbines rotated by propellers can convert wind power into electric power with an efficiency of 60 to 80%. Like tidal energy and other forms of hydropower, wind power has the great advantage that it does not release waste heat into the living quarters.

The difficulty in using wind power results in the problem of energy storage. Of all natural energy sources, wind is the most variable. If you want a power plant with a constant output, you must acquire and save that energy when the wind is blowing. Unfortunately, no technology has been developed to produce practical energy storage media. The charger is not a problem either.

One of the promising plans is to decompose water into hydrogen and oxygen using the variable electrical output produced by the wind turbine. These gases are stored under high pressure and recombined at a constant rate in the fuel cell to produce power (see Figure 8-16). Instead, this hydrogen can be burned in a gas turbine to rotate conventional generators. (Rocketdyne Division, North American Rockwell, Northamerica Rockwell), a hydrogen-fueled rocket engine made by the company for the Saturn Moon spacecraft, Which can be used to generate the required hot gas ejection required to power the turbine. In the Rakiddainbu, water-cooled gas turbines can operate at higher temperatures than conventional fuel-burning gas turbines and predict that the overall efficiency of the plant can reach 55%. If the Rakidyne method is successful, you can use any source of hydrogen. Wind-driven hydrogen kits Gas turbine power plants will be innovative enough to please even the most exotic people.

<Figure 8-16> Winds as energy sources are attractive because they do not add extra heat to the environment, as is the case for fossil fuels or energy from nuclear fuel. Like capturing solar energy, wind is available anywhere, other than hydropower or tidal energy. Unfortunately, however, the wind is also too much change. To use this effectively, the energy captured when the wind is blowing must be stored and released somewhat continuously. One way is to break down water by electrolysis using the power produced by the wind. Then, the stored hydrogen and oxygen can be supplied to the electrolysis tank at a constant rate to produce DC. This direct current is converted into alternating current and supplied to the electric wire. The electricity produced outside the peak demand period elsewhere can be used for electrolysis by supplying it to the electrolysis tank whenever there is no wind.

On the other hand, most of the proposals using solar energy seem really monotonous. Recently, Arizona University has made considerable direct proposals to the Arizona Power Authority, the Elden Mayen and Marjorie Mayen of the Optical Science Center. They suggested that if they efficiently collected sunlight reaching 14% of the western desert region of the United States, it would translate it to 1,000 GW, that is, energy equivalent to an increase in energy demand, typically between 1990 and 1990. They believe that within the current technology range, they can design a mass storage system that stores solar energy as heat at 574 ° C, which can translate into a total efficiency of 30%.

The key to this plan is in recently developed surface coatings, which are highly absorbent to sunlight and emit little of the infrared portion of the spectrum. The heat collected during the day to resume energy release for 24 hours a day resists the molten salt at 574 ° C. The heat exchanger transfers this stored energy to steam at the same temperature. A thermal storage tank for a 1000 MW power plant will have a capacity of about 300,000 gal. (May 25th) suggests that the electricity industry and the government should immediately design and construct a demonstration plant with 100MW output near Arizona Humor (Yuma). The width of the light plate required for this level of power plant will be 3.6 million square meters (slightly larger than 1 square mile). After the necessary developments are made, it is estimated that it will be possible to build a solar power plant with an output of about $ 1.1 billion, which is about four times the cost of the current nuclear power plant and a power output of 1,000 MW. As they pointed out, "the solar power has an economic problem of purchasing by facility funds, not by operating expenses." Nonetheless, solar power plants with a 40-year life span are priced at an average of 1/2 cent per kW / h They are estimating that they can produce power.

[Fig. 8 - 17] Peter Glazer of Arthur D. Little proposed a solar collector on a rectified orbit. The space station, which is 29,000km above the equator, is fixed relative to the ground station. An 8 × 8 km light receiving plate will accept about 8.5 × 10 ⁷ kW of solar radiation. A solar cell with an efficiency of about 18% converts it to a power of 1.5 x 10 ⁷ kW, which is converted to microwaves and sent to Earth. On Earth, this translates back to 10 ⁷ net kW, or enough power in New York City. The coverage area of the receiving antenna will be about 6 times as wide as required for a coal-fired power plant with the same output, or about 20 times as wide as required for a nuclear power plant.

A more exotic plan for exploiting solar power has been developed by Peter E. Glaser of Arthur D. Little, Inc. His idea is to put a lightweight solar panel on a synchronous orbit about 3,500 km from the Earth and keep it on for 24 hours a day. Solar cells (under development) collect radiant energy and convert it to power at 15-20% efficiency. This power is converted electronically into 85% of the microwave energy in orbit, which is still possible today. This microwave will be chosen as the wavelength that can pass through the cloud with little or no loss and will be collected by a suitable antenna on the ground. With current technology, microwave energy can be converted to power with an efficiency of about 70%, and it can reach 80 ~ 85% efficiency. (Glazer) estimates that New York City's energy demand of 10,000 MW (= 10 GW) output power plants will require 8 square kilometers of receiving plate. The receiving antenna on the ground is slightly larger than 9.6km2. The microwave energy of this beam will be no harm because it is comparable to the intensity of sunlight. Glazer believes that this system will cost about $ 500 per kilowatt, or about twice the price of a nuclear power plant, assuming that round-trip space travel is possible for the construction of these satellites. The entire space station is 2,265 t, which is slightly lighter than the kit at launch time.

To meet the expected total electricity demand of 2,500 GW in 2000, 250 space stations of this size would be needed.

The great advantage of energy plans based on solar energy collected from the wind or the Earth's surface is that it may sound like an overpower today, but it does not add heat to the ecosystems of the earth. They say it's an invariant energy system. . The solar energy collected in the orbit is not a constant energy system in strict sense because most of the radiant energy blocked at 3,500 km altitude is a radiant energy that otherwise would not reach the earth. Only the energy collected when the sun's light-receiving plate is in line with the sun and the center of the earth does not heat up the earth's heat. On the other hand, the receiving plates in outer space will emit much less waste heat to the environment than fossil fuel or nuclear power plants. All but 20% of the total energy of the microwave to the Earth is converted to useful power. Of course, when this power is consumed, it is released into heat.

Recognizing the macroscopic nature of invariant energy system development, one has to be aware of what a certain amount of exponential growth means. The doubling process is a dreaded phenomenon. The amount of increase during any one doubling period - whether it is energy consumption, population, or land area occupied by freeways - is the same amount that it increased during its past past. For example, the next boats will contain as much fossil fuel as all the fossil fuels that have been mined on the Earth so far. Over the next decade, the United States will produce the same amount of power that has been produced since the beginning of the era of electricity.

The curve of this exponential increase is usually indicated on the opposite scale to indicate the whole. By specifying an appropriate value for both axes of the opposite scale, we can obtain a curve representing the number of boats required to reach saturation, or depletion, from the position of any known or imaginary percentage (see Figure 8-13 on the left) ) As an example, let's assume that 0.1% of the total fossil fuel reserves in the Earth have been mined so far, and that this amount has been doubled every 10 years. If this speed continues, you will be able to digest all of this fuel within a doubling period of ten times, in less than a hundred years. Of course, we do not know for sure how much of the total fossil fuel reserves have been mined so far. Let's assume that it is relatively small and 0.01% is mined, not 0.1% so far. According to this curve, in this case, all of them will be mined 100% within a period of 13.3 times, 133 years. In other words, even if there is a difference of 10, 1,000 or 100,000 times the amount of fuel mined to this moment, the timing of complete exhaustion does not differ much. Thus, even if only 1% (1%) of the total fossil fuel reserves of the Earth have been mined, even if the amount is doubled every 10 years, the total reserves will be exhausted in 266 years (Figure 8-13 See figure at right). It should be pointed out that the actual amount of mining depends on the type of fossil fuel, and that the 10-year period is only an example.

The key factor in estimating how many times the United States will tolerate a doubling of electricity demand every two decades (which is the actual rate of increase) is probably due to the fact that fuel supply - If so, it is almost infinite - not heat, but the effect of the environment on the conversion of fuel to electricity and ultimately to power. For the sake of discussion, let's consider only the heat content of the power actually consumed, ignoring the burden of waste heat from fossil fuel or nuclear power plants. By 2000, most of the power would be produced in a huge power plant for miles away from the coast, and it would be possible to imagine a game that would be able to release waste heat to the surrounding sea without damaging it (at least for some period of time).

In 1970, the United States consumed 1.55 billion kWh / h. If this were transformed into heat (and indeed it was) and evenly distributed throughout the land of the United States (which was not really the case), the energy released was 0.017 W per square foot. At the present rate of doubling, power consumption is increased ten times every 33 years. After the next 99 years, or ten times the number of doubles, the amount of heat released will be slightly less than 17 watts per square foot, or 18 to 19 watts per square foot, the average energy the United States receives from the sun 24 hours a day. Before doing so, you will need to change your current energy consumption pattern or develop the necessary technologies for an invariant energy system.

Let's examine what would happen if we changed the increasing pattern of energy in a way that seemed to be quite pronounced. Consider an incremental curve with an extension of 20% for each doubling period (see Figure 8-14). In the exponential growth curve, the energy consumption is increased by a factor of 10 by a factor of 3.32 times, or 33 years. The same increase in the curve of the increase rate is 10 times, which takes five times, that is, 50 years. In other words, it is only 17 years. The extension of consumption to 100 times is only 79 years (ie the difference between 145 and 66 years).

Another way is to significantly reduce current consumption levels and keep them at a low level for a certain period of time so that they do not increase and then return to the current rate of increase. If you reduce power consumption by half immediately, keep it for 10 years, and then regain the same growth rate as before, the time it takes for a 100-fold increase in consumption is only 20 years, extending from 66 to 86 years (See Figure 8-12, right).

In order to expect a long-term effect, the amount of increase needs to be the same curve, that is, a curve that increases by the same amount every original doubling period. On these curves, it would take nearly 1,000 years, not 100 years, to be predicted as a doubling every ten years for power output to reach the same level as the radiation received from the sun. As long as the invariable energy system does not supply much of the electricity demand, it is almost certain that the current rate of doubling can not continue for another 100 years, but how this system will look is still a problem hidden in the future.

As described above, the present invention provides a method and means for installing a nuclear waste disposal double-structure block tank marine tunnel transportation device (941) including marine deuteromagnetism in the marine environment to meet the electric power demand with the invariable energy system, The means of eco-friendly energy production of the present generation and all the so-called business people who have made the best efforts to extend exhausted resources should be accompanied by cooperation and efforts to join them for their descendants.

The present invention is based on the idea that even when the sea floor depth of the ocean is 10 meters, the raft or the marine vessel which is sunked by the typhoon and the waved wave, and the deep sea area where the sea floor depth is about 10 km, In the bottom layer, a dam hydroelectric turbine generator is combined with a water turbine tidal power or submersible control system. The turbine generator is connected to the submarine water depth gauge, or the turbine of thermal power generation turbine is combined with other power generation facilities. (2) Nuclear power plant (811) inside reactor body (1) of nuclear power plant equipped with dual structure block tank dust collector (811) Permanent disposal method of long-term nuclear waste with anti- To implement the waste treatment of the nuclear waste.

Referring to FIG. 21, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is installed in the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. (Nuclear Power Plant) Operation of Nuclear Power Plant Nuclear power generation facility (811) of elementary conventional nuclear power plant showing construction of one embodiment Example of conventional nuclear power plant showing decommissioning aspect of thermal power generation operation method of conventional thermal power plant Nuclear power plant Operation of nuclear power plant Thermal power generation of thermal power plant Disassembly aspect of operating method Construction of road,

Referring to FIG. 2m, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is provided inside the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. Nuclear power generation facility of nuclear power plant (811) The nuclear power plant of the conventional nuclear power plant (811) The nuclear power plant of the conventional thermal power plant The operation of the turbine rotary blade (267) and the steam locomotive (1) of the nuclear power plant showing the operation mode as a side view, the operation of the thermal power generation operation of the thermal power plant of the nuclear power generation facility (811)

Referring to FIG. 2n, a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention includes a nuclear reactor main body 1, a nuclear power plant 1, Nuclear Power Plant Operation of Nuclear Power Plants In a nuclear power plant of a conventional nuclear power plant showing the essential constitution of the embodiment, a nuclear power plant unit 811, a steam pipe 779, and a high-temperature high-pressure steam inlet 780 of steam or a strong gas, The nuclear reactor 783 is decomposed into a side view and a cross-sectional view of the nuclear reactor of the conventional nuclear power plant. The nuclear power generation facility 811 is disassembled. The thermal power generation operation of the side power generation plant.

Referring to FIG. 2O, in the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, The nuclear power generation facility 811 is connected to the conventional production power central control room 781 and the transmission measuring room transformer room 782 through a connection structure The thermal power generation of the thermal power plant showing the operation methods of the thermal power generation and the operation of the nuclear power plant,

As shown in FIGS. 2L and 2M, in the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste, the conventional nuclear reactor of the nuclear power generation facility 811 is operated before and after failure A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and the condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and the core 791, the drum 792 and the reheater 793, the dust collector 794 of the thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

As shown in FIG. 2n and FIG. 2o, in the nuclear reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the conventional nuclear reactor of the nuclear power generation facility 811 is operated A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and the condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and the core 791, the drum 792 and the reheater 793, the dust collector 794 of the thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

Referring to FIG. 2P, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Nuclear power plant (811) Nuclear power plant road,

As shown in FIG. 2P, in the reactor installation of the nuclear power generation facility 811 during the operation of the nuclear power plant, a double structure inner block tank 596 for treating nuclear waste is connected to an iron plate 597 of high strength stainless steel, The steam 780 containing the radiation material into the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector 794 provided as a tank 599 and provided in the form of a dual structure block tank 598, And the reactor pressure vessel 813 is provided with a nose 791 on the core 791 centered on the core 791 composed of the fuel assembly 671 and the control rod 798. In the reactor pressure vessel 813, A control rod guide tube 798e and a control rod drive housing 798a are disposed under the core 791 and a plurality of core shrouds and a plurality of jet pumps 325 are disposed around the core 791. [ There are all kinds of irrigation facilities. Uigae construction machinery transporter committed to being composed of nuclear power seolbibu 811 is connected to the reactor construction equipment,

Referring to FIG. 2Q, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, The nuclear power plant 811 of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment is divided into the nuclear power plant 811 of the elementary conventional nuclear power plant, Decomposition side strap configuration Road,

     As shown in FIG. 2Q, in the nuclear reactor power plant of the conventional nuclear power plant, the nuclear reactor power plant of the nuclear power generation plant 811 is reliably stopped in the boiling water reactor plant 802 when the engineering safety system is abnormal If an accident occurs in the piping of the reactor cooling system and the cooling water 287 of the core 791 is lost (coolant loss accident), an emergency core cooling system (ECCS) is installed to prevent the fuel from being damaged The system consists of a high-pressure core sprinkler system, an automatic decompression system, a low-pressure core sprinkler system, and a low-pressure sprinkler system connected to engineering safety systems in a boiling water reactor facility (802).

      In case of fuel breakage, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged to the outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

Referring to FIG. 2r, a nuclear reactor power plant main body 1 having a dual structure block tank dust collector for treating nuclear waste according to the present invention is installed in an internal nuclear power generation facility 811, The diesel engine and the generator according to the operation of the hydroelectric power plant showing the conventional configuration of the hydroelectric power plant that provides the recovery, the diagonal construction of the electric motor pump for supplying the power of each compressor and the pump,

As shown in FIG. 2 (r), the nuclear power plant (1) of the nuclear power plant, the nuclear power plant (811) of the nuclear power plant, and the hydrothermal power plant (943) A hydro turbine pump turbine 943a, a large hydroelectric turbine Pelton turbine 943b and a large hydroelectric turbine Francis turbine 943c are connected to a large hydraulic power generator seesaw hydroelectric power plant 944, And at the same time the marine seesaw hydropower plant 943 facility of the hydroelectric power plant is connected to the power line 95, the transformer 96, the power line 71, the air compressor 80, the high pressure storage tank 145, The motor shaft of the nuclear power plant is divided into a connecting shaft and a distributing shaft of a motor motor body 192, a compressor body 263, a turbine 267, an engine 268, an intake port 269, a watertight passage 270, Nuclear reactor facility main body (1) Internal nuclear power generation facility (811) It is made up of marine seesaw hydroelectric power station (943) connected to the structure of the equipment to provide a hydroelectric power station at the time of recovery after failure of the entire nuclear power plant operation.

Conventional Nuclear Power Plant Reactor Facility Main Unit (1) Inside Nuclear Power Generation Facility (811) Hydroelectric power plant's hydropower distribution facility is composed of dams constructed to control flood and drought in the reservoirs and rivers of highlands The distal end portion of the introducing pipe 191 having a water pressure located at the intermediate position between the multipurpose dam 680 and the multi-purpose dam 680 storing the water of the flood control equipment such as an underwater dam is connected to the through hole of the dam 680 And a rear end portion of the introduction pipe 191 is connected to a suction port 269 of the head tank 189 having a pressure and a plurality of introduction pipes 191 are connected to the discharge port 270 located at the rear end of the head tank 189, And the flow rate of the pressure, which is supplied to the inside of each of the plurality of hydraulic generators, is moved inside the hydroelectric power plant located at the lower end of the multipurpose dam 680, It consists of a hydro generator equipment for production.

Referring to FIG. 2, the nuclear reactor main body (1) of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention comprises an internal nuclear power generation facility (811) The hydro-electric generator inside the hydroelectric power plant showing the conventional structure composed of the hydro-electric power production control unit for restoration, the pump aberration in the Francis aberration and the Pelton aberration, and the constitution diagram of the turbine and the guide vein inner- ,

As shown in FIG. 2S, the nuclear power plant (1) of the nuclear power plant is equipped with an internal nuclear power plant (811). The nuclear power plant (943) of the hydroelectric power plant The power generation facilities of the marine seesaw hydroelectric power plant 943 include a hydraulic aquifer 943a for a hydroelectric power plant, a Phelpton aberger 943b for a large hydroelectric power plant, and a Francis turbine 943c for a large hydroelectric power plant. At the same time, large-scale hydropower generator Shizuo hydroelectric power plant (944) generates hydroelectric power by generating hydraulic pressure inside the generator (944) to generate mechanical energy. A plurality of aberrons and turbines 267 for rotating the turbine 267 to produce power, a generator 944 for providing the power conversion produced from the aberrations and turbines 267, A plurality of turbines 267 and a generator 944 are connected to an upper end of a rotating shaft 198. The turbine 267 and the generator 944 are connected to each other by an electric motor A lower portion of the upper rotary bearing 944d is positioned at a lower portion of the device 944b for pushing the ring tubular feathers and a stator coil 944f and a lower portion of a stator 944e are provided below the device 944e, The frame 944g and the central stator 944h are positioned and the electric wire 71 is sandwiched between the central stator 944h and the fan 195 is positioned below the central stator 944h and the fan 195 A low speed cooler 944i is provided below the braking device ring 944j and the braking device jack 944k and the low speed rotation bearing 944l and the engine generator 944m, the turbine rotation support 944n, (944p) The rotation axis (198) An armature coil for a generator, which is a non-rotating coil provided along the circumferential surface of the rotor coil, and a plurality of aberrators and a turbine 267 for providing a position to the lower end of the rotating shaft 198 And the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydroelectric power connection structure power production control unit 811b and at the same time the Francis turbine 943c The Peltton turbine 943b has a turbine 267 and a suction port 269 and a discharge port 270. The inlet port 269 and the discharge port 270 communicate with each other in the casing 141 and with a pressurized flow rate within the hydraulic power generator 944, The pump turbine 943a can control the distribution to the respective industries by adjusting the voltage in the substation of the transformer 96 of the substation, which is the power transmission unit, while generating hydroelectric power by rotating the aberration, The main pump 265 is controlled by opening and closing the main valve 265 to operate the pump water turbine 943a while generating hydroelectric power and move the water to the water storage dam 680 located at the upper part of the power plant (811) of the nuclear reactor facility main body (1) of the nuclear power plant, and at the same time, the nuclear reactor facility (811) of the reactor main body (1) of the nuclear power plant is provided with the hull position Control of the construction construction machinery and the hydro-hydro power production control unit of the hydro-hydro power generation, control of the power transmission, prevention of the harmful red tide prevention control, prevention of disaster prevention, control of the fish and shell scattering control unit, and control of the hydrological control of the dam. Connection axis connection structures.

(943b) for a large hydroelectric power plant and a Francis turbine (943c) for a large hydroelectric power plant are provided in a pump aberration (943a) for a hydroelectric power plant constituted by an offshore hydroelectric power plant (943) A head tank 189 serving as a pressure tank for providing a position above the power generation plant 943 and a suction port 269 located in front of the head tank 189 are provided with a connection structure with a head tank 189, The turbine 264 and the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydraulic power connection structure power production control unit 811b The turbine 267 is different in shape from the Francis aberration 943c to the Pelton aberration 943b to the marine seesaw hydroelectric power plant 943 while the suction port 269 and the discharge port 270 are connected to the inside of the casing 141 And pressurized flow provide for movement within hydraulic power generator 944 The pump aberration 943a can control the flow rate of the flow rate stored in the stream by adjusting the flow rate of the flow rate stored in the stream, The hydraulic pump 943a is operated by controlling the opening and closing of the main valve 265 by the electric power supplied from the nuclear power plant while simultaneously generating hydroelectric power to the marine seesaw hydroelectric power plant 943, 680 of the reactor main body 1 of the nuclear power plant, or by the dispensing apparatuses of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant, The hydroelectric power generation unit 941 may be connected to the hydroelectric power generation unit 944 in the power generation facility unit 811, The impeller 143 may be attached to the end of the rotating shaft 192 of the motor body 192 and may be formed of a prime mover having a connection structure with the power pump 304. At the same time, To the distribution apparatuses of the nuclear reactor main body 1 of the nuclear power plant 1 and the internal nuclear power generation facility 811 of the nuclear reactor main body which are formed by the distributing and inputting apparatuses of the internal nuclear power generation facility 811 as the urine site equipment.

Referring to FIG. 2, a conventional diesel engine unit (1) of a nuclear reactor plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention comprises a diesel engine External Dimensions and Power Motors Model Construction of Internal Disassembly and Assembly of the Motor Body (192)

The power motor motor body 192 provided in the nuclear reactor main body 811 of the nuclear reactor main body 1 of the nuclear power plant is provided with a hood 193 and a fan 194 195 and the body frame 196 are provided with a body front reinforcing steel plate 197, a rotary shaft 198, a rotor assembly 199, a front rotary support 200, a stator assembly 201, a motor protection casting frame 202, A terminal box 203, a lifting bolt 204, a terminal box cover 205, a rear rotation bearing 206, a rear reinforcing steel plate 207, a gap 208, a fan protection cover 209 and a rotor iron core 210 And a stator core 211 and a stator winding 212. The hydroelectric power generation is generated by a power transmission unit and a diesel engine generator 268 and is wound around the pump and the compressor by a rope It is equipped with a tackle winch (137) for connection and disconnection of the gate with a chain, Consists reactor equipment body (1) connected to the dispensing coupling input device connection structure of the internal atomic power seolbibu 811.

The electric motor body 192 of the distribution and connection device connecting structure of the internal nuclear power plant 811 of the main body 1 is provided with a hood 193 and a fan 195 and a body 192 in a snap ring 194 The cast body body frame 196 is provided with a body front racket 197 and a center rotary shaft 198 along the periphery of the rotor assembly 199 and a forward bearing 200 And the stator assembly 201 is formed inside the body frame, the terminal box 203 and the motor body 192 are fixed to the outer side surface of the casting frame 202 for protecting the motor, After the threaded tabs 167 having a predetermined dimension are formed in consideration of the weight of the object by the electromagnetism force so that the lifting bolts 204 can be lifted to lift the object, the lifting bolts 204 in the form of O- The terminal box 203 is provided with an attachment bond to the tab 167, The terminal box cover 205 is attached after the screw tabs are installed at four positions and a gap 208 is formed in the rear bearing 206 and the rear racket 207 at the rear of the rotary shaft 198 and a fan cover 209 are mounted on a fixed pinhole 20 at a forward portion of the rotary shaft in a link band 249 connecting the crank 248 and the crank 248 attached to the rotary body, (Square × 6 mm × 6 mm, length: 60 mm, 254) is fixed to a pin hole (width × length × height × A length of 3 mm x 3 mm x 3 mm x 80 mm, 20) is machined in half by a fixing pin dimension of the rotary shaft fixing pin hole and the fixing pinhole, the fixing pin 254 is screwed into the fixing pin hole By means of the Lena group, the individual bearings and bearings provide for disassembly and assembly, but at the same time they are fixed to the motor body 192 facility And the stator core 211 and the stator winding 212 are attached to the inner surface of the body frame and are provided with the electric motor pump formed to be attached to the processing hole 20 of the fixing pin 254 of the impeller 143 without the plow 250, 251 and the belt 252 are mounted on the circumference of the piston 127 with a plurality of cylinders 126 separated by a compressor to form a pump and a compressor. to be.

: 상기 형태, 129)로 뺑글뺑글 앞산 계곡으로부터 출발하여 360°로 회전시켜서 다시 앞산 계곡으로 설치되되, 단 산정상 산맥을 따라 지나는 소방방재배관라인(168)에는 상기 빗장걸이 장금장치(129) 형태의 방재수로(17)의 집수정탱크(34) 하부 위치에 레듀사(35)와 배관연결부속엘보 또는 티이엘보(44)로 방재배관라인(168)에 연결된다.As described above, according to the operation of the impeller of the motor motor rotary shaft 198, the booster pump control box 2 installed at the left side of the pump and the booster pump control box 2 installed in the industrial machine room in which the water pressure of the incoming fire water is compressed and stored, 3) and the discharge joint pipe 4 made of a material capable of withstanding high pressure is referred to as a manifold or a head tank 189 and a predetermined amount of fire-fighting water conveying means (for example, High mountain top to low mountain as an agate methane type plastic vinyl coating material, 350mm diameter flow tube can be transported by manpower, light and long life after being selected. 14) is formed and the piping 14 is connected to the piping 14 and the disaster prevention system 14 by a predetermined standard (width × height × width × height = 1 × × 1M) The bolt locks on the door (17) at a constant angle of inclination (16) 1 ° ((

The fire-fighting piping line 168, which is installed along the mountain-top mountain range, is installed in the form of a bolt latching device 129 Is connected to the disaster prevention pipe line (168) by a reducer (35) and a piping connection attached elbow or tee elbow (44) at the lower position of the water collecting tank (34)

Referring to FIG. 2U, a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention includes a main body 1 of a nuclear power plant, an internal nuclear power plant 811, The control block diagram and BF model are shown in the schematic block diagram of the pump front and front view and the cross-sectional multi-stage pump system concept; Speed control method, and 3-pump direct-injection-start-type system.

As shown in FIG. 2U, a distributing and inputting device for a nuclear reactor installation of a nuclear power plant constituting the nuclear reactor internal power generation unit 811 of the nuclear reactor facility main body 1 of the nuclear power plant is provided with a control block The pump power source 272 is divided into the control power sources 273 and the control power source 273 is operated in the emergency operation mode. (M / C) switch contact of the pump power source 272 and the inverter contact of the inverter 47 after being contacted with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontrol unit 276 by the micropower supply circuit 275 of the control power source 273 so that the microcontroller 277 and the switch input circuit 58 are connected When the input setting And the motor overload signal input circuit 280 outputs a signal to the (M / C) drive signal contact output circuit 279 and the motor overload signal input circuit 280, MCC B + T HR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the micro control unit 276, And a discharge pressure transmitter 284 is connected to the pressure sensing circuit 282 and connected to the inside of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal after connection, After the intake / discharge pressure switch 285 is connected to the external state input circuit 283 and the input circuit 283 is again connected to the microcontroller unit 286, Lt; RTI ID = 0.0 &gt; 276 & Type multi-stage pump operation modes is provided as an automation is composed of a nuclear power station connected to the distribution chute of a nuclear reactor plant having a structure of double nuclear waste disposal building block tank for the dust collector.

Referring to FIG. 2 (b), a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention has a conventional multi-stage multi- In the control system using the microcomputer of the pump and the inverter system of the digital pID control system, an unmanned camera of the control system is installed, and the inverter system in which the fire water is discharged from the injection nozzle is combined with the equipment of the control system. Operation Configuration Road,

As shown in FIG. 2 (b), the distribution input device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor installation main body 1 of the nuclear power plant is provided with the disaster- An inverter system in which an unmanned camera 184 of a control system is installed in an inverter system of a control method using a microcomputer and a digital pID control system of the preventive and controllable multi-stage pump 8 and fire water is discharged from the injection nozzle, (1) of a nuclear power plant to which the equipment of the fire extinguisher is attached, a fire body (166) in which a flood control process is formed is burned, and fire water in the fire body nozzle body is held inside the fire extinguisher, Stored in the fire extinguisher body 164 is stored and discharged simultaneously to the outside of the extinguisher body, The unmanned camera (not shown) installed at the height of the electric pole around the fire scene when the discharge pouring water 38 and the discharge pouring water curtain water film 39 are burned out at a moment when the burning pillar 237 is removed, 184 in order to display the situation at the time of fire on the monitor 52 through the information detection function of the pump control server 51 of the multi-stage multi-stage pump 8 control system 150, 8) is characterized by a digital control system and an inverter (47) consisting of a distributing and inputting device connection structure of a nuclear reactor plant including a speed control system and an algebraic control system.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor installation of the nuclear power plant has disaster prevention water, disaster prevention water, The control material or the disaster prevention material replacing the disaster prevention yarn is a natural loess or powdered yellow loam, and is a transportation equipment for transporting disaster prevention material, such as a fire fighting helicopter and a fire truck. The transportation equipment uses a basket (42) Disaster prevention waterways (17) in river streams with abundant disaster prevention materials or reservoirs or reservoirs that have a certain amount of disaster prevention water are transported and transported a number of times in order to evacuate the national disaster prevention fire. It is fortunate that if the initial evolution is carried out at this time, it will be declared as a disaster area if the evolving activity proceeds for more than a week. As a result of the need for prevention of disasters caused by disasters, which is a collective term for all disasters that are not declared as a disaster area, the development of disaster prevention has been progressed by the research and development of double structure block tank dust collector Research and development are underway in the distribution shaft and the connection shaft which are formed in the nuclear reactor main body (1) and the internal nuclear power generation equipment section (811) of the nuclear power plant.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor facility of the above nuclear power plant is designed to protect the life, The present invention provides the disaster prevention technology of the disaster prevention system of the present invention, and it is possible to provide the disaster prevention technology of the present invention by using the conventional fire fighting equipment, communication equipment and transportation equipment as advantages and disadvantages, Of the above-mentioned fire fighting equipment, an air balloon rubber air hose, a rubber hose to a wire rope, and other equipment to prevent a large-sized fire, And a tube nozzle processing hole formed by a hose and a nozzle body of a double pipe structure.

As shown in FIG. 2 (b), in the high-pressure type multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant, the fire nozzle (10) The disaster prevention nozzle is a small size pipe (14), a disaster prevention hose (9) that is made of a mixture of air (gas) and liquid, and a disaster prevention nozzle ), A disaster prevention nozzle (10) connected to the rear end of the piping of the high pressure multi-stage pump (8), a cable type disaster prevention nozzle (10), and a disaster prevention nozzle (10) A nozzle 18 is attached to the nozzle support frame 11 and the hook 13 and a spring 186 is attached to the wire rope 19 so as to impact the lug 21 and the shackle 23 for the safety pin, The nut 25 and the washer 26 as the bolts 24, The system including the high performance submersible pump 36 and the high pressure bottom-up pump control device by the mobile phone 82 of the communication means and the cable car 256 engine 226 after assembling the plate 165 and the flange 28 (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste.

As shown in FIG. 2V, the high-pressure multi-stage multi-stage pump 8 of the nuclear reactor plant includes a plurality of ejection nozzles 38 ejected into the nozzle gap 15, A partition wall 39, a water film or a plurality of radiation curtain water films 39 are arranged in a reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for providing fire suppression for life- ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the multi-stage, multi-stage multi-stage pump (8) of the high pressure multi-stage multi-stage pump (8) for connecting the distributing and inputting apparatus of the reactor plant of the nuclear power plant has fire water The conventional high-pressure type multi-stage pump is a water supply system for supplying water from a low place to a high place by watering. In a step drive system in which each pump is controlled to be turned on and off, It is a trend to change to an inverter drive method for drive control. The control system for efficiently controlling the driving of the multi-stage multi-stage pump of high pressure is such that the high-pressure multi-stage multi-stage pump 8, as shown in the figure, The pump 8 is equipped with a double structure block tank dust collector for treatment of nuclear waste, in which a plurality of high performance submerged pumps 36 are provided at intervals of 160 meters in a stepwise manner after the elevation of the elevator (1) of a nuclear power plant.

As shown in FIG. 2 (b), the high-pressure three-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor installation of the nuclear power plant is equipped with such a high- If so,

Firstly, most of them are monitored and controlled independently in the off-line. Therefore, the burden on the operation of the high-pressure type multi-stage pump is increased in a place where the worker or the worker is difficult to access and in a dangerous place. Second, since the switch button is used, And the third is that it is difficult to apply the system for managing the entire system when the system is dispersed in a plurality of places. In the fourth place, a plurality of high-pressure multi-stage multi-stage pump 8 control system 150 is manufactured and installed It is time consuming and costly to perform the independent test for setting the initial value and initializing the program.

In some prior arts for solving the above problem, firstly, in a high-pressure type multi-stage pump remote control system using a public telephone network, an alarm signal is transmitted to a central control server While the unmanned camera 184 at the same distance as the installation position of the electric pole is spaced apart by 50 meters outside the pipe nozzle industrial site, Inline high pressure bottom-up type, which has communication means of circulating water supply device, can be installed in a large number of neighbors in the inline high-pressure bottom-up type having the communication means of the circulating water supply device because the gas is supplied continuously, A high-pressure bottom-up type wired / wireless communication unit is provided and connected to the control system 150 And a helium (176) gas is formed into a plurality of hoses through the intake port and the exhaust port into the above-described advection balloon (77) and the airship (78), so that a nuclear power plant having a dual structural block tank dust collector In the "pressurized water supply operation management system", the load distribution of the reactor installation main body 1 is provided. At the same time, in the "pressurized water supply operation management system", the operation of the pneumatic water supply operation facility is grasped by using the Internet network 50, A management sub-system for providing information on the operation status of the water supply operating facility of the pneumatic conveyance transmitted through the network is provided on a date basis, and a portable wireless communication terminal Pressure multi-stage pump control system (not shown) that provides various services to the monitor 52 through the portable wireless communication terminal 82 (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste through wireless network (1) Nuclear power plant equipment (1) Equipment to be formed in the nuclear power plant (811). Ad-hoc or infrastructural Establish network construction.

In the high pressure stage multi-stage pump 8 installed in the interior of the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, And a motor is installed in the motor, a motor is constantly rotated by electricity supply, and the motor 127, which generates a very high pressure by reciprocating operation and operation, is referred to as a high-pressure multi-stage multi-stage pump, The pump module is equivalent to the engine module and is coupled with the pump module which is a mechanical value. In the inside of the three-stage multi-stage pump, the fluid flow in the impeller 143 is uniformly provided and the loss due to friction, vortex, etc. of water flowing out from the impeller 143 is reduced And is made to be guided.

The high pressure stage multi-stage pump (8) installed in the interior of the machine room formed in the internal nuclear power plant (811) of the reactor facility main body (1) of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, A power line for sensing sensor, and an electronic line for electronic control, and connected to the overcurrent breaker brake 61 and the main switch button 66 by the monitor 52 and the power supply 62, The check valve 6 is connected to the isolation valve 5 formed outside the pump body which is connected to the control device with the operation-on and the operation-off respectively, and the regulator 136, which is constantly reduced in pressure, And an electronic control unit 88 formed by a plurality of pumps in a plurality of valves and an electronic control unit such as an emergency valve 84 and a pressure check sensor in the low-pressure shut-off valve 83 are installed with a plurality of switch buttons , The above- A short distance wireless communication antenna 54 and a short distance wireless communication control module 54 are connected to a power supply 46 which is a power supply unit and a three stage multi-stage pump control board 53 of a high voltage down- The portable radio terminal 82 of the communication means or the electronic control device connected to the public telephone communication network is installed inside the multi-stage multi-stage pump control box 2, ), When the signal is wirelessly received by the electronic control unit module and the "switch button-on" inside the control room, the display screen 63 of the monitor 52 is installed so that it can be visually recognized in the control room, Communication valves belonging to the electronic control device and the isolation valve 5 on the front and rear sides of the three-stage multi-stage pump, the low-pressure shut-off valve 83 and the low-pressure shut- Electronics Which is a disaster prevention material including a wired / wireless communication device and an electronic control device which are connected to a solenoid valve 76 and an air compressor 80 of an air conditioning system via a collecting nozzle 34 and a dust collecting line 89, And it is a device installed on the roof of a lot of forest fires and dwellings in the shape of a discharge water jetting or a curtain water film, and the fire extinguishing material having a constant water pressure is fired into a plurality of nozzles gap and a plurality of nozzle gap machining holes. (1) Nuclear power plant reactor main body having a dual structural block tank dust collector for nuclear waste disposal with fire fighting and disaster prevention measures for life saving purposes (1) The pump 8 is provided with a connection structure.

In the high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811, a detection sensor 104 for checking the amount of arson at a low water level on the inner wall of the water collecting compartment is connected to the first ignition sense wire The multi-stage pump control box 2 of high pressure inside the machine room is delivered to the electronic control sensor for checking the level of the disaster prevention water, and when the disaster prevention water reaches a certain level after the pump operation is stopped, The bevel tap 499 in the form of a circle is attached to the inner wall of the collecting wall by a small thin wire serving as a lever, and when the bevel tap 499 is moved downward, the pump operates and the position is fixed horizontally The operation of the sensing wire 41 is performed at an angle of 90 ° or 120 °, and a high mountain In the case of the low-acid collecting tank, it is necessary to install the collecting tank (34) inside the collecting tank (34) so that the height of the collecting tank can be adjusted before the disaster, (2) A double structure block tank for the treatment of nuclear waste, which provides simple solution within one second for the normal fire separated by A fire. (1) Nuclear power plant main body of nuclear power plant with dust collector Pressure multistage multistage pump 8 installed inside the machine room formed in the main body 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is such that a machining hole 20 (not shown) is formed in the stopper steel plate 165 on the flange- The filtering water is filtered by the isolation valve 5 and the check valve 6 so as to pass through the suction and return pipe 3, ). At the same time, the detection sensor integrally includes a meter 105 for checking the flow rate of the water, a ball tower 104 for sensing the water level, A high pressure isolation valve is installed in the middle of the meter 105 and the pump suction connection flange 28 at the upper end of the piping in front of the pump suction port 269 and a high pressure isolation valve 5) This is an automatic control valve that controls the transmission. The control unit is a magnetically controlled valve and a solenoid operated control valve. The solenoid valve 76 or the butterfly butterfly valve (305) is formed in the disaster prevention piping line (89), and a nuclear power plant having a double structural block tank dust collector for nuclear waste treatment is installed in the nuclear power plant (811) Stage type multi-stage pump (8).

The connection structure of the high-pressure three-stage multi-stage pump 8 formed in the nuclear power generation facility unit 811 is such that the basket 42 or the plastic pack 43 is connected to the ground surface 292 by the fire 292 or the spark 293, The control unit, which is a sensing sensor at the top of the valve, detects a fire, the valve is opened, the water is held at the top of the upper part and the water is held in the disaster prevention pipe, and the water having a constant water pressure passes through the valve opened to the disaster prevention pipe, And reaches the plurality of injection nozzles 10 in the region. The injection nozzle 38 discharges the water by the constant water pressure of the water pressure of the diverging nozzle. Accordingly, the disaster prevention piping 89 is provided at the lower end of the high pressure multi-stage pump inside the machine room, and the joint connection site emergency valve 84 and the hydraulic pressure control reducing valve 85 of the head tank 189, The first pressure check sensor 86, which is a detection sensor attached to the multi-stage pump control box 53, is connected to the inner multi-stage pump control box internal control board 53. After the pump is operated again to maintain the hydraulic pressure of a certain standard, At the same time, the disaster prevention piping line 89 is provided with a double structure block tank dust collector for processing nuclear waste, which is provided with a water pressure sensing regulating valve 85 at a constant distance from the machine room floor surface (MFG) Pressure multi-stage multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant provided with a connection structure.

The high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811 is configured such that pressure suction is performed to the left and right sides around the suction port around the impeller 143 inside the protective cover of the multi- And the discharge piping 3 and 4 are referred to as a head tank 189. The head tank 189 has a very high and high pressure and the water pressure of the fire water rises. At this time, the head tank has a capacity of 8 liters, When the pressure is reached, the pump inlet or pump discharge port in front of the head tank and the large pipe (14) of a certain standard size and the pipe connection fitting corresponding to the elbow or tee elbow (44) having a double structure block tank for treating nuclear waste, which is provided with a suitable material to withstand a high pressure, (1) providing a connection structure for Vertical multi-stage pump 8, the high pressure that would be installed in a machine room inside are formed in the atomic power seolbibu 811.

The high-pressure multi-stage multistage pump 8 connecting structure of the nuclear power plant 811 has a flange connection on the junction of the disaster pump connection port and a flange 28 and a flange 28 on the flange connection. (1) and (2), consisting of a nozzle nozzle (10) and a fire hose (9) connected to each other by bolts and nuts, Pressure pump may be installed in the head tank 189. However, the pressure tank may be connected to the high-pressure head tank (not shown) 189), there is a lack of realism and an uneconomical problem. In addition, the injection nozzle body (B), which is the injection nozzle (10), is divided into basic 1 type and basic 2 type "Title 100" ( 240 " to " NAME 50 "238 and" NAME 40 "239 to" NAME 75 "236 and" NAME 65 "237 to" NAME 90 "235, (10) Body (B) to be detached and connected to a standard type fire hose connection is a nuclear-power plant having a double structure block tank dust collector for nuclear waste treatment provided in a basic type 1. Pressure multi-stage multi-stage pump 8 installed in the machine room formed in the multi-stage pump 811.

The multistage multi-stage pump 8 connecting structure of the nuclear power plant 811 includes a water inlet 169 of the fire and disaster prevention line inside the multi-stage pump 8 and the collecting tank 34 inside the pump extinguisher body. The float 315 on the upper part of the manhole cover 152 and the float 315 on the lower part of the manhole are connected to the lower end of the manhole cover 169 by the water supply port 168, the water supply port 168 and the waterproof port 169, The float 315 is attached to the float 315 at four places around the processing hole 20 of the outer wall of the tank so as to fill the inside of the manhole 152 to fill the inside of the manhole 152. [ Is coupled to the square flange 28 of the louver cover 550 body so as to be formed of a separate louver cover 550 and a float retainer switch 551 and then inserted into the tank outer wall machining hole 20, Fill the nuts (25) after binding to the four places, The key wrench is used to separate and separate. Meanwhile, as shown in the figure, the upper portion of the bed frame 286 is fixed to the upper portion of the bed frame 286 above the upper surface of the bed frame 286 above the ground surface GLL, A pump 259 attached to the pump 308 with an upper tee elbow 44 is connected to the valve 114 via a flange 28 at the left side of the valve 114, A bass canceller alarm 543, a remote control alarm 544 and an alarm reset button 545 and a low level switch 546 at a low position inside the tank are connected to the switch 541 and the high level alarm 542, And is installed inside and outside the control board 53.

The centrifugal pump unit 308 has a structure in which the rotary shaft 198 which is the center shaft 198 of the motor 192 is connected to the high- A guide vane 142 is attached to the impeller 143 inside the casing 141 which is a body of the pump 308 so as to be closely attached to the previous pump driving yaw member and is mounted on the periphery of the rotating shaft 198 located at the center line of the casing 141 A balance hole 376 is formed in the septum seal 156 and the partition wall 372 of the shaft seal device so that the axial seal portion 390 is formed in such a manner that the cooling method 391 of the cylindrical seal is largely changed. The control box of the board 53 is configured such that the flow rate check flow meter 105 and the overpressure prevention switch 108 function as a stop valve at the upper part of the water line 169 line pipe 114 and a pipeline line sensor formed by a separate tee elbow 44 in the line piping 168 Is detected.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 is connected to a disaster prevention pipe 14 for disaster prevention next to the water supply pipe 14, The name "100 × 90 (241), 90 × 75 (242), and 75 × 65 (243)" are used for the seven standard types of the standard specifications formed by the piping bodies so that the standard can be adjusted by the connecting subsidiary reducers (35) The injection nozzle body is connected to the spray nozzle body in an antenna type so that installation is possible in the order of nominal 4 × 25 "(246) to nominal 50 × 40 (245) of 65 × 50 (244) And the pipe 14 of the injection nozzle body is joined to or connected to the pipe 14 of the injection nozzle body one by one so as to be connected to the rear end of the pipe bottom surface of the machine room. ) Are classified by designation and are connected by piping connection lead (35) And the piping 14 and then the piping connection reducer 35 are connected in this order so that the coupling and separation are performed in the reverse order and the bolts 24 and the nuts 25 for connecting the injection nozzles are connected to the washer 26 by the dis- The nozzle body (B) is connected to the flange connection processing hole (20) inside the flange (28) and connected to a recess formed between the flange (28) and the flange Is a high-pressure type multi-stage pump (1) installed in the interior of a machine room formed in an internal nuclear power plant (811) of a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector 8).

The high-pressure type multi-stage pump 8 connecting structure of the nuclear power plant 811 has a structure in which a bolt nut (not shown) can be easily disassembled and assembled so that the washer 26 can be adjusted to 0.5 millimeter or 5 millimeter at an intermediate portion between the flange and the flange. The discharge jetting number 38 can be set such that the operation of the radiation curtain water film 39 or the straight discharge jetting number of the valve and the high pressure stage type multi-stage pump 8, which are control devices, The discharge jet 38 that continuously and continuously discharges into the nozzle gap 15 is applied to a multipurpose range of preventive measures to prevent the spread of a large-sized fire and to prevent disasters. A plurality of airships 78 and an ad hoc balloon 77 are connected to the air hose 109 through the nozzle hose in the form of a multi- (1) of a reactor plant main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, including a method of using disaster prevention equipment for transferring air generated in an air compressor (80) And a connection structure is provided to a high-pressure type multi-stage pump (8) installed inside the machine room formed in the nuclear power generation facility unit (811).

The nozzle gap 15 formed around the periphery of the pipe 14 of the injection nozzle body 10 has a plurality of linearly arranged plurality of nozzles As the water film ejection number 38 rapidly evolves the flame 292 and the flame 293 gradually and precisely and evolves to prevent a large fire as a result, In the rice fields around the mountains and on the roads and neighboring houses, a straight nozzle gap is formed in two places on the pipe as in the arrangement of telephone poles. Small pipes are used as disaster prevention water transport means by using large and small pipes. The piping is slightly larger than the small piping to the top of the piping, and the piping parts are joined together by using a bolt or a nut and a nozzle gap (15) of a straight line with a piping length of 4 meters As a result, the discharge jet 38 was ejected from the two high-pressure multi-stage multi-stage pumps 8, and the performance was tested 20 times by adjusting the gap 15 again. The fire wall nozzle is formed in such a way that the fire wall nozzle is formed so as to prevent the road from freezing in winter due to the weather condition due to the installation length depending on the installation height of the water film curtain of the triangle, In order to improve the quality of life of the working environment, the fog is removed around the surface of the road and the view of the front of the road is widened so as to smoothly communicate with the traffic vehicle for safe driving of the driver. For farmers engaged in agriculture, it is necessary to protect and cultivate the crops of the vinyl house, On the day of precaution and rainy weather, the disaster prevention waterway (17) of the steep slope angle (91) and the constant slope angle (91) of the ridge line in the drought And disaster prevention pipelines. In order to prevent hail damage in the summer, it is necessary to keep the water properly in the vicinity of the disaster prevention pipe. It is a holiday resort on the sandy beach of the resort area. It cools the heat on the hot day on the coastline. It is a means of ejecting from the gap between the straight nozzles and the cold air. The fog is removed and the traffic is smoothly made. The fall harvesting sparrow prevents the grasshopper from being in proximity to prevent the loss of grain, In order to preserve large-scale bridge management, which is a first-class steel structure for the preservation of buildings, To establish a non-disaster world village in the international society in addition to the opening zone (sovereignty zone) in the multi-racial format, or in order to achieve peaceful coexistence in Northeast Asia, it was installed as the central axis of the center line of the Pyungang River, Cheorwon (2) A double structure block tank for the treatment of nuclear waste having a pipe nozzle-moving type fire sensor pump installed in a 1200-kilometer radius of 3000 Lane. (1) Nuclear reactor main body (1) It is necessary to cooperate with all the people of the respective countries in the creation of the global village without disaster by exercising the diplomatic capacity of reconciliation and goodwill of the international community to provide the connection structure to the high pressure multi-stage pump (8) installed inside the machine room.

The multistage multi-stage pump 8 connection structure of the high-pressure type formed in the nuclear power generation facility unit 811 is constructed such that the discrete multi-stage pump 8 and the high-performance submerged pump 36 are connected to the disaster prevention hose 9 of the disaster prevention nozzle 10, A pipeline 14 and a portable wireless communication terminal 82 of a multi-stage multi-stage pump system, a switch button for controlling the operation of the disaster prevention material transporting device and the pipe nozzle body, and a high pressure multi- The multi-stage pump control board 53 and the power source 46 as the power source are installed inside the multi-stage pump control box 2, and the power cable 80 is connected to the inverter 47 and a power supply unit 62 and a power cable 80 as an overcurrent breaker brake 61. The switch button is provided inside the control room and the machine room as a switch button for on / ) In close cooperation with the crew, As shown in the figure, the high-pressure isolating valve 5, the check valve 6 for preventing the backflow, and the emergency valve 84 are reciprocally operated by the piston. The plunger pump 148 is a reciprocating pump installed with a plunger for isolating the high-pressure isolating valve 5 and the check valve 6 for checking the backflow prevention. Pressure tubular multi-stage pump 8 installed in the interior of the machine room formed in the nuclear reactor main body 1 of the nuclear reactor main body 1 of the nuclear power plant having the block tank dust collector.

The disaster prevention nozzle is separated from the disaster prevention nozzle upper support frame 11, the lower support frame 11 and the vertical support frame 11 by the connection structure of the high pressure multi-stage pump 8 formed in the nuclear power plant 811 And the injection nozzle claw 13 and the hook hook 18 or the hook hook hook frame 11 and the hook hook hook engaging hole 20 are formed in order to protect the injection nozzle and the nozzle hose, The wire rope knot hooking hole 20 and the wire rope knot hooking hole 20 are used to protect the injection nozzle and the nozzle hose by being attached to each other so that the connecting hooking lug 21 and the connecting hooking lug working hole 20 or the connecting hooking safety hook shackle 23, Is used for disassembling the injection nozzle and the nozzle hose and is connected to the nozzle hose by means of the coupling 29 of the disaster prevention equipment and the evapotranspiration equipment coupling element thread body 30 and the disaster prevention equipment coupling A threaded body 31 is fabricated and a coupling seal rubber packing 32 is provided at an intermediate portion inside the female thread. Then, a paraffin stopper for a fire occurrence detection sensor is attached as a nozzle replacement to replace the packing 32, If you change the production method of existing fire extinguishing equipment to suppress the fire and flame at the time of occurrence, it will lead to the least cost or environment-friendly way in consideration of the difficulty of financing the source due to the small change due to the new production technology (8) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment which provides a technological progress. (1) A high pressure multi-stage pump (8) installed inside a machine room formed in an internal nuclear power generation facility (811) Thereby providing a connection structure.

The connection structure of the high pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 uses the air hose 109 and the high pressure hose 190 for the air balloon 77 and the airship 78, Fire and other functions of fire protection are used for the protection of forest protection. (158) Air is generated from air compressors for disaster prevention. Cold air and hot air are always separated and separated by compressed air. Air is supplied and fixed by wire rope and frame. , An active and passive disaster prevention means of domino type is used in which the disaster prevention material is controlled by the equipment inside the body of the pump fire extinguisher body formed according to the meteorological condition, . In addition, the mixer section at the rear of the disaster prevention pump uses a carbon dioxide (174) gas cylinder 171 as a teel elbow coupling gas inlet, and the carbon dioxide evolves 15 times faster than the fire water as a powder and compressed liquid gas, A gas cylinder 171 is installed in the monohull gas supply pipe 175 to construct a pipeline line 89 at the end of a high pressure multistage multistage pump formed by the gas inlet mix mixer 191 to perform a PORT injection And the port injection method is a method of injecting an injection liquid into a blood vessel of a human body and a dual structural block tank dust collector for treatment of nuclear waste, And a connection structure is provided to a high-pressure stage multi-stage pump 8 installed inside the machine room formed in the facility unit 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is applied in case of a large-scale fire incapability, but it is a general tendency to be applied to a conventional industrial site. (9) inside the disaster prevention hose (9), and then a collecting tank (34) built on the roof of a large number of mountains and a large number of large buildings together with a connecting part and an elevator (1) internal nuclear power generation facility (811) of a reactor facility main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, which is connected to a speed reducer (251) motor.

As shown in FIG. 2 (b), the pipe-type multi-stage high-pressure pump (8) of the reactor installation of the reactor plant of the nuclear power plant is equipped with a pipe nozzle type fire extinguisher It is a flow chart of the entire fire fighting equipment belonging to the inside of the center pump body. It is a flow chart showing the whole of the fire fighting equipment belonging to the inside of the center pump body, the industrial safety control room using the high pressure multi-stage pump and communication equipment using carbon dioxide and halon gas as disaster prevention materials, The carbon dioxide 174 and the halon gas 175 may be mixed with the natural earth or the loess soil 158 in appropriate proportions using the disaster prevention material carbon dioxide 174 and the halon gas 175. Alternatively, Gas and natural loess 158 are necessary for explaining the constitution in the present invention. The. The above-mentioned natural loess (158) is a reality that is used today as a ship and helicopter relief equipment for pest control by dispersing and dispersing liquid by a helicopter. Such a control activity is a phenomenon that can not prevent the work from being stopped by a hummi In addition, there is a dual structure block tank dust collector for the nuclear waste disposal that supplies the firepower disaster prevention device to the firepower power generator in the first place without the production electric power. In addition, the reactor of the nuclear power plant having the dust collector Pressure multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the facility main body 1.

The piping body of the firefighting nozzle installed at each location of the high and low mountains, valleys, roadsides and neighboring buildings was standardized with a total length of 2100mm to be separated into 7 segments with a distance of 300mm for the multi- Nozzle Nozzle Nozzle Cutting Hole Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz With The height is adjusted according to the shape of the building and the forest, and the elevation of the hose and the pipe body of the double pipe structure is adjusted to the elevation of the transportation equipment adver- tune and the unmanned airship To disrupt many disaster disasters, and as a disaster prevention and control system, air and carbon dioxide After the installation of the liquid fire water, the solid ocher powder and the fire sand, the fire pump and the air compressor were operated immediately after the detection sensor sensed the heat, and a large number of discharge jet was discharged to the outside of the pipe nozzle. Unmanned camera or mobile service to reliably extinguish flame and pillar of fireworks, display of score on monitor by calculation of control server of multi-stage pump control system received from mobile phone terminal Firefighting with firefighting equipment The pipe nozzle of the sensor pump is fixed to the roof of each corner and the building roof of each spot, and the disaster prevention material mixed with the liquid and the gas solidly on the valley or the beach road is firstly fired In a period of 1 second, the incombustible gas (Oxygen) to prevent the combustion by preventing the combustion of air and oxygen (combustion) to reduce the temperature of the combustion to below the temperature of the cooling function and the hose as a cooling effect to put water with the early evolution of the life saving No-accident fire prevention sensor pump that guarantees life-saving structure and early evolution from seasonal fire and large-scale fire is surely installed Fire damage sensor A double structure block tank for supplying electric power to the pump tank reactor main body 1 of a nuclear power plant having a dust collector a high pressure multi-stage pump installed inside a machine room formed in an internal nuclear power plant 811 8).

The fire-fighting nozzle formed by the double pipe structure which supplies a lot of disaster prevention materials is installed in the water supply piping line of the water supply water pump of the water supply construction of the former water supply corporation and the neighboring living place where the building with the lower mountain is located, In order to keep the line from being extended, and to go further, sleeping, sleeping, and sleeping so that the forest fire does not evolve, the air tubing is added together with the water piping line by combining it with the weather forecast. In order to use the correction tank equipment efficiently, it is necessary to connect the air compressor, the high-performance submersible pump and the multi-stage pump electronic control unit and the portable wireless communication terminal to the wireless communication device, A system for enabling a disaster, It is about disaster prevention method and disaster prevention means to prevent disaster loss which flies like a snowball more quickly by judging dan more quickly, and furthermore how to control disaster through Internet. Fire hose connection port before and after the fire without the personnel approaching. Connection of the male and female hose connections. Piping nozzle is connected to the hose connection node. Nozzle fire prevention sensor pipe which is longer than the previous evolution hose used. (1) a reactor structure main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment provided with an air tube type collecting tank having a double pipe structure for rapidly accelerating the lifespan and the initial evolution by the fire fighting / ) The high-pressure (low-pressure) high-pressure And the type multistage pump (8) provide a connection structure.

In order to cope with the sudden occurrence of frequent occurrences without distinction of day and night, the large fire and large fire are not caused by the advance notice. For disposal of nuclear waste to set up a hydraulic pump capable of pumping up to 50 times of free fall by using the water hammer action to make the forest fire evolve within 1 second by the membrane pump (diaphragm pump) Pressure tubular multi-stage pump 8 installed in the interior of a machine room formed in an internal nuclear power plant 811 of a reactor facility main body 1 of a nuclear power plant having a dual structure block tank dust collector.

The previous large-sized fire is delayed due to the delay of dispatch of the fire-fighting vehicle according to the circumstances of the residential living area. As a result, the small fire spreads and the fire pillar becomes large, resulting in a large fire. In such a large area of the neighboring living area, there is a considerable difficulty in entering the fire truck into the production plant and the market. In this case, the fire is generated at the bottom of the building, and the toxic gas- In order to solve this problem, it is a sad situation that gas leakage is caused due to gas choking caused by a fire caused by gas infiltration into the upper floor of a residential area through a one-way passage. It is possible to prevent a large-scale disaster of a large number of water films ejected through a plurality of nozzle gaps of

As described above, fire extinguishment in this way is the same as that in the fire-fighting house, because fire-fighting vehicles are usually dispatched after the previous fire, . The apparatus of the non-emergency pump extinguisher for the early evolution and lifesaving of the large-sized fire according to the present invention comprises a nozzle body (B) for use in accordance with the specifications of the fire hose name used in the standard firefighter window specification, ) Are precisely standardized on the joint nozzle so as to form a basic 1-type and a basic 2-type

The above-mentioned initial ignition sources were ignited by fire, fire and fire due to friction of light flame, fire of lightning, and fire of flint among fireplace park, match fire and candle A large fire is caused by the generation of flame material. At the same time, a large fire is a public building of a building in a commercial building, a wooden building, and fire suppression within a range of a fire belonging to a kind of fire. In order to ensure the early evolution and to guarantee the life structure, it is necessary to precisely set the open / close position and the open / close position of the multiple open / close nozzles at each ignition site so that there is no damage to human life. Is set as follows

A fire such as the above-mentioned building A fire usually causes fire of general combustible materials such as wood (forest) and paper (fiber) to be high, low mountains, thorny bush of grassland, grass, The best way to prevent the fire is to fire the cable car arocarbons and ocher powder on the top of the machine room and on the mountain top of the large building. It mixes with the fire water in the field and surrounds the combustible with combustible gas within 1 second so as not to escape from the safe area of the fire. Painting section) The natural swamp composition was formed at the disaster prevention channel of the ridge line.

In this way, the dislodged material and the ignition material are accurately set to the closing position so as to suppress the ignition of the ignition material, and to maintain the antagonistic relationship between the disaster material and the ignition material.

The large-sized fire is limited to occur in a vast and wide area of neighborhood life without prior notice, and due to the diversification of frequency of occurrence outside the closed space,

In the fire fighting and fire fighting equipment system, which is mobilized by the ignition source providing material and the substance for suppressing the ignition, as described above, various tube nozzle holes are installed in the building and the exterior to the inside with a large number of obstacles, Paraffin sensor used as a detection sensor for active disaster prevention and active disaster prevention equipment Nuclear waste disposal to provide installation of pipe nozzle to the outside of water tank of double pipe structure at the position where many pipe nozzle holes are formed by paraffin stopper of pipe nozzle (1) of a nuclear power plant having a dual structure block tank dust collector.

As shown in FIG. 2 (b), the problems of the prior art are improved in the high-pressure multi-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant. However, In the event of fire, before and after the occurrence of the fire, all communications equipment of the Internet control system, the multi-stage pump and the pump electronic control unit, and the air storage tank of the air compressor and the wire rope of the air compressor It is possible to quickly and accurately mix piping nozzles with solid nozzle nozzles and mix them with liquid and solid disaster prevention materials by mixing the facilities including the fire fighting disaster prevention countermeasure fire fighting equipment formed on the cable car body, As the pipe nozzle is changed, the gap between the nozzle of the radiation type and the gap formed by the straight gap is partitioned The fire water is separated into a plurality of radiological curtain water films and a plurality of linear straight curtain water films by nozzles and then discharged or ejected, and the gas which is generated in the case of fire is discharged from the dioxins and flame materials, It has evolved within one second from forest fires and large fires, resolved the priority of life-saving, prepared for floods and droughts, set up thorough measures to prevent landslides and roads, and distributed the distribution of nuclear facilities It is designed to eliminate many disasters at the same time by means of input devices. At the same time, it is necessary to calmly cope with the crisis and to overcome the disasters of the earth. Paraffin sensor installed in fire-fighting nozzle The fire sensor installed in the mountains and the building to prevent fire. The fire pump installed in the marine to prevent the disasters from occurring in the world. 591) Nuclear waste disposal at the bottom of the Otaei Daejangju Double Structure Block Tank Marine Tunnel Traffic System (941) In the station where the electric train (771) is installed, a number of fire fighting equipment for each type of fire is installed in the double structure block tank And installed in the nuclear reactor main body 1 of the nuclear power plant having the dust collector.

The pipe-nozzle type fire-fighting sensor pump of the non-emergency fire fighting and disinfection countermeasure product for the marine power plant is provided with an electric motor body inside the fire-fighting sensor pump and a center portion circle of a shaft, which is a motor center shaft formed on the horizontal center line (MBCL) The impeller which is a rotating body to the surface portion, a piston attached to a guide vane pump on both sides of the impeller, and a prime mover pump which is assembled to be detachable from the turbine. The pump body is provided with an isolation valve and a check valve, Flow control sensor that adjusts the direction control automatically and sensor switch that controls gas, liquid and solid in the pressure sensor and controls the flow inside the pipe. Power cable that supplies power energy and A fuse suitable for fire It can be used as a flammable gas such as fire water, loess, fireproof gas, carbon dioxide gas, carbon dioxide halon gas The tank is installed in a high-pressure tank and a collection tank in a closed tank and an open-flow type plastic bag or a tent tent. The nozzle of the nozzle is moved in the form of a moving boat for disaster prevention, Sensor pump installation is done

The tube nozzle moving type is divided into a basic type 1 and a basic type 2 according to a standard fire hose standard. A flange joint is formed by a firepipe nozzle and a coupling joint firepipe nozzle. The pipe nozzle is connected to a fire cable car, It is separated into a fixed fire-fighting nozzle fixed at 50m distance of installation with the same angle of inclination of the ridge of each corner at the bottom of the normal mountain range (GLL). At this time, High and low building in the beach near the seaside beach Build up a fire tower for firefighting cable car at each point of the rooftop and nearby mountain peaks, fix it with an anchor bolt by a hand tool, And the pylons were installed, and the top of the pylon was erected and the top of the tower was erected. A firefighter nozzle connected to a fire hose connection node of a disaster prevention material transfer device mounted on the firefighting cable car, a mobile firefighter nozzle having a plurality of pipe nozzle holes formed on the circumference of the pipe body, After receiving the power source generated from the generator through a power supply line of a transformer and a telephone pole connected by a plurality of electric wires, each pump motor motor and each compressor motor motor receives rotational power of the angular accelerator by sensor detection of each solenoid valve The impeller or the piston is used as a plunger pump to return the fire water to the top of the high acid and the backwash water is returned to the top of the high acid by the non-powered pump without receiving the power supply from the generator or the engine generator of the power plant, There is an appropriate level of normal fire such as buildings belonging to different types of fire Nuclear power plants with a double structure block tank dust collector for treating nuclear wastes that evolve early and evacuate lives in the wood, forest, and paper with fire and flaming pellets in less than one second ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading apparatus of the reactor plant of the nuclear power plant has a plurality of fire- A multi-pipe hose formed by a tank, and an electronic heat sensing sensor and a flow control valve, a manometer-level hose provided with an air compressor in a piping nozzle and installed in a fire disaster prevention piping line, and a fire- And the number of discharging water droplets and the number of curtain water films surrounded by the flammable gas together with the incombustible gas to block the supply of air to prevent the combustion and the cooling action to lower the temperature of the combustible material to the temperature below the ignition point are performed in the fire hose pipe processing The above-mentioned cooling action fire-fighting method which puts muddy water ejected to the space between the holes is a method in which, at the beginning of the fire, The above-mentioned adverbons and airships, which are designed to evacuate the refugees to the firefighting cable car security area by dispersing the load of the body of the fire sensor pump body, ensure the safety of the pump body, (Standard point) is set as one point of the triangular boundary line of the iron, which is the ceiling line of the silence, and then the standard point is set. In the land of the ancient ancestor and the territorial sea of the silent descendants in the land of 2400km diameter to the east, west and north of Kangsu Kangshan, the primary non-motorized pump of the multi- Nuclear power plant with double structure block tank dust collector for nuclear waste disposal providing turn-type fire-fighting nozzle and fire-fighting piping line And is formed in the nuclear reactor main body 1 of the nuclear reactor facility 811.

In the following description, the same reference numerals are applied to the same formation as in the drawings, and the present inventor emphasizes that the pipe nozzle moving type fire pump sensor pump is not limited to fire prevention according to the type of A fire, B fire and C fire. The fire sensor pump of this nuclear power plant (811) was first coated with vinyl coating on KSD 3507 general piping rolled steel, and connected with nozzle body by KSD 2331 aluminum alloy for die casting. Plasma flow tube or KSD 3699 hot rolled stainless steel coil. The temperature sensor is replaced with a bimetal or bourdon tube to paraffin sensor type. It is used for diesel engine, fire pump, solenoid solenoid valve and other Standardized general purpose hose pipes are equipped with a double pipe structure type of liquid and gas The sizes of the pipe nozzles to be supplied to the city are classified into seven types according to the types of fire hose connection types: "Tubular Nozzle 1" Diameter of 200 mm, 180 mm, 150 mm, 130 mm, 100 mm, 80 mm, (150x150) mm, (150x130) mm, (130x100) mm, (100x80) mm, (80x50) It is formed by the tube nozzle connected to the hose connection part and the tube nozzle of the multiple straight line type crevice hole, so that it can be used as a demilitarized zone in building, Has evolved from fire and forest fire of general combustible materials such as wood, forest, paper and duvets such as buildings belonging to different fire classifications or large fire of neighboring living area, With this many adverbons and airships, , And at the same time, the center line of the center line of the triangular barriers of the Demilitarized Zone, which was intended to destroy many disaster disasters, was established. Nuclear Power Plant's reactor main body with a double structure block tank dust collector for nuclear waste disposal that ensures the installation position in multi-tiered form and allows the installation location to be determined beyond the border line of the non-disaster global village that ensures the peaceful coexistence of Northeast Asia 1) The equipment formed in the internal nuclear power generation facility 811 makes the configuration of the internal nuclear power generation facility 811 of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste reasonable.

The hose 9 and the piping 14 which are processed into a plurality of double pipe structures in the inside of the fire sensor pump body of the nuclear reactor main body 811 of the reactor facility main body 1 of the nuclear power plant and the injection nozzle 10 gap 15 and the processing hole 20 of the nozzle 10 are 300 mm in the distance of one body of the pipe 14 so that the bolts 24 and the nuts 25 in the total number of 7 are filled with the washer 26, And a plurality of processing holes 20 having a diameter of 5 mm or less are provided along the circumference of the pipe in the form of a cylindrical body of the pipe body. There are 498 total machining hole gaps. The injection nozzle body (B) has a multi- The two flanges 28 attached to the main body of the injection nozzle body A are connected to a single pipe which is a pipe body with eight machining holes at a predetermined inclination angle 16 of 45 degrees, (28) A stopper plate (165) is attached to the upper end (A) of the flange (28) by a stopper cap disk (165) The stopper cap 165 is disposed under the flange of the lower end A of the body so that carbon dioxide 174, halon gas 175, helium 176, fuel 131, The body 29 of the coupling 29 to the center position is inserted into the through hole 20 in which the small water tube 29 of the fire hose and the wire rope 19 are formed inside the coupling body 30 and the coupling body The wire rope 19 formed by a pumping pipe 89 for supplying the above-mentioned disaster prevention material, which is standardized to have a total length of 2100 mm and a total length of 7 mm, which is detachably assembled by a hand tool monkey spanner, And is bound to the inside of the fire hose 9

After the fuel piping line and the gas disposal material piping line are united together with the piping line of the liquid, the fire-fighting nozzle 10, which calls the nozzle formed of the pipe nozzle and the piping body in an orderly double- A spray nozzle body (B) detachably assembled to a nozzle body upper end portion (C) above a lower end portion of the body and a lower end portion (C) of the nozzle body; 2500 mm × 2500 mm × 2000 mm, which is made of a wire rope or a rope, is installed. Inside the basket 42, fuel supplied from the gas fuel supply pipe line is supplied to the ground or burner 173 ) Is adhered to the lower part of a vinyl tent (77) of an adverb (a cross-length × length × diameter: 10M × 10M × 10M, formed in a double structure in a circular shape), and a gas burner 173 for cooking used at this time is connected to an unmanned igniter 187 are installed and wrapped around the outer circumferential surface of the adobe with the wire rope 19 or the rope 131 and bound to the lower part of the adobe together with the rope 131 and then the unmanned camera 184 A radiosonde 134 as a meteorological observation device for observing the diurnal state of the farther farther from a higher position is mounted and the lower part of the injection nozzle body B is connected to the lower end of the integral multi- A multi-stage pump 8 as a device of the electronic control unit 8, a disaster prevention pipe line 89, a disaster prevention waterway 17, a double tube structure collecting tank 34, a fire fighting unit 40, A plurality of valves and an air compressor 80 for interrupting the flow of the microcomputer system, the communication equipment system and the piping internal flow rate, the generator 124, the engine 144, the air cylinder 138 formed in the doctor ventilation, An air trowel winch 137, a combined life-structure bed The iron structure 143 and the pump inner impeller 143 are connected to the nozzle 172, the hydrant 179, the grid drive 185, the air tube 188, the head tank 189 and the high pressure hose 190, The entire area where the pyrotechnic material and other gases such as the flue gas 292, the flame 293 and the pyrethrum 294 are generated is referred to as a fire sensor pump body and the reactor facility main body 1 of the nuclear power plant, Inside the nuclear power plant (811), the whole equipment of the fire-fighting and disaster prevention industrial goods necessary for the entire life span and the early evolution is included.

The fire-fighting nozzle 10 used as a plurality of pipe nozzles of the nuclear power plant 811 inside the reactor facility main body 1 of the nuclear power plant is made of KSD 3507, KSD 2331 and KSD 3699, In the case of the 7-bar basic type 1, when the nozzle is vertically installed at a height of more than the height of the main body, the nozzle joint portion is set in 7 stages. The basic 1-type nozzle is referred to as "nominal 100" (234), "nominal 90" The fire-fighting nozzle 10 is divided into the "name 50" 238, the "name 40" 239, and the "name 25" 240 separated by "name 75" 236 and "name 65" The pipe nozzle (10) is attached to a plurality of fire-fighting disaster prevention piping lines (168) formed along the mountainous mountain range and formed on the elbow or tee elbow (44). The pipeline (diameter: φ350 mm, Quot; 50 x 40 "to the " nominal 100 x 9" 241, the " nominal 90 x 75 "242, the " nominal 75 x 65" 243, (245) and " When a firefighter nozzle is formed at a position higher than that of the basic type 1 by 40 x 25 '' (246), the tip of the spray nozzle is positioned at the uppermost position of the spray nozzle A plurality of 8-joint gap 15 machining holes 20 are formed in the joint between the flange 28 and the flange 28 to form an 8-nozzle gap therebetween and connected to the joint at the lower end of the flange 28 when the 50- The nozzle 10 is fastened to the shale 23 and the bolt 24 so as not to be temporarily detached from the shale 23 and the bolt 24 with the nut 25 at two places of the tee elbow 44, After connecting the rope to the upper part of the body, pull it from both sides of the shackle (23) opposite to the binding position and disassemble the rope (137) after the bolting work. However, the worker should go up to the height of the poles, By using the spur winch 137, The firefighter nozzle 10 is provided with a plurality of firefighting nozzles 10 attached to a 15 m firefighting hose and connected to a plurality of firefighting nozzles 10 to form a length of 1 km, (1) of the nuclear reactor plant (1) of the nuclear power plant.

The head tank 189 of the nuclear power generation facility unit 811, the solenoid valve 76, the fire water 7, the loam 158 and the arsonization chamber 159 of the nuclear reactor facility main body 1 of the nuclear power plant, A power source 46 as a unitary power source for the pump control system 150, a high-pressure multi-stage pump control box 2, a high-pressure multi-stage pump control box 2, A switch button 66 for operating the pump on the wire rope 19 to the control board 53 inside the control box and the power supply unit 62 to the control server 51 and the control server 51, The radio communication antenna 54 and the portable communication terminal 82 are connected to the collecting tank 34 serving as a storage tank, the piping connection connecting adjunct 35 and the high-performance submersible pump 36, A plastic bag 43 and a hooking lug 18 are attached to the computer network input 68 and the elbow or tee elbow 44 connected to the disaster prevention pipe and the monitor 52, Apparatus in which the brakes (61) installation is conventional soy and accompanied.

The spiral casing 141 and the impeller 143 are provided in the guide vane 142 as a protection cover for the body of a plurality of the pump 8 of the nuclear power generation facility 811 inside the reactor facility body 1 of the nuclear power plant, The type and characteristics of the pump attached to the central axis of the rotating shaft 198 of the body 192 and the countermeasures against the main problems during the driving of the pump and the calculation of the pump according to the existing selection of the pump, , The pump shaft device, the countermeasures against the vibration of the pump, and the handling of compressors to compress the gas. It is a fire-fighting and disaster prevention countermeasure device that is formed on the body of the offshore power plant. Explain as follows.

As described above, in the inside of the nuclear reactor facility main body 1 of the nuclear power plant, there are provided a plurality of fire hose 9 and the pipe body 14 in the nuclear power generation facility 811, A paraffin tape 177 for a fire detection sensor and a nozzle stopper 100 for connecting a paraffin type pipe jointing nozzle with a processing hole 20 are formed by a combination of high and low mountains 395, (333) Roof rope (19) Fire cable cable (256) type No-accident fire prevention disaster prevention article pipe nozzle Movable type fire sensor After installing the pump, When a fire in a wooden building (332) and a forest (266) of a fire occurs, a fire of a general combustible material such as paper and a duvet is generated. In the past, a fire engine such as a helicopter and a fire truck started to fire with a siren, A streetcar The fire helicopter in the mountain and the obstacle such as the parking lot of the car is revived again at the moment when the helicopter is turned on and off to carry the fire water, and the digestion activity of the fire scene is disputed for a moment. In order to solve the danger of losing to life in an imminent situation, the pipe-nozzle-type fire-extinguishing sensor pump, which provides a simple initial evolution just before the start of a fire or a helicopter, (1) Inside is the nuclear power plant (811) fire fighting system.

The hose 9 of the sensor pump 811 of the nuclear power plant 811 and the plurality of the non-hazardous paraffin nozzle plugs 100 and the paraffin tape 177 formed inside the nozzle body 10 are installed inside the reactor facility body 1 of the nuclear power plant Closed multi-pipe nozzles Opening the crevice hole Fire heat sensor Paraffin burning flame and flame on ignition object due to match fire (166) and detection of low temperature of candle can not easily spread to large fire, The inventive non-hazardous-pipe nozzle-moving type fire-fighting sensor pump of the present invention is a fire extinguishing material of the pump fire extinguisher 124e to the acid alkali fire extinguisher 124b and the foam fire extinguisher 124b adapted to A fire, It is a non-flammable gas of non-combustible gas that surrounds combustible material to block the supply of air (oxygen) to prevent combustion, and to reduce the temperature of combustible material to below the ignition point. It is a fire extinguishing fire extinguisher that can guarantee the rescue and early evolution from large-scale fire and large fire caused by the seasons. It is a pipe fire extinguisher The air circulation pump 124 is connected to the membrane pump 144 and the air compressor 80 through the hopper 73, which is a mixer, into the water collection tank 34 through the fire water 7 and the loess 158, Is formed by a fire device of the intercooler (170).

The ignition object 166 of the nuclear power generation facility unit 811 is burned into the nuclear reactor facility main body 1 of the nuclear power plant while being stored inside the fire fighting nozzle nozzle body together with the fire water whose internal pressure of the fire hose is held, The incombustible gas 164 is stored and discharged to the outside of the fire extinguisher body at the same time so that the fire ejection water 38 and the curtain water film 39 are burned in a plurality of openings 294 in the gap 15 of the fire- When this is removed at the moment of departure, this scene is transmitted to the unmanned camera 184 installed at the height of the telephone pole around the fire scene, and the information detection function of the pump control server 51 of the multi-stage multi- The characteristics of the microcomputer control of the pump 8, which is configured to display the state of the fire at the time of the fire on the monitor 52, include a digital control method, an inverter 47 speed control method and an algebraic control method Chiyida.

The configuration of the multi-stage pump 8 is as follows.

Multistage Pump Specification

Details of the control method of such a three-stage multi-stage pump system are as follows.

· Pressure control method (Figure 1)

The operating range of the system is formed from the operating point (Pon) of all the pumps to the operating stop point (Poff1) of the maximum load operation pump and the operation stop point (Poff2) of the law firm. After the operation stop point of Poff2 of the pressure control type system is reached, it stops completely after the minimum operation between 180 seconds to 210 seconds (CO-CR) and 0 to 120 seconds (CO-ER). Although the width of ΔP can not be kept narrower than the inverter control method, it is mainly used for absorption pressure of the low layer by detecting input change of about 1 bar.

· Frequency modulation control decoration (Figure 2)

The operating range of the system maintains the adjustment value range.

When the flow rate of each operating pump reaches 100%, and the pressure of the operation standby pump is the operating point Pon and the pressure of the individual maximum operation pump is the stop point Poff before stopping.

Therefore, the frequency modulation method can maintain the narrow width of ΔP and control the rotation speed of the main pump with the frequency modulator, so that the system compensates the sudden pressure change occurring when the operation standby pump is in operation or when the operation pump is stopped do.

When the pressure of the system is lowered to the vicinity of the operating point, the main pump is slowly operated by the frequency modulator control, and if there is no change in the flow rate, the controller stops the pressure fluctuation due to the system hunting.

The details of the main functions of the three-stage multi-stage pump will be described as follows.

As described above, in the multi-stage pump of the present invention, the main function is described in detail inside the body of the pump-like gap type pump fire extinguisher, which is a urinal part, which is an urinal part, so that anyone can easily pumped without being close to the fire scene or near the pump machine when a fire occurs. (At the time of going to bed), as a result of the structure of the present invention, the fire-fighting helicopter of the fire-fighting vehicle according to the life structure and the advance prevention is made to evolve within one second before the arrival of the fire scene. At the same time, the distributing and loading device connecting structure of the reactor installation of the nuclear power plant is provided with the pressure tank 189, the collecting tank 34, Inverter 47 and the associated line relationship of the control inverter 47 and the collecting tank 34, The suction port 269 is formed in such a manner that the air shutoff prevention device 271 and the check valves of the respective pumps can be controlled to be fully closed and expanded by the inverter 47, The pressure tank 189 and the control unit inverter 47 are connected to the discharge confluence pipe 5 after the mounting position is clearly set in front of the separation valve 8 and the isolation valve (Isolating Vavle, Ballo-2 Butterfly 5) Which is a discharge port 270, is controlled by a first pressure check sensor 86 as a discharge pressure check sensor and an overpressure prevention switch 108 as an integral part of the second pressure check sensor 87 on the line (4) A plurality of fire nozzles 10 injects loess 158 into the mixer 73 so that each fire A is cooled and suffocated within one second with a fire within a second. Residential firefighting cable car (25 6) is formed by a plurality of high and low mountain peaks and a plurality of buildings having different height. Each of the plurality of fire hoses (9) is connected to a safety net (hose of a net including a wire rope of a cross shape or a well- ) Type hose 9 is a technical feature.

As shown in FIG. 2V, according to the configuration of the multi-stage pump operation mode of the control block diagram and the VFM model, the control power source 273 is separately divided into the pump power source 272 and the control power source 273 is operated in an emergency The sequence circuit 274 is brought into contact with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontroller 276 by a decoupling power supply circuit 275 of the control power supply 273 so that the microcontroller 276 is contact- A setting circuit 277 and a switch input circuit 58 are input to the unit 276 and signals L and D are supplied to the LED display circuit 278 and the M / C drive signal contact output circuit 279, And the motor overload signal input circuit 280 is connected to the unit 276 and the pump &lt; RTI ID = 0.0 &gt; (MCCB + THR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the microcontroller unit 276, And a discharge pressure transmitter (transmitter) 284 is connected to the pressure sensing circuit 282 so that the circuit 282 is again set to be input to the unit 276, The pressure switch 285 is input to the microcontrol unit 276 via the external state input circuit 283 and then inputted to the microcontroller 276 again. (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste (1) It is the equipment to be formed in internal nuclear power plant (811).

The impeller 143 is coupled to the motor shaft 198 so that a predetermined amount of the disaster prevention material, which is formed by the impeller 143, is introduced into the spiral casing 310 of the plurality of can pump bodies, A plurality of fire fighting and disinfecting piping lines 168 of a predetermined amount of fire fighting water 7 transferring device and a left and right side head tank 189 for compressing and storing the water pressure of the inflowing fire water 7, A collecting tank 34 having a double structure in which disaster prevention waterways 17 of a certain standard are installed at intervals of a predetermined distance from the disaster prevention waterway 17 at constant inclination angles 16, A fillet tap 499 as a sensing sensor which senses the level of the flammable water inside the correction tank 34 and a flange stopper for the plug filter 269 for blocking the inflow of foreign substances into the condensate tank 34. [ (28), a switch button- A plurality of solenoid valves 76 which are closed at the time of the switch button turn-off and a plurality of solenoid valves 76 connected to the tee elbow 44 of the binding apparatus so that the disaster prevention material carbon dioxide 164 and the halon gas 175 are introduced into the rear of the head tank 189 And a mixer (hopper) 73 for mixing the disaster prevention material carbon dioxide 164 and the natural loamy soil 158. The low pressure shutoff valve 83 is connected to the disaster prevention piping 14, The multifunctional piping 14 is connected to the flange 28 of the discharge pipe 35 and the discharge pipe 35. The discharge pipe 14 is connected to the discharge pipe 35 through the flange 28, And a gap 15 between a plurality of flange 28 junctions formed between the processing hole 20 and a gap 15 around a plurality of pipe circumferences connected to the nozzle hose 9. [

In this way, the fire water 7 has the shape of the jet ejection 38 (380) of 490 circular dots or the shape of the curtain water film 39, and the eight water films at the higher and higher positions are flushed by the buoyancy of the adevolunes 77 and the airships 78 The life of the facility is extended by dispersing the body load of the cable car (256). After the safety is secured, the mixture of the loess is ejected to the pipe nozzle (10), causing disasters such as forest fires and large fires inside and outside the building The pump is a non-powered pump (393) that can be pumped up to about 50 times as much as the freezing pump due to the movement of the fluid, which is preheated at a time before and after 1 second. The air compressor And a two-stage squeegee air compressor 80 in which heat is dispersed to the oil cooler 157 without an intercooler 170 and an aftercooler 182 are integrally connected to each other through a suction port 269 and a discharge port (270) Which is installed in the air tub 730 formed by the fire extinguisher 710 and the bed jacket 172 of the lifesaving structure, The check valve 6 is provided so that the fluid can be movably transferred to the pressure tank (high-pressure bowl tank 303) inside the non-powered pump 393 so that the fluid can be transferred to the control valve 50 times as much as the drop. And an isolation valve (5), and the function of a plurality of expansion and full functions is ensured in the interior of the marine power plant body Double structure block tank for nuclear waste disposal provided as a system connection device for valves classified as flow control valves in valves and directional control valves Nuclear power plant reactor main body with a dust collector (1) Internal nuclear power plant (81 1).

As shown in FIG. 2V, a first pressure check sensor (not shown) installed in front of the isolation valve 5 as described above is installed in the high-pressure multi-stage pump 8 facility of the distribution and input device of the reactor installation of the nuclear power plant, 86);

A second pressure check sensor (87) installed integrally with the pressure reducing valve;

A bypass disruption piping line (168) installed to bypass the isolation valve (5) by connecting the front and rear sides of the isolation valve (5) and bypassing the isolation valve (5);

An emergency valve (84) installed in the bypass pipe line (168) so as to open and close as opposed to the isolation valve (5);

An electronic control unit (88) integrally controlling the operation of the emergency valve (84) by checking a pressure value from the first pressure check sensor (86) and the second pressure check sensor (87);

The solenoid valve 76 at the joint portion of the intake manifold 3 flange 28 at the upper end of the ground surface at the lower end of the stage multi-stage pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine chamber, An air hose 109 installed inside the nozzle hose 9 and an air nipple 109 for receiving and releasing the air from the air hose 109, And an engine generator 226 at the upper end of the engine compartment in such a manner that the airship 78 is mounted on the upper end of the upper surface of the ground surface. 46 is supplied to the air compressor 80 power motor control module 106 and then the air generated by the operation of the air compressors is stored in the air receiver high pressure storage tank 145 so that air of constant pressure is stored. Tank( 145, air pressure is constantly generated in the inside of the building, and the emergency valve (84) of the disaster prevention air piping line (181) is deployed when the disaster occurs and air is blown into the building and attached to the piping frame outside the building

Therefore, when the air balloon is lifted up to the top of the upper surface of the surface of the outdoor building so that air is stored in the rubber tubes of a plurality of container sizes and at the same time the life structure is formed, It is installed in fire-fighters nozzles as a whole with equipment for manufacturing and installing facilities and lifesaving means. It is installed in mountains and buildings with a parapet sensor nozzle stopper (100). It is used for fire prevention purposes. In case of disasters other than that, it is extended to the fire fence (40) and fire hydrant (179) The air pipe line 181 is connected to each of the pumps and each valve, 56 are constructed such that the flame 293 and the pillar 294 are simply annihilated and removed in less than one second by using a pump extinguisher 124.

Referring to FIG. 2w, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention, Partial strapless configuration diagrams of compressors moving compressors, stationary compressors and multi-stage screw compressors, as well as operating configuration of the front section for fixing underground anchor bolts,

As shown in FIG. 2w, the distributing and inputting device for the reactor installation of the nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant is provided with a multi- The solenoid valve 76 at the joint portion of the flange 28 of the lower end road surface upper surface suction confluent pipe 3 of the pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine room are connected to the fire- An air hose 109 installed inside the nozzle hose 9 and an air nipple 110 for a socket connected to the air hose 109 at a connection portion, And a diesel engine generator 268 at the upper part of the inside of the machine room for driving the airship 78 to the upper end of the surface of the ground are operated and the power source 46 ) The air generated by the operation of the electric motor 192 of the prime mover 80 supplied to the motor control module 106 of the synchronous motor 80 is supplied to the receiver high pressure storage tank 145 before the occurrence of the disaster Air pressure is constantly maintained in the receiver high pressure storage tank 145. At the same time, when a disaster occurs, the emergency valve 84 of the disaster prevention air piping line 181 is expanded, air is blown into the building, The pressure gauge 101 and the pressure switch 104 are provided with the overpressure prevention switch box 108 of the motor control module 106 and the crank 248 and the linkage 249, A safety operation is provided while connecting the wheel 250 and the V-belt 252 included in the speed reducer 251 to the prime mover 80 and the motor 192 to which the knob handle, the piston 127 and the cylinder 126 are attached At the same time, the belt cover 261 is moved to the feeder 250, A suction filter 262 installed on the circumference of the V-belt 252 to adjust the rotational speed of the prime mover 80 and to attract foreign substances to the air inlet 269 to the upper end of the compressor main body 263, The piston 127 of the main body 263 and the air discharge port 270 to which the cylinder 126 is attached are connected to the receiver high pressure storage tank 145 and are connected to the high pressure storage tank 145 at 6 kg per 1 cm 2 of air pressure When pressure is applied, the pressure gauge 101 and the pressure switch 104 connected to the safety valve 258 cut off the operation of the electric motor 192 and when the pressure in the high-pressure storage tank 145 falls below 6 kg per 1 cm 2 of air pressure, Pressure reservoir tank 145 is provided with an air valve 257 and a drain valve 60 at the automatic valve 259 while simultaneously operating the air hose 109 and the air hose connection device nipple 110 ) And the piston is reciprocally operated simultaneously Stage type screw cooler 147 in which heat is dispersed to the oil cooler 157 without the internal cooler 170 and the after cooler 182. The inlet port 269 and the outlet port 269 are connected to each other by a connecting device, And the disposal adjustment devices of the nuclear facility tubing 130, the basket 42, the bed nozzle 172 combined with the lifesaving structure, and the distribution and input devices of the reactor facility of the nuclear power plant, Nuclear reactor facility of power plant (1) Nuclear power plant's reactor facilities consist of connection structures of hydrological control regulator of dam of internal nuclear power plant (811).

As shown in FIG. 2w, the distributing and inputting device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a collecting tank (width × length × A plurality of disaster prevention pipes (not shown) connected directly to the disaster prevention water passage 17 and connected to the lower portion of the tank 34 are provided in the intake port 269 of the cement cone type with a height of 10M x 10M x 1M, Line (168) pulls overflowing valleys and immediately floods the floods to the Sea of the East Sea and the Sea of West Sea of the South Sea to the artificial waterfalls like the waterfall of Jeongbang, which is a natural waterfall of Jeju Island. In this case, the air compressor (80) and the diaphragm pump (144) are operated at the same time so that the valley water is not flooded. (43) was installed in the area of disaster prevention as appropriate for the case of 150mm or 300mm rainfall per hour, despite the fact that the damage was restored. In order to reduce the landslide damage, the double vinyl (43) However, even if the trenches are lost and the bridges are cut off and the other side of the valley is followed by the resettlement of the refugees, there will be a tug-of-war (139) in the valley to rescue the refugees isolated in the mountain valley. (1) The single-pipe small-sized pipe is formed in the bottom of the valley with a diameter of 100 mm and a length of 10M or less, and then the single- After installing it in such a way as to allow passage of fish, the plastic bag (size: length × length: 49kg, 60mm × 1M, firewood and loess, 180) After having been laid on the upper part of the bag 180 to a size of 200 mm in diameter and 7 m in length or less, the bag was again packed with the gravel and sand in the upper part of the middle pipe, A large-diameter pipe with a diameter of 300 mm or more and a length of 5 M is formed thereon, and a wire netting 139 formed of a net-like wire rope 19 is covered in each stepwise layer unit, and then a sharp- 185) or an O-ring bolt (204) and an anchor bolt (133) are installed, the knot is attached to the torpedo so that it can not be floated on the rapids. (It is recognized that there is no disaster when there are a lot of pine trees in the mountain fire prevention condition of the present invention).

Referring to FIG. 2x, a conventional structure of a nuclear reactor power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is shown in FIG. A gear drive 290 in which a tank is adhered, and a squeegee compressor connected to the motor.

As shown in FIG. 2x, the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant composed of the above- The apparatus for dispensing the nuclear reactor facility of the present invention includes a gear train 290 to which an oil separation tank 288 of a conventional nuclear power generation facility unit 811 is attached to prevent disaster prevention and control, And is connected to the air intake port 269 of the receiver high pressure storage tank 145 by disassembly and assembling with the inlet valve 263 and the suction valve 289 so that the distribution input devices of the nuclear power generation facility can be connected to the water inlet port 269 of the receiver high pressure storage tank 145, To be able to adjust the angle of view.

Referring to FIG. 2 (a) and FIG. 2 (b), a rear structure of a conventional nuclear waste disposal system for nuclear waste processing according to the present invention is shown in FIG. The suction filter 262 attached inside the air dryer and the suction filter attached to the inside of the air dryer 291,

As shown in FIG. 2 (a), a distributing and inputting device for a reactor installation of a nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant The apparatus for dispensing the nuclear reactor facility is provided with a suction filter 262 and a drier 291 which are installed inside the rear gate cooler 182 and the inside of the dryer 291, The suction filters 262 are attached to the distributing and inputting devices of the nuclear power plant to form connection structures so as to adjust the internal wastage of the nuclear power plant's nuclear power plant main body 1.

Referring to FIG. 2Z, a conventional fire hydrant system (conventional fire extinguisher system) shown in FIG. 2 (a) shows a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste processing according to the present invention, (179a) of an underground fire extinguisher (179a) and an underground fire extinguisher (179b) of an underground fire hydrant box at the lower part of the road surface. And is a front view of the fire extinguisher container and the fire hydrant box inside the fire hydrant box 161 and the fire hydrant box 160. The fire hydrant 179 is attached to the water feed port 168 of the connection and water pipe and the water- Sectional configuration and perspective view showing the construction of the fire hydrant system shown in FIG. 1 (a), (b) and (c) of FIG. Minute road-side configuration,

As shown in FIG. 2 (2), the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the nuclear reactor facility main body 1 of the nuclear power plant includes a conventional distribution device Prevention of disaster prevention at the flood control section (811) Underground fire hydrant (179a) and subterranean fire hydrant (179b) at the bottom of the ground surface Underground hydrant fire hydrant The firebox manhole is partly constituted and the fire extinguisher (161) and the fire hydrant box inside the fire hydrant box (160) are equipped with the fire extinguisher accessories and the fire hydrant box, and the fire extinguisher (179) (A) of the indoor fire hydrant piping system and (b) a small scale fire hydrant facility, A is composed of a connecting structure to adjust the reactor equipment body (1) inside the flood of a nuclear power plant.

Referring to FIG. 3, the reactor main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore power plant Straight road,

Referring to FIG. 3A, the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore Power Plant Side Construction Road,

Referring to FIG. 3B, the reactor main body 1 of the nuclear power plant having the double structural block tank dust collector for treating nuclear waste according to the present invention (1) The reactor main body 1 of the nuclear power plant, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Sectional configuration of offshore power plant roads,

As shown in FIG. 3, FIG. 3A and FIG. 3B, the atomic power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment according to the present invention, The position of the hull of the marine power plant floating ship with the connection structure with the hydroelectric power station of the land and the landing tunnel (672a) of the stepped dam revolving road which provides the position of the nuclear power plant (811) Hull Location of the Controlled Marine Power Plant Construction Machinery Control Section Marine Dock Body Dock The pipe bridge (928), which shows the arrangement of the hull displacement control and the position of the construction machine in the marine hydroelectric power plant floodplain (593,594,595) (771) inside the marine tunnel transport device to the inside of the marine tunnel transport device (941) to the pipe bridge (937) The hydraulic pumps 593, 594 and 595 of both hydroelectric power plants are connected to a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, The portable lug 607 and the portable lug pin 604 are connected to the vertical partition wall 605 and the pin linking shaft 606 for connection to the portable lug by the distributing and inputting apparatuses of the flood control machine provided with the door 624 for the hydraulic cylinder, 608) to the inside of the marine tunnel traffic device 941 to the construction machine connection structure and bridge bridge 928 and the pipe bridge 937 to the drilling machine 908 to the crude oil drilling machine 908, (928) and a pipe bridge (937) to the inside of the marine tunnel traffic device (941) for the nuclear waste disposal. The marine tunnel traffic device internal train (771) facility is connected to the marine hydroelectric power station floating ship (593,594,595) Location control and control of construction machine position Construction machine connection structure and disassembly (2) Nuclear power plant nuclear waste disposal facility (1) Nuclear power plant construction (811) Nuclear power plant nuclear power plant nuclear power plant nuclear waste disposal system Double structure Block tank Tank inside of marine tunnel traffic device (941) Marine tunnel Internal traffic train (771) Equipment Dual structure block tank for nuclear waste disposal by water pollution control facility Nuclear power plant reactor main body with dust collector And is further configured in the nuclear power plant 811,

(593, 594, 595) of the nuclear power plant's nuclear reactor facility installation and disposal unit (593, 594, 595) constituting the nuclear power plant section (811) inside the nuclear reactor facility main body (1) of the nuclear power plant are classified into rack and pinion type And the distribution of the nuclear reactor power plant provided with the butterfly valve 622 for controlling the buoyancy force of the band guide 621 and the door 624 for the hydraulic cylinder in the hydraulic cylinder hydraulic oil pressure 623 A large flange connection connection joint portion machining hole 615 to the portable lug 607 and the portable lug pin 608 to the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling with the insertion devices, (908) hydroelectric power plant construction machine connection structure and disassembly and disassembly combined with double structure block for nuclear waste disposal Tank Haze (771) inside the tunnel transport device (941) Internal tunnel of the water transport facility (771) Nuclear power plant reactor with double structure block tank dust collector for treatment of nuclear waste by the flood control facility (1) Internal nuclear power plant (811 ). &Lt; / RTI &gt;

Referring to FIG. 3C, there is shown a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. The construction of the sprinkler head pipe 111 of the sprinkler installation piping system sprinkler system and the torsion configuration of the trench head and the vibration alarm device 300 is shown in FIG.

3C, a plurality of drencher heads 299a, b, c, and d are installed on the sprinkler head 111 of the trench head in the sprinkler installation for preventing and preventing disaster of the nuclear power plant 811, The metal tube 113 for the fuse and the water valve 114 for the stop valve are connected to the reflector 112 by the underground pipes 115 and at the same time, A double structure block tank dust collector for nuclear waste treatment equipped with switch 118, bell 119, alarm valve 120, test valve 121, high pressure water pump 122 and vibration alarm device 300 Nuclear Power Plant Reactor Facility (1) Internal Nuclear Power Facility (811) Disaster Prevention Preventive Control Connected structures.

Referring to FIG. 3D, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention, Is a partial side view showing the operation of the piston pump 127 in a side view and a partial plunger pump 148 operating configuration diagram showing the manner in which the plunger pump 148 is partially actuated by the plunger 253, A partial side view showing the side surface of the pump 311 and the toe empty pump 140 and a driving side surface configuration showing the installation state of the waste water pump 309 as a side view,

The operation mode of the reciprocating pump piston pump 127 and the operation mode of the plunger 253 are connected to the rotational axis of the electric motor 192 in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, And the turbine pump 140 and the wing pump 327 of the rotary pump simultaneously move the handle in the left and right directions. , And it is equipped with a suction pump and a discharging pump in two chambers, respectively. The pump is equipped with a simple pump which can be easily mounted on a wall, 309) Nuclear power plants with a dust collector Unit main body (1) Internal distribution of nuclear power generation facilities (811) Discharging unit Disaster prevention Preventive control part Connection structure It can control.

As shown in FIG. 3D, the disaster prevention preventive control unit of the nuclear power generation facility unit 811 includes a closed position in the positive displacement pump formed by the preferred embodiment according to the detailed description of the type and characteristics of the pump, In a guaranteed function of the pump, in which the deployment position is clearly defined, a certain amount of fluid is delivered in the same manner as when dispensing fluid.

Therefore, a predetermined amount of liquid is sucked up by using a piston or a plunger of a reciprocating pump, and is sent out by pushing up.

First, get a high pressure even in a compact And is available for small flow rates of high viscosity.

Secondly, the pumping action is intermittent, so there is pulsation. To reduce this, a fly wheel to keep the rotating speed constant, or an air chamber (402) Accumulator) and the like

Thirdly, since the discharge amount of one stroke (stroke) is constant, it is possible to dispense and deliver a fixed amount.

Next, even if the number of revolutions is changed, the change of the discharge pressure is not as severe as that of the centrifugal pump. Therefore, there is always a suction / discharge valve to increase the number of parts, and the failure of the valve is fatal. In order to convert the rotational motion of the power into the reciprocating motion It is necessary to use a crank method or an exen method, which may complicate the components or cause vibration.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power plant unit 811, there are the following kinds of reciprocating pumps.

First, the piston pump has a seal line (packing) and a valve attached to the piston,

Second, the plunger pump differs from the piston pump in that the seal line is fixed to the pump body and is not attached to the reciprocating plunger. Therefore, the plunger 253 is easy to replace the packing, and a very high pressure can be obtained.

The pump is connected to a speed reducer 251 motor 192 and a wire rope 19 of a tug winch 137 to various motors in a rooftop collection tank 34 inside a machine room roof of a large building It is operated by pushing the top and bottom of the building with the switch button. The disaster prevention water (7) of the line of the fire prevention disaster prevention pipeline (168) is integrated into the equipment inside the pump fire extinguisher body, ) And firefighter (159) to the diaphragm pump (144).

In this way, the diaphragm pump (membrane pump 144) can pump water containing a large amount of fluid, mud or sand, and the suction or discharge is performed by moving the rubber membrane or the Teflon membrane 538 up and down . The feature that the crank 248 and the link belt 249 are formed on the rubber film 538 on the upper surface of the pump 144 and is not easily worn or closed with a fluid containing slurry (particle) It is composed of prevention of evolution. Therefore, it is suitable for chemical and harmful fluids because it can be completely leak-proofed without grand packing. It is suitable for fire disaster prevention in case of fire and other disasters.

And the wing pump (paddle pump) is a simple pump that moves the handle to the left and right to allow suction and discharge in two chambers. It can be easily mounted on the wall to transfer the oil from the drum, It is often used when you publish or publish.

As shown in FIG. 3D, in order to smoothly utilize the movement of the equipment installed in the past, the fire fighting cable control unit 256 of the nuclear power generation facility unit 811 A plurality of pumps are attached to the fire sensor pump body, and the tackle winch 137 described above is supplied with air supplied from the air compressor 80 to open (open) the air shutoff valve, A folding winch 137 is used in the rooftop fire-fighting cabin 394 and the steel tower 116 of the high and low mountains 395, The disc brake 399 serving as a brake is formed while winding the gears and the wire rope of the transmission 398 and the motor speed and the speed com- mer 397 so as to be able to perform the speed com- mer 397, (126) and electric A motor 192 and a switch are formed.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, a rotary pump Rothermal pump 357 is connected to the rotary pump 357 when one of the positive displacement pumps rotates The fluid is pushed and discharged between the main body (casing) and the rotor. The characteristic feature of this centrifugal pump is that it is not confused with centrifugal pump using centrifugal force. First of all, there is no suction / discharge valve such as reciprocating pump, continuous discharge and less pulsation. Secondly, high pressure discharge is possible. (Oil, oil, tar, pitch, paint, etc.), but at this time, the larger the viscosity, the smaller the number of revolutions and select the one with larger power. In the case of high pressure, it is sensed that a safety valve is installed, and that a liquid having no viscosity is good for a centrifugal pump. However, the gear pump is a type in which two types of gears are meshed, The second feature is that it is suitable for high-pressure use. Even if the discharge pressure is changed, the discharge amount does not change much. Thirdly, the liquid such as centrifugal pump is severely damaged The fourth is that the structure is simple, and it is easy to decompose, sift and clean, and the fifth is that the abrasion is promoted by the liquid containing the particles, so that it can not be used for the liquid containing solid particles, In addition, the spur gears are simple in structure, easy to process, costly, and widely used. However, there are noise and vibration, And the durability is weak.

In the rotary pump 357, the double helical gear for canceling the thrust (the force to be pushed in the axial direction) of the helical gear or the helical gear having a tilted inclination is difficult to process and the cost is high There is no noise or vibration.

The external gear pump 326a and the internal gear pump 326b are classified according to the shape of the gear and the reference for the sealing and cavitation by the gear tooth of the gear pump 326 Explain as follows.

In the pump of the rotary pump 357, the involute gear is in contact with the two points when the gears are engaged with each other, so that the liquid contained therebetween is hardly compressed and forms a very high high pressure, The rotation of the pump is a serious obstacle to the rotation of the pump, which causes an increase in the shaft force, breakage of the bearing, noise and vibration. However, in the rotary pump 357, If the two points are in contact, the liquid outside of the two points of the gear can not be inserted. In the space between the two points, a very large negative pressure is formed. If one point is in contact with the point, It collapses and makes a large noise, generates bubbles and causes vibration, which significantly reduces the durability of the pump. In order to prevent cavitation, first, the finishing should be very precise, the material should be carefully selected, so the price is very expensive. Secondly, the structure is complicated, so it is difficult to exchange or assemble. If it does not go through the angles, it will get caught soon, and the sixth can not be clamped on the way like gland packing, and once it is exchanged or wrapped, If you do not eliminate the vibration by connecting the power of the pump well, you will shorten the life of the seal. However, it is the most excellent sealing method at present. It is important to be able to avoid.

First, the type of mechanical seal is an inside-out type according to the set type, a single-seal type according to the seal type, and an unbalance type and a balance type according to the double seal type surface pressure balance type.

First, the inside (inside) type is the one commonly used in the way that the fixed side is on the pump side.

Secondly, the outside type of the outside is the case where there is a problem of the corrosion resistance of the structural material and the spring material in the way that the rotation is on the pump side. When the viscous coefficient is high viscosity liquid exceeding 100 cp, Is usually used when it is high vacuum.

Third, a single mechanical seal type is a general method in which the sliding surfaces are sealed together.

Fourth, double mechanical seal type is a type that has two sliding surfaces. It is used when it is a toxic liquid or a flammable liquid, when it needs to keep warm and cold, when it leaks, when it solidifies, when it is solid, when it is high vacuum, And is also effective for a liquid containing slurry which is a disadvantage of a high-temperature or low-temperature liquid or a mechanical seal.

Fifth, the unblanced type is generally used as a sealing method in which the pressure in the pump is directly applied to the sliding surface of the seal. Fluid pressure is less than 4kg / ㎠ (depending on the product, less than about 7kg / ㎠ for liquid with good lubricity and less than 2.5kg / ㎠ for liquid with bad lubricity).

Sixth, the blance type is a method that makes the pressure on the sliding surface of the seal not to be applied when the pressure in the pump is large. When the pressure is 4 to 5kg / ㎠ or more, It is used.

In the case of the ordinary mechanical seal, the spring is a spring that pushes the rotating ring of the sliding surface. When the liquid pressure is applied to the rotating ring, the contact force of the sealing section is added to prevent leakage. However, when the contact pressure is too high, the abrasion of the sliding surface is promoted. Therefore, when the internal pressure is high, this pressure is balanced to adjust the contact pressure.

The following cooling and lubrication is the frictional heat of the liquid or the sliding surface of the liquid. When the temperature rises due to the heat of the liquid, the material wears and corrodes or the packing seals. Therefore, the cooling and lubrication functions As shown in the drawing, a quadrangle 268 is formed above the shaft bar 390 and a flashing hole 361 is formed in the culver 367 in the cornering method 391 of the mechanical seal.

First, flushing is the most common method. In this method, liquid is injected and extracted from the outside of the high-pressure side liquid of the shaft end to maintain the temperature of the seal appropriately. Thus, vaporization of the sealing end face is prevented to improve lubrication, It also prevents accumulation on the shaft bar.

Second, quenching is a method of injecting a coolant into the sealing section of the seal so that the fluid does not flow to the high-pressure side of the shaft. When the fluid comes into contact with volatile fluids or air, If leaking fluid is washed out, dilute and recover. In addition, it is a device formed in the nuclear reactor main unit (1) 811 of the reactor main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for isolating air from the sealing end and preventing oxidation.

For example, in the case of handling (LPG) or the like, the cooling water is flowed outside the seal face so that it can be washed away.

Third, cooling is a method of cooling the outer periphery of the seal rather than a sealing cross section, which has a cooling effect lower than that of quenching, but does not require leakage to the atmospheric side, and there is no need to pay attention to the purity of cooling water.

In the material of the mechanical seal, the material of the seal varies depending on the type of the sealed liquid, the temperature, the pressure, the presence of foreign matter, the speed, the degree of leakage, and the like, but is known to the general public as stainless steel and Kaibon graphite It is a combination. Carabong graphite is self-lubricating, does not fuse with metals, has low friction, and is resistant to chemicals. In addition to stainless steel, stainless steel, ceramics, cemented carbide is added or heat treated. Dual structure block tank for treatment of nuclear waste to provide sufficient corrosion resistance and abrasion resistance Nuclear power plant with dust collector Main body (1) Internal nuclear power plant 811).

Examples of combining materials of the mechanical seal are as follows.

In the reactor installation of a nuclear power plant equipped with a double structure block tank dust collector for treating nuclear waste according to the present invention, there are one or a plurality of factors superimposed on the vibration of the pump.

First, according to the hydrostatic vibration, the vibration by the cavitation: the cycle of about 600 to 25,000 cycles brings about the rapid vibration and the noise. Second, the vibration by the surging phenomenon: Cavitation occurs when the discharge amount is large, The vibration due to the water hammer (water hammer) and the vibration due to the unbalance of the flow in the pump 4 and the vibration caused by the mechanical vibration firstly have a long period of about 10 to 0.1 cycle, The vibration due to the unbalance of the rotating body and the vibration due to the dangerous speed cause a severe vibration caused when the rotational speed of the shaft resonates with the natural frequency of the rotating body. Vibration due to solid friction is a kind of self-excited vibration, and there is a shortage of lubricating oil on the rotating shaft, And fourthly, the vibration caused by the hydraulic pressure of the bearing is a vibration generated due to the oil pressure of the bearing part when the rotary shaft rotates at an angular speed about twice as high as the dangerous speed, In particular, the vibration caused by the natural frequency of the pump is a problem in the vertical shaft pump. In the sixth place, the vibration due to the centering failure is a serious factor when the centering failure is caused. And the seventh is hydrodynamic vibration to the reactor facility of a nuclear power plant equipped with a double structure block tank dust collector for nuclear waste disposal which occurs due to the vibration caused by the prime mover and the eighth foundation weakness

The output definition for the use of the diesel engine 226 will be described as follows.

First, the term commercial refers to the generator The term "emergency" refers to the output (equivalent to ISO 8528 ESP) applicable to emergency generators used for a limited period of time in the event of a mains failure, while the engine model is referred to as a cooling fan And a flywheel 268 and a V-belt 252 are attached to the cylinder 250 and the cylinder 250, respectively. As shown in the figure,

As shown in the above table, the output tolerance is ± 5%. The description of the specification of the engine 226 is the same as the specification of the engine specification of the right side.

<Engine Specification>

Finally, the precautions for handling the compressor are described in detail as follows.

First, in general precautions concerning the handling of compressors,

First, the compressor is always kept clean and the surroundings are cleaned and arranged thoroughly.

Second, when the operation of the compressor is shut down, the engine is operated for a short time only once a day for a short period of time.

However, in case of long-term shutdown, disassemble and clean, replace worn, damaged parts or lubricating oil with new ones, drain all cooling water (drain) and prevent corrosion.

Third, each axis is checked and adjusted every opportunity.

Fourth, valves, pressure gauges, regulators, filters, etc. are prevented from malfunctioning by regular inspections and daily inspections.

Fifth, cool water uses clean water. Cooling tube is disassembled every June or year. It is cleaned with water vapor. If the weight is decreased by 10% or more, it is corroded or worn.

Sixth, always pay attention to the gas leak of each part, and the toxic and flammability should be detected with a small amount of detector, and proper measures should be taken.

Seventh, oil is selected with the help of the manufacturer.

The eighth, if there is an abnormality, stop driving immediately, notify the manufacturer and ask for repair.

In the following notes on starting,

Be sure to check that bolts, nuts and other screws are tight.

Next, fill the crankcase with a specified amount of lubricating oil and check the lubrication condition.

Pass the third cooling water and check whether the cooling water circulates.

Next, open the pressure gauge, pressure regulating valve, drain valve, etc. to check the pressure indication.

Next, the small compressor should be rotated by hand with no load. Check the connection of the electric motor by inserting the hand switch after checking the switch, and check whether the foreign substance is not caught in the cylinder.

The sixth suction valve is closed and the switch is opened with the bypass or drain valve open.

Next, when the normal rotation is performed, the drain valve and the bypass valve are closed from the first stage to the next stage, and at the same time, the suction valve is opened.

Finally, pay attention to pressure, lubricating oil, temperature, noise, vibration leakage at each stage.

Then, in the notes during driving,

The pressure, leakage, vibration, temperature, abnormal noise of each stage, the quantity and temperature of the cooling water, the temperature and pressure of the lubricating oil and the load of the motor are checked.

In particular, pay attention to abnormal increase or decrease in temperature or pressure, and never tighten or hammer the bolt during operation with leakage.

This is divided into the following.

First, regarding handling of reciprocating compressors

First, whether there is abnormality in the scale of the pressure gauge and the suction / discharge gas temperature at each end

Second, the change of bearing temperature and the abnormal rise

Third, keep a watch on the change of the cooling water temperature and adjust the quantity if necessary.

Fourth, watch the oiling situation of the cylinder lubricator, adjust the flow rate, and supply oil to the lubricator.

Fifth, the state of change of external flow or hydraulic pressure

Sixth, the piston rod packing leakage and temperature rise

The seventh is whether the color of the drain is rapidly blackened

Eighth, are there any differences in the sounds and vibrations of each part from normal?

Ninth Valves or flange joints such as safety valves, drain valves, etc. · Are there any gas leaks on other tight surfaces?

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

The following is the handling of Turbo Compressor

First, the lubricating oil pressure of the bearing lubricant or the temperature of the returned oil

Second, the oil pressure or return oil pressure for the shaft bar or the differential pressure or leakage flow

Third, whether vibration of each part such as main body, bearing,

Fourth, abnormality of bearing water temperature

Fifthly, the change of the cooling water temperature is monitored, and the quantity of water is adjusted when necessary.

Sixth, there is no leakage of gas from valve or flange joint of piping system or other tight surface

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

In the note of the fourth stop,

First, switch off the electric motor and close the intake valve.

Second, check the pressure drop and close the discharge valve. Observe the abnormal sound or vibration until stop.

Next, close the coolant valve to cut off the coolant and drain all water from the water jacket or cooling tube.

Finally, discharge any other condensate or oil.

In the notes on the fifth disassembly and inspection,

Firstly, when disassembling and checking, make sure that the machine is disconnected from the power source so that it does not operate.

Secondly, if the gas inside is toxic or flammable, it should be completely insulated and replaced with inert gas.

The following should be done after confirming that there is no pressure at each end of the decomposition operation.

Finally, when the cylinder head is disassembled, the bolt alternates in the order of the opponent facing each other, gradually releasing it to the two relatively positioned positions (of course, confirming that there is no abnormality,

As described above, each of the prime movers and the compressors are connected to each other by an electric motor and are connected to each other to show the conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment. As for the selection of the model in the separation process, the damage to the fire caused by the fire occurring in the blink of an eye for 1 second as described above clearly according to the type of fire by the type of fire as a fire-fighting disaster prevention countermeasure is impossible. Therefore, the fire should be selected as the most appropriate place for the initial site precaution.

Referring to FIG. 3E, there is shown a conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, (459) Each valve configuration providing the land and off-shore reactor facilities of the faucet (496) of the faucet type of the integral type and the piping accessories,

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, The control valve 459 is integrally connected to the pressure reducing valve 460 and the pilot operated pressure reducing valve (not shown) in the distribution input device of the nuclear plant installed in the offshore of the general faucet 496, A main valve 466, a main valve spring 467, an adjusting spring 468, and a control valve 468 are connected to the main valve 461 and the magnetic pressure reducing valve 461, A spring type safety valve 473 and a relief type safety valve 474 and a screw type pressure regulating valve 471b and a screw type automatic pressure regulating valve 470a, a flange type pressure regulating valve 471b, a safety valve 472, A steam-type pop-spring-type safety valve 475, a PFO-type safety valve 476, The automatic level adjuster 478 and the automatic level adjuster 479a as well as the automatic level adjuster 480 and the air vent valve 481 and the thermal type automatic air vent valve 482 and the bucket Type hot air type automatic air exhaust valve 483, a refrigerant pipe valve 484, a refrigerant stop valve 485, a feed valve 486, a bellows type charge valve 487, and a diaphragm-type charge valve 488, an expansion valve 489, a diaphragm-type expansion valve 490, a bellows-type expansion valve 491, a rich valve 492, a refrigerant pressure regulating valve 493 and a solenoid valve 494 The water supply type common faucet 496 of the piping accessories is composed of the faucet body 529, the packing box 530, the packing press 531, the faucet 532, A disk 534, a disk packing 535, a water-resistant packing 536, an aging resistant packing 537, And Teflon membranes 538, which are installed in the reactor installation of the nuclear power plant, and the disruption prevention preventive control connection structures of the nuclear power generation facility 811 of the nuclear power plant.

The ground level load (GLL), the ground level load on the upper (GLL), and the ground level load (GLL) Abbreviated as GLD).

On the right side of the valley, the wire rope 19 for the 5000 kg overhead crane for the industrial site or the rope 131 at the point A and B of the valley at the bottom of the valley, The ropes 19 and 131 are connected to the hooking hooks 18 by the shackle 23 and the driving wheel rollers 135 by the hoisting ropes 135 at the points C and D, The lifting baskets 42 and the injection nozzles 10 are connected to each other by a 15-m-long fire hose at the cable car (256) The length of the injection nozzle is set so that the length of the injection nozzle is set to a predetermined value after the collecting tank 34, which is a bucket of a movable dual structure, and the pump 71 are installed together in the cable car 256, (A), (B), (C), and (D) according to the length of the nuclear waste (451) showing the conventional construction constituted in the nuclear reactor main body (811) of the nuclear reactor main body (1) of the nuclear power plant having the double structure block tank dust collector and the general type faucet (496 ) Of nuclear power plants and nuclear reactors equipped with respective valves to provide the land and ocean reactor facilities, and the operation of nuclear power plants is carried out on land and in the oceans of the world.

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, (496) of the faucet of the faucet of the faucet of the accessory, and the distribution apparatus of the reactor facility of the nuclear power plant installed in the sea,

(Sluice valve), stop valve, glove valve, angle valve, check valve, and reduction valve are used to control the fluid and flow rate of steam or water. A reducing valve, a cock, etc. may be used depending on the purpose of use.

Table 2-1 shows the valve configuration, Table 2-2 lists the valves, and Table 2-3 lists the (KS) specifications of the valves.

<Table 2-1> Configuration of valve

<Table 2-2> Classification of Valve

<Table 2-3> Valve KS specification list

As shown in FIG. 3E, the following describes the slew-valve device in the disaster prevention preventive control section connection structure of the nuclear power plant section 811

The valve is also referred to as a gate valve 296 by opening and closing the valve by a screw bar in parallel with the cross section of the pipe. When the valve is fully opened, the resistance of the fluid flow is very small compared to other valves. Fluid is not left in the valve chamber, the diameter is usually 50mm or 1,000mm, and the large size is operated by power. However, there is a drawback that the valve is expensive and takes time to open and close the valve. Therefore, when the diameter of the water pipe of the power plant 267 and the water pipe of the water supply pipe are large and it is not necessary to frequently open and close the valve, various accessories formed on the slow valve valve 403 are attached, The valve 403 is connected to the valve cover 405 and the slow valve 406 by the packing press 407 and the packing press nut 408 as shown in the figure, The valve seat 409, the handle 410, the handle nut 411 and the packing 412 are attached.

As shown in FIG. 3E, in the specification table of the slow valve on the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811,

The kind of the slew valves includes a wedge gate valve, a parallel slide valve, a double disk gate valve, a wiping valve, and the like depending on the structure of the disk.

As shown in FIG. 3E, in the apparatus configuration of the wedge gate valve 413 in the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811,

The wedge gate valve 413 is divided into a single valve 414 and a flexible valve 415.

As shown in the figure, the unit type is a wedge-shaped valve, and the angle of the wedge is usually 6 ° to 8 °, while the bronze small valve has a wedge angle of 8 °.

As shown in the figure, the flexible valve 415 is provided with a groove at its center, so that the flexible valve 415 absorbs the influence of heat on the valve seat in the high-temperature pipe or the like by using the flexible.

Second, in the device configuration of the parallel slide valve 416,

The parallel slide valve has a spring inserted between two parallel valve bodies so that the valve is pressed against the valve seat by fluid pressure.

As shown in FIG. 3E, there is a gap between the valve body and the disk in the disconnection prevention preventive control connection structure of the nuclear power plant 811, so that there is little friction on the valve side and is not affected by thermal expansion. .

The valve disc and the valve seat act as a slide, so the valve seat uses a hard metal. This valve is suitable for high temperature and high pressure when vertically mounted.

Next, in the device configuration of the double disk gate valve 417,

The wedge type valve is difficult to be completely opened and closed due to deformation of the valve seat due to frictional resistance and thermal expansion. In order to prevent this, the valve body is divided into two, and the valve disk is widened by the thrust of the valve step to press the valve seat against the valve seat.

The structure adopting the advantages of the wedge gate valve 413 and the parallel gate valve 416 has a relatively small influence on the deformation due to temperature and pressure.

As shown in FIG. 3E, a detailed description of the device configuration of the stop valve 418 in the disaster prevention preventive control connection structure of the nuclear power plant unit 811 is as follows.

It is called the glow valve that the inlet and the outlet are in a straight line according to the flow direction of the fluid and the angle valve is the angle of the inlet and the outlet. The connection method of pipe is screwed joint and flange joint method. The material is made of forged steel for bronze high temperature and high pressure when it is used for small medium pressure, and cast iron is used for large type. The opening / closing spherical surface of the valve has a flat sheet, a conical sheet, a spherical sheet, and a stud sheet, which have a large resistance loss against the flow of fluid and are prone to collect dust in the water bodies. This is the most widely used type of valve because it is easy to make valve and valve seat when the lift is small and the valve opening and closing is fast.

Valves and valve stems are connected by packing glands and valves and rods are in the form of cylinders.

The Y-shaped glow 419 is used for applications such as glow valves, and is designed such that the valve cylinder is inclined by 45 to 60 degrees with respect to the center line for the purpose of reducing the resistance.

The angle valve 420 has the same function as the glow valve 419, but is used to change the flowing direction of the fluid at right angles.

As shown in FIG. 3E, the needle valve in the connection structure of the preventive shut-off control part of the nuclear power generation facility 811 has a conical needle 15 to 16 mm used for flow control, (Bonnet) 422, the disk 423, and the lid-attaching valve seat 424 are attached to the valve body 421 as shown in the figure, The packing presser 429 and the valve presser 426 are pushed into the screw fitting 431 and the cover bolt 432 in the packing presser ring 429 and the packing presser 430 in the handle 427 and the cover fitting ring 428, A cover bolt nut 435 is attached to the pin bolt 433 and the pin 434 and a detent screw 438 is attached to the handle nut 437. A gasket 441 is attached to the washer 439 and the packing 440, Device.

3E, the specification sheet (flange type glow valve and angle valve) of the valve to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811,

As shown in FIG. 3E, the cock in the connection structure of the preventive control section of the nuclear power plant 811 is classified into a cock 1 type 443 and a cock 2 type 444, and a cock 1 type 443 are formed with a bronze threading main cock 445 and a bronze threaded gland cock 447 in a cast iron flange type gland type 446 and the cock 2 type 444 is formed of a trunk 448 and a four- (449). However, when the fluid flows in a straight line and the cock is rotated 1/4, the passage is opened completely, so that the opening and closing is fast. There are many cast iron and bronze materials, and small diameter low pressure springs are used for drainage.

The cock may be a one-way stream of two-way cocks and a two-way stream of three-way cocks.

The main cock is (a) fastened with a nut under the plug 458 as shown in the same figure, and the gland cock is pressed by the packing as shown in (b) and (c).

3E, the swing type check valve 452 and the lift type check valve 453 are connected to the check valve 451 of the connection structure of the nuclear power generation facility part 811 to prevent the disaster, It is used to automatically close the valve when the fluid flows in one direction. It has a swing type and a lift type.

3E, the swing type check valve 452 on the connection structure of the disaster prevention preventive control unit of the nuclear power generation facility unit 811 is opened and closed by rotating the pin 457, so that the frictional resistance Can be used for any piping that is less horizontal than vertical type.

The lift-type check valve 453 has a structure of a valve seat such as a glow valve. As shown in the drawing, the valve is vertically lifted by the pressure of the fluid. The lift of the valve is about ¼ of the diameter and the friction resistance against the flow is large. A check valve 451 is formed and a disk 456 and a disk pin 457 and a plug 458 are attached to the body 454 and the cover 455. The check valve

A check list

In addition, the lift type check valve 453 has a Sumorenski type which has a wing to mitigate the impact.

The check valve is designed to flow only in a certain direction, so pay attention to the flow direction of the fluid when installing. Bronze screw type of 10A or 15A or cast iron or cast steel flange type of 50A or 200A is used.

The control valve 459 is connected to the pressure reducing valve 460 and the safety valve 472 via the temperature control valve 477 and the temperature control valve 472 to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The pressure reducing valve (460) is installed between the high-pressure pipe and the low-pressure pipe so that the lift of the valve is braked by an appropriate device, the pressure on the high-pressure side And the pressure of the low-pressure side is kept substantially constant regardless of the change of the steam consumption amount and the change of the steam consumption amount.

The actuation of the valve is usually done with a bellows, diaphragm 463 or piston 127.

When the pressure ratio of the high-low pressure is within 2: 1 and the pressure ratio of the high-low pressure is exceeded, it is better to use the two pressure-reducing valves 460 in series to perform the two-stage pressure reduction. The structure is generally composed of an adjustment spring 468, a diaphragm 463, a pilot valve 464, a piston 127, a main valve 466, and the like as shown in the same figure.

3E, a secondary-side sensing hole 462 and a diaphragm 463 are provided in a pyrotechnic-operated pressure reducing valve (magnetic force type) 461 in a disaster prevention preventive control connection structure of the nuclear power plant 811, A main valve spring 467 is attached to the pilot valve 464 and the piston 127 and the main valve 466 and a screw-type (½~1½ inch) (2 to 6 inch) pressure regulating valve 471b and a flange type

3E, a spring type safety valve 473 and a relief type safety valve 474 are connected to the safety structure of the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811, And is separated into a Pope spring type safety valve 475 and a Pope type safety valve 476.

The closing mechanism of the fluid is the same as the glow valve 419 and the glow valve 419 is opened or closed by an external force. However, the safety valve is closed by the force of the spring on the external force sensor or the weight of the valve stem and the weight of the lever Is opened and closed.

As shown in FIG. 3E, the safety valve to the connection structure for preventing and preventing disaster of the nuclear power generation facility 811 is installed in a pipe for handling a pressure vessel such as a boiler and a high-pressure fluid, When the specified limit is reached, the internal energy is automatically released to the outside to keep the pressure in the container at a safe level at all times.

It is a safety device that must be attached to pressure vessels with large accumulation energy such as boilers. One type of safety valve is a relief valve. It is used as a valve connected directly to a pipe line of a pipe through which a pressure fluid flows, and is used for the purpose of warning while adjusting the pressure of the pipe constantly.

The performance of the valve is determined by the accuracy of the ejection pressure, the pressure at the ejection stop, the pressure difference in the ejection, and the ejection volume. When the valve is opened and the steam is spouted, the pressure at the inlet side is referred to as the ejection pressure, the pressure at the inlet side is referred to as the ejection stop pressure when the valve is closed, and the difference between the ejection pressure and the ejection stop pressure is referred to as the ejection difference pressure.

As shown in FIG. 3E, the temperature control valve 477 in the connection structure of the disaster prevention preventive control unit of the nuclear power plant 811 has the same configuration as the auto temperature control valve 477, It is an oto control valve which is opened and closed by the action of bellows which is very sensitive to temperature change and automatically adjusts the flow rate of heating steam or cooling water. It is used for heat exchanger and heavy oil heater.

3E, an automatic level regulator 480 is additionally formed in the automatic water dispenser 479 in the disaster prevention preventive regulating connection structure of the nuclear power generation facility unit 811. The automatic water leveler 479 and the regulator 480) is to automatically level the level of the autosappler boiler to its maximum efficiency point, where the level difference is always derived at abundance, thereby preventing the risk caused by the shortage of the boiler water supply.

3E, the ventilation valve 481 belonging to the regulating valve 459 to the disaster prevention preventive control connection structure of the nuclear power generation facility unit 811 is provided with an oto-air exhaust valve thermostat (for steam, 533 mm x 68 mm, 483) to the dimensions of the exhaust valve (width x length; 53 mm x 56 mm, 482) And the air vent valve for the air is either an inferior type or a thermostatic float type, and a float type valve is adopted as a warm air vent valve. The fuselage is made of bronze bronze, bronze bronze, and brass.

3e, a float valve 484 belonging to the refrigerant stop valve 485 and a pack valve 486 belonging to the refrigerant stop valve 485 are connected to the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811, (Diaphragm type) 488 is formed by a refrigerant stop valve 485 and a diaphragm type expansion valve 490 and a bellows type expansion valve 491 are formed in the expansion valve 489 And is formed as a refrigerant pipe valve 484 integrally with a solenoid valve 492 and a pressure regulating valve (for refrigerant 493) integrally with a solenoid valve 494 and an oto water feed valve (not shown).

As shown in FIG. 3E, the emergency valve 486 belonging to the refrigerant stop valve 485 and the valves 487 and 488, which are connected to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The valve 485 has a structure of a valve seat and a valve seat similar to those of the above-described glow valve. In order to prevent refrigerant from leaking from the valve body side through-passages, a ground packing type (phone net type) And a diaphragm type in which a shaft is sealed by a diaphragm and a diaphragm type which is sealed by a bellows and can not be manufactured by a bellows or a diaphragm. The Grand type has all shaft caps (bonnets, caps) and is now mostly packed type to prevent the exchange of bellows, packs or packing tightenings, and to prevent leakage when the valve is opened.

As shown in FIG. 3E, in the connection structure of the disaster prevention preventive control section of the nuclear power generation facility 811, the large body is a pouring agent or a cast iron agent, The sheet is made of Nerunel metal.

Valve material should be harder than valve seat material to prevent abrasion.

The expansion valve 489 is formed by separating the diaphragm-type expansion valve 490 and the bellows-type expansion valve 491

Generally, the installation of conventional nuclear power plant's nuclear reactors installed according to the installation location of the inland river in the global village and coastal area of the coast is very weak in safety from natural disasters and the nuclear power generation operation is stopped or the nuclear power plant is exploded, , So that once the companies manufacturing these reactors have met the requirements of the containment vessel corresponding to the fourth wall of the recently developed reactor to meet the reliability of the power consumer and the fifth wall A plurality of through holes are formed at a predetermined angle of 45 ° in the upper part of the nuclear reactor building, and a machine cutter and a construction machine crane and a conveyor are machined in a drilling machine and a cutting machine rotary lathe machine. A number of safety valves are connected to the bolt and nut on the block piping line. The nuclear waste treatment storage block tanks and the radiation type connection structures are constructed in eight double structure block tanks each having a diameter twice the diameter of the reactor building along the circumference of the outer wall of the nuclear reactor building. Nuclear safety and economics are very severe and dangerous Reactor facility design process has been exposed and nuclear power safety and economics to recover the reliability of power consumers. Nuclear Radiation Leakage Control for the Equipment Nuclear Reactor Suitable for the Double Structure Block Tank Reactor Dust Collector The need to install nuclear waste disposal shielding device has been urgently required and the design and experiment for the safety and economical solution have been continued and research Global Nuclear Power Plant Nuclear power plants with multiple reactors Nuclear power plants Nuclear reactors for reactor shielding Nuclear radioactivity leakage control Dual structure block tank Dust collector Nuclear power plant forming a distribution device Nuclear power plant Nuclear power plant with double structure block tank for nuclear waste treatment Nuclear power plant with nuclear reactor Much effort has been devoted to finding the reactor design process.

However, since the demands of those skilled in the art have become more diverse, and a serious risk level has been expressed in terms of nuclear safety and economy, in order to solve the desire to recover the reliability of electric power consumers, nuclear waste treatment double structure block tank reactor Nuclear Radiation Leakage Control of a Nuclear Power Plant with Nuclear Power Plant Dual Structure Block Tank Nuclear Reactor Corresponding to the Fourth Walls of the Nuclear Reactor and the Nuclear Reactor Corresponding to the Fifth Wall A plurality of penetrating The hole is machined by a computer cutting machine, a construction machine crane and a conveyor in a drilling machine and a rotary machine of a cutting machine, and a block pipe line of a double pipe structure is formed in the plurality of through holes, while a plurality of safety valve connection structures are connected to a double pipe structure block pipe Gaskets rubber packing in bolts and nuts in line The flange connection structure is equipped with a hand tool hammer and a wrench and at the same time a double space structure block tank having a diameter twice the diameter of the reactor building along the circumference surface of the nuclear reactor building is provided with an empty space for a nuclear waste treatment storage block tank The double pipe structure piping line with multiple safety valve connection structures constituting a double pipe structure piping line in a plurality of through holes is provided with a radiation type connection structure and a plurality of reactor facilities of a marine power plant floating plant nuclear plant. Waste treatment shielding device and nuclear waste treatment for nuclear power plant Double structure block tank A double structure block reactor of a nuclear power plant equipped with a dust collector is a construction machine and a construction machine for the foundation of a floating power plant of a marine power plant Marine tunnels formed by replacing marine vessels The floating power plant of the marine power plant composed of the distribution device of the transportation device operates the nuclear plant power plant of the floating power plant of the marine power plant by operating the nuclear power plant nuclear reactor plant of the marine power plant at the sea bottom easily, The reactor main body of the nuclear power plant having the double structural block tank dust collector for the nuclear power generation nuclear waste disposal is constituted so that the safe operation of the nuclear reactor nuclear plant can be further performed by further inputting the barge hull position movement control device and the throttle control device.

A plurality of nuclear reactor facilities for nuclear power generation of the prior art, which are installed in the reactor main body of a nuclear power plant having the double structure block tank dust collector for treating nuclear waste, provided with nuclear energy will be described.

The conventional water reactor having various water reactors for nuclear power generation according to the prior art is formed of a boiling water reactor system 802 and a pressurized water reactor system 803, and a power reactor is mainly used for a light reactor Other than that, a gas cooling furnace reactor facility 804, a multi-purpose high temperature gas reactor facility 805 and a new conversion furnace reactor facility 806 are used. The boiler water reactor reactor facility 802 and the pressurized water reactor facility 803, A gas cooling furnace reactor installation 804 and a multi-purpose high temperature gas reactor installation 805, a new conversion furnace reactor installation 806 and a high-speed proliferation furnace installation 838, Level nuclear power plants.

Not only are the reserves of uranium as a raw material of nuclear energy limited, but also there is nuclear energy as an energy source that causes pollution less than fossil fuel. Therefore, this nuclear energy is attracting attention as a new power source in the future. The more serious problem is the disposal of nuclear waste.

Environmental pollution caused by nuclear waste can fatally destroy our only earth.

So, we have come up with a way to get energy without pollution, and today we want to get the answer from the sun and the sea.

There are many ways to get energy from the ocean. Tidal power to obtain energy using tidal and tide movements, Wave power to obtain energy using the power of waves, Sea water temperature to obtain energy using the temperature difference of seawater. By using various methods, we can provide an unlimited amount of pollution-free energy at sea.

The double structure block tank of the nuclear radiation leak control nuclear reactor construction for inserting into the nuclear reactor reactor double structure block for the treatment of nuclear waste tank In various types of reactor facilities of a nuclear power plant having a dust collector,

Nuclear power plant nuclear waste treatment double structure block tank Various kinds of reactor facilities of nuclear power plants equipped with reactor dust collectors are equipped with transport materials for control of nuclear fuel explosion prevention control to store and shield nuclear radioactive pollutants from outside the reactor. Using the shielding concept of in-depth defense concept of Nuclear Safety Engineering, it is possible to prevent leakage of nuclear fuel radiation and prevent nuclear explosion from outside of dual structure block tank dust collector. Prevention of nuclear fuel radiation leak and primary fuel explosion prevention. Double structure block tank reactor The nuclear waste treatment is controlled to the inside of the nuclear power plant, and at the same time, the secondary structure is composed of a plurality of nuclear reactor facilities of a nuclear power plant having a double structure block tank reactor dust collector, Outside of double structure block tank dust collector It is equipped with dual pipe structure block piping to control nuclear waste treatment, as well as dual pipe structure block piping system, including a pressure sensor sensor and a water pump connection structure to efficiently improve the operation of the nuclear power plant. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Which is equipped with a safety valve and water pumps to generate soap bubbles contained in cooling water. It uses a nuclear waste disposal device, which converts the energy of water into kinetic energy, Of a nuclear power plant equipped with dual structure block tank dust collector The facility is a double structure block tank. It is a connecting structure composed of the outer surface of the outer wall of the former reactor building in the form of an egg. It has a double structure block tank for the treatment of nuclear power generation nuclear waste. Operation of Nuclear Power Plants in Land and Ocean Nuclear Power Plants to Improve Operation of Nuclear Power Plants Having Significant Difference Between Nuclear Reactor Facilities and Nuclear Power Plants Having Nuclear Radiation Leakage Control of Nuclear Waste Treatment Shielding Equipment Is generally equipped with double pipe structure block pipes having the potential energy of water and is equipped with a safety pressure sensor and water supply pumps to generate cooling water and soap bubbles, In the form of a structural capsule, along the circumference of the outer wall of the former reactor building The reactor structure of the nuclear power plant equipped with the double structure block tank dust collector for the nuclear power generation nuclear power generation is manufactured, and it is manufactured at a remarkable difference from the reactor facility in which the existing nuclear fuel cell explosion occurred.

The present invention relates to a nuclear power plant having a double structure block tank dust collector for collecting all of a plurality of nuclear reactor facilities for nuclear power generation of the prior art, 672 of the present invention will be described with reference to the drawings as follows.

Referring to FIG. 1, there is shown a schematic diagram of a conventional boiling water reactor (802) nuclear power plant showing an essential constitution of a conventional boiling water reactor plant nuclear power plant according to an embodiment of the present invention. Nuclear Reactor Facilities (802) Outline of Nuclear Power Plant Side Lateral Construction Road,

As shown in Fig. 1, the conventional boiling water reactor equipment 802 constituted from among various types of reactor facilities of the conventional nuclear power plant 672,

The reactor structure of a nuclear power plant according to the prior art has a structure in which the five-folded protective walls are formed in a closed structure, and explosion occurs in any one of the five-folded protective walls. If the number of neutrons is large, When the energy exceeds the danger level and then a boiler reactor that exploits the fission chain reaction in an ideal state explodes, it can be recognized that the boiling water reactor (BWR) It is a reactor that can use water as a moderator and coolant and boil it to directly drive the turbine of the generator. The steam void in the moderator caused by boiling has a negative reaction effect. Half of positive The output of the reactor can be suppressed by controlling the flow rate of the cooling water by changing the flow rate of the cooling water in addition to the control rod. The boiling water reactor (802) power plant is simple in system, Can be said to be an easy plant.

The suppression of the output of the boiling water reactor assembly 802 is controlled not only by the control rod 798 but also by changing the flow rate of the cooling water 287 so that the output of the boiling water reactor assembly 802 is suppressed by the recirculation flow rate control system, Water reactor facility (802) The power plant is composed of a power plant with simple system and easy operation control.

Referring to FIG. 1A, a reactor boiler 688A and a turbine building 688A, which illustrate a conventional boiling water nuclear reactor nuclear power plant internal structure showing an essential constitution of an embodiment formed by a conventional boiling water reactor plant nuclear power plant according to the present invention, A diagonal configuration of the waste building 688G in the diesel generator building 688E and the nuclear fuel building 688F in the control building 688C and the auxiliary building 688D in the building 688B,

1A, a reactor building 688, which constitutes one embodiment of a conventional boiling water nuclear reactor nuclear power plant, includes a control building 688C and an auxiliary building 688D in a reactor building 688A and a turbine building 688B. (688E) in the diesel generator building (688E) and the waste building (688G) in the nuclear fuel building (688F) to provide an easy connection control structure for operation of the boiling water reactor (802) of the nuclear power plant (672) And a power plant.

Hereinafter, as shown in Figs. 1A to 1D, the constituent elements of a conventional boiling water nuclear reactor nuclear power plant according to an embodiment will be described as follows.

Referring to FIG. 1B, there is shown a conventional boiling water reactor (802) nuclear power plant according to an embodiment of the present invention. As shown in the figure,

      Referring to FIG. 1C, there is shown a schematic view of an elementary boiling water reactor plant nuclear power plant according to an embodiment of the present invention, which is constituted by a conventional boiling water reactor plant nuclear power plant, road,

       Referring to FIG. 1d, there is shown a side view of a conventional boiling water reactor plant nuclear power plant showing an essential constitution of one embodiment formed by the operation of a nuclear power plant of a conventional boiling water reactor plant nuclear power plant according to the present invention As a result,

       As shown in FIG. 1B, a conventional boiling water nuclear reactor (802) nuclear power plant is formed by a conventional boiling water reactor (802) nuclear power plant. The following describes the main structure inside the 1100 MWe boiling water reactor pressure vessel 813 as follows.

The boiling water reactor (802) is the first commercial reactor developed. The boiler water reactor (802) has a capacity of 1.2 million KW and the capacity of the boiler water reactor (802) Unlike the facility 803, the steam generator 810 is not required, but the steam 780 containing the radioactive material circulates to the turbine 267, A steam separator 818 and a steam dryer 786 are disposed on the core 791 and a steam guide 786 and the like are disposed on the core 791 composed of the assembly body 671 and the control rod 798. A control rod guide tube 798e And a control rod drive housing 798a. Around the core 791, there are a core shroud, a jet pump 325, and the like.

     The fuel assemblies 671 of the boiling water reactor equipment 802 are arranged in a square lattice of 88, for example, a total of 64 such as 62 fuel rods 689, one spacer supporting water rod and one water rod, It is surrounded by a zircalodian channel box.

     The fuel rod 689 has a structure in which a uranium hexafluoride fuel pellet 683, a plenum spring or the like is loaded into a zircaloy cladding tube 682, helium 176 is sealed, and both ends are welded and sealed with a plug. The plenum is a space that accommodates the fission product gas discharged from the fuel pellets in accordance with combustion and is set such that the internal pressure of the fuel rod 689 is not excessive.

     The control rod 798 of the boiling water reactor has a crisscross blade to move through the gap formed by the four fuel assemblies 671 and the control rod 798 is provided with a boron carbide B4C Hafnium (Hf), or other types using them in combination.

     Below the control rod 798, there is a falling speed limiter having an umbrella-type structure in order to limit the falling speed of the control rod 798 when the drop occurs.

      In addition, there is a socket for coupling with the control rod drive mechanism.

     As the drive mechanism for the control rod 798, there are a hydraulic lubrication type and an electric drive type. In both systems, the nitrogen gas pressure stored in the accumulator is used for rapid insertion of the control rod 798. However, The entire control rod 798 is inserted into the core 791 at the lower part of the core 791 to stop the reactor installation.

Since the boron-containing water injection system capable of stopping the reactor installation can be installed even when the entire control rod 798 can not be inserted, the boron absorbs the neutrons 675 well. Boron-containing water is stored in the tank, 791).

1C, the carbon steel containment vessel 808 to the boiling water reactor installation 802 has a steel thickness of 3 cm, the pressure vessel 813 has a steel thickness of 16 cm, and a concrete hangar (reinforced concrete) 225 has a thickness of 200 Cm &lt; / RTI &gt;

First, in the control of the output of the boiling water reactor installation 802, the boiling water reactor installation 802 uses the hard water 654a as the moderator 676 and the coolant 816, (Void) generated in the moderator 676 by boiling in addition to generating steam of about 70 kg / cm 2 under pressure, and the hard water 654a is used to control the use of light water, that is, ordinary water It says.

      Secondly, when the control rod 798 is drawn out, the reactivity of the reactor increases and the output increases.

     Thirdly, when the boiling is promoted and the void is increased, the density of the moderator 676 is decreased, and the deceleration efficiency of the neutrons 675 is lowered, so that the negative reaction is applied.

     In the fourth case, when the reactivity of the positive and the negative reactivity generated by the withdrawal of the control rod 798 are balanced, the reactor output is stabilized.

     In the fifth case, when the control rod 798 is inserted, the opposite phenomenon occurs. Therefore, as the void decreases and the density of the moderator 676 increases, the efficiency of decelerating the neutrons 675 increases and a positive reactivity is applied to the reactor .

     In the sixth case, when the reactor is balanced with the negative reactivity applied by the control rod 798, the reactor is stabilized at a new output. Thus, the boiling water reactor assembly 802 has self controllability by voids.

     Next, the heat generated in the fuel rod 689 in the core 791 is transferred to the coolant 816.

     Next, in the boiling water reactor installation 802, heat transfer in the boiling region is utilized.

     In the ninth, the size of the heat flux flowing due to the temperature difference between the heat transfer surface and the coolant 816 is obtained in a lot of experiments, and in the transition boiling region where boiling is vigorous, the heat transfer is lowered so that the fuel covering material 681 may be burned The operation is restricted so as not to reach the transition boiling region during normal operation and during operation and during the operation.

     The heat generated in the fuel rod 689 is transferred to the coolant 816 in the tenth.

    Since the cooling water 287 is recirculated and the flow rate of the cooling water 287 is increased to increase the flow rate of the refrigerant flowing through the core 791, (816) recirculation system is provided.

     The twelfth one is that when the reactor installation is combined with the turbine generator 772, the reactor installation output can follow the turbine load.

     In the boiling water reactor installation 802, if there is a change in the load at the final stage, the control device 798 first adjusts the reactor installation output by increasing or decreasing the flow rate of the insertion or recirculation of the control rod 798.

     In this state, when the output of the reactor installation and the load are shifted, the pressure of the reactor installation increases or decreases.

    Thus, the pressure of the reactor facility is controlled by adjusting the opening of the turbine add / drop valve.

     This method is called "(Reactor Master / Turbine Slave) reactor facility priority system".

     When the turbine 267 stops abnormally, the flow of the steam is interrupted to increase the reactor installation pressure, but the bypass valve of the turbine 267 is opened to suppress the increase of the reactor installation pressure.

     As shown in Fig. 1d, the engineering safety system in the boiling water reactor facility 802 will be described as follows.

     If the cooling water 287 of the core 791 is lost due to a breakage accident in the piping of the reactor cooling system, (ECCS) is installed in order to prevent the damage of the fuel. This system is composed of a high pressure core sprinkler system, an automatic decompression system, a low pressure core sprinkler system and a low pressure injection system, It is connected to engineering safety systems.

     If a fuel breakage occurs, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

     However, it is also true that there is a problem to be considered, such as the operation of the power plant by enlarging the operation of the boiling water reactor (BWR, 802), and the securing of personnel related to these power plants equipped with maintenance and maintenance, As a long-term task of nuclear power in the future, it is thought that the construction of the nuclear power plant concept that is close to Siam is necessary for the next generation reactor considering social acceptance due to the lack of workers' resources. do.

     In the following, the study of the simplified boiling water reactor (BWR, 802) is based on the concept of SBWR (Simplified BWR) (600 MWe) (BWR, 802), a combination of a static containment system such as a static containment vessel cooling system and a gravity falling ECCS, including a 1000 MW expansion, and a natural circulation core. (BWR, 802), which is composed of a large natural circulation core, a static containment vessel cooling system, and a gravity falling type ECCS, (791) can eliminate the current BWR recirculation system, the recirculation pump (239) and the MG set and connection to it (BWR, 802), it is necessary to meet the problems and necessity of natural circulation establishment in order to realize the research of simplified boiling water reactor (BWR, 802) That is, the problem of response to output control remains.

     Second, the static containment vessel cooling system of the simplified boiling water reactor (BWR) 802 eliminates the decay heat of the core 791 after an accident for a long period of time, and various designs have been proposed. However, I / C (Isolation Condenser), which is a condensation heat transfer method using a water-immersion type insulation tube, which has high applicability to the furnace, has been selected.

     Third, the static safety system such as the gravity-drop type ECCS of the simplified boiling water reactor (BWR, 802) has an emergency power supply to the core 791 in case of an accident, Power is not strong. However, the continuous drive system and the complex network of conventional pumps, motors, valves, piping, and auxiliary machinery systems together with the above-mentioned static containment cooling system are greatly simplified, which reduces human factors related to operation. (791) irrigation is possible by reflecting the interpretation result of the accident such as water supply pipe breakage etc. To the full capacity and the applicability of this method is suggested.

     Hereinafter, the following directional description of the simplified boiling water reactor installation (BWR, 802) will be described as follows.

     In the simplified BWR, since a large amount of water such as the pressure control pool 240 as the source of the ECCS is installed on the upper portion of the containment vessel, the center has become higher and the containment vessel 808 has been severely subjected to various tests. have.

     As described above, since the elementary technology of the simplified BWR is a good step to confirm its conformity, the static simplification is starting from the existing concept that it is intimate to the person and it can be suitable for the social situation of the world in the future Potential technologies are provided.

     Uranium 235 (812), plutonium 239 (801), and neutrons 675 in the nuclear reactor (BWR) 802 operation of the boiling water reactor (BWR) 802 are mixed to prepare a mixed reaction of atoms and other atoms with the neutrons 675 However, since the generated neutrons 675 become triggers for generating the above-described reactions, they are called chain reactions. In the end, the control of the neutrons 675, that is, the control of the chain reaction, to be.

    The core 791 melting and nuclear meltdown in the boiling water nuclear reactor facility (BWR 802) operation includes the dissolution of the fuel assembly 671 and the core 791 structure by nuclear fuel overheating, The spent fuel rod 689 is exposed to the air when the cooling water 287 is not present, or the fuel rod 689 exposed to the air is overheated while the temperature rises, Radiation leakage becomes inevitable.

     In the case of the conventional boiling water reactor (BWR, 802) operation of the above-mentioned nuclear power plant, in 1986, when the Chernobyl accident occurred, the radioactive water vapor rose to 30,000 feet (9144 m) and suffered a long time. At worst, At the same time, the amount of uranium 235 in the spent fuel was less than 1%, so the radioactive efflux was possible. However, because there was no possibility of a nuclear explosion, the nuclear fuel rod (689) It took 6 months to cool down, and at the same time, when the temperature exceeded 2,000 degrees centigrade, radioactive materials such as cesium and iodine contained in the fuel rod (689) provided vaporization. At the same time, zirconium and water vapor were mixed, And the hydrogen generators are used as the coolant 816 to provide a temperature control of a conventional boiling water reactor facility 802 Or

     Referring to FIG. 1E, the operation of the nuclear reactor of the Fukushima boiling water reactor system before the accident, which shows the essential constitution of one embodiment formed by the operation of the nuclear power plant of the conventional accident-occurred Fukushima boiling water reactor plant nuclear power plant, Elementary Boiling Water Reactor Facilities as shown in Fig.

     As shown in Fig. 1 (e), the operation of the nuclear reactor of the boiling water reactor (802) is a boiling water reactor (BWR) type in which the steam of water boiling in the core is directly sent to the power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

     However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats did not disclose detailed information, refused to provide US technical support, and at the same time, they poured seawater into a wreckage and drove fire trucks and helicopters into the building.

     Due to this method, various impurities mixed with seawater were converted into radioactive isotopes and contaminated, and the contaminated seawater evaporated, spread to the surrounding area, and flowed into the sea and contaminated vast areas with radioactivity.

      Hiroshima, Nagasaki Japan, which has been devastated by the atomic bombs, has ironically built many nuclear power plants. On March 11, 2011, an earthquake and tsunami hit the northeastern part of Japan, causing the Fukushima nuclear plant to melt its core and leak radioactivity.

     Referring to FIG. 1F, there is shown a conventional boiling water reactor (802) nuclear power plant having a boiler water reactor (802) showing the essential constitution of an embodiment formed by the operation of a nuclear power plant, As a side view,

       As shown in Fig. 1F, the operation of the boiler-type nuclear reactor 802 is controlled by the nuclear waste in the nuclear reactor 802 and the spent fuel rods 689 in the boiler- Substances that have undergone a reaction. Concentrated plutonium, and enriched uranium. Exposure to air causes a fission reaction and releases radioactive material. The zirconium coating on which the fuel rod is packed is oxidizing, causing a fire. Radioactive materials can spread to the atmosphere due to fire.

     At the time of the Soviet Chernobyl Nuclear Power Plant explosion in 1986, when the nuclear reactor of the boiling water reactor facility (802) started to operate, a military helicopter was used to shield a huge amount of radiation from nuclear fuel and graphite moderator (676) 2,400 tons of lead, 1,800 tons of sand and mud. The boron compound was to absorb the neutrons that caused the chain reaction, while the lead and mud were to shield the radiation.

     The safe operation of the nuclear reactor facility of the boiling water reactor 802 is limited to the deceleration of the coolant 816 and the neutrons 675. The nuclear reactor coolant of the Dreamy Island, Chernobyl, and Fukushima nuclear reactors The uranium fuel rod 689 can not be cooled with water and is exposed to the air and melted. When the uranium fuel rod 689 melts, Uranium flows out and risks increase.

     In this situation, the Drill Mile Island nuclear power plant of the boiling water reactor facility 802 is sprayed with boric acid water by the emergency sprayer installed above the nuclear reactor building 688 and the emergency cooling water 287 is restored. Fortunately, Respectively.

Referring to FIG. 1G, a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional pressurized water reactor type nuclear reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1G, the operation of the nuclear power plant of the pressurized water reactor (803) is performed by supplying water to the pressurized water reactor (803) through water stored at a high pressure And is a pressurized water reactor 803 in which heat is transferred from the core to the steam generator 810. The steam generator 810 provides a turbine 267 operation to produce electricity, while the pressurized water reactor type reactor 803 is the most widely used nuclear reactor facility in the world. The pressurized water reactor or water- It is also referred to as a type pressurized water channel.

      In the pressurized water reactor type nuclear reactor facility 803, the hard water of the coolant compilation is firstly used in the PWR for the designing and editing of the pressurized water reactor, but in the primary system, it is provided at about 315 degrees Celsius, (654a) at 2000 psig and 15 MPa and a pressure of 150 times the atmospheric pressure do not boil while at the same time the water in the primary system is in the secondary system in most designs, the temperature is 275 degrees Celsius and the pressure is 900 psig The water flowing at a pressure of about 6.2 MPa is made into steam and sent to the steam turbine 267.

     In the case of the commercial pressurized water reactor type reactor installation 803 of the pressurized water reactor type nuclear reactor 803, the amount of the coolant 816 is constant, but the reactor can adjust the flow of the coolant 816, Neutrons 675 are provided in a reactor and have a shape similar to that of a thermal reactor design. However, many water molecules are the same size as the neutrons 675, and when colliding with the neutrons 675, neutrons 675 While the neutron "deceleration" is better with a higher molecular number of the water molecules, while the pressurized cooling water 287 has a structure in which the hydrogen atoms in the water molecules control the velocity of the neutrons 675 The use of water is one of the main safeguards of light water reactors, consisting of a neutron reduction structure that regulates the speed of water as it rises and the density of water molecules is lowered, If the neutron (675) deceleration structure has a lower void effect and at the same time the reactor malfunctions, the deceleration rate of the neutrons (675) becomes lower, the neutron (675) deceleration structure becomes lower, The inherent stability is very stable in a pressurized water reactor type reactor (803).

     The pressurized water reactor (PWR) facility is a nuclear reactor facility that uses water as coolant and moderator for pressurized water reactor pressure. The name of this reactor facility is the name of the internal circulation system, The pressurized water reactor facility is the most common reactor facility in the world. About 230 nuclear reactors are used for power consumption and hundreds of reactors are used for propulsion. Korea's standard pressurized water reactor facility (803) is constructed in Koryeong Gwangseong.

     In the early days of editing, the Westinghouse Betis Lab developed a military pressurized water reactor (803) at Westinghouse.

     In the United States, the pressurized water reactor facility (803) program operated the reactor from 1954 to 1974, but the first two pressurized water reactors (803) operated the TMI-1 and TMI-2 At this time, the construction of the new power plant was stopped due to partial core melting in TMI-2 in 1979, and at the same time, the core and fuel assemblies of the pressurized water reactor facility 803, the control rod and the pressure vessel 813, 658), a primary system, a secondary system, a condenser, a turbine and a generator connection structure, and the pressurized light water reactor provides a reactor chain reaction operation.

     In the pressurized water reactor (PWR) facility, it is delivered to the primary system circulating between the fuel and the heat exchanger 658. The primary heat system, called the primary system hot steam generator 810, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser 790 and at the same time enter the steam generator 810 again while at the same time the turbine 267 of the secondary system provides power production in connection with the turbine generator 772, (PWR, 803) facilities are compared with two pressurized light water reactors and other reactors. In a pressurized light water reactor, there are two cooling water primary systems and a secondary system Gt; 267 &lt; / RTI &gt; Frequency electric power production arranged in connection with (772) and or, at the same time, the two flows of water (hard water). In contrast, in a boiling water reactor (BWR), there is no strain.

Referring to FIG. 1H, a conventional pressurized water reactor type nuclear reactor (803), a conventional pressurized water reactor type nuclear reactor (803) nuclear power plant operating at a nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, As an elemental aspect of the operation,

As shown in Fig. 1H, in the pressurized water reactor type nuclear reactor (803) nuclear power plant, the water pressure of the coolant compilation is changed from the PWR to the first However, in the primary system, it is provided at about 315 degrees Celsius, and at the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light valve 654a at a pressure of 150 times the air pressure does not boil, In the primary system, water is sent to the steam turbine (267) in most designs, with water vapor at 275 degrees Celsius and 900 psig at 6.2 MPa.

     The stability of such a pressurized water reactor type reactor (803) is such that when the pressurized water reactor is provided with a very stable production, but when the RBMK (graphite reduction speed boiling water pressure tubular reactor) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, they are heated and sintered. However, at the same time, the production of ceramic pellets made of uranium dioxide is carried out. (Zirconia), helium is injected into the zirconia rods to help heat transfer, but the finished fuel rods are bundled with bundles of fuel-fuel assemblies, which are called aggregate bundle fuels, It is loaded.

    It is very important to prevent a chain reaction from occurring in the core of a nuclear reactor facility that does not allow a rapid chain reaction in a pressurized water reactor (803) of the nuclear power plant of the nuclear power plant. However, when the chain reaction occurs, , Or 200 to 300 fuel rods of a pressurized water reactor, 150 to 250 fuel assemblies, or simultaneously enter uranium at 80, It is maintained at 14X14,17X17 pieces of about 100 tons.

     The pressurized water reactor (803) fuel bundle of the nuclear power plant operating at the nuclear power plant is provided at about 4 meters, and at the same time, there are many pressurized light water reactors with many pressure vessel control of the pressurized light water reactor and many pressure vessel controls of the military primary pressurized water reactor Adjust it to positive.

     In the pressurized water reactor type nuclear reactor facility 803 for operating the nuclear power plant, since the neutron is absorbed immediately, the reactor system is controlled by reducing the chain reaction by the pressurized light reactor. Therefore, the control pump of the entire pressure relaxation system is included. Is to provide high concentration of neutrons in a large number of emergency stopping cooling water, but also CANDU is an auxiliary means to enable the boric acid to quench the chain reaction. .

     In addition, the control rod enters the fuel assembly from the pressure vessel and is usually used when the first nuclear power plant is started or when the nuclear power plant is shut down. At the same time, the fuel assembly is regulated to a height at the reactor plant, The fuel rod of the stabilized fuel pellets of the barrier wall and the first barrier pellet was burnt inside the radioactive material generated by the fuel rod. The second barrier wall was enclosed with the nuclear fuel pellets and put into a metal tube of a special alloy as a nuclear fuel rod The small amount of gas that is released is a reactor vessel provided with a 20 cm thick steel containing the nuclear fuel assemblies in the reactor vessel which is the third barrier wall at the same time to provide a seal to the second barrier wall.

     In addition, the shielded concrete wall, which is the fourth barrier wall, prevents the leakage of the radioactive material as a concrete wall surrounding the nuclear reactor facility. In the containment vessel of the fifth firewall, the safety system and the whole space At the same time, the biological shielding wall of the 5-1 barrier wall is provided with a final biological shielding wall as a thick building 70 to 100 cm outside the steel, and at the same time, It is a container and a dome form, and it is a safe nuclear building to prevent the leakage of radioactive material, but at the same time, it provides an external shielding of radioactive material in case of an accident.

     However, the Chernobile model, RBMK, with a graphite reduced-rate boiling water pressure tubular reactor (RBMK), has become increasingly unstable as the thermal response increases, but the choice of this graphite-slowing boiling water pressure tubular reactor (RBMK) .

Referring to FIG. 1I, a conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant, and a conventional nuclear power plant pressurized water reactor facility (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in Fig. 1 (i), in the pressurized water reactor (803) nuclear power plant, the operation of the nuclear power plant is such that during the pressurized water reactor installation (803) .

Uranium fission and reactor facilities As mentioned above, 99.3% of stable uranium 238 is contained in natural uranium, 0.7% of unstable uranium 235 which can cause fission, and at the same time, domestic nuclear reactor types are mainly PWR ) And pressurized water reactor (PHWR). At the same time, the water reactor is a type of conventional nuclear reactor (803) operated by Kori, Yonggwang and Uljin, mainly supplied by the United States. (H ₂ 0) as a moderator (676), which is a material promoting the fission reaction using concentrated uranium (U-235, 4-5%) as a fuel, and at the same time one year or one year and six months Once the reactor is shut down, the fuel must be replaced.

In the meantime, the heavy water type reactor is a type supplied from Canada, which is currently in operation in Wolsong. As a characteristic, the reactor is horizontal and uses natural uranium (U-235, 0.72%) as fuel, moderator (676) ₂ O) and a portion of the fuel can be replaced daily.

Referring to FIG. 1J, the conventional pressurized water reactor (803) nuclear power plant is operated by a nuclear power plant. In the conventional nuclear power plant, a pressurized water reactor (803) (803) side-by-side configuration of an elementary pressurized water reactor type reactor,

As shown in FIG. 1J, the operation of the nuclear reactor of the water reactor (803) during the pressurization operation is the same as that of the pressurized water reactor In the comparison of water reactor equipment during pressurization, the distinction between pressurized water reactor (PWR) and pressurized heavy water reactor (PHWR) is rated power of 1 million kW and 70,000 kW. The reactor type is vertical type, and the pressure vessel is a horizontal pressure tube. The operating pressure is from 158.2 kg to 110 kg at the operating temperature of ~ 310 ° C and the fuel used is fuel for the use of low enriched uranium (U-235, 4 ~ 5%) and natural uranium (U-235, 0.72% 816) and moderator 676 (D ₂ O), and the period of preventive maintenance of the fuel replacement period is 1 year to 1.5 years. At the same time, Wolsung nuclear power plant in Korea is a Canadian type This reactor installation uses cheap natural uranium (about 0.7% U-235) as fuel and moderator (676) and coolant (816) as expensive heavy water D ₂ O) is used.

     If the heavy water of the water reactor 803 is boiled during the pressurization, the reactor installation system is pressurized to about 110 times to prevent boiling of the heavy water because the reactor 676 and the coolant do not act properly. Water heated to 300 degrees Celsius is sent to the steam generator 810 and then heated to heat water on the secondary side through heat exchange to generate a steam 780 for driving the turbine generator. At the same time, as in the case of the pressurized light water reactor, And the turbine equipment side are completely separated so that the secondary side is the same as the pressurized light water reactor type, and at the same time, the cooling side material (816), which is slightly different in shape from the primary side, Heating is provided by the heat generated by the fission through the inside of the equilibrium cylindrical reactor, while the pressurized light water reactor (803) provides the reactor with a vertical barrel The coolant 816 is circulated from the lower portion of the core 791 to the upper portion.

     Referring to FIG. 1K, the pressure of the pressurized water reactor installation 803 of a conventional nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional pressurized water reactor (803) Internal decomposition of the pressure vessel 813 of the water reactor installation 803 during elemental pressurization, shown as the internal decomposition side of the vessel 813,

      As shown in FIG. 1K, the operation of a nuclear power plant at the pressurized water reactor (803) nuclear power plant has a low probability of causing nuclear fission when natural uranium is used as the nuclear fuel. Therefore, it is necessary to separately install the moderator (676) system, which is a heavy water reactor which can sufficiently absorb the neutrons and contribute enough heat neutrons to the nuclear fission while effectively decelerating the high-speed neutrons generated during the nuclear fission. At the same time, Three of the nuclear fuel change are basic characteristics of the pressurized heavy water reactor.

Referring to FIG. 11, there is shown a structural configuration of nuclear fission of uranium fuel 235 showing nuclear fission structure of nuclear fuel uranium 235 showing the essential constitution of an embodiment formed by operation of a nuclear power plant of a conventional nuclear power plant according to the present invention,

       As shown in FIG. 11, the structure of the nuclear fuel pellet 683 of the nuclear power plant constituting the reactor facility of the nuclear power plant having the double structural block tank dust collector for nuclear nuclear waste disposal is described in detail as follows I will explain.

      The electrons are composed of the nucleus 815 and the electrons surrounding the nucleus 815. The nucleus 815 is composed of a proton 674 and a nucleon 675, (815b) that are transversely driven by the coupling force between the two forces.

]쯤 이나 그 질량은 원자(784) 질량의 대부분을 차지한다.The radius of the nucleus 815 is about 10 ^-14 m and the neutron 675 of the nucleus 815 is electrically neutral and the mass is almost the same as the proton 674 and the diameter of the nucleus 815 is atomic 784)

], The mass occupies most of the atom (784) mass.

     The structure of nuclear power generation is the same as that of thermal power generation. Nuclear power generation also generates steam by rotating a steam turbine. Nuclear power generation and thermal power generation have different ways of generating steam. The thermal power plant rotates the steam turbine 267 by burning coal, oil and natural gas in the boiler 778 , The nuclear power generation generates nuclear fission in the reactor, and steam is generated from the heat to rotate the steam turbine (267).

      The structure of an atom or a helium atom is an atomic nucleus 815 in which a proton 674 and a neutron 675 are combined with each other. The atomic nucleus 815 refers to the amount of static electricity carried by the object of the electron 785, (+), The charge of the same sign repulses each other, and the charge of the other sign pulls each other.

The number of protons (674) in the nucleus (815) is equal to the number of neutrons (675). The number of protons in the hydrogen and isotopes of triple hydrogen is all one If the number of neutrons (675) combined with the number of protons (674) is called the mass number, the half life of uranium 238 is 4.51 × 10 ⁸ years, shorter than uranium 238.

      The atomic nucleus of uranium (815) is a model of a red bead, a neutron (675), which is a proton (674). Uranium 238 (uranium 238) and uranium 234 (isotope 234) are weighted according to the number of neutrons It is different. First, uranium 238 (653a) is the most abundant uranium, but unfortunately it can not fission. The following are uranium 235 (812) and uranium 234, which are only slightly contained in natural uranium, so it is uranium 235 (812) that is capable of fission.

      The atomic nucleus 815 formed by the collapse of the radiation nucleus 815 contains a property that it is unstable and stabilizes even a little bit. It is a natural collapse, that is, it becomes a stable atom by self-emission of gamma rays to alpha particles or beta particles. 235 (812) has the greatest property, so the main role of nuclear power is uranium 235 (812).

     This is because fission occurs in the form of collapse of radioactive materials.

     However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the electric charge of the atomic nucleus (815) of Ura 235 (812) is +. Again, when a proton having a charge of + is collided, it repels each other by the law of charge and tangles the proton 820.

      Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

      When the neutrons 675 collide, the uranium 235 breaks up into pale yellow barium or silver white barium which is well oxidized in the air and krypton is a slightly colorless odorless gas mixed with air, At this time, large energy is generated.

      Referring to FIG. 1m, there is shown a partial side view of a method of using a control rod for controlling a chain reaction of nuclear fuel fission in a nuclear reactor of a conventional nuclear power plant according to the present invention. And the lower drawing shows a reactor fuel production and a decomposition of the steam generator 810, the pressurizer 814, and the coolant 816 of the reactor steam take-off system 1073, which show the process of generating plutonium in the uranium 238, Straight configuration Road,

As shown in FIG. 1 m, the number of protons 820 in the nucleus 815 is equal to the number of neutrons 675. The isotopes of hydrogen, for example, are hydrogen atoms in water and deuterium. The number of protons (820) is the same as the number of neutrons (675). The number of neutrons (675) is different from that of hydrogen and heavy hydrogen. The number of neutrons (675) Speaking of the half-life of uranium-238 (679) is shorter than 4.51 × 10 ⁸ years of uranium 238 (679) in.

The atomic nucleus of uranium (815) is a model of a red bead, which is a neutron (675). The bean is a proton, isotope uranium 238 (679), uranium 235 (812) and uranium 234 is a neutron (675) Uranium 238 (679) is the most abundant uranium, and unfortunately, it can not be fissioned. Therefore, uranium 235 (812) and uranium 234 are contained only in natural uranium, which means that uranium 235 812).

The atomic nucleus formed by the collapse of the radiation nucleus 815 contains a property that it becomes unstable to become even a little stable. It is a natural collapse, that is, it emits gamma rays to alpha particles or beta particles and becomes a naturally stable atom 784. Uranium 235 (812) has the greatest property. So the main role of nuclear power is uranium 235 (812).

Because nuclear fission now occurs in the form of the collapse of radiation.

However, even if the uranium 235 (812) naturally collapses, it can not take out the energy, so the uranium 235 (812) artificially collides with the well-fractured uranium 235 (812) What does it collide with? If the question is solved, the charge of the atomic nucleus (815) of uranium 235 is +. Again impinging the protons 674 having a charge of + will repel each other and tie the protons 674 by the law of charge.

Since neutron 675 is electrically neutral, it is easy to access the nucleus 815, and of course colliding is also simple.

When the neutrons 675 collide, uranium 235 (812) is split into a colorless odorless gas that is barely oxidized in air or krypton is slightly mixed in the air, provided that the barium is either pale yellow or silver white barium, There are three bounces, which generate a large amount of energy.

Originally, uranium 235 (812) absorbs slow neutrons (675), but the neutrons (675) that are fresh from nuclear fission can not catch the neutrons (675) because of their high velocity. In order to slow down the velocity of fresh neutrons from nuclear fission Or a heavy water or graphite moderator 676 having a larger molecular weight than ordinary water is used.

If the particles collide with heavy objects, the neutrons 675 are splashed out. However, if the particles are of similar size, the neutrons 675 will eventually fall into thermal neutrons 675 because they are splashed. The thermal neutrons 675 are not hot, And the neutron 675 having an energy of less than leV (electron volt) is called a heat neutrality. The neutrons 675 collide with another uranium 235 (812) to divide and collide, . 1e V to 1k e V are called low-speed neutrons (812), and 100k e V to 10M e V are high-speed neutrons (675).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons may be increased when the chain reaction is finished, but that is not so. If the number of neutrons (675) is high, the chain reaction becomes excessive, and the energy generated when the nuclear fission breaks out exceeds the danger level, and then the reactor of the nuclear reactor in which the fission chain reaction proceeds in an ideal state is exploded.

In order to prevent such an explosion, a control rod 798 made of cadmium is inserted and controlled to control a chain reaction of the fission in the reactor, but since the control rod 798 eats the neutron 675 generated from the fission, Which slows down the neutron 675. In nuclear fission, the speed and number of neutrons (675) are controlled by the end of the running horse.

When 1 k g of uranium 235 (812) is cleaved, neutrons (812) protrude from barium and krypton, and their mass is lighter than 1 k g of original uranium 235 (812).

Since there are two or three neutrons (675) in a single fission, I think that the number of neutrons (675) is probably good after the chain reaction, but that is not it. If the number of neutrons (675) is too high, the chain reaction will be excessive, and the energy generated when the nuclear explosion occurs will exceed the danger level. If this happens, a nuclear reactor will be exploded that will progress the fission chain reaction in an ideal state. In order to prevent such an explosion, In order to control the chain reaction, the control rod 798 made of cadmium is inserted and removed, and the control rod 798 eats the neutrons 675 generated from the fission, so that the moderator 676 lowers the speed of the neutrons. In nuclear fission, the velocity and number of the neutrons (675) are controlled by the endothelium, and when one kilogram of uranium 235 (812) breaks down, neutrons (675) protrude from barium and krypton, 812) It is lighter than 1kg compared with 1kg.

According to Einstein's formula E = mc ² , this lighter mass is converted to the kinetic energy of barium and krypton and neutrons (675). In theory, a mass of 1 g is the same heat as when about 2150 tons of oil are burned together. In fact, the energy of 1k g of uranium 235 (812) is calculated as 20 billion kcal of energy. If it is gasoline, it is enough to make 500 rounds of cars by car, 300 tons for coal, and 2 million liters for oil One neutron (675) divides one uranium nucleus into two or three neutrons (675).

Referring to FIG. 1, a conventional gas cooling furnace reactor 804 according to the present invention includes a gas cooling furnace reactor 804 of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operating a nuclear power plant, (804) side-by-side configuration of the elementary gas cooling furnace reactor,

1N, in the structure of the gas cooling furnace reactor facility 804, graphite is used as a moderator 676, carbon dioxide is used as a coolant 816 in the gas cooling furnace in the structure of the gas cooling furnace reactor facility 804 And the use of natural uranium and enriched uranium 235 as the fuel and the use of carbon dioxide as the coolant 816. At the same time, the thermal efficiency and the thermal efficiency equivalent to the thermal power of the high-temperature and high- And at the same time, the structure of the nuclear reactor furnace facility 804 is configured to perform nuclear power generation.

A nuclear reactor facility using gas as a coolant 816 to the gas-cooling furnace reactor facility 804, a calderhall type of graphite-retarded natural uranium fuel type, carbon dioxide gas (CO ₂ ) as its reforming type, and a high temperature gas- (CO ₂ ) is supplied to the cooler 816 as a cooler hole type reactor, which is a nuclear reactor type reactor with a deceleration natural uranium fuel type reactor, and an improved version thereof, while using helium (He 176) The generic name of the reactor used by. The structure of a gas-cooled furnace reactor (804), which is a typical reactor cooling furnace reactor developed in the UK, using natural uranium as fuel, graphite as a moderator 676, carbon dioxide gas as a coolant 816, and the like.

     Referring to FIG. 10, there is shown a conventional gas cooling furnace reactor facility 804 according to the present invention, an elemental conventional gas cooling furnace reactor facility 804 showing the construction of an embodiment formed of a nuclear power plant, As a side view,

    1O, a gas cooling furnace reactor facility 804 formed by the nuclear power plant operation of the nuclear power plant is provided with a coolant 816 inside the reactor pressure vessel 813 of the gas cooling furnace reactor facility 804, And carbon dioxide gas is supplied from the carbon dioxide gas 164 and the coolant 816 provided in the gas cooling furnace reactor facility 804 The helium 176 is provided as a coolant 816 and at the same time the connection structure inside the reactor pressure vessel 813 formed by the operation of the nuclear power plant is connected to the recirculation pump 239 and the water feed pump 241, The steam 780 and steam are cooled in the pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689 and the steam pipe 779 and the steam pipe 779, Which is a cooling device of the apparatus for making the reactor 790, the core 791, A control rod drive housing 798a provided inside the heat exchanger 793 and the control rod 798, a control rod drive shaft 798b and enriched uranium 812, and a gas cooling furnace reactor facility 804 ) To make nuclear power.

      Referring to FIG. 1P, there is shown a constitution of an embodiment of a steam generator 810 of a conventional nuclear power plant reactor according to the present invention. One elementary nuclear power plant reactor generator steam generator (810) Side construction of connecting structure Road,

      As shown in FIG. 1P, the structure of the steam generator 810, which is formed by the connection structure of the steam generator 810 of the reactor plant of the nuclear power plant, includes a steam outlet 810a and a water supply nozzle 810b to the turbine generator, The cooling water 810c, the vibration suppression rods 810d, the tubular support pipe 810e, the tubular lid 810f, the tubule bundle 810g, the tubular steel plate 810h, the separation plate 810i, the primary outlet 810j, A steam generator 810n and a steam generator internal body 810o as a connection structure of a steam generator 810 of a nuclear reactor nuclear reactor installation. The steam generator 810a includes a primary inlet 810k, a heat exchange tube 810l, a cooling water passage 810m, The formed steam generator 810 facility structures include the recirculation pump 239 and the feed pump 241, the circulating water pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689, A pipe 779 and a steam 780 and a cooling device 780 for cooling the water vapor into water, A control rod drive shaft 798a and a control rod drive shaft 798b and enriched uranium 812 provided inside the core 791 and the reheater 793 and the control rod 798, And a reactor facility (804) for nuclear power generation.

Referring to FIG. 1q, a conventional multipurpose hot gas furnace reactor 805 of a conventional nuclear power plant showing an essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the nuclear power plant 805 of the conventional multi-purpose hot gas furnace according to the present invention, Elementary gas cooling furnace reactor facility (804) side view configuration showing nuclear operation as external side view

As shown in FIG. 1Q, the multi-purpose high temperature gas furnace 805 is provided with a multipurpose hot gas and the reactor installation 805 is provided with graphite as a moderator 676, and the coolant 816 includes helium gas 176). At the same time, the fuel is composed of enriched uranium 235 and thorium, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation.

Referring to FIG. 1 r, a conventional multi-purpose high temperature gas furnace reactor 805 nuclear power plant (FIG. 1), which shows the construction of a conventional multi-purpose hot gas furnace reactor 805 nuclear power plant 672 according to the present invention, 672 in a side view of the nuclear reactors 805 side of the elemental multi-purpose high temperature gas reactor,

As shown in FIG. 1 (r), graphite is used as a moderator 676 in the structure of the nuclear reactor 672 multi-purpose high temperature gas reactor 805, and helium gas 176 is used as a coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, The operation method includes a water pump 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser The control rod 798 and the coolant 816 are connected to the reactor structure 805 as a multipurpose hot gas of the nuclear power plant 672 to constitute nuclear power generation.

 Referring to FIG. 1s, there is shown a constitutional example of a conventional multi-purpose hot gas furnace 805 nuclear power plant according to the present invention. The constituent conventional multi-purpose hot gas furnace 805 and the new conversion furnace 805, Nuclear reactor facility (806) Elementary multi-purpose high temperature gas reactor facility (805) and new conversion furnace reactor facility (806) showing side view of nuclear reactor operation of nuclear power plant.

The use of graphite as a moderator 676 is provided for the structure of the reactor facility 805 of the nuclear power plant 672 and the use of helium gas 176 is used for the coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, In the operating mode, the internal structure 805a of the Pebble-Bed type high-temperature gas path in which the primary cooling system is housed is provided with the heat shield 805b, the through-hole stopper 805c, the auxiliary circulator 805d, the control rod reservoir 805e, The control unit 805g and the auxiliary circulating unit 805h and the auxiliary heat exchanger 805i and the core support structure 805j and the prestressed concrete reactor vessel 805k and the PCRV safety valve 805l, A fuel inlet 805m, a helium circulation unit 805n, and PCRV The HTR-module reactor structure 805p includes a spherical fuel outlet pipe 805q, a boron refining furnace system 805r, a reflector region control rod 805s, A gas circulating unit 805w and a high temperature gas pipe 805x, a surface cooler 805y and a heat insulating material 805z, and at the same time, the fuel supply pipe 805t, the water supply pipe 805u, The use of enriched uranium 235 (812) and thorium and the heat of helium gas 176 are transmitted to water to generate nuclear power by steam generation. At the same time, 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser 790 and a control rod 798 and the coolant 816 to connect the reactor facility 805 to the multi-use hot gas of the nuclear power plant 672 At the same time, nuclear power plant (672) is operated as a nuclear power plant. In the new reactor type reactor structure (806), a new type of reactor power plant (806) And the steam is supplied to the steam turbine 267. The steam is supplied to the steam turbine 267 through the steam turbine 267, The heavy water 654b is used as the moderator 676 and the neutrons 675 are more absorbed than the hard water 654a so that the utilization efficiency of the uranium is increased so that the plutonium (ATR) as an example, the MOX fuel of "Fugen" is taken as an example, and the characteristics and specifications of the fuel for ATR and the manufacturing method thereof Do technology However, since the ATR is a water-cooled type, such as a heavy water reduction ratio, and a pressure tubular type, the fuel assembly has a circular section and is slightly lower in plutonium hatching than the MOX fuel for a light water reactor. However, Equivalent, PuO2 and UO2 powder adopts a two-phase combination method to prevent the generation of plutonium spots and scattering of plutonium hatching degree.

Referring to FIG. 1 (a), a nuclear power plant of a conventional nuclear power plant showing the essential constitution of one embodiment formed by the operation of a nuclear power plant of a nuclear power plant of a conventional new type conversion reactor 806 according to the present invention, New Transition Reactor Facilities (806)

As shown in Fig. 1 (t), the new conversion furnace 806 and the characteristics of the fuel are developed as a national project together with a fast breeder reactor as a Japanese independent reactor, and the use of heavy water as a moderator Therefore, it is a resource saving type power generation furnace capable of efficiently controlling the fuel combustion with a lower degree of enrichment than the light water reactor.

It is possible to freely load with MOX fuel and non-enriched uranium fuel because there is a relatively small influence on the reactor due to the kind of fuel. It is necessary to consider arrangement and control rod as in the case of using MOX fuel in light water reactor There is no.

Since the new type conversion reactor 806 is a heavy water reducing boiling water cooler and is a pressure tubular type, the fuel assembly has a circular section. In addition, there are SGHWR of UK and CANDU-BLW of Canada, There is no example in which a large number of fuel such as ATR is used.

The fuel of the new conversion furnace reactor 806 is slightly lower than the MOX fuel for the light-water reactor, but the fuel production method is almost the same, and the plutonium of the inner fuel rod whose neutron density is lowered Hatching degree is raised.

The structure and specifications of the fuel "Fugen" fuel of the new conversion furnace 806 include "Fugen" MOX fuel, in which 28 fuel rods are arranged concentrically with four inner layers, 8 middle layers and 16 outer layers, The upper and lower tie plates are placed on the upper and lower tie plates, respectively. In the middle, the fuel rods are maintained at appropriate intervals with twelve spacers at appropriate intervals. The main specifications of the fuel assembly and the fuel rods and the assembly are shown. Also, the plan has been discontinued, but the main specification of the 36-fuel assemblies developed as a fuel for the reactor facility (806) demonstration after the "Fugen" was also presented.

Fuel of the reactor plant 806 of the new type conversion furnace 806 is produced by mixing the PuO 2 powder and the UO 2 powder, press-molding them, and then sintering them to prepare pellets, filling them into cladding tubes to form fuel rods, And at the same time, this fuel processing method is almost the same as MOX fuel for fast breeder reactors and light water reactors, and the shape of the pellets is not limited to the corner chamfer used in BWR and the dish used for PWR And the fuel cell system 806 is provided with the fuel cell of the new type conversion reactor 806 adopting the both.

The fuel of the new conversion furnace reactor (806) is mixed with a lubricant to a particle size suitable for molding, and then molded into a green pellet by press molding. At the same time, this is pre-sintered at 800 ° C to evaporate the lubricant After disassembling, sintering is carried out at 1,650 ° C for 2 hours. At the same time, the sintered pellets are judged whether the whole water is passed through a diameter separator. If the diameter is large, the side of the cylinder is grinded with high accuracy by a centerless grinder, At the same time, unlike the case of high-speed fuel, plutonium hatching degree is low. Therefore, no-core grinding using ordinary water such as uranium fuel is provided. The pellets completed with the above-mentioned new type conversion reactor facility 806 are subjected to various analyzes and inspections, and passed through the inspection of the government office and passed to the fuel rod processing step, which is the next manufacturing step.

The pellet of the new conversion furnace reactor 806 is automatically filled by plugging the clad with a plug welded on one side. At this time, the end of the cladding tube is contaminated by contact with the pellet, A countermeasure for mounting a thin plate called a pipe mouth mask on the tube end is provided.

After plugging the pellet of the reactor installation 806 with the new type of conversion, a plug is attached to one of the remaining pipes and sealed and welded by TIG welding to provide a fuel rod. After that, the sealed fuel rod surface is carefully decontaminated, After making the draw from the box and then performing various nondestructive tests such as surface contamination, appearance, dimension, bending, and X-ray penetration test of the welded part, it is inspected by the government office and passed to the assembling process of fuel assemblage which is the next manufacturing process.

If the upper and lower tie plates and the twelve spacers are fixed in advance in a predetermined position of the automatic assembly apparatus, the fuel assembly assembly of the new type conversion reactor unit 806 can be automatically inserted Thereby completing the fuel assembly. The aggregate is inspected and cleaned by bending and twisting, passed the pre-use inspection of the government office, and shipped to the nuclear installation site.

Referring to FIG. 1U, a new type conversion reactor furnace 806 of a conventional nuclear power plant 672 according to the present invention is installed in a nuclear reactor main body of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment A dual structure block for treating nuclear waste according to the present invention. The present invention relates to a dual structure block tank for a nuclear power plant having a dust collector, a new conversion furnace facility (806) provided in a reactor facility, and an elementary nuclear Double Structure Block for Waste Treatment Nuclear Power Plant Reactor Facility Having a Tank Dust Collector In the present invention, a new reactor furnace facility (806)

As shown in FIG. 1U, the nuclear explosion-proof double structure block tank 598 in the form of a raw statistic of the nuclear power plant 627 is provided with a double structure block tank 598 among the plurality of reactor facilities for processing radioactive nuclear waste. A new type conversion reactor 806 in the structure of the nuclear reactor facility 806 which uses the light water 654a as the coolant 816 to increase the utilization of the nuclear fuel than the existing reactor And the steam is generated at the high temperature during the rising of the fuel, so that water and steam are separated from the steam drum, and the steam is sent to the steam turbine 267 to form an energy nuclear power. The heavy water (654b) The absorption efficiency of neutrons is lower than that of hard water, and the efficiency of utilization of uranium is increased. As fuel, nuclear power generation using plutonium and natural uranium is formed, A double-structure block tank is provided with a double-structure block tank dust collector for treating nuclear waste, which is in the form of raw statistics, in a nuclear reactor plant having a dust collector, Inside the reactor facility of the nuclear power plant, a new conversion reactor facility (806) consists of the input of the carrier construction machine.

Referring to FIG. 1 v, there is shown a cross-section of an elemental conventional nuclear power plant reactor building 688 showing the construction of an embodiment of a conventional nuclear power plant according to the present invention, and an elemental reactor building Sectional view of fuel rod 688 and detailed side configuration of fuel rod 689,

As shown in FIG. 1 v, in the section of the nuclear power plant reactor building 688 and in the fuel rod 689 facility, the facilities of the nuclear power plant reactor building 688 include reactor building 688A, turbine building 688B, The facility 688 of the nuclear power plant reactor 688 is provided with the building 688C and the auxiliary building 688D and the diesel generator building 688E and the nuclear fuel building 688F and the waste building 688G, The fuel bundle adjustment 689a and the upper nozzle 689b and the fuel rod adjustment 689c and the fuel rod 689d and the spring clip assembly 689e and the lower end nozzle 689f and the fuel rod rear end cap 689g, Plutonium (689h), hold down spring uranium (689i), and dioxid fuel pellets (689j), gas caps (689k) and zircaloy crowding (689l) are used to operate nuclear power plants.

Referring to FIG. 1w, a conventional high-speed multiprocess reactor (838) nuclear power plant according to the present invention includes a nuclear power plant, A lateral side view constituting an elemental side view,

As shown in FIG. 1w, in the structure of the fast breeder reactor facility 838, the high-speed breeder reactor facility 838 includes uranium enriched in about 20% of enriched uranium 235 at the central portion of the fuel rod 689, And plutonium 801 formed from uranium 238 (653a) is contained in the fuel rod 689. The plutonium 801 is taken out and used as the next fuel The coolant 816 does not contain the moderator 676 and the intermediate heat exchanger 657 does not contain the heat generated from the reactor in the intermediate heat exchanger 657 because the liquid metal sodium is used and the neutrons 675 need not be decelerated. Liquid metal sodium, while the heat exchanger 658 converts the water into steam by the heat of the liquid sodium so that the steam turbine 267 rotates to make nuclear power.

Referring to FIG. 1x, an elemental conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of one embodiment formed from a conventional fast breeder nuclear reactor facility 838 nuclear power plant, (838) disassembled lateral strabismus structure,

    Referring to FIG. 1 (a), an elementary conventional fast breeder nuclear reactor 838 nuclear power plant operating at a nuclear power plant, showing the configuration of an embodiment formed from a conventional fast breeder nuclear reactor 838 nuclear power plant according to the present invention, As shown in the side view, an elemental fast breeder reactor facility (838)

       As shown in FIGS. 1x and 1y, the fast breeder reactor facility 838 generates nuclear energy by generating a nuclear fission reaction using a high-speed neutron and produces uranium, which is a non-fissile material that accounts for 99% of natural uranium 238 (653a) to uranium 239 (653), which is a fissionable material, and at the same time, it is a high-speed propagation furnace facility 838, so liquid sodium metal is used as a coolant 816. However, Because the neutron 675 rate is low because the uranium 235 (812) is focused on the fission, the fast reactor reactor 838 has a high neutron 675 velocity.

     It is common for the fast breeder reactor facility 838 to reduce the amount of fissile material, especially when burning the fuel within the reactor facility 838, where the breeder initially produces more plutonium 801 than the amount of plutonium 801 The plutonium 801 is consumed but the uranium is converted into plutonium through the reaction. As a result, plutonium 801 is consumed more plutonium 801 than plutonium 801, (801). However, if 1 g of uranium 238 is used at the same time, it will be propagated as 1.17 g of plutonium 239 in the reactor and used as fuel. If such a liquid metal is put into practical use, However, when the liquid sodium used as the coolant 816 is combined with the water air, The cause has the problem in a practical use very difficult to ensure the handling skills to easily corrode the pipe it stably.

     The Super Phosphorus in France and the Monju Fast Breeder Reactor in Japan to the fast breeder reactor facility 838 were able to continue to use the fuel that had already been used, It is called a "dream reactor" that produces fuel, "the more fuel it gets."

Existing light and heavy water reactors H2O and heavy water D2O are used as a moderator 676 and a coolant 816 in the reactor plant 838 to generate fission by using low energy thermal neutrons. While the sodium-cooled high-speed furnace uses a high-temperature liquid sodium (Na) as a coolant without a moderator 676, thereby providing a fission reaction using a high-speed neutron having a higher energy than that of the light water reactor and the heavy water reactor. Since the cross-sectional area of the neutron (675) is remarkably reduced, a high-concentration fuel is provided in order to generate the necessary amount of fission, and at the same time, the power density is high and the reactor size can be made smaller than that of the light- .

In order to overcome the disadvantages of the sodium coolant, there is a closed 'sodium intermediate system', which is designed to heat the water in the steam generator without direct contact between sodium and water. At the same time, all piping and walls through which sodium flows are double A system in which the sodium of sodium DHX (sodium-sodium heat exchanger), which seals the leak or is warmed by hot sodium, rises up the piping and cools it through an AHX (sodium-air heat exchanger) There is one more important story that is missing, worrying about waste and worrying about safety, more economical, more economical and not meeting the high-speed cooling roads, or if the fast breeder reactor facility (838) is provided, Rather, spent fuel that has been stored in the basement can be taken out and reused.

Hereinafter, the conventional nuclear waste disposal method and the cause of the nuclear explosion accident will be described as follows.

      Referring to FIG. 1Z, a conventional nuclear waste disposal method according to the present invention includes a disposal facility 1030 of a nuclear facility 1029, a nuclear waste disposal method 1040 according to a previous design of a plutonium disposal process 1040 in dismantling a nuclear weapon The construction of the conventional elemental nuclear waste disposal method showing the difference showing the construction,

      As shown in FIG. 1z, in the conventional constitution of the nuclear waste disposal method, uranium used as nuclear fuel for a nuclear power plant is purified by purifying natural uranium so that uranium 235 can be concentrated by 3 to 4% and used as a nuclear weapon Of uranium enriched to 95%. As a result of negotiations to reduce nuclear weapons in the 1990s, many nuclear weapons have been dismantled. However, with the remaining nuclear weapons, humanity has been wiped out several times, We have also made uranium for power generation by mixing an appropriate amount of uranium 235 from nuclear weapons into natural uranium. But these nuclear fuel rods are called MOX, but how does nuclear fission occur in reactors? It begins by striking the nucleus of uranium 235 with a neutron, which when hit with a neutron causes unstable uranium 235 to fission and turn into another stable element.

     In the above-mentioned conventional elementary nuclear waste disposal method, while releasing three neutrons with energy as much as the mass difference, the neutrons hit the other uranium 235 to cause nuclear fission, so that the fission occurs sequentially, (675), and then grasps the neighboring fangs, and then the fellow next to it fissures and squeezes the neutrons (675) to squeeze them beside them .

     The conventional elemental nuclear waste disposal method does not divide uranium 235 into neutrals 675 into a nuclear reactor facility, disintegrate and heat the nuclear reactor 675, and crack neutrons 675 at the same time, At the same time, the Uranium 238 gladly does not know the neutrons (675), accepts the neutrons (675) and turns them into my family, then turns into a plutonium (801), and at the same time keeps neutrons Because it is too hot, the cadmium rod is inserted between the fuel rods to absorb and reduce the neutrons (675), and the boron acid is added to the reactor coolant to slow down and calm the neutrons (675).

      As shown in FIG. 1z, in the constitutional arrangement of the conventional nuclear waste disposal method, the plutonium disposal process 1040 in the dismantling of the nuclear weapon includes the nucleus 1029, the dismantling facility 1030, And a deep underground cave 1038 in the MOX processing 1032 and the MOX combustion furnace 1033 and the mixed glass solid 1034 and the high level waste 1035 and the final repository 1036 and the long term storage 1037, The fuel rods 683a and 683c are provided with fuel rods 683a and 683c in the fuel rods 683 and 683a, The lower end nozzle 683f and the fuel rod rear end cap 683g and the plunger 683h and the hold down spring 683i and the uranium dioxide fuel pellet 683j and the gas cap 683k) and zircaloy crowding (683l) and consists of nuclear waste disposal methods of nuclear fuel (683) There is.

     As shown in FIG. 1 (a), in the conventional method for treating nuclear waste, the difference between an atomic bomb and a nuclear reactor is that the fuel of a nuclear reactor containing a small amount of uranium 235 is less likely to be fissioned by a neutron generated by fission, There is no intense chain reaction like bombs, the atomic bombs explode at once, and the nuclear power plant burns low enriched uranium (812) by letting it burn slowly by regulating the fuel (683) with diluted uranium 235 (812) The fuel filler 683 is a nuclear fuel rod 689 filled with a pellet 683 and a zircaloy pipe 682 which is a cladding tube 682. The fuel rod 689 is formed into a square bundle If the number of neutrons 821 is large due to earthquake and tsunami during operation of the nuclear power plant, the chain reaction will be excessive, If the energy exceeds the danger level and the nuclear fission chain reaction proceeds in an idealized state, then many nuclear reactors will explode like atomic bombs, (683) is a key cause of the explosion.

As shown in FIG. 1Z, in the conventional nuclear waste disposal method of the related art, a plurality of existing nuclear reactors include a dust collector 794 of an exhaust gas (171) facility and an exhaust gas 171, In view of the lack of exit and entrance, the explosion of Fukushima Dai-ichi Nuclear Power Plant, caused by a failure of the cooling system caused by the tsunami on March 13, 2011, is a reactor that can not accommodate the high temperature and high pressure inflation and expansion liquid inside the reactor. As a direct cause of the accident, the water, which is the inflating liquid of high temperature and high pressure after the failure of the cooling system, turns into steam, and the steam of high temperature and high pressure is combined with the high temperature high pressure inflation gas at the moment of chemical decomposition of oxygen and hydrogen. At the same time, an electronic flame generated by air friction due to an earthquake is generated, so that its electron flame is ignited by high temperature and high pressure oxygen and hydrogen, The secondary explosion after a primary explosion outside the on-pressure vessel and inside the nuclear reactor building is caused by the explosion of the reactor in the core of the nuclear fuel vessel inside the pressure vessel, causing the explosion of a nuclear explosive It is recognized as a key cause of the nuclear explosion of the first nuclear reactor, recognizing that it has an abrupt chain explosive shape.

As shown in FIG. 1 (a), the above-mentioned conventional elementary nuclear waste disposal method includes a nuclear disaster of a conventional nuclear submarine and a nuclear-powered aircraft carrier, and an explosion of a reactor engine until now, (688), which is the fifth protection wall made of concrete, among the ones equipped with a plurality of nuclear reactor facilities installed inside the body of the hull deck deck of the barge, because it can carry out the construction Since the barge hull 591 itself formed of the double structure block tanks 598 itself corresponds to the fifth protection wall, the reactor building 688 formed of concrete in the past has the reinforcing concrete mat 225 generated at the time of explosion of the reactor, Waste ([<<<, >>>], 224) is a cause of environmental pollution by turning into detonated explosives combined, There deulsu that you meet the hellish chain of explosions explosives shaped like the reactors in operation in the transition to a hydrogen bomb atomic bomb reason, be recognized as a key cause of the explosion of the first nuclear reactor.

As shown in FIG. 1Z, in the conventional method for treating nuclear waste, the conventional nuclear reactors of various types have been equipped with a dust collector and an exhaust gas outlet of an exhaust gas facility, The explosion accident at the Fukushima Dai-ichi Nuclear Power Plant caused by the failure of the cooling system caused by the tsunami on March 13 is a reactor that can not cope with the high-temperature high-pressure inflation gas and the expansion liquid inside the reactor. After the failure of the cooling system, the water, which is the inflating liquid of high temperature and high pressure, turns into steam, and the steam of high temperature and high pressure is combined with the inflation gas of high temperature and high pressure at the moment of chemical decomposition of oxygen and hydrogen, The electronic flame is ignited by oxygen and hydrogen at high temperature and high pressure to cause hydrogen explosion, The secondary explosion after the primary explosion on the outside of the vessel and inside the nuclear reactor building is due to the nuclear explosion in the core of the fuel vessel inside the pressure vessel, In the present invention, in contrast to the conventional nuclear reactors, the double-structure block tank reinforced with the concept of defense in depth, the nuclear power plant of the nuclear and hydroelectric power plants of the offshore and offshore, Nuclear Radiation Leakage Control of Nuclear Reactor Facilities of Waste Treatment Shielding Unit Double structure block tank Double pipe structure piping using energy of water composed of distributing device of dust collector and equipped with safety pressure valve and water pumps as temperature pressure sensor, By selecting the method of automatically injecting the mixture of yellow loess that generates soap bubbles, And the nuclear waste shielding method of the dispensing device of the apparatus for controlling fuel and fuel explosion.

Referring to FIG. 2, a nuclear reactor power plant having a dual structure block tank reactor for nuclear waste treatment according to the present invention is provided with a power generation facility connection structure equivalent to the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 The thermal power plant 626 of the conventional thermal power plant 626 showing the essential constitution of an embodiment formed by the thermal power generation operation of the conventional thermal power plant 626 has the operation mode of operation of the thermal power generator 772 of the thermal power plant 626, Thermal power generator (772) Operation method Elementary side profile Straight configuration Road,

As shown in FIG. 2, the thermal power generator 772 of the conventional thermal power plant 626, which shows the essential constitution of an embodiment formed by the thermal power generation operation of the thermal power plant 626, The conventional operation method of the thermal power generator 772 of the thermal power plant 626 shown in FIG. 7 is similar to that of the conventional nuclear power plant of the world-wide nuclear power plant in that the boiler and the reactor of the thermal power plant are technically differentiated, In order to understand the structure of nuclear power, it is necessary to understand the structure of the boiler (778) and the melting furnace (783) to dissolve the metal. In order to understand the structure of nuclear power generation, (1) of a nuclear power plant having a structural block tank dust collector to control the operation of the nuclear power plant of the nuclear power generation facility (811) It handles all the tasks of a central control station (781) is equivalent to the computer.

On the other hand, coal-fired power plants are constructed on coastal areas or coasts where there is usually a large demand for electric power, and due to the exhaust gas emitted from the stack, the order of the ecosystem is broken, and dusts such as soot, The natural disaster has reached a serious level due to the global warming phenomenon due to the increase of the discharge, etc. The countermeasure against this is that the inventor of the present invention installs a seesaw-type wind turbine hydropower generator of the nuclear- , Which is a means of solving human anxieties with endless production of environmentally friendly energy.

The thermal power generation unit of the post-thermal power plant 626 before the failure recovery of the nuclear power generation facility 811 into the reactor main body 1 of the conventional nuclear power plant includes the above- The thermal power generation apparatus of the nuclear power plant includes a steam turbine 267 which generates steam by burning fuel in the boiler so as to produce steam by the heat to rotate the steam turbine 267 to produce power, A rotating rotor electromagnet coil 774 for the thermal power generator installed along the circumference of the rotating shaft 198 connecting the steam turbine 267 and the thermal power generator 772, A non-rotating armature coil 773 for a thermal power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for the thermal power generator, and a non-rotating armature coil 773 mounted on the steam turbine 267, It is formed to be made to develop seolbibu 811 when after any reactor plant safety operation i and reactor equipment failure recovery before and after the thermal power during which includes a frame 775 for fixing the rotary shaft 198 integrally.

Referring to FIG. 2A, a conventional high-speed breeder reactor facility 838 of the nuclear power plant 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (838) Elementary fast breeder reactors facility (838) showing disassembled side view of nuclear operation of nuclear power plants Nuclear reactor construction (838) Disassembled lateral strainer configuration Road ,

As shown in FIG. 2A, the fast propagating furnace reactor facility 838 generates uranium 238 (653a), which is a non-fissile material that generates energy by generating a fission reaction using a high-speed neutron and occupies 99% ) Is converted to a fissile material, uranium 239 (653), and at the same time, the liquid fuel metal 838 is used as a coolant 816 because it is a high-speed propagation furnace facility 838. However, 812), the speed of the neutron 675 is high in the reactor plant 838 of the fast breeder reactor, while the speed of the neutron generator 675 is low.

Referring to FIG. 2B, in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, a nuclear power plant 811, A nuclear waste disposal system is provided to provide a nuclear waste disposal system to restore the nuclear power plant. A nuclear waste disposal system is used to operate a nuclear power plant. A nuclear waste disposal system A side view of the apparatus, a nuclear waste disposal apparatus for operation of nuclear power plants of a conventional nuclear power plant,

As shown in FIG. 2B, in the conventional method of treating nuclear waste generated from a nuclear power plant for nuclear power plant nuclear power plant operation of a nuclear power plant, ventilation inside the building and air contained in water inside the reactor In the case of a gas, purified air is exhausted to the outside by an activated film type gas hold-up device 213 which weakens the radioactivity when the pressurized water reactor system is operated. However, ventilation of the power plant is performed by a plurality of symmetrical filters 214 And discharges all of the ventilated air from the exhaust tower 215 to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

In addition, when the inside of the nuclear power plant is solid and the paper, cloth, work clothes, shoes, and so on are solid in the inside of the nuclear power plant 672, the filter sludge and the used resin liquid are stored in the storage tank 216, and then filled in the drum 220. The paper and the cloth are compressed to reduce the volume and attenuate them. All of them are filled with concrete into the drum 220, and the nuclear waste 224 to move the nuclear waste storage building 332 and monitoring monitoring post 219 to a nuclear waste disposal facility, To prevent radioactive contamination.

When the regenerated liquid of the ion exchange resin is liquid in the water leaking from the valve of the nuclear power plant 672 and the water in the building into the nuclear power plant 672, the washing water is collected in the storage tank 216 and filtered with the filter 217 After measuring the radiation level by the radioactivity measuring device 218, it is confirmed that there is no harm, and then it is sent to the sea together with the seawater for cooling. The water other than the washing water is purified by the filter 217, and the filtered water, distilled water, And is provided with monitoring posts 219 for monitoring at the same time to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2C, in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a nuclear power plant 811, Nuclear power plants operating nuclear reactors providing nuclear waste disposal facilities to provide for post-war reconstruction Deep safety Nuclear power plant 5 Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant , Nuclear power plant operation of elemental conventional nuclear power plant shown in cross section in-depth safety Fifth barrier side lateral diagonal construction road,

     As shown in FIG. 2C, the control rod 798 is inserted into the fuel assembly 671 from the pressure vessel 813 in the fifth-level safety barrier for operating the nuclear power plant of the conventional nuclear power plant, At the same time, the fuel assemblies 671 are adjusted to the height of the fuel assemblies 671 at the height of the nuclear reactor facility, and at the same time, the fuel assemblies 671 are used to stabilize the pellets 683 The nuclear fuel pellet 683 is enclosed in the covering material 681 as the second barrier wall and is put into the metal tube of the special alloy as the fuel rod 689 as the fuel rod 689. [ At the same time, in the reactor pressure vessel 813, which is the third barrier wall, a small amount of gas discharged from the nuclear fuel assembly 671 provides a seal to the second barrier wall, Is a facility pressure vessel 813.

     In the shielded concrete wall as the fourth barrier wall, the radioactive material is prevented from leaking as a concrete wall surrounding the nuclear reactor facility. In the containment vessel 808 as the fifth barrier wall, a safety system and a system At the same time, the facilities of the biological shielding wall, which is the 5-1 barrier wall, are provided with a final biological shielding wall as a thick building of 70 to 100 cm outside the steel, , And at the same time a containment vessel (808) and a dome-shaped, secure nuclear building that provides protection against leakage of radioactive material, while at the same time providing emergency shutdown of radioactive material in the event of an accident.

However, since the conventional nuclear reactor power plant is constructed so that the deep-safety nuclear reactor facility can not cope with a stronger earthquake than 5, it is urgently necessary to take measures against it.

Referring to FIG. 2d, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, Nuclear Power Plant Operation Having the Evaporator Structure 1005 of the Steam Generator, the Steam Generator 810, and the Intermediate Heat Exchanger 657 During the operation of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment, The steam generator 810 and the intermediate heat exchanger 657 are separated from each other in a side view in section, and the steam generator 810 and the intermediate heat exchanger 657 of the steam generator are connected to each other. The evaporator structure 1005 of the generator, the steam generator 810 and the intermediate heat exchanger 657,

As shown in FIG. 2D, the facility structure of the nuclear reactor nuclear power plant 811 of the nuclear power plant, the vapor generator structure 1005 of the steam generator, the steam generator 810, and the intermediate heat exchanger 657 is first subjected to intermediate heat exchange The apparatus 657 includes a secondary cooling system outlet 657a, a low temperature head 657b, a secondary cooling material inlet 657c, a support plate 657d, a central pipe 657e, an outer annular portion 657f, And the heat insulating material 657h and the high temperature head 657i and the mixer 657j and the primary system gas inlet 657k and the primary system gas outlet 657l and the single pipe 657m pressure vessel 657n, 657o, 657p, 657p, 657r, 657r, 657s, 657t, 657u, 657v, and 657w, respectively, The steam generator 810 is provided with a steam outlet 810a and a water supply nozzle 810b and a secondary cooling water 810c and a vibration suppression rod 810d ) customs A tubular shell 810f and a tubular shell 810g and a tubular steel plate 810h and a separating steel plate 810i and a primary outlet 810j and a primary inlet 810k and a heat exchange tubular 8101, And the steam generator internal tubular body 810o and the evaporator structure 1005 of the steam generator are provided with the steam outlet pipe 1006 and the steam outlet body external appearance A connection pipe 1013 and a cooling water leakage detecting pipe 1014 and a hygrometer pipe 1008, a steam outlet pipe 1009, a liquid level pipe 1010, a sodium cooling water inlet pipe 1011, an upper plate 1012, A secondary argon gas pipe 1015, a skirt 1016, a spiral heat exchanger tube 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a water drain pipe 1020 and a cover 1021, Water reaction product discharge pipe 1024 and an inner pipe 1025 and a monitoring inlet pipe 1026 and a water inlet pipe plate 1027 and a water inlet pipe 1010, 28) and a water supply inlet chamber (1028a) connection structure to prevent nuclear radiation pollution both inside and outside the nuclear power plant.

Referring to FIG. 2E, the boiling water reactor unit 802 of the nuclear power plant 811 and the pressurized water reactor 802 of the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, Type nuclear reactor (803) Nuclear power generation facility (811) is installed inside a nuclear reactor main body (1) of a conventional nuclear power plant shown in a cross section of a conventional nuclear power plant showing an essential constitution of an embodiment formed by operation of a nuclear power plant ) Of the boiler water reactor (802) and the pressurized water reactor (803) of the nuclear power plant,

     As shown in FIG. 2E, the operation of the boiling water nuclear reactor 802 is a boiling water reactor (BWR) type in which water vapor of water boiling in the core is directly sent to a power generation turbine, There is half water vapor in the water, which is half format.

     The deceleration of the neutrons 675 of the nuclear reactor reactor 802 of the boiling water reactor equipment 802 is a moderator 676 and boric acid H3BO3 is a pretext for suppressing the fission 791b by grabbing the neutrons 675 of the fuel rods 689 And natural nuclear installations have provided 15 discoveries that have operated for thousands of years with non-authentic reactors and naturally-made reactor installations, and it is difficult to extend the life of uranium 235 (812) due to depletion, At the same time, it evaporates all the water and fails to produce thermal neutrons, thus ceasing its activity and preventing melting of the core (791).

However, the Fukushima nuclear plant operated by the nuclear reactor of the boiling water reactor (802) failed to operate such a safety facility in this situation. Tokyo Electric Power officials and bureaucrats hid their details without disclosing details, refused to provide US technical support, and at the same time, they poured seawater into a wreckage, drove a fire engine and used a helicopter to put it into the building, In the reactor (PWR, 803) facility, there is provided a primary system transfer that circulates between the fuel and the heat exchanger 658, and at the same time, a heat system, called the hot system steam generator 810 of the primary system, , As a result of which the steam provides turbine generator rotation and nuclear power provides power for propulsion, whereas the nuclear power plant provides the electricity supply generated, while at the same time the secondary system is connected to the condenser The turbine 267 of the secondary system is connected to the turbine generator 772 to generate electric power at the same time. (PWR, 803) facilities are compared with two pressurized water reactors and other reactors. In the pressurized water reactor, there are two cooling water 1 In the boiling water reactor (BWR), the turbine (267) of the secondary system and the secondary system provides electric power production in connection with the turbine generator (772), while at the same time water none.

In the pressurized water reactor type nuclear reactor (803) nuclear power plant, in the pressurized water reactor type nuclear reactor facility (803), the hard water of the coolant is designed for the primary use in the PWR, , And 315 degrees Celsius. At the same time, the primary flow pressure is usually 2000 psig and 15 MPa, and the light pressure (654a) at a pressure of 150 times the pressure does not boil. At the same time, The water is steamed at a temperature of 275 degrees Celsius and a pressure of 900 psig and a pressure of about 6.2 MPa, and is sent to the steam turbine 267.

     The stability of such a pressurized water reactor type reactor (803) is such that a pressurized water reactor is provided with a very stable production. However, when the graphite deceleration boiling water pressure tubular reactor (RBMK) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, the heat and sintering of the phenomenon to be used are provided, and at the same time, the production of ceramic pellets made of uranium dioxide is provided, and the pellets made of such a cylinder are made into a zirconium alloy Zirconia), and helium is injected into the zirconia bar to help heat transfer, but the finished fuel rod is bundled with bundles of fuel assemblies, which are called bundle bundles of fuel, which are loaded into the reactor core do.

Referring to FIG. 2F, a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant (1) (1) of a conventional nuclear power plant showing the operation method of a nuclear power plant of a conventional nuclear power plant, showing the configuration of the nuclear power plant of the nuclear power plant (811)

As shown in FIG. 2F, the nuclear plant power plant of the nuclear power plant 811 includes a safety valve 472, a for-spiff safety valve 475 for steam, an air vent valve 481, The reactor pressure vessel 813 is connected to the pressure vessel container 813a and the pressure vessel 813a by the air air exhaust valve 482 and the nichrome wire 659 and the steam generator 810, A pressure vessel cylindrical top end portion 813d and a pressure vessel cylindrical top end portion 813e, an inlet nozzle 813f and a deflector steel plate 813h, which form a position in the top cover lower portion 813b and the pressure vessel cylindrical cover 813c, A pressure vessel cylindrical top cover for providing a position in the air chamber chamber 813i, the baffle plate 813j, the water 813k, the spray pool 8131, the vent five 813m and the fuel assembly 813n, (813p) is provided with a dry wall (813q), a pressure vessel cylindrical cover bottom assembly (813s) and a pressure vessel cylindrical cover top And a connection structure of the control rod guide tube assembly 813z of the reactor core assembly 813y and the outlet nozzle 813w and the core assembly 813y of the nuclear fuel assembly 811t, the fuel rod steel plate 813v, It is structured to prevent nuclear radiation pollution both inside and outside of the operation equipment.

      Referring to FIG. 2G, the nuclear power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention includes the nuclear power generation facility 811 intermediate heat exchanger 657, The structure of a nuclear power plant having a structure 1005 and a steam generator 810 is shown in a schematic view of an elemental conventional nuclear power plant operating at the nuclear power plant 811 and an intermediate heat exchanger 657 and a steam generator The structure of the evaporator 1005 and the steam generator 810 are shown in side elevation and in cross section in the nuclear reactor of the conventional nuclear power plant and the evaporator structure of the steam generator in the nuclear power plant 811 intermediate heat exchanger 657 1005) and the steam generator (810)

As shown in FIG. 2G, the inside of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the nuclear power generation facility 811 intermediate heat exchanger 657 and the vapor generator structure of the steam generator 1005 and the steam generator 810, the structure of the intermediate heat exchanger 657 includes a secondary cooling system outlet 657a, a low temperature head 657b and a secondary cooling system inlet 657c and a support 657d and a central piping 657e and an outer annular portion 657f and a pressure vessel 657g and a heat insulating material 657h and a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k ), A primary system gas outlet (657l), a single pipe (657m), an internal pressure pipe (657n), a heat insulating layer (657o), a high temperature gas passage (657p), a liner (657q), a double pipe (657r) A gas pipe 657t and an inner pipe 657u and a hot gas passage 657v and a liner 657w and a heat insulating layer 657x. A tubular lid 810a connected to the turbine generator, a water supply nozzle 810b, a secondary cooling water 810c and a vibration damping rod 810d, a tubular supporting pipe 810e, a tubular lid 810f, a tubule bundle 810g, And the steam generator 810n and the steam generator internal fuselage 810i and the steam generator internal pipe 810i and the steam generator internal pipe 810i, the primary pipe outlet 810j, the primary pipe inlet 810k, the heat exchange pipe 8101, the cooling water passage 810m, The steam outlet pipe 1006 and the steam outlet body 1007 are connected to the hygrometer pipe 1008 and the steam outlet pipe 1009 and the liquid level sensor A cooling water leakage detection pipe 1014, a secondary argon gas pipe 1015, a skirt 1016, and a spiral heat exchange tubular pipe 1010, a sodium cooling system inlet pipe 1011, an upper flat plate 1012, a connecting rod 1013, 1017, a sodium coolant outlet pipe 1018, a hemispherical lower body 1019, a drain water pipe 1020, a cover body 1021, a body outer pipe 1022, a sodium channel 1023, and a sodium- A water inlet pipe plate 1027, a water inlet pipe 1028, and a water inlet chamber external pipe 1028a connecting structures to the inside of the nuclear power plant 1024, the inner pipe 1025, the monitoring inlet pipe 1026, the water inlet pipe plate 1027, (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste of a nuclear power plant, and a nuclear power plant (811) intermediate heat exchanger (657) and an evaporator of a steam generator The construction of the structure 1005 and the steam generator 810 can be configured to prevent nuclear radiation pollution both inside and outside the nuclear power plant operating the nuclear power plant.

Referring to FIG. 2H, a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention includes a nuclear power plant The nuclear power plant of the conventional nuclear power plant showing the configuration of the embodiment of the nuclear power plant in operation of the nuclear power plant, the nuclear power plant of the conventional nuclear power plant showing the side view of the steam generator 810 of the nuclear power generation facility 811, (811) Steam Generator (810) Side Construction Road,

The steam generator 810 of the nuclear power plant 811 includes a steam outlet 810a connected to the turbine generator and a steam generator 810a connected to the turbine generator 810, The tubular lid 810f, the tubular bundle 810g, the tubular steel plate 810h and the separated steel plate 810i, the water supply nozzle 810b, the secondary cooling water 810c, the vibration suppression bar 810d, A primary side inlet 810k, a heat exchange tubular 810l, a cooling water flow channel 810m, a steam generator tubular tube 810n and a steam generator internal body 810o, The safety valve 474 and the intermediate heat exchanger 657 are structured such that the secondary cooling system outlet 657a, the low temperature head 657b, the secondary cooling material inlet 657c, the support plate 657d and the central pipe 657e, A heat exchanger 657h, a heat insulating material 657h, a high temperature head 657i and a mixer 657j and a primary system gas inlet 657k and a primary system gas outlet 657l, (657m), a pressure insulation pipe (657n), a heat insulation layer (657o), a high temperature gas pipe (657p), a liner (657q), a double pipe (657r), a pressure pipe (657s), a low temperature gas pipe (657t) (657v), a liner (657w), a heat insulating layer (657x), and a reheater (793), and at the same time, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste 1) Nuclear power plant (811) inside Nuclear power plant (811) Nuclear power plant with intermediate heat exchanger (657) and connecting structure of steam generator evaporator structure (1005) and steam generator (810) As shown in FIG.

Referring to FIG. 2I, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention (1) Nuclear waste treatment is performed inside the production power central control room (781) Operation of a Nuclear Power Plant Having a Cutter and a Robot 912 by Remote Control of the Apparatus In an elemental conventional nuclear power plant showing the construction of a nuclear power plant during operation of the nuclear power plant, (912) of the nuclear waste disposal apparatus remote control nuclear power plant nuclear waste disposal method of the nuclear power plant nuclear waste disposal method of the elemental conventional nuclear power plant operating nuclear power plant nuclear power generation facility 811) Production power Central control room (781) Inside Nuclear waste processing device Remote control Cutting machine and robot (912) Nuclear power plant Nuclear waste disposal side In addition,

As shown in FIG. 2 (i), the piping line of the nuclear reactor facility is connected to the safety valve 472 in preparation for a period of three months or longer for the repair work of the inside of the reactor facility of the nuclear power plant 672, The boiler 783 of the thermal power plant is operated at the same time, and the connection structure is formed in the reactor power generation facility 811 to supply the steam of high temperature and high pressure and further emergency power generation operation is performed. In order to secure the safety of the nuclear power plant by safe and continuous operation of the nuclear power plant inside the nuclear power plant by replacing the electric power supply with the thermal power generation facility during the work period and to prevent the radioactive contamination during the renovation of the reactor facility, At the same time, during the operation of nuclear power plants, the production power central control room 78 of the nuclear power generation facility 811 1) Nuclear power plant nuclear power plant equipped with cutter and robot (912) device by remote control of nuclear waste treatment device inside It is provided with nuclear waste disposal method to guarantee the repair of nuclear reactor.

Referring to FIG. 2J, there is shown a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The reactor core 1 includes a nuclear power plant 1071 having a nuclear fuel industry cycle 1077 of the nuclear power generation facility 811, The nuclear fuel cycle of the nuclear power plant 811 in the operation of the nuclear power plant of the conventional nuclear power plant showing the configuration of the nuclear power plant of the power plant is shown in a side view and a cross-sectional view Nuclear Power Plant (811) Nuclear Fuel Industry Cycle (1077) Nuclear Fuel Transfer Process and Revision of Revision Scene Disassembly of the Scene Scenery Construction of roads,

As shown in FIG. 2J, the nuclear fuel cycle 1077 of the nuclear power plant 811 is transferred into the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment The spent nuclear fuel 683 consumed in the nuclear power plant 672 and the remaining uranium 812 are processed in the reprocessing plant 228 and then converted into uranium fluoride 812 in the conversion plant 229 to be concentrated in the concentrating plant 230 to convert the uranium fluoride 812 to uranium dioxide at the conversion plant 229 and process it into pellets 683 to form the fuel rods 689 and process them in the reprocessing plant Plutonium 801 is produced at the conversion and processing plant 231 and fuel rods 689 are produced so that these reprocessed fuel rods 689 are moved back to the nuclear power plant 672 and the fuel 683 is transferred to the nuclear power plant 672 The concentrating plant 230 in the reprocessing plant 228, The conversion plant 229 and the conversion processing plant 231 prepare nuclear waste 224 as a nuclear fuel cycle of the nuclear fuel industry on the top surface of the sinking prevention type barge deck 40 m above the sea surface of the ocean, 672) The nuclear fuel cycle of the Edo nuclear fuel industry is constructed so as to prevent nuclear radiation contamination both inside and outside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment.

In addition, the long half-life nuclear waste 224 generated from the reprocessing process at the nuclear power plant 672 inside the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste has a half- Heavy construction equipment heavy equipment hire (877) and excavators (845), which provide shelter for thousands of years because of their long shelf life, while at the same time providing for the permanent disposal of long-term waste, Comprising the steps of constructing the waste to be treated with a device of a permanent disposal method of a long-term nuclear waste,

The nuclear waste treatment includes the steps of fissioning in the nuclear reactor facility to construct a conversion into another material,

The nuclear waste disposal includes the step of constructing a deep burial site by having a construction machinery heavy equipment hoeing 877 and an excavator 845 in a stratum or ocean,

The nuclear waste disposal includes the steps of constructing a double tubular drum (220) having a sinking prevention vessel and containing nuclear waste to be transported to a buried area,

In the nuclear waste disposal, a dual tubular drum 220 containing nuclear waste is mounted on the space rocket 612 at the position of the upper end of the barge deck deck 591 provided with the space rocket 612 and the space rocket launching rods 646 (224) containing nuclear waste (224) comprising steps constituting transmission to the outer space of a nuclear power plant having a dual structure block tank dust collector for the treatment of nuclear waste (1) To make the treatment of the nuclear waste with the devices of the permanent disposal method of the nuclear waste.

Referring to Figure 2K, there is shown a structural and engine side view of an elemental configuration of an embodiment of a nuclear power station of a TVA Paradise Power Plant Steam Turbine Generator in the vicinity of the prior art Paradise in Kentucky, Generator and engine side Elementary strap configuration Road,

As shown in FIG. 2K, the following is a detailed description of the energy conversion of the translation of the contents of the American Science Series of the energy and power of the modern science in the late 1960's.

TVA's Paradise Power Plant Steam Turbine Generator in the vicinity of Paradise, Kentucky, has a capacity of 1,150 MW. When it first started operation in February 1970, it was the largest power plant in the world. The turbine, which is produced by General Electric Company, first enters the high-pressure turbine under the right-angled pipe on the left, and flows through the rectangular pipe in turn to the intermediate-pressure turbine (the rear lid) and the low-pressure turbine (the front lid). The high pressure turbine is connected to one generator (gray box on the left) and the other two turbines are connected to a second generator (front box) with the same capacity. The entire plant is run by 3.6 million kg of water vapor per hour, which enters the high pressure turbine at a pressure of 1,650 kg per square inch and 427 ° C. The coal consumption per day is 10,572 tons, enough to fill 210 coal cargoes. The net heat efficiency of this facility is 39.3%. Two small turbine generators, each with 704 MW, are visible at the rear.

<Efficiency of household stoves, steam turbines, automobile engines and bulbs helps to determine energy demand. What is primarily needed is a kind of energy source that does not increase the earth's heat load.>

Modern industrial societies can be seen as a complex machine that emits the energy necessary to create numerous goods and services, while at the same time, the high quality energy is reduced to waste heat. Last year, the United States achieved a gross national product of just over $ 1,000 trillion using 69 × 10 ¹⁵ Btu, of which fossil fuels accounted for 95.9 percent of the energy, 3.8 percent of water falls, and 0.3 percent of the U ²³⁵ split Respectively. The consumption of 340 million Btu per person is equivalent to the energy contained in about 13 tons of coal, or 2,700 grams of gasoline if followed recently by the most frequently used method. It can be estimated that in 1900-70, the efficiency of the spent fuel for all purposes was improved by a factor of four. Without this efficiency improvement, the US economy in 1971 would already be consuming as much energy as it would have expected in 2025 or at that time.

GNP could be increased at an annual rate of 3.25% while fuel consumption increased only 2.7% per year in 1890-1960, as the efficiency of converting energy into useful heat, light, and work continued to improve. However, it seems that this favorable phenomenon is no longer persistent. Since 1967, the annual increase in fuel consumption has been faster than GNP growth, making fuel economy more difficult to improve and new products and services requiring more energy input and costs than in the past. Given the expected increase in fuel use for power generation, it is clear that a significant portion of the fuel to be consumed in the 1980s and 1990s will be transformed into a useful form with a lower efficiency than today's fossil fuels. This is because current nuclear power plants convert only about 30% of the fuel's energy into electricity, compared to about 40% efficiency of the most efficient fossil fuel power plants.

It is understandable that engineers try to improve the efficiency of converting the energy of a fuel into another more useful form. Improving efficiency in industry means reduction of production cost, lowering price for consumers, and reducing pollution of air and water quality to all people. Electric utilities have long known that it can stimulate consumption by lowering the price of energy for many users. The recent campaign by the utility, <1W Save>, represents a significant reversal of corporate philosophy. The difficulty of selecting a suitable new power plant site not only indicates the need for efficiency of consumption, but also the saving of consumption. In addition, we can not but emphasize that even with this much improvement in efficiency, we can expect only a slight effect in extending the life of fossil fuels and fuel supplies. I would like to elaborate on this point from the back of this article.

<Figure 8-1> The transformation path connects many familiar forms of energy. The four black markings are important energy sources of today, and potentially important energy sources for solar energy. The dashed lines represent unusual, accidental, or theoretically useful transformations. The white line represents the fate of intermediate form energy. Most of the energy is converted into mechanical energy, except for the thermal energy used for heating. Mechanical energy is used for direct traffic (see Figure 8-2) or used for power generation. And electrical energy is used for lighting, heating and mechanical work. As a secondary form, chemical energy can be found in batteries and chargers. Most of the radiant energy produced by the bulb is lost as heat.>

Figure 8-2 shows the path to the final destination for the three major energy sources. The most direct and most efficient conversion is from falling water to mechanical energy, which is then converted back to electrical energy. Energy trapped in fossil fuels and nuclear fuel is first released in the form of heat energy, then converted to mechanical energy, and then converted to electrical energy if desired. Losses in conversion and transmission include the use of various non-energy sources of fossil fuels, such as the use of fossil fuels for the production of lubricants or the conversion of coal to coke. However, the greatest loss is due to power generation with an average efficiency of 32.5%.

The efficiency of converting the energy contained in a fuel into a useful form varies depending on the conversion method and the desired end use. When burning wood or coal in an open fireplace, less than 20% of that energy is emitted into the room. All the rest are lost to the chimney. On the other hand, a well designed home stove can capture 75% of the energy of the fuel and use it for heating. The average efficiency of fossil fuel conversion for heating is now 50-55%, which is three times higher than that of today. In 1900, more than half of all the fuel consumed in the United States was spent on heating, but today less than one third of it is spent on it.

Sadi Carnot, 1796-1832)는 1824년 증기터빈이나 다른 열기관의 이론적 최대효율을 계산하는 방법을 발표하였다. 가능한 최대효율은 (T ₁-T ₂)/T ₁로써 표현되는데 여기서 T ₁은 열기관으로 들어가는 작용액체의 절대온도이며, T ₂는 기관 밖으로 나오는 액체의 온도이다. 이들의 온도는 보통 켈빈 도수(degrees Kelvin)로 표현되는데, 이 온도는 섭씨온도에 절대냉도와 섭씨 0°와의 차이인 273을 더한 것이다. 현대의 증기터빈에서 T ₁은 전형적인 811°K(=573.7℃)이며 T ₂는 311°K(=37.8℃)이다. 따라서 (까르노)의 식에 의하면 이 열기관의 이론적 최고효율은 약 60％이다. 그러나 수증기의 순환 자체가 가진 성질로 인하여 항상 이러한 상한 온도로 유지할 수 없기 때문에 이론적 최고효율은 60％가 아니라 53％일 가능성이 더 크다. 현대의 증기터빈은 이 값의 약 89％, 즉 순 47％ 정도를 달성하고 있다.The most significant improvement in fuel conversion efficiency for this century was achieved by the power generation business. In 1900, less than 5% of the fuel's energy had been converted to electricity. Today, the average efficiency is around 33%. This increase was mainly due to the increase in the temperature of the steam entering the turbine that drives the generator and the construction of larger-scale power plants. In 1910, the typical incident water vapor temperature was 260 ° C, but today the facility uses steam heated at a high temperature of 574 ° C (Nicolas Carnot; Nicolas

Sadi Carnot, 1796-1832) published a method to calculate the theoretical maximum efficiency of a steam turbine or other heat engine in 1824. The maximum possible efficiency is expressed as ( T ₁ - T ₂ ) / T ₁ where T ₁ is the absolute temperature of the working liquid entering the heat engine and T ₂ is the temperature of the liquid exiting the engine. Their temperature is usually expressed in degrees Kelvin, which is the difference between absolute cold and 0 ° C, plus 273 degrees Celsius. In modern steam turbines, T ₁ is typically 811 ° K (= 573.7 ° C) and T ₂ is 311 ° K (= 37.8 ° C). Therefore, according to (Carnot) equation, the theoretical maximum efficiency of the heat pump is about 60%. However, due to the nature of the water vapor circulation itself, it is not always possible to maintain this upper limit temperature, so the theoretical maximum efficiency is more likely to be 53% than 60%. Modern steam turbines achieve about 89% of this value, or about 47%.

To determine the overall efficiency of a steam turbine plant, this value should be multiplied by the efficiency of the other energy converters in the chain from fuel to power. Modern boilers convert about 88% of the chemical energy of the fuel into heat. The generator can convert up to 99% of the mechanical energy produced by the steam turbine into electricity. Thus, this overall efficiency is 88 × 47 (efficiency of the turbine) × 99, ie about 41%.

(See also Lord Kelvin, William Thomson, 1824-1907)

[Figure 8-3] Energy converter efficiency is from less than 5% of normal incandescent lamps to 99% of large generators. The efficiency shown here is an alternative maximum value that can be reached with current technology. A figure of 47% of the kit with liquid fuel was calculated for the liquefied hydrogen engine used in the Salton lunar spacecraft. The efficiency of fluorescent lamps and incandescent lamps is not a theoretical value of 220 lumens per V of fully flat white light, but is assumed to be about 400 lumens per W for the maximum efficiency that white light that can be tolerated can reach.

Nuclear power plants are less efficient because their current reactors can not be as hot as boilers burning fossil fuels. The temperature produced by the water boiling reactor is around 350 ° C, which means that T ₁ is 623 ° K in the Karno equation. In a complete cycle from fuel to power, the efficiency of a nuclear power plant is reduced to about 30%. This means that about 70% of the energy of the fuel used by the nuclear power plant is waste heat, which is discharged to the surrounding atmosphere when using adjacent water bodies or cooling towers. In fossil fuel power plants, this waste of heat amounts to about 60% of the energy of the fuel.

However, the actual waste heat load on water or air is much higher than the figure of 60% or 70%. For power plants with the same kilowatt output, nuclear power plants generate about 50% more waste heat than fossil fuel power plants. The reason is that a nuclear power plant must burn about one-third more fuel than a fossil fuel plant to produce 1 kW / h of power, and many more B.t.u. And 70% of the input is wasted.

Of course, there is no thermodynamic rule that heat emitted by nuclear power plants or fossil fuel power plants must be wasted. The problem is to find useful things that can be done by this much amount of low energy. Many applications have been proposed, but all of them are facing economic constraints. For example, low pressure water vapor emitted from a steam turbine can be used for heating. In some communities, especially in New York City, New York (Consolidated Edison, Inc.) supplies a lot of water vapor. Many chemical plants and refineries use low-pressure steam from turbines as water vapor for the treatment process.

[Figure 8-4] Three of the fastest growing energy consumption appliances are electrical appliances, automobiles, and aircraft. These three now consume about 40% of all energy consumed in the United States. By 1940, they were much smaller than now, accounting for 18% of total energy consumption. Fuel demand for aircraft has more than tripled in ten years.

There was also a suggestion that heated water released from the power plant would help promote fish and shellfish growth in some areas. But nationwide, waste heat from current fossil fuel power plants or waste heat from dozens of new nuclear power plants in the near future seems to have no attractive use. The problem is to limit the harmful effects of this waste heat on the environment.

In the discussion above, it can be seen that the use of electric power for home heating (which is still actively recommended by some electric companies) is an inefficient use of chemical fuels. Domestic luxury oil stoves and gas stoves typically exhibit at least twice the efficiency of power plants. In some regions, however, despite the low efficiency at the annual price of electric heating, it is likely to compete with direct heating by fossil fuels. In such anomalous cases, various factors are involved. The higher the temperature, the lower the consumption. Electric heating is usually installed in a new building with good thermal insulation. In some areas, finding natural gas is a bit difficult and expensive. The supply of oil is not always reliable. As chemical fuels become more prevalent, their value will be higher and nuclear power generation will increase. Unfortunately, despite the inefficient use of fuel, we can not help but expect that more of our fuel resources, especially nuclear fuel, will be used for power heating.

[Figure 8-5] The efficiency of fossil fuel power plants in the United States has improved nearly 10 times from 3.6% in 1900 to 32.5% in 1970. This improvement was made possible by increasing the operating temperature of the steam turbine and increasing the size of the power plant.

The most widespread of all prime movers is the piston engine. Many American household garages have two piston engines, even if they do not include power mowers, snow throwers, chain saws, and the like. The output of piston engines in more than 100 million cars in the United States is estimated to be more than 17 billion horsepower, or more than 95% of all prime movers (defined as engines that convert fuel into mechanical energy). Although this massive output is not used most of the time, it accounts for more than 16% of the fossil fuel consumed in the United States. All forms of transportation - consuming a million tons of coal from ships, accounting for 16% of the total energy demand in the country. According to estimates by the energy consultant John Hume, the railroad delivered 54% more traffic (measured as an index of transport performance) as 1/6 of B.t.u. than in 1920. This increase in efficiency has reduced the share of the nation's total energy budget from 16% to about 1%, with the role of the railway in the national economy declining. But the curves for total energy consumption in 1920-67 show little or no impact of this tremendous change.

<Figure 8 - 8> The efficiency of the lamp depends on the quality of the light which each thinks is good. For perfectly flat white light, the theoretical efficiency is 220 lumens per Watt. You can get up to about 400 lumens per W by slightly boosting the light in the middle of the spectrum. Current fluorescent lamps can be 36% efficiency or 20% efficiency.>

An important use for the least efficient use of power is probably to supply light. (General Electric Company) estimates that lighting consumes about 24% of total electricity generation, or 6% of total national energy budget. It is well known that filaments of ordinary 100W incandescent lamps produce much more heat than light. Actually, it appears as infrared rays of 95% or more of power input, and only 5% or less is emitted as visible light. Nevertheless, this is more than five times the light emitted by a 100W bulb in 1900. Modern fluorescent lamps convert about 20% of the power consumption to light.

[Figure 8 - 9] Power generators currently in use utilize energy from falling water, fossil fuels or nuclear fuel. A hydro turbine generator (1) converts the potential kinetic energy into electricity. In a fossil fuel steam turbine generator (2), the boiler produces water vapor, which circulates the turbine, which turns the generator. At the nuclear power plant (3), a split of U ²³⁵ releases energy and creates water vapor, which is then passed through the circuit as in a fossil fuel power plant. In the currently undergoing nuclear proliferation furnace (4), surplus neutrons are captured by a coating of U ²³⁸ or Th ²³² atoms that can not divide and converted to Pu ²³⁹ or U ²³⁸ , which these atoms can divide. The heat of this reactor is carried by liquid sodium.>

This value is not a complete white light, but is based on a practical upper limit of 400 lumens per watt, assuming acceptable white light. The maximum theoretical output is reduced to 220 lumens per watt if the spectrum is limited to fully flat white light. Theoretically, you can reach 680 lumens per watt if you can be satisfied with the light of the shortest wavelength (550 nm), which is most sensitive to human eyes.

General Electric currently owns about 70 percent of the nation's total lighting, while the remaining incandescent light bulbs and high-end electric propulsion systems, locomotives and aircraft - consume about 25 percent of the nation's energy budget.

[Figure 8-6] The efficiency of a locomotive can be expressed as the amount of energy required to represent the unit <transport performance> in the US railway. The dramatic improvement in the 1950s reflects the fact that steam locomotives were almost completely replaced by diesel locomotives.

Automotive engineers estimate that the average efficiency of automotive engines has improved by roughly 10% over the past 50 years, from 22% to 25%. But the distance that you can run with 1gal of fuel is actually smaller. From 1920 until World War II, passenger cars typically traveled about 21.6 kilometers per gram of fuel. Over the last 25 years this average has been gradually shortened to about 20.5 km per gallon. This decline is due to the fact that the car is heavier, has a much faster engine speed, and has a powerful engine. It takes about eight times more energy to run a vehicle at 96 kilometers per hour than at 48 kilometers per hour. An amount of energy equal to the energy needed to accelerate the car's weight to 96 km / h should be absorbed by the brakes, mainly as heat, when the vehicle is stopped. Thus, much of the engine efficiency improvement is lost due to the way humans use the machine. Air conditioning of passenger cars also caused a decrease in the number of kilometers per gallon. This number of kilometers will soon improve as consumers change their preference for compact cars. However, the efficiency of the basic piston engine can no longer be greatly improved.

[Figure 8-7] The efficiency of an automobile engine is not perfect due to its weight and speed increase, but it is reflected in the number of miles per gram of fuel. Car makers say that the engine's thermal efficiency in the 1920s was about 22 percent. Today this is about 25%.

Even if all the cars in 2000 were powered by a charger charged with power from a central powerhouse, there would be no change in the overall fuel demand in the United States. The initial conversion efficiency at the power plant would be 35% compared to 25% of the piston engine, but it would be lost to convert the power into electrical energy (within the charger) and convert it back to power to drive the wheels Because. Current chargers have little room to improve their overall efficiency from 70% to 75%. Anyone who believes that all passenger cars are beneficial to power operation by everyone should consider the problem of increasing national power generation by about 75% as a necessary measure to run 100 million vehicles.

It is difficult to trace the savings made by the difference in efficiency of energy conversion, even if the difference is large, after the rail has been converted from a steam locomotive (10% maximum thermal efficiency) to a diesel locomotive (35% thermal efficiency) I can see that this happened. In 1920, the railroad is estimated to be about 135 million yuan. The efficiency of such a challenge is comparable to that of fluorescent lamps, and sometimes it is more efficient. This distribution means that the average efficiency of converting power to light is about 13%. To calculate the overall efficiency of converting chemical (or nuclear) energy into visible light, this percentage should be multiplied by the average efficiency of the power generation (33%), so the net conversion efficiency is typically 4%. Nevertheless, due to the increase in use of fluorescent lamps and famous lamps, the consumption of lighting in the country during the 1960s and 1970s was only doubled, and the consumption of lighting could triple.

[Fig. 8 - 10] The propulsion machine converts the energy of the liquid fuel into mechanical energy or kinetic energy, which is used for work and traffic. In the piston engine 5, the compressed fuel and air are exploded by electric ignition. The inflated gas pushes the piston, which is transmitted to the crankshaft. In the diesel engine 6, compression alone is sufficient to ignite the mixture of fuel and air. In the airplane gas turbine (7), the hot gases from the combustion chamber continue to expand and rotate the multi-stage air compressor as it flows through the turbine. The hot gases from the turbine provide kinetic energy for propulsion. The liquid fuel rou- tine 8 has an oxidant in addition to the fuel and does not depend on the air supply. Locate exhaust provides kinetic energy>

<Figure 8-11> New energy converters are being designed to use various energy sources. The fuel cell 9 converts the energy of the hydrogen or liquid fuel directly into electricity. This combustion of the fuel takes place in the porous electrode. In the recently proposed solar power plant 10, the sunlight reaches the specially coated light receiving plate, raising the temperature of the liquid metal to 500 캜. The heat thus collected is transferred to water vapor by a heat exchanger, which rotates the turbine generator as in a conventional power plant. It stores enough heat in the salt heat reservoir so that it can continue to generate water vapor even when the sun is covered by night or clouds. The NHD <turbine> (11) converts the energy of the hot, electrically conductive gas into direct power. In order to improve the electrical conduction of this hot gas, a small amount of <seed> substance such as potassium carbonate should be injected into the flame. Electricity is generated when the charged particles of this gas pass through a magnetic field by external magnetic force. The long-term goal is a thermonuclear reactor (12) where the atom of a light element fuses into a heavy element and releases energy. It is possible to capture high-speed charged particles produced by thermal nuclear reactions to produce power directly.

By simply looking at changes in ideal energy conversion efficiency, you will have some insight into the expected effects of a new energy conversion system under development. Two devices that have received much attention are fuel cells and MHD (magnetohydrodynamic) generators. Fuel cells convert chemical energy directly into electricity and the latter has the potential to be used as a high-temperature topping device that works with steam turbines and generators in power generation. A fuel cell has been developed which can <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> <BR> combustion < The output of the hydrogen-oxygen fuel cell produced by the Pratt & Whitney division of United Aircraft, used in the Apollo space program, was 20.5 V DC, 2.3 kW.

MHD generators have been developed as energy converters for the future for 10 years. In this machine, the fuel is burned at a high temperature, and a fuel such as potassium carbonate is sprayed to make the combustion products of the gas have electrical conductivity. This electrically conductive gas passes through the magnetic field at high speed and causes a flow of DC in the process (see Figure 8-11). If this MHD engineering can be developed, it will be possible to design a fossil fuel power plant with an efficiency of 45-50%. Because MHD requires very high temperatures, it is not suitable for reactors that form working liquids that are much lower in temperature than the working liquid temperature that can be obtained with a combustion chamber using fossil fuels.

If an energy source is developed at the right time, it is nuclear. There are currently 22 nuclear power plants operating in the United States. In addition, there are 55 nuclear power plants under construction and more than 40 orders have been placed. This year, the United States will produce 1.4% of its total power by nuclear fission, which will reach 25% in 1980 and 50% in 2000.

[Figure 8-12] The diagonal curve (left) bends exponentially over time. This curve shows how many times a doubling interval is needed to achieve a certain amount of increase. That is, if power demand continues to be doubled every 10 years, the demand for electric power will increase 8 times after three triple times, in 2001. An exponential growth curve is plotted on the opposite scale (right). If we reduce power consumption by half in the period A and then keep it for 10 years and return to the previous growth rate, the time required to reach the constant size demand B is twice the doubling period, It will not extend outside.

A nuclear power plant with an output of 1,000 MW is 10% more expensive than a fossil fuel plant ($ 280 million versus $ 250 million), but nuclear fuel is already cheaper than fossil fuel. According to some estimates, the value of coal is likely to double from now to 1980. One reason is that the new tonnages of coal produced per capita per day have been reduced to less than 15 tons from 20 tons already reached in 1969 due to federal safety regulations.

The electrical industry is characterized by its basic load, intermediate load (which is roughly equivalent to the sum of all the work done by people at home and work from 7 am to midnight), and peak load (seasonal load only a few percent of total demand) Is a new era in which we must rethink the way we should pay for it. In the past, the electrical industry used the newest and most efficient facilities to cover basic loads, and older and smaller facilities were used to cover the daily needs of the day. However, in the future when more new facilities will emerge, the facilities that currently cover the basic load are too large to easily operate and can not easily be downgraded to accommodate intermittent use because it is difficult to stop.

Therefore, there is a need to build a new type of flexible power generation facility that links industrial gas turbines to generators that produce low-pressure steam that is required for the combination of steam turbines and power plants using waste heat from gas turbines. (General Electric and Westinghouse Electric Company) are currently recommending this type of combination. Gas turbine facilities can reach maximum loads in less than an hour, although they are slightly less efficient than the most efficient conventional large facilities, and can be constructed at a lower cost per kWh. To meet the short-term peak demand, the electrical industry is increasingly turning to gas turbines (gas turbines can be fully operational in minutes if there is no waste heat boiler) and pumped hydro power generation systems. In the latter case, the electricity produced when not in peak demand can raise water to a reservoir at a higher location and release it when needed to produce electricity.

(Westinghouse Inc.) recently estimated that in 1970-90 the US power industry would have to build a new facility three times more than the current facility output of 1,000 GW (10 ⁹ W), or about 300 GW. Of this new facility output, 500 GW, or half, will be used to cover the expected increase in base load, and 75% of this 500 GW will be due to nuclear power. More than 400 GW will be used to cover the ever-increasing intermediate load, and a significant portion of that will be supplied by the gas turbine. The new maximum demand of around 170 GW is believed to be supplied by the gas turbine and the pumped storage system at a 10: 7 ratio (Westinghouse Inc.).

[Figure 8-13] The exhaustion of a resource can be read in the curve on the left. That is, if 0.1% of the world's oil resources are currently used, if the doubling period is 10 years, all of the oil resources will be exhausted within 10 doubles, ie, less than 100 years. According to the table on the right side, although there is a big difference in the estimated amount of resources used so far, the ultimate exhaustion period does not change much.

This expectation can be thought of as wisdom. If so, what can innovative wisdom offer in the 1990s, or what might be the new effects that will affect power generation in 2000? First and foremost, there are optimists who believe that a prototype nuclear fusion plant will be built in the 1980s and a full scale will be built in the 1990s. In a sense, however, this is merely a view of the conventional wisdom as an accelerated time unit. Those who really want to try innovative approaches ask why we do not start to develop the technology to get energy from the sun, wind or tide.

Many are still recalling the 1930s (Passamquoddy) plan, which is being discussed again, and the new plan is the Bay of Fundy between Maine and Canadier, (Less than 1/3 of the turbine generator output) using an average of 5.4 m of tidal power. A 240MW tidal power plant, currently in operation, was recently launched by the French government on the estuary of the Languedoc River, with an average of 8 meters in tidal range. How many tidal energies would you get if you developed both of the appropriate bays and estuaries in the United States? All estimates should be accompanied by sufficient evidence, but by relatively modest estimates it is thought to be around 100 GW. But I have just seen that the electrical industry has to increase this output by 10 times to meet the demand in 1990. We can conclude that tidal energy is not qualified to be a major innovative energy source.

The energy that the square feet of the American land receives from the sun will be the same amount of power output in the next 100 years, when power demand is doubled every decade.

[Figure 8-15] Three incremental curves were compared. Curve A is an exponential increase curve. Curve B is an extension of the doubling period by 20%. In curve C, the amount of increase during this doubling period is always constant.

What about the wind? A study by authors a few years ago (Occluder State University) found that wind in Orcler Homeric region is about 18.5 W per square foot of ground when it is in a direction perpendicular to the wind. This is roughly equivalent to the amount of solar energy per square foot of Ohl K. Homer's average of 24 hours a day under all weather conditions, all seasons. Turbines rotated by propellers can convert wind power into electric power with an efficiency of 60 to 80%. Like tidal energy and other forms of hydropower, wind power has the great advantage that it does not release waste heat into the living quarters.

The difficulty in using wind power results in the problem of energy storage. Of all natural energy sources, wind is the most variable. If you want a power plant with a constant output, you must acquire and save that energy when the wind is blowing. Unfortunately, no technology has been developed to produce practical energy storage media. The charger is not a problem either.

One of the promising plans is to decompose water into hydrogen and oxygen using the variable electrical output produced by the wind turbine. These gases are stored under high pressure and recombined at a constant rate in the fuel cell to produce power (see Figure 8-16). Instead, this hydrogen can be burned in a gas turbine to rotate conventional generators. (Rocketdyne Division, North American Rockwell, Northamerica Rockwell), a hydrogen-fueled rocket engine made by the company for the Saturn Moon spacecraft, Which can be used to generate the required hot gas ejection required to power the turbine. In the Rakiddainbu, water-cooled gas turbines can operate at higher temperatures than conventional fuel-burning gas turbines and predict that the overall efficiency of the plant can reach 55%. If the Rakidyne method is successful, you can use any source of hydrogen. Wind-driven hydrogen kits Gas turbine power plants will be innovative enough to please even the most exotic people.

<Figure 8-16> Winds as energy sources are attractive because they do not add extra heat to the environment, as is the case for fossil fuels or energy from nuclear fuel. Like capturing solar energy, wind is available anywhere, other than hydropower or tidal energy. Unfortunately, however, the wind is also too much change. To use this effectively, the energy captured when the wind is blowing must be stored and released somewhat continuously. One way is to break down water by electrolysis using the power produced by the wind. Then, the stored hydrogen and oxygen can be supplied to the electrolysis tank at a constant rate to produce DC. This direct current is converted into alternating current and supplied to the electric wire. The electricity produced outside the peak demand zone elsewhere can be used for electrolysis by supplying it to the electrolysis tank whenever there is no wind.>

On the other hand, most of the proposals using solar energy seem really monotonous. Recently, Arizona University has made considerable direct proposals to the Arizona Power Authority, the Elden Mayen and Marjorie Mayen of the Optical Science Center. They suggested that if they efficiently collected sunlight reaching 14% of the western desert region of the United States, it would translate it to 1,000 GW, that is, energy equivalent to an increase in energy demand, typically between 1990 and 1990. They believe that within the current technology range, they can design a mass storage system that stores solar energy as heat at 574 ° C, which can translate into a total efficiency of 30%.

The key to this plan is in recently developed surface coatings, which are highly absorbent to sunlight and emit little of the infrared portion of the spectrum. The heat collected during the day to resume energy release for 24 hours a day resists the molten salt at 574 ° C. The heat exchanger transfers this stored energy to steam at the same temperature. A thermal storage tank for a 1000 MW power plant will have a capacity of about 300,000 gal. (May 25th) suggests that the electricity industry and the government should immediately design and construct a demonstration plant with 100MW output near Arizona Humor (Yuma). The width of the light plate required for this level of power plant will be 3.6 million square meters (slightly larger than 1 square mile). After the necessary developments are made, it is estimated that it will be possible to build a solar power plant with an output of about $ 1.1 billion, which is about four times the cost of the current nuclear power plant and a power output of 1,000 MW. As they pointed out, "the solar power has an economic problem of purchasing by facility funds, not by operating expenses." Nonetheless, solar power plants with a 40-year life span are priced at an average of 1/2 cent per kW / h They are estimating that they can produce power.

[Fig. 8 - 17] Peter Glazer of Arthur D. Little proposed a solar collector on a rectified orbit. The space station, which is 29,000km above the equator, is fixed relative to the ground station. An 8 × 8 km light receiving plate will accept about 8.5 × 10 ⁷ kW of solar radiation. A solar cell with an efficiency of about 18% converts it to a power of 1.5 x 10 ⁷ kW, which is converted to microwaves and sent to Earth. On Earth, this translates back to 10 ⁷ net kW, or enough power in New York City. The coverage area of the receiving antenna will be about 6 times as wide as required for a coal-fired power plant with the same output, or about 20 times as wide as required for a nuclear power plant.

A more exotic plan for exploiting solar power has been developed by Peter E. Glaser of Arthur D. Little, Inc. His idea is to put a lightweight solar panel on a synchronous orbit about 3,500 km from the Earth and keep it on for 24 hours a day. Solar cells (under development) collect radiant energy and convert it to power at 15-20% efficiency. This power is converted electronically into 85% of the microwave energy in orbit, which is still possible today. This microwave will be chosen as the wavelength that can pass through the cloud with little or no loss and will be collected by a suitable antenna on the ground. With current technology, microwave energy can be converted to power with an efficiency of about 70%, and it can reach 80 ~ 85% efficiency. (Glazer) estimates that New York City's energy demand of 10,000 MW (= 10 GW) output power plants will require 8 square kilometers of receiving plate. The receiving antenna on the ground is slightly larger than 9.6km2. The microwave energy of this beam will be no harm because it is comparable to the intensity of sunlight. Glazer believes that this system will cost about $ 500 per kilowatt, or about twice the price of a nuclear power plant, assuming that round-trip space travel is possible for the construction of these satellites. The entire space station is 2,265 t, which is slightly lighter than the kit at launch time.

To meet the expected total electricity demand of 2,500 GW in 2000, 250 space stations of this size would be needed.

The great advantage of energy plans based on solar energy collected from the wind or the Earth's surface is that it may sound like an overpower today, but it does not add heat to the ecosystems of the earth. They say it's an invariant energy system. . The solar energy collected in the orbit is not a constant energy system in strict sense because most of the radiant energy blocked at 3,500 km altitude is a radiant energy that otherwise would not reach the earth. Only the energy collected when the sun's light-receiving plate is in line with the sun and the center of the earth does not heat up the earth's heat. On the other hand, the receiving plates in outer space will emit much less waste heat to the environment than fossil fuel or nuclear power plants. All but 20% of the total energy of the microwave to the Earth is converted to useful power. Of course, when this power is consumed, it is released into heat.

Recognizing the macroscopic nature of invariant energy system development, one has to be aware of what a certain amount of exponential growth means. The doubling process is a dreaded phenomenon. The amount of increase during any one doubling period - whether it is energy consumption, population, or land area occupied by freeways - is the same amount that it increased during its past past. For example, the next boats will contain as much fossil fuel as all the fossil fuels that have been mined on the Earth so far. Over the next decade, the United States will produce the same amount of power that has been produced since the beginning of the era of electricity.

The curve of this exponential increase is usually indicated on the opposite scale to indicate the whole. By specifying an appropriate value for both axes of the opposite scale, we can obtain a curve representing the number of boats required to reach saturation, or depletion, from the position of any known or imaginary percentage (see Figure 8-13 on the left) ) As an example, let's assume that 0.1% of the total fossil fuel reserves in the Earth have been mined so far, and that this amount has been doubled every 10 years. If this speed continues, you will be able to digest all of this fuel within a doubling period of ten times, in less than a hundred years. Of course, we do not know for sure how much of the total fossil fuel reserves have been mined so far. Let's assume that it is relatively small and 0.01% is mined, not 0.1% so far. According to this curve, in this case, all of them will be mined 100% within a period of 13.3 times, 133 years. In other words, even if there is a difference of 10, 1,000 or 100,000 times the amount of fuel mined to this moment, the timing of complete exhaustion does not differ much. Thus, even if only 1% (1%) of the total fossil fuel reserves of the Earth have been mined, even if the amount is doubled every 10 years, the total reserves will be exhausted in 266 years (Figure 8-13 See figure at right). It should be pointed out that the actual amount of mining depends on the type of fossil fuel, and that the 10-year period is only an example.

The key factor in estimating how many times the United States will tolerate a doubling of electricity demand every two decades (which is the actual rate of increase) is probably due to the fact that fuel supply - If so, it is almost infinite - not heat, but the effect of the environment on the conversion of fuel to electricity and ultimately to power. For the sake of discussion, let's consider only the heat content of the power actually consumed, ignoring the burden of waste heat from fossil fuel or nuclear power plants. By 2000, most of the power would be produced in a huge power plant for miles away from the coast, and it would be possible to imagine a game that would be able to release waste heat to the surrounding sea without damaging it (at least for some period of time).

In 1970, the United States consumed 1.55 billion kWh / h. If this were transformed into heat (and indeed it was) and evenly distributed throughout the land of the United States (which was not really the case), the energy released was 0.017 W per square foot. At the present rate of doubling, power consumption is increased ten times every 33 years. After the next 99 years, or ten times the number of doubles, the amount of heat released will be slightly less than 17 watts per square foot, or 18 to 19 watts per square foot, the average energy the United States receives from the sun 24 hours a day. Before doing so, you will need to change your current energy consumption pattern or develop the necessary technologies for an invariant energy system.

Let's examine what would happen if we changed the increasing pattern of energy in a way that seemed to be quite pronounced. Consider an incremental curve with an extension of 20% for each doubling period (see Figure 8-14). In the exponential growth curve, the energy consumption is increased by a factor of 10 by a factor of 3.32 times, or 33 years. The same increase in the curve of the increase rate is 10 times, which takes five times, that is, 50 years. In other words, it is only 17 years. The extension of consumption to 100 times is only 79 years (ie the difference between 145 and 66 years).

Another way is to significantly reduce current consumption levels and keep them at a low level for a certain period of time so that they do not increase and then return to the current rate of increase. If you reduce power consumption by half immediately, keep it for 10 years, and then regain the same growth rate as before, the time it takes for a 100-fold increase in consumption is only 20 years, extending from 66 to 86 years (See Figure 8-12, right).

In order to expect a long-term effect, the amount of increase needs to be the same curve, that is, a curve that increases by the same amount every original doubling period. On these curves, it would take nearly 1,000 years, not 100 years, to be predicted as a doubling every ten years for power output to reach the same level as the radiation received from the sun. As long as the invariable energy system does not supply much of the electricity demand, it is almost certain that the current rate of doubling can not continue for another 100 years, but how this system will look is still a problem hidden in the future.

As described above, the present invention provides a method and means for installing a nuclear waste disposal double-structure block tank marine tunnel transportation device (941) including marine deuteromagnetism in the marine environment to meet the electric power demand with the invariable energy system, The means of eco-friendly energy production of the present generation and all the so-called business people who have made the best efforts to extend exhausted resources should be accompanied by cooperation and efforts to join them for their descendants.

The present invention is based on the idea that even when the sea floor depth of the ocean is 10 meters, the raft or the marine vessel which is sunked by the typhoon and the waved wave, and the deep sea area where the sea floor depth is about 10 km, In the bottom layer, a dam hydroelectric turbine generator is combined with a water turbine tidal power or submersible control system. The turbine generator is connected to the submarine water depth gauge, or the turbine of thermal power generation turbine is combined with other power generation facilities. (2) Nuclear power plant (811) inside reactor body (1) of nuclear power plant equipped with dual structure block tank dust collector (811) Permanent disposal method of long-term nuclear waste with anti- To implement the waste treatment of the nuclear waste.

Referring to FIG. 21, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is installed in the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. (Nuclear Power Plant) Operation of Nuclear Power Plant Nuclear power generation facility (811) of elementary conventional nuclear power plant showing construction of one embodiment Example of conventional nuclear power plant showing decommissioning aspect of thermal power generation operation method of conventional thermal power plant Nuclear power plant Operation of nuclear power plant Thermal power generation of thermal power plant Disassembly aspect of operating method Construction of road,

Referring to FIG. 2m, a thermal power generation operation of the conventional thermal power plant of the nuclear power generation facility 811 is provided inside the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. Nuclear power generation facility of nuclear power plant (811) The nuclear power plant of the conventional nuclear power plant (811) The nuclear power plant of the conventional thermal power plant The operation of the turbine rotary blade (267) and the steam locomotive (1) of the nuclear power plant showing the operation mode as a side view, the operation of the thermal power generation operation of the thermal power plant of the nuclear power generation facility (811)

Referring to FIG. 2n, a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention includes a nuclear reactor main body 1, a nuclear power plant 1, Nuclear Power Plant Operation of Nuclear Power Plants In a nuclear power plant of a conventional nuclear power plant showing the essential constitution of the embodiment, a nuclear power plant unit 811, a steam pipe 779, and a high-temperature high-pressure steam inlet 780 of steam or a strong gas, The nuclear reactor 783 is decomposed into a side view and a cross-sectional view of the nuclear reactor of the conventional nuclear power plant. The nuclear power generation facility 811 is disassembled. The thermal power generation operation of the side power generation plant.

Referring to FIG. 2O, in the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, The nuclear power generation facility 811 is connected to the conventional production power central control room 781 and the transmission measuring room transformer room 782 through a connection structure The thermal power generation of the thermal power plant showing the operation methods of the thermal power generation and the operation of the nuclear power plant,

As shown in FIGS. 2L and 2M, in the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste, the conventional nuclear reactor of the nuclear power generation facility 811 is operated before and after failure A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and a condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and a core 791, a drum 792 and a reheater 793, a dust collector 794 of a thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

As shown in FIG. 2n and FIG. 2o, in the nuclear reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the conventional nuclear reactor of the nuclear power generation facility 811 is operated A transformer 96, a block pylon 116, a transmission line 775, a power transmission pylon 776, and an opening and closing facility 777 provided in a substation are installed in a nuclear thermal power plant 626 of a nuclear power plant, Ignition material wire 178 and flame 236 and the rotary vane 267 and the crank 248 and the piston 136 and the piston pump 127, regulator 136, exhaust gas 171, gas range 173, A steel pipe 746 for a petroleum industry and a steam pipe 779 for providing a cooling water outlet 350 and a cooling water inlet 352 and a Century Pewer pump 308 and an exhaust stack 465 and electric power 685, ), Steam (780), turbine generator (772), non-rotating armature coil (773) for nuclear power generators, and rotating The electromagnetic electromagnet coil 774 and a condenser 790 serving as a cooling device of the apparatus for cooling the water vapor to water and a core 791, a drum 792 and a reheater 793, a dust collector 794 of a thermal power plant, The tank 795 and the heavy oil 796 and the kettle 778 and the steam pipe 779 and the steam 780 to the electronic control units in the transmission measuring room transformer room 782 and the production power central control room 781 It is also possible to provide an internal operation status check of the reactor core 783 and to provide a double structure block tank dust collector for nuclear waste disposal to the inside of the reactor main body 1 of the nuclear power plant before the failure of the conventional nuclear reactor operation of the nuclear power generation facility 811 (626) Installed thermal power plant of nuclear power plant to provide post-fire restoration Thermal power generation operation of the thermal power plant Consists of connection structure,

Referring to FIG. 2P, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Nuclear power plant (811) Nuclear power plant road,

As shown in FIG. 2P, in the reactor installation of the nuclear power generation facility 811 during the operation of the nuclear power plant, a double structure inner block tank 596 for treating nuclear waste is connected to an iron plate 597 of high strength stainless steel, The steam 780 containing the radiation material into the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector 794 provided as a tank 599 and provided in the form of a dual structure block tank 598, And the reactor pressure vessel 813 is provided with a nose 791 on the core 791 centered on the core 791 composed of the fuel assembly 671 and the control rod 798. In the reactor pressure vessel 813, A control rod guide tube 798e and a control rod drive housing 798a are disposed under the core 791 and a plurality of core shrouds and a plurality of jet pumps 325 are disposed around the core 791. [ There are all kinds of irrigation facilities. Uigae construction machinery transporter committed to being composed of nuclear power seolbibu 811 is connected to the reactor construction equipment,

Referring to FIG. 2Q, the nuclear plant of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in the nuclear reactor main body 1, The nuclear power plant 811 of the nuclear power plant of the conventional nuclear power plant showing the construction of one embodiment is divided into the nuclear power plant 811 of the elementary conventional nuclear power plant, Decomposition side strap configuration Road,

     As shown in FIG. 2Q, in the nuclear reactor power plant of the conventional nuclear power plant, the nuclear reactor power plant of the nuclear power generation plant 811 is reliably stopped at the boiling water reactor plant 802 when the engineering safety system is abnormal If an accident occurs in the piping of the reactor cooling system and the cooling water 287 of the core 791 is lost (coolant loss accident), an emergency core cooling system (ECCS) is installed to prevent the fuel from being damaged The system consists of a high-pressure core sprinkler system, an automatic decompression system, a low-pressure core sprinkler system, and a low-pressure sprinkler system connected to engineering safety systems in a boiling water reactor facility (802).

      In case of fuel breakage, the reactor water storage container 808 is provided so that the radioactive material is contained in the cooling water 287 at high temperature and high pressure discharged from the core 791, so that the radioactive material is not discharged to the outside.

      Since the reactor containment vessel 808 in the boiling water nuclear reactor (BWR) 802 is all pressure-relieved, this system guides the outflowed steam 780 to the pressure control pool 240 of the pressure- The temperature rise in the containment vessel 808 is raised by the decay heat of the post-accident fuel, and at the same time, the cooling of the containment vessel 808 is provided And a containment vessel 808 sprinkler system for sprinkling cooling water 287 at the top of the containment vessel to remove radioactive material such as iodine floating in the containment vessel 808. [

     In order to prevent leakage of the radioactive material in the reactor containment vessel 808 in the boiling water reactor installation (BWR) 802, an emergency gas treatment system may be installed in the reactor building 688 to direct the radioactive material directly into the atmosphere Prevent emissions.

     In addition, there is a possibility that the temperature of the fuel covering material 681 increases with the loss of the coolant, hydrogen may be generated by the water-metal reaction, and the integrity of the containment vessel 808 may be impaired if hydrogen is burned rapidly Therefore, in the boiling water reactor installation (BWR, 802), nitrogen is sealed in the reactor containment vessel 808 during normal operation, but MARK-3, which is a design which does not require nitrogen sealing, is not adopted in Japan.

     In the boiling water reactor facility (BWR, 802), there is provided a flammable gas concentration control system for preventing sudden combustion by recombining the hydrogen and oxygen generated in the operation of the nuclear power plant. The following will be described.

    In the boiling water reactor facility (BWR, 802), during the operation of the nuclear power plant, the power station is stopped for regular inspection after a certain period of operation. Therefore, the fuel is replaced in parallel with the regular inspection. The temperature of the reactor cooling water 287 is lowered, the upper cover pressure vessel cover 813a of the reactor pressure vessel 813 is peeled off, the water is filled in the reactor pressure vessel 813 and the atomic low well, (BWR, 802), which is the core of the BWR, describes the use of a fuel changer, the control of abnormal BWR reactors, the construction of engineering safety, and fuel handling. ABWR, a large-sized nuclear reactor that pursues the cost advantage, and the utility company using each BWR are considering the ABWR as the next reactor.

Referring to FIG. 2r, a nuclear reactor power plant main body 1 having a dual structure block tank dust collector for treating nuclear waste according to the present invention is installed in an internal nuclear power generation facility 811, The diesel engine and the generator according to the operation of the hydroelectric power plant showing the conventional configuration of the hydroelectric power plant that provides the recovery, the diagonal construction of the electric motor pump for supplying the power of each compressor and the pump,

As shown in FIG. 2 (r), the nuclear power plant (1) of the nuclear power plant, the nuclear power plant (811) of the nuclear power plant, and the hydrothermal power plant (943) A hydro turbine pump turbine 943a, a large hydroelectric turbine Pelton turbine 943b and a large hydroelectric turbine Francis turbine 943c are connected to a large hydraulic power generator seesaw hydroelectric power plant 944, And at the same time the marine seesaw hydropower plant 943 facility of the hydroelectric power plant is connected to the power line 95, the transformer 96, the power line 71, the air compressor 80, the high pressure storage tank 145, The motor shaft of the nuclear power plant is divided into a connecting shaft and a distributing shaft of a motor motor body 192, a compressor body 263, a turbine 267, an engine 268, an intake port 269, a watertight passage 270, Nuclear reactor facility main body (1) Internal nuclear power generation facility (811) It is made up of marine seesaw hydroelectric power station (943) connected to the structure of the equipment to provide a hydroelectric power station at the time of recovery after failure of the entire nuclear power plant operation.

Conventional Nuclear Power Plant Reactor Facility Main Unit (1) Inside Nuclear Power Generation Facility (811) Hydroelectric power plant's hydropower distribution facility is composed of dams constructed to control flood and drought in the reservoirs and rivers of highlands The distal end portion of the introducing pipe 191 having a water pressure located at the intermediate position between the multipurpose dam 680 and the multi-purpose dam 680 storing the water of the flood control equipment such as an underwater dam is connected to the through hole of the dam 680 And a rear end portion of the introduction pipe 191 is connected to a suction port 269 of the head tank 189 having a pressure and a plurality of introduction pipes 191 are connected to the discharge port 270 located at the rear end of the head tank 189, And the flow rate of the pressure, which is supplied to the inside of each of the plurality of hydraulic generators, is moved inside the hydroelectric power plant located at the lower end of the multipurpose dam 680, It consists of a hydro generator equipment for production.

Referring to FIG. 2, the nuclear reactor main body (1) of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention comprises an internal nuclear power generation facility (811) The hydro-electric generator inside the hydroelectric power plant showing the conventional structure composed of the hydro-electric power production control unit for restoration, the pump aberration in the Francis aberration and the Pelton aberration, and the constitution diagram of the turbine and the guide vein inner- ,

As shown in FIG. 2S, the nuclear power plant (1) of the nuclear power plant is equipped with an internal nuclear power plant (811). The nuclear power plant (943) of the hydroelectric power plant The power generation facilities of the marine seesaw hydroelectric power plant 943 include a hydraulic aquifer 943a for a hydroelectric power plant, a Phelpton aberger 943b for a large hydroelectric power plant, and a Francis turbine 943c for a large hydroelectric power plant. At the same time, large-scale hydropower generator Shizuo hydroelectric power plant (944) generates hydroelectric power by generating hydraulic pressure inside the generator (944) to generate mechanical energy. A plurality of aberrons and turbines 267 for rotating the turbine 267 to produce power, a generator 944 for providing the power conversion produced from the aberrations and turbines 267, A plurality of turbines 267 and a generator 944 are connected to an upper end of a rotating shaft 198. The turbine 267 and the generator 944 are connected to each other by an electric motor A lower portion of the upper rotary bearing 944d is positioned at a lower portion of the device 944b for pushing the ring tubular feathers and a stator coil 944f and a lower portion of a stator 944e are provided below the device 944e, The frame 944g and the central stator 944h are positioned and the electric wire 71 is sandwiched between the central stator 944h and the fan 195 is positioned below the central stator 944h and the fan 195 A low speed cooler 944i is provided below the braking device ring 944j and the braking device jack 944k and the low speed rotation bearing 944l and the engine generator 944m, the turbine rotation support 944n, (944p) The rotation axis (198) An armature coil for a generator, which is a non-rotating coil provided along the circumferential surface of the rotor coil, and a plurality of aberrators and a turbine 267 for providing a position to the lower end of the rotating shaft 198 And the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydroelectric power connection structure power production control unit 811b and at the same time the Francis turbine 943c The Peltton turbine 943b has a turbine 267 and a suction port 269 and a discharge port 270. The inlet port 269 and the discharge port 270 communicate with each other in the casing 141 and with a pressurized flow rate within the hydraulic power generator 944, The pump turbine 943a can control the distribution to the respective industries by adjusting the voltage in the substation of the transformer 96 of the substation, which is the power transmission unit, while generating hydroelectric power by rotating the aberration, The main pump 265 is controlled by opening and closing the main valve 265 to operate the pump water turbine 943a while generating hydroelectric power and move the water to the water storage dam 680 located at the upper part of the power plant (811) of the nuclear reactor facility main body (1) of the nuclear power plant, and at the same time, the nuclear reactor facility (811) of the reactor main body (1) of the nuclear power plant is provided with the hull position Control of the construction construction machinery and the hydro-hydro power production control unit of the hydro-hydro power generation, control of the power transmission, prevention of the harmful red tide prevention control, prevention of disaster prevention, control of the fish and shell scattering control unit, and control of the hydrological control of the dam. Connection axis connection structures.

(943b) for a large hydroelectric power plant and a Francis turbine (943c) for a large hydroelectric power plant are provided in a pump aberration (943a) for a hydroelectric power plant constituted by an offshore hydroelectric power plant (943) A head tank 189 serving as a pressure tank for providing a position above the power generation plant 943 and a suction port 269 located in front of the head tank 189 are provided with a connection structure with a head tank 189, The turbine 264 and the turbine rotary support 944n and the impeller 944q are provided inside the casing 141 of the hydroelectric power generator 944 to constitute the hydraulic power connection structure power production control unit 811b The turbine 267 is different in shape from the Francis aberration 943c to the Pelton aberration 943b to the marine seesaw hydroelectric power plant 943 while the suction port 269 and the discharge port 270 are connected to the inside of the casing 141 And pressurized flow provide for movement within hydraulic power generator 944 The pump aberration 943a can control the flow rate of the flow rate stored in the stream by adjusting the flow rate of the flow rate stored in the stream, The hydraulic pump 943a is operated by controlling the opening and closing of the main valve 265 by the electric power supplied from the nuclear power plant while simultaneously generating hydroelectric power to the marine seesaw hydroelectric power plant 943, 680 of the reactor main body 1 of the nuclear power plant, or by the dispensing apparatuses of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant, The hydroelectric power generation unit 941 may be connected to the hydroelectric power generation unit 944 in the power generation facility unit 811, The impeller 143 may be attached to the end of the rotating shaft 192 of the motor body 192 and may be formed of a prime mover having a connection structure with the power pump 304. At the same time, To the distribution apparatuses of the nuclear reactor main body 1 of the nuclear power plant 1 and the internal nuclear power generation facility 811 of the nuclear reactor main body which are formed by the distributing and inputting apparatuses of the internal nuclear power generation facility 811 as the urine site equipment.

Referring to FIG. 2, a conventional diesel engine unit (1) of a nuclear reactor plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention comprises a diesel engine External Dimensions and Power Motors Model Construction of Internal Disassembly and Assembly of the Motor Body (192)

The power motor motor body 192 provided in the nuclear reactor main body 811 of the nuclear reactor main body 1 of the nuclear power plant is provided with a hood 193 and a fan 194 195 and the body frame 196 are provided with a body front reinforcing steel plate 197, a rotary shaft 198, a rotor assembly 199, a front rotary support 200, a stator assembly 201, a motor protection casting frame 202, A terminal box 203, a lifting bolt 204, a terminal box cover 205, a rear rotation bearing 206, a rear reinforcing steel plate 207, a gap 208, a fan protection cover 209 and a rotor iron core 210 And a stator core 211 and a stator winding 212. The hydroelectric power generation is generated by a power transmission unit and a diesel engine generator 268 and is wound around the pump and the compressor by a rope It is equipped with a tackle winch (137) for connection and disconnection of the gate with a chain, Consists reactor equipment body (1) connected to the dispensing coupling input device connection structure of the internal atomic power seolbibu 811.

The electric motor body 192 of the distribution and connection device connecting structure of the internal nuclear power plant 811 of the main body 1 is provided with a hood 193 and a fan 195 and a body 192 in a snap ring 194 The cast body body frame 196 is provided with a body front racket 197 and a center rotary shaft 198 along the periphery of the rotor assembly 199 and a forward bearing 200 And the stator assembly 201 is formed inside the body frame, the terminal box 203 and the motor body 192 are fixed to the outer side surface of the casting frame 202 for protecting the motor, After the threaded tabs 167 having a predetermined dimension are formed in consideration of the weight of the object by the electromagnetism force so that the lifting bolts 204 can be lifted to lift the object, the lifting bolts 204 in the form of O- The terminal box 203 is provided with an attachment bond to the tab 167, The terminal box cover 205 is attached after the screw tabs are installed at four positions and a gap 208 is formed in the rear bearing 206 and the rear racket 207 at the rear of the rotary shaft 198 and a fan cover 209 are mounted on a fixed pinhole 20 at a forward portion of the rotary shaft in a link band 249 connecting the crank 248 and the crank 248 attached to the rotary body, (Square × 6 mm × 6 mm, length: 60 mm, 254) is fixed to a pin hole (width × length × height × A length of 3 mm x 3 mm x 3 mm x 80 mm, 20) is machined in half by a fixing pin dimension of the rotary shaft fixing pin hole and the fixing pinhole, the fixing pin 254 is screwed into the fixing pin hole By means of the Lena group, the individual bearings and bearings provide for disassembly and assembly, but at the same time they are fixed to the motor body 192 facility And the stator core 211 and the stator winding 212 are attached to the inner surface of the body frame and are provided with the electric motor pump formed to be attached to the processing hole 20 of the fixing pin 254 of the impeller 143 without the plow 250, 251 and the belt 252 are mounted on the circumference of the piston 127 with a plurality of cylinders 126 separated by a compressor to form a pump and a compressor. to be.

: 상기 형태, 129)로 뺑글뺑글 앞산 계곡으로부터 출발하여 360°로 회전시켜서 다시 앞산 계곡으로 설치되되, 단 산정상 산맥을 따라 지나는 소방방재배관라인(168)에는 상기 빗장걸이 장금장치(129) 형태의 방재수로(17)의 집수정탱크(34) 하부 위치에 레듀사(35)와 배관연결부속엘보 또는 티이엘보(44)로 방재배관라인(168)에 연결된다.As described above, according to the operation of the impeller of the motor motor rotary shaft 198, the booster pump control box 2 installed at the left side of the pump and the booster pump control box 2 installed in the industrial machine room in which the water pressure of the incoming fire water is compressed and stored, 3) and the discharge joint pipe 4 made of a material capable of withstanding high pressure is referred to as a manifold or a head tank 189 and a predetermined amount of fire-fighting water conveying means (for example, High mountain top to low mountain as an agate methane type plastic vinyl coating material, 350mm diameter flow tube can be transported by manpower, light and long life after being selected. 14) is formed and the piping 14 is connected to the piping 14 and the disaster prevention system 14 by a predetermined standard (width × height × width × height = 1 × × 1M) The bolt locks on the door (17) at a constant angle of inclination (16) 1 ° ((

The fire-fighting piping line 168, which is installed along the mountain-top mountain range, is installed in the form of a bolt latching device 129 Is connected to the disaster prevention pipe line (168) by a reducer (35) and a piping connection attached elbow or tee elbow (44) at the lower position of the water collecting tank (34)

Referring to FIG. 2U, a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention includes a main body 1 of a nuclear power plant, an internal nuclear power plant 811, The control block diagram and BF model are shown in the schematic block diagram of the pump front and front view and the cross-sectional multi-stage pump system concept; Speed control method, and 3-pump direct-injection-start-type system.

As shown in FIG. 2U, a distributing and inputting device for a nuclear reactor installation of a nuclear power plant constituting the nuclear reactor internal power generation unit 811 of the nuclear reactor facility main body 1 of the nuclear power plant is provided with a control block The pump power source 272 is divided into the control power sources 273 and the control power source 273 is operated in the emergency operation mode. (M / C) switch contact of the pump power source 272 and the inverter contact of the inverter 47 after being contacted with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontrol unit 276 by the micropower supply circuit 275 of the control power source 273 so that the microcontroller 277 and the switch input circuit 58 are connected When the input setting And the motor overload signal input circuit 280 outputs a signal to the (M / C) drive signal contact output circuit 279 and the motor overload signal input circuit 280, MCC B + T HR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the micro control unit 276, And a discharge pressure transmitter 284 is connected to the pressure sensing circuit 282 and connected to the inside of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal after connection, After the intake / discharge pressure switch 285 is connected to the external state input circuit 283 and the input circuit 283 is again connected to the microcontroller unit 286, Lt; RTI ID = 0.0 &gt; 276 & Type multi-stage pump operation modes is provided as an automation is composed of a nuclear power station connected to the distribution chute of a nuclear reactor plant having a structure of double nuclear waste disposal building block tank for the dust collector.

Referring to FIG. 2 (b), a conventional multi-stage block tank dust collector for treating nuclear waste according to the present invention has a conventional multi-stage multi- In the control system using the microcomputer of the pump and the inverter system of the digital pID control system, an unmanned camera of the control system is installed, and the inverter system in which the fire water is discharged from the injection nozzle is combined with the equipment of the control system. Operation Configuration Road,

As shown in FIG. 2 (b), the distribution input device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor installation main body 1 of the nuclear power plant is provided with the disaster- An inverter system in which an unmanned camera 184 of a control system is installed in an inverter system of a control method using a microcomputer and a digital pID control system of the preventive and controllable multi-stage pump 8 and fire water is discharged from the injection nozzle, (1) of a nuclear power plant to which the equipment of the fire extinguisher is attached, a fire body (166) in which a flood control process is formed is burned, and fire water in the fire body nozzle body is held inside the fire extinguisher, Stored in the fire extinguisher body 164 is stored and discharged simultaneously to the outside of the extinguisher body, The unmanned camera (not shown) installed at the height of the electric pole around the fire scene when the discharge pouring water 38 and the discharge pouring water curtain water film 39 are burned out at a moment when the burning pillar 237 is removed, 184 in order to display the situation at the time of fire on the monitor 52 through the information detection function of the pump control server 51 of the multi-stage multi-stage pump 8 control system 150, 8) is characterized by a digital control system and an inverter (47) consisting of a distributing and inputting device connection structure of a nuclear reactor plant including a speed control system and an algebraic control system.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor installation of the nuclear power plant has disaster prevention water, disaster prevention water, The control material or the disaster prevention material replacing the disaster prevention yarn is a natural loess or powdered yellow loam, and is a transportation equipment for transporting disaster prevention material, such as a fire fighting helicopter and a fire truck. The transportation equipment uses a basket (42) Disaster prevention waterways (17) in river streams with abundant disaster prevention materials or reservoirs or reservoirs that have a certain amount of disaster prevention water are transported and transported a number of times in order to evacuate the national disaster prevention fire. It is fortunate that if the initial evolution is carried out at this time, it will be declared as a disaster area if the evolving activity proceeds for more than a week. As a result of the need for prevention of disasters caused by disasters, which is a collective term for all disasters that are not declared as a disaster area, the development of disaster prevention has been progressed by the research and development of double structure block tank dust collector Research and development are underway in the distribution shaft and the connection shaft which are formed in the nuclear reactor main body (1) and the internal nuclear power generation equipment section (811) of the nuclear power plant.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading device of the reactor facility of the above nuclear power plant is designed to protect the life, The present invention provides the disaster prevention technology of the disaster prevention system of the present invention, and it is possible to provide the disaster prevention technology of the present invention by using the conventional fire fighting equipment, communication equipment and transportation equipment as advantages and disadvantages, Of the above-mentioned fire fighting equipment, an air balloon rubber air hose, a rubber hose to a wire rope, and other equipment to prevent a large-sized fire, And a tube nozzle processing hole formed by a hose and a nozzle body of a double pipe structure.

As shown in FIG. 2 (b), in the high-pressure type multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant, the fire nozzle (10) The disaster prevention nozzle is a small size pipe (14), a disaster prevention hose (9) that is made of a mixture of air (gas) and liquid, and a disaster prevention nozzle ), A disaster prevention nozzle (10) connected to the rear end of the piping of the high pressure multi-stage pump (8), a cable type disaster prevention nozzle (10), and a disaster prevention nozzle (10) A nozzle 18 is attached to the nozzle support frame 11 and the hook 13 and a spring 186 is attached to the wire rope 19 so as to impact the lug 21 and the shackle 23 for the safety pin, The nut 25 and the washer 26 as the bolts 24, The system including the high performance submersible pump 36 and the high pressure bottom-up pump control device by the mobile phone 82 of the communication means and the cable car 256 engine 226 after assembling the plate 165 and the flange 28 (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste.

As shown in FIG. 2V, the high-pressure multi-stage multi-stage pump 8 of the nuclear reactor plant includes a plurality of ejection nozzles 38 ejected into the nozzle gap 15, A partition wall 39, a water film or a plurality of radiation curtain water films 39 are arranged in a reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for providing fire suppression for life- ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the multi-stage, multi-stage multi-stage pump (8) of the high pressure multi-stage multi-stage pump (8) for connecting the distributing and inputting apparatus of the reactor plant of the nuclear power plant has fire water The conventional high-pressure type multi-stage pump is a water supply system for supplying water from a low place to a high place by watering. In a step drive system in which each pump is controlled to be turned on and off, It is a trend to change to an inverter drive method for drive control. The control system for efficiently controlling the driving of the multi-stage multi-stage pump of high pressure is such that the high-pressure multi-stage multi-stage pump 8, as shown in the figure, The pump 8 is equipped with a double structure block tank dust collector for treatment of nuclear waste, in which a plurality of high performance submerged pumps 36 are provided at intervals of 160 meters in a stepwise manner after the elevation of the elevator (1) of a nuclear power plant.

As shown in FIG. 2 (b), the high-pressure three-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor installation of the nuclear power plant is equipped with such a high- If so,

Firstly, most of them are monitored and controlled independently in the off-line. Therefore, the burden on the operation of the high-pressure type multi-stage pump is increased in a place where the worker or the worker is difficult to access and in a dangerous place. Second, since the switch button is used, And the third is that it is difficult to apply the system for managing the entire system when the system is dispersed in a plurality of places. In the fourth place, a plurality of high-pressure multi-stage multi-stage pump 8 control system 150 is manufactured and installed It is time consuming and costly to perform the independent test for setting the initial value and initializing the program.

In some prior arts for solving the above problem, firstly, in a high-pressure type multi-stage pump remote control system using a public telephone network, an alarm signal is transmitted to a central control server While the unmanned camera 184 at the same distance as the installation position of the electric pole is spaced apart by 50 meters outside the pipe nozzle industrial site, Inline high pressure bottom-up type, which has communication means of circulating water supply device, can be installed in a large number of neighbors in the inline high-pressure bottom-up type having the communication means of the circulating water supply device because the gas is supplied continuously, A high-pressure bottom-up type wired / wireless communication unit is provided and connected to the control system 150 And a helium (176) gas is formed into a plurality of hoses through the intake port and the exhaust port into the above-described advection balloon (77) and the airship (78), so that a nuclear power plant having a dual structural block tank dust collector In the "pressurized water supply operation management system", the load distribution of the reactor installation main body 1 is provided. At the same time, in the "pressurized water supply operation management system", the operation of the pneumatic water supply operation facility is grasped by using the Internet network 50, A management sub-system for providing information on the operation status of the water supply operating facility of the pneumatic conveyance transmitted through the network is provided on a date basis, and a portable wireless communication terminal Pressure multi-stage pump control system (not shown) that provides various services to the monitor 52 through the portable wireless communication terminal 82 (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste through wireless network (1) Nuclear power plant equipment (1) Equipment to be formed in the nuclear power plant (811). Ad-hoc or infrastructural Establish network construction.

In the high pressure stage multi-stage pump 8 installed in the interior of the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, And a motor is installed in the motor, a motor is constantly rotated by electricity supply, and the motor 127, which generates a very high pressure by reciprocating operation and operation, is referred to as a high-pressure multi-stage multi-stage pump, The pump module is equivalent to the engine module and is coupled with the pump module which is a mechanical value. In the inside of the three-stage multi-stage pump, the fluid flow in the impeller 143 is uniformly provided and the loss due to friction, vortex, etc. of water flowing out from the impeller 143 is reduced And is made to be guided.

The high pressure stage multi-stage pump (8) installed in the interior of the machine room formed in the internal nuclear power plant (811) of the reactor facility main body (1) of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, A power line for sensing sensor, and an electronic line for electronic control, and connected to the overcurrent breaker brake 61 and the main switch button 66 by the monitor 52 and the power supply 62, The check valve 6 is connected to the isolation valve 5 formed outside the pump body which is connected to the control device with the operation-on and the operation-off respectively, and the regulator 136, which is constantly reduced in pressure, And an electronic control unit 88 formed by a plurality of pumps in a plurality of valves and an electronic control unit such as an emergency valve 84 and a pressure check sensor in the low-pressure shut-off valve 83 are installed with a plurality of switch buttons , The above- A short distance wireless communication antenna 54 and a short distance wireless communication control module 54 are connected to a power supply 46 which is a power supply unit and a three stage multi-stage pump control board 53 of a high voltage down- The portable radio terminal 82 of the communication means or the electronic control device connected to the public telephone communication network is installed inside the multi-stage multi-stage pump control box 2, ), When the signal is wirelessly received by the electronic control unit module and the "switch button-on" inside the control room, the display screen 63 of the monitor 52 is installed so that it can be visually recognized in the control room, Communication valves belonging to the electronic control device and the isolation valve 5 on the front and rear sides of the three-stage multi-stage pump, the low-pressure shut-off valve 83 and the low-pressure shut- Electronics Which is a disaster prevention material including a wired / wireless communication device and an electronic control device which are connected to a solenoid valve 76 and an air compressor 80 of an air conditioning system via a collecting nozzle 34 and a dust collecting line 89, And it is a device installed on the roof of a lot of forest fires and dwellings in the shape of a discharge water jetting or a curtain water film, and the fire extinguishing material having a constant water pressure is fired into a plurality of nozzles gap and a plurality of nozzle gap machining holes. (1) Nuclear power plant reactor main body having a dual structural block tank dust collector for nuclear waste disposal with fire fighting and disaster prevention measures for life saving purposes (1) The pump 8 is provided with a connection structure.

In the high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811, a detection sensor 104 for checking the amount of arson at a low water level on the inner wall of the water collecting compartment is connected to the first ignition sense wire The multi-stage pump control box 2 of high pressure inside the machine room is delivered to the electronic control sensor for checking the level of the disaster prevention water, and when the disaster prevention water reaches a certain level after the pump operation is stopped, The bevel tap 499 in the form of a circle is attached to the inner wall of the collecting wall by a small thin wire serving as a lever, and when the bevel tap 499 is moved downward, the pump operates and the position is fixed horizontally The operation of the sensing wire 41 is performed at an angle of 90 ° or 120 °, and a high mountain In the case of the low-acid collecting tank, it is necessary to install the collecting tank (34) inside the collecting tank (34) so that the height of the collecting tank can be adjusted before the disaster, (2) A double structure block tank for the treatment of nuclear waste, which provides simple solution within one second for the normal fire separated by A fire. (1) Nuclear power plant main body of nuclear power plant with dust collector Pressure multistage multistage pump 8 installed inside the machine room formed in the main body 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is such that a machining hole 20 (not shown) is formed in the stopper steel plate 165 on the flange- The filtering water is filtered by the isolation valve 5 and the check valve 6 so as to pass through the suction and return pipe 3, ). At the same time, the detection sensor integrally includes a meter 105 for checking the flow rate of the water, a ball tower 104 for sensing the water level, A high pressure isolation valve is installed in the middle of the meter 105 and the pump suction connection flange 28 at the upper end of the piping in front of the pump suction port 269 and a high pressure isolation valve 5) This is an automatic control valve that controls the transmission. The control unit is a magnetically controlled valve and a solenoid operated control valve. The solenoid valve 76 or the butterfly butterfly valve (305) is formed in the disaster prevention piping line (89), and a nuclear power plant having a double structural block tank dust collector for nuclear waste treatment is installed in the nuclear power plant (811) Stage type multi-stage pump (8).

The connection structure of the high-pressure three-stage multi-stage pump 8 formed in the nuclear power generation facility unit 811 is such that the basket 42 or the plastic pack 43 is connected to the ground surface 292 by the fire 292 or the spark 293, The control unit, which is a sensing sensor at the top of the valve, detects a fire, the valve is opened, the water is held at the top of the upper part and the water is held in the disaster prevention pipe, and the water having a constant water pressure passes through the valve opened to the disaster prevention pipe, And reaches the plurality of injection nozzles 10 in the region. The injection nozzle 38 discharges the water by the constant water pressure of the water pressure of the diverging nozzle. Accordingly, the disaster prevention piping 89 is provided at the lower end of the high pressure multi-stage pump inside the machine room, and the joint connection site emergency valve 84 and the hydraulic pressure control reducing valve 85 of the head tank 189, The first pressure check sensor 86, which is a detection sensor attached to the multi-stage pump control box 53, is connected to the inner multi-stage pump control box internal control board 53. After the pump is operated again to maintain the hydraulic pressure of a certain standard, At the same time, the disaster prevention piping line 89 is provided with a double structure block tank dust collector for processing nuclear waste, which is provided with a water pressure sensing regulating valve 85 at a constant distance from the machine room floor surface (MFG) Pressure multi-stage multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant provided with a connection structure.

The high-pressure type multi-stage pump 8 connection structure formed in the nuclear power plant 811 is configured such that pressure suction is performed to the left and right sides around the suction port around the impeller 143 inside the protective cover of the multi- And the discharge piping 3 and 4 are referred to as a head tank 189. The head tank 189 has a very high and high pressure and the water pressure of the fire water rises. At this time, the head tank has a capacity of 8 liters, When the pressure is reached, the pump inlet or pump discharge port in front of the head tank and the large pipe (14) of a certain standard size and the pipe connection fitting corresponding to the elbow or tee elbow (44) having a double structure block tank for treating nuclear waste, which is provided with a suitable material to withstand a high pressure, (1) providing a connection structure for Vertical multi-stage pump 8, the high pressure that would be installed in a machine room inside are formed in the atomic power seolbibu 811.

The high-pressure multi-stage multistage pump 8 connecting structure of the nuclear power plant 811 has a flange connection on the junction of the disaster pump connection port and a flange 28 and a flange 28 on the flange connection. (1) and (2), consisting of a nozzle nozzle (10) and a fire hose (9) connected to each other by bolts and nuts, Pressure pump may be installed in the head tank 189. However, the pressure tank may be connected to the high-pressure head tank (not shown) 189), there is a lack of realism and an uneconomical problem. In addition, the injection nozzle body (B), which is the injection nozzle (10), is divided into basic 1 type and basic 2 type "Title 100" ( 240 " to " NAME 50 "238 and" NAME 40 "239 to" NAME 75 "236 and" NAME 65 "237 to" NAME 90 "235, (10) Body (B) to be detached and connected to a standard type fire hose connection is a nuclear-power plant having a double structure block tank dust collector for nuclear waste treatment provided in a basic type 1. Pressure multi-stage multi-stage pump 8 installed in the machine room formed in the multi-stage pump 811.

The multistage multi-stage pump 8 connecting structure of the nuclear power plant 811 includes a water inlet 169 of the fire and disaster prevention line inside the multi-stage pump 8 and the collecting tank 34 inside the pump extinguisher body. The float 315 on the upper part of the manhole cover 152 and the float 315 on the lower part of the manhole are connected to the lower end of the manhole cover 169 by the water supply port 168, the water supply port 168 and the waterproof port 169, The float 315 is attached to the float 315 at four places around the processing hole 20 of the outer wall of the tank so as to fill the inside of the manhole 152 to fill the inside of the manhole 152. [ Is coupled to the square flange 28 of the louver cover 550 body so as to be formed of a separate louver cover 550 and a float retainer switch 551 and then inserted into the tank outer wall machining hole 20, Fill the nuts (25) after binding to the four places, The key wrench is used to separate and separate. Meanwhile, as shown in the figure, the upper portion of the bed frame 286 is fixed to the upper portion of the bed frame 286 above the upper surface of the bed frame 286 above the ground surface GLL, A pump 259 attached to the pump 308 with an upper tee elbow 44 is connected to the valve 114 via a flange 28 at the left side of the valve 114, A bass canceller alarm 543, a remote control alarm 544 and an alarm reset button 545 and a low level switch 546 at a low position inside the tank are connected to the switch 541 and the high level alarm 542, And is installed inside and outside the control board 53.

The centrifugal pump unit 308 has a structure in which the rotary shaft 198 which is the center shaft 198 of the motor 192 is connected to the high- A guide vane 142 is attached to the impeller 143 inside the casing 141 which is a body of the pump 308 so as to be closely attached to the previous pump driving yaw member and is mounted on the periphery of the rotating shaft 198 located at the center line of the casing 141 A balance hole 376 is formed in the septum seal 156 and the partition wall 372 of the shaft seal device so that the axial seal portion 390 is formed in such a manner that the cooling method 391 of the cylindrical seal is largely changed. The control box of the board 53 is configured such that the flow rate check flow meter 105 and the overpressure prevention switch 108 function as a stop valve at the upper part of the water line 169 line pipe 114 and a pipeline line sensor formed by a separate tee elbow 44 in the line piping 168 Is detected.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 is connected to a disaster prevention pipe 14 for disaster prevention next to the water supply pipe 14, The name "100 × 90 (241), 90 × 75 (242), and 75 × 65 (243)" are used for the seven standard types of the standard specifications formed by the piping bodies so that the standard can be adjusted by the connecting subsidiary reducers (35) The injection nozzle body is connected to the spray nozzle body in an antenna type so that installation is possible in the order of nominal 4 × 25 "(246) to nominal 50 × 40 (245) of 65 × 50 (244) And the pipe 14 of the injection nozzle body is joined to or connected to the pipe 14 of the injection nozzle body one by one so as to be connected to the rear end of the pipe bottom surface of the machine room. ) Are classified by designation and are connected by piping connection lead (35) And the piping 14 and then the piping connection reducer 35 are connected in this order so that the coupling and separation are performed in the reverse order and the bolts 24 and the nuts 25 for connecting the injection nozzles are connected to the washer 26 by the dis- The nozzle body (B) is connected to the flange connection processing hole (20) inside the flange (28) and connected to a recess formed between the flange (28) and the flange Is a high-pressure type multi-stage pump (1) installed in the interior of a machine room formed in an internal nuclear power plant (811) of a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector 8).

The high-pressure type multi-stage pump 8 connecting structure of the nuclear power plant 811 has a structure in which a bolt nut (not shown) can be easily disassembled and assembled so that the washer 26 can be adjusted to 0.5 millimeter or 5 millimeter at an intermediate portion between the flange and the flange. The discharge jetting number 38 can be set such that the operation of the radiation curtain water film 39 or the straight discharge jetting number of the valve and the high pressure stage type multi-stage pump 8, which are control devices, The discharge jet 38 that continuously and continuously discharges into the nozzle gap 15 is applied to a multipurpose range of preventive measures to prevent the spread of a large-sized fire and to prevent disasters. A plurality of airships 78 and an ad hoc balloon 77 are connected to the air hose 109 through the nozzle hose in the form of a multi- (1) of a reactor plant main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, including a method of using disaster prevention equipment for transferring air generated in an air compressor (80) And a connection structure is provided to a high-pressure type multi-stage pump (8) installed inside the machine room formed in the nuclear power generation facility unit (811).

The nozzle gap 15 formed around the periphery of the pipe 14 of the injection nozzle body 10 has a plurality of linearly arranged plurality of nozzles As the water film ejection number 38 rapidly evolves the flame 292 and the flame 293 gradually and precisely and evolves to prevent a large fire as a result, In the rice fields around the mountains and on the roads and neighboring houses, a straight nozzle gap is formed in two places on the pipe as in the arrangement of telephone poles. Small pipes are used as disaster prevention water transport means by using large and small pipes. The piping is slightly larger than the small piping to the top of the piping, and the piping parts are joined together by using a bolt or a nut and a nozzle gap (15) of a straight line with a piping length of 4 meters As a result, the discharge jet 38 was ejected from the two high-pressure multi-stage multi-stage pumps 8, and the performance was tested 20 times by adjusting the gap 15 again. The fire wall nozzle is formed in such a way that the fire wall nozzle is formed so as to prevent the road from freezing in winter due to the weather condition due to the installation length depending on the installation height of the water film curtain of the triangle, In order to improve the quality of life of the working environment, the fog is removed around the surface of the road and the view of the front of the road is widened so as to smoothly communicate with the traffic vehicle for safe driving of the driver. For farmers engaged in agriculture, it is necessary to protect and cultivate the crops of the vinyl house, On the day of precaution and rainy weather, the disaster prevention waterway (17) of the steep slope angle (91) and the constant slope angle (91) of the ridge line in the drought And disaster prevention pipelines. In order to prevent hail damage in the summer, it is necessary to keep the water properly in the vicinity of the disaster prevention pipe. It is a holiday resort on the sandy beach of the resort area. It cools the heat on the hot day on the coastline. It is a means of ejecting from the gap between the straight nozzles and the cold air. The fog is removed and the traffic is smoothly made. The fall harvesting sparrow prevents the grasshopper from being in proximity to prevent the loss of grain, In order to preserve large-scale bridge management, which is a first-class steel structure for the preservation of buildings, To establish a non-disaster world village in the international society in addition to the opening zone (sovereignty zone) in the multi-racial format, or in order to achieve peaceful coexistence in Northeast Asia, it was installed as the central axis of the center line of the Pyungang River, Cheorwon (2) A double structure block tank for the treatment of nuclear waste having a pipe nozzle-moving type fire sensor pump installed in a 1200-kilometer radius of 3000 Lane. (1) Nuclear reactor main body (1) It is necessary to cooperate with all the people of the respective countries in the creation of the global village without disaster by exercising the diplomatic capacity of reconciliation and goodwill of the international community to provide the connection structure to the high pressure multi-stage pump (8) installed inside the machine room.

The multistage multi-stage pump 8 connection structure of the high-pressure type formed in the nuclear power generation facility unit 811 is constructed such that the discrete multi-stage pump 8 and the high-performance submerged pump 36 are connected to the disaster prevention hose 9 of the disaster prevention nozzle 10, A pipeline 14 and a portable wireless communication terminal 82 of a multi-stage multi-stage pump system, a switch button for controlling the operation of the disaster prevention material transporting device and the pipe nozzle body, and a high pressure multi- The multi-stage pump control board 53 and the power source 46 as the power source are installed inside the multi-stage pump control box 2, and the power cable 80 is connected to the inverter 47 and a power supply unit 62 and a power cable 80 as an overcurrent breaker brake 61. The switch button is provided inside the control room and the machine room as a switch button for on / ) In close cooperation with the crew, As shown in the figure, the high-pressure isolating valve 5, the check valve 6 for preventing the backflow, and the emergency valve 84 are reciprocally operated by the piston. The plunger pump 148 is a reciprocating pump installed with a plunger for isolating the high-pressure isolating valve 5 and the check valve 6 for checking the backflow prevention. Pressure tubular multi-stage pump 8 installed in the interior of the machine room formed in the nuclear reactor main body 1 of the nuclear reactor main body 1 of the nuclear power plant having the block tank dust collector.

The disaster prevention nozzle is separated from the disaster prevention nozzle upper support frame 11, the lower support frame 11 and the vertical support frame 11 by the connection structure of the high pressure multi-stage pump 8 formed in the nuclear power plant 811 And the injection nozzle claw 13 and the hook hook 18 or the hook hook hook frame 11 and the hook hook hook engaging hole 20 are formed in order to protect the injection nozzle and the nozzle hose, The wire rope knot hooking hole 20 and the wire rope knot hooking hole 20 are used to protect the injection nozzle and the nozzle hose by being attached to each other so that the connecting hooking lug 21 and the connecting hooking lug working hole 20 or the connecting hooking safety hook shackle 23, Is used for disassembling the injection nozzle and the nozzle hose and is connected to the nozzle hose by means of the coupling 29 of the disaster prevention equipment and the evapotranspiration equipment coupling element thread body 30 and the disaster prevention equipment coupling A threaded body 31 is fabricated and a coupling seal rubber packing 32 is provided at an intermediate portion inside the female thread. Then, a paraffin stopper for a fire occurrence detection sensor is attached as a nozzle replacement to replace the packing 32, If you change the production method of existing fire extinguishing equipment to suppress the fire and flame at the time of occurrence, it will lead to the least cost or environment-friendly way in consideration of the difficulty of financing the source due to the small change due to the new production technology (8) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment which provides a technological progress. (1) A high pressure multi-stage pump (8) installed inside a machine room formed in an internal nuclear power generation facility (811) Thereby providing a connection structure.

The connection structure of the high pressure type multi-stage pump 8 formed in the nuclear power generation facility unit 811 uses the air hose 109 and the high pressure hose 190 for the air balloon 77 and the airship 78, Fire and other functions of fire protection are used for the protection of forest protection. (158) Air is generated from air compressors for disaster prevention. Cold air and hot air are always separated and separated by compressed air. Air is supplied and fixed by wire rope and frame. , An active and passive disaster prevention means of domino type is used in which the disaster prevention material is controlled by the equipment inside the body of the pump fire extinguisher body formed according to the meteorological condition, . In addition, the mixer section at the rear of the disaster prevention pump uses a carbon dioxide (174) gas cylinder 171 as a teel elbow coupling gas inlet, and the carbon dioxide evolves 15 times faster than the fire water as a powder and compressed liquid gas, A gas cylinder 171 is installed in the monohull gas supply pipe 175 to construct a pipeline line 89 at the end of a high pressure multistage multistage pump formed by the gas inlet mix mixer 191 to perform a PORT injection And the port injection method is a method of injecting an injection liquid into a blood vessel of a human body and a dual structural block tank dust collector for treatment of nuclear waste, And a connection structure is provided to a high-pressure stage multi-stage pump 8 installed inside the machine room formed in the facility unit 811.

The connection structure of the high-pressure type multi-stage pump 8 formed in the nuclear power plant 811 is applied in case of a large-scale fire incapability, but it is a general tendency to be applied to a conventional industrial site. (9) inside the disaster prevention hose (9), and then a collecting tank (34) built on the roof of a large number of mountains and a large number of large buildings together with a connecting part and an elevator (1) internal nuclear power generation facility (811) of a reactor facility main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, which is connected to a speed reducer (251) motor.

As shown in FIG. 2 (b), the pipe-type multi-stage high-pressure pump (8) of the reactor installation of the reactor plant of the nuclear power plant is equipped with a pipe nozzle type fire extinguisher It is a flow chart of the entire fire fighting equipment belonging to the inside of the center pump body. It is a flow chart showing the whole of the fire fighting equipment belonging to the inside of the center pump body, the industrial safety control room using the high pressure multi-stage pump and communication equipment using carbon dioxide and halon gas as disaster prevention materials, The carbon dioxide 174 and the halon gas 175 may be mixed with the natural earth or the loess soil 158 in appropriate proportions using the disaster prevention material carbon dioxide 174 and the halon gas 175. Alternatively, Gas and natural loess 158 are necessary for explaining the constitution in the present invention. The. The above-mentioned natural loess (158) is a reality that is used today as a ship and helicopter relief equipment for pest control by dispersing and dispersing liquid by a helicopter. Such a control activity is a phenomenon that can not prevent the work from being stopped by a hummi In addition, there is a dual structure block tank dust collector for the nuclear waste disposal that supplies the firepower disaster prevention device to the firepower power generator in the first place without the production electric power. In addition, the reactor of the nuclear power plant having the dust collector Pressure multi-stage pump 8 installed inside the machine room formed in the internal nuclear power plant 811 of the facility main body 1.

The piping body of the firefighting nozzle installed at each location of the high and low mountains, valleys, roadsides and neighboring buildings was standardized with a total length of 2100mm to be separated into 7 segments with a distance of 300mm for the multi- Nozzle Nozzle Nozzle Cutting Hole Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzle Nozzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz With The height is adjusted according to the shape of the building and the forest, and the elevation of the hose and the pipe body of the double pipe structure is adjusted to the elevation of the transportation equipment adver- tune and the unmanned airship To disrupt many disaster disasters, and as a disaster prevention and control system, air and carbon dioxide After the installation of the liquid fire water, the solid ocher powder and the fire sand, the fire pump and the air compressor were operated immediately after the detection sensor sensed the heat, and a large number of discharge jet was discharged to the outside of the pipe nozzle. Unmanned camera or mobile service to reliably extinguish flame and pillar of fireworks, display of score on monitor by calculation of control server of multi-stage pump control system received from mobile phone terminal Firefighting with firefighting equipment The pipe nozzle of the sensor pump is fixed to the roof of each corner and the building roof of each spot, and the disaster prevention material mixed with the liquid and the gas solidly on the valley or the beach road is firstly fired In a period of 1 second, the incombustible gas (Oxygen) to prevent the combustion by preventing the combustion of air and oxygen (combustion) to reduce the temperature of the combustion to below the temperature of the cooling function and the hose as a cooling effect to put water with the early evolution of the life saving No-accident fire prevention sensor pump that guarantees life-saving structure and early evolution from seasonal fire and large-scale fire is surely installed Fire damage sensor A double structure block tank for supplying electric power to the pump tank reactor main body 1 of a nuclear power plant having a dust collector a high pressure multi-stage pump installed inside a machine room formed in an internal nuclear power plant 811 8).

The fire-fighting nozzle formed by the double pipe structure which supplies a lot of disaster prevention materials is installed in the water supply piping line of the water supply water pump of the water supply construction of the former water supply corporation and the neighboring living place where the building with the lower mountain is located, In order to keep the line from being extended, and to go further, sleeping, sleeping, and sleeping so that the forest fire does not evolve, the air tubing is added together with the water piping line by combining it with the weather forecast. In order to use the correction tank equipment efficiently, it is necessary to connect the air compressor, the high-performance submersible pump and the multi-stage pump electronic control unit and the portable wireless communication terminal to the wireless communication device, A system for enabling a disaster, It is about disaster prevention method and disaster prevention means to prevent disaster loss which flies like a snowball more quickly by judging dan more quickly, and furthermore how to control disaster through Internet. Fire hose connection port before and after the fire without the personnel approaching. Connection of the male and female hose connections. Piping nozzle is connected to the hose connection node. Nozzle fire prevention sensor pipe which is longer than the previous evolution hose used. (1) a reactor structure main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment provided with an air tube type collecting tank having a double pipe structure for rapidly accelerating the lifespan and the initial evolution by the fire fighting / ) The high-pressure (low-pressure) high-pressure And the type multistage pump (8) provide a connection structure.

In order to cope with the sudden occurrence of frequent occurrences without distinction of day and night, the large fire and large fire are not caused by the advance notice. For disposal of nuclear waste to set up a hydraulic pump capable of pumping up to 50 times of free fall by using the water hammer action to make the forest fire evolve within 1 second by the membrane pump (diaphragm pump) Pressure tubular multi-stage pump 8 installed in the interior of a machine room formed in an internal nuclear power plant 811 of a reactor facility main body 1 of a nuclear power plant having a dual structure block tank dust collector.

The previous large-sized fire is delayed due to the delay of dispatch of the fire-fighting vehicle according to the circumstances of the residential living area. As a result, the small fire spreads and the fire pillar becomes large, resulting in a large fire. In such a large area of the neighboring living area, there is a considerable difficulty in entering the fire truck into the production plant and the market. In this case, the fire is generated at the bottom of the building, and the toxic gas- In order to solve this problem, it is a sad situation that gas leakage is caused due to gas choking caused by a fire caused by gas infiltration into the upper floor of a residential area through a one-way passage. It is possible to prevent a large-scale disaster of a large number of water films ejected through a plurality of nozzle gaps of

As described above, fire extinguishment in this way is the same as that in the fire-fighting house, because fire-fighting vehicles are usually dispatched after the previous fire, . The apparatus of the non-emergency pump extinguisher for the early evolution and lifesaving of the large-sized fire according to the present invention comprises a nozzle body (B) for use in accordance with the specifications of the fire hose name used in the standard firefighter window specification, ) Are precisely standardized on the joint nozzle so as to form a basic 1-type and a basic 2-type

The above-mentioned initial ignition sources were ignited by fire, fire and fire due to friction of light flame, fire of lightning, and fire of flint among fireplace park, match fire and candle A large fire is caused by the generation of flame material. At the same time, a large fire is a public building of a building in a commercial building, a wooden building, and fire suppression within a range of a fire belonging to a kind of fire. In order to ensure the early evolution and to guarantee the life structure, it is necessary to precisely set the open / close position and the open / close position of the multiple open / close nozzles at each ignition site so that there is no damage to human life. Is set as follows

A fire such as the above-mentioned building A fire usually causes fire of general combustible materials such as wood (forest) and paper (fiber) to be high, low mountains, thorny bush of grassland, grass, The best way to prevent the fire is to fire the cable car arocarbons and ocher powder on the top of the machine room and on the mountain top of the large building. It mixes with the fire water in the field and surrounds the combustible with combustible gas within 1 second so as not to escape from the safe area of the fire. Painting section) The natural swamp composition was formed at the disaster prevention channel of the ridge line.

In this way, the dislodged material and the ignition material are accurately set to the closing position where the antagonistic relationship is terminated and the stiffness relationship is maintained so as to suppress ignition of the ignition material.

The large-sized fire is limited to occur in a vast and wide area of neighborhood life without prior notice, and due to the diversification of frequency of occurrence outside the closed space,

In the fire fighting and fire fighting equipment system, which is mobilized by the ignition source providing material and the substance for suppressing the ignition, as described above, various tube nozzle holes are installed in the building and the exterior to the inside with a large number of obstacles, Paraffin sensor used as a detection sensor for active disaster prevention and active disaster prevention equipment Nuclear waste disposal to provide installation of pipe nozzle to the outside of water tank of double pipe structure at the position where many pipe nozzle holes are formed by paraffin stopper of pipe nozzle (1) of a nuclear power plant having a dual structure block tank dust collector.

As shown in FIG. 2 (b), the problems of the prior art are improved in the high-pressure multi-stage multi-stage pump (8) installation structure of the distribution apparatus of the reactor plant of the nuclear power plant. However, In the event of fire, before and after the occurrence of the fire, all communications equipment of the Internet control system, the multi-stage pump and the pump electronic control unit, and the air storage tank of the air compressor and the wire rope of the air compressor It is possible to quickly and accurately mix piping nozzles with solid nozzle nozzles and mix them with liquid and solid disaster prevention materials by mixing the facilities including the fire fighting disaster prevention countermeasure fire fighting equipment formed on the cable car body, As the pipe nozzle is changed, the gap between the nozzle of the radiation type and the gap formed by the straight gap is partitioned The fire water is separated into a plurality of radiological curtain water films and a plurality of linear straight curtain water films by nozzles and then discharged or ejected, and the gas which is generated in the case of fire is discharged from the dioxins and flame materials, It has evolved within one second from forest fires and large fires, resolved the priority of life-saving, prepared for floods and droughts, set up thorough measures to prevent landslides and roads, and distributed the distribution of nuclear facilities It is designed to eliminate many disasters at the same time by means of input devices. At the same time, it is necessary to calmly cope with the crisis and to overcome the disasters of the earth. Paraffin sensor installed in fire-fighting nozzle The fire sensor installed in the mountains and the building to prevent fire. The fire pump installed in the marine to prevent the disasters from occurring in the world. 591) Nuclear waste disposal at the bottom of the Otaei Daejangju Double Structure Block Tank Marine Tunnel Traffic System (941) In the station where the electric train (771) is installed, a number of fire fighting equipment for each type of fire is installed in the double structure block tank And installed in the nuclear reactor main body 1 of the nuclear power plant having the dust collector.

The pipe-nozzle type fire-fighting sensor pump of the non-emergency fire fighting and disinfection countermeasure product for the marine power plant is provided with an electric motor body inside the fire-fighting sensor pump and a center portion circle of a shaft, which is a motor center shaft formed on the horizontal center line (MBCL) The impeller which is a rotating body to the surface portion, a piston attached to a guide vane pump on both sides of the impeller, and a prime mover pump which is assembled to be detachable from the turbine. The pump body is provided with an isolation valve and a check valve, Flow control sensor that adjusts the direction control automatically and sensor switch that controls gas, liquid and solid in the pressure sensor and controls the flow inside the pipe. Power cable that supplies power energy and A fuse suitable for fire It can be used as a flammable gas such as fire water, loess, fireproof gas, carbon dioxide gas, carbon dioxide halon gas The tank is installed in a high-pressure tank and a collection tank in a closed tank and an open-flow type plastic bag or a tent tent. The nozzle of the nozzle is moved in the form of a moving boat for disaster prevention, Sensor pump installation is done

The tube nozzle moving type is divided into a basic type 1 and a basic type 2 according to a standard fire hose standard. A flange joint is formed by a firepipe nozzle and a coupling joint firepipe nozzle. The pipe nozzle is connected to a fire cable car, It is separated into a fixed fire-fighting nozzle fixed at 50m distance of installation with the same angle of inclination of the ridge of each corner at the bottom of the normal mountain range (GLL). At this time, High and low building in the beach near the seaside beach Build up a fire tower for firefighting cable car at each point of the rooftop and nearby mountain peaks, fix it with an anchor bolt by a hand tool, And the pylons were installed, and the top of the pylon was erected and the top of the tower was erected. A firefighter nozzle connected to a fire hose connection node of a disaster prevention material transfer device mounted on the firefighting cable car, a mobile firefighter nozzle having a plurality of pipe nozzle holes formed on the circumference of the pipe body, After receiving the power source generated from the generator through a power supply line of a transformer and a telephone pole connected by a plurality of electric wires, each pump motor motor and each compressor motor motor receives rotational power of the angular accelerator by sensor detection of each solenoid valve The impeller or the piston is used as a plunger pump to return the fire water to the top of the high acid and the backwash water is returned to the top of the high acid by the non-powered pump without receiving the power supply from the generator or the engine generator of the power plant, There is an appropriate level of normal fire such as buildings belonging to different types of fire Nuclear power plants with a double structure block tank dust collector for treating nuclear wastes that evolve early and evacuate lives in the wood, forest, and paper with fire and flaming pellets in less than one second ) Is an equipment formed in the internal nuclear power plant 811.

As shown in FIG. 2 (b), the high-pressure multi-stage multi-stage pump (8) for connecting the distributing and loading apparatus of the reactor plant of the nuclear power plant has a plurality of fire- A multi-pipe hose formed by a tank, and an electronic heat sensing sensor and a flow control valve, a manometer-level hose provided with an air compressor in a piping nozzle and installed in a fire disaster prevention piping line, and a fire- And the number of discharging water droplets and the number of curtain water films surrounded by the flammable gas together with the incombustible gas to block the supply of air to prevent the combustion and the cooling action to lower the temperature of the combustible material to the temperature below the ignition point are performed in the fire hose pipe processing The above-mentioned cooling action fire-fighting method which puts muddy water ejected to the space between the holes is a method in which, at the beginning of the fire, The above-mentioned adverbons and airships, which are designed to evacuate the refugees to the firefighting cable car security area by dispersing the load of the body of the fire sensor pump body, ensure the safety of the pump body, (Standard point) is set as one point of the triangular boundary line of the iron, which is the ceiling line of the silence, and then the standard point is set. In the land of the ancient ancestor and the territorial sea of the silent descendants in the land of 2400km diameter to the east, west and north of Kangsu Kangshan, the primary non-motorized pump of the multi- Nuclear power plant with double structure block tank dust collector for nuclear waste disposal providing turn-type fire-fighting nozzle and fire-fighting piping line And is formed in the nuclear reactor main body 1 of the nuclear reactor facility 811.

In the following description, the same reference numerals are applied to the same formation as in the drawings, and the present inventor emphasizes that the pipe nozzle moving type fire pump sensor pump is not limited to fire prevention according to the type of A fire, B fire and C fire. The fire sensor pump of this nuclear power plant (811) was first coated with vinyl coating on KSD 3507 general piping rolled steel, and connected with nozzle body by KSD 2331 aluminum alloy for die casting. Plasma flow tube or KSD 3699 hot rolled stainless steel coil. The temperature sensor is replaced with a bimetal or bourdon tube to paraffin sensor type. It is used for diesel engine, fire pump, solenoid solenoid valve and other Standardized general purpose hose pipes are equipped with a double pipe structure type of liquid and gas The sizes of the pipe nozzles to be supplied to the city are classified into seven types according to the types of fire hose connection types: "Tubular Nozzle 1" Diameter of 200 mm, 180 mm, 150 mm, 130 mm, 100 mm, 80 mm, (150x150) mm, (150x130) mm, (130x100) mm, (100x80) mm, (80x50) It is formed by the tube nozzle connected to the hose connection part and the tube nozzle of the multiple straight line type crevice hole, so that it can be used as a demilitarized zone in building, Has evolved from fire and forest fire of general combustible materials such as wood, forest, paper and duvets such as buildings belonging to different fire classifications or large fire of neighboring living area, With this many adverbons and airships, , And at the same time, the center line of the center line of the triangular barriers of the Demilitarized Zone, which was intended to destroy many disaster disasters, was established. Nuclear Power Plant's reactor main body with a double structure block tank dust collector for nuclear waste disposal that ensures the installation position in multi-tiered form and allows the installation location to be determined beyond the border line of the non-disaster global village that ensures the peaceful coexistence of Northeast Asia 1) The equipment formed in the internal nuclear power generation facility 811 makes the configuration of the internal nuclear power generation facility 811 of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste reasonable.

The hose 9 and the piping 14 which are processed into a plurality of double pipe structures in the inside of the fire sensor pump body of the nuclear reactor main body 811 of the reactor facility main body 1 of the nuclear power plant and the injection nozzle 10 gap 15 and the processing hole 20 of the nozzle 10 are 300 mm in the distance of one body of the pipe 14 so that the bolts 24 and the nuts 25 in the total number of 7 are filled with the washer 26, And a plurality of processing holes 20 having a diameter of 5 mm or less are provided along the circumference of the pipe in the form of a cylindrical body of the pipe body. There are 498 total machining hole gaps. The injection nozzle body (B) has a multi- The two flanges 28 attached to the main body of the injection nozzle body A are connected to a single pipe which is a pipe body with eight machining holes at a predetermined inclination angle 16 of 45 degrees, (28) A stopper plate (165) is attached to the upper end (A) of the flange (28) by a stopper cap disk (165) The stopper cap 165 is disposed under the flange of the lower end A of the body so that carbon dioxide 174, halon gas 175, helium 176, fuel 131, The body 29 of the coupling 29 to the center position is inserted into the through hole 20 in which the small water tube 29 of the fire hose and the wire rope 19 are formed inside the coupling body 30 and the coupling body The wire rope 19 formed by a pumping pipe 89 for supplying the above-mentioned disaster prevention material, which is standardized to have a total length of 2100 mm and a total length of 7 mm, which is detachably assembled by a hand tool monkey spanner, And is bound to the inside of the fire hose 9

After the fuel piping line and the gas disposal material piping line are united together with the piping line of the liquid, the fire-fighting nozzle 10, which calls the nozzle formed of the pipe nozzle and the piping body in an orderly double- A spray nozzle body (B) detachably assembled to a nozzle body upper end portion (C) above a lower end portion of the body and a lower end portion (C) of the nozzle body; 2500 mm × 2500 mm × 2000 mm, which is made of a wire rope or a rope, is installed. Inside the basket 42, fuel supplied from the gas fuel supply pipe line is supplied to the ground or burner 173 ) Is adhered to the lower part of a vinyl tent (77) of an adverb (a cross-length × length × diameter: 10M × 10M × 10M, formed in a double structure in a circular shape), and a gas burner 173 for cooking used at this time is connected to an unmanned igniter 187 are installed and wrapped around the outer circumferential surface of the adobe with the wire rope 19 or the rope 131 and bound to the lower part of the adobe together with the rope 131 and then the unmanned camera 184 A radiosonde 134 as a meteorological observation device for observing the diurnal state of the farther farther from a higher position is mounted and the lower part of the injection nozzle body B is connected to the lower end of the integral multi- A multi-stage pump 8 as a device of the electronic control unit 8, a disaster prevention pipe line 89, a disaster prevention waterway 17, a double tube structure collecting tank 34, a fire fighting unit 40, A plurality of valves and an air compressor 80 for interrupting the flow of the microcomputer system, the communication equipment system and the piping internal flow rate, the generator 124, the engine 144, the air cylinder 138 formed in the doctor ventilation, An air trowel winch 137, a combined life-structure bed The iron structure 143 and the pump inner impeller 143 are connected to the nozzle 172, the hydrant 179, the grid drive 185, the air tube 188, the head tank 189 and the high pressure hose 190, The entire area where the pyrotechnic material and other gases such as the flue gas 292, the flame 293 and the pyrethrum 294 are generated is referred to as a fire sensor pump body and the reactor facility main body 1 of the nuclear power plant, Inside the nuclear power plant (811), the whole equipment of the fire-fighting and disaster prevention industrial goods necessary for the entire life span and the early evolution is included.

The fire-fighting nozzle 10 used as a plurality of pipe nozzles of the nuclear power plant 811 inside the reactor facility main body 1 of the nuclear power plant is made of KSD 3507, KSD 2331 and KSD 3699, In the case of the 7-bar basic type 1, when the nozzle is vertically installed at a height of more than the height of the main body, the nozzle joint portion is set in 7 stages. The basic 1-type nozzle is referred to as "nominal 100" (234), "nominal 90" The fire-fighting nozzle 10 is divided into the "name 50" 238, the "name 40" 239, and the "name 25" 240 separated by "name 75" 236 and "name 65" The pipe nozzle (10) is attached to a plurality of fire-fighting disaster prevention piping lines (168) formed along the mountainous mountain range and formed on the elbow or tee elbow (44). The pipeline (diameter: φ350 mm, Quot; 50 x 40 "to the " nominal 100 x 9" 241, the " nominal 90 x 75 "242, the " nominal 75 x 65" 243, (245) and " When a firefighter nozzle is formed at a position higher than that of the basic type 1 by 40 x 25 '' (246), the tip of the spray nozzle is positioned at the uppermost position of the spray nozzle A plurality of 8-joint gap 15 machining holes 20 are formed in the joint between the flange 28 and the flange 28 to form an 8-nozzle gap therebetween and connected to the joint at the lower end of the flange 28 when the 50- The nozzle 10 is fastened to the shale 23 and the bolt 24 so as not to be temporarily detached from the shale 23 and the bolt 24 with the nut 25 at two places of the tee elbow 44, After connecting the rope to the upper part of the body, pull it from both sides of the shackle (23) opposite to the binding position and disassemble the rope (137) after the bolting work. However, the worker should go up to the height of the poles, By using the spur winch 137, The firefighter nozzle 10 is provided with a plurality of firefighting nozzles 10 attached to a 15 m firefighting hose and connected to a plurality of firefighting nozzles 10 to form a length of 1 km, (1) of the nuclear reactor plant (1) of the nuclear power plant.

The head tank 189 of the nuclear power generation facility unit 811, the solenoid valve 76, the fire water 7, the loam 158 and the arsonization chamber 159 of the nuclear reactor facility main body 1 of the nuclear power plant, A power source 46 as a unitary power source for the pump control system 150, a high-pressure multi-stage pump control box 2, a high-pressure multi-stage pump control box 2, A switch button 66 for operating the pump on the wire rope 19 to the control board 53 inside the control box and the power supply unit 62 to the control server 51 and the control server 51, The radio communication antenna 54 and the portable communication terminal 82 are connected to the collecting tank 34 serving as a storage tank, the piping connection connecting adjunct 35 and the high-performance submersible pump 36, A plastic bag 43 and a hooking lug 18 are attached to the computer network input 68 and the elbow or tee elbow 44 connected to the disaster prevention pipe and the monitor 52, Apparatus in which the brakes (61) installation is conventional soy and accompanied.

The spiral casing 141 and the impeller 143 are provided in the guide vane 142 as a protection cover for the body of a plurality of the pump 8 of the nuclear power generation facility 811 inside the reactor facility body 1 of the nuclear power plant, The type and characteristics of the pump attached to the central axis of the rotating shaft 198 of the body 192 and the countermeasures against the main problems during the driving of the pump and the calculation of the pump according to the existing selection of the pump, , The pump shaft device, the countermeasures against the vibration of the pump, and the handling of compressors to compress the gas. It is a fire-fighting and disaster prevention countermeasure device that is formed on the body of the offshore power plant. Explain as follows.

As described above, in the inside of the nuclear reactor facility main body 1 of the nuclear power plant, there are provided a plurality of fire hose 9 and the pipe body 14 in the nuclear power generation facility 811, A paraffin tape 177 for a fire detection sensor and a nozzle stopper 100 for connecting a paraffin type pipe jointing nozzle with a processing hole 20 are formed by a combination of high and low mountains 395, (333) Roof rope (19) Fire cable cable (256) type No-accident fire prevention disaster prevention article pipe nozzle Movable type fire sensor After installing the pump, When a fire in a wooden building (332) and a forest (266) of a fire occurs, a fire of a general combustible material such as paper and a duvet is generated. In the past, a fire engine such as a helicopter and a fire truck started to fire with a siren, A streetcar The fire helicopter in the mountain and the obstacle such as the parking lot of the car is revived again at the moment when the helicopter is turned on and off to carry the fire water, and the digestion activity of the fire scene is disputed for a moment. In order to solve the danger of losing to life in an imminent situation, the pipe-nozzle-type fire-extinguishing sensor pump, which provides a simple initial evolution just before the start of a fire or a helicopter, (1) Inside is the nuclear power plant (811) fire fighting system.

The hose 9 of the sensor pump 811 of the nuclear power plant 811 and the plurality of the non-hazardous paraffin nozzle plugs 100 and the paraffin tape 177 formed inside the nozzle body 10 are installed inside the reactor facility body 1 of the nuclear power plant Closed multi-pipe nozzles Opening the crevice hole Fire heat sensor Paraffin burning flame and flame on ignition object due to match fire (166) and detection of low temperature of candle can not easily spread to large fire, The inventive non-hazardous-pipe nozzle-moving type fire-fighting sensor pump of the present invention is a fire extinguishing material of the pump fire extinguisher 124e to the acid alkali fire extinguisher 124b and the foam fire extinguisher 124b adapted to A fire, It is a non-flammable gas of non-combustible gas that surrounds combustible material to block the supply of air (oxygen) to prevent combustion, and to reduce the temperature of combustible material to below the ignition point. It is a fire extinguishing fire extinguisher that can guarantee the rescue and early evolution from large-scale fire and large fire caused by the seasons. It is a pipe fire extinguisher The air circulation pump 124 is connected to the membrane pump 144 and the air compressor 80 through the hopper 73, which is a mixer, into the water collection tank 34 through the fire water 7 and the loess 158, Is formed by a fire device of the intercooler (170).

The ignition object 166 of the nuclear power generation facility unit 811 is burned into the nuclear reactor facility main body 1 of the nuclear power plant while being stored inside the fire fighting nozzle nozzle body together with the fire water whose internal pressure of the fire hose is held, The incombustible gas 164 is stored and discharged to the outside of the fire extinguisher body at the same time so that the fire ejection water 38 and the curtain water film 39 are burned in a plurality of openings 294 in the gap 15 of the fire- When this is removed at the moment of departure, this scene is transmitted to the unmanned camera 184 installed at the height of the telephone pole around the fire scene, and the information detection function of the pump control server 51 of the multi-stage multi- The characteristics of the microcomputer control of the pump 8, which is configured to display the state of the fire at the time of the fire on the monitor 52, include a digital control method, an inverter 47 speed control method and an algebraic control method Chiyida.

The configuration of the multi-stage pump 8 is as follows.

Multistage Pump Specification

Details of the control method of such a three-stage multi-stage pump system are as follows.

· Pressure control method (Figure 1)

The operating range of the system is formed from the operating point (Pon) of all the pumps to the operating stop point (Poff1) of the maximum load operation pump and the operation stop point (Poff2) of the law firm. After the operation stop point of Poff2 of the pressure control type system is reached, it stops completely after the minimum operation between 180 seconds to 210 seconds (CO-CR) and 0 to 120 seconds (CO-ER). Although the width of ΔP can not be kept narrower than the inverter control method, it is mainly used for absorption pressure of the low layer by detecting input change of about 1 bar.

· Frequency modulation control decoration (Figure 2)

The operating range of the system maintains the adjustment value range.

When the flow rate of each operating pump reaches 100%, and the pressure of the operation standby pump is the operating point Pon and the pressure of the individual maximum operation pump is the stop point Poff before stopping.

Therefore, the frequency modulation method can maintain the narrow width of ΔP and control the rotation speed of the main pump with the frequency modulator, so that the system compensates the sudden pressure change occurring when the operation standby pump is in operation or when the operation pump is stopped do.

When the pressure of the system is lowered to the vicinity of the operating point, the main pump is slowly operated by the frequency modulator control, and if there is no change in the flow rate, the controller stops the pressure fluctuation due to the system hunting.

The details of the main functions of the three-stage multi-stage pump will be described as follows.

As described above, in the multi-stage pump of the present invention, the main function is described in detail inside the body of the pump-like gap type pump fire extinguisher, which is a urinal part, which is an urinal part, so that anyone can easily pumped without being close to the fire scene or near the pump machine when a fire occurs. (At the time of going to bed), as a result of the structure of the present invention, the fire-fighting helicopter of the fire-fighting vehicle according to the life structure and the advance prevention is made to evolve within one second before the arrival of the fire scene. At the same time, the distributing and loading device connecting structure of the reactor installation of the nuclear power plant is provided with the pressure tank 189, the collecting tank 34, Inverter 47 and the associated line relationship of the control inverter 47 and the collecting tank 34, The suction port 269 is formed in such a manner that the air shutoff prevention device 271 and the check valves of the respective pumps can be controlled to be fully closed and expanded by the inverter 47, The pressure tank 189 and the control unit inverter 47 are connected to the discharge confluence pipe 5 after the mounting position is clearly set in front of the separation valve 8 and the isolation valve (Isolating Vavle, Ballo-2 Butterfly 5) Which is a discharge port 270, is controlled by a first pressure check sensor 86 as a discharge pressure check sensor and an overpressure prevention switch 108 as an integral part of the second pressure check sensor 87 on the line (4) A plurality of fire nozzles 10 injects loess 158 into the mixer 73 so that each fire A is cooled and suffocated within one second with a fire within a second. Residential firefighting cable car (25 6) is formed by a plurality of high and low mountain peaks and a plurality of buildings having different height. Each of the plurality of fire hoses (9) is connected to a safety net (hose of a net including a wire rope of a cross shape or a well- ) Type hose 9 is a technical feature.

As shown in FIG. 2V, according to the configuration of the multi-stage pump operation mode of the control block diagram and the VFM model, the control power source 273 is separately divided into the pump power source 272 and the control power source 273 is operated in an emergency The sequence circuit 274 is brought into contact with the output circuit end of the (M / C) drive signal contact output circuit 279 of the DC power supply supply circuit 275, The microcontrol unit 276 is connected to the microcontroller 276 by a decoupling power supply circuit 275 of the control power supply 273 so that the microcontroller 276 is contact- A setting circuit 277 and a switch input circuit 58 are input to the unit 276 and signals L and D are supplied to the LED display circuit 278 and the M / C drive signal contact output circuit 279, And the motor overload signal input circuit 280 is connected to the unit 276 and the pump &lt; RTI ID = 0.0 &gt; (MCCB + THR) and (MCCB) circuit contacts are connected to the contacts of the inverter 47 and the inverter operation data input / output circuit 281 is connected to the inverter 47 circuit and the microcontroller unit 276, And a discharge pressure transmitter (transmitter) 284 is connected to the pressure sensing circuit 282 so that the circuit 282 is again set to be input to the unit 276, The pressure switch 285 is input to the microcontrol unit 276 via the external state input circuit 283 and then inputted to the microcontroller 276 again. (2) Nuclear power plant with dual structure block tank dust collector for treatment of nuclear waste (1) It is the equipment to be formed in internal nuclear power plant (811).

The impeller 143 is coupled to the motor shaft 198 so that a predetermined amount of the disaster prevention material, which is formed by the impeller 143, is introduced into the spiral casing 310 of the plurality of can pump bodies, A plurality of fire fighting and disinfecting piping lines 168 of a predetermined amount of fire fighting water 7 transferring device and a left and right side head tank 189 for compressing and storing the water pressure of the inflowing fire water 7, A collecting tank 34 having a double structure in which disaster prevention waterways 17 of a certain standard are installed at intervals of a predetermined distance from the disaster prevention waterway 17 at constant inclination angles 16, A fillet tap 499 as a sensing sensor which senses the level of the flammable water inside the correction tank 34 and a flange stopper for the plug filter 269 for blocking the inflow of foreign substances into the condensate tank 34. [ (28), a switch button- A plurality of solenoid valves 76 which are closed at the time of the switch button turn-off and a plurality of solenoid valves 76 connected to the tee elbow 44 of the binding apparatus so that the disaster prevention material carbon dioxide 164 and the halon gas 175 are introduced into the rear of the head tank 189 And a mixer (hopper) 73 for mixing the disaster prevention material carbon dioxide 164 and the natural loamy soil 158. The low pressure shutoff valve 83 is connected to the disaster prevention piping 14, The multifunctional piping 14 is connected to the flange 28 of the discharge pipe 35 and the discharge pipe 35. The discharge pipe 14 is connected to the discharge pipe 35 through the flange 28, And a gap 15 between a plurality of flange 28 junctions formed between the processing hole 20 and a gap 15 around a plurality of pipe circumferences connected to the nozzle hose 9. [

In this way, the fire water 7 has the shape of the jet ejection 38 (380) of 490 circular dots or the shape of the curtain water film 39, and the eight water films at the higher and higher positions are flushed by the buoyancy of the adevolunes 77 and the airships 78 The life of the facility is extended by dispersing the body load of the cable car (256). After the safety is secured, the mixture of the loess is ejected to the pipe nozzle (10), causing disasters such as forest fires and large fires inside and outside the building The pump is a non-powered pump (393) that can be pumped up to about 50 times as much as the freezing pump due to the movement of the fluid, which is preheated at a time before and after 1 second. The air compressor And a two-stage squeegee air compressor 80 in which heat is dispersed to the oil cooler 157 without an intercooler 170 and an aftercooler 182 are integrally connected to each other through a suction port 269 and a discharge port (270) Which is installed in the air tub 730 formed by the fire extinguisher 710 and the bed jacket 172 of the lifesaving structure, The check valve 6 is provided so that the fluid can be movably transferred to the pressure tank (high-pressure bowl tank 303) inside the non-powered pump 393 so that the fluid can be transferred to the control valve 50 times as much as the drop. And an isolation valve (5), and the function of a plurality of expansion and full functions is ensured in the interior of the marine power plant body Double structure block tank for nuclear waste disposal provided as a system connection device for valves classified as flow control valves in valves and directional control valves Nuclear power plant reactor main body with a dust collector (1) Internal nuclear power plant (81 1).

As shown in FIG. 2V, a first pressure check sensor (not shown) installed in front of the isolation valve 5 as described above is installed in the high-pressure multi-stage pump 8 facility of the distribution and input device of the reactor installation of the nuclear power plant, 86);

A second pressure check sensor (87) installed integrally with the pressure reducing valve;

A bypass disruption piping line (168) installed to bypass the isolation valve (5) by connecting the front and rear sides of the isolation valve (5) and bypassing the isolation valve (5);

An emergency valve (84) installed in the bypass pipe line (168) so as to open and close as opposed to the isolation valve (5);

An electronic control unit (88) integrally controlling the operation of the emergency valve (84) by checking a pressure value from the first pressure check sensor (86) and the second pressure check sensor (87);

The solenoid valve 76 at the joint portion of the intake manifold 3 flange 28 at the upper end of the ground surface at the lower end of the stage multi-stage pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine chamber, Discharge water quantity is sensed by a counter 499 which is a water level sensor and is connected to an air hose 109 installed inside the nozzle hose 9 and a socket air- And an engine generator 226 at the upper part of the inside of the machine room for driving the airship 78 to the upper end of the surface of the ground are operated to supply power to the power source (not shown) 46 to the power motor control module 106 of the air compressor 80 so that the air generated by the operation of the air compressor 80 is stored in the air compressor high pressure storage tank 145 at a constant pressure Air receiver before disaster Storage tank 145. As the interior of the air pressure is constant disaster emergency air pipe line 181, the emergency valve (84) is formed after development to bring the air into the building is attached to the outer pipe frame of a building

Therefore, when the air balloon is lifted up to the top of the upper surface of the surface of the outdoor building so that air is stored in the rubber tubes of a plurality of container sizes and at the same time the life structure is formed, It is installed in fire-fighters nozzles as a whole with equipment for manufacturing and installing facilities and lifesaving means. It is installed in mountains and buildings with a parapet sensor nozzle stopper (100). It is used for fire prevention purposes. In case of disasters other than that, it is extended to the fire fence (40) and fire hydrant (179) The air pipe line 181 is connected to each of the pumps and each valve, 56 are constructed such that the flame 293 and the pillar 294 are simply annihilated and removed in less than one second by using a pump extinguisher 124.

Referring to FIG. 2w, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention, Partial strapless configuration diagrams of compressors moving compressors, stationary compressors and multi-stage screw compressors, as well as operating configuration of the front section for fixing underground anchor bolts,

As shown in FIG. 2w, the distributing and inputting device for the reactor installation of the nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant is provided with a multi- The solenoid valve 76 at the joint portion of the flange 28 of the lower end road surface upper surface suction confluent pipe 3 of the pump 8 and the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine room are connected to the fire- An air hose 109 installed inside the nozzle hose 9 and an air nipple 110 for a socket connected to the air hose 109 at a connection portion, And a diesel engine generator 268 at the upper part of the inside of the machine room for driving the airship 78 to the upper end of the surface of the ground are operated and the power source 46 ) The air generated by the operation of the electric motor 192 of the prime mover 80 supplied to the motor control module 106 of the synchronous motor 80 is supplied to the receiver high pressure storage tank 145 before the occurrence of the disaster Air pressure is constantly maintained in the receiver high pressure storage tank 145. At the same time, when a disaster occurs, the emergency valve 84 of the disaster prevention air piping line 181 is expanded, air is blown into the building, The pressure gauge 101 and the pressure switch 104 are provided with the overpressure prevention switch box 108 of the motor control module 106 and the crank 248 and the linkage 249, A safety operation is provided while connecting the wheel 250 and the V-belt 252 included in the speed reducer 251 to the prime mover 80 and the motor 192 to which the knob handle, the piston 127 and the cylinder 126 are attached At the same time, the belt cover 261 is moved to the feeder 250, A suction filter 262 installed on the circumference of the V-belt 252 to adjust the rotational speed of the prime mover 80 and to attract foreign substances to the air inlet 269 to the upper end of the compressor main body 263, The piston 127 of the main body 263 and the air discharge port 270 to which the cylinder 126 is attached are connected to the receiver high pressure storage tank 145 and are connected to the high pressure storage tank 145 at 6 kg per 1 cm 2 of air pressure When pressure is applied, the pressure gauge 101 and the pressure switch 104 connected to the safety valve 258 cut off the operation of the electric motor 192 and when the pressure in the high-pressure storage tank 145 falls below 6 kg per 1 cm 2 of air pressure, Pressure reservoir tank 145 is provided with an air valve 257 and a drain valve 60 at the automatic valve 259 while simultaneously operating the air hose 109 and the air hose connection device nipple 110 ) And the piston is reciprocally operated simultaneously Stage type screw cooler 147 in which heat is dispersed to the oil cooler 157 without the internal cooler 170 and the after cooler 182. The inlet port 269 and the outlet port 269 are connected to each other by a connecting device, And the disposal adjustment devices of the nuclear facility tubing 130, the basket 42, the bed nozzle 172 combined with the lifesaving structure, and the distribution and input devices of the reactor facility of the nuclear power plant, Nuclear reactor facility of power plant (1) Nuclear power plant's reactor facilities consist of connection structures of hydrological control regulator of dam of internal nuclear power plant (811).

As shown in FIG. 2w, the distributing and inputting device of the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a collecting tank (width × length × A plurality of disaster prevention pipes (not shown) connected directly to the disaster prevention water passage 17 and connected to the lower portion of the tank 34 are provided in the intake port 269 of the cement cone type with a height of 10M x 10M x 1M, Line (168) pulls overflowing valleys and immediately floods the floods to the Sea of the East Sea and the Sea of West Sea of the South Sea to the artificial waterfalls like the waterfall of Jeongbang, which is a natural waterfall of Jeju Island. In this case, the air compressor (80) and the diaphragm pump (144) are operated at the same time so that the valley water is not flooded. (43) was installed in the area of disaster prevention as appropriate for the case of 150mm or 300mm rainfall per hour, despite the fact that the damage was restored. In order to reduce the landslide damage, the double vinyl (43) However, even if the trenches are lost and the bridges are cut off and the other side of the valley is followed by the resettlement of the refugees, there will be a tug-of-war (139) in the valley to rescue the refugees isolated in the mountain valley. (1) The single-pipe small-sized pipe is formed in the bottom of the valley with a diameter of 100 mm and a length of 10M or less, and then the single- After installing it in such a way as to allow passage of fish, the plastic bag (size: length × length: 49kg, 60mm × 1M, firewood and loess, 180) After having been laid on the upper part of the bag 180 to a size of 200 mm in diameter and 7 m in length or less, the bag was again packed with the gravel and sand in the upper part of the middle pipe, A large-diameter pipe with a diameter of 300 mm or more and a length of 5 M is formed thereon, and a wire netting 139 formed of a net-like wire rope 19 is covered in each stepwise layer unit, and then a sharp- 185) or an O-ring bolt (204) and an anchor bolt (133) are installed, the knot is attached to the torpedo so that it can not be floated on the rapids. (It is recognized that there is no disaster when there are a lot of pine trees in the mountain fire prevention condition of the present invention).

Referring to FIG. 2x, a conventional structure of a nuclear reactor power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is shown in FIG. A gear drive 290 in which a tank is adhered, and a squeegee compressor connected to the motor.

As shown in FIG. 2x, the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant composed of the above- The apparatus for dispensing the nuclear reactor facility of the present invention includes a gear train 290 to which an oil separation tank 288 of a conventional nuclear power generation facility unit 811 is attached to prevent disaster prevention and control, And is connected to the air intake port 269 of the receiver high pressure storage tank 145 by disassembly and assembling with the inlet valve 263 and the suction valve 289 so that the distribution input devices of the nuclear power generation facility can be connected to the water inlet port 269 of the receiver high pressure storage tank 145, To be able to adjust the angle of view.

Referring to FIG. 2 (a) and FIG. 2 (b), a rear structure of a conventional nuclear waste disposal system for nuclear waste processing according to the present invention is shown in FIG. The suction filter 262 attached inside the air dryer and the suction filter attached to the inside of the air dryer 291,

As shown in FIG. 2 (a), a distributing and inputting device for a reactor installation of a nuclear power plant constituting the internal nuclear power generating facility 811 of the reactor facility main body 1 of the nuclear power plant includes a nuclear power plant The apparatus for dispensing the nuclear reactor facility is provided with a suction filter 262 and a drier 291 which are installed inside the rear gate cooler 182 and the inside of the dryer 291, The suction filters 262 are attached to the distributing and inputting devices of the nuclear power plant to form connection structures so as to adjust the internal wastage of the nuclear power plant's nuclear power plant main body 1.

Referring to FIG. 2Z, a conventional fire hydrant system (conventional fire extinguisher system) shown in FIG. 2 (a) shows a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste processing according to the present invention, (179a) of an underground fire extinguisher (179a) and an underground fire extinguisher (179b) of an underground fire hydrant box at the lower part of the road surface. And is a front view of the fire extinguisher container and the fire hydrant box inside the fire hydrant box 161 and the fire hydrant box 160. The fire hydrant 179 is attached to the water feed port 168 of the connection and water pipe and the water- Sectional configuration and perspective view showing the construction of the fire hydrant system shown in FIG. 1 (a), (b) and (c) of FIG. Minute road-side configuration,

As shown in FIG. 2 (2), the distribution input device for the reactor installation of the nuclear power plant constituting the internal nuclear power generation facility 811 of the nuclear reactor facility main body 1 of the nuclear power plant includes a conventional distribution device Prevention of disaster prevention at the flood control section (811) Underground fire hydrant (179a) and subterranean fire hydrant (179b) at the bottom of the ground surface Underground hydrant fire hydrant The firebox manhole is partly constituted and the fire extinguisher (161) and the fire hydrant box inside the fire hydrant box (160) are equipped with the fire extinguisher accessories and the fire hydrant box, and the fire extinguisher (179) (A) of the indoor fire hydrant piping system and (b) a small scale fire hydrant facility, A is composed of a connecting structure to adjust the reactor equipment body (1) inside the flood of a nuclear power plant.

Referring to FIG. 3, the reactor main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore power plant Straight road,

Referring to FIG. 3A, the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention 1 is installed in an internal nuclear power generation facility 811, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Offshore Power Plant Side Construction Road,

Referring to FIG. 3B, the reactor main body 1 of the nuclear power plant having the double structural block tank dust collector for treating nuclear waste according to the present invention (1) The reactor main body 1 of the nuclear power plant, (593,594,595) equipped with hydroelectric power station of land-based hydroelectric power plant of a stepped dam revolving road which provides the position of nuclear power plant (811) on the ridge line of each ship, and a connection structure with the island tunnel (672a) Sectional configuration of offshore power plant roads,

As shown in FIG. 3, FIG. 3A and FIG. 3B, the atomic power plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment according to the present invention, The position of the hull of the marine power plant floating ship with the connection structure with the hydroelectric power station of the land and the landing tunnel (672a) of the stepped dam revolving road which provides the position of the nuclear power plant (811) Hull Location of the Controlled Marine Power Plant Construction Machinery Control Section Marine Dock Body Dock The pipe bridge (928), which shows the arrangement of the hull displacement control and the position of the construction machine in the marine hydroelectric power plant floodplain (593,594,595) (771) inside the marine tunnel transport device to the inside of the marine tunnel transport device (941) to the pipe bridge (937) The hydraulic pumps 593, 594 and 595 of both hydroelectric power plants are connected to a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, The portable lug 607 and the portable lug pin 604 are connected to the vertical partition wall 605 and the pin linking shaft 606 for connection to the portable lug by the distributing and inputting apparatuses of the flood control machine provided with the door 624 for the hydraulic cylinder, 608) to the inside of the marine tunnel traffic device 941 to the construction machine connection structure and bridge bridge 928 and the pipe bridge 937 to the drilling machine 908 to the crude oil drilling machine 908, (928) and a pipe bridge (937) to the inside of the marine tunnel traffic device (941) for the nuclear waste disposal. The marine tunnel traffic device internal train (771) facility is connected to the marine hydroelectric power station floating ship (593,594,595) Location control and control of construction machine position Construction machine connection structure and disassembly (2) Nuclear power plant nuclear waste disposal facility (1) Nuclear power plant construction (811) Nuclear power plant nuclear power plant nuclear power plant nuclear waste disposal system Double structure Block tank Tank inside of marine tunnel traffic device (941) Marine tunnel Internal traffic train (771) Equipment Dual structure block tank for nuclear waste disposal by water pollution control facility Nuclear power plant reactor main body with dust collector And is further configured in the nuclear power plant 811,

(593, 594, 595) of the nuclear power plant's nuclear reactor facility installation and disposal unit (593, 594, 595) constituting the nuclear power plant section (811) inside the nuclear reactor facility main body (1) of the nuclear power plant are classified into rack and pinion type And the distribution of the nuclear reactor power plant provided with the butterfly valve 622 for controlling the buoyancy force of the band guide 621 and the door 624 for the hydraulic cylinder in the hydraulic cylinder hydraulic oil pressure 623 A large flange connection connection joint portion machining hole 615 to the portable lug 607 and the portable lug pin 608 to the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling with the insertion devices, (908) hydroelectric power plant construction machine connection structure and disassembly and disassembly combined with double structure block for nuclear waste disposal Tank Haze (771) inside the tunnel transport device (941) Internal tunnel of the water transport facility (771) Nuclear power plant reactor with double structure block tank dust collector for treatment of nuclear waste by the flood control facility (1) Internal nuclear power plant (811 ). &Lt; / RTI &gt;

Referring to FIG. 3C, there is shown a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. The construction of the sprinkler head pipe 111 of the sprinkler installation piping system sprinkler system and the torsion configuration of the trench head and the vibration alarm device 300 is shown in FIG.

3C, a plurality of drencher heads 299a, b, c, and d are installed on the sprinkler head 111 of the trench head in the sprinkler installation for preventing and preventing disaster of the nuclear power plant 811, The metal tube 113 for the fuse and the water valve 114 for the stop valve are connected to the reflector 112 by the underground pipes 115 and at the same time, A double structure block tank dust collector for nuclear waste treatment equipped with switch 118, bell 119, alarm valve 120, test valve 121, high pressure water pump 122 and vibration alarm device 300 Nuclear Power Plant Reactor Facility (1) Internal Nuclear Power Facility (811) Disaster Prevention Preventive Control Connected structures.

Referring to FIG. 3D, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention, Is a partial side view showing the operation of the piston pump 127 in a side view and a partial plunger pump 148 operating configuration diagram showing the manner in which the plunger pump 148 is partially actuated by the plunger 253, A partial side view showing the side surface of the pump 311 and the toe empty pump 140 and a driving side surface configuration showing the installation state of the waste water pump 309 as a side view,

The operation mode of the reciprocating pump piston pump 127 and the operation mode of the plunger 253 are connected to the rotational axis of the electric motor 192 in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, And the turbine pump 140 and the wing pump 327 of the rotary pump simultaneously move the handle in the left and right directions. , And it is equipped with a suction pump and a discharging pump in two chambers, respectively. The pump is equipped with a simple pump which can be easily mounted on a wall, 309) Nuclear power plants with a dust collector Unit main body (1) Internal distribution of nuclear power generation facilities (811) Discharging unit Disaster prevention Preventive control part Connection structure It can control.

As shown in FIG. 3D, the disaster prevention preventive control unit of the nuclear power generation facility unit 811 includes a closed position in the positive displacement pump formed by the preferred embodiment according to the detailed description of the type and characteristics of the pump, In a guaranteed function of the pump, in which the deployment position is clearly defined, a certain amount of fluid is delivered in the same manner as when dispensing fluid.

Therefore, a predetermined amount of liquid is sucked up by using a piston or a plunger of a reciprocating pump, and is sent out by pushing up.

First, get a high pressure even in a compact And is available for small flow rates of high viscosity.

Secondly, the pumping action is intermittent, so there is pulsation. To reduce this, a fly wheel to keep the rotating speed constant, or an air chamber (402) Accumulator) and the like

Thirdly, since the discharge amount of one stroke (stroke) is constant, it is possible to dispense and deliver a fixed amount.

Next, even if the number of revolutions is changed, the change of the discharge pressure is not as severe as that of the centrifugal pump. Therefore, there is always a suction / discharge valve to increase the number of parts, and the failure of the valve is fatal. In order to convert the rotational motion of the power into the reciprocating motion It is necessary to use a crank method or an exen method, which may complicate the components or cause vibration.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power plant unit 811, there are the following kinds of reciprocating pumps.

First, the piston pump has a seal line (packing) and a valve attached to the piston,

Second, the plunger pump differs from the piston pump in that the seal line is fixed to the pump body and is not attached to the reciprocating plunger. Therefore, the plunger 253 is easy to replace the packing, and a very high pressure can be obtained.

The pump is connected to a speed reducer 251 motor 192 and a wire rope 19 of a tug winch 137 to various motors in a rooftop collection tank 34 inside a machine room roof of a large building It is operated by pushing the top and bottom of the building with the switch button. The disaster prevention water (7) of the line of the fire prevention disaster prevention pipeline (168) is integrated into the equipment inside the pump fire extinguisher body, ) And firefighter (159) to the diaphragm pump (144).

In this way, the diaphragm pump (membrane pump 144) can pump water containing a large amount of fluid, mud or sand, and the suction or discharge is performed by moving the rubber membrane or the Teflon membrane 538 up and down . The feature that the crank 248 and the link belt 249 are formed on the rubber film 538 on the upper surface of the pump 144 and is not easily worn or closed with a fluid containing slurry (particle) It is composed of prevention of evolution. Therefore, it is suitable for chemical and harmful fluids because it can be completely leak-proofed without grand packing. It is suitable for fire disaster prevention in case of fire and other disasters.

And the wing pump (paddle pump) is a simple pump that moves the handle to the left and right to allow suction and discharge in two chambers. It can be easily mounted on the wall to transfer the oil from the drum, It is often used when you publish or publish.

As shown in FIG. 3D, in order to smoothly utilize the movement of the equipment installed in the past, the fire fighting cable control unit 256 of the nuclear power generation facility unit 811 A plurality of pumps are attached to the fire sensor pump body, and the tackle winch 137 described above is supplied with air supplied from the air compressor 80 to open (open) the air shutoff valve, A folding winch 137 is used in the rooftop fire-fighting cabin 394 and the steel tower 116 of the high and low mountains 395, The disc brake 399 serving as a brake is formed while winding the gears and the wire rope of the transmission 398 and the motor speed and the speed com- mer 397 so as to be able to perform the speed com- mer 397, (126) and electric A motor 192 and a switch are formed.

As shown in FIG. 3D, in the disaster prevention preventive control unit of the nuclear power generation facility unit 811, a rotary pump Rothermal pump 357 is connected to the rotary pump 357 when one of the positive displacement pumps rotates The fluid is pushed and discharged between the main body (casing) and the rotor. The characteristic feature of this centrifugal pump is that it is not confused with centrifugal pump using centrifugal force. First of all, there is no suction / discharge valve such as reciprocating pump, continuous discharge and less pulsation. Secondly, high pressure discharge is possible. (Oil, oil, tar, pitch, paint, etc.), but at this time, the larger the viscosity, the smaller the number of revolutions and select the one with larger power. In the case of high pressure, it is sensed that a safety valve is installed, and that a liquid having no viscosity is good for a centrifugal pump. However, the gear pump is a type in which two types of gears are meshed, The second feature is that it is suitable for high-pressure use. Even if the discharge pressure is changed, the discharge amount does not change much. Thirdly, the liquid such as centrifugal pump is severely damaged The fourth is that the structure is simple, and it is easy to decompose, sift and clean, and the fifth is that the abrasion is promoted by the liquid containing the particles, so that it can not be used for the liquid containing solid particles, In addition, the spur gears are simple in structure, easy to process, costly, and widely used. However, there are noise and vibration, And the durability is weak.

In the rotary pump 357, the double helical gear for canceling the thrust (the force to be pushed in the axial direction) of the helical gear or the helical gear having a tilted inclination is difficult to process and the cost is high There is no noise or vibration.

The external gear pump 326a and the internal gear pump 326b are classified according to the shape of the gear and the reference for the sealing and cavitation by the gear tooth of the gear pump 326 Explain as follows.

In the pump of the rotary pump 357, the involute gear is in contact with the two points when the gears are engaged with each other, so that the liquid contained therebetween is hardly compressed and forms a very high high pressure, The rotation of the pump is a serious obstacle to the rotation of the pump, which causes an increase in the shaft force, breakage of the bearing, noise and vibration. However, in the rotary pump 357, If the two points are in contact, the liquid outside of the two points of the gear can not be inserted. In the space between the two points, a very large negative pressure is formed. If one point is in contact with the point, It collapses and makes a large noise, generates bubbles and causes vibration, which significantly reduces the durability of the pump. In order to prevent cavitation, first, the finishing should be very precise, the material should be carefully selected, so the price is very expensive. Secondly, the structure is complicated, so it is difficult to exchange or assemble. If it does not go through the angles, it will get caught soon, and the sixth can not be clamped on the way like gland packing, and once it is exchanged or wrapped, If you do not eliminate the vibration by connecting the power of the pump well, you will shorten the life of the seal. However, it is the most excellent sealing method at present. It is important to be able to avoid.

First, the type of mechanical seal is an inside-out type according to the set type, a single-seal type according to the seal type, and an unbalance type and a balance type according to the double seal type surface pressure balance type.

First, the inside (inside) type is the one commonly used in the way that the fixed side is on the pump side.

Secondly, the outside type of the outside is the case where there is a problem of the corrosion resistance of the structural material and the spring material in the way that the rotation is on the pump side. When the viscous coefficient is high viscosity liquid exceeding 100 cp, Is usually used when it is high vacuum.

Third, a single mechanical seal type is a general method in which the sliding surfaces are sealed together.

Fourth, double mechanical seal type is a type that has two sliding surfaces. It is used when it is a toxic liquid or a flammable liquid, when it needs to keep warm and cold, when it leaks, when it solidifies, when it is solid, when it is high vacuum, And is also effective for a liquid containing slurry which is a disadvantage of a high-temperature or low-temperature liquid or a mechanical seal.

Fifth, the unblanced type is generally used as a sealing method in which the pressure in the pump is directly applied to the sliding surface of the seal. Fluid pressure is less than 4kg / ㎠ (depending on the product, less than about 7kg / ㎠ for liquid with good lubricity and less than 2.5kg / ㎠ for liquid with bad lubricity).

Sixth, the blance type is a method that makes the pressure on the sliding surface of the seal not to be applied when the pressure in the pump is large. When the pressure is 4 to 5kg / ㎠ or more, It is used.

In the case of the ordinary mechanical seal, the spring is a spring that pushes the rotating ring of the sliding surface. When the liquid pressure is applied to the rotating ring, the contact force of the sealing section is added to prevent leakage. However, when the contact pressure is too high, the abrasion of the sliding surface is promoted. Therefore, when the internal pressure is high, this pressure is balanced to adjust the contact pressure.

The following cooling and lubrication is the frictional heat of the liquid or the sliding surface of the liquid. When the temperature rises due to the heat of the liquid, the material wears and corrodes or the packing seals. Therefore, the cooling and lubrication functions As shown in the drawing, a quadrangle 268 is formed above the shaft bar 390 and a flashing hole 361 is formed in the culver 367 in the cornering method 391 of the mechanical seal.

First, flushing is the most common method. In this method, liquid is injected and extracted from the outside of the high-pressure side liquid of the shaft end to maintain the temperature of the seal appropriately. Thus, vaporization of the sealing end face is prevented to improve lubrication, It also prevents accumulation on the shaft bar.

Second, quenching is a method of injecting a coolant into the sealing section of the seal so that the fluid does not flow to the high-pressure side of the shaft. When the fluid comes into contact with volatile fluids or air, If leaking fluid is washed out, dilute and recover. In addition, it is a device formed in the nuclear reactor main unit (1) 811 of the reactor main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment for isolating air from the sealing end and preventing oxidation.

For example, in the case of handling (LPG) or the like, the cooling water is flowed outside the seal face so that it can be washed away.

Third, cooling is a method of cooling the outer periphery of the seal rather than a sealing cross section, which has a cooling effect lower than that of quenching, but does not require leakage to the atmospheric side, and there is no need to pay attention to the purity of cooling water.

In the material of the mechanical seal, the material of the seal varies depending on the type of the sealed liquid, the temperature, the pressure, the presence of foreign matter, the speed, the degree of leakage, and the like, but is known to the general public as stainless steel and Kaibon graphite It is a combination. Carabong graphite is self-lubricating, does not fuse with metals, has low friction, and is resistant to chemicals. In addition to stainless steel, stainless steel, ceramics, cemented carbide is added or heat treated. Dual structure block tank for treatment of nuclear waste to provide sufficient corrosion resistance and abrasion resistance Nuclear power plant with dust collector Main body (1) Internal nuclear power plant 811).

Examples of combining materials of the mechanical seal are as follows.

In the reactor installation of a nuclear power plant equipped with a double structure block tank dust collector for treating nuclear waste according to the present invention, there are one or a plurality of factors superimposed on the vibration of the pump.

First, according to the hydrostatic vibration, the vibration by the cavitation: the cycle of about 600 to 25,000 cycles brings about the rapid vibration and the noise. Second, the vibration by the surging phenomenon: Cavitation occurs when the discharge amount is large, The vibration due to the water hammer (water hammer) and the vibration due to the unbalance of the flow in the pump 4 and the vibration caused by the mechanical vibration firstly have a long period of about 10 to 0.1 cycle, The vibration due to the unbalance of the rotating body and the vibration due to the dangerous speed cause a severe vibration caused when the rotational speed of the shaft resonates with the natural frequency of the rotating body. Vibration due to solid friction is a kind of self-excited vibration, and there is a shortage of lubricating oil on the rotating shaft, And fourthly, the vibration caused by the hydraulic pressure of the bearing is a vibration generated due to the oil pressure of the bearing part when the rotary shaft rotates at an angular speed about twice as high as the dangerous speed, In particular, the vibration caused by the natural frequency of the pump is a problem in the vertical shaft pump. In the sixth place, the vibration due to the centering failure is a serious factor when the centering failure is caused. And the seventh is hydrodynamic vibration to the reactor facility of a nuclear power plant equipped with a double structure block tank dust collector for nuclear waste disposal which occurs due to the vibration caused by the prime mover and the eighth foundation weakness

The output definition for the use of the diesel engine 226 will be described as follows.

First, the term commercial refers to the generator The term "emergency" refers to the output (equivalent to ISO 8528 ESP) applicable to emergency generators used for a limited period of time in the event of a mains failure, while the engine model is referred to as a cooling fan And a flywheel 268 and a V-belt 252 are attached to the cylinder 250 and the cylinder 250, respectively. As shown in the figure,

As shown in the above table, the output tolerance is ± 5%. The description of the specification of the engine 226 is the same as the specification of the engine specification of the right side.

<Engine Specification>

Finally, the precautions for handling the compressor are described in detail as follows.

First, in general precautions concerning the handling of compressors,

First, the compressor is always kept clean and the surroundings are cleaned and arranged thoroughly.

Second, when the operation of the compressor is shut down, the engine is operated for a short time only once a day for a short period of time.

However, in case of long-term shutdown, disassemble and clean, replace worn, damaged parts or lubricating oil with new ones, drain all cooling water (drain) and prevent corrosion.

Third, each axis is checked and adjusted every opportunity.

Fourth, valves, pressure gauges, regulators, filters, etc. are prevented from malfunctioning by regular inspections and daily inspections.

Fifth, cool water uses clean water. Cooling tube is disassembled every June or year. It is cleaned with water vapor. If the weight is decreased by 10% or more, it is corroded or worn.

Sixth, always pay attention to the gas leak of each part, and the toxic and flammability should be detected with a small amount of detector, and proper measures should be taken.

Seventh, oil is selected with the help of the manufacturer.

The eighth, if there is an abnormality, stop driving immediately, notify the manufacturer and ask for repair.

In the following notes on starting,

Be sure to check that bolts, nuts and other screws are tight.

Next, fill the crankcase with a specified amount of lubricating oil and check the lubrication condition.

Pass the third cooling water and check whether the cooling water circulates.

Next, open the pressure gauge, pressure regulating valve, drain valve, etc. to check the pressure indication.

Next, the small compressor should be rotated by hand with no load. Check the connection of the electric motor by inserting the hand switch after checking the switch, and check whether the foreign substance is not caught in the cylinder.

The sixth suction valve is closed and the switch is opened with the bypass or drain valve open.

Next, when the normal rotation is performed, the drain valve and the bypass valve are closed from the first stage to the next stage, and at the same time, the suction valve is opened.

Finally, pay attention to pressure, lubricating oil, temperature, noise, vibration leakage at each stage.

Then, in the notes during driving,

The pressure, leakage, vibration, temperature, abnormal noise of each stage, the quantity and temperature of the cooling water, the temperature and pressure of the lubricating oil and the load of the motor are checked.

In particular, pay attention to abnormal increase or decrease in temperature or pressure, and never tighten or hammer the bolt during operation with leakage.

This is divided into the following.

First, regarding handling of reciprocating compressors

First, whether there is abnormality in the scale of the pressure gauge and the suction / discharge gas temperature at each end

Second, the change of bearing temperature and the abnormal rise

Third, keep a watch on the change of the cooling water temperature and adjust the quantity if necessary.

Fourth, watch the oiling situation of the cylinder lubricator, adjust the flow rate, and supply oil to the lubricator.

Fifth, the state of change of external flow or hydraulic pressure

Sixth, the piston rod packing leakage and temperature rise

The seventh is whether the color of the drain is rapidly blackened

Eighth, are there any differences in the sounds and vibrations of each part from normal?

Ninth Valves or flange joints such as safety valves, drain valves, etc. · Are there any gas leaks on other tight surfaces?

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

The following is the handling of Turbo Compressor

First, the lubricating oil pressure of the bearing lubricant or the temperature of the returned oil

Second, the oil pressure or return oil pressure for the shaft bar or the differential pressure or leakage flow

Third, whether vibration of each part such as main body, bearing,

Fourth, abnormality of bearing water temperature

Fifthly, the change of the cooling water temperature is monitored, and the quantity of water is adjusted when necessary.

Sixth, there is no leakage of gas from valve or flange joint of piping system or other tight surface

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

In the note of the fourth stop,

First, switch off the electric motor and close the intake valve.

Second, check the pressure drop and close the discharge valve. Observe the abnormal sound or vibration until stop.

Next, close the coolant valve to cut off the coolant and drain all water from the water jacket or cooling tube.

Finally, discharge any other condensate or oil.

In the notes on the fifth disassembly and inspection,

Firstly, when disassembling and checking, make sure that the machine is disconnected from the power source so that it does not operate.

Secondly, if the gas inside is toxic or flammable, it should be completely insulated and replaced with inert gas.

The following should be done after confirming that there is no pressure at each end of the decomposition operation.

Finally, when the cylinder head is disassembled, the bolt alternates in the order of the opponent facing each other, gradually releasing it to the two relatively positioned positions (of course, confirming that there is no abnormality,

As described above, each of the prime movers and the compressors are connected to each other by an electric motor and are connected to each other to show the conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment. As for the selection of the model in the separation process, the damage to the fire caused by the fire occurring in the blink of an eye for 1 second as described above clearly according to the type of fire by the type of fire as a fire-fighting disaster prevention countermeasure is impossible. Therefore, the fire should be selected as the most appropriate place for the initial site precaution.

Referring to FIG. 3E, there is shown a conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, (459) Each valve configuration providing the land and off-shore reactor facilities of the faucet (496) of the faucet type of the integral type and the piping accessories,

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, The control valve 459 is integrally connected to the pressure reducing valve 460 and the pilot operated pressure reducing valve (not shown) in the distribution input device of the nuclear plant installed in the offshore of the general faucet 496, A main valve 466, a main valve spring 467, an adjusting spring 468, and a control valve 468 are connected to the main valve 461 and the magnetic pressure reducing valve 461, A spring type safety valve 473 and a relief type safety valve 474 and a screw type pressure regulating valve 471b and a screw type automatic pressure regulating valve 470a, a flange type pressure regulating valve 471b, a safety valve 472, A steam-type pop-spring-type safety valve 475, a PFO-type safety valve 476, The automatic level adjuster 478 and the automatic level adjuster 479a as well as the automatic level adjuster 480 and the air vent valve 481 and the thermal type automatic air vent valve 482 and the bucket Type hot air type automatic air exhaust valve 483, a refrigerant pipe valve 484, a refrigerant stop valve 485, a feed valve 486, a bellows type charge valve 487, and a diaphragm-type charge valve 488, an expansion valve 489, a diaphragm-type expansion valve 490, a bellows-type expansion valve 491, a rich valve 492, a refrigerant pressure regulating valve 493 and a solenoid valve 494 The water supply type common faucet 496 of the piping accessories is composed of the faucet body 529, the packing box 530, the packing press 531, the faucet 532, A disk 534, a disk packing 535, a water-resistant packing 536, an aging resistant packing 537, And Teflon membranes 538, which are installed in the reactor installation of the nuclear power plant, and the disruption prevention preventive control connection structures of the nuclear power generation facility 811 of the nuclear power plant.

The ground level load (GLL), the ground level load on the upper (GLL), and the ground level load (GLL) Abbreviated as GLD).

On the right side of the valley, the wire rope 19 for the 5000 kg overhead crane for the industrial site or the rope 131 at the point A and B of the valley at the bottom of the valley, The ropes 19 and 131 are connected to the hooking hooks 18 by the shackle 23 and the driving wheel rollers 135 by the hoisting ropes 135 at the points C and D, The lifting baskets 42 and the injection nozzles 10 are connected to each other by a 15-m-long fire hose at the cable car (256) The length of the injection nozzle is set so that the length of the injection nozzle is set to a predetermined value after the collecting tank 34, which is a bucket of a movable dual structure, and the pump 71 are installed together in the cable car 256, (A), (B), (C), and (D) according to the length of the nuclear waste (451) showing the conventional construction constituted in the nuclear reactor main body (811) of the nuclear reactor main body (1) of the nuclear power plant having the double structure block tank dust collector and the general type faucet (496 ) Of nuclear power plants and nuclear reactors equipped with respective valves to provide the land and ocean reactor facilities, and the operation of nuclear power plants is carried out on land and in the oceans of the world.

3E, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste is provided with the disaster prevention preventive control valve 459 of the internal nuclear power plant 811, (496) of the faucet of the faucet of the faucet of the accessory, and the distribution apparatus of the reactor facility of the nuclear power plant installed in the sea,

(Sluice valve), stop valve, glove valve, angle valve, check valve, and reduction valve are used to control the fluid and flow rate of steam or water. A reducing valve, a cock, etc. may be used depending on the purpose of use.

Table 2-1 shows the valve configuration, Table 2-2 lists the valves, and Table 2-3 lists the (KS) specifications of the valves.

<Table 2-1> Configuration of valve

<Table 2-2> Classification of Valve

<Table 2-3> Valve KS specification list

As shown in FIG. 3E, the following describes the slew-valve device in the disaster prevention preventive control section connection structure of the nuclear power plant section 811

The valve is also referred to as a gate valve 296 by opening and closing the valve by a screw bar in parallel with the cross section of the pipe. When the valve is fully opened, the resistance of the fluid flow is very small compared to other valves. Fluid is not left in the valve chamber, the diameter is usually 50mm or 1,000mm, and the large size is operated by power. However, there is a drawback that the valve is expensive and takes time to open and close the valve. Therefore, when the diameter of the water pipe of the power plant 267 and the water pipe of the water supply pipe are large and it is not necessary to frequently open and close the valve, various accessories formed on the slow valve valve 403 are attached, The valve 403 is connected to the valve cover 405 and the slow valve 406 by the packing press 407 and the packing press nut 408 as shown in the figure, The valve seat 409, the handle 410, the handle nut 411 and the packing 412 are attached.

As shown in FIG. 3E, in the specification table of the slow valve on the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811,

The kind of the slew valves includes a wedge gate valve, a parallel slide valve, a double disk gate valve, a wiping valve, and the like depending on the structure of the disk.

As shown in FIG. 3E, in the apparatus configuration of the wedge gate valve 413 in the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811,

The wedge gate valve 413 is divided into a single valve 414 and a flexible valve 415.

As shown in the figure, the unit type is a wedge-shaped valve, and the angle of the wedge is usually 6 ° to 8 °, while the bronze small valve has a wedge angle of 8 °.

As shown in the figure, the flexible valve 415 is provided with a groove at its center, so that the flexible valve 415 absorbs the influence of heat on the valve seat in the high-temperature pipe or the like by using the flexible.

Second, in the device configuration of the parallel slide valve 416,

The parallel slide valve has a spring inserted between two parallel valve bodies so that the valve is pressed against the valve seat by fluid pressure.

As shown in FIG. 3E, there is a gap between the valve body and the disk in the disconnection prevention preventive control connection structure of the nuclear power plant 811, so that there is little friction on the valve side and is not affected by thermal expansion. .

The valve disc and the valve seat act as a slide, so the valve seat uses a hard metal. This valve is suitable for high temperature and high pressure when vertically mounted.

Next, in the device configuration of the double disk gate valve 417,

The wedge type valve is difficult to be completely opened and closed due to deformation of the valve seat due to frictional resistance and thermal expansion. In order to prevent this, the valve body is divided into two, and the valve disk is widened by the thrust of the valve step to press the valve seat against the valve seat.

The structure adopting the advantages of the wedge gate valve 413 and the parallel gate valve 416 has a relatively small influence on the deformation due to temperature and pressure.

As shown in FIG. 3E, a detailed description of the device configuration of the stop valve 418 in the disaster prevention preventive control connection structure of the nuclear power plant unit 811 is as follows.

It is called the glow valve that the inlet and the outlet are in a straight line according to the flow direction of the fluid and the angle valve is the angle of the inlet and the outlet. The connection method of pipe is screwed joint and flange joint method. The material is made of forged steel for bronze high temperature and high pressure when it is used for small medium pressure, and cast iron is used for large type. The opening / closing spherical surface of the valve has a flat sheet, a conical sheet, a spherical sheet, and a stud sheet, which have a large resistance loss against the flow of fluid and are prone to collect dust in the water bodies. This is the most widely used type of valve because it is easy to make valve and valve seat when the lift is small and the valve opening and closing is fast.

Valves and valve stems are connected by packing glands and valves and rods are in the form of cylinders.

The Y-shaped glow 419 is used for applications such as glow valves, and is designed such that the valve cylinder is inclined by 45 to 60 degrees with respect to the center line for the purpose of reducing the resistance.

The angle valve 420 has the same function as the glow valve 419, but is used to change the flowing direction of the fluid at right angles.

As shown in FIG. 3E, the needle valve in the connection structure of the preventive shut-off control part of the nuclear power generation facility 811 has a conical needle 15 to 16 mm used for flow control, (Bonnet) 422, the disk 423, and the lid-attaching valve seat 424 are attached to the valve body 421 as shown in the figure, The packing presser 429 and the valve presser 426 are pushed into the screw fitting 431 and the cover bolt 432 in the packing presser ring 429 and the packing presser 430 in the handle 427 and the cover fitting ring 428, A cover bolt nut 435 is attached to the pin bolt 433 and the pin 434 and a detent screw 438 is attached to the handle nut 437. A gasket 441 is attached to the washer 439 and the packing 440, Device.

3E, the specification sheet (flange type glow valve and angle valve) of the valve to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811,

As shown in FIG. 3E, the cock in the connection structure of the preventive control section of the nuclear power plant 811 is classified into a cock 1 type 443 and a cock 2 type 444, and a cock 1 type 443 are formed with a bronze threading main cock 445 and a bronze threaded gland cock 447 in a cast iron flange type gland type 446 and the cock 2 type 444 is formed of a trunk 448 and a four- (449). However, when the fluid flows in a straight line and the cock is rotated 1/4, the passage is opened completely, so that the opening and closing is fast. There are many cast iron and bronze materials, and small diameter low pressure springs are used for drainage.

The cock may be a one-way stream of two-way cocks and a two-way stream of three-way cocks.

The main cock is (a) fastened with a nut under the plug 458 as shown in the same figure, and the gland cock is pressed by the packing as shown in (b) and (c).

3E, the swing type check valve 452 and the lift type check valve 453 are connected to the check valve 451 of the connection structure of the nuclear power generation facility part 811 to prevent the disaster, It is used to automatically close the valve when the fluid flows in one direction. It has a swing type and a lift type.

3E, the swing type check valve 452 on the connection structure of the disaster prevention preventive control unit of the nuclear power generation facility unit 811 is opened and closed by rotating the pin 457, so that the frictional resistance Can be used for any piping that is less horizontal than vertical type.

The lift-type check valve 453 has a structure of a valve seat such as a glow valve. As shown in the drawing, the valve is vertically lifted by the pressure of the fluid. The lift of the valve is about ¼ of the diameter and the friction resistance against the flow is large. A check valve 451 is formed and a disk 456 and a disk pin 457 and a plug 458 are attached to the body 454 and the cover 455. The check valve

A check list

In addition, the lift type check valve 453 has a Sumorenski type which has a wing to mitigate the impact.

The check valve is designed to flow only in a certain direction, so pay attention to the flow direction of the fluid when installing. Bronze screw type of 10A or 15A or cast iron or cast steel flange type of 50A or 200A is used.

The control valve 459 is connected to the pressure reducing valve 460 and the safety valve 472 via the temperature control valve 477 and the temperature control valve 472 to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The pressure reducing valve (460) is installed between the high-pressure pipe and the low-pressure pipe so that the lift of the valve is braked by an appropriate device, the pressure on the high-pressure side And the pressure of the low-pressure side is kept substantially constant regardless of the change of the steam consumption amount and the change of the steam consumption amount.

The actuation of the valve is usually done with a bellows, diaphragm 463 or piston 127.

When the pressure ratio of the high-low pressure is within 2: 1 and the pressure ratio of the high-low pressure is exceeded, it is better to use the two pressure-reducing valves 460 in series to perform the two-stage pressure reduction. The structure is generally composed of an adjustment spring 468, a diaphragm 463, a pilot valve 464, a piston 127, a main valve 466, and the like as shown in the same figure.

3E, a secondary-side sensing hole 462 and a diaphragm 463 are provided in a pyrotechnic-operated pressure reducing valve (magnetic force type) 461 in a disaster prevention preventive control connection structure of the nuclear power plant 811, A main valve spring 467 is attached to the pilot valve 464 and the piston 127 and the main valve 466 and a screw-type (½~1½ inch) (2 to 6 inch) pressure regulating valve 471b and a flange type

3E, a spring type safety valve 473 and a relief type safety valve 474 are connected to the safety structure of the disconnection preventive control unit connection structure of the nuclear power generation facility unit 811, And is separated into a Pope spring type safety valve 475 and a Pope type safety valve 476.

The closing mechanism of the fluid is the same as the glow valve 419 and the glow valve 419 is opened or closed by an external force. However, the safety valve is closed by the force of the spring on the external force sensor or the weight of the valve stem and the weight of the lever Is opened and closed.

As shown in FIG. 3E, the safety valve to the connection structure for preventing and preventing disaster of the nuclear power generation facility 811 is installed in a pipe for handling a pressure vessel such as a boiler and a high-pressure fluid, When the specified limit is reached, the internal energy is automatically released to the outside to keep the pressure in the container at a safe level at all times.

It is a safety device that must be attached to pressure vessels with large accumulation energy such as boilers. One type of safety valve is a relief valve. It is used as a valve connected directly to a pipe line of a pipe through which a pressure fluid flows, and is used for the purpose of warning while adjusting the pressure of the pipe constantly.

The performance of the valve is determined by the accuracy of the ejection pressure, the pressure at the ejection stop, the pressure difference in the ejection, and the ejection volume. When the valve is opened and the steam is spouted, the pressure at the inlet side is referred to as the ejection pressure, the pressure at the inlet side is referred to as the ejection stop pressure when the valve is closed, and the difference between the ejection pressure and the ejection stop pressure is referred to as the ejection difference pressure.

As shown in FIG. 3E, the temperature control valve 477 in the connection structure of the disaster prevention preventive control unit of the nuclear power plant 811 has the same configuration as the auto temperature control valve 477, It is an oto control valve which is opened and closed by the action of bellows which is very sensitive to temperature change and automatically adjusts the flow rate of heating steam or cooling water. It is used for heat exchanger and heavy oil heater.

3E, an automatic level regulator 480 is additionally formed in the automatic water dispenser 479 in the disaster prevention preventive regulating connection structure of the nuclear power generation facility unit 811. The automatic water leveler 479 and the regulator 480) is to automatically level the level of the autosappler boiler to its maximum efficiency point, where the level difference is always derived at abundance, thereby preventing the risk caused by the shortage of the boiler water supply.

3E, the ventilation valve 481 belonging to the regulating valve 459 to the disaster prevention preventive control connection structure of the nuclear power generation facility unit 811 is provided with an oto-air exhaust valve thermostat (for steam, 533 mm x 68 mm, 483) to the dimensions of the exhaust valve (width x length; 53 mm x 56 mm, 482) And the air vent valve for the air is either an inferior type or a thermostatic float type, and a float type valve is adopted as a warm air vent valve. The fuselage is made of bronze bronze, bronze bronze, and brass.

3e, a float valve 484 belonging to the refrigerant stop valve 485 and a pack valve 486 belonging to the refrigerant stop valve 485 are connected to the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811, (Diaphragm type) 488 is formed by a refrigerant stop valve 485 and a diaphragm type expansion valve 490 and a bellows type expansion valve 491 are formed in the expansion valve 489 And is formed as a refrigerant pipe valve 484 integrally with a solenoid valve 492 and a pressure regulating valve (for refrigerant 493) integrally with a solenoid valve 494 and an oto water feed valve (not shown).

As shown in FIG. 3E, the emergency valve 486 belonging to the refrigerant stop valve 485 and the valves 487 and 488, which are connected to the disaster prevention preventive control unit connection structure of the nuclear power generation facility unit 811, The valve 485 has a structure of a valve seat and a valve seat similar to those of the above-described glow valve. In order to prevent refrigerant from leaking from the valve body side through-passages, a ground packing type (phone net type) And a diaphragm type in which a shaft is sealed by a diaphragm and a diaphragm type which is sealed by a bellows and can not be manufactured by a bellows or a diaphragm. The Grand type has all shaft caps (bonnets, caps) and is now mostly packed type to prevent the exchange of bellows, packs or packing tightenings, and to prevent leakage when the valve is opened.

As shown in FIG. 3E, in the connection structure of the disaster prevention preventive control section of the nuclear power generation facility 811, the large body is a pouring agent or a cast iron agent, The sheet is made of Nerunel metal.

Valve material should be harder than valve seat material to prevent abrasion.

The expansion valve 489 is formed by separating the diaphragm-type expansion valve 490 and the bellows-type expansion valve 491

As shown in FIG. 3E, there are three types of expansion valve 489 in the connection structure of the disaster prevention preventive control section of the nuclear power generation facility section 811, namely, a passive expansion valve and a thermodynamic expansion valve.

Referring to FIG. 3F, there is shown a conventional structure for constituting the internal nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for treating nuclear waste according to the present invention, The main problem of the pump in driving the enlarged cross section of the drive during construction,

As shown in FIG. 3F, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating the nuclear waste (1) The main trouble facility In addition,

As shown in FIG. 3F, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating the nuclear waste (1) The main trouble facility In addition,

As shown in FIG. 3F, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating the nuclear waste (1) The main trouble facility In addition,

As shown in FIG. 3F, the reactor main body (1) of the nuclear power plant having the double structure block tank dust collector for treating the nuclear waste (1) The main trouble facility A gland 345, a liquor liner ring packing 346, a lantern packing 347 and a double gland packing 348 are attached to the standard gland packing 344 on the main problematic equipment during the pump operation. And the throttle bush attaching packings 349 are provided so that the pump drive is provided to provide the cooling water outlet 350, the seal 351 and the cooling water inlet 352, and at the same time the water jacket attachment packing 353 for the sleeve inner cooling water bottle, The inner cooling chamber 354 of the inner cooling chamber 354 and the coolant chamber 356 of the leakage liquid are provided in the inner cooling chamber 354 and the gland packing weaving method at the same time include eight strand weaving 358 and bag weaving 359, (361), an O-ring (362), a stopper (363), a middle ring The seat ring 366 and the driven ring 367, the quenching 368 and the culling 369 are provided at the handle 371 and the sealing section 365 at the same time while the handle 371 and the partition wall 372 are provided with the axial The balance hole 376 and the balance hole 376 are formed in the balance hole 374 and the unbalance 335 so that the pressure 374 acting on the impeller front surface and the pressure 375 acting on the impeller rear surface can be adjusted by the pushing load 373, The discharge pressure 381 of the front wear ring 380 of the balance hole 376 is provided to the rear rotation bearing ring 382 and the rear wing 384 At the same time, the pressure distribution and the impeller arrangement shaft portions 390 of the multi-stage pump of the impeller 385 are constituted by the distributing and inputting devices of the reactor installation of the nuclear power plant equipped with the cooling method 391 of the mechanical seal, The pump 393 is connected to the impeller arrangement 386 of the multi-stage pump by a return pipe 370, The pumps 393 provide the water hammer action 389 while the main problematic equipment during the pump operation is the nuclear reactor facility main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, (811) preventing disaster prevention.

Referring to FIG. 3G, there is shown a conventional nuclear waste disposal system for a nuclear waste disposal system according to the present invention. And a plurality of valves formed on the prime mover,

3G, the valve body 404 is provided with a plurality of sluice valves 403 in the fire pump and prime mover of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant, The valve cover 405 and the sleeve 406 and the packing press 407 and the packing press nut 408 and the valve 409 and the handle 410 and the handle nut 411 and the packing 412 At the same time, the wedge gate valve 413 is separated into a single valve 414 and a flexible valve 415 while a parallel slide valve 416 and a double disk gate valve 417 are distinguished while the stop valve 418 is a flange- A valve body 425 and a valve cap 425. The body 421 and the bonnet 422 as a lid are separated from each other by a valve body 419 and a flange type angle valve 420, 426, a handle 427, a cover fitting ring 428, a packing presser ring 429, a packing pusher 430, a threaded fitting 431, The packing bolt 433 and the packing 434 and the pin 434 and the cover bolt nut 435 and the packing bolt nut 436 and the handle nut 437 and the detent screw 438 and the washer 439 The valve presser 442 is connected to the plane pusher 442a, the conical pusher 442b, the spherical pusher 442c, and the stator pusher 442d, while the valve pusher 442 is connected to the gasket 441 and the packing 440. [ Type cock 443 is divided into a bronze threading main cock 445, a cast iron flange type land type 446 and a bronze threading gland cock 447, while the two-type cock 444 The check valve 451 is divided into a swing type check valve 452 and a lift type check valve 453 and at the same time, The body 454 is provided with a nuclear reactor plant reactor facility having a dual structure block tank dust collector for treating nuclear waste with a cover 455, a disk 456, disk pins 457 and plugs 458, Body 1 is composed of a disaster prevention block allocation control unit input device connection structure of the internal atomic power seolbibu 811.

As shown in FIG. 3G, in a plurality of sluice valves 403 of the fire pump and the prime mover of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant, the passive expansion valve is manually The expansion valve is used for a small capacity such as a domestic refrigerator. The pressure in the evaporator is adjusted to a constant value by controlling the pressure in the evaporator In addition, the thermodynamic expansion valve is widely used today, and it is a device that operates completely when the liquid refrigerant exits the evaporator and operates as gasified, and it is used for the direct inflatable evaporator. The valve is made of stainless steel, the valve seat is made of monel metal, and Bellows is made of phosphorus The float valve of the rich valve 492 is a valve used for the monolithic evaporator and is a low pressure side rich valve for constantly controlling the liquid level in the evaporator. The valve is opened and closed according to the amount of refrigerant in the evaporator. The structure of the float and the arm is made of cast iron or steel plate in the brass surge chamber. The valve is made of stainless steel and the valve seat is made of brass use. The float valve also has a high-pressure float valve for adjusting the amount of refrigerant on the high-pressure side.

As shown in FIG. 3G, the pressure adjustment of the refrigerant to the fire pump of the internal nuclear power plant 811 of the reactor installation main body 1 of the nuclear power plant and the plurality of slew valves 403 of the prime mover In the configuration of the valve 493, the pressure regulating valve 493 is used to keep the temperature of the refrigerant vaporized in the evaporator constant regardless of the load in the evaporator, and this purpose can be achieved by having the pressure in the evaporator 493 .

However, in the configuration of the solenoid valve 494 as described above, the solenoid valve 494 is opened and closed by the action of the electromagnet in the same manner as described above. It is a separate valve to operate.

This is because the electromagnetic coil is attached to the glow valve. When the current flows through the coil, the plunger with the needle valve is moved upward by the electromagnet to open the valve. When the current does not flow, the plunger falls down by gravity. It is installed in front of the expansion valve to prevent the refrigerant liquid from flowing into the evaporator when the compressor is stopped.

As shown in FIG. 3G, an automatic water supply valve (not shown) for the fire pump of the internal nuclear power plant 811 of the reactor installation main body 1 of the nuclear power plant and a plurality of slew valves 403 of the prime mover 495, not shown), the auto water valve is mounted on the outlet side of the condenser of the freezer (on the outlet side of the cooling water), which is used to increase or decrease the amount of water supplied to the condenser automatically in response to the change in load of the compressor. Or a mechanism in which a valve is installed and the valve is moved up and down by the high-pressure gas pressure of the compressor.

As shown in FIG. 3G, a plurality of sluice valve (403) facilities constituting a fire pump and a prime mover of the nuclear reactor main body (811) of the reactor main body (1) of the nuclear power plant, A packing press 531 is attached to the body 529 of the nipple 496 and the packing box 530 and a handle 533 and a disk 534 are provided in the nipple 532 in a general type faucet Resistant packing 536 and a packing 537 of an aging resistant material are disassembled and assembled into a gasket 538 and a disk packing 535. [

The equipment that opens and closes the flow of water and water directly connected to the end of the water supply hot water pipe is called as a faucet. The material of the faucet is made of bronze casting and brass casting in general. Nickel or chrome plating is generally used to prepare it. The structure and part names are as shown in the figure, and the currents for the general building equipment are shown in the figure, and the faucet specifications are as follows.

Standard faucet specification sheet

The general type faucet 496 formed in the inside of the building is extinguished by a fire extinguishing piping pump fire extinguisher to a plurality of connecting socket portions. The facility is also installed in the nuclear reactor facility (811) of the nuclear reactor main body 1 of the nuclear power plant

As shown in FIG. 3G, the number of the sluice valves 403 installed in the fire pump and the prime mover of the internal nuclear power plant 811 of the reactor installation main body 1 of the nuclear power plant, The previous equipment is described as follows

Before the index, there are two types of index. It is used to regulate a part of water quantity of water supply device or to open and close it. It is installed in a position where it can freely open and close in the middle of a high tank water vertical up tube, a shower vertical up tube and an upper vertical up tube. There are two types of joints with pipe: screw joint for steel pipe and soldering for connection pipe.

(497), which sets the limits of water supply for the entire water supply system, is provided in the ground water distribution branch of the highway and site boundary, unlike before the bubble.

The exponent (497) is usually protected by a pre-exponential box and is not open or closed at will, except for special cases, such as water leakage.

As shown in the drawing, the structure of the exponent field 497 is such that, when the plug is rotated by 90 degrees, water flows, while when it is rotated by 90 degrees, the flow of water is stopped

At the next corporation stop, 498,

It is used to divide water supply pipe less than 40mm from the water supply pipe buried in the highway. The diameter of the water before the fraction is 13, 16, 20, 25mm. Attach directly to the supply pipe of a cast iron or asbestos cement pipe or by using fractional saddles. Before the fountain can be installed, it is possible to use a monolithic perforator (a machine that punctures the water pipe without interrupting the water) without stopping the water in the water pipe.

As shown in FIG. 3G, the fire pump of the nuclear reactor main body 1 of the nuclear reactor plant 1 and the plurality of slew valves 403 of the prime mover, )

It is a rich type valve used to supply water to the water tank. It has a ball made of copper or synthetic resin at the end of the lever,

When the water level reaches a certain level, the valve is automatically closed by buoyancy of the ball, so that a certain amount of water is always stored in the water tank. This All-tap (499) is small-sized and large-sized, depending on the type of fast and doubles.

Referring to FIG. 3H, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, The way of operation of the road,

As shown in FIG. 3H, the above-mentioned distributing and inputting device of the nuclear reactor power plant of the above-mentioned each valve NORMAL POWER OF THE NATIONAL POWER PLANT (811) Type strainer outer shape 501a, the U-type strainer end face 502b, and the V-type strainer 392 are provided in the plurality of strainer 392 constituting the branch line 497 and the water outlet 498 of the pipe 14, While the tube fixing metal 504 is provided with the turnbuckle support band 505, the support band 506, the roller support band 507, the vertical tube 506, And a bottom band 510. The trap 511 is also provided with an angled thermal trap 522 and a straight thermal trap 523 and a bucket trap 524 and a bottom- 525, a top-down bucket kit trap 526, a float trap 527, (1) Nuclear power plants with a double structure block tank dust collector for treating nuclear waste with steam traps (528) Disaster prevention control section of nuclear power plant (811) .

As shown in FIG. 3H, the above-mentioned distributing and inputting device of the nuclear reactor power plant of the above-mentioned each valve NORMAL POWER OF THE NATIONAL POWER PLANT (811) Type strainer 501 and the U-shaped strainer 502 are provided with a V-type strainer 503 on the strainer 392. The strainer is used for piping such as steam, water, and oil, It is used for the purpose of removing. In general, 2 B or less is a bolt screw type and a cast iron flange type is used for 2½B or more.

The Y-type strainer 501 is provided with a cylindrical metal net in a Y-shaped body inclined by 45 °, and the resistance against the fluid is set by the strainer 392. The strainer 392 has Y-, U-, V- , The fluid flows from the inside to the outside of the net, and the opening area of the metal net to remove the impurities by providing a plug at the bottom is about 3 times the nominal diameter cross-sectional area, and the mesh is easily exchanged.

As shown in FIG. 3H, the above-mentioned distributing and inputting device of the nuclear reactor power plant of the above-mentioned each valve NORMAL POWER OF THE NATIONAL POWER PLANT (811) And a U-shaped strainer 502, which is a vertically-inserted tubular cylinder with a filter net in the body of cast iron, flows outwardly from the inside of the net. Because the flow direction of the fluid changes perpendicularly to the structure, resistance to fluid is greater than that of Y-type strainer, but it is easy to repair and inspect. It mainly consists of oil strainer.

In the V-type strainer 503, a metal mesh is formed in a V-shape in the cast iron body, and the fluid passes through the mesh and the dirt is filtered. However, since the structural fluid flows linearly through the strainer, And a bucket trap 524 and a bottom-up type trap 524 are attached to a trap 511 of a pipe fitting for easy exchange and inspection of the filter net, and an angled thermal trap 522 and a straight thermal trap 523, The steam trap separates the condensed water and the air generated in the radiator or the steam pipe from the steam so as not to allow the steam to pass therethrough but to discharge the condensed water only to the steam trap 528. The steam trap 528 is connected to the top trap 525 and the float trap 527, It is a device that discharges to a water pipe. Generally, it is installed at the end of the steam pipe, the radiator outlet or the place where the condensate collects. Types of steam traps include thermal traps, bucket traps, float traps, and impulse steam traps (528), depending on operating pressure, emissions, and so on.

As shown in FIG. 3H, the above-mentioned distributing and inputting device of the nuclear reactor power plant of the above-mentioned each valve NORMAL POWER OF THE NATIONAL POWER PLANT (811) The heat traps 523 are low pressure type and high pressure type depending on the operating pressure. The traps, which are divided into an angled type and a straight type according to the type, are also called a silpone trap. The bellows are made of a thin plate of phosphor bronze, And the steam is supplied to the outlet of the radiator at the same time. When the steam is evaporated around the bellows, the bellows expands to expand the bellows. When the valve 301 is closed and the drain 301 or the air is heated, And the pressure is low, so that a radiator of less than 1 kg / Used in the lab, and also passes through the air used because the air-liter frozen (air retern) water exchange method or a vacuum tube system of a steam pipe.

 As shown in FIG. 3H, the distribution valve of the nuclear reactor power plant of each of the above-mentioned valves is operated. In the nuclear reactor system of the nuclear power plant, The buckets of the buckets are operated by the steam pressure, so that the pressure difference between the steam pipe and the return pipe is reduced When the pressure difference is 1 kg / ㎠, theoretically, the condensate can be pushed vertically up to 10.33 m, but it is actually less than 8 m. In addition, the low pressure steam pipe which does not have enough pressure difference does not discharge the condensed water. At the same time, the bucket trap is suitable for the high pressure steam pipe. The return pipe can be piped upwards from the trap. .

First, in the bottom-up bucket kit 525 facility, the bottom-up bucket kit 525 facility is also referred to as an open trap. When the condensate enters the trap, the bottom- B) float with its buoyancy and close the valve (C). When the condensate flows slowly overflowing into the kits, the bucket becomes heavy and loses its buoyancy and sinks, opening the valve (C). When the valve is opened, the condensate is discharged by the pressure of the steam acting on the water surface in the bucket.

In the following top-down bucket-trap (526) installation, the bottom-up bucket kit (526) arrangement is such that the bucket is upside down relative to the bottom up and when steam and condensate enters from under the trap, the bucket is filled with steam The buoyancy is lifted up and the valve closes. The steam in the bucket is discharged to the small hole in the upper part of the bucket according to the accumulated condensed water. When the steam is discharged, the Bucket loses its buoyancy and descends to its own weight to open the valve and discharge the condensed water and air. At the end of the discharge, the bucket is again filled with steam, buoyant, and the valve closes.

As shown in FIG. 3H, the distribution valve of the nuclear reactor power plant of each of the above-mentioned valves is operated. In the nuclear reactor system of the nuclear power plant, The float trap 527 is also referred to as a so-called multipass trap, and the valve is opened and closed by using the buoyancy of the float. At the same time, the operating pressure is set to a low pressure, a medium pressure (about 4 kg / Air heaters, heat exchangers, etc., and it is not possible to discharge air. Therefore, when necessary, the thermal air is used in combination to provide a low temperature air discharge through the upper air discharge pipe.

As shown in FIG. 3H, the distribution valve of the nuclear reactor power plant of each of the above-mentioned valves is operated. In the nuclear reactor system of the nuclear power plant, The impulse vapor trap 528 has a structure in which the valve is continuously opened and closed in accordance with the temperature change in the cylinder and the structure is extremely simple and small compared with the amount of the drain to be handled, It can be used for high pressure, medium pressure and low pressure, but the drawbacks are that the steam leaks somewhat.

As shown in the figure, the structure is composed of a disk-shaped valve rod and a disk sheet. At the same time, in the drain trap (not shown), the drain trap is constructed such that the gas generated in the drain pipe flows through the drain pipe The structure is made of a cast iron, a bronze brass, a porcelain, and the like. The structure is such that water is allowed to flow through a part of the drainage device and water is freely passed through, At the same time, the depth of the trap seal is 50 ~ 100mm. If it is lower than 50mm, there is a possibility of gas or air passing. When it is deeper than 100mm, the self-cleaning force becomes weak, which causes debris on the bottom of the trap.

As shown in FIG. 3H, the distribution valve of the nuclear reactor power plant of each of the above-mentioned valves is operated. In the nuclear reactor system of the nuclear power plant, The drain trap can be largely divided into a pipe trap and a box trap in the structure. Thus, in a vertical piping support metal equipment, when a vertical pipe penetrates the floor, a sleeve is placed on the bottom to freely expand and contract the pipe, The supporting metal is installed in the middle of the layer. The support interval will be described later in the construction method.

The tube fixing metal 504 of the stationary metal has a steel buckle support band 505 and a support band 506 and a roller support band 507 and a vertical tube for band 508, Band 510 or the like

The purpose of the pipe is to prevent the tube from moving with respect to the expansion and contraction of the pipe and to securely attach the pipe to the building. At the same time, The gasket 32 is sandwiched between two flanges and is compressed by the tightening force of the tightening nut to prevent the gasket 32 from leaking close to the flange. It should have some elasticity. The reason is that if there is no elasticity in the gasket 32 when the bolt is increased for some reason, leakage will occur immediately.

The following points should be considered when selecting gasket for piping.

First, the physical properties of an object should be taken into account, and the temperature, pressure, gas body and liquid separation, density, and viscosity should be taken into account. The following chemical properties of the object should be taken into account, and the chemical composition, stability, It is necessary to pay attention to volatility, flammability and explosiveness, and the mechanical properties of piping gasket should be evaluated by considering all the conditions such as exchanging difficulty, vibration, degree of internal pressure and external pressure, The first is rubber products and processed products, the second is plant fiber products, the third is animal fiber products, the fourth is mineral fiber products, and the fifth is gaskets. Is a synthetic resin product, and the sixth is a metal product, and the main thing is as follows.

The above rubber streams and their processed products are widely used as gasket materials since they have high elasticity and are not eroded by chemicals. When strength is required, use of a rubber or metal mesh blend of cloth (cloth, 75) is provided, but at the same time, for the selection of natural rubber, the rubber is characterized by a very high elasticity, And alkaline, but are poor in heat resistance, rubber products and their processed products which can not be used in piping handling a high temperature of 100 ° C or higher are cured at -55 ° C, but at the same time, And thus it can be used for general cold water, drainage and air piping, but it can not be used for oil, steam, hot water, refrigerant piping, etc. As a distributing and inputting device of a nuclear reactor, ) Prevention of disasters Preventive control Mechanism of operation showing the configuration Gasketing of the reactor installation of the nuclear power plant A.

Referring to FIG. 3i, the conventional nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention has a conventional capacity structure shown in an internal nuclear power generation facility 811. The operation of the diaphragm pump 144 and the operation of the wing pump 327 are shown in the drawing. The inside of the rotary pump 337 and the external gear pump (326) The other rotary pump rotor (338) can be configured to operate in partial operation,

As shown in FIG. 3i, the distribution input device of the nuclear reactor of the nuclear power plant according to each of the above-mentioned pump types Operation mode showing the disaster prevention prevention control section of the nuclear power generation facility (811) Distribution method of the nuclear reactor power plant The facility includes an electric motor (not shown) which constitutes a reciprocating pump plunger pump 148 of a volumetric pump type in the distribution input unit of the nuclear power generation facility 811 showing the configuration of the hydrological control control unit of the dam of the nuclear power generation facility unit 811 192 and the suction and confluence pipe 3 are connected to each other so that the operation of the diaphragm pump 144 and the operation of the wing pump 327 are performed simultaneously with the connection of the discharge joint pipe 4 and the belt carver 261, A rotary pump rotor 338 inside the pump 337 and the external gear pump 326 is provided with a discharge port 270 at the suction port 269 to provide water movement and a double structure (1) Nuclear Power Plant (811) Disaster Prevention Control Section of Nuclear Power Plant showing the construction of preventive control unit. (1) Distribution facility of nuclear reactor plant. (2) have.

Referring to FIG. 3J, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, The schematic diagram of the priming pump 339 and the sucking pump 340 in the diagonal view is a view showing the operation of the axial flow pump 341 and the mixed flow pump 342 of the propeller pump 146, (343) Construction of the viscous pump and impeller strainer in the sash construction diagram, side view of the operation of each pump,

As shown in FIG. 3J, the distribution input device of the nuclear reactor of the nuclear power plant according to each of the above-mentioned pump types Operation mode showing the disaster prevention preventive control section of the nuclear power generation facility 811 The distribution device of the reactor facility of the nuclear power plant A plurality of chains are connected to a plurality of gears for replacing the connection of the electric motor 192 constituting the turbine pump 140 and the turbine pump 140 with the rotor 250 of the rotary shaft 198 of the electric motor 192 And simultaneously the suction pump 3 and the suction pump 340 having the discharge coupling pipe 4 and the priming 339 are connected to the axial flow pump 341 of the propeller pump 146 and the mixing pump 341 of the propeller pump 146, The viscous pump 343 and the viscous pump and the impeller 143 are installed in the reactor main body 1 of the nuclear power plant and the discharge position of the positive displacement pump and the deployment position inside the positive displacement pump, Bo (1) of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to each pump type, in which a certain amount of fluid shoveling is provided in the function of the pump, It is composed of the distribution system of the reactor installation of the nuclear power plant showing the construction of preventive control section of the nuclear power plant (811).

Referring to FIG. 3K, there is shown a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, The construction of the side operation showing the manner of operation of the correction tank,

Referring to FIG. 31, the conventional nuclear waste disposal system for a nuclear waste treatment system according to the present invention comprises a main body (1) of a nuclear power plant having an internal nuclear power plant (811) The construction of the side operation showing the manner of operation of the correction tank,

Referring to FIG. 3m, the conventional nuclear waste disposal system for a nuclear waste disposal system according to the present invention comprises a main body 1 of a nuclear power plant having an internal nuclear power plant 811, The construction of the side operation showing the manner of operation of the correction tank,

Referring to FIG. 3n, a conventional automatic building system (hereinafter, simply referred to as a &quot; nuclear power plant &quot; The construction of the side operation showing the manner of operation of the correction tank,

As shown in FIGS. 3K, 3L, 3M, and 3N, the operation of showing the disaster prevention preventive control section configuration of the nuclear power plant 811 of the distributing and inputting apparatus of the reactor facility of the nuclear power plant (34) facilities of nuclear power plant nuclear power plant nuclear power plant, the operation configuration of the automatic collecting tank showing the conventional configuration of the hydrological control unit of the dam of the nuclear power generation facility and the distribution input device of the nuclear power generation facility In the collection tank 34, a pump body horizontal center line PBCL of the centrifugal pump 308, which constitutes a position outside the collection tank 34, A plurality of chains are coupled to the rotation shaft 198 of the electric motor 192 to connect the electric motor 192 and the Centrifugal Pump 308 to each other so that the pump rotational motion is performed, An automatic valve 259 coupled to the tee elbow 44 connected to the pipe 14 located at the center of the outer wall manhole cover 152 located at the front of the tank 34 and the lower end of the collecting tank 34, The motor 192 and the centrifugal pump 308 are provided in the frame 286 while the pressure switch 104 for the low water level is provided with a valve 315 for operating according to the water level, The coupler 315 pushes the flexible couplings 317 into the through holes of the collecting tank 34 with the device 316 for pushing the coupler 315 into the through holes of the collecting tank 34, The main switch button 66, which is a switch for on / off control of each pump, is connected to the flange 28 coupled with the bolt and nut by a hand tool, and at the same time, in the switch input circuit 58 provided inside the louver cover 550, The switch 318 is connected to the suction / discharge switch 285, the flow rate meter for flow rate check 105, The synchronous control module 106 is provided with the shutoff valve 114 and the automatic valve 259 connected to the water supply port 168 to simultaneously supply the metal 539 having a large thermal expansion and the metal 540 having a small thermal expansion, The alarm reset button 545 and the low level switch 546 are connected to the level switch 541 and the high level alarm 542 and the flap 547 and the low level switch 546 are connected to the bus compander alarm 543 and the remote relay alarm 544, A vent pipe connection 554 and a flange connection 555 to the check graduation 552 and the overflow connection 553 to the check nozzle 549 and the float switches 551 to the sound cap 548, ), Which is a connection structure between a switch and a pipeline, for controlling the water storage level in the collection tank (34). (1) Inside the nuclear plant of the power plant (811) (34) Nuclear Power Plant's Nuclear Power Plant (811) Nuclear Power Plant (811) Nuclear Power Plant (811) Nuclear Power Plant (811) ) Prevention of disasters Prevention of regulatory action Mechanism of operation Configuration of distribution facility of nuclear reactor plant nuclear power plant Separate collecting tank (34) Consisting of facility connection structures.

Referring to FIG. 3O, the conventional nuclear waste disposal system for a nuclear waste disposal system according to the present invention comprises a nuclear water treatment plant main body 1 having an internal nuclear power generation facility 811, The structure of the embodiment showing a plurality of solenoid valve actuating assemblies attached to the cylinder, and the configuration of the pneumatic pressure and sensor technology applying method by the configuration of the sensor according to the configuration of the detecting switch integrally,

As shown in Fig. 3O, a solenoid valve 76 (hereinafter, referred to as &quot; solenoid valve &quot;) is provided as a connection structure of the main body 1 which provides a plurality of solenoid valve actuating assemblies attached to the hydraulic pneumatic cylinder, When the solenoid valve pressure switch of the main switch button 66 is manually depressed to the on-time main switch button 66 of the main switch button 66 for the solenoid valve start switch button, the butterfly valve 622 is opened and the main switch button 66 When the off-time main switch button 66 is manually depressed, the connection structure of the butterfly valve 622 is fully closed and the operation is stopped. On the main switch button 66 of the main switch button 66 for the start switch button When the air is compressed by the hand, the butterfly valve 622 connection structure is opened to allow the pressurized air generated in the air compressor 80 to pass through the pipeline connection structure while simultaneously operating the construction machine and the line (1) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal as a connection structure providing a plurality of hatch covers (153) and a plurality of fire doors (154) The solenoid valve body 557 is provided with the oil, air pressure, and sensor technology. At the same time, the solenoid valve body 557 is provided with a cover 558 and a spool Flow manifold 564 and manifolds 565 at the same time while providing a connection to the solenoid valve 559, the spool packing 560, the pilot 561, the coil 562 and the connector 563, The solenoid valve body 557 is provided with the screw bolts 567, the air hose coupling center union couplings 568 and the body coupling union couplings 569, while at the same time, In the form of a body 557 It is also possible to provide a horizontal type 575 including a two position single 570 and a two position double 571, a central vertical type 572 and a vertical type 573 and a horizontal type 574 and fittings, The body symbol of the body 557 includes a direct tubing type 582 providing a connection with the microswitch 581 in a single 576, double 577, and loop 578, eye 579, A pneumatic cylinder operating regulation for providing a connection structure with the damper spindle 584 of the fire damper 583 for controlling the air flow rate of the intake port 585a and the discharge port 585b of the doctor ventilation 585 to the base piping type The solenoid valve body 557 includes an internal connection structure of the reactor installation main body 1 of the nuclear power plant having a double structure block tank dust collector for treating nuclear waste, a Bellows butterfly valve 622 of the construction machine connection structure, And submersible control device Connection structure Doctor ventilation (38) The connection structure provided with the compressed air generated in the condenser is provided with a connection structure of a butterfly butterfly valve (622) of a diving control device of a piping line equipped with pipeline automatic pneumatic conveying device (916) Double structure block for waste treatment Nuclear power plant reactor main body with tank dust collector (1) Distribution and input device of hydrologic control section of the dam of internal nuclear power plant (811), each instrument and switch And piping lines, and each pump is provided with operating methods, or the distribution device of the reactor installation of the nuclear power plant. Operation mode showing the construction of the preventive control section of the nuclear power generation facility (811) of the nuclear power plant Distribution of the reactor facilities of the nuclear power plant The input piping line automatic pneumatic conveying system (916) consists of connecting structures for the operation of the nuclear power plant.

The 5 port solenoid valve is provided with a spool 559 and a spool 558 to the valve body 557 and the cover 558 because the solenoid valve 76 has many different models. The coil 562 is attached to the pilot pilot (PILOT) 561 to the left side of the coil 562 in the two position single 569 and the two position double 570 is also attached to the left side of the valve body 557 (569) and two-position double (570), which are attached to the left and right sides of the coil, respectively, on the right side. In addition to the above-mentioned standard products, order products include Center Closed 577 and a 3-position center pressure 578 and a center exhustation 579 in a variety of structures. The products are represented by symbols S (S) as shown in FIG. SINGLE, 575) and double (D, Double, 576) are standard products. J (Center Exhaust, 579) to the Center Closed (577) and I (Center Pressure, 578) are separated into the above-mentioned custom-made products, Is connected to the air hose 109 in front of the cylinder 126 as a fire damper opening mechanism of the ventilation device of the ventilation vent of the outlet of the doctor ventilation when the fire occurs, and is widely used in a building or other industrial and marine vessel interior

3O, the manifold type of the manifold system includes (DMQF100-MOO-S) and (DMQF100-MOO-L) of the 5-port pilot type (M5, ), Which is described in the following specification.

As shown in Fig. 3O, in each of the solenoid valve specifications,

As shown in Fig. 3O, the valve 76 is formed in a mounting form of a direct piping type 581 and a base piping type (valve seat 582) in a mounting manner, (DC, DC 12V) and a DC (direct current 24V) are connected to a coil (L, 571) and a vertical type (L, 572) The solenoid valve body 557 has an inlet and an outlet which are attached to the solenoid valve body 557 and have a screw tap and a machining hole dimension Described as follows (distance dimension description is omitted)

As shown in Fig. 3O, the screw holes of the air hose coupling former 56 and the union coupler 56 are formed as follows.

As shown in FIG. 3O, the pressure extinguisher installed in the elevator machine room and the pump extinguisher installed in the cable cachar 256 so that the initial evacuation and lifesaving structure of the present invention is less than one second The detailed configuration is performed with the drawing.

As shown in Fig. 3O, the sign of the state before use of the product of the air solenoid valve 76 will be described as follows.

As shown in FIG. 30, in a detailed description of the use conditions of the fluid,

First, the filter should have a filter with a filtration degree of 5 μm or more. If the drain is large, the pneumatic equipment may malfunction when the valve is used for the first time.

As shown in Fig. 3O, when the drain control of the product of the air solenoid valve 76 is difficult, use of the filter with the auto-drain is provided.

When there is a large amount of carbon tar in the air compressor, a large amount of carbon tar can be attached to the inside of the valve, making it impossible to operate. Therefore, an air compressor which generates less carbon tar is used, but an oil mist separator is used.

Regarding other conditions of the fluid to be used, the compressed air purification system of the pneumatic equipment manufacturer is taken into consideration.

The following is about lubrication

(ISO VG32) is used for lubrication if it is necessary to lubricate. However, if the lubrication is interrupted during use, it may cause malfunction due to loss of initial lubricant. Must be used contiguously

Especially, do not use spindle oil.

The following leakage voltage will be described as follows.

When the power is cut off, the leakage voltage remaining at both ends due to leakage current should be suppressed to 3% or less,

If a C-R device is used for contact protection, the leakage voltage flowing through the C-R device may increase the leakage voltage.

Particular attention should be paid to the contactless relay because it may have a built-in protection circuit.

Fourth, for low temperature use

Although the temperature can be used up to -10 ° C, care must be taken to solidify or freeze the moisture of the drain 301

If you are concerned about freezing, install an air dryer.

Next,

When the double solenoid type is used by instantaneous energization, the energization time should be 0.1 second or more.

As noted above, it is a note of the solenoid valve prior to use according to the description of the warning sign.

According to warning signs

In the detailed description when selecting and handling pneumatic equipment,

First, the proper selection and determination of pneumatic equipment should be done after determining the design or specification of a function with expert knowledge and experience

The use of pneumatic equipment is handled by a person with sufficient knowledge and experience

Compressed air is very dangerous if it is handled incorrectly, so maintenance personnel are responsible for the maintenance of the equipment.

After confirming the safety device, operate the pneumatic equipment and confirm that the initial condition of the system and the compressed air are completely exhausted when disassembling and disassembly and assembly.

The maintenance of the compressed air in the condition that the air is not branched may cause injury to the human body due to the malfunction of the machinery.

If this condition is not used under normal conditions, or when controlling other harmful fluids other than compressed air or other gases, consult the manufacturer and consult with the manufacturer of the pneumatic equipment for safety reasons. Remove the hazard.

Therefore, before using a pneumatic device, the person skilled in the art should confirm once again whether the specification to be ordered is correct, and then thoroughly clean the inside of the pipe before piping or other cleaning, so as to prevent foreign matter and other dirt from entering the pipe

If Teflon tape is used, it should be rolled around 1.5 to 2 threads of the screw.

In the case of using the intermediate stop valve as described above, care should be taken not to cause leakage in the piping between the valve 76 and the cylinder 126. In the case of precise position control, precise stopping due to compressibility and minute leakage, If you need to stop for a long period of time, contact the manufacturer to solve the problem. If you do not tighten it with excessive force when piping or if you do not tighten it with proper torque, Therefore, piping should be installed with the following proper torque.

For a more detailed description of the operating environment

Install in a place with corrosive gas, chemical solution, seawater, rainwater, water vapor, etc. Install it in a place where water, oil, etc. are temporarily installed. It should not be used in an explosive environment by attaching a silencer to the vent port of the valve. It should not be used in an explosive environment. It should block radiant heat in an environment where there is a heat source by avoiding direct sunlight. (1) Install and install the pressure sensor and the pneumo-pressure sensor in the internal nuclear power plant (811) of the nuclear power plant equipped with a double structure block tank dust collector for nuclear waste treatment, do.

Referring to FIG. 3P, there is shown a conventional structure of an internal nuclear power plant 811 of a reactor facility main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for treating nuclear waste according to the present invention. It shows the operation method of the airship. It is an operational composition diagram according to the typhoon and the weather forecast inside the atmosphere. It is a type of fire and disaster prevention method that constitutes the initial evolution within one second after installing the injection nozzle and bed nozzle inside and outside the building. ,

As shown in FIG. 3P, the distribution input device of the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment is provided with various kinds of devices such as fire, drought, heavy snow, In order to prevent various natural disasters, Kelly's hot air balloon 588 is inserted into the reactor main body 1 of the nuclear power plant, which provides the flood control facility, to the hot air balloon 586 of Mongolia and the hot air balloon 587, (589) is equipped with a rooftop tank and a pressure tank which are provided in the fire area in preparation for firefighting before and after the occurrence of forest fires and at the same time, (393), which has a connection structure of a water pump and a fire extinguisher, and at the same time, the prevention of forest fires is simplified. A carbon dioxide gas fire extinguisher equipped with a double pipe fire hose and spray nozzle assembly, a three stage stepped pump fire extinguisher, and an amendment tank, an alternate manometer turn type level balancing pipe. (647) and a large number of anchor bolts (395) located in high and low mountains (395) to replace fire trucks in the dual-pipe fire-fighting hose, which is stored in the double vinyl tent nozzle form of the ridge line within one second 133 and a wire rope (19) provided with a driving wheel roller (135) for driving wheel rails (160), and a cable cable (256) for controlling the position and movement of the yellow pipe mixture fire water and the double pipe fire hose for supplying fire water, The building rooftop fire fighting cabin 394 includes a vibration control unit 396, a speed control unit 397, an electric motor rotation transmission 398, a disk brake unit 399 (137) Tongue winch for controlling the opening and closing of the gate with ropes or chains attached to the body (128) Fire extinguisher (124) Fire extinguisher fixing pin (128) Locking device (129) Life-saving tube ) Of the ropes 131 and the carbon dioxide of the incombustible gas 164 and the carbonic acid gas 174 as the halon gas 175 so as to perform the initial evolution within one second after the spray nozzles and the bed nozzles are installed inside and outside the building, It is equipped with double structure block tank dust collector for nuclear waste disposal to adjust the scale of fire and disaster prevention by equipped with flood control facilities to prevent many natural disasters such as dust, snowstorms, typhoons, typhoons, floods and droughts and landslides (1) Internal Nuclear Power Plant (811) Disaster Prevention Control Section of the Nuclear Power Plant (1) In order to control overcoming of the flood by the distribution control unit, each instrument, switch and pipeline (811) of the nuclear power plant (811) Operation mode showing the configuration of the preventive control part of the nuclear power plant The distribution device of the reactor facility of the nuclear power plant Piping line Automatic pneumatic transportation system (916) Landslide with connecting structures It is constructed to operate nuclear power plants with harmonization control facilities to prevent many natural disasters.

In the past, the dams were not equipped at all with the same number of revolutions as the round water tanks, causing landslides in the rainy season, causing the flood victims to take away the lives and property of the people, and low- Due to inundation of living area, livestock industry and industrial complex, wastewater from living and livestock industries flows into rivers and flows into the sea, so that marine creatures move to rivers, so that fishes and shellfish can not freely scatter in the rivers of valleys In order to contribute to national economic development, four major river revitalization projects and the restoration of the world's four major fisheries, it is possible to reduce the damage of life and property from a large number of floods efficiently and rapidly in a short period of time A comprehensive measure is urgently needed,

 Therefore, in order to adjust the overcoming of flood damage with the disaster prevention control section of the internal nuclear power plant (811) of the reactor main body (1) of the nuclear power plant having the double structural block tank dust collector for treating nuclear waste according to the present invention Each pump is connected to each instrument and switch and pipeline. Each pump is operated by each pump operation method. Distribution of Nuclear Power Plant's Nuclear Reactor Facilities Nuclear Power Plant (811) (916) Landslides due to the connection structures are constructed to operate nuclear reactors by means of flood control facilities to prevent many natural disasters. At the same time, nuclear reactors of nuclear power plants In addition to the dam gates stored in the facility main body 1, In order to make the marine organisms move to the river and to be able to scatter fish and shellfish steadily in the rivers of the valleys by constructing a device and constructing several fish tunnels for the underwater dam of the river middle dam, germanium It is possible to maximize ecosystem restoration activities by restoring the natural ecosystem order and balance by improving the level of the geological level by introducing the lipid level into the ocean to improve the lipid level. In the drought period that is made up, there is a good quality water supply that can be used for three years, such as drinking water, drinking water, industrial water, industrial water, To provide a continuous supply of water resources, The offshore hydropower dam facility is divided and divided into the control shaft and the distribution shaft by the distribution and input device of the construction machine. The offshore hydroelectric power generation dam facility and the offshore hydroelectric power generation dam facility are provided at the same time. Location Movement Power transmission to the control part of the construction machinery and the hydro-power generation control part of the hydro-hydroelectric power generation Control part and harmful red tide prevention Preventing disaster prevention Preventing control of the dam (1) of the nuclear power plant having the structural block tank dust collector, and (811) the disaster prevention prevention control section of the internal nuclear power plant (811).

Hereinafter, in the distribution apparatus of the nuclear power plant for reducing the effective flood damage of the multipurpose dam according to the prior art level, the amount of water flowing out to the flood season is about 43% of the total amount of domestic water resources, In addition, at the same time, it is necessary to store and use the dam facility when necessary. In addition, it is necessary to provide representative facilities used in the Southeast Asian monsoon climate region such as Korea, and at the same time, Will be described in detail as follows.

First, as shown in the drawing, a construction equipment excavating machine is divided into a bulldozer 855, a scraper 859, an excavator 856 and a luther The diesel pile hammers 883 and the steam hammers 884 are separated by a pile driver 882 and a steam hammer 884. The hydraulic cranes 885 and the tower cranes 886 are connected to a crane 861, It is separated into a crane 887 and a truck crane 888 and at the same time the loading machine loader 857 is separated into a shovel loader 857a and a payloader 857b to a payloader 857c, A tandem roller 890 and a tamping roller 891 and a tire roller 892. The next packing machine is divided into a concrete finisher 866 and an asphalt finisher 871 ), An asphalt distributor (871a) and a concrete The dump truck 860 and the tractor 893 and the trailer 894 and the forklift 858 are provided at the same time as the separating plant 865 and the asphalt mixing plant 870 and the aggregate duster 873, The dredger 879 is divided into a pump dredging line 879a and a bucket dredging line 879b and a dredging dredger 879c and a grab dredging line 879d in the range to which the dredging line 879 is connected. The main construction machine is provided with a separator by a perforator 876 and a crusher 874 and an air compressor 875. At the same time, construction machines are constructed at the upper end of deck deck of the strut tank upper barge hull 591, An engine generator 226 equipped with an underwater light 843 provided in the barge hull 592 and an unmanned camera 184 is provided at the position of the deep sea bottom where the lower tank barge hull 592 is provided at the same time as providing the use for transportation and towing. Is isolated from each construction machine body, (52) Dual structure block tank for treatment of nuclear waste constituting regulation of nuclear power plant with operating device (52) Nuclear power plant with a dust collector The inside of the nuclear reactor plant main body (1) It is the distribution input device of the transportation transport part (811c) of the locomotion construction machine and is selected for the nuclear power station facility and reactor facility.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following, a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor main body 1, The details of the range of construction equipment of nuclear power plant equipment and reactor equipment according to the prior art level constituting the equipment, such as scope of construction machinery management law, shall be as follows.

Referring to FIG. 3q, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste disposal according to the present invention, the transportation transport section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 ) Construction of a marine power plant body dock showing a construction machine A plurality of construction machinery bulldozers (855) showing the arrangement of construction machine position adjustment of hull position movement of marine hydroelectric power plant flood control consoles (593,594,595) constituting at the upper part of the deck of a ship hull (SDU) The strabismus configuration of the road,

As shown in FIG. 3q, the construction machine dispensing and dispensing apparatus doser 811c of the hull position shifting construction machine of the reactor facility nuclear power plant 811 of the nuclear power plant has a doser It is a soil construction machine that is equipped with straight and angled type asphalt boards and attaches an auxiliary device such as a ripper and a lute to the rear. A compound term for a bull resting machine, it is a construction machine equipped with a doser that provides a powerful pushing action to liberate bulls from work, as a dispensing device for the hull position shifting construction machinery control section of the nuclear power plant (811).

As shown in Fig. 3q, the use will be described as follows.

As shown in FIG. 3Q, the construction machine dispensing and dispensing apparatus doser 811c of the hull position shifting construction machine of the reactor facility nuclear power plant 811 of the nuclear power plant is provided with a doser (In ton or kg), ie, its own weight. The economical working distance of the doser is 10100m. The distance between the shovel and dozer is less than 100m. In addition,

The following table shows the power transmission sequence of the doser,

The calculation of the workload of the doser is explained as the following table.

1) Workload per hour:

Where q is the capacity of the earth plate (m ³ ), f is the soil conversion factor

E : Working efficiency () C _m : 1 cycle time (min)

Blade (earth plate) Capacity:

here. Q : Blade capacity (m ³ )

B : Blade width (m)

H : Blade height (m)

 1 cycle time

(Min) L : working distance (m) V ₁ : forward speed (min) V ₂ : reverse speed (m / min) t :

A detailed description of the traction force is as follows.

Here, ((coefficient of friction)

( W : Vehicle weight (kg))

Traction horsepower (H)

only,

As shown in FIG. 3Q, the crawler type low loader 855 of the bulldozer 855 showing the configuration of the construction machine dispatching apparatus of the transportation transport unit 811c of the hull position moving construction machine of the nuclear reactor power plant 811 of the nuclear power plant 855b and 855b and 855b and 855b and 855b and 855b and 855b and 855b and 855b and 855b and 855b and 855b, 855b and 855b, respectively, of the hinged dozer 855a and 855b, 855i) In the attachment equipment of the bulldozer showing the strabismus configuration of the construction machine connection structure and the structure of the power transmitter of the dozer, the straight lake dozer is attached to the straight dozer by the rake instead of the shovel. It is used exclusively for the excavation of rocks. The following backhoes are used for burial of pipe wires. The following hydraulic rippers were used for excavation of drainage gutters. The following hydraulic rippers were used for crushing, roots and rock scraping of grounds and pavements that were difficult to excavate from hard and hard ground. The towing winches were used for traction of heavy timber. Snow plows were used for snow removal The sketch loader is used to transport wood, pump round objects, and to load cranes or heavy objects. The rock bucket is dedicated to the loading of rocks and the shovel is used for excavation of mountains and cliffs by the hull locating and construction machinery of the nuclear power plant (811), the hull position of the marine hydroelectric power station floodplain (593,594,595) (811c) of the hull position moving construction machine of the nuclear power plant (811) of the nuclear power plant which provides the moving control and disassembly assembly.

As shown in FIG. 3Q, a transportation structure 811c of a hull position moving construction machine of a nuclear power generation facility 811 provided inside a reactor facility body of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The distribution input apparatus includes nuclear power generation facilities 811 for controlling the flow of nuclear power into the nuclear reactor main body 1 of the nuclear power plant constituting the moving control and disassembling assembly of the marine hydroelectric power plant floating posture 593,594,595 (811c) Construction machinery dispensing equipment consisting of parts of power equipment of construction machine dozer, replacing earthwork equipment of bulldozer attaching equipment, And the structure of the power transmission device 855j of the dozer includes a suction pump 855k for the cam other device and a cooling system 855m and a final gear device 855k in the engine 855l. n) to the idler 855p of the driven wheel and the idler 855p of the bogie 855q to the idler 855p of the bogie 851q of the construction machine, (811c) Double structure block tank for treating nuclear waste at the upper part of the hull deck (SDU) of the hull dock (593,594,595) with construction machines by the construction machinery Nuclear reactor main body of the nuclear power plant with dust collector (1) The power plant (811) consists of the construction and transportation machinery (811c) of the construction machinery.

Referring to FIG. 3r, a nuclear reactor plant main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for treating nuclear waste according to the present invention, an internal nuclear power generation facility 811, A tamping truck 860 and a concrete bumping plant 865 and a machine roller 889 and a tamping roller 891 and a tire roller 892 and a trailer 894, Straight configuration of operation Road,

Referring to FIGS. 3Q and 3R, the construction machine dispensing and dispensing apparatus doser 811c of the hull position shifting construction machine of the nuclear reactor power plant 811 of the nuclear power plant of the prior art is equipped with the doser, Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant As shown in the table,

As shown in FIGS. 3q and 3r, the crawler type dump bottom 855a and the wheel dump bottom 855b, which are used in the infinite track type, are separated from each other by the traveling device .

As shown in FIG. 3q and FIG. 3r, the transportation facility 811c of the hull position moving construction machine of the nuclear reactor facility 811 of the nuclear power plant includes a crawler type ) Has wide grounding area, low earth pressure and strong excavation ability even on bad terrain, and has good backing ability. Wetland traces are very suitable for wetland work because of low ground pressure. It is easy to work underwater to the depth where the track can be locked by the dispenser input device construction machine doser equipment of nuclear power plant nuclear power plant (811) of nuclear power plant.

As shown in FIG. 3q and FIG. 3r, the transportation facility 811c of the hull location moving construction machine of the reactor facility nuclear power plant 811 of the nuclear power plant includes a wheel type ) Has a large grounding area and a large grounding pressure, which makes it impossible to work on wetlands and limbs. However, it has better mobility and mobility than an infinite tracked type, and works on a flat ground or pavement. Nuclear power plants of nuclear power plants 811 ) Distribution dispenser, construction machine, and doser equipment.

As shown in FIG. 3q and FIG. 3r, in the nuclear power plant 811 of the nuclear power plant, the transportation transport part 811c of the hull position shifting construction machine of the nuclear power plant, , The straight dozer 855c and the tilt dozer 855d are separated by an angle dozer 855e. Straightness is also commonly referred to as a dozer, and the shovel can not be changed. Cutting and transferring work. It is a machine that uses a hydraulic cylinder to vertically operate the blades to excavate and exert powerful force by its own weight. Nuclear Power Plant's Nuclear Power Plant Nuclear Power Plant (811) Adjust the pitch of the front and back ten shovels to adjust the oyster force.

As shown in FIGS. 3q and 3r, the transportation dispenser 811c of the hull position moving construction machine of the nuclear reactor power plant 811 of the nuclear power plant includes an angle dossier 855e, The blade can be used as a tilt dozer 855d and a straight dozer 855c by changing the position of the blade to the left and right by changing the position of the blade so as to cut the hillside on the new road, The tilt dozer is used for the slope soil work, the cutting work, the snow removal work, the lateral laying work, the trench filling work, the pipe burial work, and the hard side cut work in the use, It can be used to work on slopes of about 15cm each on the left and right, while at the same time it is used for freezing land, hard land, side ditch excavation, rock stone rolling, V type drainage works, Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant 811 Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant 811

As shown in FIG. 3q and FIG. 3r, the transportation facility 811c of the hull position moving construction machine of the reactor facility nuclear power plant 811 of the nuclear power plant includes a distributor / dispenser, The rake dozer 855f is divided into a tree dozer 855g and a hydraulic raider 855i by a push dozer and a tin dozer by a U dozer while the rake dozer 855h is divided into a rake type wheel arch It is suitable for picking rocks during farmland clearance and road construction, drawing brushes and tree roots, and carrying bricks when constructing dams. Nuclear Power Plant's Nuclear Power Plant's Nuclear Power Plant (811) 's distribution input system is used as a construction equipment dozer.

As shown in FIGS. 3q and 3r, the transporting part 811c of the hull locating and construction machine of the nuclear reactor power plant 811 of the nuclear power plant is suitable for opening and shutting operations , And hinge dozer (855f) are suitable for jetting, snow removal, and soil conveying. Hydraulic Ripper (855i) is used when rigid and rigid ground is difficult to excavate. It is difficult to excavate or difficult to excavate Removal of rocks or pomegranates, destruction of asphalt pavement Nuclear power plant nuclear reactor facility Nuclear power plant facility (811) distribution input device Used as construction machinery equipment.

As shown in FIGS. 3q and 3r, the pushing-down portion of the transportation conveying portion 811c of the hull position moving construction machine of the reactor facility nuclear power plant 811 of the nuclear power plant pushes the scraper from the back (811c) of the nuclear power plant (811) of the nuclear power plant (811c) of the construction machine, and the construction machine dozer It is advantageous that it is possible to increase the amount of cargo to be transported by the facility, it is easy to move and does not harm the packaging.

As shown in FIGS. 3q and 3r, the U-shaped portion of the U-shaped conveyor 811c of the hull position shifting construction machine of the nuclear reactor power plant 811 of the nuclear power plant has a U- (2) Nuclear power plant with a dust collector (2) Nuclear power plant with a dust collector (1) Nuclear power plant (811) Nuclear power plant body dock (593,594,595) Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant (811) Hull Location Moving Construction Machine Transportation Plant (811c) Dispensing Apparatus Construction machinery Dozer facilities constitute nuclear power plant operation facilities.

Referring to FIG. 3, the nuclear plant construction unit 1 of the nuclear power plant having the double structural block tank dust collector for nuclear waste disposal according to the present invention is connected to the transportation transportation unit 811c of the nuclear power plant 811, The six shoveling devices 861p and 861r and the shoveling device 861s and the scraping device 861t and the weighing device 861u are used as the six all devices 861p of the construction machine, And pillar shaper (861v) operation,

As shown in FIG. 3S, in the nuclear power plant 811 of the nuclear power plant, the hull position moving construction machine transport transportation part 811c, the distribution input equipment construction machine cable crane 861o, A hook device 861q and a second device such as a Clamshell device 861r and a third device such as a shovel device 861s, Fourth, the operation of the construction machine is provided by the dragline (861t), the fifth, the trenchhoe (861u), and the sixth, the pile driver (861v) , And the construction machine cable cranes (861o) are installed to control and disassemble the hull position of a marine nuclear hydroelectric power plant floating hood, and to construct a reactor structure of a nuclear power plant having a double structural block tank dust collector (1) to regulate the flow of nuclear power plants inside (811c) Transmission of the hull position of the nuclear power plant (811) Transmission of the hull position of the construction machinery (811c) Body dock of the offshore power plant Hull position control of the marine hydroelectric power plant lifting plant (593,594,595) Construction equipment is connected to the facilities of the marine nuclear power plant and the reactor facilities.

As shown in FIG. 3 (S), the maximum hoisting load is indicated by the tone (ton) in the specification (performance) display method, and the seven basic operations of the crane are shown in the following table.

As shown in FIG. 3S, the crane (hook) is first used for the six lifting operations of the crane, the lifting and loading operation of the cargo, and the clam shell (Shell: Clamshell) is suitable for earth loading, vertical excavation, dirt removal, underwater excavation, hopper work and deep hole excavation. At the same time, the shovel can be used for excavation, The drag line is suitable for the construction of the embankment, the construction of the drainage line, the loading of the soil on the flat bottom and the underwater work vehicle, while the drag line (raking line) At the same time, the trench hoe (trench hoe) is designed to be suitable for drainage work, burial operation, excavation work, mining work, pipeline installation work, and at the same time, a pile driver It provided the use of a pole-driving operation, the pontoon bridge and pile driving work and, at the same time, the six cranes are the major equipment to establish a nuclear power plant assembly plant

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste is connected to the transportation transport part 811c of the hull position moving construction machine The operating angle of the boom showing the conventional configuration to constitute is as follows.

The minimum limit angle is 20 (but the backhoe is not limited to the minimum limit angle), the maximum limit angle is 78 °, the maximum safety angle is 66 ° 30 'and the normal working angle is 45 ° to 65 °.

And, when the weight of the object is heavy, the length of the boom is shortened and the angle is set large when the crane is operated.

Classification of cranes is classified into crawler type and truck type. Classification by traveling device is as follows.

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste is connected to the transportation transport part 811c of the hull position moving construction machine The drag crane has a large earth pressure and can not be operated on soft ground but has good maneuverability. The use of the drag crane is as follows: the steel frame assembly of a high-rise building, The structure and function of the tower crane are used for the loading and unloading of the material. The tower crane is a crane equipped with a short jib or hammerhead truss on a high tower. It is used for high-rise buildings or buildings The structure and function of the hydraulic crane, which has been widely used in the field, is as follows. As shown in FIG. 3S, As a crane, the boom can be expanded and contracted up to 510m and the hoisting load is usually 310 tons. Its usage is used for the harbor construction work, civil engineering work, electric pole work, heavy lifting work and also the structure and function of cable crane silver,

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the transportation transport part 811c of the hull position moving construction machine, The cable crane equipment shown in the conventional structure is constructed by loading both ends with a thick cable to the tower to lift the trolley. The application is used for concrete and material transportation in the dam construction and at the same time, The structure and function of the derrick crane are such that the boom is set up at the lower part of the steel mast, and the hoist is passed over the block and the rope is lifted and carried by the winch. , Foundation work, and bridge construction. Gai Derek has the ability to hang loads on material beams and has a large work radius and is easy to disassemble. However, at the same time, the triangular derrick is suitable for the roof work of a narrow place or a building and does not need a foundation, and it is easy to move when installed on a wheel. (593,594,595) is a dual structure block tank for nuclear waste disposal to regulate movement and disassembly of the hull position of marine hydroelectric power station (593,594,595) because it is used for pile hammer work, bridging hypothesis and harbor unloading. (811), which regulates the flow of nuclear power generation facilities within the facility body (1), the transportation of the construction machinery (811c), the ship's body dock, the offshore hydroelectric power plant It is composed of the construction machines of the hull position movement control of the flood control.

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the transportation transport part 811c of the hull position moving construction machine, A tractor crane having a crane mounted on an upper part of a shovel excavator is a wheel type and a crawler type. The following outriggers maintain safety and prevent a load from being applied to a tire (Crane) is a crane that moves by installing a running rail on the ceiling. It is used for the production and processing of ordinary concrete beams (Beam) . Fixed type is used for loading work at factories and warehouses. However, it is not used for construction work, It is widely used in construction.

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the transportation transport part 811c of the hull position moving construction machine, A chain block 648 showing a conventional structure of the crane 648 can be lifted up to a maximum of 15 tons for unloading. The safeguard device for lifting and unloading the crane is a brake and a limiting switch.

As shown in FIG. 3S, the nuclear power plant 811 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the transportation transport part 811c of the hull position moving construction machine, The construction of a conventional marine crane is shown in Fig. And a crane 888 having a hydraulic crane 885 and a cable crane and a clam shell attachment in a drag crane 887 and a tower crane 886, which are used for transportation and installation of super large facilities, The names 886a of the cranes 885 and the tower cranes 886 and the guidder structures 886a and 886b are connected to the girder 886b, the main side 886c, the boom 886d, the boom foil 886e and the turnbuckle 886f, While the triangular derrick 886h is constituted by the main side 886i and the boom 886j and the boom foil 886k and the leaks 886l while the dragged crane 886h is connected to the drag cranes 886g, The structure 887a of the crane includes a hoist cable 887b, a dump cable 887c, a bucket 887d, a lower boom 887e, a letterlet cable 887f, a cable roller 887g, a boom cable 887h, And is connected to the roller 887i and the boom hoist cable 887j, the cable drum 887k, the cable drum 887l and the parallel weights 887m And at the same time the structure of the crane 888 having a clam cell attachment is provided with a holding line 888a, an opening and closing line 888b, a clam cell bucket 888c, an upper frame 888d, a lower frame 888e, A boom hoist rope 888j, a front drum 888k, a rear drum 888l and a parallel weight 888m while being connected to the rope guide 888g, the boom tide 888h, the breeze 888i, the boom hoist rope 888j, A double structure block tank for the treatment of nuclear waste composed of a construction machine that arranges movement control and disassembly of hull position of a marine hydroelectric plant (593,594,595). Nuclear power plant of nuclear power plant equipped with dust collector Nuclear power plant The nuclear power plant 811 for controlling the flow of the nuclear power plant into the reactor main body 1 of the nuclear power plant showing the conventional structure constituted in the transportation unit 811c of the hull position shifting construction machine 811 And the marine power plant body The construction equipment of the marine hydro-power plant flood control station constructed on the upper part of the deck of the ship hull deck (SDU) consists of reactor facilities that provide connection with the facilities of the nuclear power plant.

Referring to FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811 ) A crusher (874) showing the position control structure of the transporting part (811c) of the construction machine of the hull of the marine hydroelectric power plant lifting plant (593,594,595) constituting the upper part of the ship's deck (SDU) ) And the dredger (879).

3t, a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment is installed inside the nuclear reactor facility main body 1, and the transportation transportation part of the construction machine of the nuclear power generation facility 811, The pump dredger 879a of the dredger 879 and the bucket dredger 879b of the construction machinery connecting structure 811c for adjusting the position of the ship 811c of the construction machine of the hull position shifting control of the nuclear power plant 811, The dredger 879 constituting the upper part SDU of the power plant body dock hull deck is mounted separately from the pump dredger 879a and the bucket dredger 879b while the dredger 879 is connected to the spot dredger 879c The red seater 879e and the spot 879f, the blast tank 879g, the blast pump 879h, the red 879i and the engine room 879j of the cab or control room 879d and at the same time the dewar dredger 879k And the grab dredger 879l are connected to the bucket drive device 879m, The belt conveyor 879u and the belt conveyor 879u are attached to the rear spot 879n, the spot winch 879o, the bucket 879p, the left and right front spots 879q, the dipper 879r, the winch 879s and the anchor storage 879t. (879v) A plurality of construction machine connection structures are provided inside the reactor main body (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal, so as to control the hull position movement of the nuclear power generation facility A submarine mineral intake sampling machine 911 and an undersea mining robot 911 are connected to an oil drilling machine 908 and a submarine mineral deposit net 910 connected to the upper part SDU of the body of the marine power plant dock, (915) and wire rope chain (915) on the periscope (913) and the rubber balloon (914) on the pipe line (912) Dual structure piping line Automatic pneumatic valve transport device (916) and core drill (917) (909) of undersea minerals and manganese nodules.

As shown in Fig. 3 (t), the dredger provided in the conventional marine power plant equipment is equipment for digging soil in the water. Fermentation. River. In order to increase the depth of waterway and to maintain depth of water, we work on the landfill of the shared water surface and the foundation construction of the coastal work such as rock wall and breakwater. Classification of the dredger is classified by classification by type and ability. The pump type is classified as a non-propelled type with the rated output of the driving engine and the bucket type is classified as non-propelled type with the non-propelled type with the rated output of the main engine and the deck type with bucket capacity (m ³ ) It has been prepared visually by the flat application amount (m ³ ) of the bucket.

As shown in FIG. 3 (t), the dredgers provided in marine power plant facilities are classified into electric, diesel, steam turbine and gas turbine types by the ability, and the pump dredger 879a for the structure and use of the dredger, The structure and purpose of the dredger is to transport the soil to the toe line or to suck up the soil and water by using the low head pump line when the delivery pipe is difficult to install or the long distance is long, The angles of movement of the hull during operation are from 70 ° to 90 °, and the standard mark is indicated by the rated output (PS) of the drive engine.

As shown in FIG. 3 (t), the structure and use of the bucket dredger 879b in the marine power plant equipment is such that the soil is continuously pumped up by using a bucket conveyor to the seabed, The dredger (879b) is characterized by continuous and intermittent type and continuous type. The standard indication is indicated by the continuous rated output (PS) of the main engine. As shown in Fig.

As shown in FIG. 3 (t), the structure and the use of the dredger dredger 879c for dredging the marine power plant equipment are used for dredging a hard ground or a broken rock having a strong digging force. ³ ), and its characteristics are described in the following table.

As described above, in the collection of the seabed mineral manganese nodule 909 in the dredger provided in the marine power plant,

A plurality of construction machine connection structures are provided inside the reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, and the transportation transportation part of the construction machine of the nuclear power generation equipment part 811 The submarine mineral intake sampling machine 911 and the submarine mineral collection robot 912 are connected to the periscope excavation machine 908 and the seabed mineral deposit net 910 connected to the upper part SDU of the marine power plant body dock hull deck 811c, (913) and rubber balloon (914) Double structure Pipeline line Automatic pneumatic valve Transport device (916) and Core drill (917) Distribution machine of construction machine Construction machine connection structure Submarine mineral manganese Nodule (909) collection.

As shown in FIG. 3 (t), a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment is installed in the reactor main body 1 of the nuclear power plant and transports the construction machine of the nuclear power plant 811 The crusher 874 connected to the crusher 874 is connected to the crusher 874 (see FIG. 8). The crusher 874 is connected to the crusher 874, The facility is provided with a gyre torch crusher 874a and a chassis frame 874b, a feeder hopper 874c and a vibrating grease repeater 874d, a primary jaw crusher 874e of a shredding head and a secondary jaw crusher 874f, vibration screen 874g, and drum elevator 874h. The crusher 874 is used for compaction of the aggregate layer in road and concrete construction.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 It is used in all crushing works and it is mainly used for aggregate production. In the future, it is going to be used for the first step of submarine mining ore.

The types of crushers are separated into primary, secondary, and tertiary crushers. The description of each part of the primary crusher is as follows.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 Jaw Crusher is a machine that is crushed by compressive force. When rocks are inserted between jaws on both sides and one side is fixed, the other side is operated and crushed by the price pressure at that time, The gravity and the pushing force come down in the discharging direction. Such a jaw is made with a structure that can crush any hard rock pomegranate with powerful force.

As shown in FIG. 3 (t), the nuclear plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the hull position of the internal nuclear power plant 811, (811c) construction machines. The Zaire Torch Crusher is made of cast iron or steel and consists of a lower frame eccentric shaft and drive gear, with a cone-shaped grinding chamber at the top. In the crushing section, there is a crushing head of a hard steel on the continuous mandrel axis, and is crusher which is firstly crushed while rotating and then discharged to the bottom of the crushing chamber. This crusher has less vibration than the Jaw crusher and has the advantage of continuous crushing. It has the upper part of the machine as the discharge port and the lower part as the discharge port. There is an advantage that it can be loaded. Impact crusher's Hammer mill crusher is equipped with a large number of discs on one rotating shaft, hanging a rectangular hammer around the hinges and rotating rapidly, And is crushed by the hitting force at this time.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 With the machines, the cone crusher of the second crusher has an umbrella-shaped cone-mantle head on a short vertical spindle, a stone is placed between the cone-curve balls mounted on the frame by the eccentric motion of the frame, This is because it is crushed by the impact action and its structure is somewhat complicated. There is no slip that the crushed stone flows down as it is, so that the crushing ratio is relatively large, but at the same time, the crushing force and compressive force are provided. , The cone is short, the dimension of the supply port is small, and the outlet gap size is the largest size of the crushed stone, The double roll crusher of Hammer crusher is characterized in that the two hard rolls are fixed on separate horizontal axes and the spacing is freely adjustable And at the same time, the rolls are provided in parallel, but the rotations are made to rotate in opposite directions so that the rocks are pinched therebetween so as to pass through between the rolls to provide crushing, while at the same time, It has main function and is widely used for packing aggregate production.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 The rod mill of the third crusher 874 was used to produce fine aggregate of less than 5 mm. The ball mill was a rod mill and the ball mill was a machine for producing crushed stone as fine aggregate , A rod of a short round rod is inserted into a forced round drum, and fine aggregate is continuously supplied with the water, and the drum is rotated, pulverized and then discharged, and relatively uniform particle size is obtained. If the water is wet, the wheat is dry, but generally it is wet.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 With the machines, the ball mill is different from the rod mill in that it puts a steel ball in a cylinder and rotates to obtain a new aggregate.

Its standard specification is to display the crushing capacity per hour in tonnes (TPH (ton per hour)].

As mentioned above, it is a machine that makes crushed stones smaller and makes crushed stones. It is used in all crushing works and mainly used for the production of aggregates. The power source 46 of the engine generator 226 treats nuclear waste. A plurality of construction machine connection structures which can be used for a limited period of time before completion of the apparatus 941 are installed in the nuclear reactor main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, (811c) Construction machinery to the marine power plant body dock Submarine mineral inhabitation on the crude drilling machine (908) and submarine mineral deposit net (910) connected to the upper deck part of the hull (SDU) A wire rope chain 915 and a double structure pipe line automatic pneumatic valve conveying device 916 and a pneumatic valve 916 are installed in the periscope 913 and the rubber balloon 914 in the machine 911 and the bottom mineral picking robot 912 (917) Distribution equipment of construction machinery (990) Submarine mineral manganese nodules collected by construction machinery connection structures (909) As a machine for crushing and reducing stones, rod mill of crusher (874) Since the ball mill produces the aggregate, the rod mill and the ball mill are machines for producing the crushed stone as aggregate again, and the new aggregate crushed stone is transferred to the transportation transport section 811c of the hull position moving construction machine of the nuclear power generation facility 811 ) And hydro-electric power production control section of the hydro-hydro power generation control section and harmful red tide prevention control section, and the connection structure of the hydrological control and control section of the dam in the control section of the fish and shell scattering control section.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 In the sorting by the mechanical subsidiary apparatus, the rake dozer 855f is subdivided into a tree dozer 855g, a hydraulic raider 855i, a push dozer and a Tina dozer U dozer, Instead, it is a dozer equipped with a rack-type hook-and-loop attachment device. It is suitable for picking rocks during farmland clearance and road construction, drawing brushes and tree roots, and carrying bricks when constructing dams. It is used for hard land digging.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 The machine tree dodger 855g is suitable for clearing and stopping operations and the hinge dozer 855f is suitable for jetting, snow removal and soil transfer. In the case of hydraulic rigs 855i, the ground is hard and rigid, It is used for the removal of asphalt pavement and rocks that are difficult to excavate, difficult to blast, and asphalt pavement.

As shown in FIG. 3 (a), the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 The pushers on the machines are pushing the scrapers from behind to give the tractor the traction in the scraper operation, while the low pressure rubber tire esophagus is faster than the infinite crawler and can increase the cargo volume. Also, it is easy to move and does not harm packaging.

As shown in FIG. 3 (a), the U Dozer has a double structure block tank dust collector for treating nuclear waste because the blade is U-shaped. Therefore, the nuclear reactor facility main body 1 of the nuclear power plant 1, 811) Construction Transmission Department of Construction Machinery (811c) Construction machinery is composed of distributing input device of marine hydroelectric power station floating docking hull position movement control device which is composed on the upper part of SDU of the body of the marine power plant.

Referring to FIG. 3U, a nuclear reactor plant main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811 ) An excavator 856 showing a construction machinery position adjustment structure of a marine hydroelectric power plant floating structure (593, 594, 595) constituting a dock top deck (SDU) of a marine power plant showing a construction machine and a hydraulic tank Axis configuration of the telescopic plunger pump 148b of the plunger pump 148 and the telescopic plunger pump 148b of the plunger pump 148 and the construction machine connection structure of the radial plunger pump 148c,

As shown in FIG. 3U, the hull locating and construction machine 811c of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste A hydraulic tank 819 having a connection structure with an excavator 856 showing a construction machine position adjustment structure of a hull position movement control of a marine hydroelectric power station floating picker 593, 594, 595 constituting an upper part SDU of a marine power plant dock hull deck, The hydraulic system 819 is provided with a heat plate 819a, an oil level system 819b and a drain 819c on the construction machine connecting structure of the boss shaft type plunger pump 148b and the radial plunger pump 148c of the pump 148, And the tank bottom plate 819d and the diaphragm 819e and the suction strainer 819f and the upper plate packing 819g and the suction port packing 819h and the suction port lid 819i and the tank upper plate 819j and the air blader / A tank leg plate 819l, and a cleaning window packing 819m, (811c) of the hull position shifting construction machine in the reactor installation main body (1) of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal by connecting with the hydraulic pump (820) and the hydraulic pump (821) ).

As shown in FIG. 3U, the transporting portions 811c of the hull position moving construction machine in the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, The plunger pump 148 and the radial plunger pump 148c of the plunger pump 148 are provided with a plunger pump 148 adapted to the high pressure pump as a pump for pumping action by the reciprocating motion of the plunger Type or a radial type according to the relative relationship between the reciprocating motion direction and the driving rotation direction of the plunger, or a pump or a motor of the same type may be classified into a rotaty pump (337). However, the crank-type piston pump can be regarded as a kind of radial type when it is classified as the motion of the piston, but it is classified into one independent type because there is a considerable difference from other pumps in structure I think standing.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 The rotor type pump 337 is capable of high-speed operation (usually 3000 to 4000 rpm, larger than 15,000 rpm) since the mass of the reciprocating portion is extremely small or there is no reciprocating portion at all. Therefore, a relatively high-pressure, high-performance pump can be obtained. Since the pump having a plurality of plungers is operated at a high speed, the pulsation of the delivery oil is extremely small and the vibration is relatively small, so that a relatively smooth operation is possible. In addition, a variable-displacement type mechanism can be easily obtained.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 Since the diameter of the plunger is relatively small, the stroke is small, and the machining accuracy is easily obtained, a pump of high volumetric efficiency can be obtained. Thus, the plunger pumps on the market today is the delivery pressure 700~350kg _f / cm ^2, songchulryang 10~50ℓ / min, usually in the 80-90% efficiency.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 In recent years, crank piston pumps have been developed for high-speed rotation, high-pressure, and small-volume delivery, and have been widely used for general industrial and special purposes because of their small size, high efficiency and simple structure. Axial type plunger pumps 148a, the plunger is inserted into a cylinder block arranged on the circumference of the cylinder on the circumference of the cylinder about the axis, parallel to the axis, and the reciprocating motion It is divided into a bent axis pump and a swash plate pump.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 A cylinder block is coupled to a drive shaft by a spline. As the drive shaft rotates, the piston in the cylinder rotates together with the swash plate. The swash plate type compressor has a structure Because it is simple and has a small number of parts, it is small and light, it is inexpensive, and its structural rotating weight is concentrated around the shaft, which is suitable for high-speed rotation and is widely used in construction vehicles and cargo handling machines.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 Marine power plant body dock The construction of the hull position control of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part of the hull deck (SDU). The construction of the elevator cable, the extender cable (861b) Construction equipment connection structure of the marine hydroelectric power station floodplain (593,594,595) constituting the upper part (SDU) of the marine power plant dock hull, with all six devices (861p) and drag cranes (887) (811) of the reactor installation main body (1) of the nuclear power plant having the double structure block tank dust collector for controlling the nuclear waste, It is.

As shown in FIG. 3U, a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment is provided with a transportation conveying section 811c of a hull position moving construction machine in a reactor installation main body 1 of a nuclear power plant 811 2L, seals 156 are attached to the axial seals formed in the cylinder 126 used as the construction vehicle or the conveying machine. The high pressure pump and the high-pressure hose 190, which are located in front of the cylinder 126, And a linkage 249 used as a coupling device to the crank 248. The dual structure block tank dust collector for nuclear waste processing is connected to the coupling device 249 by a heavy equipment construction machine (811) of the reactor plant main body (1) of a nuclear power plant equipped with a transporter (811c) of a marine power plant constructed in the upper part (SDU) (593, 594, 595) To the transportation unit (811c) of the hull where moving construction machine consists of the upper deck to the dock hull (SDU) position.

Referring to FIG. 3 (b), a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811 ) 855a of the bulldozer 855 showing the configuration of the construction machine position adjustment of the hull position movement of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part (SDU) of the dock hull deck of the marine power plant showing the construction machine, A wooden dozer 855b with a straight dozer 855c and an angle dozer 855e with a dilator dozer 855d and a tree dozer 855g with a hinge dozer 855f and a hydraulic hopper 855i with a rake dozer 855h, Construction configuration of connecting structure of construction machine Road,

As shown in FIG. 3 (b), in the nuclear plant having the double structure block tank dust collector for nuclear waste treatment, (855a) of the bulldozer (855) showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power station floodplain (593,594,595) constituting the upper part of the ship's deck (SDU) 855b on the straight dozer 855c and an angle dozer 855e on the deleter dozer 855d and a tree dozer 855g on the hinge dozer 855f and a hydraulic ripper 855i on the rake dozer 855h. Distribution road system configuration of flood control machinery showing strabismus road, dozer power transmission arrangement. In the attachment of the bulldozer, the straight lake dozer is attached to the straight dozer instead of the shovel, and the roots are removed. It is used exclusively for the excavation of rocks. The following backhoes are used for burial of pipe wires. The following hydraulic rippers were used for excavation of drainage gutters. The following hydraulic rippers were used for crushing, roots and rock scraping of grounds and pavements that were difficult to excavate from hard and hard ground. The towing winches were used for traction of heavy timber. Snow plows were used for snow removal The sketch loader is used to transport wood, pump round objects, and to load cranes or heavy objects. The rock buckets are dedicated to the loading of rocks. The shovels are construction machines used for excavation of mountains and cliffs. They consist of a reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The transportation transportation units 811c of the hull position moving construction machine constituting the upper portion SDU of the ship body dock hull deck provided with the transportation transportation units 811c of the hull position moving construction machine of the nuclear power generation facility 811 inside .

As shown in FIG. 3 (b), in the nuclear plant having the double structure block tank dust collector for nuclear waste treatment, The bulldozers 855 are installed in the construction of the transportation section 811c of the floating cargo ship hull locating construction machine constituted by the power transmission device parts of the dozer of the construction machine, A cooling system 855m is provided in the engine 855l and a sprocket 855b is provided in the final gear device 855n in the structure of the power transmission device 855j of the dozer. (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, which is equipped with power transmission device parts of a dozer of a construction machine (855q) and a provision clutch (855q) on an idler (855p) Nuclear power generation inside And a transportation transport section 811c of the hull position moving construction machine constituting the upper part SDU of the marine power plant body dock hull deck provided with the transportation section 811c of the hull position moving construction machine of the equipment section 811 .

Referring to FIG. 3w, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, the transportation transport section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 ) Construction configuration of a construction machinery connection structure showing the arrangement of construction machine position adjustment of hull position movement of a marine hydroelectric power plant floating attachment (593,594,595) constituting the upper part (SDU) of a dock hull deck of a marine power plant showing a construction machine.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, A crawler-type dozer 855a and a wheel-type dozer 855b, which show the construction machine position control arrangement of the hull position movement control of a marine hydro-power plant flotation receiver (593,594,595) constituting the upper part (SDU) The ball constitutes the center of the scraper 859 as a container for transporting the gravel 812 with respect to the main components and roles of the pile driver 882 and the scraper 859 in the excavator 856 and the skimmer 856f With the cutting edge on the lower side of the running direction, push the ball to the excavating surface with the operating device while advancing to prepare the excavation and loading.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, (593, 594, 595) equipped with powertrain components of dozer provided with construction equipment, but also at the same time as the nuclear power plant with a dual structural block tank dust collector for nuclear waste treatment Hull Location of Nuclear Power Plant (811) into Nuclear Power Plant Reactor Main Unit (1) of the Power Plant Marine Power Plant Portage (811c) of Construction Equipment 593, 594, 595), the construction machine connection structure showing the construction machine position adjustment structure of the hull position shifting control has a larger carrying distance than the bulldozer and is called a carryover type, As a machine for working, it is composed of power transmission device parts of a dozer of a construction machine because it is possible to consecutively perform five operations such as excavation, loading, transportation, laying and compaction.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The construction equipment of the motor grader 862 includes a muffler 862a, a cooling fan 862c for the engine flywheel 862b, a transducer 862e for the fore and aft forehead value 862d, A parking brake 862g in the transmission 862f and a motor grader 862 equipped with a gear reducer 862i in the differential gear 862h and a tangential drive 862k in the disc brake 862j are connected to a marine hydroelectric power plant floating pickup (593, 594, 595) are arranged for movement control and disassembly and assembly.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, Construction machines Motor scraper is a combination of vehicle type tractor and scraper, and it is different from the fact that it is equipped with power and it is able to carry a lot of soil to excavation and excavation Cutting the ground surface of smooth terrain composed of loose soil and loose soil. Tossa (812). Cutting, loading, transporting and embankment work can be done, and the main job can not be transported by pushing with the soil (812).

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, For construction machines, the standard (load) capacity of the ball in m ³ is indicated in the standard, and the power transmission sequence is as shown in the table below.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, Details of the classification of the scrapers 859 by the construction machines will be described as the following table.

[Comparison between pull-type scraper 859a and power-type scraper 859b]

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment by a pulling scraper (859a) and a power type scraper (859b) classified as scrapers (859) And a transportation transport section 811c of the hull position moving construction machine of the equipment section 811.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The apron (859c) equipment provided by the construction machines is installed on the front of the ball and serves to prevent the soil (812) of the ball from flowing down. In the case of loading and unloading, the oceanic hydroelectric power plant floodplain (593,594,595) The combination of disassembly and assembly of the ball 859e and the cutting tee 859f on the air front 859c and the ejection 859d constitute the flow control of the nuclear power plant equipment. The power transmission devices include a dual structural block tank for the treatment of nuclear waste. The hull position of the nuclear power plant (811) is transferred into the reactor main body (1) of a nuclear power plant having a dust collector. (811c) consists of the construction machinery.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The Ejector (859d) facility, which is equipped with construction machines, is located at the back of the ball, which is called a tailgate, and serves to push out the soil in the ball and to make a space for loading the soil, (Yoke) is a member that joins the ball 859e and the tractor.

Double structural block for nuclear waste treatment Tank Nuclear power plant reactor with dust collector Moving hull position of nuclear power plant (811) inside the main body (1) Transporting part of construction machinery (811c) Workload of scraper provided by construction machines (Braking type scraper)

Here, Q : the ball carrying capacity

f : Conversion factor

E : Working efficiency of the scaler

C _m : Classify by cycle time.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, Grader (862l) equipment provided by construction machinery is mainly used for civil engineering work. It is mainly equipment for stopping work. It is equipment to pick ground by scraping the ground by installing blade plate (blades) (Blades), and the following table shows the usage and performance of the equipment.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The power transmission sequence provided by the construction machines is described in the following table.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The parking brake of the motor grader 862, which is provided by the construction machines, is an external contraction type which catches the lower shaft of the transmission.

The power transmission procedure will be described in the following table.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, As for the propulsion angle and cutting angle of the blade provided by the construction machines, the propulsion angle is the angle formed by the center line of the grader and the blade, and is small in the hard ground and 70 ° to 90 ° in the stop operation The cutting angle is an angle at which the cutting edge of the blade is inclined with respect to the cutting surface, and is small at the cutting operation. The angle between the main body of the grader and the cover plate is adjusted to 45 ° and 60 ° when the soil is pushed to the side, and it is about 90 ° when the finishing is done.

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The following table describes the blade capacity provided by construction machines.

only. Q : Blade capacity (m ³ )

B : Blade width (m)

H : Blade height (m)

Minimum turning radius of the steering system

(단. L : 축 거리. : 킹 핀. : 외 측 바퀴 각 )

( L : Axis distance: King pin: Outer wheel angle)

Why there is no differential mechanism

As shown in FIG. 3w, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment, The motor grader 862, which constitutes the movement control and disassembly assembly of the hull position of the marine hydroelectric power station submersible poison 593, 594, 595, A dual structural block tank for nuclear waste treatment consists of the construction equipment of the transport facility of the construction machine (811c) of the nuclear power plant (811) and the construction machinery of the nuclear power plant (1) of the nuclear power plant with dust collector. At the same time, an air plunger 859c, an ejection 859d, a ball 859e, and a cutting tee 859f constituting disassembly and assembling of the hull position of the marine hydroelectric power plant lifting plate are disassembled and assembled The nuclear power plant 811 has a double structure block tank dust collector for nuclear waste disposal by the power transmission device parts of the dozer of the construction machine, Location Transport and Transportation Department of Construction Machinery (811c) Construction machines consist of nuclear plant facilities.

Referring to FIG. 3, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention, the transportation transport section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811 ) A crawler-type dozer 855a and a wheel-type dozer 855b which show a construction machine position control arrangement of a marine hydro-power plant flotation receiver (593,594,595) constituting a dock top deck (SDU) (852) on the excavator (856) and the skimmer (856f).

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The shovel excavator as construction machine is the oldest used loader as well as excavator. In addition to the front attachment, a shovel and a crane are installed as a multipurpose machine for many works. As a machine to prepare various excavation work and crane work by exchanging various accessories, the upper rotating body can be turned 360 ° and the structure of the excavator (856) of the three major components is explained as follows.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, With regard to the external structure of the excavator 856 and the excavator 856 provided by the construction machines, the crawler type is divided into the crawler type and the wheel type and the truck type according to the sorting according to the traveling device. It is easy to operate in wetlands, limbs and livestock, and it is very stable. It is difficult to travel on pavement roads and its speed is slow as 3.2 km / hr. The next wheel type is good for pavement roads and bridges. It is easy to move the work place. It has a running speed of 40 km / hr, the working efficiency is 30% ~ 35% higher than that of the crawler type, and the truck mounted type has a running speed of 60 km / hr. The working efficiency is low.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, In the classification according to the operation method provided by the construction machines, it is separated into the manual type and the hydraulic type by the air type and the electric type. In the classification by the size, the small type is separated into the large type and the large type. A bucket capacity of 0.6 m ³ or less and a medium capacity bucket capacity of 3 m ^3. Anchorage capacity up to 10 t.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The performance display method of the excavator 856 provided with the construction machines is represented by the capacity m of the backhoe 856a, the power shovel 856b, the drag line 856c and the clam shell 856e bucket, The hoist 856d is indicated by the excavation diameter and the file driver 882 is represented by the weight of the hammer and the crane 861 is indicated by the maximum hoisting load in ton and the shovel 856b, (856c) and the clam shell (856e) are as follows.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, In the construction of the backhoe 856a of the construction machine provided with the construction machines, the backhoe 856a, the backhoe 856a, is used for excavation lower than the working position and is used for the foundation excavation of the river and the construction And can be loaded on a conveying equipment higher than the machine while digging the lower side of the trench digging machine. The trench 856a is suitable for disaster prevention for the prevention of large-scale forest fires and installation of the piping for the control, The power shovel is circular and suitable for excavation above the working position. It is used for cliff drilling.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, According to the characteristics of the hydraulic excavator (compared with the mechanical rope type) provided by the construction machines, the structure is simple, the second is easy to change and run the front, the third is easy to repair and operate, Rope type.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The construction of the drag line (856c) provided by the construction machinery was that the work radius was large and easy to underwater excavation. Next, it was used to excavate the ground lower than the ground. And it was not suitable for picking solid or gravel.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The earth drill 856d provided with the construction machines is used for adjusting the on-site spreading by drilling a large hole of a large diameter with no noise. The earth drill 856d is constructed by combining the piercing column holding tank 590, the barge hull 591 at the upper end of the holding tank, Barge hull (592) The following crane is used for the installation of bridge pier. The crane is used for heavy construction, high building construction. It is a machine that lifts a hook instead of a bucket and lifts a heavy object at the same time. The pile driver 882) is used as a pile driving device for piling concrete piles or sheet piles. It is suitable for installation of piers by pillar installation, and at the same time clamshell (856e) (909), and it is necessary to use gravel, sand, and earth for the vertical excavation at a narrow place beneath the ground. It is not suitable for excavation and hard soil excavation, which is widely used for loading on dump trucks. At the same time, Trencher is suitable as a construction machine to dig ditches.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The maximum excavation depth is the length from the ground surface to the tip of the bucket tooth when the tip of the bucket tooth is lowered to the lowest position. The maximum excavation radius (= maximum working radius) And the maximum dump height was the maximum ground clearance.

Dual structural block for nuclear waste treatment Tank of a nuclear power plant with a dust collector Moving hull position of a nuclear power plant (811) inside a nuclear power plant main body (1) Transport transportation part of a construction machine (811c) Skimmer ; 856f) is a construction equipment in which a bucket is moved along a boom on a swing platform by the force of a chain and slicing off the ground surface, which is suitable for thin excavation in a narrow place, and is difficult to work with a large machine (593,594,595) of marine hydroelectric power stations, which are used for thin excavation in a narrow space, and at the same time, the control of the position of the construction machinery of the marine hydroelectric power plant flood control station in the upper part of the body of the marine power plant dock hull deck (SDU) (811c) of construction machinery of hull locomotion control construction equipment, and a dual structural block tank dust collector for nuclear waste disposal Hull position moving construction machine transportation portion (811c) of the reactor facility of the nuclear power plant unit (1) to the internal nuclear power seolbibu 811 nuclear power plants are facilities that consist of construction machinery.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The structure and function of Ripper and Rooter (856g) provided by construction machines are used when the ground is hard and solid and difficult to excavate. It is attached to the back of large bulldozer and uses 23 foot saw blades by its own weight It is suitable for scraping hard ground. It is used for the purpose of removing the tree roots, the asphalt and concrete pavement, and the rock and the pavement removal.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, Cranes (cranes, 861) equipped with construction machines are called cranes. They are used for lifting and lowering heavy objects, crushing works using other working devices, collecting waste and building construction, For the purpose of moving and transporting stone materials and equipment, hook, clam shell and drag line are installed in front of the vehicle body. The structure and basic three part names are explained as follows.

As shown in FIG. 3x, a traffic transportation unit 811c of the hull position moving construction machine of the nuclear power generation facility 811 is installed inside the reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The construction and name 861a of the crane 861 constructed by the construction machines are as shown in the drawings except for the hook 18.

The name of each part of the crane or crane structure is the name of the crane or hoist structure in which the bridge 861d is attached to the extender cable 861b and load system 861c, the May rope 861f is attached to the boomboxes 861e, 861h and the lower frame 861i with hoist ropes 861j and counterbalances 861n on the rear drums 861l and 861m on the front drum 861k, (1) of a nuclear power plant having a block tank dust collector, a nuclear power plant facility and a nuclear reactor facility are constructed with the construction transportation machinery of the construction transportation machine (811c) of the hull position shifting construction machine of the nuclear power generation equipment section (811).

Referring to FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811 ) Extender Cable (856 g) to the Ripper and Luther (856 g) showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power station levitation stand (593, 594, 595) 861b) and all six of the cranes (861p) and drag cranes (887)

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, The apron (859c) equipment provided by the construction machinery is installed on the front of the ball and serves to prevent the soil (812) of the ball from flowing down, and to lift up the load and saturation of the ocean hydroelectric power plant floodplain (593,594,595) The airbag 859c, the ejection 859d, the ball 859e, and the cutting tee 859c are provided in the reactor main body 1 of the nuclear power plant, (859f) of the nuclear power plant having a double structure block tank dust collector for nuclear waste disposal, which is provided with the power transmission device parts of the construction machine dozer, (811c) construction equipment of the hull position moving and construction machine of the nuclear power generation facility (811).

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, Ejector (859d) equipment provided by construction machines is called a tailgate and is located on the back of the ball and serves to push out the gravel in the ball and to create a large space for loading the gravel.

Dual structural block for nuclear waste treatment Tank of a nuclear power plant with a dust collector Moving hull position of a nuclear power plant (811) inside a nuclear power plant main body (1) Traffic transportation part of a construction machinery (811c) Construction of a yoke ) Is a member that joins the ball 859e and the tractor.

Double structural block for nuclear waste treatment Tank Nuclear power plant reactor with dust collector Moving hull position of nuclear power plant (811) inside the main body (1) Transporting part of construction machinery (811c) Workload of scraper provided by construction machines (Braking type scraper)

Wherein, Q: In view once soil carrying load capacity, f: Sat amount conversion coefficient and E: is classified as cycle time: Crested's working efficiency and C _m of the buffer.

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, Grader (862l) equipment provided by construction machines is mainly used for civil engineering works. It is mainly equipment for stopping work. It is equipment to pick up ground by scraping the ground with blade plate (blade). It is equipment called earth planer machine. For use and specifications, the indication of use and performance is indicated by the length of blade (blade) and it is explained as below table.

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment is connected to the transportation conveying portion 811c of the hull position moving construction machine of the nuclear power generation facility 811, The power transmission sequence provided by the construction machines is described in the following table.

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, The parking brake of the motor grader 862, which is provided by the construction machines, is an external contraction type which catches the lower shaft of the transmission.

The power transmission procedure will be described in the following table.

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, As for the propulsion angle and cutting angle of the blade provided by the construction machines, the propulsion angle is the angle formed by the center line of the grader and the blade, and is small in the hard ground and 70 ° to 90 ° in the stop operation The cutting angle is an angle at which the cutting edge of the blade is inclined with respect to the cutting surface, and is small at the cutting operation. The angle between the main body of the grader and the cover plate is adjusted to 45 ° and 60 ° when the soil is pushed to the side, and it is about 90 ° when the finishing is done.

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, The following table describes the blade capacity provided by construction machines.

only. Q : Blade capacity (m ³ )

B : Blade width (m)

H : Blade height (m)

Minimum turning radius of the steering system

(단. L : 축 거리. : 킹 핀. : 외 측 바퀴 각 )

( L : Axis distance: King pin: Outer wheel angle)

Why there is no differential mechanism

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, The motor grader 862, which constitutes the movement control and disassembly assembly of the hull position of the marine hydroelectric power station submersible poison 593, 594, 595, Structure of double structural block tank for nuclear waste disposal combined structure Structure of nuclear power plant reactor (1) of the nuclear power plant equipped with a dust collector Location of the hull of the nuclear power plant (811) Construction transportation of the construction machine (811c) .

Nuclear power plant reactor with double structure block tank for nuclear waste disposal Nuclear power plant facility (1) Nuclear power plant part (811) Hull position transfer Construction machine transportation part (811c) Built-in air- 859c and a disassembled assembly of a ball 859e and a cutting edge 859f to an ejection 859d and a power transmission device part of a dozer of a construction machine and having a dual structural block tank dust collector for nuclear waste treatment It consists of the construction equipment of the nuclear power plant's nuclear reactor facility (1) and the transportation transport unit (811c) of the hull position shifting construction machinery of the nuclear power plant (811).

As shown in FIG. 3 (a), the interior of the reactor installation main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment is connected to the transportation conveying section 811c of the hull position moving construction machine of the nuclear power generation facility 811, The construction machine connection structure of the ripper, the lute (856g), the extensile cable (861b), the all six devices of the cranes (861p) and the drag cranes (887) (593, 594, 595) of the hydro-electric power station of the hydro-electric power plant constituting the hydro-electric power plant.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The shovel excavator that is used to install the machine is the oldest used loader and it is a multipurpose machine that can be used as an excavating machine as well as installing a front attachment.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The machine is equipped with a shovel and a crane to set up the machine, and various excavation and crane works by exchanging various accessories. The upper rotating body can turn 360 degrees and the excavator (856) The structure is explained as follows.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, With regard to the external structure of the excavator 856 and the excavator 856 for sorting the machine, the crawler type is divided into the crawler type and the wheel type and the crawler type is classified into the wheel type and the crawler type. Is easy to operate, and it is easy to operate wetlands, limbs and livelihoods. It has very good stability. It is difficult to travel on pavement roads and speed is slow as 3.2 km / hr. The next wheel type is good for pavement roads and bridges, , The traveling speed is about 40 km / hr, the working efficiency is 30% to 35% higher than that of the crawler type, and the truck mounted type has a traveling speed of about 60 km / hr, This business efficiency is low.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, In the classification according to the operation method of preparing the machine, it is separated into the manual type and the hydraulic type by the air type and the electric type. In the classification by the size, the small type is separated into the large type and the large type. As a limit, a gas weight of 20 tons or less refers to a bucket with a bucket capacity of 0.6 m ³ or less and a medium size bucket capacity of 3 m ³ to an anchorage capacity of 10 t.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The performance display method of the excavator 856 for preparing the machine is represented by the capacity m of the backhoe 856a, the power shovel 856b, the drag line 856c and the clam shell 856e bucket, 856d are denoted by the excavation aperture and the file driver 882 is denoted by the weight of the hammer and the crane 861 is denoted by the maximum hoisting load in ton and the shovel 856b, the backhoe 856a, the drag line 856c, and clam shell 856e are as follows.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The backhoe (856a) dispensing device of the construction machine providing the machine is used in the backhoe (856a) dispensing device backhoe (856a) for lower excavation than the working position and is used for the foundation excavation of the river, (856a) is suitable for disaster prevention and prevention piping line installation for prevention of large-scale forest fires and it is also suitable for installing a power shovel Power shovel) is suitable for excavation in a circular shape higher than the working position. It is used for cliff drilling.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, Compared with the mechanical rope type, which is a feature of a hydraulic excavator to provide the machine, the first is simple in structure, the second is easy to change the front, and the third is easy to repair and operate. .

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, In the drag line (856c) for preparing the machine, the work radius was large and it was easy to underwater excavation first. Next, it was used for digging widely below the ground, and then used for harvesting the rivers. It was not suitable for hardened ground or gravel extraction.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The earth drill 856d provided for the machine is used to adjust the on-site spreading by drilling a deep hole of large diameter with no sound. The barrel hull 591 at the upper end of the holding tank and the bridge pillar holding tank 590, The following crane is suitable for installation of a pier of a ship 592. The following crane is used for unloading heavy objects, building a high building, installing a hook instead of a bucket, lifting a heavy object, and a pile driver 882 The clamshell (856e) is suitable for installation of concrete pile or seat pile as a hovering tool, and it is suitable for installation of pier by pillar. It is used for underwater excavation, It is used for vertical excavation in a narrow place under the ground. It is suitable for re-use of manganese nodule (909), and is used for digging gravel, sand and soil to be loaded on a dump truck. And finally, the trencher is suitable as a machine used to break the trench.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The maximum excavation depth is the length from the ground surface to the tip of the bucket tooth when the tip of the bucket tooth is lowered to the lowest position. The maximum excavation radius (= maximum working radius) The maximum horizontal distance of the bucket tooth from the center and the maximum dump height was the maximum ground clearance, and the structure and function of the skimmer (856f) include a construction equipment that slides down the surface of the bucket as the bucket is moved by the force of the chain But it is suitable for thin excavation in a narrow place and it is used for thin excavation in a narrow place where it is difficult to work with a large machine in its use. A water treatment tank precipitator dual structure block SHIFT hull of the nuclear reactor plant of the plant body (1) inside the nuclear power seolbibu 811 having a construction machine for transportation unit (811c) is comprised of a construction machine.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The structure and function of the Ripper and Luther (856g) to prepare the machine is used when the ground is hard and rigid, making it difficult to excavate. It is attached to the back of the large bulldozer, It is suitable for scraping and digging. It is used for the purpose of removing the tree roots, the asphalt and concrete pavement, the rock or the pavement, and the hard soil.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, It is called a crane according to the equipment of the crane (crane, 861) that sets up the machine. It is used for lifting and lowering heavy objects, crushing work by using other working devices, heavy use for collecting waste and building construction, For the purpose of moving and transporting stone materials and equipment, hook, clam shell and drag line are installed in front of the vehicle body. The structure and basic three part names are explained as follows.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, The structure of the crane 861 and the name 861a of the crane for constructing the machine include the hook 18 and the name of each part of the structure of the crane or the crane as shown in the drawings are the name of the extender cable 861b and the loadmeter 861c, The hoist rope 861j on the upper frame 861h and the hoist rope 861j on the boom hoist rope 861g and the middle portion of the hoist rope 861j on the boom hoist rope 861f on the boom axles 861d, And the balance drum 861n is provided on the rear drum 861l and the drum 861m to provide a coupling structure.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The cable crane 861o for preparing the machine is provided with a hook device 861q, a clamshell device 861r and a shovel 861r for providing all six devices 861p of the following crane (Trenchhoe, 861u) and pile driver (861v) devices, and at the same time, a nuclear power station floating plant (593,594,595 (1) Nuclear power station of the nuclear power plant (811) Transfer of the hull of the nuclear power plant (811) Transport transportation part of construction machinery (811c) Marine power plant body providing construction machinery Top of deck of hull deck (593,594,595) of the marine hydroelectric power station (SDU), which are connected to the reactor facilities of the construction machine nuclear power plant.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The standard method of setting up the machine is to display the maximum hoisting load in tonnes. The seven basic operations of the crane are shown in the table below.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The crane (hook: Hook) is used for general lifting work, cargo loading and loading work, and the clamshell (clamshell) is used for loading and unloading of soil, It is suitable for dirt removal, underwater excavation, hopper work and deep hole digging work. Shovel is suitable for soil excavation, slope descent, earth loading of vehicles, road foundation and drag line (scraping: Drag line is suitable for embankment construction, drainage construction work, loading of soil to flat bottom and underwater work vehicle, and trench hoe is used for drainage, burial, mining, Was suitable for laying work pile drivers (driving pole: Pile driver) is the six cranes as used in the hierarchical pile driving operations of bridge building foundation work when pole-driving operation, is the main equipment to assemble the nuclear power plant

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The operating angle of the boom that provides the machine is as follows.

The minimum limit angle is 20 (but the backhoe is not limited to the minimum limit angle), the maximum limit angle is 78 °, the maximum safety angle is 66 ° 30 'and the normal working angle is 45 ° to 65 °.

And as the weight of the object increases, the length of the boom becomes shorter and the angle becomes larger as the crane works.

Classification of cranes is classified into crawler type and truck type. Classification by traveling device is as follows.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The drag crane has a large grounding pressure and can not be operated on soft ground but has good maneuverability. The purpose of the drag crane is to assemble the steel frame of high-rise buildings, to load the material The structure and function of the tower crane used for the hauling and harbor loading and unloading operations is a crane equipped with a short jib or hammerhead type truss on a high tower. It is used for high-rise buildings and construction sites The structure and function of the hydraulic crane,

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, Boom is a mobile crane operating the hydraulic system to operate the equipment. The boom can be stretched up to 510m and the hoisting load is usually 310 tons. Applications are used for harbor loading and unloading work, civil works, At the same time, the structure and function of the cable crane,

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, It is a method to load a trolley by hitting a thick cable on a tower at both ends of the machine. The derrick crane is used for conveying concrete and materials at the time of dam construction, (1) Nuclear power plant part (811) of a nuclear power plant having a structure block tank dust collector Moving hull position of a hull locating construction machine (811c) As a main constituent part for providing a construction machine, The structure and function is a machine that lifts a boom at the bottom of a steel mast and winds up the weights with the rope passing through the block and the rope Assembly of Steel turn, foundation, is used in the working hypothesis as a kind of bridge, Guy derrick is large and the power or working radius hanging load beam for the material is easy to disassembly and assembly loading and unloading operations. Movement of heavy objects. It is used for steel frame assembly work and at the same time the triangular derrick is suitable for the roof work of the narrow place or the building and does not need the foundation, and when it is installed on the wheel, it is easy to move and it is used for file hammer work, bridge construction, The hull position of the flood control section 811 for controlling the flow rate of the flow of the flood control apparatus into the main body 1 of the flood control apparatus constituted for controlling and disassembling the hull position of the marine hydroelectric power plant flood control station 593,594,595, (811a) Marine Dock Body Dock It is connected to the construction equipment of the marine hydroelectric power station floodplain (593,594,595) which is composed on the upper part of the ship deck (SDU).

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, Tractor crane, which is equipped with a crane on the upper part of shovel excavator, is wheel type and crawler type. The following outriggers keep safety and prevent load on the tire, The crane is a crane that moves by installing a running rail on the ceiling. It is used for the production and processing of concrete beams. It is used for fixed type Is used for loading work at factories and warehouses, but not used for construction work, The.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, Chain block 648, which provides the machine, can be lifted up to a maximum of 15 tons for loading and unloading. The safeguard device for lifting the crane is a braking and limiting switch.

As shown in FIG. 3 (a), a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, a transportation section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, The marine cranes that provide the machinery are transported and constructed of large steel structures of bridges. And a crane 888 having a hydraulic crane 885 and a cable crane and a clam shell attachment in a drag crane 887 and a tower crane 886, which are used for transportation and installation of super large facilities, The name 886a of each of the cage 886 and the tower cranes 886 has a girder 886b and a boom 886d on the side 886c and a turnbuckle 886f on the boom 886e, While the triangular derrick 886h is constituted by the boom 886k and the lok 886l at the main side 886i and the boom 886j and at the same time the side of the drag crane 886k of the drag crane 887 The structure 887a is connected to a hoist cable 887b and a bucket 887d to a dump cable 887c and a letter cable 887f to a lower boom 887e and a boom cable 887h to a cable roller 887g, 887i and the boom hoist cable 887j to the cable drum 887k and the cable drum 887l by parallel weights 887m And at the same time the structure of the crane 888 with the clam shell attachment is provided with the upper frame 888d on the clam cell bucket 888c and the rack line 888f on the lower frame 888e on the holding line 888a, A boom hoist rope 888j and a rear drum 888l and a parallel weight 888m to the front drum 888k to the boom tide 888h and the breeze 888i to the rope guide 888g, A double structure block tank for the treatment of nuclear waste to provide control and disassembly of the hull position of a marine hydroelectric plant (593,594,595). Nuclear power plant reactor main body having a dust collector 1) Hull of internal nuclear power plant 811 (811c) construction machinery of the locomotion construction machinery is constructed and connected to the construction machinery of the hull locomotion control system of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part of the deck of the hull deck (SDU) .

Referring to FIG. 3Z, a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transport conveying section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811 ) A forklift 858 and a forklift 858 are mounted on a loader 857 showing a construction machine position control structure of a hull position movement control of a marine hydroelectric power plant flood control console (593, 594, 595) Trailer (860a) of dump truck (860) Straight configuration of construction machine connection structure Road,

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, In the schematic configuration of the forklift 858 and the trailer 860a of the construction machine connection structure of the dump truck 860 to the loader 857 for preparing the machine and the distribution input device loader 857 of the flood control machine, It is a construction equipment that is mainly called a loader and has a shovel device on the front of the tractor main body and it is mainly used to load gravel, sand and soil on a dump car in the construction work. The first specification (performance) (Bucket) capacity in m ³ .

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The crawler type loader 857a (long-reach type = infinite crawler type = crawler type = shovel loader) is used as a sorting method by the traveling method in which a bucket is provided in front of the crawler tractor The wheel type loader (wheel type = 857b) (wheel type = tire type = wheel type loader) is equipped with a bucket in front of the wheel type tractor and can be operated in a flat work area It has excellent maneuverability, great work ability, easy to work on packed roads, semi-infinite crawler loader, one side of the front and rear wheels are trackless, and the other side is equipped with tires And a model kinks Tracked and wheel type, rail loader (857c) has a loading operation in a tunnel or underground as a device capable of running over the rail.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, Classification according to the loading method to prepare the machine is shown in the table below.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The loading method of the loader 857 for preparing the machine is shown in the following table.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The other loader (857) equipment that sets up the machine is used as a Muk loader in tunnel construction and is used to load demolished debris from the excavation work on the car. The pay loader The dump trucks (860) are used to load the dirt, and should be operated as slowly as possible. The bucket should not be raised during no-load operation. The rail-type slack loader is used to load the blasted slag in the car It is used for various tunnels, residential land composition and limestone mining with continuous rocker loader and continuous rocker loader. Screw excavator is used for underground excavation work in city area, factory or ship Those of which was to be used for quarrying loading operation, an as a belt loader with a bucket wheel X-car elevators are used used skid steer loader is the same as the following table estimating workload as appropriate stacking machines for working in the tunnel or tunnels expression.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, It is connected to the distribution dispenser to prepare the machine.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, In the kind of the dump truck 860 that arranges the machine, the rear dump truck is used most often in civil engineering work by loading the luggage compartment backward, and the side dump truck 860 tilts the luggage compartment sideways The bottom dump truck (860) is a truck that can open the lower part of the jib and load down. It is widely used in trailer dump trucks. The three-room open dump truck is a truck that can load in three directions. The workload calculation formula is shown in the table below.

Calculating the required number of trucks:

Calculate truck workload:

here,

표시하고,구배 저항은(W_g)은

상기와같으며,구동력(W_s)은

상기와 같았다.여기서,

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, In the running resistance of the dump truck 860 for preparing the machine, there is a calculation formula of the driving force on the rotational resistance and the spherical resistance, and the rotational resistance W _r

, And the gradient resistance (W _g ) is

As described above, the driving force (W _s )

As described above,

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, Dumptor is a special off-road truck for short-haul trucks that can be used in narrow workshops. The dumptor is used when the haulage distance is more than 1 km and is used for the construction of tunnel constructions. And the size is indicated by the weight indicating the traction force, and the tractor and trailer 860a is a machine for transporting the tractor 860a by the trailer 860a, which is loaded with a heavy load, a bulldozer of the construction machine, and a roller The tractor is classified into crawler type, semi-crawler type, and wheel type.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The Rope way to set up the machine is a machine that carries the cargo by placing a steel tower on both sides of the mountain and connecting the cables and arranging the transporter every 60 m. It is not restricted by topography and road conditions, It was easy to carry long distance. The wagon is similar to a motor scraper but can not be grounded by a magnetic force. It is a machine that transports soil from a loading machine. A tractor-driven wagon is used to transport material from a tractor . front. It is also called a full trailer (860a) with an axle and wheels attached to the rear end.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, Forklift (858) equipment that sets up a machine is equipment that raises or lowers cargo, equipment that is common with automobiles, and is widely used in warehouses and paddocks indoors and outdoors. In other words, it is effective for short distance transportation and loading and dropping work of hardened product. The standard indication shows the capacity (in tonnes) that can be lifted (middle of 1 ton or more), and the tilt lever installed in the cockpit is a master (858) equipment, while at the same time providing for the operation of a forklift (858), with a maximum of 4500 mm and a minimum of 3000 mm , The minimum radius (the angle of steering of the wheels inside 65 ° and 75 °) is very small and the pressure of the hydraulic piston is set to 110130 kgf / cm ^2. At the same time, all-wheel drive is provided in the rear- The steering apparatus of the forklift 858 is provided with a rear-wheel-drive-type steering wheel, but at the same time, there is provided a master bundle that operates at hydraulic pressure (hydraulic pressure of 70130 kgf / cm ² ). At the same time, the fork is raised 150 m from the ground However, The distance is within 250m from station when effective, the front wheels are directly installed on the frame and the rear wheels is small, but the suspension springs is large is also used for suspension springs.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, For a forklift (858) to control the equipment, the efficient transportation distance is suitable for the operation within 250m. The height of the fork during the operation is 150200mm height for carrying the cargo. The fork part (front part) of the cargo carrying the cargo is directed to the upper part and moves backward. It is composed of the forklift (858) equipment which adjusts and disassembles the hull position of the marine hydroelectric power station proprietary dock (593,594,595).

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, Conveyor (633) equipment for machinery is mainly used for transportation of materials and concrete. It is widely used because it is easy and economical to install. In the case of kind, large conveyor is used for transportation of sand, soil, gravel, Screw conveyors are used for sand, cement and concrete conveying. Belt conveyors are the most widely used for soil, crushing and aggregate transportation. Size: tonm Portable conveyors are used for sand At the same time, it is necessary to provide hoisting of unoccupied driving vehicles and unimog in the car carrier, and at the same time, Uni mog is a vehicle that can be widely used in various fields of agriculture, civil engineering, snow removal and road maintenance, and hoisting is a vehicle which can be used in transportation, such as mud, It is connected to the nuclear waste disposal unit of the reactor installation of the nuclear power plant composed of the construction machine that carries and transports heavy materials.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The roller (863) equipment to prepare the machine is a compaction machine with two or more smooth drum rollers, which is a voluntary one with a voltage device. It is also called a voltage machine and is mainly used for the construction of roads, embankments, airfields and runways. The weight of the roller 863 is expressed in ton and the weight of the roller 863 is 815 ton when the weight of the roller 863 is 8 ton and the weight of the roller 863 is 8 ton. Load) up to 7 tons.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The rollers 863 provided for the machine are separated into a voltage-type oscillatory type and a pressure-type oscillatory type.

As shown in the above table, the reactor structure of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste (1) the hull position of the internal nuclear power generation facility (811), the transportation section of the construction machine (811c) The additional load (weight weight) of the yaw portion is called an additional load, which increases the voltage capability by loading the additional load when the voltage capability is small due to the weight of the roller itself. The additional load includes iron, water, and sand. The tire roller provides the necessary amount of water to the water tank. At the same time, the machine, tandem, and tamping roller increase the voltage capability by injecting an additional load on the wheel.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, In the sorting by the pressurizing method for preparing the machine, the voltage type compaction machine is separated into a load roller, a tire roller, and a tamping roller, the impact type compaction machine is separated by a rammer and a tamper, and the vibration type compaction machine is divided into a vibration roller 863a, Factor 863b.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The roller of the static pressure by the type and the characteristics of the rollers for preparing the machine is used to prepare the road surface by the static self weight of the rollers and the use of the Machadam roller 863c is applied to a crushed stone layer, It is suitable for initial compaction when packing. It is characterized by a differential gear which can decelerate the speed of the inner ring for smooth turning when the curve turns. It is mounted at the center of the rear axle, Speed.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The use of the tandem roller 863d for preparing the machine is suitable for the compaction of clay and clayey soil and is used for finishing the asphalt pavement and for finishing the asphalt pavement. The order of power transmission is engine main clutch transmission front and rear differential gear type decelerator It can not be used for crushing and compaction. It is equipped with two-axis tandem and three-axis tandem with cylindrical steel wheel which is injected with heavy oil into the driving drum, but also the compaction width is broadened It is possible.

As shown in FIG. 3z, the use of the tamping rollers 863e is used to adjust the softness of the soil. The tamping roller 863e is provided with a plurality of projections in the form of a plurality of projections in the form of cylindrical projections, We will make arrangements.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The tire roller (863f) equipment that equips the machine is equipped with a tire in place of the iron wheel of the tandem roller, and has a traction type and self-propelled type. The application is used to uniformly maintain the pressure of the road surface during the airfield runway and highway asphalt pavement. The air pressure of 1.510 kg / cm ^2, and the characteristic was that the traveling speed was very high.

Thus, the roller by centrifugal force is used to concentrate the surface by centrifugal force on its own weight, and the vibrating roller is suitable for compaction of crushed stone, gravel, earth, asphalt and concrete by vibrating the compaction wheel by vibrating the vibrator. The weight of the equipment.

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The impact-type compaction machine to set up the machine is equipped to tighten free-fall impacts, while the Rammer is equipped with a compaction foot on the two-stroke cycle engine body of a small internal combustion engine, while Tamper is used to torque the explosive force of the gasoline engine And is changed to a reciprocating motion of the crankshaft and then transmitted to the compaction plate through an elastic body of the spring. The structure is suitable for tightening a narrow place and a road, and the soil compactor 863b is equipped with a small- Is a compaction machine in which a vibrating body is combined with a flat vibrating body, There was that that would fit the clay inappropriate.

The equilibrium is the line pressure due to the width (maximum width) of the rollers compaction width in one pass, which is the value of the ground weight of the wheel divided by the width of the wheel (kg / cm).

As shown in FIG. 3Z, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structure block tank dust collector for nuclear waste treatment, the transportation section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, The soil stabilizer (864), which is the same as the road safety device that provides the machine, road. It is a stable processing construction machine that can be used as an economical compaction stabilization method for aerodrome construction and can finish various kinds of work in real work at one time. Therefore, it is to put the road and bedrock materials precisely on site, (593,594,595) Nuclear power plants are composed of distributing devices of construction machines that provide movement control and disassembly of the hull.

Referring to FIG. 4, the structure of the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention is transferred to the inside of the nuclear reactor main body 1, The upper tank barge hull 591 of the holding tank and the lower tank barge hull 592 of the holding tank are connected to the central holding tank 598 of the double structure block tank 598 by the auxiliary supporting coupling detachment portable lug coupling pin 811a, Detailed assembly process showing the assembling structure of the floating hooking hull structure in the sea with the connection shaft 606 and the portable lug 607. Nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility section 811 Of the nuclear power plant of the ocean power plant in the assembly method of the hull assembling system,

As shown in FIG. 4, the reactor main body 1 of the nuclear power plant constituting the nuclear power plant facility and the nuclear reactor facility 1, the internal nuclear power generation facility 811, the hull position of the nuclear power nuclear waste treatment unit 811a, Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant (1) At the same time, the nuclear power plant equipment is provided with an internal block tank 596 equipped with a double structure block tank 598 and a buoyancy regulating tank 593 provided in an empty space of the outer block tank 599, The outer portion of the floatation restraining outer wall is provided with a pin connection shaft 606 for coupling the lug 607 and a lug pin 608, (941) and marine hydroelectric power station (593, 594, 595) are the same as the device that unclamps and unfolds the table legs. The barge hull is equivalent to the table top table type. The table-top table facility, which is equivalent to the holding tank 590 of the barge hull, is provided with an operation mode in which the table table legs are freely pushed and unfolded by manpower, The operation of unfolding and unfolding the hull is performed by assembling the holding tank 590 of the barge hull to the hydraulic rotary cylinder 620 and the hydraulic cylinder 623 and the hydraulic cylinder door assembly 624 by the barge hull assembling devices at the sea level In the nuclear waste treatment storage tanks and water intake dams, (936), and a holding tank (590) connected to the buoyancy control tank and connected to the operation structure of the marine nuclear hydroelectric power station.

4, the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste constituting a reactor facility main body 1 of a nuclear power plant is connected to a nuclear power plant 811, The nuclear power plant of the nuclear power generation plant 811a and the double structure of the nuclear power plant are inserted through the distribution shaft constituting the collector of the nuclear power plant and the nuclear reactor, A buoyancy adjusting butterfly valve 622 provided in a connection structure with the buoyancy adjusting tank of the barge hull and an opening of a buoyancy adjusting butterfly valve 622 having a connection structure with the solenoid valve 76 are provided, (66) operation of the on-time main switch button (66) of the barge, A barge hull 591 at the upper end of the holding tank and a barge hull 592 at the lower end of the holding tank are connected to each other through a connecting structure of the holding tank 590 to the upper end SLU of the sea surface to provide a barge hull, The sea water surface upper end portion SLU provided with a coupling structure at one side of both sides of the holding tank 590 equipped with the block tank combined portable lugs 607 of the barge hull, The buoyancy control butterfly valve 622 provided in a connection structure with the buoyancy control tank on the hull of the barge and the opening of the buoyancy control butterfly valve 622 having the connection structure to the solenoid valve 76 are connected to the solenoid valve 76, (66) of the main switch button for the start switch button is provided, and at the same time, an empty space for the diving control on the barge hull is provided The hydraulic cylinder door 624 is opened by the operation of the pressure cylinder 623 so that the barge hull assembling apparatuses form an assembly form of the nuclear power plant facility at the sea level.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, the electrolytic water is filled in the empty space for controlling the diving, and at the same time, the barge hull loses its buoyancy, and at the same time, And simultaneously lug-coupled to a single vertical processing lug (615) portion on one side of a plurality of vertical lugs (607) on both sides of a holding tank (590) equipped with a block tank-engaging portable lug (607) The connecting pin shaft 606 structure is coupled to the hydraulic rotary cylinder 620 by the operation of the hydraulic cylinder 623, At the same time as the vessels 624 are fully closed, the horizontal holding tank 590 pipe bridge 928 is connected to one side of the vertical lug 607 by the barge hull and lug 607 without losing buoyancy. The bottom tanker hull 592 of the holding tank bottom barge hull 592 is first submerged at the same time as the barge hull in the water at the position of the connecting shaft of the horizontal state holding tank 590 at the position of the connecting shaft fore- And the assembly form of the nuclear power plant equipment is formed at the bottom of the sea surface at the bottom of the sea surface.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition, at the same time, in the nuclear power plant facilities, the stern of the connecting column shaft 590, which is not connected to the hull of the barge, is connected to the vertical The stern section of the connecting column 590, which is not connected to the barge hull at the same time as the holding tank upper barge hull 591, is vertically moved to the vertical position (590), and the stern portion of the holding tanks (590) The top of the tank top barge hull (591) is equipped with a distributing input device connection structure and at the same time a submersible and semi-submerged ship (637), a barge and tugboat (636) and a floating crane Construction equipment of anti-erector and anti-aircraft (877) and disposal of nuclear waste Discharging and dispensing equipment of marine tunnel traffic system Position shifting device and throttling device are inserted to prevent sinking (593,594,595) distribution equipment of the marine hydroelectric power plant by putting the position shifting control device and the throttling control device of the construction equipment and nuclear waste disposal marine tunnel traffic equipment equipments to install the nuclear power plant equipments And at the same time, a hollow space for diving control of the barge hull is provided with doors 624 for hydraulic cylinders by the action of hydraulic cylinders 623 Room is provided consists of an assembly in the form of a nuclear power plant equipment be made in the sea surface location to the barge hull assembled device.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (607) equipped with a block tank combined with a barge hull provided at the sea, the nuclear power plant equipment is provided with an inserting unit for inserting the nuclear power plant equipment and the nuclear reactor equipment through both sides of the distribution shaft constituting the equipment and the reactor equipment, A holding tank 590 of a barge hull of a coupled connection structure is connected to one side of both sides of the tank, and a holding tank 590 for providing a buoyancy adjusting device in the body of the barge hull is vertically and horizontally disposed at a predetermined angle of 0 ° to 350 ° Of a marine hydroelectric power plant equipped with a landing block tank capable of controlling the position of a nuclear power plant (591) Inside of the ship's deck center (SDM), a plurality of inner block tanks (596) are installed in the center of the hull deck center The double structure barge hull 591 at the upper end of the holding tank 590 for inserting the adjustment shafts is provided at each end of the hull deck upper part A guide rail 618 is installed on the left and right sides of the deck deck and a crane 861 having a capacity of 5000 tons is formed on the guide rail 618 while moving installation inside the barge hull is provided, The assembly devices consist of an assembly of nuclear plant installations at sea level.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (861), which is installed in nuclear power plants and reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities, and at the same time, the nuclear power plant equipment is provided with a double structure The sliding hatch cover (153) is installed in a double or triple structure. A hydraulic structure (623) is provided at one end of each of the control shafts to adjust the position of the hull. Hydraulic pressure A cylinder 623 and a barge hull 591 at the upper end of the double structure holding tank and a barge hull 592 at the lower end of the double structure holding tank The lag 607 and the lug connection shaft coupling bolt 603 and the lug connection shaft coupling and disassembling nut 604 are connected to each other by the disassembly coupling portable lug coupling pin connection shaft 606, The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility 811 and the transportation transportation units 811c of the construction machine to adjust the positions of the respective control shafts, The flood control installation includes dual structure block tank bridge pier (928) of double structure block tank (598), nuclear waste dual structure block tank pipe bridge (929), dual structure block tank pipe bridge (937) (591) at the top of the holding tank at the upper end of the holding tank of the above-mentioned control shaft (591), and a deck-side hull deck center inside The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 and the electric power production and production unit 811b that generates power and the construction And a power transmission unit 811d that transmits power to the transportation transport unit 811c of the machine and the nuclear power generation facility 811 is provided with a nuclear power plant safety control production production front 811e and an electronic control & A control unit 811f and a screw control unit 811g, so that the nuclear power plant equipment can be remodeled in an assembled form.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plants and the reactor facilities are inserted into the nuclear power plant facilities and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the reactor facilities, In addition, at the same time, in terms of producers, the nuclear waste treatment dual structural block tank, the connection structure of the connection shaft of the marine tunnel traffic device (941), the nuclear power plant (1), and at the same time, the reactor main body (1) of a nuclear power plant 1) Efficient operation of the nuclear power plant It is connected with the electronic control and control system connection structure of the hydroelectric power plant which improves the nuclear power generation facility to regulate the flow of power, automatically checks the power to each distribution shaft, (591) of the double-structure barge hull (591) is equipped with a distributing and feeding device for adjusting the hull position so that it can withstand the natural disasters of the sea. Consists of.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (1) the nuclear waste disposal structure consisting of the inside of the nuclear reactor plant main body (1) of the nuclear power plant, and the nuclear waste disposal structure Block tank The marine tunnel transport device (941) and the marine hydroelectric power plant aquaculture, the large hydroelectric power plant (944) included in the control shaft of the hydroelectric power plant of the marine Seisoh Hydroelectric Power Plant (943) And the kinetic energy of the gravity due to the liquid energy, which is the liquid energy, is converted into rotational energy by the propeller (146) and the turbine (267) At the same time, the propeller 146 and turbine 267 devices of the large hydroelectric power plant 944 to the marine Seisoh hydroelectric power plant 943 are different from the intake and water supply facilities, The industrial field of the float ship hull with priority of production is provided with a double structure block tank bridge pier 928 formed as a double structure block tank 598 connecting the books at the same time and maintaining the distance of 1 km, A nuclear waste disposal structure double structure block tank bridge 929 and a nuclear waste disposal double structure block tank 941 are installed on a guide rail 618. A power cable The power generation and supply unit 811b of the nuclear power generation facility unit 811 is provided with the connection of the transmission line 71 to the inside of the nuclear waste disposal marine tunnel transportation device 941, The power transmission unit 811d for transmitting the power to the industrial site and at the same time the distribution of the power supplied from the large hydropower generators 944 included in the control shaft of the hydroelectric power generator of the marine seesaw hydroelectric power plant 943 (591) that allows double structure barge hull (591) to withstand the natural disasters of the sea while having a connection structure to the shaft. The distribution system of the position adjustment of the barge hull (591) .

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, nuclear power plant facilities are provided with a holding tank (590) at the lower part of the central position of the deck deck at the top of the holding tank upper barge hull (591), and at the same time, The valve, which is opened at the time of the switch button ON to provide a position in the center of the center and closed at the time of the switch off, is operated by the buoyancy adjusting butterfly valve 622 and the solenoid valve 76 While the switch button-on door is opened and the hydraulic cylinder door (624), which is closed when the switch button is turned off, is identical to the safety device of the submarine, At the bottom of the sea where the large barge hull 592 is located, a submarine ground excavation is provided by a core drill 917. At the same time, a boring hole 936 is drilled at the bottom of the sea floor with the core drill 917 At the same time, after the drilling of the borehole 936 on the ground surface, the natural loess soil 158 is kneaded with a mixing equipment mixer 649 in a kneading room for preventing the release of noxious gas into the gap 15 of the borehole 936, The natural loess soil 158 mixed with the mixer 649 is buried in the void space 15 of the excavated borehole 936 while the natural gas 922 is collected by the mixer 649. At the same time, The power plant equipment is provided with a connection structure to a distribution shaft provided by large hydroelectric generators 944 included in the control shaft of the hydraulic power generator of the marine seesaw hydroelectric power plant 943 while the double structure barge hull 591 is connected to a natural disaster Pants to withstand Hull 591 is input to the distribution device of the positioning assembly in the form of a nuclear power plant equipment configuration be made the renovation of a nuclear power plant.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The hatch cover 153 is provided with hydraulic cylinders 623 and 623 as safety equipment for replacing the equipment, and at the same time, inserting the nuclear power plant equipment and the reactor equipment through both sides of the distribution shaft constituting the equipment and the reactor equipment, (1) to provide a connection structure to the distribution shaft inside the nuclear reactor plant (1) of the nuclear power plant, and to allow the hull of the nuclear power plant to withstand the natural disasters of the sea. The construction machine equipment provided with the process sets up the double structure block tank pipe bridge 928, and at the same time, the wing crank 846 is provided to the anti- (593,594,595) of the marine tunnel transportation device (941) and the marine hydroelectric power plant (593,594,595) are installed on the submarine by the distribution input device of the hull position adjustment. do.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (1) The nuclear power plant equipment is connected to the distribution shaft to the inside of the reactor main body (1) of the nuclear power plant by inserting the nuclear power plant equipment and the nuclear reactor equipment through both sides of the distribution shaft constituting the equipment and the reactor facilities. (597), which is equipped with a nuclear power plant facility and a nuclear reactor facility control process, is installed in a certain size, butt joint welding is performed, and the shape of various welded joint grooves The design of the welding improvement surface is carried out manually by hand considering the tensile strength and the thickness dimension of the steel plate, A first auxiliary steel section 600 for a block tank processed by laser underwater cutting and computer cutting by connecting the design dimension to the nuclear power plant facility with the laser underwater cutting computer control section through the computer network input 68 to the memory 70, The second auxiliary steel plate 601 for the block tank, the snap hole 602, the block steel tower 116, the vertical partition wall 605, the portable lug 607, the horizontal partition wall 609, the partition wall manhole 610, The manhole manhole cover 152 and the machining hole 615 of the hatch cover 153 and the block tank large flange 614 and the elongated hole 616 of the portable lug 607, The same double pipe structure tank bridge construction submerged saddle formwork 617 as well as the underwater laser cutting machine in the form of the band guide 621 and the reinforcing steel plate 165 are operated simultaneously and at the same time, The high-strength steel plate 597 is rolled to a 500-mm standard length A plurality of large hydroelectric generators (not shown) which provide a combination of a double structure block tank 598 with a water channel and a large flange 614 on one side of the inner and outer parts of the inner and outer tubular parts, 944) is a power generating device that provides a connection structure to the distribution shaft of a hydro-electric power station floating tank (593, 594, 595) inside a nuclear reactor main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (1) The nuclear power plants are installed in the nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the facilities and the reactor facilities. At the same time, The drilling machine 908 for crude oil constituting the connecting structure is provided with a core drill 917 which is coupled to and disconnected from the pipe rack 854 for providing the drilling machine 908 with crude pulverizing operation during crude oil, (185) of a worm crank (846) replacing an anchor bolt (133) for providing a safety mooring with the mooring device of the floating attachment while providing excavation, A hydraulic cylinder 623 provided at the center of a quick-dry bed 616 for providing a connection structure at the lower end of a holding tank 590 of a barge hull is operated by an actuator 848 and at the same time, (846) attached to the lower part of the pier of the pier when the ship is anchored to the nuclear power plant facilities at the same time, and a crane (846) fixed to the borehole It is also possible to fix the web 185 to the hydraulic cylinder 623 with the actuator 848 and at the same time to adjust the direction of the web belt 185 to the hydraulic cylinder 623 with the actuator 848, (593,594,595) of each control shaft to the inside of the nuclear reactor plant main body (1) of the nuclear power plant in the floating nuclear plant to provide control of the nuclear power plant Is composed of a plant body (1) support reactor equipment constituting be position adjustment is made to the interior sikdok nuclear power seolbibu 811 position hull construction machine transportation unit (811c) of the distribution of the control of the input device.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (1) The nuclear power plant equipment is provided with a connection structure to the distribution shaft to the inside of the reactor main body (1) of the nuclear power plant while inserting the nuclear power plant equipment and the reactor equipment through both sides of the distribution shaft constituting the equipment and the reactor facilities. (593,594,595) Barge hull (591) Above the center of deck deck The block pylon (116) is equipped with a satellite launch pad (643) and a space rocket launch pad (646) to the left. At the same time, the satellite 611 and the space rocket 612 are mounted on the left and right sides of the inner center of the respective launching rods of the nuclear power plant, It is more powerful than the atomic bomb to remove the factor of destabilizing the international community, which is anxious due to the war that is similar to an artificial disaster, the terrorism, the nuclear test and the launch of the missile. At the same time, It is necessary to overcome the economic crisis and to resolve the unemployment crisis, including both the global economic crisis, the unemployment crisis and the natural disasters, and at the same time, to create a reconciliation mood between the strong and weak countries in nuclear power plant facilities, It is necessary to share peace with the Northeast Asian neo-Confucian states including the treaty documents and the constitutional content of the Nuclear Power Plant (1) to prevent the production of all kinds of commercial weapons for any reason and without any excuse. The hull position of the oceanic hydroelectric power plant flood control station (593,594,595) (811c) of the construction machine of the hull position control of the nuclear power plant (811), which constitutes a control system for controlling the position of the nuclear reactor facility inside the reactor main body (1) of the nuclear power plant providing the disassembly and assembly, .

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition to providing inserting into nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities, the nuclear power plant facilities shall be provided with a unique territorial and territorial sea, which should be mutually respected regardless of whether it is a powerful country or a weak country. I think it is yours. "The development of space science and the creation of a peaceful global village, taking into account the domestic circumstances of the strife that disputed. Nuclear waste treatment in the sea, (941) facilities are provided with the dimensions of the circumference of the global circumference, and at the same time, (1) Nuclear power generation facility (811) Nuclear waste treatment facility (811a) Nuclear waste treatment facility (811a) The deck of the upper deck of the sea deck (SL U) In addition to providing the exchange of cultural knowledge information while equipping the construction machinery, the distribution of the load of the pipe bridge object which allows the future civilization to flow freely is provided, and at the same time, the position of the hull for the renovation of the nuclear power plant equipments, The position of the hull of the floating power plant 811 which is arranged to adjust the position of the nuclear reactor facility to the inside of the nuclear power plant main body 1 of the nuclear power plant for the operation of the marine power generation plant and the marine environment industrial power generation, And a transportation transport section (811c) of the control construction machine.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant equipment and the nuclear reactor facility are provided with the inserting facilities for the nuclear power plant equipment and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the nuclear reactor facility, (811) Nuclear power plant (811) Nuclear power plant (Nuclear power plant) 811e of nuclear power plant control facility operation control facility (811e) (10) has a double pipe structure control nozzle (10) for joining a T-shaped elbow in a cross shape in the form of a cross, In the upper part of the deck deck, a 15M long fire hose (9) is provided with a thermal cross-shaped control nozzle (10), and at the same time, the sea surface to the side of deck deck The air in the control room is supplied to the receiver tank 145 through the hose 109 when the internal air compressor 80 is operated. (40) of the control piping line of the compressed and stored pipeline is supplied while the control hose (9) which spreads like a net to the side of the deck deck provides high pressure air pressure Discharge jetting is provided and the prevention of damage from the harmful red tide of the marine aquatic products is provided, and at the same time, the harmful red tide dispersion eradication with the sediments of the seabed to the nuclear power plant facilities is provided At the same time, the position of the hull which can be remodeled is adjusted by the distributing and inputting device to the nuclear power plant facilities, And a dispatching and dispensing device of the transportation unit 811c of the construction machine of the hull position adjustment of the floating-type installed nuclear power plant 811 configured to adjust the facility position.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition, as a function of the function of the marine cleaner, the continuous control activities of the nuclear power plant equipments are carried out in the vicinity of the offshore water supply and drinking water facilities. The bridges are designed to provide an alternate water gate for the upper and lower operation, while maintaining the opening of the water gate, And the flow of the flow of the distribution shaft into the reactor main body (1) of the nuclear power plant is restored In addition, it is necessary to prepare harmful red tide dispersal along with the sediments of the seabed to the nuclear power plant facility, and at the same time, to the nuclear power plant facilities, the location of the hull to be renovated (811) which is arranged to control the position of the nuclear reactor facility inside the reactor main body (1) of the nuclear power plant for the operation of the generator of the offshore power plant and the marine environment industrial power generation by arranging the position of the nuclear power plant ) Of the hull position adjusting construction machine 811c.

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, It is necessary to insert both nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities. At the same time, the control devices to the nuclear power plant facilities are provided for protection of fishery products and seafood, At the same time, a series of measures are taken so that the living beings can breathe and stay alive at the nuclear power plant facilities. At the same time, a garden basket 842 for the harmful redeye suction dust collector is attached to the nuclear power plant equipment, (19) and to the nuclear power plant facilities at the same time while removing harmful red tide breeding before the harmful red tide. And is constructed to be connected to the land and land so as to provide an unspecified sea pirate with a net made of a wire rope and a net 932 and a net for securing a fishery resource 842, (593) and a peacekeeping force in a three-dimensional operation, the floating cargo ship (593) is submerged in the water, and when passing through a pirate ship, the water inside the barge ship is pushed out and the air is taken out of the sea floor The ship is supplied from the air hose line to provide a floating position to the upper sea level (SLU) position. At the same time, the position of the hull to be remodeled is installed in the nuclear power plant facility by the distribution input device, (1) A nuclear power plant nuclear power plant for operation and marine environment industrial power generation equipped with a generator And a dispatching and dispensing device of a transportation transport section (811c) of the construction machinery of hull position control of the western style nuclear power plant (811).

As shown in FIG. 4, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, nuclear facilities are equipped with nuclear power plant equipment, such as fish caught in the net, and the pirates are provided with a pinhole stamper inside the net, In the future, the pirates will be released to the world by means of a mass-media report sent to the unmanned camera (184) by the unmanned camera (184), and those who are involved in territorial disputes and those who do not participate in the reduction of the armaments The scene that was prepared to be exiled to the outside world was broadcast on media coverage, Even though the war is triggered, the image of Photoshop which is stronger than the atomic bomb has already been released on the internet all over the world, so that the people of each nation who give up the war will gather the will of peace, Nuclear waste treatment dual structure block tank prepared in preparation for the occurrence Nuclear reactor facility (941) equipped with a nuclear reactor facility within one day to distribute nuclear power to the reactor main body (1) (811c) of the construction machine of the hull position control construction equipment of the buoyant pilot Nuclear power plant (811) which constitutes the position control, and the flow control process to the nuclear power plant facility by the distribution input apparatus Respectively.

Referring to FIG. 4A, the structure of a nuclear power plant 811 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention is transferred to a nuclear power plant 811, (811a) to connect the crude oil drilling rig structure showing the construction machine position control structure of the marine power station floating structure (593,594,595) to the marine power plant dock top deck (SDU) (937) and Nuclear Waste Treatment Ocean Drilling Machine (908) into the interior of the marine tunnel traffic facility (941) Nuclear power plant construction Construction of the connecting structure of the road Construction of road,

As shown in FIG. 4A, a reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant equipment includes a bridge pier 928 which shows the configuration of the position adjustment mechanism of the construction machine for adjusting the position of the hull, (908) construction machinery connection structures inside the bridges (937) and the nuclear waste disposal dual structure block tank marine tunnel traffic facility (941), and at the same time, to the nuclear power plant facilities, The power station floating dishes 593, 594 and 595 are connected to a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder and a butterfly valve 6 22, a hydraulic cylinder, a hydraulic actuator 623, and a door for a hydraulic cylinder 624, the vertical partition wall 605 and the pin linking shaft 606 for the portable lug coupling A portable lug 607 and a portable lug fin 608 and a large flange connection joint joint area machining hole 615 and a construction machine link structure and bridge bridge 928 and a pipe bridge 937 and a nuclear waste treatment dual structure block tank (908) hydroelectric power plant construction machine connection structure and disassembly combined to constitute nuclear power plant facility and nuclear reactor facility,

Referring to FIG. 4B, the structure of the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention is transferred to the inside of the reactor main body 1, (811a) showing a partial partial structure of the steel structure front side of a double pipe structure provided with a steel plate bending method and a weld joint basic method for a piping block of a marine power plant lifting plant, Nuclear power plant installation Lifting construction of hood assembly method Road,

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, It is necessary to insert both nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities. At the same time, the nuclear waste treatment of the nuclear power plant nuclear power plant facilities to the nuclear power plant facilities. In the apparatus tube manufacturing process 705, a small-diameter electric resistance welding pipe 706 manufactured by a marine vessel manufacturing department that controls production by a disassembly-connectable connection structure at a marine vessel manufacturing factory of a connection shaft is provided with a raw material 707, (712) process to the ring leveling 709, the side trimming 710, the cutting and the rough connection 711, The weld heat treatment 715 is performed while the ultimate wave and eddy current test 714 is performed on the equipment and the welding and the inner and outer bead removal 713 are performed by using the air cooling 716 and the centrifuge 718 The process of calibrating 722 of the structure tube 721 is performed in the intermediate stack 723 and in the induction heating furnace 724 by hot cutting to the SRM 725 standard while providing the cut 719 and the flatness test 720. [ The ultrasonic wave and eddy current test 729 and the weight and length measuring instrument 730 are visually performed to perform the dimensional inspection 731 and the tube manufacturing process 726, the chamfering 727, the hydrostatic test 728, 708), a screw (732), a cast iron (733), a general piping (734), a galvanizing (735) and a galvanized steel pipe (736) and a boiler tube (737) And at the same time, a small diameter electrical resistance welded pipe (706) to be manufactured in the reactor body manufacturing section of a nuclear power plant is formed. In addition, The resistance welding pipe 739 is provided with a pipe forming ultrasonic wave 743 and a flaw test 744 by a cage forming device 742 connected to the side trimming device 741, The production of a medium diameter cage-shaped electrical resistance welded tube 739 manufactured in the main body manufacturing section provided with the end molding 745 adjustment to the process 705 is constituted as a reactor installation of the nuclear power plant with the dispensing apparatuses, The large-diameter steel pipe 747 of the oil pipeline for oil industry 746 is equipped with an edge milling machine 748 and a three-roll banding machine 749 and a post-banding machine 750, (754) is performed while providing preparation for the weld 751 and the inner weld 752 and the back weld 753 while providing the manufacture at the reactor facility body manufacturing section of the reactor installation The sling 755, the tube section 756 and the X- (759), cold expansions (758), and marking and packaging shipment (759) process steps to the tube manufacturing process (705) while providing process operations to the dispensing devices The construction of the coil ring 761 and the non-bladed pile 763 of the steel pipe pile 762 is similar to that of the primary paint 764 of the outer blast cleaning 764, the inner blast cleaning 765 and the inner paint 766 767) and the coating and coating process 768 are performed while simultaneously performing the ultrasonic wave and X-ray inspection (770) process to prepare the large-diameter steel pipe (746) of the oil- 747), and at the same time, the mooring device and the buoyancy control device (593,594,595) constructed in the marine power plant floating plant (1) inside the nuclear plant main body (1) of the nuclear power plant, Nuclear reactor facility main pipe manufacturing process (705) Connection ship marine vessel manufacturing plant A nuclear waste treatment double structure block tank bridge 929 constituting a nuclear reactor facility main body 1 of the nuclear power plant is constituted so as to constitute a nuclear reactor facility main body 1 of a nuclear power plant, The distribution side 705 of the pipe manufacturing process of the connection shaft provided for manufacturing the connection structure capable of disassembling and coupling the connection shaft of the nuclear waste disposal double structure block tank and the marine tunnel transportation device 941 is characterized in that the body of the double structure block tank 598 has a center And an outer block tank 599 for providing a position outside the inner block tank 596. The high-strength stainless steel plate 597 in the form of a double structure is used for cutting and welding at the industrial site Process and connection Structure Double structure block manufactured by distributing injection device Block connection of tank (598) to the distribution device of nuclear waste treatment double structure block tank marine tunnel traffic device (941) The first auxiliary steel pipe 600 and the second auxiliary steel pipe 601 for the block tank are connected to the aft and stern connection positions of the double structure block tank 598, The large flange 614, which provides a location for the connection shaft connection structure, has a large flange connection flange connection flange 614 of the large flange connection position, a large flange 614 for positioning the connection flange 614 with the cutting tool, (625) of a certain size are provided as a nuclear reactor main body of a nuclear power plant in the manufacturing process, while at the same time a nuclear power plant equipped with a double structure block tank dust collector for nuclear waste treatment (1) Nuclear Power Plant (811) Nuclear Power Plant (811a) Movement of hull position to nuclear power plant facility and nuclear reactor facility The nuclear power plant is a nuclear power plant facilities and equipment and the reactor equipment with a resolution combined into a construction machine of a construction machine transportation unit (811c) for providing the insertion configuration to the reactor plant so as to penetrate through the shaft on both sides,

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition, it is also possible to insert the nuclear power plant equipment and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the nuclear reactor facility. At the same time, according to the manufacturing process according to the safe design of the nuclear reactor facility body of the nuclear power plant, (598) of the metal structure for the steel structure for manufacturing and installing the reactor main body is provided with a steel plate (597) made of high-strength stainless steel so as to provide a marking process, and at the same time, The overhead crane 861 and the conveyor 862, which are fed into the double structure block tank 598 in accordance with the cutting and conveying process sequence, (597) of a high-strength stainless steel is bent at right angles to a foaming bending machine using a foaming machine and a roll foaming machine according to the thickness of a steel sheet of a high-strength stainless steel steel plate (633) The bending process of the bending type (b) and the round bending type (c) is carried out, while the bending process of the press braking type, the bending type roller bending process machine and the bending roll bending process machine A bending process of a high-strength stainless steel steel plate 597 and bending of the steel plate 597 are performed while the upper end of the high-strength stainless steel steel plate 597 is bent by the overhead crane and the conveyor 633, At the same time as installing the ceiling crane and conveyor (633), the equipment of the nuclear power plant is equipped with welding machine, cutting tool, drill lathe and cutter A large flange (598) having a large flange (614) for providing a position for a stern connection with a bow of the double structure block tank (598) while performing a welding process to the banding joint portion of the high-strength stainless steel plate (597) 614 are provided as a nuclear plant main body connection structure of a nuclear power plant of a manufacturing and processing shelf process with a certain size of stopper steel plates 625 and are arranged in a position outside the inner block tank 596 and the inner block tank 596 The inner block tank 596 is moved to the inner position of the outer block tank 599 and the position of the inner block tank 596 is adjusted to the overhead crane 861 and the conveyor 633 (593,594,595) equipped with a dual structure cylindrical connection structure inside the nuclear reactor facility of a nuclear power plant after completing the welding process, the dual structure block Nuclear waste treatment double structure block tank bridge 929 and dual structure block tank pipe bridge 937 and nuclear waste treatment dual structure block tank marine tunnel transport device 941) a plurality of distribution shafts and a double structure block tank 598 for distributing to the disassembly-connectable connection structure of the connection shaft to provide the discharge to the facility of the tube manufacturing process (705) of the reactor main body 1 of the nuclear power plant, To be operated.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (588) of the double structure block tank (598) are provided with a plurality of holes (584) extending from both sides of the distribution shaft constituting the facility and the reactor facility to the nuclear power plant facility and the nuclear reactor facility, The first auxiliary steel pipe 600 for the block tank and the second auxiliary steel plate 601 for the block tank and the horizontal partition wall 609 and the steel beam 149 The second auxiliary steel plate 601 for the block tank, the second auxiliary steel plate 601 for the block tank, the vertical partition wall 605, the horizontal partition wall 609, the steel beam 149, the snap hole 602, (610) Each machine is equipped with a laser cutting machine, And the vertical partition wall 605 and the horizontal partition wall 609 in which the partition wall manhole 610 is formed are provided with a traffic device hydraulic cylinder door 624 and an emergency structure block tank 598. [ The stair step (631) equipment is provided with traffic devices provided by a welding process, and when the inside and outside are refurbished with a double structure block tank facility, the stair step (631) ) Is a press braking type bending machine, a bending type roller bending machine and three bending roller bending machine of the bending bending machine of the section steel bending and bending process with the bending and bending machine of high tension stainless steel (597) While at the same time the nuclear plant installation is provided with a double structure block tank 598, which is provided with a plug-and-loop fastening assembly of a dual structure block tank 598 having a cylinder- A plurality of inner block tanks 596 and a plurality of outer block tanks 599 are connected to the upper and lower ends of the double structure block tanks by a welding process and a large flange bolting connection device coupling structure is provided in an egg- (593,594,595) dual structure block (1) into a nuclear power plant and a nuclear reactor main body (1) at the same time as a plug- The double structure block tank bridge pier 928 of the tank 598 and the nuclear waste treatment double structure block tank pipe bridge 929 and the dual structure block tank pipe bridge 937 and the nuclear waste disposal dual structure block tank marine tunnel transportation device 941) Multiple distribution shafts to distribute to the connection structure capable of disassembling and coupling the connection shaft and to divide and dispense devices to provide the discharge Double structure block tank Nuclear power generation It is configured to be made and equipment nuclear reactor plant operations.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, A double structure block tank 598 is installed in the reactor main body 1 of the nuclear power plant, and at the same time, the double structure block tank 598 is inserted into the nuclear reactor main body 1 of the nuclear power plant, (593,594,595), which is composed of mooring device, diving buoyancy control device and marine tunnel traffic pipe manufacturing process (705), which are connected to the marine shipbuilding factory in the marine vessel manufacturing plant. And barge ship hull can be prevented from sinking and buoyancy control device can be assembled and installed, while at the same time, The nuclear power plant unit 811 configured to control the nuclear power plant facility and the reactor facility within the nuclear power plant main body 1 of the nuclear power plant with the power of 1000000k w / h, And the supply power is regulated by the power transmission control unit 811d for generating and delivering the generated power from the power production and manufacture unit 811b of the marine hydroelectric power plant, and at the same time, the nuclear power plant facility and the reactor facility main body 1, (593,594,595) Double structure block tank pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank pipe bridge (929) and double structure block tank pipe bridge (937) And nuclear waste treatment dual structure block tank marine tunnel transport device (941) multiple distribution axes and distributions to distribute to disassemblyable connection structure of connection shaft to provide discharge It is configured to be made separately admission teeth of the double structure block tank nuclear power plant facilities and nuclear reactor plant operations.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant equipment is inserted into the nuclear reactor facility main body 1 of the nuclear power plant through the power transmission unit 811d as well as the nuclear power plant facility and the nuclear reactor facility by inserting both sides of the distribution shaft constituting the facility and the reactor facility, Voltage substation 690 provided in the power plant and the voltage 684 to the transformer 96 via the primary substation 691 while being supplied with the power 685 produced by the marine hydroelectric power plant constituting the connection, A connection shaft for providing power 685 to the dual structure block tank bridge 937 including the large-scale plant 698 and the flood control console 705, (697) manufacturing of high-strength steel plates and the supply of electric power (685) to steel beam beam (149) and equilateral-beam steelmaking (839) The tank pipe bridge pier (928) is equipped with a diameter of 5M and is provided in the form of a reducer (35) per 1 km of water depth. At the same time, the diameter of the pipe pier is 5M and the diameter is increased by 1M A double pipe structure tank pier in the same form as the band guide 621 which provides connection of the flange 614 of the large flange 614 provided at the top of the deck deck to the semi-submerged operation line 637 of the nuclear power plant, (617) for construction is equipped with disassembly and coupling, and at the same time, a nuclear power plant and a nuclear power plant are installed in the main body (1) of a double structural block tank (598) (928) and nuclear waste disposal binaries A number of distributions to distribute and discharge the detachable connection structures of the block tank pipe bridge (929), the double structure block tank pipe bridge (937) and the nuclear waste disposal double structure block tank marine tunnel traffic device (941) It is divided into shafts and distribution dispensers, which are constructed to operate the dual structure block tank nuclear plant and nuclear reactor plant.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The inserts are inserted into the nuclear plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility, and at the same time, the junction of the bridge type saddle formwork 617 to the nuclear power plant facility is provided with various types of jigs A disaster shelter is provided while providing an attachment to the jig 22 by welding while providing a counter mooring device for replacing the breakwater 400 in the territory of the territorial dispute, A plurality of jig processing holes 615 and a plurality of jig breakers 185 are connected and disassembled simultaneously by connecting the coupling processing hole 615 and the plurality of jig breakers 185 to the link stand 249, And an anchor replacement level crane 846 and a bridge pillar level foundation base 851 are installed at the side and lower sides of the saddle form frame 617 for the anchor replacement crankshaft of the nuclear plant 1) of the worm crank 846 which replaces the anchor bolt 133 is located at the center of the key bed 616 that provides the connecting structure at the lower end of the holding tank 590 of the barge hull, While an operation of the hydraulic cylinder 623 provided with the anchor 848 is provided and at the same time an anchorage is provided to the nuclear power plant facility by the anchor replacement crank 846 at the seabed at the bottom of the nuclear power plant, The directional control of the webbing retractor 185 fixed to the borehole of the undersurface of the wreck crank 846 attached to the lower part of the pier of the pier is fixed by the actuator for operating the hydraulic cylinder 623 At the same time, (593,594,595) Dual structure block tank (598) Double structure block tank pipe pier (928) and nuclear waste treatment Double structure block tank pipe bridge (929) and dual structure block It is divided into a number of distribution axes that divide the tank bridge bridge (937) and a disassembly-connectable structure of the connection shaft of the nuclear waste disposal double structure block tank (941) Block Tank Nuclear Power Plant Facilities and Nuclear Reactor Facilities.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (2) The nuclear power plants are installed in the reactor main body (1) of the nuclear power plant, and at the same time, they are inserted into the nuclear power plant facilities and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the reactor facilities. A transportation transport section 811c of the floating construction hood position moving construction machine constituting the control of the nuclear power plant facility inside the reactor facility main body 1 of the nuclear power plant providing the movement control and disassembling assembly of the hulls 593,594,595, The double structure block tank 598 is moved to a marine assembly site by a tug line 636 constituted by a distributing / And at the same time, an assembling connection is provided by underwater operation to a nuclear power plant facility, a semi-submerged operation line 637, a band guide 621, and at the same time, a double structure block tank 598 is installed at a pipe bridge, The tugboat 636, together with the movement control and disassembly assembly of the marine tunnel transportation device and the marine hydroelectric power plant floodgate, sets the buoyant flag rubber balloon 628 and the rope 629 for confirming the diving position to the rope knot hooks The double ballast block tank 598 is connected to the outside of the double structure block tank 598 while the ballast rubber balloon 628 is formed as a medallion, (1) while maintaining the air inlet condition, the electronic control valve operation status, and the air hose (109) and pump hose status check, while providing diving and floating function checks. (593,594,595) Dual structure block tank tank (598) Dual structure block tank pipe bridge (928) and nuclear waste treatment double structure block tank bridge (929), double structure block tank bridge bridge (937) and nuclear waste (941) Double-structure block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connection shaft and provide the discharge. Nuclear power plant equipment and nuclear reactor plant equipment So as to be operated.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The semi-submerged operation line 637 to the nuclear power plant equipment is provided to the double-structured block tank 598 at both sides of the distribution shaft constituting the facility and the reactor facility, While the safety work is provided by the band guide 621 and the hydraulic cylinder key 623 while the barge hull 591 at the upper end of the holding tank is exposed at the upper end of the sea level SLL, The buoyancy regulating butterfly valve 622, the hydraulic cylinder door 624 and the hydraulic cylinder hatch cover 153 are separately connected to the tugboat 636, The cargo ship is provided with an anchorage at the ship sinking prevention stay line 634 while the water is being discharged to the outside of the tank and at the same time the block steel tower 116 composed of the diaphragm-type steel pipe 149 and the pipe, the emergency stairs 631 and the elevator 632 The ceiling crane crane 861 is mounted on the steel tower 116, the emergency stairs 631, and the elevator 632 of the nuclear power plant while being laid on the upper end of the barge hull deck deck at the upper end of the holding tank At the same time, the bottom tank barge hull 592 of the holding tank 592 is secured to the upper end of the upper end of the upper end of the barge hull deck deck of the holding tank at the sea level upper end portion SLU, , The emergency stairs 631, the bolts for connecting the elevator and the block unit lug connection shaft, and the block unit block pylon 116 for the lug connection shaft coupling and disassembling nut are provided inside the block steel tower 116, (593,594,595) Double structural block tank block (598) Double structure block tank pipe bridge (928) and nuclear waste treatment Double structure block tank bridge (929) Nuclear power plant facilities and reactor facilities ) And a dual structure block tank bridge 937 and a nuclear waste treatment dual structure block tank marine tunnel traffic device 941. A plurality of distribution shafts and distributing devices , Which is composed of a double structure block tank nuclear power plant facility and nuclear reactor nuclear power plant operation.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, the nuclear power plant equipment is provided with an emergency staircase 631, an elevator 632, and an aerial tower 644 of a mooring tower 644, which are installed in the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility. A lightning rod 500 is formed on the top of the block pylon 116, which is a metal rod with a sharp tip for preventing damage to the lightning strike when a thunderstorm occurs, and at the same time, a position is provided at the upper end of the lightning rod 500 And the weather zone information transmitted from the satellite 611 of the communication system is transmitted to the weather station At the same time, while providing diary information to the weather observation station, the control department of flood control facilities can prevent the natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods and droughts, (593,594,595) Dual structure block tank (598) Double structure block tank bridge pier (928) Nuclear waste treatment Double structure block tank bridge (929) Double structure block tank bridge (937 ) And Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) Double-structured block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connecting shaft, And nuclear reactor nuclear power plants.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (2) The nuclear power plants are equipped with nuclear power plant facilities and nuclear reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities. At the same time, An unattended camera 184 for unmanned on-boarding and an adevalon 77 of the meteorological observation equipment are installed in a basket 42 provided in the lower part of the meteorological observation apparatus in which the flood control process for the nuclear power plant facility is constituted, The burner boom 920 is provided to adjust the position of the burner boom and the fuel gas supply hose 694 to the nuclear power plant facility The hose 694 of the gas transportation means which is lighter than air by the shackle 23 and the lug 21 is connected to the inside of the disaster prevention hose 9 by the wire rope 19 for protection of the disaster prevention hose for fire fighting, The multi-stage pump 8 and the air generated by the air compressor 80 at the rear of the water shutoff valve 40 and the air compressor 80 are connected to the receiver tank 145 and the air storage tank, A water turbine boom 920, a high-pressure storage tank receiver tank 145, and a large-capacity hydroelectric power generator 944, which are located inside the large-capacity hydroelectric power generator 944, In the event of an emergency in the event of the generation of harmful gas during storage of the non-office kit 918, natural gas 922 and crude oil 841 from the storage tank and the storage tank, The cement 931 and the clay loops 158 and the cement 931 to recover the drilling space with the loess soil 158 and the cement 931 after the crude oil 841 is collected and produced. And a blender 73 as a device for mixing the loess soil 158 and the blast furnace 158. At the same time, the helicopter station 619, the crew work room, the control room, and the crew cabin cabin room machine room are provided in the nuclear power plant facility. At the same time, the satellite launch pad 643 and the space rocket launch pad 646, which provide the launch of the satellite 611 and the space rocket 612, are positioned at the left side of the safety control room of the nuclear power plant, The position of the mooring unit bollard 638 is provided with an anchoring vessel and at the same time a space between the artificial satellite 611 and the space rocket 612 is provided inside the artificial launching platform 643 and the space rocket launching platform 646, (593,594,595) Dual structure block tank (598) Double structure block tank pipe bridge (928) and nuclear waste treatment dual structure block tank bridge bridge (929) Double structure block tank pipe bridge (937) and nuclear waste treatment double structure block tank marine tunnel traffic equipment (941) are divided into multiple distribution axes and distribution input devices that distribute to disassembly connection structure of connection axis and prepare discharge. And to construct the nuclear power plant and nuclear power plant of the dual structure block tank.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition, the air compressor (80) facility is provided with a function to prevent the harmful red tide from breeding, and at the same time, A drilling machine 908 for supplying crude oil to the machine room 908 while providing installation on the sea floor with the hose 109 and the nozzle 923 and a pipe for a toothed- The rack 854 is provided with a crane (not shown) of the wire rope 19 of the overhead crane 861, which provides a connection rotation operation and at the same time provides positional shift control of the drilling machine 908 A pipe rack 854 of 15 meters in length providing a position at the upper end of the drilling machine 908 for providing the shoveling of the boom 65 while simultaneously providing the hooking of the tug- And at the same time, in the center of the barge hull at the bottom of the holding tank (590) at the bottom of the seabed at a depth of 10 km, the core drill (917) (593,594,595) double structure block tank (598) double structure block tank bridge pier (928) and nuclear waste treatment double structure block tank bridge (929) of nuclear power plant facility and nuclear reactor facility main body ) And double structure block tank bridge (937) and the nuclear waste treatment double structure block tank marine tunnel traffic device (941) connection shaft. The axis of the distribution and allocation input device, separated by a double structure of a block tank nuclear power plant facilities and nuclear reactor plant operations consist be achieved.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant equipment and the nuclear reactor facilities are inserted through both sides of the distribution shaft constituting the facility and the reactor facilities, and at the same time, the nuclear power plant facilities are provided with the nuclear power plant facilities The hydraulic cylinder device 623 and the hydraulic rotary cylinder 620, which are equipped with a nuclear power plant facility control process, which is constituted by a transportation and dispensing device for hull position control by the transportation conveying part 811c of the floatation moving facility construction machine, It is equipped with installed band guide (621) and hand tool hammer and wrench, And air compressors (80), while at the same time, the air pressure regulating device and the water pressure regulating device in the block tank in the nuclear power plant equipments are installed in the portable tank It is possible to provide a coupling with the lug 607 machining hole 615 and the pin linking shaft 606 for the portable lug coupling and at the same time to provide a coupling with the lug coupling shaft bolt 603 screw thread and lug coupling split nut 604 At the same time, a portable lug pin 608 is provided in the bolt thread end machining hole, and at the same time, the pin 608 is broken by a pin to the nuclear power plant equipment and the nut is fixedly coupled to the double structure block tank line The submarine wiring is provided and at the same time, the power is supplied to the land, and the pump and the air compressor (80) are operated before the occurrence of the harmful tide and before the harmful tide and the typhoon, Shaped flexible high pressure hose 190. At the same time, the disaster prevention water of the water pressure inside the pump piping line hose is provided with discharging water discharge jet number and radial type curtain water film through the nozzle gap, (925) and a downward current (926), it is necessary to prepare the power of the typhoon and prevent the global warming, and to transform the people of the nuclear bomb manufacturing party, which is equivalent to the harmful red tide, To the unmanned camera 184 to the wireless device radar of the computer system 611 of the computer system combined with the information exchange communication means of the Internet network 50 which peacefully resolves the international social dispute, (593,594,595) of the hydro-electric power station in the main body of the nuclear power plant (1) The double structure block tank bridge pier 928 of the block tank 598 and the nuclear waste treatment dual structure block tank pipe bridge 929 and the double structure block tank pipe bridge 937 and the nuclear waste disposal dual structure block tank marine tunnel transportation device (941) is divided into a plurality of distribution shafts that distribute to the connection structure capable of disassembling and disassembling the connection shaft, and a distribution input device, and are configured to operate the dual structure block tank nuclear power plant and the nuclear reactor nuclear power plant.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant equipment and the nuclear reactor facilities are inserted through both sides of the distribution shaft constituting the facility and the reactor facilities, and at the same time, the nuclear power plant facilities are provided with the nuclear power plant facilities (811c) of the construction equipment of the floating structure of the hull, the hull, the hull, the hull, the hull, and the hull, , While at the same time collecting submarine mineral resources and dissolving iron ore immediately Nuclear waste treatment dual structure block tank to control supply of iron ore, crude oil (841) and pollution-free natural gas (922) to the countries of the world while processing manganese nodule in furnace (909) The facility is equipped with a maritime trade volume control system and a double structural block tank pipe bridge (928) and a nuclear facility (593,594,595) double structure block tank (598) in the nuclear power plant facility and reactor facility main body Waste treatment Double structure block Tank pipe bridge (929), double structure block tank pipe bridge (937) and nuclear waste treatment double structure block tank marine tunnel traffic device (941) , Which are divided into a number of distribution shafts and distribution input devices, and are configured to operate the nuclear power plant and the nuclear power plant of the double structure block tank.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition to providing installation in nuclear power plants facilities and reactor facilities through both sides of the distribution shaft constituting the facilities and reactor facilities, it is also necessary to provide facilities for cooperation with the international community for economic development, and at the same time, , While at the same time keeping all military materials and bomb manufacturing experiments confined to the designated areas of the sea, and establishing peace preservation as a management form of the international peacekeeping force, the unmanned camera (184) After confirming winning for countries and individuals with a large number of acquisition points, While at the same time providing a maritime anti-piracy annihilation device that emits and exits in a specific area of the sea bass while changing one of the engine propeller 146 and the skewer 147, In addition to the construction of a pirate ship with docking vessels, diving into the water, or at the same time maintaining the close relationship between the fire and the disaster prevention materials, the communication equipment of the Internet control system before and after the fire, Pump electronic control unit, high performance submersible pump (36), air compressor (80), air storage tank and wire rope, multiple frames and mobile transport equipment Helicopter, connection structure including adverbalon and airship, Nuclear reactor plant (1) Inland hydroelectric power station Floating plant (593,594,595) Double structure block tank (598) double structure block tank bridge pier (928), nuclear waste treatment dual structure block tank pipe bridge (929), dual structure block tank pipe bridge (937) and nuclear waste treatment dual structure block tank marine tunnel traffic device ) It is divided into a number of distribution axes which distribute to the connection structure capable of disassembly coupling of the connection shaft and the distribution shaft and the distribution input device, and the dual structure block tank nuclear power plant facility and the nuclear power plant nuclear power plant are operated.

As shown in FIG. 4B, a reactor structure main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, The nuclear power plant facilities are equipped with the flood control process for the nuclear power plant facilities, and the fire-fighting and disaster control equipment is installed in the nuclear power plant facilities. Shaped nozzle 15 and a straight gap 15 are provided in the piping nozzle while a fire is generated when a fire occurs and a plurality of radiation curtain water films 39 and A plurality of linear straight-line curtain membrane members 39, and at the same time, a gas of death occurring in the event of a fire (163) , Which is composed of vertical and horizontal curtain walls that make up the world's uninhabited earth. Pump and valve connection structure of the electronic control unit is composed of fire, drought, typhoon, typhoon, flood, (685) as an electronic control pump fire fighting and disinfection device consisting of fire-fighting and disaster prevention control device in the global village along with the prevention of disasters such as droughts and landslides. At the same time, (593,594,595) Double structure block tank bridge pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank bridge bridge (929) and dual structure block tank bridge bridge (937) and nuclear (941) Multiple distribution shafts and distributing inputs to distribute to a disassemblyable connection structure of the connection shaft to provide the discharge Are separated by teeth are configured to be made double the building block tank nuclear power plant facilities and nuclear reactor plant operations.

Referring to FIG. 4C, the structure of the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention is transferred to the nuclear power plant 811, (811a) is a partial structural detail of the partial cross-sectional side view of the double-structure block tank connection part of the marine hydro-power plant floating tank, and a dual structure holding tank and a flood control unit to explain the overall construction of the marine nuclear hydroelectric power plant , Which is a decomposition and disassembly unit of a marine nuclear hydroelectric power plant, is shown as a block tank unit of a marine nuclear power hydroelectric power plant. Marine Nuclear Hydroelectric Power Plant Floating Plant Nuclear Hydroelectric Power Plant Sikdok configuration of the hull assembling the road,

As shown in FIG. 4C, a reactor structure of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant equipment and the nuclear reactor facility are inserted into the nuclear power plant facilities through both sides of the distribution shaft constituting the facility and the nuclear reactor facility and at the same time, The block tank hull disassembly and connection portable lug 607, which is provided in a horizontal and vertical type coupling structure at respective portions of the strut tank upper barge hull 591 and the strut tank lower barge hull 592, A horizontal block 616 having a chucking hole 615 and an elongated hole 616 for a block tank block unit hull breaker position shifting regulator Lock tank Hull disassembly Portable lug pin Vertical block tank with connecting shaft (606) and machining hole (615) Disassembly Portable lug pin Connecting shaft (606) and machining hole (615) The elongated hole 616 for the movement control device is provided so that the barge hull 591 at the upper end of each strut tank and the barge hull 592 at the lower end of the strut tank are connected to each other A plurality of lug pin connecting shafts 606 engaged with a plurality of processing holes 615 provided in the lug processing hole 615 are removed to remove the block tank hull disassembly and coupling lug pin connecting shaft 606, The double structure holding tank 598 is provided by the portable lug pin connecting shaft 606 having the lug pin connecting shaft 606 engaged to the distributing and inputting device of the sinking prevention stay line 634 of the sinking ship holding line, , While at the same time, The intake port 585a and the outlet port 585b of the block valve unit tank hull buoyancy adjusting butterfly valve 622 of the diving control device and the doctor ventilation 585 of the diving control device are connected to the block tank hull Hydraulic cylinder door (624) and stopper plate (625) for traffic control system Double structure piping line Automatic pneumatic valve transport device (916) and power motor control module for engine control (106) (590) to a vertical holding tank (590). At the same time, the nuclear power plant equipment is provided with preparations for submerging at the lower sea level (SLD), and at the same time, (593,594,595) Double structure block tank pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank pipe bridge (929) and dual structure block tank The bridge 937 is divided into a plurality of distribution shafts and distribution and dispensing apparatuses for distributing the waste water into a connection structure capable of disassembling and coupling the connection shaft of the nuclear waste disposal double structure block tank and the marine tunnel transportation apparatus 941, Nuclear power plants and nuclear reactors.

As shown in FIG. 4C, a reactor structure of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) (1) to the inside of the nuclear reactor facility main body (1) of the nuclear power plant, and to the distribution shaft of the regulating shaft through the both sides of the distribution shaft constituting the nuclear reactor facility and the nuclear reactor facility, The impeller 148 and the outer surface of the impeller 143 on the outer circumferential surface of the center of the rotating shaft 198 formed on the horizontal center line MBCL of the power motor electric motor body 192, A pump to which the guide vane 142 is not attached, a piston 127 to be attached to the rotary shaft 198, and a large- A main valve 265 on the side of the pump aberration 943a for providing a position below the large hydroelectric power generator 944 of the marine sheath hydroelectric power plant 943 provided with the power generator 944, A balance nozzle and turbine 267 in the aberration 943b are connected to the plunger pump 148 and the high pressure piston pump 127 by a propeller pump 146 and a viscous pump 343, A plurality of microcomputer type multi-stage pumps 8 configured with a number of motors motor body 192 detachable from the rotary shaft 198 in the casing 141 are installed inside the reactor facility body 1 of the nuclear power plant And the existing crude oil drilling rig is equipped with anchor hull fixation, but at the same time, it is different from working in the continental shelf area within 200m depth. At the reactor facility of the nuclear power plant, the hull fixation is replaced with anchor replacement crank 846) It is a remarkable difference from the previous anchor configuration of the hull.

Referring to FIG. 4D, the structure of the nuclear power plant 811 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention is transferred to the inside of the nuclear reactor main body 1, (913) and the pipe bridge (928) and the bridge bridge (937) showing the configuration of the position control mechanism of the hull of the marine nuclear hydroelectric power station floating structure (593,594,595) constituting the upper part (SDU) Nuclear waste disposal Marine tunnel Internal to the traffic device (941) Marine tunnel Transport device Internal train (771) Nuclear hydroelectric plant Construction Construction of the connecting structure of the road Construction of road,

As shown in FIG. 4D, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) (1) of the nuclear power plant (1) of the nuclear power plant (811) to the inside of the nuclear power plant main body (1) of the nuclear power plant at the same time as inserting the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility. Hull Location Movement The ship's pier (811c) of the construction machine shows the construction of the position control structure of the hull of the offshore hydroelectric power station (593,594,595) on the upper part of the ship's deck (SDU) 928) and the bridge bridge (937) to the inside of the marine tunnel traffic device (941). The marine tunnel traffic device internal train (771) (593, 594, 595) of the hydraulic power plant are equipped with a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, The vertical partition wall 605 and the pin linking shaft 606 for connecting to the portable lug 606 and the portable lug 607 are installed in the distributing and introducing devices of the nuclear power plant facility regulating machine provided with the hydraulic pressure switch 623 and the hydraulic cylinder door 624, And portable lug fins (608) and large flange connection joints Machining holes for joints (615) Drilling for crude oil into the construction machine connection structures and pipe bridge pier (928), pipe bridge (937) and marine tunnel traffic equipment (941) Nuclear waste treatment dual structure block tank on bridge 908 to bridge bridge 937 Internal marine tunnel transport device internal train 771 facility inside marine tunnel traffic device 941 The construction equipment connection structure At the same time, while providing decomposition bonds, (593,594,595) Double structure block tank pier (928) of double structure block tank (598) and nuclear waste treatment double structure block tank pipe bridge (929) and double structure block tank It is divided into a number of distribution axes for distributing the pipe bridge (937) and a connection structure capable of disassembling the connection shaft of the nuclear waste treatment double structure block tank (941) Tank nuclear power plants and nuclear reactors.

Referring to FIG. 4E, the hull position of the nuclear power plant 811 is transferred into the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention. (811a) of a hydro-electric power plant showing the disassembly and disassembly of a floating tank block unit of a hydro-electric power plant.

As shown in FIG. 4E, a reactor structure main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (590) facilities equipped with a buoyancy control tank and a connection structure are installed in the nuclear power plant equipments at the same time as the nuclear power plant equipments and the nuclear reactor facilities are inserted into the nuclear power plant equipments and the reactor equipments through both sides of the distribution shaft constituting the equipments and the reactor equipments, The inner block tank 596 provided with the block tank 598 and the tank mounting plate 593,594,595 for adjusting the buoyancy of the empty space of the outer block tank 599 are provided on the outer side portion provided outside the position, A nuclear waste disposal double structural block tank marine tunnel transport device 941 and a marine hydroelectric power station floating navigation barge hull facility equipped with a lug pin 606 and a lug pin 608, The holding tank 590 of the barge hull is freely folded and unfolded at the position of the sea surface as in the holding tank 590 of the barge hull by an equipments equivalent to a tabletop table provided with an operation of folding and unfolding the barrel hull, A butterfly valve 622 for controlling buoyancy and a solenoid valve 76 connected to the buoyancy adjusting tank of the barge hull are provided as the hydraulic cylinder 623 and the door 624 for the hydraulic cylinder, The opening of the buoyancy control butterfly valve 622 is opened while the operation of the on-time main switch button 66 of the main switch button 66 for the solenoid valve start switch button 66 is provided while simultaneously operating the inside of the nuclear plant installation and the reactor installation main body 1 (598,594,595) Dual structural block tank block (598) Double structure block tank pipe bridge (928) and nuclear waste treatment double structure block tank bridge (929) Dual structure (937) and a nuclear waste treatment dual structure block tank (941). The distribution shaft is divided into a plurality of distribution shafts and distributing input devices which are divided into a connection structure capable of disassembling and coupling the connection shaft, Structure block Tank Nuclear power plant facility and nuclear reactor facility are constructed to operate nuclear power plant.

As shown in FIG. 4E, a reactor structure main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, nuclear plant facilities are equipped with an upper tank barge hull (591), which is connected to each of the struts, which is not connected to the barge hull, to the nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the equipment and reactor facilities. The connecting shaft aft part of the tank 590 is provided with a connecting shaft aft part of each holding tank 590 having a positional shift control in a vertical state at the upper end of the sea surface in a state in which the positional movement adjustment in the vertical state is completed and the holding tank upper barge hull 591, (637), barge, tug (636) and lifting line (636), as well as a distributing and loading device connection structure (877) equipped with marine cranes and anti-erosion machine (877), and the installation and dismantling control device of the distributing and inputting device of the marine tunnel traffic device are put into the automatic manufacturing connection structure of the fixing and termination of the mooring device In addition, at the same time, it is necessary to set up the position control system of the distribution and input device of the construction machine and the marine tunnel traffic equipment to the nuclear power plant facilities, (593, 594, 595) distributing and inputting apparatus, while simultaneously holding a holding tank (590) of a barge hull of a coupled connecting structure on one side of a holding tank having a block tank-engaging portable lug (607) A holding tank 590 for providing a buoyancy adjusting device in the body of the hull is vertically and horizontally disposed at a constant angle of 0 to 350 degrees (593,594,595) equipped with a marine hydroelectric power plant, which is equipped with a holding block tank capable of adjusting the position of the hull, can be overcome in order to cope with natural disasters. At the same time, (593,594,595) Dual structure block tank (598) Double structure block tank bridge pier (928) Nuclear waste treatment Double structure block tank bridge (929) Double structure block tank bridge (937 ) And Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) Double-structured block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connecting shaft, And nuclear reactor nuclear power plants.

As shown in FIG. 4E, a reactor structure main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (591) of the marine hydroelectric power plant to the inside of the SDM of the hull deck (SDM) of the nuclear power plant at the same time, while inserting the nuclear power plant equipment and reactor facilities through both sides of the distribution shaft constituting the equipment and the reactor facilities. A plurality of internal block tanks 596 and a power transmitting portion 811d for transmitting hydraulic power to both the fore and aft ends of the inner block tanks 596, The guide rails 618 are installed to the left and right sides of the deck deck to the upper portion SDU of the hull of the barge hull 591. At the same time, And a sliding hatch cover 153 of double structure is provided at the safety position where the crane 861 provided with the hydraulic equipment refurbishment is provided at the same time. And a hydraulic cylinder 623 provided at one end of each of the control shafts and provided with a connection structure for adjusting the position of the hull with a hydraulic cylinder 623 to adjust the position of the control shaft, (593,594,595) Double structure block tank pier (928) of double structure block tank (598) and nuclear waste treatment double structure block tank pipe bridge (929) and double structure block tank (937) and a nuclear waste treatment dual structure block tank (941), a plurality of distribution shafts And distribution and dispensing devices, and it is structured to operate the dual structure block tank nuclear plant and nuclear reactor nuclear power plant.

As shown in FIG. 4E, a reactor structure main body 1 of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, At the same time, nuclear plant facilities are equipped with a barge hull (591) at the top of a dual structure holding tank and a lower structure at the bottom of a dual structure holding tank The lug 607 and the lug connecting shaft coupling bolt 603 and the lug connecting shaft 606 are connected to the disassembling and engaging portable lug connecting pin connecting shaft 606 of the block tank position shifting control device to the holding tank 590 by the barge hull 592. [ (593,594,595) of the marine hydroelectric power plant as a transportation transportation part (811c) of the construction machine for the floating cargo hull locating facility for adjusting the position of the respective adjustment shaft and the joint decomposition nut (604) The double structure block tank pipe bridge 928 of the structural block tank 598 and the double structure block tank pipe bridge 937 and the nuclear waste disposal marine tunnel transport device 941 are connected to each other by a disassembly- And a plurality of distribution shafts provided in the inner tank tanks (596) and connected to several inner block tanks (596) inside the SDM of the double structure barge hull (591) at the upper end of the holding tanks of the respective control shafts, (593,594,595) and a double structure block tank (598) composed of a hydroelectric power plant floating inside the reactor main body (1) of the nuclear reactor main body (1) and a dual structural block tank bridge bridge (928) Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) A small flood control console (593) that distributes the connection shaft to the disassembly-connectable connection structure to provide the discharge, and the disassembly- A double structure block tank 598 on the side surface of the stand 593 and a hull attachment separation portable lug 607 and a portable lug pin connection shaft 606 and a middle hull stand 594, The mating separating portable lug 607 and the portable lug pin connecting shafts 606 may be combined with a small floating picker 593 and a medium floating picker 594 combination with a hydraulic cylinder 623, A hull attachment / detachment portable rug 607 and a portable lug pin connecting shaft 606 for providing positions at respective positions of the side portions are provided with hydraulic cylinders 623, The coupling separation portable lug 607 and the portable lug pin connection shaft 606 are each provided with a damping and separating coupling by a hydraulic cylinder 623 while simultaneously assembling at the sea surface and simultaneously installing the nuclear power plant equipment and the inside of the reactor facility body 1 Offshore hydroelectric power plant (593,594,595) Dual structural block tank tank (598) Dual structure block tank pipe bridge (928) Nuclear waste treatment Double structure block tank pipe bridge (929) Double structure block tank pipe bridge (937) Block Tank Marine Tunnel Traffic System (941) Double-structure block tank divided into a number of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connection shaft and provide discharge. Nuclear power plants and nuclear reactors .

A buoyancy adjusting butterfly valve 622 having a buoyancy adjusting butterfly valve 622 and a solenoid valve 76 connected to the buoyancy regulating butterfly valve 622 is installed in the floating plant to the nuclear power plant, (66) operation of the main switch button for the start switch button of the solenoid valve (76) is provided so that the operation of the hydraulic cylinder (623) for opening the hydraulic cylinder 624 are opened so that the electrolytic water is filled in the empty space for controlling the diving. At the same time, the barge hull is gradually submerged into the water while the buoyancy is lost, and at the same time, the water in the stages 590 on both sides of the holding tank 590 equipped with the block tank- The lug coupling pin connection shafts 606 to one of the vertical processing holes at one side of the lug 607 in the vertical direction are connected to the hydraulic rotary cylinder 620 The door 624 for the hydraulic cylinder is fully closed while the connection is established by the operation of the pressure cylinder 623 and the positional movement is adjusted while the diving operation is proceeding so that the disassembly and coupling are performed in the sea in units of the floating hydro- The double structure block 598 of the marine hydroelectric power plant floating structure block tank 598 is installed at the nuclear power plant facility and the inside of the reactor facility main body 1 at the same time with disassembly and coupling with the lug hinge sockets 613 located at each portion of the nuclear power plant facility 590, It is possible to disassemble the connecting shaft of the tank pipe bridge 928, the nuclear waste treatment double structure block tank bridge 929, the double structure block tank bridge 937 and the nuclear waste disposal double structure block tank marine tunnel traffic apparatus 941 It is divided into a number of distribution axes which distribute to connection structure and discharge, and distribution dispensers, so that double structure block tank nuclear plant facility and nuclear reactor facility operation There is sex.

Referring to FIG. 4F, the hull position of the nuclear power plant 811 is transferred into the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention. (811a) is provided with a marine safety tool band guide device (621) at the upper part of a sea semi-submerging operation line for providing a welding connection assembly operation for each of double structure block tanks (598) of a marine hydro- A partial structure block tank 598 partially showing the double structure block tank 598 and the band guide 621 showing the side construction of the double structure block tank showing the welding preparation process, Nuclear power plant lifting equipment to show the structure of the hood assembly method Road,

As shown in FIG. 4F, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) At the same time, the nuclear power plant facilities are equipped with nuclear waste processing double structure block tank marine tunnel transportation equipment (for example, 941), and a marine safety tooling equipment band jig base (621) on the upper half of the sea bottom semi-submerging operation line for providing a welding operation for assembling the respective welding connections, The dual structure block tank 598, the detachable portable lug 607 and the portable lug pin connecting shaft 606, The welded joints are welded symmetrically with each other while the pin connection shaft 606 is connected to one side at the sea level, while at the same time the tool block band guide 621 is connected to the semi-diving work line 637 of the double structure block tank 598 to connect the large flange 614 of the connecting flange 614 at the connecting position in units of the double structure block tank 598 to the lever block 123 While the band guide 621 and the semi-submerging operation line 637 are welded to the double structure block tank 598 and the flange connection is performed by a welding machine, a bolt and a nut, (598) of the marine tunnel transportation device (941) of the marine hydroelectric power plant lifting plant can be welded and flange-coupled to each other, while at the same time, the nuclear power plant facility and the inside of the nuclear power plant main body Hydraulic feet (928), nuclear waste treatment double structure block tank bridge (929), double structure block tank bridge (937) and nuclear waste treatment dual structure block Tank marine tunnel traffic device (941) Double shaft block tank divided into a number of distribution shafts that distribute to the connection structure capable of disassembly and disassembly of the connection shaft, and the distribution input devices, Consists of.

As shown in FIG. 4F, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plants are installed in the nuclear power plant facilities and the nuclear reactor facilities through both sides of the distribution shaft constituting the facilities and the reactor facilities, The double structure block tank 598 of the marine tunnel traffic device 941 includes a block pylon 116 housing a plurality of emergency stairs 631 at the upper end of the flood control port The tackle winch 137 of the tie-rod winch 137 is provided with the block pylon tower 116 and the lug connecting shaft coupling bolt 603 is coupled to the unit block pylon tower connection hole processing hole 615 The block staple block 116 is constituted while the blocks are connected to each other by the lug connection shaft coupling nut 604 while the emergency stairs 631 are installed around the upper end of the block stiffener 116, Is provided with a crane 861 for carrying a pipe rack and an elevator 632 to the lower center of the lower end portion of the airship lane and an elevator 632 installed at the upper end portion of the mooring tower 644, The buoyancy control marine tunnel transportation device 941 constructed inside the nuclear reactor plant main body 1 of the nuclear power plant which is capable of protecting the safety of the object while dispersing the load of the marine tunnel transportation device 941 to the position of 40M below the sea level SLL (593,594,595) double structure block tank (598) inside the main body (1) of the nuclear power plant and the inside of the reactor main body (1) (928), Nuclear Waste Treatment Double Structure Block Tank Bridge (929), Double Structure Block Tank Bridge (937) and Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) The system consists of a number of distribution shafts that distribute to a possible connection structure and discharge, and a distribution input device, which is used to operate the dual structure block tank nuclear plant and nuclear reactor nuclear power plant.

As shown in FIG. 4F, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) In addition, at the same time, the nuclear power plant equipment is provided with a connection structure of the nuclear reactor main body of the nuclear power plant, and a distribution input device for the operation of the construction machine is installed in the nuclear power plant equipment. A connection structure of the marine tunnel traffic device 941 to the submarine mineral resource network 941 for providing buoyancy control, The manganese nodules (909) of the connecting structure of the diving position-controlling moving device of the barge hull by replacing the simple structure (909) (SDU) at the top of the ship's upper deck (SDU) at the same time, while at the same time arranging the buoyancy control connection structure at the same time, The crane boom is connected with the crane boom level level maintenance weight (107), and it has the connection structure with the mooring system, and it is the connecting structure that continuously produces the hydroelectric power by the power generation facilities. (811b) is installed in the reactor main body (1) of the nuclear power plant as a transportation transport part (811c) of the construction machine of the floating hood and hull locomotion facility so as to control the power generation of the nuclear power plant. As the connection structure of the reactor facility main body, the distribution input device of the submarine mineral manganese nodule (909) A plurality of hatch covers 153 provided on the outer bulkhead of each body of the body 592, and a connection structure having a connection structure to the dual structure pipeline line automatic pneumatic conveying device 916. The diving control of the pipeline And the main switch button 66 for the solenoid valve start switch button is connected to the solenoid valve pressure switch of the connection structure solenoid valve 76 while the connection structure with the butterfly valve 622 for controlling the buoyancy of the control device is provided. A power transmission control unit 811d for transmitting the power constituting control of the power generation of the nuclear power plant to the inside of the reactor main body 1 of the nuclear power plant having the connection structure provided with the connection structure, (593,594,595) Dual structure block tank (598) Double structure of the hydroelectric power station (593,594,595) inside the plant (1) It is possible to disassemble the connecting shaft of the tank pipe bridge 928, the nuclear waste treatment double structure block tank bridge 929, the double structure block tank bridge 937 and the nuclear waste disposal double structure block tank marine tunnel traffic apparatus 941 It is divided into a number of distribution shafts that distribute to the connection structure and provide the discharge, and the distributing and inputting devices are constructed to operate the dual structure block tank nuclear plant and nuclear reactor nuclear power plant.

Referring to FIG. 4G, a reactor structure (1) of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste according to the present invention is installed inside a nuclear power plant (672) of a marine power plant (593,594,595) Nuclear Reactor Facilities (1) Nuclear power plant facilities for operation (811a) Nuclear power plant nuclear waste disposal unit (811a) (598), which is a connection assembly, is installed in the reactor main body (1) of a nuclear power plant with a sail (959), a tug (636) (636), which can be used as a substitute for sails (959) and tugboats (636), to provide a tugboat (640) The double structure block tank (598) of 500m unit of one side of the bridge block tank bridge (929) is connected to the sea surface by the coupling work process. 929) is a double structure block tank 598, a partially detailed double structure block tank 598, a nuclear waste treatment dual structure block tank bridge 929, Connection of the nuclear power plant Lifting stand Construction of hull assembly method Road,

As shown in FIG. 4G, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, In addition, at the same time, the nuclear power plant facilities are provided with a plurality of towers for raft line disassembly and disassembly when equipped with tugboats at the time of long distance transportation of the pipe bridge, while inserting into the nuclear power plant facilities and reactor facilities through both sides of the distribution shaft constituting the equipment and reactor facilities. Tube bridge Block tank Disassembly and transporting Transformation method 500m unit Block tank installation Wiring method Wiring method Nuclear waste treatment provided by crank shaft Double structure Block tank pipe bridge (929) Connected nuclear power plant Lifting consoles The top of the holding tank upper barge hull (59) formed before and after the shared water surface treatment process inside reactor body (1) of nuclear power plant 1) a plurality of strut tanks 590 formed at the outer side of the central area stepped strut holding tank 590 and the strut tank lower barge hull 592, a strut tank upper barge hull 591, The block tank hull disassembly-type portable lug 607 formed in the lug pin connecting and dismounting portable lug 607 is provided with a lug pin connecting shaft 606 and a lug connecting shaft coupling bolt, a thread-and-lug connecting shaft coupling and dismounting nut and a portable lug pin connecting shaft 606, 608 of the portable lug 607. The processing hole 615 and the long hole 616 formed in the portable lug 607 function as a horizontal vertical building structure, At the same time, the nuclear power plant equipment is provided with sub-style docks 998 to prevent sinking, and each of the vertical holding tanks 590 (see FIG. 5) along outer circumferential surface of the inner circumferential holding tanks of the upper barge hull 590 ) In the lower part of the core, a borehole excavation is provided with a core drill 917 formed in a number of pipe racks 854 formed on the undersurface ground surface GLD by excavation equipment and mooring devices, and at the same time, anchor replacement crankshaft 846 Is connected to the hydraulic cylinder 620 and the hydraulic cylinder key bed 623 and is provided with a connection structure of a construction machine 970 mounted on the barge at the upper end of the column of each of the holding tanks, The wrench crank 846 is pushed into the core drilling hole through the hydraulic cylinder 620 by pushing the wrench crank 846 while the wrench crank 846 is inserted into the drilling hole The compressed air inflated to form a barbed wire hull drift prevention by fixing the lower end portions of the respective holding tanks by providing a fixture to the ground in which the tool chain shredder (185)At the same time, the marine tunnel traffic devices formed in the floodplain are provided in a shared landfill 944 and a shared water surface landfill 945 which are secured by mooring devices, and at the same time, the nuclear power plant facility and the reactor facility main body 1 (593,594,595) Dual structure block tank (598) Double structure block tank bridge pier (928) Nuclear waste treatment Double structure block tank bridge (929) Double structure block tank bridge (937 ) And Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) Double-structured block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connecting shaft, And nuclear reactor nuclear power plants.

Referring to FIG. 4H, the hull position of the nuclear power plant 811 is transferred into the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) showing the arrangement of the position adjustment mechanism of the hull of the marine hydroelectric power plant floating structure (593,594,595) constituting the upper part of the ship's deck hull (811a) And a large flange connection to the portable lug 607 and a portable lug pin 608 on the pin connection shaft 606 for joining the portable lug. Processing hole 615 of the joint part of the hydraulic lug 607 and the portable lug pin 608.

As shown in FIG. 4H, a reactor structure main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste, an internal nuclear power generation facility 811, a nuclear power plant nuclear waste disposal unit 811a, (1) of the nuclear power plant (1) of the nuclear power plant (811) to the inside of the nuclear power plant main body (1) of the nuclear power plant at the same time as inserting the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility. Nuclear Waste Treatment Department of Nuclear Power Plant (811a) Marine Dock Body Dock Marine diesel power plant floating structure (593,594,595) constructed on the upper deck part (593,594,595) The vertical partition wall 605 and the pin connecting shaft 606 for connecting the portable lug 604 and the portable lug 607 and the large lug 608, And the marine hydro-power station floating dishes 593, 594 and 595 are provided with a hydraulic rotary cylinder 620 of a rack and pinion type (NRP) which is a rotary cylinder, The vertical partition wall 605 and the vertical partition wall 602 are provided with the butterfly valve 622 for controlling the buoyancy of the turbine 621 and the distributing and introducing devices of the nuclear power plant regulating machine provided with the hydraulic cylinder or the hydraulic oil presser 623 for the hydraulic cylinder door 624, A portable lug coupling pin coupling shaft 606, a portable lug 607, a portable lug pin 608, a large flange connection connector joint portion machining hole 615, and a hydraulic power plant construction machine coupling structure, (593,594,595) Double structural block tank block (598) Dual structure block tank pipe bridge (928) and nuclear waste treatment double structure block tank bridge (929) Nuclear power plant equipment and nuclear reactor facility (1) And dual structure block Tang (937) and the nuclear waste treatment double structure block tank (941). The distribution shaft is divided into a plurality of distribution axes and distribution input devices which are divided into a connection structure capable of disassembling and coupling the connection shaft, Block Tank Nuclear Power Plant Facilities and Nuclear Reactor Facilities.

Referring to FIG. 4I, a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention is installed in a nuclear reactor main body 1, 811c to the concrete bocking plant 865 and the concrete finisher 866 showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power station floodplain 593,594,595 constituting the upper part of the marine power plant dock hull deck (SDU) Mixer trolleys (868) Construction machinery Construction of connecting structures Construction of roads,

As shown in FIG. 4I, the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the internal nuclear power generation facility 811, the nuclear power nuclear waste treatment unit 811a, (811c) of the nuclear power plant is installed in the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the nuclear power plant facility and the nuclear power plant facility. At the same time, A concrete bocking plant 865 and a concrete finisher 866 showing a construction machine position control arrangement of a hull locomotion control of a marine hydroelectric power plant flood control station 593,594,595 constituting the upper part of a marine power plant dock hull deck (SDU) Concrete mixer trucks (868) and construction machinery linkage structures Nuclear power plant equipment Regulating machinery distributing equipment Concrete packing machines Is divided into a concrete batching plant 865, a concrete mixer, a concrete mixer truck 868, a concrete pump 869, a concrete finisher 866, and a concrete spreader 867, and at the same time a concrete manufacturing machine concrete batching plant 865 ) The equipment is equipped with an aggregate storage / passage improving device and a mixing device, and has a prime mover. It is a device that manufactures and produces concrete with a predetermined blending ratio of each material. The type is a trolley type and a loading type middle type. (Ton / hr).

As shown in FIG. 4I, a reactor structure of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) It is necessary to insert both nuclear power plants and reactor facilities through both sides of the distribution shaft that make up the equipment and reactor facilities, and at the same time to mix the sand, gravel, cement and water in the concrete mixer to the nuclear power plant facilities The dryness type is a system that weighs cement and aggregate, mixes water while driving, transports it to the destination site, and drives it by mixing with hydraulic pressure. Wetness type is also referred to as "agitator" in which a fully mixed raw concrete mixture is transported with agitation, and the standard mark is expressed as the amount of concrete that can be mixed once (m ³ ).

As shown in FIG. 4i, the nuclear reactor facility main body (1) of the nuclear power plant, the nuclear power generation facility (811) of the nuclear power plant, the hull position moving nuclear power generation nuclear waste processing unit (811a) of the nuclear power plant, and the nuclear power plant equipment constituting the nuclear reactor facility , The concrete batching plant 865 constituting the adjustment of the construction machine position of the hull locomotion control of the marine hydroelectric power plant flood control consoles 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) The overall belt conveyor 865h and the turn head 865i are attached to the adjustment plate 865c and the balance plate 865d on the apparatus charging chart 865b and the symmetric hopper 865e and the scale frame 865f and the storage bin 865g, 595 and 595 to the elevator 865j and the conveying cement Chad 865k with the cement silo 865o and the scour conveyor 865p to the adjusting plate 865l and the recording device 865m and the circular mixer 865n, Move the hull position of (593,594,595) double structure block tank (598) double structure block tank pipe bridge (1) of nuclear power plant equipment and nuclear reactor facility inside (1) 928), the nuclear waste treatment double structure block tank bridge 929, the double structure block tank bridge 937 and the nuclear waste disposal double structure block tank marine tunnel traffic apparatus 941, The reactor is divided into a number of distribution shafts and discharge devices for discharging, and the dual structure block tank nuclear power plant facility and the nuclear reactor nuclear power plant are operated.

As shown in FIG. 4i, the concrete pump (869) facility is convenient for conveying concrete in a limited space such as a bridge in a tunnel and a building. The pump is a mechanical type and a hydraulic type. There is no special limitation, and it is a combination of hydraulic or hydraulic system, it is less shock or vibration, easy to handle, easy to repair and economical, and is provided for transportation of high - rise building and long - distance concrete.

As shown in FIG. 4I, the concrete pump 869 is movable and mechanically driven by hydraulic pressure and truck mounted, and the diaphragm type is used for a high-rise building (100 m or more). The standard display is expressed in terms of the delivery capacity per hour (m ³ / hr) The components of the piston-type concrete pump consist of a concrete injection hopper, suction and discharge valves, pistons, and cylinders.

As shown in FIG. 4I, the concrete pouring machine is a concrete finisher 866. The concrete pouring machine includes a concrete pouring machine, a concrete pouring machine, and a finishing machine. The pouring machine includes a concrete pouring machine. Finish the concrete slab surface while moving in the transverse direction.

As shown in FIG. 4I, the use of the machine is that the load on each part of the machine is small, the structure is simple, and the machine wear and noise are small, so that the concrete finisher finishes the surface of the package while vibrating the front and back of the surface. The standard marking is expressed by the standard width (m) that can be applied, while the disassembled assembly is provided inside the nuclear reactor facility main body 1 of the nuclear power plant, and the nuclear power plant facility and the reactor facility main body 1, (593,594,595) Double structure block tank pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank pipe bridge (929) and double structure block tank pipe bridge (937) And nuclear waste treatment double structure block tank Marine tunnel transport equipment (941) Multiple distribution axes and distribution bases to distribute to disassembly connection structure of connection shaft and to provide discharge Separated by a double structure of a block tank nuclear power plant facilities, nuclear reactor equipment consists of a movable be achieved.

Referring to FIG. 4J, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed in a nuclear reactor main body 1, The asphalt finishing machine 871 and the asphalt finishing machine 871 are attached to the hearth safety device 864 showing the configuration of the construction machine position adjustment control of the hull position movement of the marine hydroelectric power plant flood control stand 593,594,595 constituting the upper part SDU of the marine power plant dock, The strainer 876 of the boom 882a and the diesel pile hammers 883 of the construction machine connection structure on the pile driver 876 and the pile driver 882 on the spreader 872,

As shown in FIG. 4J, the inside of the reactor installation main body 1 of the nuclear power plant is connected to the upper portion (SDU) of the hull deck of the marine power plant body by the transportation transport portion 811c of the hull position moving construction machine of the nuclear power generation facility portion 811 The asphalt finisher 871, the asphalt spreader 872, the perforator 876, and the pile driver 876, which show the construction machine position adjustment structure of the hull locomotion control of the constituent marine hydroelectric power station floodplain 593, 594, 882), a boom (882a) and a diesel pile hammer (883). The asphalt mixing plant (870) has an aggregate feeder, a drying heater and a mixer asphalt feeder. It is a machine and its equipment for manufacturing asphalt mixture used in airport, port construction as well as road pavement construction, and the exhaust dust collecting device is a device for collecting water vapor, dust, The centrifugal separator is cleaned using dust generated from the asphalt or vibration screen. The specification mark is expressed by the hourly output (ton / hr) of the asphalt mixture (ascon).

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The concrete spreader 867 is installed in the nuclear power plant equipments, and the equipment of the concrete spreader 867 is installed in the nuclear power plant equipment and the nuclear reactor facility through the both sides of the distribution shaft constituted by the transportation conveying unit 811c of the concrete conveying unit 811c. , The application is to convey concrete from a truck mixer or dump truck while it is running in front of a concrete finisher, and to transport, lay up and lay down the machine. The standard marking is indicated by the standard width (m) The blades are classified into a screw type and a box type, and at the same time, asphalt packing machines are classified as asphalt mixing plant 870 and ah The asbestos sprayer 871 and the asphalt sprayer 872 and the asphalt cover and the asphalt spray while simultaneously separating the inside of the reactor main body 1 of the nuclear power plant into the nuclear power generation facility 811 and the nuclear waste disposal unit 811a, It is composed of construction machinery of the hull position movement control of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part (SDU) of the ship body dock hull deck (811c) of the construction machinery.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And the transportation conveying portion 811c of the nuclear power plant, and at the same time, in the nuclear power plant facilities, the weighing and mixing methods of the nuclear power plant facilities are formed by the batch type and the continuous type The method of installation is fixed type. The operation method is manual type in electromagnetic and semi-automatic type, and the application is asphalt heating in combination with drying of aggregate and asphalt. The composition is as follows. It consists of a screen, a mixer and a weighing device on the asphalt cake.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, (871) of the nuclear power plant is provided with a sorting device and a finishing device. The asphalt finishing device (871) is installed in the nuclear power plant equipment and the nuclear reactor facility through both sides of the distribution shaft Asphalt Mixing Plant boils over 160 ° of gravel sand to spread the aggregate on the road to a certain standard thickness. It is used in asphalt pavement, asphalt pavement, highway and asphalt pavement of airfield runway and highway. (M / s) and packing capacity (ton / hr), and in the mechanism of the asphalt finisher 871, The living hopper is a container for storing the mixed material (asphalt) carried by the dump truck with a hopper of more than 5 tons installed on the front of the equipment, and the feeder is installed on the bottom of the hopper, To the spreading screw, and the bumper is installed on the front of the screed to increase the packing surface to the thickness required for the mixed material sprayed on the road surface.

As shown in FIG. 4J, equipment for asphalt spreader (872) is an apparatus for boiling asphalt and sprinkling it on the road surface for the first time. In other words, it is a sprayer that blows asphalt on the road surface. The type is self-propelled, gear pump type, solution pressurized type and mounted type, and the specification mark is expressed by maximum spraying width (m) and tank capacity (m ³ ).

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The asphalt cover is used as a construction equipment for continuously covering the asphalt mixture material for the highway, and the asphalt cover is installed in the nuclear power plant equipment and the nuclear reactor facility at the same time. Also, asphalt spray is a device to heat and dissolve asphalt, asphalt emulsion and tar by oil burner, and pressurize and spray it on the road surface. On the roadside stabilizer, surface leveling, by tightening equipment to the guthim to a standard display is displayed in a dose of the fluid tank (m ³⁾ It said ergonomics is well characterized and it was excellent maneuverability and better efficiency of the player shows that it's easy to adjust the depth digging.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, (811c), and the nuclear plant is installed in the nuclear power plant equipment and the nuclear reactor facility. At the same time, the nuclear power plant equipment is classified into the diesel file The hammer 883 is a machine that uses the explosion power of a two-cycle diesel engine to drive the machine twice as fast as a vibration hammer and a steam hammer of the same size. When the ram is raised and lowered by the starter, The fuel is injected into the concave surface of the anvil, and the ram explodes at the moment when the ram hits the anvil, so that the explosive force and the striking force of the ram The pile is transferred to the pile and the ram is repelled by the repulsive force. At this time, the pile is exhausted and sucked, and the pile is repeatedly subjected to the drop, the impact and the explosion. The ram and the anvil inserted in the lower part of the cylinder consist of the fuel pump and the fuel injector start devices, which constitute water tank devices for cooling the cylinders.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The diesel pile hammer 883 is inserted into the lead 896 at the left side of the body of the diesel pile hammer 883, and at the same time, A fuel pump 900 is installed at a lower portion of the cam 901 in the ram 895 and the fuel tank 902 to the lower right side of the cylinder 126, A helmet 899 is formed below the pump 900 and a pile 899 is attached to the lower surface of the heel 899 to advance pile operation.

As shown in FIG. 4J, its standard marking is indicated by the weight of the ram (ton), which is used to stamp wood, concrete, and steel pipe files, and its characteristics are shown in the table below

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The present invention is not limited thereto. For example, in the case of a nuclear power plant installation, the outline of the column hammer (= column file hammer) Or compressed air to continuously move up and down the piston to continuously pile up the ram at the bottom of the piston rod. The type of column hammer is steam hammer. The outline of this is to use steam expansion energy It is a machine that operates by operating the piston. The specification mark is indicated by the piston weight (ton). Due to this feature, the structure is complicated, maintenance and maintenance are difficult It is used for putting piles in hard and denser soil. It is guided to a lead and has a single acting type and a double acting type. The outline of the vibration hammer is the hammering or pulling operation by the vibration power, and the frequency is more than 500 times per minute. The specification mark is expressed by the output of the motor (kW) and the excitation force, and the drop hammer is the metal block by the wire Was to drop the file onto the head of the file and put the file with its striking power. It was suitable when the equipment cost and operation cost were to be reduced in the case of a small amount of construction in the remote place among the basic use machines.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And the transportation conveying portion 811c of the nuclear power plant and the nuclear power plant, and at the same time, the first advantage of the nuclear power plant is that it is easy to operate and operate the hammer, And it was possible to increase the energy of the blow by adjustment of the drop height.

As shown in FIG. 4J, the second problem was that the piling of the pile was slow, and there was a danger of damaging the file, and it was easy to damage the surrounding buildings due to the vibration at the time of work. .

4j, on the upper portion of the lead 896 of the body of the file driver 882, the adapter 906, the wire rope 19 to the boom front pin 904, and the crane boom 651 And a CAD work 905 on the front of the crane was attached. The file driver 882 mounts the deck deck on the upper deck deck of the barge hull 591 and fixes the deck deck operation position to the file 898

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And a transportation conveying portion 811c of the main body 811. The nuclear power plant equipments include a steam hammer in a diesel hammer and a drop hammer in a vibration hammer When you put the file, you use the drop hammer or diesel hammer and install the work device on the crane boom.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The pile 898 is fixed to the lower base post portion of the deep sea bed at the same time as the nuclear power plant equipment is inserted into the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituted by the transportation transportation portion 811c The concrete bridge pillar can be easily installed on the bottom of the seabed with the saddle form frame 617 for the bridge pier.

As shown in FIG. 4J, the construction machine air compressor 875 sucks air in the air to make compressed air, which is used for various purposes in various construction work by making it into a high pressure state. Equipment and other accessories. Here, the drive device is a gasoline or diesel engine that supplies the power for operating the compressor. In addition, it was said that the volumetric type compressor was mainly used for the construction work. For this purpose, the quarrying work was to drill and split the rock by using the rock drill, and the clay excavation work was carried out by using hard rock solid rock Is to excavate with an excavator or excavator, and the destruction work is to destroy concrete and asphalt with brake.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And the transportation transportation portion 811c of the nuclear power plant, and at the same time, the nuclear power plant equipment is provided with the painting work for the concrete vibration work and the cutting work, the tire air infusion Equipment cleaning and construction air compressors are large.

As shown in Fig. 4J, the compressors of this type are classified and classified into a reciprocating piston type vane type compressor and a rotor type compressor by a screw type compressor and a centrifugal turbo type compressor. It is used mainly for large-scale construction while being fixed, and it is possible to use the compressor while moving the compressor easily.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The air cleaner low-pressure cylinder intermediate cooler high-pressure cylinder air tank is provided with the inserts of the atomic power plant equipment and the nuclear reactor equipment at both sides of the distribution shaft constituting the transportation transportation unit 811c of the air cleaner low- The amount of air discharged per cubic meter (m ³ / min). In other words, 210 cfm is expressed as 210 cubic feet of compressed air per minute (ft ³ / min), and the parts of the air compressor consist of piston, cylinder, and pressure regulating valve for intake and exhaust valves.

As shown in FIG. 4J, functions (roles) of the main parts thereof are described as the following table.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, The puncturer 876 equivalent to a rock drill is described in detail in the following description of the nuclear power plant equipments as follows. do.

The puncturer 876 is a machine for punching a rock or a ground, and is operated by an air compressor or hydraulic pressure. The impact type is excavated by the impact energy of the blade, and the excavation speed is fast but its depth is low.

Most of the compressed air is used, and the impact rod is operated by this compressed air. The rock is crushed by the impact force. The structure is simple, easy to handle, Is excavated by a rotating blade in the hole, and the excavation speed is slow or deep.

The crawler type shows the weight of the rock drill and the air consumption per minute (m ³ / min). The crawler jumbo type is represented by the number of the prestrol rolls and the number of rock drills (end) The tunnel excavator is indicated by the maximum excavation dimension (mm).

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And the transportation conveying portion 811c of the nuclear power plant, and at the same time, in the nuclear power plant facilities, the sinker is the latest type of rock drilling machine having the soundproofing device, It is suitable for hole drilling, swelling cuts of various kinds, and downward work of tunnel. In other words, it is a small-sized machine that can be operated by manpower, and operates by the force of air.

It is a powerful perforator that is suitable for punching large holes in excavation work, quarrying work and dam excavation. By means of a manual or automatic feeder, the drill is drilled with a bit of suitable pressure on the bit, which is chain and screw type, and the stopper is a machine punching from the horizontal to the sky and is suitable for vertical excavation

And the breaker is used for crushing the concrete road, for the destruction of the building and the strong foundation, and it has a strong crushing power with low consumption of air. It is mainly used for hydraulic backhoe excavators. Rock crackers are used to crush rocks and concrete by hydraulic pressure in places where gunpowder can not be used.

Thus, the hand hammer is effective for narrowing work and secondary crushing work, and it is easy to use because it is sound proofed. It is also called a jack hammer. It is a small type of rock drill that can be moved and manipulated by manpower. It is mainly used to drill holes downward.

As shown in FIG. 4J, the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste, the nuclear reactor main body 811 of the nuclear reactor, the nuclear waste disposal unit 811a of the nuclear reactor, And a transportation conveying portion 811c of the main body 811c to be inserted into the nuclear power plant equipment and the nuclear reactor equipment. At the same time, the nuclear power plant equipment includes the rag drill, the boring machine and the crawler drill, The pick hammer is installed in the main body (1) of the distribution control device of the flood control machine, the hull position of the flood control part (811) is controlled by the construction machine control part (811a), the marine power plant body dock, The asphalt finisher 871 and the asphalt spreader 872 are provided with a perforator 876 and a wave breaker 874 on a hearth safety device 864 showing a construction machine position adjustment arrangement of the hood locomotion of readings 593, The boom 882a and the diesel pile hammers 883 are connected to the driver 882 by a plurality of construction machine connection structures inside the dispensing and inputting apparatus main body 1 of the flood control machine, (811a) Marine Dock Body Dock Consists of distribution dispensers of construction machines connected to the upper deck (SDU) of the hull deck.

Referring to FIG. 4K, a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention is installed in a nuclear reactor main body 1, 811c to the pump dredger 879a of the dredger 879 and the bucket dredger 879a of the dredger 879 which shows the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power station floodplain (593,594,595) 879b) Straight configuration of construction machinery connection structure Road,

As shown in FIG. 4K, the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the internal nuclear power generation facility 811, the nuclear power nuclear waste treatment unit 811a, The nuclear plant installation is provided with a hull position of the flood control section 811 inside the main body 1 and a hull position of the flood control section 811. [ Construction of hull position control of marine hydroelectric power station floating structure (593,594,595) in the upper part (SDU) of the hull deck body of the marine power plant by the moving construction machinery control part (811a) and the transportation part (811c) The construction of the pump dredger 879a of the dredger 879 and the bucket dredger 879b of the construction machine connecting structure showing the machine position adjustment configuration is shown in Fig. The dredger 879 constituting the upper part SDU of the marine power plant body dock is connected to the pump dredger 879a and the bucket dredger 879b while being separated from the dredger 879. At the same time, A blast tank 879g is attached to the red shear 879e and the spot 879f and a red 879i and an engine room 879j are attached to the turbine 879c and the cab or the adjustment chamber 879d. At the same time, the deeper dredger 879k and the grab dredger 879l connect the left and right front spots 879q to the spot winch 879o and the bucket 879p to the bucket driving device 879m and the rear spot 879n, A belt conveyor 879u and a gravure 879v are attached to a winch 879s and an anchor storage 879t on the dipper 879r and a plurality of construction machine connecting structures are installed inside the dispensing and inputting apparatus main body 1 of the flood control machine (811a) of the off-shore control unit (811), and the control unit (811a) of the off-shore control unit (811) A wire rope chain 915 and a double wire rod 915 are attached to the periscope 913 and the rubber balloon 914 in the underwater minerals collecting machine 911 and the undersea mining collecting robot 912 on the reeling machine 908 and the undersea netting net 910. [ Structural pipeline line Automatic pneumatic valve transport system (916) and core drill (917) Distribution machine of construction machine Construction machine connection structures constitute submarine mineral manganese nodule (909) collection.

As shown in FIG. 4K, the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the internal nuclear power generation facility 811, the nuclear power nuclear waste treatment unit 811a, And the transportation conveying portion 811c of the main conveyor 811c to insert the nuclear power plant equipment and the nuclear reactor facilities at the same time. At the same time, the conventional dredgers are equipment for digging the soil in the water Ports in the port construction. Fermentation. River. In order to increase the depth of waterway and to maintain water depth, we work on the filling of the shared water surface and the foundation work of the coastal work such as rock wall and breakwater. Classification of the dredger is classified by classification by type and ability. , Pump type is non-magnetic type with rated output of drive engine, and bucket type is non-magnetic type with rated output of main engine. It is non-magnetic type with deeper bucket capacity (m ³ ) ³ ).

As shown in FIG. 4K, the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the internal nuclear power generation facility 811, the nuclear power nuclear waste treatment unit 811a, And the transportation conveying portion 811c of the nuclear power plant, and at the same time, the nuclear power plant equipment is provided with an electric and diesel type steam turbine type and gas The structure and purpose of the pump dredger (879a) for the structure and use of the dredger is divided into a turbine type and the structure and use of the dredger is to transport the soil to the treadmill by using the low head pump line when the delivery pipe is difficult to install or the delivery distance is long. It is used to dredge the harbor or to fill in the land. The angle of movement of the hull is 90 ° to 70 °, Remote display is shown with a rated output (PS) of the driving engine to the characteristics thereof are shown in the table below.

As shown in FIG. 4K, the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste, the internal nuclear power generation facility 811, the nuclear power nuclear waste treatment unit 811a, The construction and use of the bucket dredging line 879b in the nuclear power plant equipments is such that the buoyant dredging of the seabed is carried out in the bucket of the bucket dredger 879b, The dredged soil is transported by a toe line and used for the dredging of large-scale passageways and anchorage. The types are continuous and intermittent. The continuous type is used. (PS) and the characteristics of the dredger (879b) are shown in the table below.

As shown in FIG. 4K, the structure and use of the deeper dredger 879c are used for dredging a rock or a hard rock having a strong excavation force. The standard indication is indicated by the bucket capacity (m ³ ) As shown in Fig.

As described above, the seabed mineral manganese nodule 909 is collected,

(1) Internal Nuclear Power Plant (811) Nuclear Power Plant Nuclear Waste Treatment Unit (811a) and Hull Location Moving Construction Machinery (1) Nuclear Power Plant The nuclear power plant equipment and the nuclear reactor facility are inserted into the nuclear reactor facility main body 1 of the nuclear power plant through the both sides of the distribution shaft constituted by the transportation transportation unit 811c, (908) connected to the upper portion (SDU) of the body of the marine power plant dock by the hull position moving construction machinery control portion (811a) of the hull position moving construction machine and the transportation transportation portion (811c) A wire rope chain 915 and a double structure pipeline line 916 are connected to the periscope 913 and the rubber balloon 914 in the mineral deposit netting machine 910 and the submarine mineral-extracting robot 912, The pneumatic valve transport system (916) and the core drill (917) distribution system of the construction machine construction machine connection structures are to constitute submarine mineral manganese nodule (909) collection.

Referring to FIG. 4L, a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, 811c) of the marine power station dock (SDU) on the upper part of the ship's hull deck (593,594,595). ,

As shown in FIG. 4L, a reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, an internal nuclear power generation facility 811, a nuclear power generation nuclear waste treatment section 811a, The construction and use of the grab dredger 879d is provided to the nuclear power plant equipment and the nuclear reactor facility through the both sides of the distribution shaft constituted by the transportation conveyance unit 811c of the grab, This equipment is used to dredge small ships or anchorage by using a special crane equipped with a shell. The standard marking is indicated by the grab bucket flat capacity (m ³ ), and its characteristics are shown in the table below.

As shown in FIG. 4L, a reactor structure of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant equipment is provided with a hull position shifting construction machine (not shown) of the flood control section 811 inside the main body 1, and at the same time, (879l) construction machine showing the arrangement of the position control of the construction machine of the marine hydroelectric power plant floating cargo ship (593,594,595) constituting the upper part (SDU) of the ship body dock of the marine power plant with the transportation transportation part (811c) The construction and use of the grab dredging line (879d) on the connection structure is such that the clam shell on the ship is installed and dredged by a special crane It is used for the dredging of a small-scale passage or anchorage, and the standard mark is indicated by the grab bucket flat capacity (m ³ ).

As shown in FIG. 4L, a reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, an internal nuclear power generation facility 811, a nuclear power generation nuclear waste treatment section 811a, And the transporting portion 811c of the submarine mineral manganese nuclide 909 is inserted through the both sides of the distribution shaft and inserted into the nuclear power plant facility and the nuclear reactor facility. At the same time,

A plurality of construction machine connection structures are installed inside the dispensing and inputting apparatus main body 1 of the flood control machine to control the hull position moving construction machine control unit 811a of the flood control unit 811 to the upper part SDU of the body of the marine power plant deck A wire rope chain (hereinafter referred to as a &quot; wire rope chain &quot;) is attached to the periscope 913 and the rubber balloon 914 in the submarine mineral intake collecting machine 911 and the submarine mineral collection robot 912 to the connected crude oil drilling machine 908 and the seabed mineral deposit net 910 915) and dual structure pipeline automatic pneumatic valve transport system (916) and core drill (917) construction machine distribution system to construct submarine mineral manganese nodule (909).

As shown in FIG. 4L, a reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, an internal nuclear power generation facility 811, a nuclear power generation nuclear waste treatment section 811a, The nuclear power plant equipment and the nuclear reactor facility are inserted through both sides of the distribution shaft constituting the nuclear power plant facility and the nuclear reactor facility by the transportation transportation unit 811c of the nuclear power plant equipment and the gravity dredging line 879d ) Is the equipment for dredging by a special crane equipped with a clamshell on the ship and used for the dredging of a small-scale lane or anchorage. The standard marking is indicated by the flat bucket capacity (m ³ ) As shown in the table below.

As shown in FIG. 4L, a reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment, an internal nuclear power generation facility 811, a nuclear power generation nuclear waste treatment section 811a, (811c) of the reactor main body (811c) to be inserted into a nuclear power plant facility and a nuclear reactor facility. At the same time, a nuclear power plant facility is provided with a flood control unit 811) of the marine hydroelectric power station floating structure (593,594,595) constituting the upper part of the ship's body deck (SDU) of the marine power plant by the transportation section of the construction machine (811c) The construction and use of the grab dredging line (879d) on the road and grab dredger (879d) is achieved by installing a clam shell on the ship to a special crane W as for dredging equipment was used in the dredging of a small passage or anchorage standard display will be described as in the grab bucket pyeongjeok capacity (m ³⁾ and are shown in the table below as its features.

As shown in FIG. 41, the collection of seabed mineral manganese nodules 909, as described above,

(1) Internal Nuclear Power Plant (811) Nuclear Power Plant Nuclear Waste Treatment Unit (811a) and Hull Location Moving Construction Machinery (1) Nuclear Power Plant The nuclear power plant equipment and the nuclear reactor facility are installed in the reactor body main body 1 of the nuclear power plant and the flood control system A submarine mineral intake sampling machine (not shown) is connected to an oil drilling machine 908 and an undersea mining net 910 connected to the upper portion SDU of the marine power plant body dock 911 and the wire rope chain 915 to the periscope 913 and the rubber balloon 914 and the dual structure pipeline line automatic pneumatic valve transport device 916 and the core drill 917 to the undersea mining robot 912, With installed machines dispensing chute connected to the structure of the construction machine is configured for subsea mineral manganese nodules 909 collected.

Referring to FIG. 4M, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention is installed in a nuclear reactor plant main body 1, 811c) of a marine power station docked at the top of the deck (SDU) of a marine hydroelectric power station (593,594,595); and a crusher (874)

Referring to FIG. 4M, a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment is disposed inside the reactor main body 1 of the nuclear power plant 811, Crusher (874) showing control structure of construction machine position control of hull position movement of marine hydroelectric power station floodplain (593,594,595) constituting at the upper part (SDU) of ship's body dock hull deck of the marine power plant with traffic transportation part (811c) The road and crusher 874 are connected to a feeder hopper 874c and a vibrating grease repeater 874d to the gyration crusher 874a and the chassis frame 874b through a primary crusher 874e of the crushing head, The crusher 874 is constituted by connecting structures of the vibration screen 874g and the drum elevator 874h to the secondary crusher 874f of the crane unit 874f and used for compaction of the aggregate layer in road and concrete construction.

As shown in FIG. 4 (m), the crushing machine is used for crushing and grinding, and is used mainly for the production of aggregate. In the future, .

The types of crushers are separated into primary, secondary, and tertiary crushers. The description of each part of the primary crusher is as follows.

As shown in FIG. 4 (m), the crusher is a machine which is crushed by a compressive force, and rocks are inserted between the jaws on both sides, and one side is fixed, and the other side is operated, The stone is crushed, and it is pulled down by magnetic gravity and pushing force. Such a jaw is made of a structure capable of crushing any hard rock pomegranate with powerful force.

As shown in FIG. 4m, the gyretor crusher is made of cast iron or steel and is composed of a frame lower eccentric shaft and a driving gear, and a cone-shaped crushing chamber is provided at the upper part. The crusher is a crusher which has a hard crushing head on the vertical crushing shaft and is first crushed while being rotated, and then discharged to the bottom crushing chamber. This crusher has the advantages of less vibration and continuous crushing compared to a jaw crusher. It has the upper part of the machine as a discharge port and the lower part as a discharge port, so that a gravel input hopper can be installed and loaded on a dump truck There are advantages. Impact crusher's Hammer mill crusher has many discs on one rotating shaft and hangs a rectangular hammer around the hinges to make a rapid rotation, And is crushed by the hitting force at this time.

As shown in FIG. 4m, the con crusher of the second crusher has an umbrella-shaped cone-mantle head on a short vertical spindle, and a stone is pinched between the cone curve balls provided in the frame by the eccentric motion of the umbrella. So that the undercoat is broken. This structure is somewhat complicated because it is crushed by the impact action, and there is almost no slip in which the crushed stone flows down as it is, and the crushing ratio is relatively large. Impact force and compressive force are used. Compared to the Zaireetori crusher, it has the advantage that the cone is short, the dimension of the supply port is small, and the outlet gap size is the largest size of the crushed stones. It is suitable for mass production of certain aged aggregates. The double roll crusher of Hammer crusher has two light-hardening rolls fixed on a separate horizontal axis, and the gap can be adjusted freely. The rolls are installed in parallel, but the rolls are rotated in opposite directions to each other, so that the rocks are squeezed while passing between the rolls. This roll has the main function of compression crushing and discharging and is widely used in the production of packing aggregate.

As shown in FIG. 4M, the rod mill of the third crusher 874 was to produce fine aggregate of 5 mm or less. In the case of the ball mill, the rod mill and the ball mill were used to separate the broken- , Which is a machine for producing short-circuited rods in a forced round drum, continuously supplying fine aggregate with water together with water, pulverizing and pulverizing the drum while rotating it, When the water is small, it is crushed finely. When there is a lot of water, the degree of roughness of the mouth is large. Wheat with water is wet, and dry without water is generally wet.

As shown in Fig. 4 (m), the ball mill is different from the ball mill in that a steel ball is rotated in place of a rod of a rod mill and rotated to obtain new aggregate.

Its standard specification is to display the crushing capacity per hour in tonnes (TPH (ton per hour)].

As described above, a crusher is used as a machine for crushing and reducing crushed stones, and is used for all crushing operations. It is mainly used for aggregate production. The power source 46 of the engine generator 226 serves as a marine tunnel transport device 941 A plurality of construction machine connection structures are provided inside the reactor installation main body 1 of the nuclear power plant so that the transportation transportation section 811c of the hull position shifting construction machine of the nuclear power generation facility section 811, The submarine mineral intake sampling machine 911 and the submarine mineral collection robot 912 are connected to the periscope 913 through the crude drilling machine 908 and the seabed mineral deposit net 910 connected to the upper part SDU of the body of the offshore power plant dock, ) And rubber balloon (914) Double-structure piping line Automatic pneumatic valve transport device (916) and Core drill (917) Distribution machine of construction machine The rod mill of the crusher 874 produces a fine aggregate of 5 mm or less. Therefore, a ball mill is a rod mill and a ball mill are made of a crushed stone As a machine for producing fine aggregate again, a new aggregate crush stone is constituted by connecting structures of (811).

Referring to FIG. 4n, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1, 811c are used to control the construction machine position adjustment of the hull position movement control of the marine hydroelectric power station floating feeder 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) Type plunger pump (148b) and radial plunger pump (148c) Straight configuration of construction machine connection structure Road,

4n, as shown in FIG. 4n, the inside of the reactor installation main body 1 of the nuclear power plant is connected to the transportation transport portion 811c of the hull position shifting construction machine of the nuclear power generation facility 811, The previous cylinder 126 showing the construction machine position adjustment arrangement of the hull position movement control of the marine hydroelectric power station flood control 593, 594, 595 constituting the deck upper part SDU, the bossable plunger pump 148b of the plunger pump 148, As shown in Fig. 21, the axial rod portion formed inside the cylinder 126 used as a construction vehicle or a conveying machine of the prior art level is provided with a seal ring (not shown) Pressure hose 190 and a coupling 29 are connected to the crank 248 and the crank 248 by valve devices, respectively, as shown in FIG. Use as a device Is assembled with the linkage 249 and is simultaneously transferred into the reactor installation main body 1 of the nuclear power plant by the transportation transport portion 811c of the hull position moving construction machine of the nuclear power generation facility portion 811 to the upper end portion of the ship's body dock hull deck (593,594,595) of the marine hydroelectric power station (593,594,595). The existing cylinder (126) showing the position adjustment structure of the construction machine of the hull displacement control construction machine connection structure of the disassembly coupling and the hydraulic cylinder equipped with the heavy equipment construction machine The cylinder and the piston constituting the body constitute the load-and-piston seal 822 and the bush seal 824 to the piston seal 823 and the slide ring 826 to the wear ring 825 and the O-ring 828 And a load seal 834 and a baffle 835 are attached to the backup seal 830 and the load seal 832 and the pin seal 832 at the load seal 829 and the load seal & A piston ring 836 and a multistring 837 made of rubber And a cylinder (126), and is divided into a high-pressure valve and a low-pressure valve of a hydraulic pump, and a connection structure is formed by an electric motor, a hydraulic tank, and hydraulic hoses to provide a water storage tank for marine- In the tunnel hydraulic system, the construction machine is installed in the reactor water main body 1 of the nuclear power plant so that the cylinder body can be separated from the hydraulic pump, Pressure relief valve 474 and the hydraulic hose 190 by providing the high-pressure pipe 14, the reducer 35, the elbow elbow 44 and the flange 28, (29) constitute male and female threaded joints.

As shown in FIG. 4n, the hydraulic pressure is defined as the hydraulic pressure. The mechanical energy is converted into the pressure energy of the fluid by the hydraulic pump using the power, and is stored in the hydraulic oil. The pressure is controlled by the control valve, Means a device or system that converts three basic control elements, flow rate (speed control) and direction change (direction control), to mechanical energy again through the actuators of hydraulic cylinders or hydraulic motors, The advantage of the system is that it generates a large force compared to the size of the system and enables precise position control and start-up under a large load condition, resulting in excellent control (power, direction , Speed) and controllability and excellent heat release.

As shown in FIG. 4n, the disadvantage of such a hydraulic pressure is that it is sensitive to foreign substances due to contamination of the surrounding environment by the waste oil, so that the risk due to the use of the high pressure and the change in the working condition due to the temperature change, In this configuration,

The hydraulic system can first be divided into power supply, control and output sections, and the power supply section supplies the flow to the system, with the main components being the prime movers and pumps, the prime mover having the mechanical power required to drive the pump In an industrial system, an electric motor is generally used as the device. In the case of a vehicle such as an excavator and a farm machinery, a prime mover is an automobile engine, and a pump obtains mechanical power from a prime mover and converts it into a fluid flow with pressure .

As shown in FIG. 4n, the output device of the hydraulic system includes an actuator (actuator) and a load, and the actuator serves to move the load by converting the power of the fluid into mechanical power, while the actuator is a cylinder Linear actuator) and the output of the hydraulic system in the case of a hydraulic motor (rotary actuator) that generates rotational motion.

As shown in FIG. 4n, the control device is located in the middle of the hydraulic system, and the components include a directional control valve, a pressure control valve, and a flow control valve. For example, the direction of motion of the actuator can be adjusted by directional control of fluid flow, such as when the cylinder advances or retracts.

As described above, controlling the pressure of the fluid is controlling the force of the output, while controlling the flow rate constitutes the control of the velocity of the actuator.

As shown in FIG. 4n, the constitution of the pressure source portion includes a tank for collecting a necessary amount of oil, a hydraulic pump for pumping oil from the tank into the circuit, and safety valves for protecting the power source, Pumps with different types of equipment are used according to their specific needs. Gears and vanes are used. Piston pumps are used for motors and tanks. Relief valves for shut-off valves. Suction lines for filters on heat-exchange thermometers. And the control unit will be described as shown in the following table.

As shown in FIG. 4n, there are constituted a pressure control valve for regulating the pressure of the oil, a direction switching valve for switching the flow direction of the oil and switching the operating direction of the actuator, and a flow control valve for adjusting the operating speed The pressure control valve is a counterbalance valve for the relief valve and the relief valve and the unbalanced valve for the sequence valve and the unbalanced valve. The directional control valves are 2/2 and 3/2 to 4/2 and 4/3 to 5/2-way valves, The control valve is composed of the orifice and the operating speed control, and at the same time, Table 1-1 describes the hydraulic device configuration as shown in the following table.

As shown in Fig. 4n, the operation unit is described as a table as shown in the following table as a linear motion and a rotational motion.

First, the cylinder of linear motion is linearly pressed or pulled.

Secondly, the motor of the rotating motion profits the weight with the wire.

Third, the swing motors of the swing motion rotate at a certain angle. Table 1-2 explains the operation of power and pressure oil in the hydraulic system as shown in the following table.

The units of pressure and power in mass and force are described in detail in the following table.

First, in terms of physical quantities, the physical quantities are the characteristics of the object, that is, the states or processes that can be measured. For example, speed (speed), pressure, time, and temperature are physical quantities. Color is not physical quantities. The mass is standardized in kilograms (kg), the time in seconds (s), the temperature in Kelvin (K) or Celsius (˚C), and the major physical quantities such as force, area, flow, The velocity can be derived from the above basic unit. SI defines kg as a unit of mass.

Secondly, in terms of mass, mass is generally used in terms of weight, and cubic steel with a mass of 1 kg on earth has a mass of 1 kg.

Thirdly, in terms of force, mass describes the mass unit with its own properties, regardless of gravitational acceleration, and the unit of force is determined in relation to gravitational acceleration (Newton, 1643-1729) ( F = m ㅧ α ), force = kg ㅧ m / s ² This is simply Newton [N], which is defined as 1N = 1 kg m m / s ² .

In the pressure Fourth, although the pressure is the "pressure to be applied to the unit area of the object, the force" is the unit to have a metric engineering units of [kg _f / cm ^2] or [kg _f / m ^2] mainly used so far In the future, you will have to use the SI unit [N / m ² ], or Pa (read Pascal).

As described above, the inside of the reactor facility main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment is transferred to the transportation transportation portion 811c of the hull position moving construction machine of the nuclear power generation facility 811, The previous cylinder 126 showing the construction machine position adjustment arrangement of the hull position movement control of the marine hydroelectric power station floodplain 593, 594, 595 constituting the body dock hull deck upper part (SDU) and the bossable plunger pump 148b and a radial plunger pump 148c.

Referring to FIG. 4o, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 of the nuclear power generation facility 811, 811c) of the marine power station dock The upper part of the deck (SDU) of the marine hydroelectric power station constructed on the upper deck (593,594,595) road,

As shown in FIG. 4O, the inside of the reactor installation main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste is connected to the transportation conveying portion 811c of the hull position moving construction machine of the nuclear power generation facility 811, (593,594,595) constituting the upper part of the ship's deck (SDU) of the marine power plant Cylinder (126) showing the position adjustment structure of the construction machine of the hull displacement control of the marine hydroelectric power plant floating structure A cylinder and a piston constituting a hydraulic cylinder 623 provided as a heavy equipment construction machine are provided with a rod-and-piston seal 822, a piston seal 823, a booster seal 824 and a slide ring 826, A backup seal 830, a load seal & backup seal 831, a dead seal 832, a pin seal 833, a multistage seal 832, and an O-ring 828, a load seal 829, The piston 834, the baffle 835, A ring 836 and a multistring 837 around the rubber zero piston 127 and the inside of the cylinder 126 are classified into a high pressure valve and a low pressure valve of a hydraulic pump and are connected to each other by an electric motor, A water storage tank for a flood control facility, a marine tunnel transportation facility, a marine hydroelectric dam facility, and a construction machine are constructed inside a reactor installation main body 1 of a nuclear power plant for distribution and input of a construction machine. The body includes a pressure relief type safety valve 474 having a high pressure piping 14, a reed 35, an elbow elbow 44, and a flange 28, And the hydraulic hose 190. At the same time, the coupling 29 is connected to the inside of the reactor installation main body 1 of the nuclear power plant as a male and female threaded connection structure, the hull position of the nuclear power generation facility 811, (811 (593,594,595) composed of the hydrodynamic power plant floodgate (593,594,595) consisting of the upper part (SDU) of the marine power plant body and the lower part (SDL) of the dock hull deck at the center of the hull deck (SDM) Cylinder (126) showing the position control arrangement. Construction machine connection structure of disassembly unit. The distribution dispenser of reactor control equipment of nuclear power plant is composed.

Referring to FIG. 4P, inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, a hose position of a nuclear power generation facility 811, A cylinder 126 showing a construction machine position adjustment structure of a hull position movement control of a marine hydroelectric power station floating picker 593, 594, 595 constituting a marine power plant dock upper deck upper part (SDU) 885a) Straight configuration of construction machinery connection structure Road,

As shown in FIG. 4P, the inside of the reactor installation main body 1 of the nuclear power plant is connected to the upper portion (SDU) of the hull deck of the marine power plant body by the transportation transportation portion 811c of the hull position moving construction machine of the nuclear power generation facility portion 811 The construction machine of the marine hydroelectric power plant flood control station (593, 594, 595) constituting the hydraulic motor of the hydraulic motor cranes (885a) and the cylinder (126) Values are generally compared to atmospheric pressure.

As shown in FIG. 4p, the atomospheric pressure refers to the air surrounding the earth, and the pressure applied by the atmosphere is called the atmospheric pressure. The standard atmospheric pressure is as follows.

1atm = 760mmHg (can height ^{_{Ontario) = 10332kg f / m 2 =}} 1.0332kg f / cm 2

= 10.332 mAq (height of water) = 101325 N / m ² = 1.0 1325 bar

As shown in FIG. 4P, the gauge pressure is the pressure measured by the gauge and the pressure measured based on the local atmospheric pressure.

As shown in FIG. 4P, the absolute pressure is a pressure measured based on the full vacuum.

As shown in FIG. 4P, in the fifth power, work is defined as the amount of energy consumed and is calculated as the product of the applied force and the distance traveled by the force ( W = F S ). Suppose you need 300 N of force to move an object 40 m. In this case, the work is W = 300N ㅇ 40m = 1200N ㅇ m [J]. However, the idea of work alone can not tell how fast the object has moved. Was this done in 10 or 5 seconds? That is, power takes into account how fast energy is consumed. By dividing the work by the time it took, you get the expression for the power.

For example, if the work is N m m and the time is in seconds, the power will be N m m / s. In general, P is used for capital letters, while the lower case p is symbol of pressure , Where s / t is replaced by speed υ in the above equation.

For example, if the force is N, the velocity is m / s, a unit of power is the o N m / s. Power is also expressed as horse power (hp). The conversion relation between these two units is as follows.

As shown in FIG. 4P, since the change relation between the units is applied to the equation, the force is N and the speed is m / s. These equations, which are made in consideration of convenience, are widely used in the industrial field. In the international system of units, the power uses Watt (Watt) as a coordination unit. Since W is a small unit, it is generally expressed in kilowatt (kW) Putting the conversion factor (1kW = 1000W) into equation (1.2) gives the following equation used in the international system of units.

As shown in FIG. 4P, the symbol kW is used to indicate that the unit of the value calculated in the above equation is kilowatt (kW). The unit applied in Eq. (1.3) is F (force) N, and υ (velocity) is m / s.

As shown in FIG. 4p, the flow of the fluid and the flow of the friction in the Bernoulli equation and the principle of Pascal's principle and the pressure transfer to the static statics of the fluid in a simple fluid dynamics continuity equation used in a hydraulic machine are explained in detail as follows.

In the continuity equation, the continuity equation applies the law of mass invariance to the flow of fluid, which means that the fluid in the closed path of the closed curve is not created or destroyed on the way.

As shown in FIG. 4P, if the flow in the channel is considered as a steady state flow and the fluid does not consider the compressibility, arbitrary sections 1 and 2 orthogonal to the tube are set, and the average flow velocity Are denoted by υ ₁ ν ₂ , the area of A ₁ A ₂ and the density of ρ ₁ ρ ₂ , respectively, and the amount of fluid flowing through each cross section per unit time must be the same according to the law of mass invariance. That is, if the mass is m ,

은 임의의 점에 있어서 관로를 지나는 질량 유량(mass flowrate)이다. And here,

Is the mass flowrate through the pipeline at any point.

As shown in FIG. 4P, since the masses passing through the point (1) in unit time are ρ ₁ , A ₁ , and υ ₁ , the above equation is as follows,

으로 되며 이 Q를 유량이라 하고 관로 속을 지나는 유체의 유량은 어느 단면에 있어서나 일 정하다는 것을 나타낸다. 즉 유압에서는 유량이란 "단위 시간에 이동하는 액체의 양"을 말하며 토 출 량으로 표현하고 있고,유량은 통상적으로 기호 Q로 표시하고 단위는 ℓ/min. cc/sec 으 로 표시하며 유속은 "단위 시간에 이동하는 유체의 거리"를 말하는 것으로 위 식으로부터

As shown in FIG. 4P, when the fluid is uncompressed, ρ = Const .

And this Q is called the flow rate, and the flow rate of the fluid passing through the pipe shows that it is fixed at a certain section. In the case of hydraulic pressure, the flow rate refers to the amount of liquid moving in a unit time, expressed as the discharge amount, and the flow rate is usually expressed by the symbol Q and the unit is expressed in l / min. cc / sec, and the flow rate refers to the "distance of fluid moving in unit time" from the above equation

And is expressed in units of m / s.

As shown in Fig. 4p, the Bernoulli equation describes the relationship of the non-compressible fluid to the total energy, and since the hydraulic fluid is almost non-compressible, the Bernoulli equation can be used in a hydraulic system and the energy of the fluid is 3 In the form of branches.

First, fluid energy (due to height and protagonist) = W h

The following pressure energy (due to pressure) = W ㅇ

Next kinetic energy (due to velocity) = W ㅇ

As shown in FIG. 4P, the units of the above three energy terms are all Nm. If there is no energy coming in or out from a system in any system, the energy at any two points must be the same.

Since W is common to each term, the following equation is obtained by dividing it.

This is a Bernoulli equation that expresses all of the energy contained in a fluid per unit weight, so if one of the three energies increases, the energy of one or both of the other two energies decreases, so that the sum of the three energies is equal Balance.

As shown in Fig. 4P, the hydrostatics of the fluid is proportional to the hydrodynamic pressure regardless of the shape of the vessel. Therefore, it can be expressed as the product of the specific weight of the fluid and the head.

p = rh (1.6)

As shown in FIG. 4p, the principle of Pascal is that when a fluid is pressurized by a force (a force of a person, a force of a machine, or a force) in a closed container, It is called "Pascal's principle" because it is Pascal who first uncovered this principle at the same size. The principle of this principle is used in a pneumo-hydraulic device, and the pressure on the surface where the stopped liquid is in contact with each other The pressure applied at a point on the stationary liquid is the same for all directions, so the pressure applied to a portion of the liquid stopping in the closed container is the same for all parts It is called Pascal's principle because it is transmitted at the same time.

As shown in FIG. 4P, when a liquid is put into a closed container and a force F is applied from above, the liquid has a property of not decreasing the volume even if it is compressed, so that the liquid has a force against the pressing force from above. This is called the reaction, and the reaction force of this liquid is called the pressure ( p ).

The pressure in the vessel is the force F divided by the area A of the piston.

단, 실린더 내 액체의 높이 차에 의한 압력의 차이는 p값에 비해 매우 작으므로 무시할 수 있다. 위의 식으로부터

As shown in Fig. 4P, the principle of pressure transfer is that when the fluid is filled in the cylinder and the forces of F ₁ and F ₂ are applied to the piston cross-sectional areas A _{1 and} A ₂ , If there is no friction between the piston and the cylinder, there is no leakage from this part, and there is no energy loss due to the transfer, the pressure generated in the two cylinders can be expressed by the following equation.

However, the difference in pressure due to the height difference of the in-cylinder liquid is negligible as it is very small compared to the p value. From the above equation

Is obtained. That is, the force is proportional to the cross-sectional area of the piston. Since A ₁ is smaller than A ₂ , a force F _{2 which} is sufficiently larger than F ₁ is obtained. Hydraulic presses and hydraulic presses use this principle.

Embodiment of the hydraulic intensifier, the surface area is in connection by the rod to the other two pistons when the action of the pressure p ₁ on the piston area A ₁ is transmitted to the small piston force F ₁ is via the load acting on the force the cross-sectional area A ₁ Therefore, the pressure p ₂ is increased and the friction loss is neglected.

The pressure in the pressure intensifier is inversely proportional to the area of the piston.

As shown in FIG. 4p, the flow of fluid is referred to as the internal flow, in which all interfaces of the fluid flow are solid surfaces, and this flow is largely divided into laminar flow and turbulent flow, In the case where the viscous force is dominant than the inertial force and the Reynolds number is small, that is, the velocity is small and the viscous flow satisfies Newton's viscosity law, the turbulent flow is inversely proportional to the inertial force, At large, the magnitude of the velocity is large and, in general, the flow in the hydraulic system is often a laminar flow.

 As shown in FIG. 4 (b), friction and flow, as shown in the table above, suffer loss when hydraulic energy is transferred through the pipe. The friction is generated by the fluid itself and the inner wall of the pipe and generates heat. The hydraulic energy is converted into thermal energy, while the loss of hydraulic energy is called the pressure loss of the hydraulic fluid. Since the hydraulic fluid has pressure loss in all the structures in the hydraulic system, The loss is due to the friction of the flow medium, and the pressure loss in the structure that changes to thermal energy is sometimes deliberately generated, so that the pressure loss that causes heat generation in the structure is not desirable, As the fluid in the pipe runs in the direction of the arrow, the pressure in the direction of flow gradually decreases because it is heated by the structure.

As shown in FIG. 4 (b), the hydraulic pump is separated from the hydraulic pump in terms of the relationship between the discharge amount and the pressure in terms of the power and efficiency of the pump. First, in the overview of the hydraulic pump, A pump that converts energy into energy and increases the hydraulic energy level of the hydraulic oil to apply energy to the hydraulic system is called a hydraulic pump. The pump is classified as a cost saving pump and a volume type pump. There are centrifugal pump, sump pump, axial flow pump and injection pump as switching pump, and there is a constant relationship between discharge amount and pressure. As the discharge amount increases, the discharge pressure decreases. The positive displacement pump means that when the axis of the pump rotates once And the discharge amount is constant regardless of the load pressure and is discharged according to the load pressure As the pressure is determined, there is a risk that the pump will be destroyed when the load becomes excessive. In the hydraulic system, the hydraulic pump pumps the low-energy hydraulic fluid in the tank by applying the pump operation, And the hydraulic oil is constituted by a system which returns to the tank by returning to the low energy, while the work or energy applied to the hydraulic oil by the pump operation is transmitted to the hydraulic oil, (= Force) ㅧ (displacement) = (pressure) ㅧ (width) ㅧ (displacement) = (pressure) ㅧ (exclusion volume).

과 같이 된다.The work done in unit time, ie, power or power,

.

 As shown in Fig. 4P, Table 2-1 explains the relation between the discharge amount and the pressure according to the classification of the hydraulic pump, as shown in the following table.

위 표와 같이, 유압 펌프의 토 출 량은 입력 축을 1회전 시킬 때 토출구로부터 내보내진 작동 유의 체적으로 나타내며,예를 들어 32cc/rev라면, 1회전당 토 출 량이 32cc라는 것이며,유압 펌프에는 그 속도 이하로 구동한 경우에는 소정의 토 출 량을 유지할 수 없는 「최저회전속도」가 있어서 속도 이상으로 회전시킬 경우, 극단으로 수명이 단축되고, 파손하는 일도 있는 「최고회전속도」가 정해져 있는데 이 최저와 최고회전 속도의 범위 내라면 임의의 속도로 유압 펌프를 구동할 수 있는 것이고 회전 속도에 비례해서 토출구로부터 내보내진 작동 유의 유량은 커지므로 32cc/rev의 유압 펌프를 1500rpm(1분당 1500회전의 속도)으 로 구동한 경우 토출구에서 나오는 유량은 32cc의 1500배, 즉 '48,000cc를 1분간에 흘린다.'라는 의미의 48 ,000cc/min(48ℓ/min)가 되며,즉 1500rpm에 놓인 이 유압펌프의 토출량은 48ℓ/min라고 표시하며 토출구에서 압력이 5kg_f/cm² 정도로 대단히 낮은 경우에는 실제로 측정한 토출량과 계산에서 구해진 토출량(이론 토출량)이 상당한 근사치가 되면서 동시에 유압 펌프에는 토출구의 압력이 수치 이상으로 높아지면 내부 누설이 많아지고 수명도 현저히 짧아진다는 의미를 갖는 「최고사용압력」이 정해져 있으므로 유압펌프의 내부에는 금속면과 금속면의 접촉부가 여러개 있어서 그 부분을 윤활하게 하기 위한 작동유가 필요하며 내부 누설은 이 목적이 이용되기 때문에 뺄 수가 없다.

As shown in the table above, the discharge amount of the hydraulic pump is expressed by the volume of the operation oil discharged from the discharge port when the input shaft is rotated once. For example, when 32 cc / rev, the discharge amount per one revolution is 32 cc. Quot; maximum rotation speed &quot; at which a predetermined amount of discharge can not be maintained when rotating at a speed equal to or lower than the speed, the &quot; maximum rotation speed &quot; The hydraulic pump can be driven at an arbitrary speed within the range of the minimum and maximum rotational speeds. Since the flow rate of the working oil discharged from the discharge port is increased in proportion to the rotational speed, a hydraulic pump of 32 cc / rev is operated at 1500 rpm Speed), the flow rate from the discharge outlet is 48,000cc / min (48ℓ / min), which means 1500cc of 32cc, ie, '48,000cc flows in 1 minute', that is, 1500rp discharge rate of the hydraulic pump is placed in m when very low as 48ℓ / labeled min and the pressure in the discharge port 5kg _f / cm ² is as a considerable approximation of the discharge amount (theoretical flow rate) obtained from the actually measured flow rate and computed at the same time the hydraulic pump Has a "maximum operating pressure" which means that the internal leakage increases and the life span is significantly shortened when the pressure of the discharge port becomes higher than the numerical value. Therefore, there are several contact portions between the metal surface and the metal surface inside the hydraulic pump, Lubrication oil is required and internal leakage can not be removed because this purpose is used.

Therefore, the internal leakage becomes larger (almost proportionally) as the pressure of the discharge port becomes higher, and at the maximum operating pressure, the leakage amount becomes 5% to 10% of the theoretical discharge amount. 95% to 90%. The numerical value indicating what percentage of the actual discharge rate at which the actual discharge rate is the theoretical discharge rate is called volumetric efficiency.

In general, when the volume efficiency is merely expressed, the volume efficiency at the maximum working pressure is often expressed. When the internal leakage is 5% of the theoretical discharge amount, in other words, when the actually measured discharge amount is 95% efficiency is shown as 95%, and in the pump power and efficiency, as the suction pressure of the hydraulic pump ^{_{p s [kg f / cm 2}} ], the discharge pressure ^{_{p d [kg f / cm 2}} ] , and the SAT output flow R [m ³ / s], the pump power generated by the pump (the horsepower that is effectively transmitted to the fluid) L _p can be obtained as follows.

( L _p = pQ [kg _f m / s]) (2.1)

Where p = p _d - p _s is the pressure difference between the outlet and inlet of the pump, but usually p _s is atmospheric pressure and p = p _d .

 If the output unit is expressed in kW or ps

to be. In addition and as a unit of p kg _f / cm ² when the units of Q ℓ / min pump power is

Theoretical power (liquid power) L _{th applied} to the hydraulic oil by the pump when it is assumed that there is no leakage loss in the pump,

( L _th = pQ _th [kg _f m / s]) (2.4)

Here, p kg _f / cm ² is the pump discharge pressure, Q _th [m ³ / s] is the theoretical discharge amount, and the power (axial power) transmitted from the prime mover to the pump shaft is L _s

Here, ω [l / s] is the angular velocity, and the torque (torque) needed to ^{_{T th [kg f / cm 2}} ] is rotating the pump, N [rpm] is the rotation number of a pump is received through the axis from the prime mover Efficiency is defined as a measure of the degree to which the pump converts the energy received through the shaft to useful energy, not because it does not give all of the energy to the hydraulic oil, but because some of the energy is lost and the remaining energy is carried by the hydraulic oil.

여기서 η는 펌프의 전 효율이다.

Where η is the total efficiency of the pump.

 As shown in FIG. 4P, the hydraulic actuator is a general term for a hydraulic device that performs mechanical work by generating a reciprocating motion or a rotary motion of an output shaft by pressure oil. The hydraulic actuator is a hydraulic motor (rotational motion of a shaft) Linear motion of the shaft) and a swinging actuator (limited rotational motion of the shaft). Table 4-1 shows the types of hydraulic actuators.

As shown in FIG. 4P, in the hydraulic motor, the hydraulic motor is a device that converts the energy of the pressure oil into rotational motion. In principle, when the hydraulic oil is supplied to the suction side of the hydraulic pump, the hydraulic motor becomes a hydraulic motor. However, However, since the hydraulic motor can rotate in any direction, the characteristics of the hydraulic motor can be compared with an AC motor having the same rotational motion as follows.

It is very easy to change the speed of rotation and change of forward and reverse rotation, and it is very easy to start and stop. It has good inertia and good tracking ability. It responds quickly and is suitable for the elements of automatic control and control mechanism. However, since the hydraulic device itself is driven by a motor, its use is limited. In the type of the hydraulic motor, the flow rate required to make one rotation of the motor is changed and the flow rate is constant. Therefore, , And the latter is referred to as a variable displacement hydraulic motor.

As shown in FIG. 4P, the structure of the gear motor is almost the same as that of the gear pump. The supplied oil is applied to the tooth surface to generate a torque to rotate the output shaft. The gear is generally used as a spur gear. It is disadvantageous in that it is difficult to fabricate a motor with a structure that is simple, compact, lightweight, and structurally variable compared to a motor, and can not be used because the torque output and rotation speed pulsations become large at a low speed of 100 rpm or less. To 80% and the rotation speed is about 1000 to 3000 rpm.

As shown in FIG. 4P, the vane motor is the same as the vane pump in the structure, and has an advantage in that the output torque is constant when the supply pressure is constant, reversible, continuously variable, Therefore, the maximum operating pressure is 70bar, the power is 5 ~ 30ps, the number of revolutions is 200 ~ 1 800rpm, and the speed limit of 200rpm is small, the output torque fluctuates little and generally the efficiency is not good at low pressure or low speed. There is also an added disadvantage.

As shown in FIG. 4P, in a piston motor, a piston motor is often called a plunger motor or a rotary piston motor, and is almost the same in structure as a piston pump, and its type is an axial type, There is a radial type. Axial piston motors have a boss and swash plate type.

As shown in FIG. 4P, a radial piston motor is a type in which several or ten pistons are radially arranged on a shaft to rotate the shaft while reciprocating in the radial direction, and the eccentric or eccentric cam of the cylinder block is used to rotate the piston As piston motors are classified as multi-stroke type which generate torque by several reciprocating piston movements per revolution by using eccentric type and multi-leaf cam to convert the force by pressure to torque, piston motors are classified into fixed displacement type and a variable displacement type are included in each square type.

As shown in Fig. 4p, in the output and efficiency of the hydraulic motor, the pressure oil to the pressure flowing into the motor ^{_{p 1 [kg f / cm 2}} ], the pressure oil to the pressure flowing out of ^{_{p 2 [kg f / cm 2}} ] And the flow rate of the supply pressure oil is Q [cm ³ / min], the power input to the hydraulic motor is calculated as follows.

The output is calculated by the torque and the angular velocity.

Where n is the torque [kg _f o m] in which the motor output-side rotational speed [rpm], T is delivered to the load on the motor output side. Therefore, calculating the efficiency of the motor in relation to input and output

The size of the hydraulic motor is expressed as q (cm ³ / revolution) pressure per revolution, Q = q ㅧ n _o , assuming no internal leakage of the motor , and λ = 100% When the pressure of oil is regarded as 0 ( p ₁ = p )

 From the above equation,

가 된다.Therefore, the torque efficiency

.

Where n _o is the number of revolutions on the assumption that there is no internal leakage in the motor and T _o is the maximum torque or the theoretical torque at which the pressure of pressure p can occur.

 As shown in FIG. 4P, the advantages of the hydraulic motor in its pros and cons are that it can be stopped rapidly more easily than an electric motor, a wide range of continuously variable transmission can be obtained, a compact, light and strong force can be obtained, It is easy to control by starting variable, variable displacement type pump or metering (valve which means throttle valve and improving flow rate), and safety device or brake for overload And it is convenient for a torque control machine such as a winder used for a wire or a wire. As described above, it is possible to control the hull position moving construction machine control of the flood control part 811 inside the main body 1 of the distribution- (811a) Body dock of marine power plant The hull of a marine hydroelectric power plant floating attachment (593,594,595) constituting the upper part of the deck (SDU) A conventional cylinder 126 showing the construction machine position adjustment structure of the movement control, a piston motor 885a of the hydraulic crane 885, a bossable plunger pump 148b of the plunger pump 148 in the hydraulic motor, (148c) The construction machinery connection structure consists of distributing devices of flood control machines based on Bernoulli's theorem and Pascal's theoretical physics method.

Referring to FIG. 4q, a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention is installed in a nuclear reactor main body 1, a hatch position of a nuclear power generation facility 811, 811c) to the marine hydroelectric power generation production of the construction machinery connection structure in the form of a windmill to show the regulation structure of the construction machine position of the marine hydroelectric power station levitation stand (593,594,595) in the upper part of the dock hull deck Control part Construction machinery Connection structure Doctor City composition Road,

As shown in FIG. 4Q, the inside of the nuclear reactor facility main body 1 of the nuclear power plant is connected to the upper portion (SDU) of the ship body hull deck upper part (SDU) of the marine power plant body by the transportation transportation portion 811c of the hull position moving construction machine of the nuclear power generation facility portion 811 Construction of marine hydropower generator (811b) Construction of connecting structure of a construction machine of a spinning mill type showing the position control structure of the construction machine of the marine hydroelectric power plant floating structure (593,594,595) It consists of distributing devices of reactor control equipment of nuclear power plant.

As shown in FIG. 4q, the offshore hydroelectric power production and production unit 811b of the marine power plant body dock hull deck upper part (SDU) of the marine hydroelectric power plant lifting plant 593,594,595, the DC 655 of the construction machine connecting structure, A head tank 189 having an AC power 656 and a hydraulic tube 190 are connected to an inlet pipe 191, a cylinder 126, a piston or piston pump 127, a bulb body 660, a battery and a battery 671) construction machine connection structures.

As described above, in the conventional technology of hydroelectric power generation, the waterproofing facilities and the waterproofing facilities in the power generation facility (amphibious water) do not impair the requirements of the hydroelectric power generation, but the setting of the dam 680 or the intake dam 680 The problem of the environmental impact of the surrounding area due to the setting of the water intake dam 680 is as follows.

First, in order to obtain adequate generation capacity, the construction cost of dams and the period required for dam construction are much larger than those of generation facilities, compared with generator generators of power generation facilities due to the construction of dams. Second, Environmental impact near the installation site (taking into consideration that the ground and the crustal changes of the dam installation location stratum have not been thoroughly checked in advance. As a result of the prolonged stay of the flow rate rather than the multi- purpose application for controlling the flood drought after dam installation There are cases where small cities are buried due to earthquakes or landslides due to algae or harmful red tide breeding and the amount of water intake is small and small. In addition, there are cases where solar power generation destroys forests due to the installation of solar power generators Inability to control flood droughts and obstacles to impeding national economic development In the case of nuclear power generation, the damage caused by the accident of the former Soviet Chernobyl nuclear power plant and the explosion of the nuclear power plant in Japan resulted in the radiation damage, and the damage was considerable. On the other hand, the thermal power plant is located near the metropolitan area Or on the shore, the exhaust gas emitted from the chimneys accelerates the global warming. In the meantime, due to the pollution of the atmosphere and the increase of carbon dioxide emissions, the natural disaster is caused by the global warming phenomenon. And the countermeasure against the problem is reached to the serious level. FIG. 1c shows a method of eliminating the troubles of mankind by endless production of environment-friendly energy by installing the generator of the present inventor in the ocean. Prevention of disaster prevention of the internal flushing control unit 811 in the main body 1 of the apparatus (811e), a control block diagram and a BF model, a speed control method, and a three-pump direct-injection-start-type method in a configuration of a multi-stage pump operation method Here, the marine hydroelectric generators, which are equivalent to the multi-stage multi-stage pump plant, are equipped with a multi-stage hydroelectric generator, so that large-capacity generating power can be produced. (SDU) of the ship's body dock hull deck (811c) of the marine power plant.

As shown in FIG. 4q, the total capacity of the multi-purpose dams in Korea is about 12.6 billion cubic meters, the capacity of the power generation facilities is about 1.05 million kw, and the flood control capacity is about 2.2 billion cubic meters The hydropower facility is a facility that uses flow and dropping, so the annual water supply capacity of these multipurpose dams is about 10.9 billion ㎥. By the dam, the lowest capacity of Soyanggang Dam is 2.9 billion ㎥, but the annual water capacity is 1.2 billion ㎥, which is less than 3.4 billion ㎥ of Chungju Dam. Capacity scale of power generation facilities is largest at Chungju Dam with 410 thousand kw. In order to allow a person skilled in the art to understand the background of the above-mentioned power station (land hydroelectric power generation) hydraulically and hydraulically by a hydraulic person, the inventive hydraulic power plant 233 The following is a detailed description of the outline of the hydropower plant.

 As shown in FIG. 4Q, the inside of the nuclear reactor facility main body 1 of the nuclear power plant is connected to the upper portion (SDU) of the ship body hull deck upper part (SDU) of the marine power plant body by the transportation transportation portion 811c of the hull position moving construction machine of the nuclear power generation facility portion 811 This is a strained construction road of a hydroelectric power plant showing a construction machine position control structure of a marine hydroelectric power plant flood control station (593,594,595) that constitutes the hydroelectric power plant. , And should also be constructed to minimize losses of drop and flow. Hydropower facilities in hydroelectric power plants are divided into 4 types according to their functions: water supply facilities (680n), power generation facilities (680p) and waterproof facilities (680q). It is necessary to plan properly and design each plant to be able to make the most effective use of the hydraulic power by combining them well. Therefore, there are various structures of the workpieces to be used in each plant. Depending on how these are combined, (679s) of the hydroelectric power plant will be briefly examined for the hydroelectric power plant.

Referring to FIG. 4r, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention is installed in a nuclear reactor facility main body 1, 811c) Hydraulic power plant showing control structure of construction machine position control of hull position movement of marine hydroelectric power station floating structure (593,594,595) composed at the upper part of deck of marine power plant dock (SDU)

Referring to FIG. 4Q, as shown in FIG. 4Q, the inside of the reactor installation main body 1 of the nuclear power plant is connected to the transportation transport portion 811c of the hull position moving construction machine of the nuclear power generation facility 811, Ship's position of the construction machine connecting structure in the form of a wheelbarrow showing the construction machine position adjustment structure of the hull position movement control of the marine hydroelectric power plant floating structure (593,594,595) constituting the upper deck part (SDU) It is composed of the strabismus configuration of the construction machinery connection structure and the distribution input devices of the reactor control equipment of the nuclear power plant.

Referring to FIG. 4R, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 and includes a power generating and manufacturing section 811b of a nuclear power generating facility 811, Hydraulic power plant construction machine connection showing control structure of construction machine position control of hull position movement of marine hydro-power plant flood control station (593,594,595) constituting on the upper part (SDU) of the marine power plant dock to the transportation transportation part (811c) Straight configuration of the structure Road,

As shown in Fig. 4 (r), the power generation and production section 811b of the nuclear power generation facility section 811 and the transportation section 811c of the hull position moving construction machine are installed inside the reactor facility main body 1 of the nuclear power plant, In order to collect the charge water for power generation, a facility that blocks water in a direction almost perpendicular to the flow of the river - this is called a water intake dam (680b) - and a facility for taking water in the immediate lower river - The water taken from the intake port 678g is guided to the water tank (680m) above the power plant 233 through the water channel to obtain a drop, which is then sent back to the water turbine through the water pressure pipe, The energy is converted into mechanical energy and used to generate electric energy by the generator. The water is discharged to the river again through the watertight path 678b. In this process, It creates sediments near the sphere and deposits the sediments in the sluice water. When the water level suddenly decreases and the water level exceeds the specified value, the surplus water is safely discharged to the river. Among them, there are two types of waterway, from the water inlet (678g) to the entrance to the water tank (680m), and the waterway is a pressure waterway which pressurizes the entire waterway and a natural water- (680 m) is used for the natural downfalling type. In case of pressure water, the crude seawater (680i) is used instead of the constant water tank (680m) Since the reservoir 680a acts as a constant tank 680m in the dam-type power plant without installing the gutter 680k, the water tank 680k does not provide a constant tank.

As shown in Fig. 4 (r), in the case of a conventional power generation dam, when a power generation dam is first classified according to its use, it is used to increase the water level on the upstream side in a simple water intake dam and a dam water- There is a gigantic low water dam (dams) that make adjustments or reservoirs (680a) by blocking the valleys or rivers to store water for a certain period of time, as well as the intake of water, The following is a list of the major issues that should be rationally designed to be safe even after receiving floods and other external forces. The next type of dam should be selected as the most economical considering the topography and geology. As the water level rises, it's called draining soon. And that the maximum flow rate should be safely discharged even in the event of a flood so as not to endanger the facilities such as power generation facilities and downstream facilities. According to the purpose of use of the power generation dam, a water intake dam and a low water dam are formed, Dam in the dam is intended to be taken from a hydroelectric power plant. Generally, the height and width of the dam are not so large. Next, in the low water dam, the dam is raised by increasing the water level on the upstream side, Since the large quantity of water that can be controlled is used, it has been explained above that it is divided into the adjustment area and the reservoir depending on the size of the adjustment ability.

As shown in Fig. 4 (r), according to the classification of the existing power generation dam by a material used, a concrete dam and a dirt dam are formed in the concrete dam. Firstly, in the concrete dam, the mixed concrete of cement, sand, This is the most used dam because it has high stability. Secondly, it is an economical dam for dams to mix and construct sand, gravel and clay. This type of dam should be designed to maintain stability by gently sloping the upstream and downstream sides of the concrete dam.

The power generation and production section 811b of the nuclear power generation facility section 811 and the transportation section 811c of the hull position moving construction machine are installed inside the reactor facility main body 1 of the nuclear power plant as shown in FIG. (678c) and the conceptual diagram (678d) of a reservoir-type power plant showing the arrangement of the construction machine position control of the hull locomotion control of the marine hydroelectric power station flood control station (593,594,595) constituting the upper part of the dock hull deck (SDU) Hydraulic Power Plants of the Conceptual Diagram of the Power Plant The marine hydroelectric power plant lifting plants 593, 594, and 595 of the connecting structure of the construction machine connect the hydraulic rotary cylinder 620 of the rack and pinion type (NRP) The vertical partition wall 605 provided with the buoyancy controlling butterfly valve 622 of the hydraulic cylinder 621 and the door 624 for the hydraulic cylinder in the hydraulic cylinder 623 or the hydraulic cylinder 623 and the pin connecting shaft 606 for the portable lug coupling, The lugs (607) Large flange connection to the portable lug pin (608) Machining hole (615) Construction machine connection structure and drilling machine for crude oil into the interior of the marine tunnel transport device (941) to bridge bridge (937) 908 to the bridge 928 and the pipe bridge 937 to the inside of the marine tunnel transport device 941 The marine tunnel transport device internal train 771 is connected to the construction machine connection structure and disassembled to connect the reactor facility control device (680o), power generation facilities (680p), and waterproof facilities (680q) are divided into water supply facilities (680n) and water supply facilities The hydraulic power plant of the hydroelectric power plant (233), which shows the configuration of the position control mechanism of the construction machine of the marine hydroelectric power plant floating posture (593, 594, 595) To (680o), power generation facilities (680p), and waterproof facilities (680q) are installed in the seawater hydropower plant (680i), which is equivalent to the arrangement of the multi- 943) multi-tiered large-scale hydropower generator (944) devices constitute a hydro-electric power plant with a seismic form of the hydraulic system and a marine tidal power plant in the form of a spinning mill.

Referring to FIG. 4S, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1, as a power generating and manufacturing section 811b of a nuclear power generating facility 811, Hydraulic power plant showing construction equipment position regulation structure of hull displacement control of marine hydroelectric power station floating structure (593,594,595) constituting the upper part of dock deck (SDU)

As shown in Fig. 4S, in the old rock dam 680z, it is economical when such a rock material is procured locally in the same manner as the clay dam 680y mainly using rock as a building material. This dam can raise the dam more than the dam dam (680y) and has high stability, but its own weight is large, so it is necessary to strengthen the foundation. The rock dam 680z is a kind of gravity dam and is composed of a rock wall 680t and an upstream surface protection layer 680u and a drainage layer 680v, a soil material 680w and a foundation rock bed 680x have.

The power generation and production section 811b of the nuclear power generation facility unit 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant as shown in FIG. (678c) and a conceptual diagram of a reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating power plant (593,594,595) The marine hydroelectric power plant flood control readers 593, 594, 595 provided in the power generating and manufacturing portion 811b of the nuclear power generation facility 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the connection structure are rack and pinion- A butterfly valve 622 for controlling the buoyancy of the band guide 621 and a hydraulic cylinder door 624 provided in the hydraulic cylinder 623 or the hydraulic cylinder 623 of the water hammer control machine A large flange connection connecting joint portion machining hole 615 to the portable lug 607 and the portable lug pin 608 to the vertical partition 605 and the pin connecting shaft 606 for the portable lug coupling by the distribution and charging devices, The bridge 928 and the pipe bridge 937 to the inside of the marine tunnel traffic device 941 to the piercing drilling machine 908 and the pipe bridge 937 to the marine tunnel traffic device 941 (771) inside the marine tunnel transportation device classifies the hydroelectric facilities in the hydroelectric power plants according to their functions while constructing the flood control facilities by the construction machine connection structure and the disassembly coupling, 680o), power plant (680p), and waterproof facility (680q) are the facilities that utilize the flow rate and dropout, while the construction machinery location of the marine hydroelectric power plant flood control station (593,594,595) Hydropower station showing regulatory configuration In the hydraulic system, the theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated. In the water intake system 680n, which is equivalent to the arrangement of the multi- With the equipment (680p) and the waterproofing facilities (680q), the multi-tiered large-scale hydroelectric power plants (944) of the SeaSeo Hydroelectric Power Plant (943) .

Referring to FIG. 4t, a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1, and a power generating and producing section 811b of a nuclear power generating facility 811, Hydraulic power plant showing construction equipment position regulation structure of hull displacement control of marine hydroelectric power station floating structure (593,594,595) constituting the upper part of dock deck (SDU)

As shown in FIG. 4 (t), according to the classification according to the mechanical structure of the existing power generation dam, the gravity dam is formed in the gravity dam, and the gravity dam is the most widely used type. Since this dam (680) is caught on the foundation part, the installation site should be a place where there is a solid rock. The gravity dam is mainly made of concrete, but also the soil dam (680y) using the soil, the rock dam (680z) Is also used as a kind of gravity dam.

As shown in FIG. 4 t, the power generation and production section 811 b of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant constructs a marine hydroelectric power plant (678c) and conceptual diagram of reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating plant (593,594,595) The marine hydro-power station floating dishes (593, 594, 595) provided in the power production and production unit (811b) of the nuclear power generation facility unit (811) inside the reactor facility main body (1) of the nuclear power plant of the mechanical connection structure are rack- A flood control valve 622 for controlling the buoyancy of the band guide 621 of the hydraulic rotary cylinder 620 of the NRP and a flood control valve 622 for the hydraulic control cylinder 623 provided with the hydraulic cylinder door 624 for the hydraulic cylinder 623, A large flange connection connecting joint portion machining hole 615 to the portable lug 607 and the portable lug pin 608 to the vertical partition 605 and the pin connecting shaft 606 for the portable lug coupling by the distribution and charging devices, The bridge 928 and the pipe bridge 937 to the inside of the marine tunnel traffic device 941 to the piercing drilling machine 908 and the pipe bridge 937 to the marine tunnel traffic device 941 The internal tunnel 771 of the marine tunnel transport device is constructed by connecting the construction machine connection structure and disassembly to form the reactor control device of the nuclear power plant and at the same time sorting the hydraulic equipment in the hydroelectric power plant according to the function thereof, The hydro-equipments which are divided into four types of water-supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) are the facilities using flow rate and free fall, while the facilities of the hydro- View construction machine position adjustment configuration In the hydraulic power plant of the marine seesaw hydroelectric power plant 943, theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, and the water intake facility 680n, which is equivalent to the arrangement of the multi- (640o), power generation facilities (680p) and waterproofing facilities (680q), the multi-tiered large-scale hydroelectric generators (944) of the Marine Seisoh Hydroelectric Power Plant (943) The marine tidal power plant is a marine hydro power plant.

Referring to FIG. 4U, a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, as a power generating and producing unit 811b of a nuclear power generating facility 811, Construction of a hydro-electric power plant with a position control structure of a marine hydroelectric power station floating structure of a dock hull deck upper part (SDU)

As shown in Fig. 4U, the previous sub-wall dam 679e is provided with a surface layer plate 679f, a hollow portion 679i at the use water depth 679h and a surface layer concrete 679k) and theoretical energy (679p) and aberration outputs (679q) at the kinetic energy of water (679m) and mechanical energy (679n) at the potential energy of water (679l)

As shown in FIG. 4U, the power generation and production unit 811b of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant constructs a marine hydroelectric power plant (678c) and conceptual diagram of reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating plant (593,594,595) The marine hydroelectric power generation control unit 811b which generates the power for producing the power of the marine pollution control unit 811 into the distribution input device main body 1 of the marine hydroelectric power generation production control unit of the mechanical connection structure, The readers 593, 594 and 595 are connected to a hydraulic rotary cylinder 620 of a rack and pinion type NRP which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, Hydraulics The portable lug 607 and the portable lug pin 608 are connected to the vertical partition 605 and the pin connection shaft 606 for connection to the large lid 606 by a distributor / (928) and pipe bridge (937) to the inside of the marine tunnel traffic device (941) to the drilling machine (908) for crude oil, and the bridge pier (928) Inside the bridge (937) Inside the marine tunnel transport device (941) Inside the marine tunnel transport device Inside train (771) consists of the construction machinery connection structure and disassembly and disassembly to constitute the flood control facility, (680n), power generation facilities (680p) and waterproof facilities (680q) are the facilities that utilize the flow rate and free fall, while the hydroelectric facilities which are divided into the four types of water intake facilities Construction of the hull locomotion control of the reader (593,594,595) In the hydraulic plant of the marine seesaw hydroelectric power plant 943 showing the system position adjustment structure, the theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, (640o), power generation facilities (680p) and waterproof facilities (680q) are installed in the facility (680n), and the seesaw type of the hydraulic device is connected to the multi-stage entry type large hydroelectric generators (944) A marine hydroelectric power plant is composed of a marine tidal power plant.

Referring to FIG. 4V, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1, and is connected to a power generating and producing unit 811b of a nuclear power generating facility 811, Construction of a hydro-electric power plant with a position control structure of a marine hydroelectric power station floating structure of a dock hull deck upper part (SDU)

As shown in FIG. 4V, the type of the previous water gate 293 is provided on the upper portion of the fixed dam, and when it is trough, it is closed to increase the water level on the upstream side to facilitate the water intake, It has the function of preventing the water level from rising excessively and discharging the sediments deposited on the upstream side of the dam. There are several kinds of gates used for this. First, the slos gate is used. This is a small dam As the simplest sidewall 293 to be used, a generally rectangular door is opened and closed by operating it vertically, and a roller gate is used. When the slit gate becomes large, the frictional resistance between the door frame and the door contact portion becomes large, And the upper and lower operation of the water gate 293 is usually carried out using a roller At the same time as using the ear rope and the tongue winch 137, the water gate 293 controls the design water level 293c with the de-intergate 293a and the rolling gate 293b while at the same time controlling the water surface 293d, And has a fixing portion 293e and a fixing portion 293f.

As shown in FIG. 4V, the power generation and production unit 811b of the nuclear power generation facility unit 811 inside the reactor facility main body 1 of the nuclear power plant constructs a marine hydroelectric power plant (678c), a conceptual drawing (678d) of a reservoir plant and a conceptual drawing (678e) of a coordinated knowledge plant, showing the construction machine position control arrangement of the hull position shifting control of a floating plant (593,594,595) The marine hydroelectric power plant flood control readers 593, 594, 595 provided in the power generating and manufacturing portion 811b of the nuclear power generation facility 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the connection structure are rack and pinion- A butterfly valve 622 for controlling the buoyancy of the band guide 621 and a door 624 for the hydraulic cylinder in the hydraulic cylinder 623 or the hydraulic cylinder 623, The distributor and dispenser of the reactor installation control machine is provided with a large flange connection connector joint portion processing hole 615 for the portable lug 607 and the portable lug pin 608 on the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling. ) Construction machine connection structure and bridge tunnel (937) to the bridge bridge (937) to the inside of the marine tunnel traffic device (941) To the crude drilling machine (908) to the bridge bridge (928) The marine tunnel internal transport electric train 771 inside the device 941 constitutes a flood control facility by the disassembly and disassembly of the construction machinery connection structure and at the same time classifies hydraulic facilities in the hydroelectric power plant according to their functions, (680o), power generation facilities (680p) and waterproof facilities (680q) are the facilities that use the flow rate and dropout, while the facilities of the marine hydroelectric power station floating ship (593,594,595) Adjustable construction machine position adjustment configuration Theoretical hydraulic force for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, and the water intake equipment 680n, which is equivalent to the arrangement of the multi-stage multi-stage pump 2, Hydraulic equipment seaside type and marine type marine type with multi-tiered large-scale hydroelectric generators (944) devices of marine Seisoh hydroelectric power plant (943) with water supply facility (680o), power generation facility (680p) The tidal power plant is a marine hydro power plant.

Referring to FIG. 4w, in the nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention, the nuclear power generation equipment part 811 is connected to the upper part (SDU) Construction of hydroelectric power plant of marine hydroelectric power plant flood control of hull position movement control constituting strainer configuration of connection structure showing construction machine position adjustment structure Road,

As shown in FIG. 4w, the power generation and production unit 811b of the nuclear power generation facility unit 811 is installed inside the reactor facility main body 1 of the nuclear power plant, and the marine hydroelectric power plant Theoretical physics of the Bernoulli theorem of connecting structures showing the arrangement of the tachograph winch (137) and the gate (293) of the construction machine for the opening and closing control of the sluice with a rope or a chain attached to the fuselage of the flood control (593,594,595) The physical properties of water and hydrodynamics are included in hydrodynamics of the state of the art to simplify the installation conditions of the marine power plant of the present invention.

As shown in FIG. 4w, the density of water in the physical properties of water is maximum at 4 [° C] under atmospheric pressure and varies somewhat with temperature, but since the change is very small, it usually has a constant weight in hydrodynamic calculations It is acceptable to handle. In other words, the weight of water is 1 [g / ㎤] or 1 [t / ㎡]. However, since the rate of change of the volume, that is, the compressibility of water, is only about 5 ㅧ 10-5 at a change of 1 atmospheric pressure at room temperature, water is usually considered to be incompressible.

As shown in FIG. 4w, if there is a difference in flow velocity inside the moving liquid, a force that resists the relative movement is generated. This property is called viscous or internal friction, and its degree is represented by the viscosity coefficient. In hydro hydrodynamics, the order of H [m] from the stationary water surface and the cross-sectional area A [㎡] think. The volume of this order is AH [㎥], and assuming that the weight per unit volume of water is ω [kg / ㎤], the total weight of this order is ωAH [kg]. Therefore, the order is supported by the force of water ω [kg] acting upward from its base, and is in equilibrium.

로 된다.That is, since W = ωAH [kg], the average force p [kg / T m2]

.

를 압력수두(pressure head]라고 하며 압력의 단위로서는 [kg/㎠]또는 [kg/㎡]를 사용한다.As shown in FIG. 4w, p is called the pressure intensity or pressure intensity at the depth H [m], and the water pressure P acting on the whole is called a voltage force or a total pressure, of

Is referred to as "pressure head" and the unit of pressure is [kg / ㎠] or [kg / ㎡].

As shown in FIG. 4w, hydrodynamics treats the law of motion of fluid (water), and when the motion of fluid is largely divided into flow, vortex, and wave, the flow is divided again, The turbulent flows and turbulence flow into the turbulent state because they are tangled with each other. The flow of fluid used in hydroelectric power plants is generally turbulent, and the amount Q [m 3] of water flowing in pipelines and waterways is expressed as the product of the cross sectional area A [m 2] of the water flow and the average flow velocity υ [m / s].

( Q = A ㅇ υ [㎥]) Equation ②

로 부 터

가 된다. As shown in Fig. 4w, 2 points in the leading enclosed by the solid of the channel, such as a, only the area of each of A ₁ [㎡] at b, A ₂ [㎡] The average flow velocity _{υ 1 [m / s],} υ ₂ [m / s], the flow rate from point a is A ₁ B ₂ [m 3 / s] and the flow rate from point b is A ₂ υ ₂ [m 3 / s].

from

.

조의 단면적은 분출구의 단면적 보다 훨씬 크기 때문에 υ ₁는 무시된다.(≒0)또, h ₁ - h ₂ = h인 조건을 윗 식에 대입하면,

으로 부터

를 얻는다.As shown in Fig. 4w, to consider the water that flows at a speed υ has a head corresponding to the height of the yisangron H in the ^{H (= υ 2/2 g} ) as a velocity head and Torricelli's Law to the end This is a very small hole in the lower side of a water tank with a cross-sectional area of 1, which is called Torricelli's theorem. Actually, due to the viscosity of water and the friction loss in the ejection hole, the actual ejection speed υ ₂ 'becomes slightly smaller than υ ₂ and is expressed by the following equation, that is, the velocity υ ₂ of the water ejected from the orifice ➁ is given by Bernoulli's theorem

Sets of cross-sectional area υ ₁ is ignored because much greater than the cross-sectional area of the air outlet (≒ 0) _{Also, h 1 -. H 2 =} h Substituting the above conditions in the formula,

From

.

As shown in FIG. 4w, the power generation and production unit 811b of the nuclear power generation facility unit 811 is installed inside the reactor facility main body 1 of the nuclear power plant, and the marine hydroelectric power plant (678c) and conceptual diagram of reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating plant (593,594,595) The marine hydro-power station floating dishes (593, 594, 595) provided in the power production and production unit (811b) of the nuclear power generation facility unit (811) inside the reactor facility main body (1) of the nuclear power plant of the mechanical connection structure are rack- Which is provided with a hydraulic rotating cylinder 620 of the NRP and a butterfly valve 622 for controlling the buoyancy of the band guide 621 and a door for the hydraulic cylinder 624 in the hydraulic cylinder or hydraulic oil press 623, The distributor and dispenser of the reactor installation control machine is provided with a large flange connection connector joint portion processing hole 615 for the portable lug 607 and the portable lug pin 608 on the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling. ) Construction machine connection structure and bridge tunnel (937) to the bridge bridge (937) to the inside of the marine tunnel traffic device (941) To the crude drilling machine (908) to the bridge bridge (928) Inside the device 941, the internal tunnel 771 of the marine tunnel transport apparatus is constructed such that the reactor control facility of the nuclear power plant is constructed by disassembly and coupling with the construction machine connection structure, and at the same time, the hydraulic power plant in the hydroelectric power plant is classified according to the function thereof. The hydro-equipments, which are divided into 4 types of facilities (680n), 680o, 680p, and 680q, are the facilities that use the flow and fall, while the facilities of the marine hydropower station (593,594,595) Construction of hull displacement control In the hydraulic plant of the marine seesaw hydroelectric power plant 943 showing the system position adjustment structure, the theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, (640o), power generation facilities (680p) and waterproof facilities (680q) are installed in the facility (680n), and the seesaw type of the hydraulic device is connected to the multi-stage entry type large hydroelectric generators (944) A marine hydroelectric power plant is composed of a marine tidal power plant.

Referring to FIG. 4x, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1, as a power generating and manufacturing section 811b of a nuclear power generating facility 811, Construction of a hydroplaning system of Bernoulli theorem showing the arrangement of the construction machine position control of the hull position movement of the marine hydroelectric power plant floating structure (593,594,595) constituting the upper part of the dock hull deck (SDU)

The kinetic energy 679m of water, the mechanical energy 679n, the electrical energy 679o, the theoretical hydraulic power 679p, the aberration output 679q, the generator output 679r ), And a schematic diagram 679s of hydroelectric power generation.

As shown in Fig. _{4x, (η t), (} η g) is aberration, respectively, in the form of a generator, the capacity, but differ slightly depending on the size of the load _{η t = 80 ~ 90 [%} ] at the time of rated operation, η _g = 90 to 97 [%], and the product of these two factors η = η _t η _g is called total efficiency. As can be seen from the above equation, how to obtain a large free fall ( H ) and economically obtain the quantity of use ( Q ) to use hydraulics effectively is a problem. If the downstream part of the stream is used, the amount of water to be used can be increased, but the drop amount is reduced. On the other hand, in the upstream part of the stream, a large fall can be obtained.

 [Table 1] Approximate values of aberration and generator efficiency

As shown in FIG. 4x, in the types and facilities of the hydroelectric power plants, the hydroelectric power plants are classified into various types according to the water intake method and the operation method. First, the dam type power plant and the hydroelectric power generation plant are formed with a dam-type hydroelectric power plant and a watershed-type power generation plant. Dam type power plants are constructed by constructing a dam across a river to prevent runoff, For this type of big dropping, it is necessary to construct a dam which is quite high and it is not an economical method because it has a large burial area. However, in addition to the aptitude terrain, it is often used as an irrigation reservoir or a flood control reservoir. This dam is the most useful in Korea and it is very important to construct this dam in future.

As shown in Fig. 4x, a dam constructed for the purposes of power generation, irrigation and flood control is called a multipurpose dam. In addition, it is often impossible to avoid considerable fluctuations due to the imbalance between the amount of rainfall and the amount of water used.

As shown in FIG. 4x, this is economically advantageous as the amount of water stored in the dam is more advantageous, and it is also preferable in terms of operation. Therefore, in the lower part of the Han river system having a relatively sloping and abundant quantity in Korea, (Chuncheon, Unam, Cheongpyeong, Paldang, Soyanggang Power Plant, etc.)

As shown in FIG. 4x, the power generation and production unit 811b of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant constructs a marine hydroelectric power plant (678c) and a conceptual diagram of a reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating power plant (593,594,595) The marine hydroelectric power plant flood control readers 593, 594, 595 provided in the power generating and manufacturing portion 811b of the nuclear power generation facility 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the connection structure are rack and pinion- A butterfly valve 622 for controlling the buoyancy of the band guide 621 and a hydraulic cylinder door 624 provided in the hydraulic cylinder 623 or the hydraulic cylinder 623, The distribution and dispensing devices of the bovine nuclear reactor control equipment are connected to the vertical lumen 605 and the port lug coupling pin connection shaft 606 by a large flange connection end joint at the portable lug 607 and the portable lug pin 608 615) to the inside of the marine tunnel traffic device 941 to the bridge of the construction machine connection structure and bridge 928 and the bridge 937 to the drilling machine 908 of the crude oil to the bridge pier 928 and the pipe bridge 937 to the marine tunnel The internal tunnel 771 of the marine tunnel communication device inside the traffic device 941 is constructed by the construction machinery connection structure and the disassembly coupling device and the hydraulic equipment at the hydroelectric power plant is classified according to the function thereof. (680o), power generation facilities (680p) and waterproof facilities (680q) are the facilities that use the flow rate and dropout, while the facilities of the marine hydroelectric power station floating ship (593,594,595) Adjustable construction machine position adjustment configuration Theoretical hydraulic force for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, and the water intake equipment 680n, which is equivalent to the arrangement of the multi-stage multi-stage pump 2, Hydraulic equipment seaside type and marine type marine type with multi-tiered large-scale hydroelectric generators (944) devices of marine Seisoh hydroelectric power plant (943) with water supply facility (680o), power generation facility (680p) The tidal power plant is a marine hydro power plant.

Referring to FIG. 4 (a), a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 of the nuclear power plant, Hydraulic power plant showing construction equipment position regulation structure of hull displacement control of marine hydroelectric power station floating structure (593,594,595) constituting the upper part of dock deck (SDU)

As shown in Fig. 4Y, the conventional hydraulic power generation outline 679s includes a concept diagram 679t of a dam-type power plant of the construction machine connection structure, an inlet valve 679v to a water intake tower 679v and a ball tap valve 679w on a screen 679u, The main transformer 679x and the main device 679y constitute a hydroelectric power plant with the main transformer 679z.

As shown in FIG. 4Y, the power generation and production unit 811b of the nuclear power generation facility unit 811 inside the reactor facility main body 1 of the nuclear power plant constructs a marine hydroelectric power plant (678c) and a conceptual diagram of a reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating power plant (593,594,595) The marine hydroelectric power plant flood control readers 593, 594, 595 provided in the power generating and manufacturing portion 811b of the nuclear power generation facility 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the connection structure are rack and pinion- A butterfly valve 622 for controlling the buoyancy of the band guide 621 and a door 624 for the hydraulic cylinder in the hydraulic cylinder 623 or the hydraulic cylinder 623, The distributor and dispenser of the reactor installation control machine is provided with a large flange connection connector joint portion processing hole 615 for the portable lug 607 and the portable lug pin 608 on the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling. ) Construction machine connection structure and bridge tunnel (937) to the bridge bridge (937) to the inside of the marine tunnel traffic device (941) To the crude drilling machine (908) to the bridge bridge (928) Inside the device 941, the internal tunnel 771 of the marine tunnel transport apparatus is constructed such that the reactor control facility of the nuclear power plant is constructed by disassembly and coupling with the construction machine connection structure, and at the same time, the hydraulic power plant in the hydroelectric power plant is classified according to the function thereof. The hydro-equipments, which are divided into 4 types of facilities (680n), 680o, 680p, and 680q, are the facilities that use the flow and fall, while the facilities of the marine hydropower station (593,594,595) Construction of hull displacement control In the hydraulic plant of the marine seesaw hydroelectric power plant 943 showing the system position adjustment structure, the theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, (640o), power generation facilities (680p) and waterproof facilities (680q) are installed in the facility (680n), and the seesaw type of the hydraulic device is connected to the multi-stage entry type large hydroelectric generators (944) A marine hydroelectric power plant is composed of a marine tidal power plant.

Referring to FIG. 4Z, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is installed inside a nuclear reactor main body 1 of a nuclear power plant, as a power generating and producing section 811b of a nuclear power generating facility section 811, Hydraulic power plant showing construction equipment position regulation structure of hull displacement control of marine hydroelectric power station floating structure (593,594,595) constituting the upper part of dock deck (SDU)

As shown in FIG. 4Z, the hydroelectric power plant of the conventional concept of the dam type power plant (679t) constructs a dam in the main stream of the river (678) to separately generate a small number of channels or pressure channels, It is mainly used to get dropouts and fallouts by a large distance of waterways using bent landforms. The water is used as water intake (678g), gypsum (680k), waterway or pressure water, constant water tank (680m) The water jets 680j, the water gates 293, the water pressure pipes 191, the water wheels 264 and the waterproof gates 678b in this order. The gutter 680k is brought close to the water inlet 678g to temporarily stop the water, Sand, and vegetation to get clear water into the waterway. On the top of the gypsum (680k), the gypsum is made into a gypsum, sometimes discharging the settled soil and sand.

As shown in FIG. 4Z, the power generation and production section 811b of the nuclear power generation facility unit 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant, and the marine hydroelectric power plant (678c) and conceptual diagram of reservoir plant (678d) showing the construction machine position control arrangement of the hull position movement control of the floating plant (593,594,595) The marine hydro-power station floating dishes (593, 594, 595) provided in the power production and production unit (811b) of the nuclear power generation facility unit (811) inside the reactor facility main body (1) of the nuclear power plant of the mechanical connection structure are rack- Which is provided with a hydraulic rotating cylinder 620 of the NRP and a butterfly valve 622 for controlling the buoyancy of the band guide 621 and a door for the hydraulic cylinder 624 in the hydraulic cylinder or hydraulic oil press 623, The distributor and dispenser of the reactor installation control machine is provided with a large flange connection connector joint portion processing hole 615 for the portable lug 607 and the portable lug pin 608 on the vertical partition wall 605 and the pin connection shaft 606 for the portable lug coupling. ) Construction machine connection structure and bridge tunnel (937) to the bridge bridge (937) to the inside of the marine tunnel traffic device (941) To the crude drilling machine (908) to the bridge bridge (928) Inside the device 941, the internal tunnel 771 of the marine tunnel transport apparatus is constructed such that the reactor control facility of the nuclear power plant is constructed by disassembly and coupling with the construction machine connection structure, and at the same time, the hydraulic power plant in the hydroelectric power plant is classified according to the function thereof. The hydro-equipments, which are divided into 4 types of facilities (680n), 680o, 680p, and 680q, are the facilities that use the flow and fall, while the facilities of the marine hydropower station (593,594,595) Construction of hull displacement control In the hydraulic plant of the marine seesaw hydroelectric power plant 943 showing the system position adjustment structure, the theoretical hydraulic power for operating the flow rate of the seaweed is input to the aberration, and the generator is rotated, (640o), power generation facilities (680p) and waterproof facilities (680q) are installed in the facility (680n), and the seesaw type of the hydraulic device is connected to the multi-stage entry type large hydroelectric generators (944) A marine hydroelectric power plant is composed of a marine tidal power plant.

As shown in the figure, as shown in the figure, the nuclear power plant for nuclear power generation has a double structure block tank, a power generating and manufacturing section 811b) of the hydro-electric power plant showing the regulating arrangement of the construction machinery position of the marine hydroelectric power plant floating structure (593,594,595) constituting the upper part of the deck of the hull deck of the marine power plant dock (SDU) It is necessary to constantly obtain the necessary flow rate for generating electricity safely and to minimize the loss of flow and flow as much as possible, or to classify the hydraulic equipment in the hydroelectric power plant according to its function, Hydropower facilities, which are divided into 4 types of facilities (680o), power generation facilities (680p) and waterproof facilities (680q) There hydroelectric facilities on the surface showing the configuration of the hull construction machinery positioning shift adjustment of marine hydro power plant flotation sikdok marine seesaw hydroelectric power plant (943)

The theoretical hydraulic power for operating the flow rate of the seaweed is inputted to the aberration and the water turbine 680o and the power generation facility 680p are connected to the water intake facility 680n which is equivalent to the arrangement of the multi- And multi-tiered large hydroelectric generators (944) of waterproofing facilities (680q) and marine Seisoh hydroelectric power plants (943).

A circular prefabricated water tank 292 for providing a position on the top of a mountain formed inside the reactor facility main body 1 of the nuclear power plant and natural water for storing the inside of the circular dam 680, A water tank 292 containing materials and a plurality of construction machines for the purpose of overcoming flood damage by circular dams 680 are installed in the nuclear power plant to control the position of the nuclear power plant equipment and reactor facilities The process and the flood control facilities were already established as a new federal state in Northeast Asia, and the land and the ocean in the world were sequentially designated 127 ° 17'00 "longitude, which is the center of the peninsula, and latitude 38 ° 20'00" latitude, Gangwon-do, Gangwon-do, Gangsan-ri, 190 Donggwon-eup, Gangsan-ri, The pump 393, the water tank, the electronic sensor valve, and the unmanned camera 184 of the control system constitute an automatic facility for the flood control facility inside the reactor main body 1 of the nuclear power plant.

Hereinafter, the water source and the water quality of the fire-fighting water (7) for a reactor facility of a nuclear power plant will be described in detail as follows.

The water that is exposed on the surface of the earth, such as river water or lake, is called surface water, and the water that is submerged in the ground like a well is called ground water. The source of the water supply was river water and well water, and the well water had an average temperature of 16 ° to 17 °, which is suitable for cooling water and industrial water because of the difference in water temperature due to seasonal changes. However, at the same time, the river water is abundant in quantity, so it is purified and used as tap water in large cities. The tap water is 3 ° to 8 ° in winter and 25 ° to 28 ° in summer. It is not suitable for other industrial purposes because it changes the water temperature by season. Therefore, water quality is not included in the water Since turbidity, color, taste, smell, etc. are different according to pests and germs, they are inspected and prohibited when they exceed the allowable contents. Germs are a cause of disease and pests are minerals that exceed the standard value, which adversely affect cooking and laundry. The hardness of water is expressed based on the content of minerals such as calcium carbonate in water. That is, when calcium carbonate is contained in water by a factor of a million, this is called 1 (p.p.m. part per milion). Water should be 90 to 110 (ppm) and should not exceed 300 (ppm). In addition, water is divided into soft water and soft water depending on the hardness. Water below 90 ppm is called soft water .

In general, the pump body will be described as follows.

The positive number of the pump is performed by an action of sucking up the inside of the suction pipe and pushing up the inside of the pipe which blows water. The sucking action is due to the vacuum, so atmospheric pressure head. In other words, it can not be raised more than 10.33m under standard atmospheric pressure. However, this 10.33m is the theoretical sump height. In fact, it can not be completely vacuumed by the evaporation of the air or the water contained in the water. Also, by the resistance loss in the sucking tube, about 2/3 of the theoretical sucking height In other words, it is only about 7m. Therefore, the height of the pump should be less than 7m from the minimum water level (hereinafter, the explanation is omitted).

Double structure block for nuclear waste treatment Nuclear power plant construction equipment with double tank dust collector is generally equipped with water storage tanks for nuclear power generation facilities, marine tunnel traffic equipment, and construction equipment for offshore hydroelectric dams. Nuclear power plant to distribute the equipment Nuclear power plant to supply water to the inside of the nuclear plant control equipment to store water to the inside of the body to transmit weather information to the barge hull at the top of the tank and the barge at the bottom of the holding tank, A small, medium and large marine hydroelectric power plant floating on a marine tunnel traffic system constituting the control system. Weather observing equipment of the connection structure of the connection structure. Receiving the weather information through the radar, a water storage tank and a round dam equipped with a construction machine, Injector nozzles, non-motorized pumps and cables, In addition to providing the distribution equipment for the distribution of the construction equipment for the marine hydroelectric dams, it is also equipped with the tunnel distribution system, and at the same time, each circular water tank located at the top of the mountain selects stainless steel plate or plastic material which does not rust. And water tanks for controlling the flow of the water. The water tank is composed of double structure block tanks, and water is stored in the inner block tanks, and the outer walls of the outer block tanks, And a heating device heater is provided in the middle between the inner block tank and the outer block tank so that the air conditioner of the cooling device and the heating fan for cooling the air and the cooling fan are further built into the nuclear reactor facility body of the nuclear power plant.

Meanwhile, the water tank provided with the tanks for controlling the flow of water and the storage of the water into the nuclear reactor plant of the nuclear power plant is composed of the lower part of the tank where the welding process is excluded, Steel plate with high tension at the bottom and lid steel plate at the top of the tank are not attached and the concrete base bottom thickness is set to 60 cm at the lower part of the water tank and at the same time, the inner block tank (width × length × thickness: 1.5 m × 1m × 3m m) of standard stainless steel plates in the form of a round tank with bolts and nuts. An inner block tank, in which each steel plate was connected in a cylindrical form, and an outer block tank were fixed to the top of the foundation bottom steel Sand and gravel cement is mixed with the concrete finishing plant and the concrete spreader in the concrete machine which is the construction machine. It is transported by the concrete mixer truck and then the concrete energy source (Hereinafter referred to as a reactor structural body of a nuclear power plant having a dual structure block tank reactor for treating nuclear waste, hereinafter abbreviated as "reactor main body"), a nuclear power plant having a double structure block tank for treating nuclear waste, box)

It is often the case that the ship sinks into the water while the ships lose their balance due to the strong wind waves. After the ocean crane is mounted on the upper deck of the hull deck, the engine or the auger generator is operated and power is supplied to the control pump device, Considering that it is used as a marine control ship after it is fixed and bound to a bollard that is a mooring device by a rope or a rope, marine power mooring facilities are fixed type double pipe structure tank bridge bridge construction saddle formwork. Of the piers are connected in 0.5 km units.

As described above, the marine power plant of the present invention is equipped with a dual structure block tank reactor for treating nuclear waste according to the depth of the sea so as not to sink even under a bad weather condition in an area having a depth of 10 km or more Separate coupling of the reactor facility of a nuclear power plant is provided,

Examples of combining materials of the mechanical seal are as follows.

In the contrast means according to the vibration of the pump according to the present invention,

The vibration of the pump is very much overlapped with one or several factors.

First,

First, vibration caused by cavitation: a period of about 600 to 25,000 cycles brings about rapid vibration and noise.

Second, vibration caused by surging phenomenon: cavitation occurs when the discharge amount is large, while surging occurs not only when the discharge amount is small, but also the cycle has a long cycle of about 10 to 0.1 cycle.

Third, vibration caused by water hammer (water hammer).

Fourth, vibration due to unbalance of the flow in the pump

The following is the result of mechanical vibration

First, vibration due to unbalance of rotating body

Second, the vibration due to the dangerous speed causes a severe vibration caused when the rotational speed of the shaft resonates with the natural frequency of the rotating body, and the rotational speed at this time is referred to as a critical speed.

Third, vibration caused by solid friction occurs when a lubricating oil is lacking in the rotating shaft due to a kind of self-excited vibration, or when an active part such as a bearing, a bush, or a ring contacts.

Fourth, vibration caused by hydraulic pressure of bearing is vibration caused by oil pressure of bearing part when rotating at angular speed about twice as high as the dangerous speed. It is not so common in normal speed pump and it is prevented by increasing bearing pressure or reducing rotation Can

Fifth, the vibration due to the natural frequency of the pump is particularly problematic in a vertical axis pump,

Sixth, the vibration due to the centering failure is very important in the case of centering failure.

The seventh is the vibration caused by the prime mover

It is the vibration that happens because the foundation is weak in the eighth

Output definitions for the use of the diesel engine 226

First, the term commercial refers to the generator Referred to as the applied power (equivalent to ISO 8528 PRP)

Secondly, the term 'emergency' refers to an output (equivalent to ISO 8528 ESP) applied to an emergency generator used for a limited time during a main power failure, in which an engine model is formed by a cooling fan 195, a cylinder 126, And is assembled and attached to the V-belt 252 and the flywheel 268. As shown in the figure,

As shown in the above table, the output tolerance is ± 5%. The description of the specification of the engine 226 is the same as the specification of the engine specification of the right side.

<Engine Specification>

Finally, the precautions for handling the compressor are described in detail as follows.

First, for general precautions,

First, the compressor is always kept clean and the surroundings are cleaned and arranged thoroughly.

Second, when the operation of the compressor is shut down, the engine is operated for a short time only once a day for a short period of time.

However, when stopping for a long time, disassemble and clean, replace worn or damaged parts or lubricant with new ones, drain all coolant (drain) and do anti-corrosion measures.

Third, each axis is checked and adjusted every opportunity.

Fourth, valves, pressure gauges, regulators, filters, etc. are prevented from malfunctioning by regular inspections and daily inspections.

Fifth, cool water uses clean water. Cooling tube is disassembled every June or year. It is cleaned with water vapor. If the weight is decreased by 10% or more, it is corroded or worn.

Sixth, always pay attention to the gas leak of each part, and the toxic and flammability should be detected with a small amount of detector, and proper measures should be taken.

Seventh, oil is selected with the help of the manufacturer.

The eighth, if there is an abnormality, stop driving immediately, notify the manufacturer and ask for repair.

In the following notes on starting,

Be sure to check that bolts, nuts and other screws are tight.

Next, fill the crankcase with a specified amount of lubricating oil and check the lubrication condition.

Pass the third cooling water and check whether the cooling water circulates.

Next, open the pressure gauge, pressure regulating valve, drain valve, etc. to check the pressure indication.

Next, the small compressor should be rotated by hand with no load. Check the connection of the electric motor by inserting the hand switch after checking the switch, and check whether the foreign substance is not caught in the cylinder.

The sixth suction valve is closed and the switch is opened with the bypass or drain valve open.

Next, when the normal rotation is performed, the drain valve and the bypass valve are closed from the first stage to the next stage, and at the same time, the suction valve is opened.

Finally, pay attention to pressure, lubricating oil, temperature, noise, vibration leakage at each stage.

Then, in the notes during driving,

The pressure, leakage, vibration, temperature, abnormal noise of each stage, the quantity and temperature of the cooling water, the temperature and pressure of the lubricating oil and the load of the motor are checked.

In particular, pay attention to abnormal increase or decrease in temperature or pressure, and never tighten or hammer the bolt during operation with leakage.

* This is divided into the following.

First, regarding handling of reciprocating compressors

First, whether there is abnormality in the scale of the pressure gauge and the suction / discharge gas temperature at each end

Second, the change of bearing temperature and the abnormal rise

Third, keep a watch on the change of the cooling water temperature and adjust the quantity if necessary.

Fourth, watch the oiling situation of the cylinder lubricator, adjust the flow rate, and supply oil to the lubricator.

Fifth, the state of change of external flow or hydraulic pressure

Sixth, the piston rod packing leakage and temperature rise

The seventh is whether the color of the drain is rapidly blackened

Eighth, are there any differences in the sounds and vibrations of each part from normal?

Ninth Valves or flange joints such as safety valves, drain valves, etc. · Are there any gas leaks on other tight surfaces?

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

The following is the handling of Turbo Compressor

First, the lubricating oil pressure of the bearing lubricant or the temperature of the returned oil

Second, the oil pressure or return oil pressure for the shaft bar or the differential pressure or leakage flow

Third, whether vibration of each part such as main body, bearing,

Fourth, abnormality of bearing water temperature

Fifthly, the change of the cooling water temperature is monitored, and the quantity of water is adjusted when necessary.

Sixth, there is no leakage of gas from valve or flange joint of piping system or other tight surface

Next, is there any abnormality in power consumption?

Finally, the abnormality of the automatic device / monitoring instrument operation

In the note of the fourth stop,

First, switch off the electric motor and close the intake valve.

Second, check the pressure drop and close the discharge valve. Observe the abnormal sound or vibration until stop.

Next, close the coolant valve to cut off the coolant and drain all water from the water jacket or cooling tube.

Finally, discharge any other condensate or oil.

In the notes on the fifth disassembly and inspection,

Firstly, when disassembling and checking, make sure that the machine is disconnected from the power source so that it does not operate.

Secondly, if the gas inside is toxic or flammable, it should be completely insulated and replaced with inert gas.

The following should be done after confirming that there is no pressure at each end of the decomposition operation.

Finally, when the cylinder head is disassembled, the bolt alternates in the order of the opponent facing each other, gradually releasing it to the two relatively positioned positions (of course, confirming that there is no abnormality,

As described above, the selection of the model for the connecting and separating process of each prime mover and the compressor to the inside of the reactor facility main body of the nuclear power plant is made by the type of fire as the fire fighting and disaster prevention countermeasure, Because the damage caused by the fire occurring in the moment of super flashlight is not inevitable, the fire should be selected as the most suitable place for the initial place of fire prevention.

In this method, a combined pumped-water power plant having a natural inflow from the river and pumping only the insufficient water from the lower reservoir in the upper reservoir, and a silo-type power plant 267, In this case, when the motor pump is pumped to generate electricity in the case of amphibious operation, the turbine aberration generates electricity to the motor generator attached to the rotating shaft. In this case, the valve next to the pump aberration must be opened. The nozzle hole 20 is formed inside the turbine 74. The reversible pump aberration shows a power generation efficiency of 70 percent at a positive power of 100 percent and at present a domestic pumping power plant is installed at the Cheongpyeong 40 (600,000 KW), Suyuan (700,000 KW) and Yangyang (1 million KW), which are all of the following: Unlike the above-described method, the drilled hole of the bottom hole becomes the injection nozzle itself, and the blade hole 20 of the nozzle hole 20 is formed so as to maintain the axial thrust balance After the turbine blades are balanced in pressure, the rotational speed of the turbine is controlled.

In this way, the inside of the reactor installation main body 1 of the nuclear power plant having the dual structure block tank reactor dust collector for treating nuclear nuclear power generation waste is filled with the paraffin tape 177 and the injection nozzle (the pipe nozzle which is completely closed by the paraffin nozzle cap 100 10) in which a pyrotechnic sensing wire 41 is attached together with a flammable sensing wire 41 which serves also as a heat sensing sensor. (Referred to as nozzle piping or socket connection joint for connection to a hosel in the form of a candle that illuminates a candle with a paraffin liquid in a cloth utensil 100) or a paraffinic tape 177 is connected to a fire hose (1 kg / cm 2) of the hose type, 9) with the hose length of 15m and the operating pressure of 20kg / ㎠, Fire water (disaster prevention water or It is used as a powder fire extinguisher in many fire extinguishers (acids, alkaline fire extinguishers, foam fire extinguishers, carbon fire extinguishers and carbonic acid fire extinguishers) 159) is referred to as including a fire extinguisher; The same number of circular ejection nozzles 38 of about 490 and the number of ejection nozzles 38 of 8 positions are formed in the gap 15 of the ejection nozzle 10 while simultaneously being discharged to the outside of the body of the fire extinguisher 124 in which the non- A plurality of flames 293 and pyramids 294 are burned by the number of curtain water films 39 and the flames of the pyramid 294 , Oil fire and electric fire, 166), and a cooling action for lowering the temperature of the ignition object (combustible material 166) to a temperature lower than the ignition point, and the hose 9) is mainly a cooling action.

In this case, it is necessary to include a double structure block tank reactor for nuclear waste disposal to achieve initial evolution within 1 second. Unmanned camera (wired / wireless communication equipment and megapixel realization above mentioned zoom module VMD1011 installed on the upper part of the main body of the fire station inside the reactor facility body 1 of the nuclear power plant of the nuclear power plant 1; passive type of analog image output, (184) that includes an OSD control function consisting of a progressive CMOS sensor with up to 20x zoom, and a pump control server (150) integrally formed with the pump control system (150) of the multi- 51) configured to display a fire scene situation on a monitor (52) (1) of a nuclear power plant having a nuclear power plant having a double structure block tank reactor nuclear reactor for processing nuclear waste after being formed into a sonar (fish finder, 907) of sensor sensing function to identify the shape of a submarine object .

A plurality of pump-type multi-stage pumps 8 are provided inside the dual pipe nozzle body B and a pump aberration 37 and turbine aberrations 74 are provided in the high performance submerged pump 36, The turbine pump 140 and the diaphragm 144 and the plurality of compressors are integrally connected to the plunger pump 148 of the air compressors 80 and the plunger 253 by a guide vane The guide wings 142 are not attached to the volute pump and a predetermined amount of the mixed material formed by the impeller 143 inside the casing 141 is introduced into the suction port 168 and the discharge port 169, And the impeller 143 is attached to the shaft 198, which is the center axis of the power motor rotating body, which is the electric motor body 192. The pump shaft of the pump according to the respective pump names is constituted into the impeller 143 or the diaphragm pump 144 and the propeller pump 146 inside the body of the skew pump 147. The gland packing 155 And the mechanical seals 156 are formed from quenching and cooling and flushing to other functions such as cooling and lubrication functions.

For this reason, according to the maritime sovereignty line, the energy resources are transported by connecting Vladivostok and Uleungdo in Russia and Pohang in Dokdo, and Yeosu and Jeju Island are constructed as double structure block tank marine tunnel transportation equipment and linking land and books. And the Shandong Peninsula, connecting to Pohang and the Gugu region of Japan by double-structure block tank marine tunnel traffic system, providing illegal living with one day's life zone, illegal fishing line or military ship of other countries visiting the territory of the 5th degree (NLL) All of them are provided with measures that can be passed by permission of the sovereignty area. In the fishery area, rope knot hooks formed on the balloon rubber balloon wire and wire rope net are illegal because illegal fishing boats can not pull the net after throwing the net on the fishing ground. It is possible to restrict the entry of fishing boats so that those skilled in the art will be able to use military defense facilities Nuclear power plant nuclear reactors can be selected for use as nuclear power plants. Nuclear radiation leakage control of reactor facilities of alternative nuclear waste treatment shielding devices can be provided to distribute and install dual structure block tank reactors.

In order to secure the safety of existing nuclear reactors, the nuclear radiation leakage control of a safety reactor having a double tube structure (dual in-tube structure) is constituted, and at the same time, a method of treating the radiation waste is solved and the distribution of nuclear reactor radiation leakage control double structure block tank reactor Substructure of land and sea composed of main body as connecting structure of marine vessel substitute traffic facility to the inside of the injecting device Operation of the nuclear power hydroelectric power plant that efficiently improves the operation of the nuclear power plant Nuclear radioactivity of the reactor facility of the nuclear waste treatment shielding device Leakage Control Dual Structure Block Tank Dust Collector Injection system Absolute safety connection structure that minimizes explosion of the main body. It is filled with devices constituting the main body as a main body. Leading figures say themselves In order to make the environment more livable, at the same time, the storks must not fall down to imitate the stiffness of the stiffness while imitating the stork 's stance, so that the stiffness of the stiffness of the stiff should not be damaged. Leaders of the social world are in charge of tanks, bombers, bombs, bullets, satellites, missiles, nuclear bombs and rocket bombs, all of which are distributed in the land, We will do our best to save the world economy by cultivating environment friendly non-polluting energy industry that uses electric power to overcome the punctured global economic crisis by establishing as international society codes and norms to transfer munitions goods to construction machinery equipments. Nuclear waste for nuclear power generation for peace Nuclear Power Plant Facilities Dual Structure The construction of reactor facilities for fast breeder reactors is urgently needed.

In addition, since the damage of typhoon is human, physical, and astronomical, it has a great impact on the national economy. Therefore, it is necessary to exercise the national cooperative spirit promptly according to the weather forecast of the Korea Meteorological Administration. In this example, When the weather forecast is announced, the fruit of the orchard is harvested from the fruit of the orchard as a national volunteer, and the fruits are harvested before the typhoon, so that the damage to flood damage is reduced. As a way to cope with floods, it is urgently necessary to cope with floods. Therefore, in order to overcome the above mentioned flood disasters, equipments equipped with a construction machine should be installed in a nuclear reactor plant for nuclear power generation, 1) Adjustment for internal nuclear waste disposal The present invention is not limited to the above-described embodiments, and it is possible to provide a system for distributing and supplying nuclear reactor control equipment of a nuclear power plant. .

(Patent Document 1) Patent No. 0546221 2006.01.19. (Patent Document 2) Patent No. 10-0650936 2006.11.20. (Patent Document 3) Patent No. 10-1167145 2012.07.13. (Patent Document 4) Published Patent No. (10-2005-000053552) 2005.06.08. (Patent Document 5) Published Patent No. (10-2005-0117496) December 14, 2005. (Patent Document 6) Published Patent No. (10-2017-0031947) 2007.03.20. (Patent Document 7) Published Patent No. (10-2007-0106398) November 11, 2007. (Patent Document 8) Published Patent No. (10-2007-0106596) 2007.11.02. (Patent Document 9) Published Patent No. (10-2010-0027087) 2010.03.10. (Patent Document 10) Published Patent No. (10-2012-0066690) 2012.06.22. (Patent Document 11) Published Patent No. (10-2012-0064663) 2012.06.19. (Patent Document 12) Published Patent No. (10-2012-0095337) 2012.08.28. (Patent Document 13) Published Patent No. (10-2012-0112315) 2012.10.11. (Patent Document 14) Published Patent Application (10-2014-0005836) 2014.01.28.

(Non-Patent Document 1) (Non-Patent Document 1) Registration No. 2012. 31. 2012. c-2012-0268465 Registration copyright, Northeast Asian peace coexistence treaty treaty document and constitutional amendment 80.000. (1860-1907) and the boiling point of the energy conversion of the energy content of the United States in the 1960s science and technology of the modern science of the late 1960s. (BWR) Nuclear Power Plant Key System Description of the BWR Nuclear Reactor Pressure Vessel Structure and BWR Fuel Assembly Construction diagram BWR control rod and control rod drive mechanism cross section and BWR fuel handling and storage facility Simplified BWR concept Boiling water reactor The source of the BWR is the author self-leader Nuclear reactor technology http://incredible.egloos.com/4549971 Nuclear reactors: Devices that regulate the nuclear chain reaction to produce energy (artificial fission control). (Non-Patent Document 2) (Non-Patent Document 2) Introduction to Nuclear Safety Engineering Introduction Publications Koryo Dong; Reference. (Non-Patent Document 3) (Non-Patent Document 3) Introduction to reactor engineering; Ulsan University Press; (Non-Patent Document 4) (Non-Patent Document 4) Reactor; (Non-Patent Document 5) (Non-Patent Document 5) A Study on the Nuclear Cooperation between the North and the South and the Northeast Asian Nuclear Cooperation; (Non-Patent Document 6) (Non-Patent Document 6) Nuclear Power Plant Operation Status 2000.10. (Non-Patent Document 7) (Non-Patent Document 7) See Environment Release Paper 2004, Registration No. 11-1480000-000586-10 by the Ministry of Environment. (Non-Patent Document 8) (Non-Patent Document 8) Reference to the 1980 Typhoon Route of the Meteorological Agency under the Climate. (Non-Patent Document 9) (Non-Patent Document 9) The harmful red tide microorganism issued by the Fisheries Research Institute is related to the harmful red tide. (Non-Patent Document 10) (Non-Patent Document 10) Information on peaceful unification on the Korean peninsula is published in the National Unification Press, December 1970 and December 1971. (Non-Patent Document 11) Technical Specification on the Collection of Crude Oil and Gas Mineral Resources (Standard Specification of Semi-Submersible Drilling Rig Page-348,84.06.24.Date; Aug.24th.1984) (HVAC) system for dynamically testing the equipment of the above document, and the HVAC system of the present invention, which is not registered in the prior art document, (NWCD) system. It is a matter of oath to collect the holy will of the gathered peace priors of the local governments and the local governments, and reserves the draft of this draft. Like a man who lives a day and lives a thousand years, he does not lose his life in the water until he is born and dies, does not lose his life in the fire, all the sailors and passengers in the waves of the strong winds, By constructing a hatch cover and an emergency exit door on the left and right sides of the ship, we are able to build a ship of resolution that lives together and dies even if it dies and builds trust and trust among the people. The purpose is to prevent the accident of the Cheonan and the sinking accident of the passenger ship in order to protect the safety of the ship with the first equivalent and the first equivalent to protect the safety of hundreds of millions with ship replacement equipment. I declare the meaning to the world. (Non-Patent Document 12) Refer to the technical literature on the outline of domestic nuclear hydroelectric power plants.

In order to solve the above-mentioned problems, a nuclear reactor facility of a nuclear power plant is provided with a double-structure high-speed multiplying reactor, The reactor facilities are composed of boiling water reactors and pressurized water reactors that usually use water, and power generating reactors are mainly used for light water reactors. In boiler water reactors, nuclear power plants equipped with pressurized water reactors and general purpose high temperature Nuclear power plants equipped with high-speed multiprocessor reactor facilities are connected to the land and the island area by the gas-line and the new conversion road, and the volcanic ash of the earthquake, earthquake, tsunami, In the past, The explosion often indicates that nuclear power plants are shut down.

As shown in FIG. 1, during the operation of the conventional nuclear power plant in the conventional nuclear power plant, when each of the conventional nuclear power plants is close to each other from the time before and after the occurrence of the natural disaster, Which may have a significant impact on the safety of nuclear power plants.

[0001] The present invention relates to a dual-structure, high-speed multiprocessor nuclear reactor facility for a nuclear waste disposal nuclear power plant for nuclear power generation, and more particularly to a nuclear reactor leakage suppression dual structure block tank collector, The best nuclear safety and economical power generation nuclear reactors in the global nuclear power plant are mainly used in light water reactors, boiler water reactor, pressurized water reactor, gas cooling furnace reactor, multi-purpose high temperature gas reactor and new conversion furnace reactor Nuclear waste disposal system for Nuclear Power Plant Operation Nuclear radiation leakage control of Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Connection structure and sinking room The cooling water and the loess mixture of the fuel control deterioration control equipment provided in the nuclear waste disposal apparatus for nuclear power generation including connection to the distribution equipment of the transportation equipment facility which constitutes the foundation of the manufacture and installation of the floating nuclear power plant A double structure storage tank constituting the fuel explosion prevention control article insertion storage and a double structure block tank dust collector connection structure provided as double structure storage tanks for nuclear operation of nuclear waste processing shielding apparatus are connected to a pump and valve generators As nuclear waste disposal control is performed sequentially by nuclear radiation leakage control, control of nuclear radiation leakage that efficiently improves the operation of nuclear reactors of multiple nuclear reactors by each nuclear power plant is provided inside the double structure block tank dust collector, and at the same time, , Safety operation before and after the nuclear power plant operation Alternative generation power production Nuclear power generation including hydroelectric power plant operation for wind turbine and thermal power plant to be installed in the tank. Nuclear power generation including dual-purpose block tank dust collector is a double pipe structure consisting of block piping line connection structure. The Nuclear Power Generation Facility is equipped with a nuclear power generation nuclear waste disposal unit, a nuclear power generation production unit, a traffic transportation unit of the construction machine that adjusts the position of the control shaft, and a power transmission unit that transmits power. The purpose of the present invention is to provide a reactor structure for a nuclear power plant for nuclear power generation, which has a double-structure high-speed multiprocessing reactor.

According to the present invention, the double-structure, high-speed multiprocessing reactor facility of a nuclear waste disposal nuclear power plant for nuclear power generation is installed in a nuclear power plant in order to secure free navigation of an aircraft and a ship, Nuclear Waste Treatment Nuclear Power Plant Facilities Dual Structure The high-speed nuclear reactor facility is designed to comply with the safety regulations established by the Ministry of Construction and Transportation of Korea in consideration of safety, fluidity and object life, In order to ensure the safe operation of the nuclear reactor facility from the strong wind wave, the reactor main body of the nuclear power plant is installed at the position of 40M below the sea level (SLL), and the nuclear waste treatment device Double Structure Block Tank Pipe Bridge Marine Tunnel Traffic Device Road This is to connect the equatorial line to the latitude of the Antarctic and North Pole in sequence. At the same time, for the safety of the reactor facility of the nuclear power plant, the bridge block tank bridges are installed in one place at intervals of 0.5km. Nuclear reactor facility at the upper part of the sea surface (SLL) Nuclear waste treatment facility Double structural block tank pipe bridge Marine tunnel At the middle of the connection position, the stationary floodgate is divided into power plant and emergency shelter located at the upper part of the deck (SDU) Nuclear waste disposal for nuclear power generation Dual structure of Nuclear power plant facilities Multipurpose high temperature gas reactor Power supply line to main body Nuclear waste treatment device Double structure Block tank pipe Bridge to marine tunnel traffic device After the re-establishment of power supply to each country, The nuclear facilities in the bovine reactor facility have been designed to appropriately dispose of all conventional warfare materials from nuclear bombs with the consent of all UN Security Council members. Nuclear power plants located in the vicinity of marine nuclear power plants equipped with power plant nuclear reactor facilities Nuclear power plants in the nuclear reactor plant to prevent war and terrorism Nuclear waste treatment connection structure as a double structure Block tank pipe bridge Marine tunnel transportation device The distribution and input device includes satellite and space rockets that are equipped with a satellite launch pad and a space rocket launch pad, and at the same time, it is equipped with a naturally occurring hurricane, earthquake, tsunami, To prevent damage, flood drought Preventive marine tunnel transport devices are equipped with subsea line injection nozzles and submarine line injection nozzles. Nuclear waste treatment double structure block tank The marine tunnel transport device distributes and feeds the production electric energy At the same time, the nuclear facilities of the nuclear reactor waste facilities of the marine vessel alternative transportation equipment that constitute the supply of the power of the feng shui power generator to the space energy production equipment, the deep sea mineral resource and the natural gas energy resource, Treatment dual structure block tank pipe bridge The connection structure of the marine tunnel traffic device is installed on the circumference surface of the existing reactor 4th wall containment vessel in preparation for the shutdown of the reactor facilities and before and after the explosion of the reactor facilities, Double Structure Block Tank Dust Collector to Maximize Explosion Prevention of Equipment In order to prevent natural disasters from being restricted by the weather conditions, the marine nuclear power plant barge is constructed to set up the installation position of the nuclear power plant at the upper 40m above the sea level. In the anchor and anchor chain of the mooring device, The reactor installation of the nuclear power plant, without being influenced by earthquakes and tsunamis by adjusting the position of the pump and valves in the regulating device by adjusting the docking weight, constituted the cessation of the reactor explosion by the double structure block tank dust collector. Prevention of environmental pollution and control of nuclear radiation leakage that does not cause reactor explosion in nuclear fuel chamber Double structure block tank Dust collector distribution device for reactor operation of nuclear power plant Nuclear waste treatment of nuclear power plant Shielding equipment Safety operation Pre- Long-term nuclear waste from the process Long-lasting half-life is long because it has to be stored for thousands of years. Permanent disposal of waste consists of a double tubular drum with nuclear waste transported to the buried area and a barge deck with space rockets and space rocket launchers The dual tubular structure containing the nuclear waste at the top of the deck was transported to the outer space with the space rocket while moving. The nuclear waste was fissioned from the reactor and converted into another material. Nuclear power plant which is equipped with an excavator to build up nuclear waste buried in polar glaciers and to construct a nuclear power plant consisting of interconnected structures that make deep burrows in strata or ocean. Nuclear waste treatment nuclear power foot There is another purpose to provide a reactor equipped with a novel non-proliferation of high-speed dual structure.

According to the present invention, the nuclear waste disposal nuclear power plant facility for nuclear power generation, which is provided in the construction design processes of the nuclear explosion prevention measures suitable for the double structure high-speed propagation reactor installation of nuclear waste disposal nuclear power plant facilities for land and ocean nuclear power plants The main body of the high speed propagation furnace reactor facility is designed to prevent collision with the height of 40m above sea level and to prevent the collision of the ship with high wind speed, The dual structure of the facility is designed considering the minimum height when refurbishing multi-purpose hot gas reactor facilities, and the ship's block tanks and the hulls at the bottom of the holding block tanks can also be used to control the deep water pressure Distribution control system of the reactor facility of the nuclear power plant Nuclear Power Plant for Nuclear Power Plant Nuclear Power Plant Equipment Dual Structure of High Speed Propagation Reactor Reactor Facility (Nuclear Power Plant) Nuclear Power Plant Reactor Facility Is designed to be rigidly supported up to the deck deck renovation period in addition to the lifetime of the fixed lifting and floating lifting weights and the effect of constructing the connection between land and various parts of the island inside the nuclear installation of the nuclear power plant Nuclear waste treatment of marine vessel alternate traffic facility equipment Dual structure block tank pipe bridge Distribution system of marine tunnel traffic system In order to be able to withstand the natural disasters of ocean composed of multiple reactor facilities of nuclear power plant in connecting structure exhaust Equivalent to dust collector of gas facility Nuclear waste and nuclear radioactivity pollutants from the exhaust gas outlet and the reactor inlet are installed in the double structure block piping lines located inside the double structure block tank. Temperature sensors in the safety valve Temperature sensors in the safety valve If the temperature inside the nuclear reactor is in the range of 700 to 800 degrees Celsius and the pressure reaches the danger level of high pressure, While simultaneously opening a plurality of pressure sensors for safety sensors, the explosive nuclear waste is passed through the inner block piping of the pressure vessel at each location, and nuclear waste is stored at each location of the block tank, Temperature pressure sensor connected to the inner block tank When the safety valve opens At the same time, as the outer block piping line, cooling water of the fuel explosion-proof control article stored in the inner block tank and yellow soil mixtures generating soap bubbles constitute conversion of the position energy of water into kinetic energy, If the vessel is filled with coolant and yellow soil mixture, the nuclear plant's main body of the reactor constitutes an explosion stop, while the reactor plant of the nuclear power plant is composed of a block-piping line connection structure of radiation type with a plurality of safety valve connection structures, And the nuclear radiation leakage control dual structural block tank dust collector of the reactor main body of the nuclear power plant is configured to transfer the nuclear fuel explosion prevention control articles to the storage to prepare the nuclear reactor radioactive pollutant Blocks and shields The nuclear reactor plant's nuclear reactor facility uses a shielding system of the defense concept of nuclear safety engineering, and at the same time, the reactor facility of the nuclear power plant is equipped with a double structure block tank dust collector to prevent the nuclear reactor explosion prevention and the nuclear fuel explosion prevention. Nuclear waste treatment is carried out inside the block tank dust collector and at the same time, the reactor facilities of the nuclear power plant are connected to the marine vessel alternative transportation facilities. Nuclear waste treatment structure consisting of the reactor main body of the nuclear power plant. Nuclear waste treatment of land and ocean nuclear power plants that efficiently controls nuclear waste treatment, as well as controlling nuclear waste disposal. Nuclear power plant nuclear reactors installed in dual structure block tank dust collectors are usually equipped with double pipe structure To establish a connection to the block piping Temperature Pressure Sensing Sensor The reactor facility of a nuclear power plant is usually equipped with a safety valve and water pumps, which uses a nuclear waste disposal device to convert the water energy potential energy into kinetic energy by mixing the cooling water and the loess mixture for soap bubbles. In the form of a tank egg, the connection structure composed of the outer wall of the former nuclear reactor building is composed of the reactor main body of the nuclear power plant. In view of the fact that the nuclear reactor main body of the nuclear power plant is formed, Dual Structure of Facilities There is another purpose of providing nuclear reactor facilities to the global land and ocean marine power plants by fast breeder reactors.

In order to accomplish the above object, the present invention as a technical idea is a nuclear power plant for nuclear power plant,

The above-mentioned nuclear power plant equipment includes nuclear reactor plant nuclear power plant (673) of a marine power plant (593,594,595) and nuclear reactor nuclear power plant facility for nuclear power plant, A nuclear power plant and a reactor facility having a dual structure block tank 598 for controlling reactor nuclear radiation leakage of a nuclear waste disposal screening apparatus and having a double structure block tank collector 794 of a nuclear waste nuclear waste treatment shielding apparatus, The operation of the nuclear power plants takes place on land and offshore of the world;

The nuclear waste disposal facility of the reactor plant of the nuclear power plant includes the mixture of the yellow waste mixed with the cooling water into the reactor core 681 inside the reactor and the reactor core 681 to the nuclear waste disposal treatment control product cooling water, The nuclear waste in the nuclear reactor main body 1 of the nuclear power plant is treated while the nuclear reactor is operated while the nuclear fuel in the nuclear fuel chamber is controlled while the inside of the reactor core 681 and the reactor core 681 are filled with the devices (593,594,595) Nuclear waste disposal of marine nuclear power plant (593,594,595) Nuclear waste disposal of dual structure block tank dust collector (794) constituting marine nuclear power plant Nuclear waste treatment Dual structure block tank pipe bridge Marine tunnel transport device (941) Constituting a reactor plant combination of a nuclear power plant having a dual structure block tank precipitator 794;

The double structure block tank arrangement of the nuclear waste disposal dual structure block tank scrubber 794 includes a disassemblyable inner block tank 596 and an outer block tank 599 having a double structure cylindrical connection structure, The dual structure block tank (794) facility of the nuclear power plant, while providing the dual structure block tank (598) as the processes, is coupled to the disaster prevention devices that control the nuclear radiation leak coupled to the reactor facility connection shafts, The nuclear waste treatment of the nuclear reactor facility is performed by the block tank dust collector 794;

The double structure block tank dust collector 794 includes a reactor structure of a nuclear power plant that provides the production control of a dual structure block tank dust collector 794 with connection structure construction machine cranes 861 that can be disassembled and coupled at a marine vessel manufacturing factory. A nuclear power plant 811 configured as an interior of the main body;

The nuclear reactor facility 811 includes a boiling water reactor 802, a pressurized water reactor 803, a gas cooling furnace reactor 804, and a multi-purpose high temperature gas reactor (810) consisting of the inside of the nuclear reactor facility main body of the nuclear power plant provided with the nuclear reactor power plant (805), the new conversion furnace reactor facility (806) and the fast propagating reactor reactor facility (838) 811a);

In the reactor facility in which the bed for regulating the nuclear waste capacity into the storage tanks of the nuclear power generation nuclear waste processing unit 811a is provided inside the reactor facility body 1 of the nuclear power plant, Nuclear reactors to prevent nuclear fuel explosion Nuclear reactors before and after breakdown Nuclear power plant replacement Alternative power generation Nuclear power plants including hydroelectric power generators including wind power generators and thermal power generators for wind power generators A power generation and production section 811b of the nuclear power generation facility unit 811 constituted;

The double structure block tank reactor 794 of the power production and production section 811b is provided with a plurality of inner block tanks 596 and a central structure block tank 589 at the center portion and aft end portions of the outer block tank 599, The crane boom 651 and the crane boom hook 652 and the conveyor 633 of the position movement control device construction machine crane 861 are opened to open and close the crane boom hook 792 and the conveyor 633, While at the same time the dual structure block tank 598 is used to construct a nuclear power plant 811 constructed inside the nuclear reactor main body of a nuclear power plant which provides transportation by means of a marine installation connection structure capable of disassembly and disassembly in the manufacture of industrial field launch dock sites. A transportation section 811c of the machine;

The transportation transport unit (811c) of the construction machine includes an adjustment shaft provided in the reactor main body (1) of the nuclear power plant to provide capacity adjustment to the storage tanks of the nuclear reactor nuclear waste disposal shield apparatus;

The control shaft is disassembled and coupled to the double-structure high-speed multiplying reactor main body 1 of the nuclear waste disposal nuclear power plant for nuclear power plants into the strut block tank 590 of the nuclear reactor main body 811 of the individual nuclear power plant The nuclear waste treatment dual structure block tank bridge pier 928 of the double structure block tank 598 with the power transmission portion 811d provided to the double structure block tank pipe bridge 591, (1) of a reactor plant of a nuclear power plant, a distribution shaft having a discharge shaft for distributing the waste to the storage tanks of the reactor facility manufacturing apparatus and the nuclear waste disposal shielding apparatus;

The distribution shaft includes a power transmission portion 811d provided with transformers for transmitting the power of the nuclear power plant 811 constituted inside the reactor facility main body of the nuclear power plant providing capacity to the storage tanks of the nuclear waste treatment shielding apparatus )Wow;

The power transmission unit 811d is provided with the same exhaust gas outlet as the dust collector of the exhaust gas facility which can withstand the natural disasters of the nuclear reactor main body 1 of the nuclear power plant before and after operation of the nuclear reactor safety facility (811e) of the nuclear power plant (811) consisting of the interior of the reactor facility of the nuclear power plant having the entrance,

The control facility 688C, the auxiliary building 688D and the diesel generator building 688E are connected to the reactor building 688A and the turbine building 688B of the nuclear power plant, Nuclear power plant buildings (688F), waste buildings (688G), and power plant buildings (688Z) with connection structures. Prevention of nuclear explosion Prevention of nuclear explosion Nuclear waste treatment Before and after nuclear power plants Nuclear power plants The electronically regulated control apparatus construction machine control unit 811f controls the crane boom 651 and the conveyor 633 of the locomotion control apparatus construction machine crane 861 while simultaneously providing an enormous amount of radiation- The operation of the carrier is separated into the electronic control devices and the operation of the carrier is controlled by the electric control device of the nuclear power plant 811 A self-regulating regulating device construction machine regulating section 811f;

The electronic control regulating device construction machine control unit 811f includes a control shaft for controlling the nuclear waste capacity to the storage tanks of the nuclear reactor nuclear waste disposal shield apparatus constituted inside the nuclear reactor facility main body 1 of the nuclear power plant (1) of the nuclear reactor plant main body (1) of the nuclear power plant to prevent the nuclear fuel explosion of the nuclear reactor main body (1) of the nuclear power plant in a safe and continuous manner. The barge hull (591) is equipped with a nuclear power plant production facility (811b) for nuclear power plant, while at the same time the barge hull (592) at the bottom of the dual structure holding tank is equipped with reactor facilities for a nuclear waste treatment nuclear power plant The screw adjusting portion 811g of the nuclear power generation facility unit 811 is connected to the holding tank 590 by the disassembly- The lug 607 and the lug connection shaft coupling bolt 603 are provided on the coupling lug pin connection shaft 606 and the position adjustment of the respective adjustment shafts is performed to the reactor installation main body 1 of the nuclear power plant A screw adjusting portion 811g of the nuclear power generation facility 811 provided inside the reactor main body 811;

The reactor installation for providing inserting on both sides of the forward and aft ends of the central portion of the double structure block tank dust collector 794 of the screw adjusting portion 811g includes a plurality of internal block tanks 596 of the dual structure block tank reactor dust collector 794 ) Nuclear power plant equipped with position shifting control by a carrier equipped with a crane boom hook 652 and a conveyor 633 on the crane boom 651 of the construction machine crane 861, Performing a nuclear power plant operation consisting of a nuclear waste disposal apparatus in a double structure block tank dust collector 794 provided with a safe and continuous nuclear radiation leakage control of a nuclear power generation facility 811 provided inside a reactor facility main body of a power plant;

The operation of the nuclear power plant is provided inside the nuclear reactor main body 1 of the nuclear power plant. However, it is also possible to freely control the amount of production power and to operate the nuclear power plant in preparation for natural disaster, The nuclear plant waste treatment tank tank 295 disposed at the upper end of the double structure block tank dust collector 794 is provided in order to supply the yellow loess mixtures to the water supply pump 241, The nuclear waste disposal reactor that provides the transfer to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 contains the yellow waste mixture mixed with the cooling water inside the reactor core 681 and inside the reactor core 681, Processing control products When the yellow waste mixture mixed with the cooling water is filled into the core (681) and the core (681) inside the reactor by the nuclear waste disposal apparatus, the nuclear fuel collision At the same time, the reactor facility maximizes the nuclear power generation production capacity of nuclear reactor facility (1) of land and ocean nuclear power plants, while preventing the explosion of nuclear reactors immediately, while preventing nuclear explosion by double structure block tank collector, The facility is equipped with nuclear waste treatment double structured block tank bridge bridge to prevent sinking of marine nuclear power plant and prevention of nuclear fuel explosion to be installed inside reactor main body (1) of marine nuclear power plant marine tunnel transportation device (941) The construction of the disassembled disaster prevention equipment and the connecting shaft of the construction machine to withstand the natural disasters of the nuclear power plant and the operation of the nuclear power plant before and after the renovation of the nuclear power plant The replacement of the wind power generator and the thermal power generator and the hydraulic power generator, Replacement power generation equipment and marine tunnel traffic equipment before and after the failure of reactor facilities (941) and marine (593,594,595) of a marine power plant constituting the nuclear power plant (672), and a construction machine including a disaster prevention apparatus and an earthquake- And a double structure block tank bridge 928 composed of a nuclear waste treatment dual structure strut block tank 590 and a dual structure block tank 598 of an individual reactor facility composed of the inside of a reactor facility main body 1 of a nuclear power plant Nuclear Radiation Leakage Control of Dual Bridge Block Tank Bridge (937) and Connection Shaft Double Structure Block Tank Dust Collector (794) and Double Structure Block Tank Bridge Bridge (937) Reactor Facilities of Nuclear Power Plant (672) The distribution shaft 705 of the nuclear waste processing pipe manufacturing process of the nuclear reactor main body 811 of the nuclear reactor main body of the nuclear power plant,

The double structure block tank 598 of the distribution shaft 705 includes an inner block tank 596 which provides a position to the center of the double structure block tank 598 and an inner block tank 596 which is located outside the inner block tank 596 (597) as a double structure with an outer block tank (599) Connected to cutting and welding processes at the industrial site by steel plate (597) The first auxiliary steel pipe 600 and the second auxiliary steel plates 601 for the block tank are connected to the distributing and loading device of the structural block tank pipe bridge 937 and are connected to the double structure block The large flange 614, which provides the connection structure for the connection shaft to the bow and stern connection position of the tank 598, is positioned as a connection structure at the connection location of the large flange connection joint connection area processing hole 615 of the large flange doing (625) of the distribution shaft (705) of the nuclear waste treatment pipe manufacturing process of the nuclear reactor plant main body of the nuclear power plant while providing the drill lathe and the cutter of the cutting tool to the flange (614) The double structure block tank 598 of the distribution shaft 705 of the pipe manufacturing process is made of the high-strength stainless steel steel plate 597 according to the manufacturing process according to the safe design, The nuclear waste treatment pipe manufacturing process of the nuclear reactor facility including the overhead crane 861 and the conveyor 633 which are fed into the transportation process with the double structure block tank 598 in accordance with the process order of the transportation, (597) of the high-strength stainless steel by the foroming and roll forming bending machine according to the thickness of the disc by a forom bending machine (a) and V-shaped bending (b)At the same time as the bending process is being performed, the stopper plate (625) of the distribution shaft (705) of the pipe manufacturing process is formed by a press braking type press braking type bending machine, a bending type roller bending machine, The overhead crane 861 and the conveyor 633 conveying body, which are fed into the conveying process while performing the bending and cutting process with the bending and cutting machine of the high-strength stainless steel steel sheet 597 by the bending roller bending machine, The welder, the cutting tool, the drill lathe, and the cutter can perform the welding process to the banding joint portion of the steel plate 597 of the high-tensile strength stainless steel, The tank 598 has a large flange 614 that provides a location for the connection of a large flange 614 that provides a location for the bow and stern connection, A stopper plate 625 is provided as a connection structure of the distribution shaft 705 of the pipe manufacturing process of the manufacturing and processing shelf process and is provided with an inner block tank 596 and an outer block tank 599 for providing a position outside the inner block tank 596 The inner block tank 596 completes the welding process while adjusting the positional movement to the overhead crane 861 and the conveyor 633 into the outer block tank 599 to form the double structure cylindrical shape The nuclear power plant is constructed such that the nuclear power plant is operated into a double structure block tank 598 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process of the nuclear power generation facility unit 811 into the reactor facility body of the nuclear power plant having the connection structure of the nuclear power plant;

The double structure block tank 598 constituting the operation of the nuclear power plant includes a plurality of outer block tanks 599, a first auxiliary shape steel for a block tank 600, The second auxiliary steel plate 600 for the block tank and the second auxiliary steel plate 601 for the block tank are provided with the second auxiliary steel plate 601, the vertical partition wall 605, the horizontal partition wall 609 and the steel beam 149, The vertical barriers 605, the horizontal barriers 609, the steel beams 149, the snap holes 602 and the barrier manholes 610 are cut by a computer laser cutter while simultaneously being welded A nuclear power plant 811 having a double structure block tank dust collector 794 inside the reactor facility main body 1 of the fifth protection wall nuclear power plant constructed along the outer wall circumferential surface of the fourth protective wall containment vessel 808 The nuclear reactor is operated with the double structure block tank 598 of the distribution shaft 705 of the nuclear waste processing tube manufacturing process, ;

The double structure block tank 598 constituting the nuclear power plant is provided with a communication device hydraulic cylinder door 624 and an emergency stairway and a step 631 in the vertical partition wall 605 and the horizontal partition wall 609 constituted by the partition wall manhole 610, ) Consists of a welding process and is equipped as a traffic device of a double structure block tank dust collector (794) to prevent explosion of a reactor, and a double structure block tank dust collector (794) A dual structure block tank (598) of a distribution shaft (705) of a nuclear waste processing pipe manufacturing process consisting of a nuclear power generation facility (811) inside the reactor facility body (1);

The plurality of stopper steel plates 625 constituting the operation of the nuclear power plant are formed by a bending type bending machine, a press braking type bending machine, a bending type roller bending machine and a three bending type roller bending machine, The bunging steel plate 625 is provided with a double structure block tank 598 having a cylinder type coupling structure egg type and constituted by a cap tight coupling assembly of the double structure block tank 598 while bending the steel plate 597 by bending and bending the bending plate, (598) The plurality of inner block tanks (596) and the plurality of outer block tanks (599) are individually welded to the upper and lower ends of the block tanks and the large flanges are assembled into a double structure block The tank 598 bolting assembly and the welding process assembly of the closure plate 625 can be assembled into a cap-tight fitting welding process assembly of a closure plate 625 without a large flange (811) inside the nuclear reactor main body (1) of the nuclear power plant and a nuclear assembly provided with the bolting coupling assembly, which are provided in the explosion-proof double structure block tank precipitator (794) The nuclear waste disposal control apparatus is divided into a waste disposal dispensing apparatus and a nuclear fuel explosion control apparatus, and a nuclear waste disposal unit 794 of the distribution shaft 705 of the nuclear waste disposal pipe manufacturing process is operated to operate the nuclear power plant;

The reactor facilities constituting the nuclear power plant operate in such a way that nuclear waste is stored in one place in a plurality of inner block tanks and a plurality of outer block tanks at the lower end of a vacant space of the outer block tanks, The reactor installation is comprised of a third wall of the reactor consisting of the interior of the inner block tank 596, which is fixed with reinforcing concrete mats 225 of thickness m and steel beams 149, The nuclear fuel is injected into the nuclear reactor, and the reactor is equipped with a distribution input device for nuclear waste disposal and a fuel injection control device for nuclear fuel explosion control to constitute the nuclear power generation and constitute the nuclear power generation facility 811 in the reactor main body 1 of the nuclear power plant The dual structure block tank precipitator 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process is constructed to operate the nuclear power plant;

In the reactor installation constituting the nuclear power plant, an enormous amount of radiation is generated inside the reactor installation, and the reactor installation includes a cladding tube 682 for safely protecting the first wall pellet 681 and the second wall fuel rod 689 The reactor building 688 portion of the reactor building 688 including the third wall reactor pressure vessel 813 and the fifth wall reinforcing concrete mat 225 in the fourth wall containment vessel 808 is divided into five A nuclear waste disposal and dispensing apparatus having a double structure block tank separator 794 constructed by replacing the nuclear waste disposal control apparatus with a protective wall, and nuclear fuel explosion control distribution dispensing apparatuses, ) To a dual structure block tank scrubber (794) of a distribution shaft (705) of a nuclear waste treatment line manufacturing process comprising:

The double structure barge ship hull 591 at the lower end of the holding tank of each control shaft is provided with a double structure block tank dust collector 794 for controlling the leakage of nuclear radiation into the SDM of the hull deck At the center of a plurality of inner block tanks 596, there are provided nuclear reactor facilities for nuclear waste disposal at each side of the bow and stern, The structure barge hull 591 is provided with the guide rails 618 installed on the left and right sides of the deck deck and the crane 861 having the capacity of 5000 ton on the guide rail 618 as the upper end portion SDU of the hull deck A nuclear waste disposal dispenser having a double structure block tank dust collector 794 constructed by replacing a 5-fold protective wall inside the barge hull with a nuclear fuel waste disposal unit and fuel explosion control At the same time as providing the moving installation of the dispensing and inputting apparatus, the nuclear waste disposal reactor facility is provided with a double hinged and triple hinged double-structure sliding hatch cover 153 at the safety place where the crane 861 for the renovation is installed, A nuclear waste disposal pipe (811) in the reactor main body (1) of the nuclear power plant, which is provided as a construction transportation transportation part for adjusting the position of the respective control shaft provided at one end of each control shaft, The dual structure block tank cleaner 794 of the distribution shaft 705 of the process;

The nuclear reactor facility constituting the operation of the nuclear power plant is composed of an exhaust gas outlet equivalent to a dust collector of an exhaust gas facility which can withstand the natural disasters of the ocean into the nuclear reactor facility main body 1 of the nuclear power plant before and after the operation of the nuclear power plant. The nuclear waste and nuclear radiation pollutants of the reactor facility having the inlet are connected to the double pipe block piping lines 74 for positioning the inside of the double structure block tank dust collector 794 to the nuclear waste locating passage And the nuclear radiation pollutants are detected by a plurality of temperature pressure sensing sensors. When the temperature sensor of the safety valve detects a temperature of 700 to 800 degrees in the inside of a nuclear reactor and a pressure of a high pressure reaches a dangerous level, At the same time that the sensing sensor transmits an alarm message to the computer in the safety control room, At the same time as the pressure sensing sensor and the safety valve are opened, the nuclear reactor waste is passed through the pressure vessel internal block piping line 74a at each location, and the nuclear waste is stored in each location of the block tank, ) At the same time that the temperature pressure sensing sensor safety valve 472 connected to the lower inner block tank is opened and the outer block piping line 74b of the nuclear reactor facility is provided with the fuel explosion prevention control article stored in the inner block tank, A thermocouple thermometer sensor switch 103 having a connection structure with a pressure gauge 101 and a temperature sensing bimetal 102, a flow rate check operation level pressure switch 104 and a flow rate check flow meter 105, And a safety valve 472 of a piping line automatic pneumatic valve conveying device 916 to form a plurality of through holes at an angle of 45 ° at an upper end of the reactor building 688 At the same time that the through-hole processing is provided by the low-cutter, the construction machine and the drill machine, the reactor facility constitutes a double-pipe structure block pipe line 74 in the plurality of through holes, and the plurality of safety valves 472 are connected to the block pipe line 74 and a bolt 24 and a nut 25 with a flange connecting connection by a gasket 32 and a double structure block having a diameter twice the diameter of the reactor building 688 along the outer wall surface of the reactor building 688. [ A tank 598 is provided at one location with an outer block tank 599 for storing nuclear waste treatment and a radiation type connection structure to provide a distribution input device for nuclear waste disposal and a distribution input device for nuclear fuel explosion control. It consists of nuclear reactor core (681) and nuclear reactor core (681), which are equipped with nuclear fuel explosion prevention control goods just before reactor explosion, Waste site The dual structure block tank collector 794 of the distribution shaft 705 of the reboiler manufacturing process is configured to operate as a nuclear power plant;

The reactor facility constituting the nuclear power plant is connected to a steam generator 810 and a steam dryer 786 installed outside the pressure vessel 813 of the double structure block tank dust collector 794, A plurality of inner block tanks 596 and a plurality of outer block tanks 599 are connected to a nuclear fuel assembly (not shown) separately in the nuclear reactor installation of the containment vessel 808 corresponding to the fourth wall and the double structure block tank precipitator 794 corresponding to the fifth wall. Explosion-control control article cooling water 287 and soap which are supplied to a pressure vessel 813 such as a furnace immediately before a reactor large-scale explosion are provided with a loess soil 158 and a cement mixing equipment mixer machine 649, The control device is charged into the pressure vessel 813 at a time by an automatic injection device at a time, and a plurality of fire-fighting nozzle nozzles 10, which are cleaned in the reactor installation after the occurrence of the earthquake, A fuel injection control device for controlling the fuel explosion control device inside the power container 813 and inside the containment container 808 and performing the cleaning process automatically inside the reactor facility without inputting human and robot, (811), which is equipped with nuclear waste disposal and disposal apparatuses for nuclear waste disposal and recycling facilities inside and outside the nuclear reactor facility, and the nuclear power generation facility (811) inside the nuclear reactor facility main body The dual structure block tank collector 794 of the distribution shaft 705 of the tube manufacturing process is configured to operate as a nuclear power plant;

The internal cleaning of the nuclear reactor constituting the nuclear power plant is performed by cleaning the inside of the nuclear waste disposal pipe manufacturing process distribution shaft 705 double structure block tank dust collector 794 through the cooling water inlet of the distribution input unit cooling water pipe line of the fuel explosion control 352 and the cooling water 287 that prevents the yellow loam mixture from solidifying is mixed with the yellow loam mixture by a mixer machine 649 to produce a soap bubble in the pressure vessel 813). After the earthquake has stopped, the internal water pump (242) immediately cleans the inside of the reactor to prepare continuous nuclear power generation without restraint from natural disasters and maximize the safety operation of the nuclear reactor facility To the distribution input device of the nuclear waste disposal with the reactor explosion preventive double structure block tank dust collector 794, The dual structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process consisting of nuclear power generation equipment part 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the land and marine nuclear power plants, To operate;

The nuclear power generation facility 811 of the reactor nuclear reactor facility includes a plurality of dual nuclear fuel reactors 810 for storing the nuclear nuclear waste 224 connecting the outer walls of the nuclear reactor building wall from the first wall to the fifth wall, The nuclear power plant 811, which is formed at a stage before and after the operation of the nuclear power plant of the nuclear power plant constituted by a plurality of nuclear reactors and a coupling connection structure inside the nuclear power plant including the structural block tank reactor accumulator 794, A steam turbine 267 generating nuclear fission in the reactor and generating steam by the heat to produce power by rotating the steam turbine 267 and a nuclear power generator 772 for converting the power produced from the steam turbine 267, And a rotary rotor for a nuclear power generator installed along the circumference of a rotary shaft 198 connecting the steam turbine 267 and the nuclear power generator 772. [ Rotating armature coil 773 for a nuclear power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for the nuclear power generator and a nuclear power generator 772 connected to the steam turbine 267, And a frame 775 that integrally fixes the rotating shaft 198 to the nuclear power generation facility 811 in the reactor main body 1 of the nuclear power plant on land and in the ocean The dual structure block tank cleaner 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process being constructed;

The nuclear power generation facility 811 of the reactor facility of the nuclear power plant operates the cooling water inlet 352 of the cooling water piping line having a connection structure with the condenser 790 at the lower part of the body of the steam turbine 267 of the nuclear power generation facility unit 811 And a circulation water pump 242 connected to a cooling water inlet 352 of a cooling water piping line to a piping line 169 at a watertight path in front of the condenser 790 to connect the reactor main body of the nuclear power plant 1) the nuclear power generation facility unit 811 inside the nuclear power plant, and the dual structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process;

The nuclear power generation facility 811 of the reactor facility of the nuclear power plant operates a water supply pump 241 at the rear of the condenser 790 and outside the reactor facility and a purifier 809 is installed outside the reactor at the front of the water supply pump 241 And a plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 storing the enriched uranium 812 fuel in the reactor internal piping line in front of the purifier 809, A safety device control rod 798 is installed in the inside of the reactor control rod 813 to automatically insert the control rod 798 at a time to automatically stop the operation of the nuclear reactor and to operate the nuclear reactor of the nuclear power plant A double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility 811 in the main body 1, And;

The nuclear power generation facility 811 of the nuclear reactor facility of the nuclear power plant operates the first wall pellet 683 of the nuclear reactor reactor facility and the cladding pipes 682 protecting the second wall foul rod 689, A collision of the cladding pipe 682 is generated by the first wall containment vessel 808 and the safety valves 472 in which the plurality of temperature pressure sensing sensors are formed in the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 are opened, Exploded nuclear waste 224 passes through the inner block piping 74a of each block piping line 74 at the upper end of the vessel 813 and the outer block piping 74b passes through the inner block piping 74a The explosion-proof control article cooling water 287 and the yellow loess mixture 927 for soap bubbles are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241 and the double structure block tank 598 ) With respect to the internal lower end positions of the respective portions, the nuclear waste 224 is moved and stored The reactor pressure control valve 472 connected to the internal block tank 596 of the pressure vessel 813 is opened and at the same time the reactor installation of the nuclear power plant is connected to the inner block piping 74b of the block piping line 74, The nuclear fuel explosion-proof control article cooling water and the loess mixture 158 stored in the block tank 596 are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 857, The cooling water and the loess mixture 927 for the soap bubble are supplied to the cooling water 287 and the cooling water 287 stored in the inner block tank 596 and the outer block tank 599, respectively, When the inside of the reactor facility is filled with the mixture of the loess mixture for the soap bubble (927), the explosion of the nuclear reactor facility is terminated, and at the same time, the nuclear reactor facility of the nuclear reactor operation is equipped with the nuclear reactor substitute input apparatuses, The nuclear reactor plant is operated with the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process consisting of the nuclear power generation facility 811 inside the reactor facility body 1 of the power plant ;

The nuclear power generation facility 811 of the reactor facility of the nuclear power plant is provided with a remote control cutting or submarine mineral collection robot 912 for disassembling the reactor facility of the nuclear power plant operating the nuclear power plant, When the internal explosion stops, a plurality of the reactor pressure relief valves 472 are closed and a plurality of the reactor pressure relief valves 472 are normally closed at the time of operation of the reactor facility. (591) of the nuclear power plant. A number of reactor facilities are installed in the anti-sinking type barge of the ocean, and are installed in the reactor main body (1) of the nuclear power plant on land and in the ocean Of the nuclear power plant 811 of the nuclear power plant, the double structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process, Configuration be made of copper and;

The nuclear power plant 811 of the reactor facility of the nuclear power plant of the nuclear power plant is provided with a position for installing the nuclear power plant 811 at the top of the sea level of 40 m so as not to be restricted by the weather conditions of the earthquake and tsunami, The equipment and the diving buoyancy control devices are used to regulate the position of the nuclear power plant so that the nuclear power plant can be operated so that a plurality of nuclear reactors of the nuclear power plants not affected by the earthquake and tsunami can not explode, The power generation facility unit 811 includes a dual structure block tank dust collector 794 for controlling the nuclear radiation leakage so as to prevent explosion of the nuclear reactor facility in the nuclear fuel chamber that prevents environmental pollution due to nuclear waste, (593,594,595), which is a marine power station that allows safe and continuous operation of nuclear power plants, (1) the nuclear power generation facility (811) inside the main nuclear power plant of the land and ocean nuclear power plants, while ensuring the safety of the power generation facilities and ensuring the renovation of the reactor facilities by continuous operation. A dual structure block tank (794) of a distribution shaft (705) configured to operate the nuclear plant at the nuclear power plant before and after the operation of the nuclear plant

The nuclear power generation facility 811 of the reactor facility of the nuclear power plant of the nuclear power plant includes a mooring device constructed on the barge by nuclear waste disposal, a diving buoyancy control device, a nuclear waste disposal dispensing device, and a nuclear fuel explosion control dispensing device, A dual structure block tank that controls the nuclear radiation leak that prevents the nuclear reactor facility from exploding inside and outside the nuclear fuel chamber to prevent the environment from being contaminated by the waste. The reactor of the nuclear power plant (672) It is equipped with a mooring device, a diving buoyancy control device, a distribution and input device for nuclear waste treatment, and nuclear reactor facilities installed in a nuclear power plant (672) (1) of nuclear power plants of land and sea nuclear power plants of nuclear power plants of nuclear power plants The unit 811 includes a dual structural block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process so as to operate the nuclear power plant. The nuclear power plant of the nuclear power plant operates. And nuclear waste disposal marine tunnel transportation equipment (941) Construction machine with location control by disaster prevention device and carrier, and wind turbine, thermal power generator and hydraulic power generator to be put into production and production of alternative power generation electric power plant (593,594,595) Nuclear power plants (672) and nuclear reactor plant main body (1) Nuclear power generation plant (811) double structure block tank dust collectors of nuclear power plants of nuclear facilities The connection shaft of the process tube manufacturing process (705) The preparation for the diving process constituting the nuclear power plant equipment The distribution tank for the operation control control and the holding tank of the nuclear power plant facility And the bottom of the barge hull (591 592), the distribution chute to provide a nuclear power plant equipment for atomic power nuclear waste processing unit (811a) to the connection structure for each connection,

The distribution input device of the nuclear power generation nuclear waste processing unit 811a is connected to the submarine line injection nozzle 593,594,595 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant, (593,594,595) of the submerged marine power plant with a connection structure with a subsea line connection structure. (591) A holding block tank (591) provided at the lower part of the center of the holding tank, A column block tank 590 for providing a position as a connecting structure at the center of the lower tank barge 592 of the lower tank barrel 590 and a plurality of column block tanks 590 for providing a position as a connection structure around the center of the barge hulls 591, 590 are connected to the upper and lower ends of the support block tank 590 of the connection shaft of the upper portion of the strut tank upper barge hull 591, A plurality of processing holes 615 and a block unit double structure block tank hull disassembly unit 607 are provided in the body of the double structure block tank combined portable lug 607. However, The lug elongated holes 616a for the position movement control device are connected to the screw shaft 603a and the lug connection shaft coupling 603a of the connection tank shaft 606 and the lug connection shaft coupling bolt 603, The nut screw thread 603b of the splitting nut 603 and the block tank hull disassembly coupling portable lug 607 and the block tank coupling portable lug fins 608 are connected to the float control port 593,594,595 of the anti- (619), a mooring unit and a floating bed (616) connection structure for a hull balancing hull balancer, there is a floating structure of a marine power plant (593,594,595) (593,594,595) Nuclear power plant (672) of submarine power plant and submarine line injection nozzle nozzle connection to submarine line main body (1) of nuclear power plant At the same time, (593,594,595) nuclear power plant (672) of a submerged offshore power plant (673) and a nuclear reactor plant main body of a nuclear power plant 1) Nuclear power plant nuclear waste disposal screening facility with internal protection Two-tiered block tank to provide leakage of nuclear radiation from nuclear reactor facilities. Nuclear power plant equipment (811) Nuclear power generation nuclear waste treatment unit (811a);

A double structure block tank coupling lug 607 for providing a connection structure to a nuclear power generation nuclear waste treatment section 811a of a nuclear power plant 672 of a marine power plant's floating power plant 593,594,595 and a nuclear power plant 811 of a nuclear power plant, ),

(593, 594, 595) nuclear power plants 672 of the nuclear power generation nuclear waste processing unit 811a are installed at the respective portions of the upper barge hull 591 and the holding tank lower barge hull 592 of the holding tank 590 in horizontal and vertical forms A double structure block tank provided with a coupling structure and having a plurality of processing holes 615 and an elongated hole 616a formed in the body and having a horizontal pin connection shaft hole 615 and a vertical pin connection shaft 615, Holes 615 and a long hole 616a are formed in the upper portion of the strut tank 590 so as to be perpendicular to the connecting portion of the strut block tank 590 and the upper end barge hull 591 and the lower end barge hull 592 of the strut tank 590, The connection shafts 606 bound to the plurality of the processing holes 615 among the plurality of connection shafts 606 coupled to the plurality of processing holes 615 provided at the respective portions in the shape of the connecting shafts 606 are removed, The connection structure is provided with the coupling of the nuclear power plant 672, The double structure strut block tank (590) facility is equipped with a connection structure distributing and inputting device capable of disassembling and disassembling the nuclear power plant (672) by pre-distributing the sink prevention rescue line (634) Assembled nuclear power plant (672), and the lower part of the center of each vertical strut block tank (590) is provided with connection structure by excavation equipment and mooring devices, and is provided as a connection structure The vertical holding block tanks 590 are provided in the vertical holding block tanks 590 and the position adjustment switching is provided in the vertical holding block tanks 590 in the auxiliary adjusting block connecting structure resisting lines 634. Alternatively, The throttling control device of the power plant (672) is provided with a pre-sinking prevention line (634) prepared for the submergence proceeding at the lower end of the sea level (SLD) (1) Double structural block for nuclear radiation leakage control of reactor facilities of nuclear waste treatment shielding system with connection structure with protection (1) Excavation equipment and mooring equipment provided on the anti-sinking rescue ship (634) (593,594,595) nuclear power plant (672) of a marine power plant and nuclear reactor facility main body of nuclear power plant (1) nuclear waste treatment section (811a) of nuclear power generation facility section (811) (811a) distribution equipment, drilling rigs and mooring devices to make the reactor plant operate;

(593,594,595) nuclear power plant (672) of the nuclear power plant of the nuclear waste disposal unit (811a) and the nuclear reactor main body (1) of the nuclear power plant. The rotary table lathe machine 908)

The nuclear reactor waste disposal unit of the nuclear waste disposal unit 811a comprises a nuclear reactor facility main body 1 and a distribution input unit of the nuclear reactor nuclear reactor operation unit comprises a floating harvesting plant of a submergence preventing marine power plant which is located at the sea level upper end SLU of the sea level SLL The rotary table lathe machine 908 of the drilling machine for drilling crude oil in the drill machine room of the hull deck upper part (SDU) is located at the upper end of the drill machine room when the crude oil is connected to the plurality of pipe racks 854 The pipe rack 854 in the state ready for excavation preparation is provided with the boom of the crane boom of the overhead crane 651 and the boom hook connection of the crude oil bound to the boom hook 652 and the connection structure of the wire rope 19, And a plurality of pipe racks 854 provided as connection structures of the sea level lower end SLD of the sea level SLL. The core drill 917 is provided with a drilling hole 936 as an excavator rotation body At the same time, the core drill (917) Which is mounted on each of the strut block tank upper barge hulls provided as a connection structure at the position of the hydraulic cylinder machine 624 and the key bed 616 at the position of the excavation hole 936 provided at the connection structure, (593,594,595) of the non-sinking marine power plant, and the crude oil and natural gas discharged from the location of the crude oil borehole (936) in the nuclear power plant facility. (SDU) upper part of the hull deck upper part (SDU) equipped with a submarine line wiring as a subsidiary connecting structure, or a connection structure is provided at the upper end of the lower part of the block pylon 15 of the nuclear power plant facility The ceiling crane 651 is provided with a linking structure inside the machine room of the drilling machine located at the lower end of the overhead crane 651, The table-table lathe machine 908 is provided with several hydraulic cylinder keys 623 for drilling, which are located at positions opposite to the circular table line with the rotating body of the rotary table lathe machine 908 body, The rotary table lathe machine 908 of the drilling machine for crude oil is brought to the position opposite to the center line position in the line, The rotary table lathing machine 908 continues to bind the pipe racks 854 to the central position with the rotor connection structure, A plurality of pipe racks 854 provided at a point of a crude oil borehole 936 located at a connecting structure, A nuclear borehole 936 is provided with a core drill 917 for rotating a drilling hole 935 of a crude oil borehole 936 equipped with a nuclear waste treatment facility 911 and a nuclear waste treatment facility 916 composed of a reactor facility body 1 of a nuclear waste treatment unit 811a The distribution dispenser of the nuclear power plant is provided with a pipe rack 854 for crude oil when crude oil is connected to the wire rope 65 of the ceiling crane 651, Machine tools turning (908) Blocks for the drilling of a bit of body Rotary table of units with hydraulic rotary cylinder machine (619) for dismounting coupling adjusters Hydraulic cylinders for drills A rotary table lathe machine (9) of a crude drilling machine for drilling crude oil with a feed arrangement with a feed arrangement to the top of a rotary table lathe machine (908) of a crude drilling machine 08) operation, the crude oil and natural gas discharged from the position of the crude oil borehole 936 are simultaneously moved to both sides of the boom and boom hook 652 of the crane boom of the tower crane 886 while terminating the excavation of the crude oil bore hole 936 The boom of the crane boom of the tower crane 886 and the boom hook 652 of the tower crane 886 are vertically rotated to provide the deep sea energy resources to the top of the deck deck. At the same time, The distribution dispenser that constitutes the waste disposal system is to transfer crude oil and natural gas discharged from the crude oil borehole (936) inside the nuclear power plant facility to the inside of the nuclear power plant from the crude oil borehole (936) Nuclear power plant is operated as a connection structure between crude oil and natural gas to be discharged. The crude oil and natural gas crude oil borehole distribution system, which is positioned as a connection structure at the location of the crude oil borehole (936) in the interior, is connected to the oil well borehole (936) Nuclear waste landfill is set up at a deep sea basin borehole (936), and nuclear power plant facilities (593,594,595) installed at coastal marine power stations are equipped with safe mooring facilities by means of mooring devices and diving buoyancy control devices At the same time, a crude oil borehole 936 is provided as a nuclear waste incineration treatment core drill 917 into the nuclear reactor facility main body 1 of the nuclear power plant, and at the same time, the nuclear facility operation body 1 of the nuclear waste treatment unit 811a is operated ;

The distribution input apparatus constituting the sinking restraining line 634 as a connection structure of the nuclear power plant facility of the marine power plant of the nuclear waste disposal unit 811a,

The nuclear power plant equipment of the nuclear waste processing unit 811a operates the hydraulic cylinder apparatus 39 by connecting the anchor replacement crankshaft 846 connected to the construction machine to the core drill 917 drilling hole 936 as a connection structure The wrench crank 846 is pushed into the excavation hole 936 and the wrench crank 846 compresses and expands inside the excavation hole 936 to form a crevice tool 185) are fixed to the ground by means of a connection structure, and at the same time, the guide bar (185) fixes the lower end portions of the respective holding tanks so that the barge line is prevented from drifting, Prevention; and

(593,594,595) of the marine power plant (593,594,595) Stacked tank top barge with mooring device of nuclear power plant equipment Construction machine mounted on the hull Barge to locate the connection structure Hull equipped with anti-drift anchor replacement crank (846) Mooring device (593,594,595) of the nuclear power plant (673) and the distribution of the diving buoyancy control device and nuclear waste disposal in the nuclear power plant (672) of the marine power plant. The reactor of the nuclear waste disposal unit 811a at the marine vessel manufacturing factory is connected to the nuclear waste disposal pipe manufacturing process 705 of the reactor facility at the Fusi Nuclear Power Plant 811 before the safe operation of the reactor apparatus and the reactor apparatus. As well as a connection structure capable of disassembling and coupling the nuclear power plant facilities. In other words, (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear power generation plant (811) Dual structure block tank The dust collector is connected to the connection axis position of nuclear waste treatment pipe manufacturing process (705) And the nuclear waste disposal input device of the nuclear waste disposal unit 811a of the nuclear waste disposal unit 811a,

The nuclear waste disposal and dispensing apparatus of the nuclear waste disposal unit 811a is a connection structure of a floating nuclear power plant 593,594,595 nuclear power plant 672 of a submergence preventing marine power plant and a nuclear power plant main body 1 of a nuclear power plant, The large flange 614, which provides the location of the nuclear waste disposal dispenser with a connection structure with submarine line injection nozzles and subsea line interconnection structure of the connection, is connected to the connection distribution dispenser connection structure of the double structure block tank 598 The connecting structure for constructing a double structure block tank 598 and a landing block tank 590 as a link structure for constructing an equator (EL) on the Earth's south pole (SP) and the north pole (NP) The double structure block tanks 598 are provided in the form of a double structure block tank barge line, and at the same time, the distribution input device of the double structure block tank barge line is provided with the pre-sinking retention line 634, (593,594,595) Nuclear power plant facilities to provide the whole connection of nuclear power plant facilities. Nuclear waste treatment at intervals of 500m. Double structure block tank pipe bridge (929) Connected (937) body structure at the same time as constructing a double structure block tank pipe bridge pier (928) in order to construct a connection structure, and at the same time, the distribution input device of the nuclear power plant equipment is submerged in the deep sea The double structure block tank pipe bridge pier 928 is installed at a location where the double structure block tank pipe bridge pier 928 is installed, At the same time as installing the flagpole rubber balloon (628), the distribution and input device of the nuclear power plant equipments are provided with direction indication and depth depth recognition notation A mounting position of the double structure block tank pipe bridge 928 which hangs the wire rope 915, the diving position adjusting movement device of the hull and the diverting buoyancy weight 949 is provided at the lower end of the flagpole rubber balloon 628 And transferring the individual double structure block tank pipe bridge 928 to the same sink prevention resident lines 634 as the floating control pipes 593,594 and 595 of the marine power generation plant while towing the double structure block tank bridge bridge 928 with the tug line 636, Distributed structure inside a reactor plant main body (1) of a nuclear power plant, and a large structure flange (614) for joining a double structure block tank with a connection structure having a submarine line wiring line connection structure (946) to the injection nozzle of a nozzle nozzle connection distribution (593,594,595) Mooring equipment of a nuclear power plant (593,594,595) Nuclear power plant (672) and atomic power plant's atomic power plant Equipment unit (1) configured to be made of nuclear waste processing plant reactor to the distribution chute of a nuclear power seolbibu 811 nuclear waste processing section (811a), and;

A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation section (811c) of a construction machine for establishing a connection with a nuclear waste disposal section (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.

The distribution input device of the reactor construction equipment of the nuclear power plant equipment is provided with the transfer of the nuclear power plant equipment to the sink prevention resident line (634), or after the transfer of the nuclear power plant equipment, the water depth of the installation point is 300 meters , The pile column is increased by 50 meters more than the water depth and attached to the seesaw crane boom base 942 of the tower crane for the position-control mobile device, the pile 898 is vertically erected and the excavator for the deep- 845), a rock drill (847), a perforator (876), a hatcher and an anti-erection machine (877) 880 includes a file driver 882, a diesel file hammer 883, a steam hammer 884, a hydraulic crane 885, a tower crane 886, a crawler crane 887, a truck crane 888, 889 and the tandem roller 890, The tamping rollers 891 and the tire rollers 892 and the tractors 893 and the trailers 894 are installed in the distributing and inputting apparatuses of the nuclear power plant construction machinery and the distribution tubes of the respective nuclear power plant construction machinery, The apparatus includes a system for distributing a nuclear power plant construction machine with a ram 895 and a lid 896, a coolant cooler 897, a helmet 899, a fuel pump 900, a cam 901 and a fuel tank 902 908 and the adapter 906 of the starter 903 which is provided as a device and simultaneously provides a base of a plurality of double structure block tank pipe bridge 928 as a connecting structure on the sea floor (929) of nuclear waste treatment double structure block tank bridge (929) and prepare double structure block tanks of 10 double structural blocks to the installation position of double structure block tank pipe pier (928) of each place Or to connect one set of the above double structure block tank The double structure block tank bridge pier (928) exposed at the upper sea level of sea surface is provided with a mooring structure, and a dual structure block tank is connected to the rope to moor and at the same time, an actuator 848 is operated in the construction machine cab (593,594,595) Protection of nuclear power plant facilities by mooring system and nuclear reactor plant main body of nuclear power plant (1) Nuclear power generation facility (811) Nuclear waste treatment section (811) (593,594,595) Nuclear power plant equipment of a marine power plant as a distribution input device of a nuclear reactor construction equipment that consists of a nuclear waste disposal dispensing device as a transportation transportation part (811c) of a construction machine providing connection with a nuclear power plant ;

A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation section (811c) of a construction machine for establishing a connection with a nuclear waste disposal section (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.

The distribution and input device of the nuclear plant construction equipment of the nuclear power plant equipment is composed of a nuclear waste processing double structure block tank bridge 929 Is provided by moving the holding block tank 590 to a depth of 500m 3 of the double structure block tank at the depth of the sea level SLL to provide movement and at the same time providing the double structure block tank bridge 929 The connecting structure anchor 639 and the anchor chain 640 provided at the crane boom portion 942 of the crane substituting tower crane are provided on the seabed. At the same time, the crane boom portion 942 is wound around the rotary body tumbler winch 958, 958 to provide a distributing and inputting device for a nuclear reactor construction machine that releases the anchor 639 and the wire rope chain 915, and at the same time, as a connection structure inside the reactor installation body 1 of the nuclear power plant, (593,594,595) of mooring prevention marine power plant with mooring devices are installed in the main body of nuclear power plant (1) Nuclear power generation facilities (811) Nuclear waste disposal and dispensing apparatus composed of a nuclear waste disposal and dispensing apparatus as a transportation transport unit (811c) of a construction machine providing connection with a nuclear waste disposal unit (811a). Constitute nuclear plant facilities;

A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation section (811c) of a construction machine for establishing a connection with a nuclear waste disposal section (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.

The distribution input device for connecting the nuclear waste treatment dual structure block tank bridge 929 constituting the nuclear power plant facility to the nuclear power plant facility and the reactor facility construction machine is a device for connecting the nuclear power plant, (959), which is repeated while being wound around a rotary hook-and-loop winch (958) and loosened with a hook-and-loop winch (958) to release the anchor chain (640). At the same time, The supply sail 959 is connected to the double structure block tank 598 at the side of the nuclear waste treatment double structure block tank bridge 929 at the sea surface by a combined operation process (929) of the double-structure block tank bridge (929) connected to the Nuclear Waste Disposal at the same time while providing a provisional passage for the ship as a connection structure. Water Treatment Double Structure Block Tank Tube Bridge (929) Double Tank Block Tank Bridge (929) Double Structure Block Tank (598) Connection Location The double structure block tank connection portion may be provided as a connection structure at a predetermined distance between the even number of connection portions and the odd number of connection portions out of the outer block tank 599 to the double structure block tank, (1) Nuclear waste disposal in-house Double structure block tank bridge (929) Combined connection structure as a mooring device Vessel vessel temporary pathway Reactor facility Providing the dispensing devices of the construction machine, It is a connection structure with an internal connection structure. It is a connection structure having a submarine line wiring connection structure to the injection nozzle of the injection nozzle connection port. (593,594,595) of mooring prevention structures (593,594,595) of mooring preventive offshore power plant by mooring devices to the nuclear reactor plant main body (1) Nuclear power generation facility (811) Nuclear waste treatment section (811a) (811c) is a connection structure of equipment for providing protection of the distribution input device of a nuclear reactor construction equipment comprising nuclear waste disposal dispenser;

A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation section (811c) of a construction machine for establishing a connection with a nuclear waste disposal section (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.

The distribution input device for connecting the nuclear waste treatment dual structure block tank bridge (929) constituting the nuclear power plant facility and the nuclear reactor plant construction equipment to the nuclear power plant facility and the nuclear reactor plant construction equipment is the same as that of the above-mentioned floating nuclear power plant equipment (593,594,595) The partitioning and injecting apparatus for pipe bridge cracking and dismounting with a connecting structure is provided with a pivoting mechanism for pivoting a pivoting lug 21 at a portion abutting against a peg lug 21 provided as a joint detachment hinge 27 at an outer position of the outer block tank 599 A double structure block tank having a hinge binding for a hinge a-shaped lug pin connecting shaft 27a and a hinge long axis connecting shaft 27b is connected to a double structure block tank connecting portion at a predetermined distance interval position (1) as a connection structure inside the reactor facility of a nuclear power plant with a spray nozzle of a nozzle nozzle connection and a connection structure with a submarine line wiring connection structure. (593,594,595) Nuclear Power Plant Reactor Facility Provided by Mooring Devices of Nuclear Power Plant Facilities (1) Nuclear Power Generation Facilities (811) Establishment of connection with nuclear waste treatment section (811a) (811c) a nuclear waste disposal and dispensing apparatus, a distributing and dispensing apparatus for a nuclear reactor construction machine is provided, and a lock-unlocking device is hung from a horizontal outer wall position;

The distributing and inputting apparatus of the nuclear reactor construction machine is provided with the handle lever 935 welded to each other while vertically rotating to arrange the connection portions of the double structure block tank at the respective positions, ) And the ground (22) are provided with a double structure block tank disassembly coupling structure and at the same time a block unit double structure block tank hinge disassembling lug hinge socket (613) (593,594,595) Internal connection structure of the nuclear power plant Equipment injection nozzle of the nozzle connection and subsea line wiring (946) Double structure block provided with connection structure Double block tank pipe bridge (937) Combined distribution input (593,594,595) Mooring equipment of nuclear power plants Mooring equipment of marine power plants (593,594,595) Combined decomposition of nuclear power plant facilities with double structure block tank connection position Fixed lifting equipments of marine power plant with provision of double structure block tank disassembly with locking device (185) and ground device (22) Dock (593,594,595) Nuclear power plant facilities were installed with the distribution and input devices of the reactor facilities of the nuclear power plant, and the mooring device, diving buoyancy control device and nuclear waste disposal processing installed in the ocean power plant floating plant (593,594,595) nuclear power plant (672) Included as a connection structure that can be disassembled and coupled at the marine shipbuilding factory with the connection shaft of the nuclear waste processing pipe manufacturing process (705) of the reactor facility at Hsinchu Nuclear Power Plant (811) before the safe operation of the reactor and the reactor equipment of the reactor facility (593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and nuclear power plants The dual structure block tank dust collector of the nuclear power generation facility 811 of the nuclear power plant 1 is provided with a plurality of generators for the nuclear waste treatment and power generation of the nuclear reactor facility, The distribution input device of the electric power production and production section 811b, which constitutes the nuclear power plant operation,

The distribution and input device of the power generation and production section 811b is a connection structure of the nuclear power plant main body 1 and includes a plurality of generator distribution input devices for generating the ocean power station's 593,594,595 power generators including 593,594,595 ) Nuclear power plant (672) and connection structure inside nuclear reactor plant main body (1) of atomic power plant Injection nozzle connection Submarine line wiring (946) Nuclear waste treatment double structure block providing connection structure with connection structure Bridge pipe bridge (593,594,595) Nuclear power plant (672) facilities are provided with a linkage arrangement control device (593, 594, 595), a connection control device (929) Dependent deck decks constructed as a structure Decks connected to each other in the marine power plant in each location Double structure block tank Decks Decks are double-structured in the form of a nuclear explosion- (593,594,595) Nuclear power plant (672) facilities of marine power plant of nuclear power plant of nuclear reactor power plant (677), marine wind power plant (957) and marine seesaw An atomic power generator 772 provided outside the hydroelectric power plant 943 outside the double structure block tank dust collector 794 for controlling the leakage of the nuclear radiation for the eco-friendly wind power generator 957a and the deck deck interior, and a large hydroelectric generator A connection structure provided with a fixed connection structure and provided with connections to respective line distribution shafts and provided with transformers for transmitting the power of the nuclear power plant 811 to each distribution shaft in the reactor main body 1 of the nuclear power plant, The nuclear waste disposal facility having the transfer unit 811d and the connection structure having the connection structure of the submarine line injection nozzle and the submarine line wiring 946 into the reactor main body 1 of the nuclear power plant (929) Combined distribution input device The connection structure of a marine power plant which is provided as a connection structure of a plurality of marine power generation facilities and a distribution input device of a floating marine mooring device. The power generation and production unit 811b of the nuclear power generation facility 811 including the nuclear power plant 672 of the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant is installed in the reactor facility (811b) which comprises a plurality of generators for nuclear waste disposal and power generation and constitutes a connection shaft reactor facility, and is configured to operate the nuclear power plant with a nuclear power plant;

A plurality of power generating and manufacturing units 811b of the nuclear power generation facility 811 of the nuclear power plant 671 of the offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant, (593,594,595) of the marine power plant. The marine seisio hydropower plant (943), which is a substitute for the power generation and power generation, is prepared for the repair of the nuclear power plant equipment. A large hydropower generator (944) as a connection structure, which constitutes a plurality of power plant nuclear power plants,

The distribution input apparatus constituting the operation of the nuclear power plant 944 of the large hydroelectric generator 943 of the marine seesaw hydropower plant 94 provided for the power generation and power generation in preparation for the retrofit of the nuclear power plant facility of the distribution and dispensing apparatus, The large hydrostatic generator body of the marine seesaw hydroelectric power plant 943 is connected to a head tank 189 for a pressure tank located at the upper end of the barge line and an inlet of cooling water for the inlet pipe 191 in front of the head tank 189, 35) An introduction pipe 191 having a water pressure pipe shape is connected to the head tank 189 and has a plurality of introduction pipes 191 at the upper end of the marine sheath hydroelectric power plant 943 and the discharge port at the rear of the head tank 189 The pump aberration 943a of the turbine 267 and the Pelton aberration 943b of the turbine 267 to the lower portion of the body of each large hydrostatic generator Seisoh hydroelectric power plant 944 that provide a position in the interior of the marine seesaw hydroelectric power plant 943, 943c ) And the discharge port (270) at the rear of the water supply port (269), and at the same time, the hydro-electric power generation distribution input device in the ocean is equipped with the flow velocity of the current, The inlet pipe 191 in the form of a hydraulic pipe riser 35, which provides a flow rate conversion with mechanical energy, is vertically rotated by a large hydrostatic generator shear facility 944 having a sheath center shaft frame 673 that provides mechanical energy conversion (593,594,595) nuclear power plant (672) of a marine power plant and a nuclear power plant (672) of a marine power plant having a seesaw crane boom stand (942) of a tower crane that performs an operation, A large hydropower generator distribution and charging device is provided inside the reactor facility main body 1 of the nuclear reactor facility 1 so that the nuclear reactor operation of the reactor facility is further performed;

The large hydraulic power generator seesaw facility 944 that constitutes further operation of the nuclear reactor of the nuclear reactor includes a hydrodynamic power generator rotational speed detector 944a for providing a position at the top of the central portion of the rotational shaft 944q, An exciter 944b for DC generator which supplies current to the motor field coil of the alternator providing a position at the lower end of the rotational speed detector 944a for use, a drag ring pipe 944c for pushing the ring pilot feather, A stator frame 944g and a center stator 944h and a rotary bearing 944i and a braking device 944j of the low speed cooler and a braking device 944j for braking The jack 944k of the apparatus and the low-speed rotary shaft 944l are positioned at the upper end of the central portion of the rotary shaft 944q while the large hydrostatic generator seesaw facility 944 is connected to the rotary shaft 944q, turbine( The power generation assembly is provided with the turbine rotation bearing 944n, the casing 944o, the guide vane and the impeller 944q and the flow velocity of the current to the inside of the hydroelectric power generating room, The large hydrostatic generator seesaw facility 944 provides a mechanical energy conversion to the inlet pipe 191 having the shape of the hydraulic pipe of the hydraulic pressure reducer 35 and the center shaft frame 673 of the sheathing equipment 944 A large hydroelectric generator seiside facility 944 having a multi-stage entrainment type manomoon form, and a seesaw crane boom zone 942 of a tower crane for performing a vertical rotation operation, thereby further providing devices for generating electrical energy, (593,594,595) of a marine power plant with a connection structure of the power generation facility to produce a large hydropower distributor / dispenser installed inside the nuclear power plant facility to make the nuclear power plant more operational And;

The power generation and production unit 811b of the nuclear power generation facility 811 constituted by the nuclear power plant 672 of the marine power plant of the land and sea and the nuclear power plant main body 1 of the nuclear power plant, The dust collector is provided with a plurality of generators for nuclear waste disposal and power generation of the nuclear reactor facility and transformers for transmitting the power between the electric power production and manufacture section 811b and the nuclear power generation facility section 811 constituting the nuclear power plant operation of the connection axis reactor facility The distribution input device of the power transmission portion 811d,

The power generation and production section 811b and the power distribution section 811d of the large hydroelectric generator seeside facility 944 constituting the nuclear reactor operation of the nuclear reactor further comprise a reactor installation main body 1 of the nuclear power plant, Deck deck reactor installation of marine nuclear power plant as an internal connection structure When the double structure block tank collector (794) is operated, the power generation capacity is increased to 1,000,000 w / h at intervals of 10 km, and a large hydropower distributor input device is provided The distributing and inputting device of the electric power producing and producing section 811b is a connection structure provided in each of the marine power generating stations with a large hydroelectric generator seesaw facility 944 and an environmentally friendly wind power generator windmill 957a, The transformer 96 of the power transmission line 775 is connected to the power transmission line 775 and the power transmission tower 776 is provided with a predetermined amount of power generation power, The generators provided in the water are designed to provide a certain amount of water to the connection process of the large flange 614 of the nuclear waste treatment double structure block tank bridge 929, which is located at the lower end of the nuclear power plant facility of the floating plant (593,594,595) It is also possible to equip the generator with the supply of power generation equipment as the connection structure of the distributing and inputting device, to simultaneously perform the bolting work process with the hammer and the wrench of the hand tool, or to control the generator power of the nuclear power plant, (593,594,595) nuclear power plant (672) of a marine power plant, each of which provides coupling of a chain block (648) and a turnbuckle (850) The submarine line injection nozzle to the structure is connected to the injection nozzle of the nozzle connection and the submarine line wiring (946), and the double structure block tank bridge bridge (929) The input device has a seesaw crane boom zone 942 of a tower crane that provides for performing a vertical rotation operation to a large hydroelectric generator seeside facility 944 having a multi-stage entrainment type man- (593,594,595) of the marine power plant with connection structure of power generation facility that provides power to the nuclear power plants. The large hydropower distributing and input device is installed inside the nuclear power plant facilities to further operate nuclear power plants;

The power generation and production section 811b of the nuclear power generation facility section 811 constituted by the nuclear power plant 672 of the marine power plant of the land and ocean and the nuclear power plant 671 of the nuclear power plant, A connecting shaft provided with a plurality of generators for processing and generating nuclear waste in a nuclear reactor facility;

The distribution input device of the power generation and production section 811b constituting the operation of the nuclear reactor of the nuclear reactor is a connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant, The dispensing device comprises:

A reactor building is provided with a vertical partition wall 605, a horizontal partition wall 609, a partition wall manhole 610, a manhole cover 152 and a hatch cover 153 in the double structure block tank of the nuclear reactor facility, The hydraulic cylinder door 624 is provided as a connecting structure in the double structure block tank 598 and the distribution block connecting structure lever block 123 and the chain block 648 and the turnbuckles 850 are provided in the double structure block tank 598 (593,594,595) of the marine power plant, the height of the nuclear waste treatment double structure block tank bridge (929) is calculated as the height of the pipe bridge (593,594,595) in nuclear power plant (593,594,595) Nuclear power plant (672) inside the reactor main body (1) of the nuclear power plant which provides the double structure block tanks to be combined with each other by 1.5 times the width of the nuclear power plant (929) chapter And a connection axis of the nuclear waste processing pipe manufacturing process 705 of the nuclear plant waste disposal processing apparatus and the nuclear plant construction unit 701 of the reactor facility from the Fuze nuclear power generation facility unit 811 before the reactor facility safety operation of the reactor facility, And a power transmission unit 811d provided with transformers for transmitting power to the power generating and manufacturing unit 811b of the power generating unit 811. In other words, (593,594,595) Nuclear Power Plant (672) and Nuclear Power Plant Reactor Facility (1) Nuclear Power Plant (811) Electronic Control Control Equipment Construction Control Equipment (811f) Disaster Prevention Equipment A distribution dispensing apparatus for a connection shaft disaster prevention control device for constituting a distribution dispensing apparatus for a device in a block steel tower,

(593, 594, 595) of the marine power plant as a connecting shaft connection structure of the nuclear power plant equipment. The disaster input device for the disaster prevention device and the lifting device and the production equipment device includes the marine (593,594,595) Nuclear power plant and Nuclear Power Plant Reactor facilities inside the main body (1) Submarine line injection nozzle connection Submarine railway line (946) and upper part of the sea surface (SDU The upper end of the holding tank upper barge hull 591 has a processing hole 615 for providing the connection of the equilateral hexagons 839 to the center upper end SDU of the upper deck deck, 25 and washer 26 provide connection of equilateral inclined ramps 839 with spanner hand tools, but the connecting shaft of the nuclear power plant equipment is connected to a seesaw crane The block unit block steel towers 116 provided with the respective connection structures by inserting the blocks 942 are inserted into the lug processing holes 20 of the block unit block steel towers 116 to be engaged with the shackles 23 of the position adjusting and moving device At the same time, the nuclear power plant equipment is provided with a block unit block steel tower 116 by assembling transportation to a seesaw crane boom zone 942 of a tower crane, An emergency staircase 631 is provided in the emergency stairway 116 and an emergency stairway 631 is provided as a traffic device and an emergency stairway 631 provided at the stair of the block pylon 116 is connected to the lower steam airliner 589) to the location of the bollard 638 of the mooring platform and to the center of the lower end of the lower part of the steam jet ship 589 to the position of the ceiling crane 651 and the elevator allybeat 632 And the holding tank top As the positions of four deck decks of the ground hull 591, there are provided a block unit boom with a connection structure of 500m units, and a plurality of seesaw crane boom units 942 of the crane provided at the bottom of the sea, (593,594,595) Nuclear power plants Nuclear power plants Nuclear power plant facilities with connection structure (2) Nuclear waste treatment facilities to provide submarine line wiring (946) Double structure block tank bridge (929 ) Combined Dispenser Input Unit The block unit block of the equipment provided as a connection structure to protect the mooring operation by the connecting structure is equipped with the emergency stairway (631) (593,594,595) Nuclear power plants Nuclear waste treatment facilities (1) Nuclear waste treatment Double structure Block tank pipe bridge (929) Coupling distribution Injection device Connecting shaft connection structure Floating stand (811) Electronic control equipment construction machinery control unit (811f) Dispensing equipment for disaster control equipment, lifting equipment and production facility equipment Dispensing equipment for disaster control equipment consisting of a block tower To constitute the facilities of nuclear power plants;

(593,594,595) of the above-mentioned marine power plant (593,594,595) Nuclear power generation unit constituting a block steel tower as a connecting shaft connection structure of a nuclear power plant facility (811) Electronic control adjusting apparatus construction machine control unit (811f)

The nuclear power plant 811 constituting the connecting shaft connection structure of the nuclear power plant equipment for providing the disaster prevention water supply to the upper end block top steel tower 116 at the upper end of the mooring tower 644, the electronic control equipment construction machine control unit 811f, The distributing and inputting device for the control device is a high pressure type multi-stage disaster prevention pump (8) for providing a nuclear power plant disaster prevention control device as a connecting structure at the upper end of the deck deck of the holding tank upper barge hull (591) When the main switch button 66 for the start switch button of the main switch button 8 of the main switch button 8 is manually depressed to the on-time main switch button 66, The multistage multi-stage disaster prevention pump 8 is connected to the double structure disaster prevention hose 9 and the disaster prevention water 7 by a connection structure structure Providing the fire emergency disaster prevention can double structure tube nozzle 10 is 7, and release, or connecting shaft of the nuclear power plant equipment; and

Electronic control device The dispensing device for the disaster control device of the construction machine control part (811f) is composed of a fire prevention disposal double structure nozzle (10) for mounting transportation equipment and a fire prevention disaster double structure Connection between pipe nozzle and water pipe connection Fixed fire fighting emergency pipe with double structure pipe Connection line of nozzle (10) Wire rope (19) and connection device Shackle (23) A connection line wire rope 19 for protecting the disaster prevention duplex pipe nozzle 10 from the lower end of the basket 42 on which the pile at the bottom of the lower end of the airship 78 and the radio sonde 134 is mounted, A disaster prevention device is provided with connection structures of connection shafts connected to the inside of the double structure disaster hose (9), and a disassembly device for disaster prevention control devices of the connection axis electronic control adjustment device construction machine control part (811f) of the nuclear power plant equipment The device production facilities are provided with a high performance submersible pump 36 and an air compressor 80 to provide a combination of a disaster control device with a top connection structure of a floating deck deck, Dispensing device for disaster control device of control unit 811f The production facility equipment is a connection structure having a connection structure of submarine line wiring 946 into the reactor main body 1 of a nuclear power plant, Block tank pipe bridge (929) Coupling distribution input device The connection block for the flood control device provided by the flood control device or the plant equipment for protection of floodproofing disaster prevention device. (593,594,595) nuclear power plant of the marine power plant and the nuclear reactor main body (1) of the nuclear power plant as the connection structure of the line distributing and inputting device, (929) Nuclear power plant (811) Electronic control equipment Construction machinery control unit (811f) Disaster prevention equipment and lifting equipment provided with connection structure to be protected by disaster prevention device and production facility equipment And a distributing and inputting device for a joint shaft disaster control device constituting a distribution input device for a production equipment device as a block steel tower as a connection structure capable of disassembling and coupling at a marine ship manufacturing factory. (593,594,595) Nuclear power plants and nuclear reactors of nuclear power plants (1) Nuclear power generation facilities (811) Electronic control systems Construction machinery control systems (811f) Discharging systems and lifting systems and distribution systems The disruption control distribution dispensing apparatus of the connecting shaft constituting the block tower,

The disaster control pump control system and the control system 150 constituted by the connection structure of the nuclear power plant facilities and the electronic control distribution dispatching apparatus of the fire fighting disaster prevention machine room are equipped with the internal control system of the nuclear plant of the marine power plant (593,594,595) Submarine line injection Nozzle connection Submarine line wiring (946) Dependent sounding deck which provides position by connection structure Disaster prevention pump on top of deck High-pressure multi-stage emergency protection pump (8) The multi-stage pump control panel control box (2) has a fire prevention electronic control device for controlling the electronic control facility of the nuclear power plant equipment. The control box (2) (3), discharge joint pipe (4), pump internal isolation valve high-pressure shut-off valve (5) and pump internal check-back check valve (6) And a fixing frame 11 for fixing the position of the fire suppression pipe nozzle 10 and the multi-stage multi-stage fire prevention pump 8, (12) for the electronic control device for detecting a fire, and a fire-control emergency electronic control device for the nuclear power plant, the electronic control device connection structure of the nuclear power plant includes a control box A power supply unit 62, an inverter 47 for an electronic control unit, an inverter VCO 48, an access pointer 49 and an internet network 50 A rechargeable battery 37 having a connection structure with a short range wireless communication antenna 54 and a wireless communication control module 55 of a short range wireless communication device is provided inside the monitor 52 and the control board 53 of the internal control server 51, The mobile terminal 81 and the portable terminal 82 are connected to each other by a connection structure, The fire fighting and disinfecting electronic control devices of the nuclear power plant equipment are connected to the display 56 and the electronic control unit ADIC 57 and the electronic control unit MCU 59 of the switch input circuit 58 A main switch button 66 for a start switch button and an auxiliary switch button 66 for providing a position to the electronic circuit connection structure between the DAC 60 and the analog input 64 of the display screen 63 and the digital input 65, 67, a display input computer network input 68 and a recognition name plate 69 of a pressure setting value which is a set pressure value of the current pressure value, a memory 70 and a connection structure of the power supply power supply line 71 The power source 46 of the fire-fighting electronic control unit of the nuclear power plant equipment is provided with the power source 46 to the electronic control devices of the fire-fighting disaster machine room, and the flood control unit 593, 594, 595 of the marine power plant, nuclear power Nuclear power plant and nuclear power plant Nuclear power plant Nuclear waste treatment facility to connect inside structure (1) Subsea line wiring (946) to connect structure Nuclear waste treatment double structure block tank pipe bridge (929) Combined distribution input device Equipment to be provided as a connection structure to protect production equipment and electronic control unit of fire fighting and disaster prevention machine room of nuclear power plant equipment. Electronic control device connection structure Maintenance of ocean power plant (593,594,595) Nuclear power plant (1) of a nuclear power plant and an electronic control device line distribution and input devices of a fire fighting and disaster prevention operation room, a nuclear power generation facility (811), an electronic control adjusting device construction machine control device (811f), a disaster prevention device and a lifting device Disassembly and dispensing equipment for production facility equipment is connected to a block tower. Disassembly control Dispensing and disposing equipment Reactor facilities of nuclear power plants To constitute the operation of nuclear power plants;

The fire fighting and disinfecting control distribution dispensing apparatus composed of the connecting shaft connection structure of the nuclear power generation facility 811 of the reactor facility main body of the nuclear power plant, the electronic control regulating apparatus construction machine control unit 811f,

The fire fighting and disinfection control distribution dispensing apparatus is a connection structure inside the reactor main body 1 of a nuclear power plant of a marine power plant (593,594,595) of a marine power plant, and is connected to a piping 89 having an electronic control device of a fire fighting disaster prevention operation room, The connection structure of the piping 89 is connected to the safety valve 258 of the piping 89 by the safety valve 258, the low pressure shut-off valve 83 for the electronic control unit, the emergency valve 84 and the relief valve 85 of the reducing valve 85 And the rubber packing 32 of the gasket for piping connection and connection is connected to the bolt 24, the nut 25 and the washer 26 at the gap 15, The first pressure check sensor 86, the second pressure check sensor 87, the electronic control unit 88 and the bypass pipe line 89 for piping connection of the collecting tank 34 are connected to each other A connecting structure having a connection structure with a dozer 35 and a tee elbow 44 of an elbow with piping connection is provided inside the piping 89, The main switch button 66 for the start switch button of the connection shaft multi-stage disaster prevention pump 8 of the electronic control regulating apparatus construction machine control section 811f and the disaster prevention water spraying (593,594,595) of a marine power plant, or a connection structure of a nuclear power plant having a submarine line wiring (946) as a connection structure inside the reactor main body (1) of a nuclear power plant. (929) Combined distribution injecting device Flotation control device and production facility Equipment to be equipped with a connection structure to protect devices Electronic control device of fire fighting and dismantling machine room (593, 594, 595) nuclear power plant of the marine power plant and the nuclear reactor facility main body (1) of the nuclear power plant as connection structures of the line distribution input apparatus, (811) Electronically controlled regulator (811f) Discharging device and lifting device for lifting device and production facility device Connection shaft for constructing block steel tower Distribution input device Configured to operate the reactor plant of the nuclear power plant;

(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution input device for the production facility apparatus (593,594,595) Fire fighting and disaster control device The distribution dispatching device of the operation of the nuclear power plant facilities,

The distribution dispenser for operating the nuclear power plant equipment comprises a detour line 35 for connection of piping connection of the connection structure water collecting tank 34 having a connection structure to the forefront of the multi-stage disaster prevention pump 8 of the fire fighting disaster prevention operation room, Piping connection There is connection structure with tee elbow (44) of attached elbow, but disaster prevention water (7) of fire prevention disaster prevention control goods is stored in piping (89) of connection structure of nuclear power plant facilities, The on-time main switch button 66 of the main switch button 66 for the start-up switch button of the emergency disaster prevention control article 7 of the multistage disaster prevention pump 8 of the control article and the high pressure multi- The operation of the pump can be provided by pushing it in by hand, or by pushing it manually at the position of the off-time main switch button 66 of the main switch button 66, High-pressure type multi-stage disaster prevention pump (8) (33) is a connection structure helicopter (647) having a connection structure with a high-performance submersible pump (36) for piping connection connection. The hooks for the electronic control device 13) and the connection structure of the nuclear power plant having the connection structure of the coupling is the disaster prevention water (7) having the internal water pressure of the double structure fire hose (9) Is pressed by hand at the position of the on-time main switch button 66 of the main switch button 66 for the start switch button of the high-pressure multi-stage emergency protection pump 8 before and after the operation of the high-pressure multi- (3) and a discharge joint pipe (4) for electronic control and an internal high-pressure shut-off valve (5) of an isolation valve pump are connected to a connection structure provided in the body of the high- Pump inside The disaster prevention water 7 having the water pressure inside the connection structure of the nuclear power plant equipment is supplied to the fire suppression double structure pipe nozzle 9 through the pipe And a nuclear waste treatment double structure block tank which provides a position having a submarine line wiring 946 as an internal connection structure of a fire fighting and disaster control apparatus facility as a connection shaft connection structure of a nuclear reactor facility main body 1 of a nuclear power plant Pipe bridge (929) Coupling dispenser Input device It is equipped with equipment to provide connection structure to protect the disaster prevention device and production facility equipment. It is equipped with electronic control device line dispensing input device of fire prevention disaster prevention machine room. (593,594,595) nuclear power plant and nuclear reactor plant main body (1) of a marine power plant with connection structure with water pressure, Electronic control equipment of machine room Electronic distribution system of line control equipment (811) Electronic control equipment of line control equipment (811f) Dispatching device for dismantling device and production equipment device Shaft Disaster Control Distribution Discharging Equipment Nuclear power plants are constructed to operate nuclear reactors;

(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution input device for the production facility apparatus (593,594,595) Fire fighting and disaster control device The distribution dispatching device of the operation of the nuclear power plant facilities,

The disaster prevention water supply apparatus 7 having the water pressure is moved through the piping to the position of the fire disaster prevention double structure pipe nozzle 10 so that the fire disaster prevention double structure pipe nozzle 10 The exhaust gas is discharged to the outside of the body of the fire-fighting disaster prevention double-structure pipe nozzle 10 in the processing clearance 15 for a plurality of position-adjusting and moving apparatuses for providing a position with the water- At the same time, the discharge jetting number 38 of the fire-fighting and disinfecting control article and the disaster prevention water 7 of the curtain water film 39 of the fire-fighting disaster control article are arranged at the positions of the plurality of processing holes 20, Discharge jetting is provided in the form of a radiation film discharge jet 38 (water film curtain 39) at the positions of the plurality of processing holes 20 and the clearance 15 of the plurality of processing holes 20. However, And the combustion effect is prevented by preventing the combustion and the combustion (593,594,595) nuclear power plant of the marine power plant and the nuclear reactor main body (1) of the nuclear power plant as the connecting structures having the water pressure of the connection structure of the nuclear power plant facilities, Electronic control equipment of disaster prevention machine room Nuclear power generation equipment with line distribution input devices (811) Electronic control equipment Dispatching device and lifting device of construction machine control part (811f) Dispatch control Dispenser Discharging device Nuclear power plant's nuclear reactor plant is constructed to operate as a nuclear power plant;

(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution and input device of the production facility apparatus. (593,594,595) Fire fighting and disaster control device The operation and distribution dispatching device of the nuclear power plant facilities,

The distribution dispenser for operation of the nuclear power plant equipment is a fire extinguishing control fire extinguisher control device that allows early evolution to occur within 1 second. The discharge nozzles 38 are provided as connection structure disaster prevention water 7 of the curtain water film 39 of the firefighting and disaster control product. The discharge jetting water 38 is provided at the positions of the plurality of processing holes 20, At the position of the jetting number 38 and the gap 15 of the plurality of processing holes 20, the discharge jetting number 38 of the radiation type provides ejection falling jetting in the form of a water film curtain 39, The disaster prevention is fire prevention by the smokestack action which surrounds the combustible with the incombustible gas and stops the supply of air to prevent the combustion and the cooling action to reduce the combustible to the ignition point temperature. By The fire prevention disaster prevention water of the nuclear power plant equipping the fire hose body with the connection structure is mixed with the fire prevention disaster control water cooling water 287 and the air hose 109 for storing the non-combustible gas 164 having the water pressure, The portable wireless communication terminal 82 of the high pressure multi-stage multi-stage disaster prevention pump control system 150 in the disaster prevention pump operation machine room and the safety control room and the disaster prevention pump control system 150 in the safety control room are provided as a connection structure for providing the mixed disaster prevention water, A main switch button 66 for operation control and a connection structure for providing a disaster-free water spraying reactor;

Dispensing Pump Auxiliary switch button (67) The power supply control box is distributed to the safety control room and the disaster control pump operating machinery room. The coupling connection pipe (29) for piping connection is connected to the coupling body It is equipped with threaded body (31) connection structure, dual fire extinguisher (40) and helicopter (647) are equipped with mixed fire water and loess soil (158) (593,594,595) of a marine power plant by arranging a structural coupling to provide a connection structure having a disconnection nozzle 945 by an underground line into the reactor main body 1 of a nuclear power plant and a submarine line wiring 946 as a connection structure Nuclear waste treatment Double structure Block tank bridge (929) Equipments to provide connection structure to protect production equipment equipment by equipped with joint distribution dispenser and flood control system The emergency stairs 631 of the traffic device of the block unit block steel tower 116 may be provided as a line distribution input device and the line distribution and input device connecting structures may be connected to the inside of the reactor facility main body 1 of the nuclear power plant, (593,594,595) of the marine power station, the mooring device, the diving buoyancy control device, the distribution and input device of the nuclear waste disposal, and the nuclear reactor facility safety operation of the nuclear reactor facility (811 ) Nuclear waste treatment plant manufacturing process at nuclear facility (705) Connection of nuclear reactor plant at nuclear power plant Disconnection device, lifting device and production facility of shaft construction machine control section (811f) Connection shaft constituting distribution dispensing device Flood of marine power plant (593,594,595) Nuclear power plants Nuclear reactors Main unit (1) Connection shaft connection structure Fire fighting and disaster control equipment Nuclear power plant Facilities for operation and distribution of input and output devices (593,594,595) nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants, and the reactor main body of the nuclear power plant (1) The nuclear power plant of the nuclear power plant The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant facility 811 operates the nuclear power plant facility that constitutes the connection axis position of the nuclear waste treatment pipe production process 705 of the reactor facility The nuclear waste disposal dispensing apparatus comprises:

The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure of a nuclear power plant, and it is provided as a nuclear waste disposal unit (811a) of a nuclear power plant for distribution and installation of facility protection facilities. The reactor installation main body 1 of the floating installation type nuclear power plant, which is located at the sea level upper end portion SLU of the sea surface SLL that provides the position with the connection structure submarine line wiring 946 to the inside of the facility main body 1, , A buoyant deck deck upper central connection structure, and a block-type bulkhead block tower (116) for positioning the inside of the reactor installation main body (1) of the buoyant nuclear power plant at the upper left corner of the upper deck deck center It has a safety control room that provides a position as a connection structure. However, many countries with nuclear weapons have nuclear power generation Nuclear Waste Dispensing and Discharging Device Consisting of Bovine Nuclear Reactor Facility The nuclear waste disposal and dispensing device equipped with the satellite launching platform and the space launch device for the nuclear waste disposal device equipped with the satellite and the space rocket, Preventing flood drought control Preventing the flood Prevention of floods Preventing the damage of volcanic ash before and after tsunami, forest fire, dust and volcanic eruption Preventive weather control to control flood forecasting Observing weather forecasting facility (958) A helicopter stop 619 is provided in the peripheral equipment of the block steel tower 116 of the nuclear waste disposal and dispensing apparatus to provide a position as a connection structure in the vicinity of the upper center of the deck deck, The satellite 962, the satellite launch pad 643, and the space rocket 961 of the space rocket 961, A nuclear power station is installed at the top of the deck deck in the vicinity of the satellite launching platform 643 and the space rocket launching platform 646 as a nuclear launching platform 643 and a space rocket launching platform 646, The connection structure inside the reactor main body (1) of the power plant is provided with a connection structure having a submarine line wiring (946). The upper part of the deck deck is provided with a natural loess (158) A connection structure provided at the top of a deck deck to prevent the harmful tidal microorganism 921 from breeding Natural sooty loess 158 of powdered soot mixed with the water for control of control of fire control is provided at the upper end of the floating deck deck In order to prevent the harmful tidal microorganisms (921) from propagating in the seabed, the undersea position is located in the inside of the yard basket (951) of the harmful rust- And the harmful tidal microorganisms 921 are stored in the harmful tidal sediment collector. The natural loess soil 158 is supplied to the inside of the greenhouse basket 951 and the harmful tidal microorganisms The natural loess soil 158 is supplied to the seabed at the bottom position of the bottom of the floating deck deck body 921. However, A winch 137 and a seesaw crane boom girder 942 and a wire rope 19 and a wire rope chain 915 of a tow crane replacement tower crane are connected to a drive wheel roller 135 for a position- While the natural loess soil 158 is fed to the seabed, the moving device tuna winch 137 and the seesaw crane boom table 942 of the tower crane substitute for crates are moved to perform the position adjustment movement while simultaneously controlling the air compressor 80 and the air In the hose 109, the net-shaped air hose 109 is filled with oxygen (593,594,595) of the marine power plant by providing a fire control control goods arrangement that protects the marine environment and protects the marine environment. The submarine line wiring (596,594,595) Nuclear plants (1) Nuclear plants (1) Nuclear plants (1) Nuclear plants (1) Nuclear plants (2) Nuclear plants The nuclear waste disposal unit 811a of the nuclear power generation facility unit 811 of the nuclear power generation facility unit 811 is connected to the connection shaft position of the nuclear waste disposal pipe manufacturing process 705 of the reactor facility The nuclear waste disposal for operation of the nuclear power plant equipment constituting the nuclear power plant is operated by the distribution and input devices;

The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant unit 811 of the nuclear power plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant of the above- Nuclear waste treatment plant of nuclear reactor waste treatment plant tank dust collector (705) Crude oil and natural gas crude oil drilling equipment crude oil drilling equipment (934) constituting the connection axis position of reactor manufacturing process (945) ,

The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure inside the nuclear reactor main body 1 of a nuclear power plant of a marine power plant (593,594,595) of a marine power plant. The upper end of the marine deck hull deck (SDU The crude oil drilling rig 934 for providing a position as a connection structure to the upper center portion is provided at a lower end of a ceiling crane 651 which is located at the upper end of the lower end inside the block steel tower 116 of the nuclear power plant facility, Drilling machine Rotary table lathe machine (908) Drilling machine for drilling machine of nuclear power plant equipment with a connection structure inside the machinery room, or a nuclear plant. Circular table with rotating body of the body. And the hydraulic cylinder actuating key 623 controls the movement of the plurality of actuating keys 623 in the opposite-to- The nuclear waste disposal and dispensing apparatus of the nuclear power plant equipment may be provided with a rotary table lathe machine 908 and a rotary table lathe machine 908. [ And a plurality of piping racks (853) are connected to the pipeline racks (854) at a central position by a connecting structure connected to the pipeline by a position movement control device. A plurality of pipe racks 854 arranged at the position of the crude oil borehole 936 provided at the location of the crude oil borehole 936. The crude oil borehole 936 equipped with the connection structure for positioning the crude oil at the crude oil pipe connection structure 917 ), The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is provided with a ceiling crane 65 1 and the pipe rope 854 for connecting the drill bar to the wire rope 19 are provided with a hydraulic rotary cylinder (not shown) for drilling the rotary drum of the rotary table lathe machine 908 of the drilling machine for crude oil at the drilling machine room 619) with a plurality of hydraulic cylinders 623 for drilling to provide a position as a connection structure in the opposite direction to the circular table table, or with a transfer arrangement to the top of the rotary table lathe machine 908 of the drilling machine, The operation of the input device is performed to terminate the excavation of the crude oil bore hole 936 and to simultaneously deliver the crude oil and natural gas discharged from the oil borehole 936 to both sides of the seesaw crane boom zone 942 of the tow- The seismic crane boom zone (942) of the tower crane replacing the above-mentioned crane was installed as a connection structure to provide a waste disposal site. (593,594,595) of the marine power plant by providing a lift to the top of deck deck. The distribution of crude oil and natural gas oil borehole that provides the connection structure with the submarine line wiring (964) The nuclear reactor power plant 811a of the nuclear power generation facility unit 811 of the nuclear power generation facility unit 811 may be provided with the double structure block tank collector 811a of the nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811, (705) of nuclear reactor waste treatment plant nuclear waste facility processing of nuclear power plant equipment constituting the connection axis position of nuclear reactor waste disposal apparatus,

The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant unit 811 of the nuclear power plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant of the above- (934) of crude oil and natural gas crude oil borehole facilities of nuclear power plants constituting the connection axis position of the nuclear waste processing pipe manufacturing process (705) of the reactor facility, and the deep sea water energy resource and mineral collection The nuclear waste disposal dispensing apparatus of the present invention,

The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure inside the nuclear power plant main body 1 of a floating nuclear power plant of a marine power plant, and a subterranean mineral resource gathering place where a submarine line wiring 946 is provided (841) for collecting manganese nodules (909), and automatic pneumatic conveying device (916) for piping line for position-regulating movement device. The suction structure of the suction suction machine (911) and the minerals of the suction- The harvesting robot 912 and the mineral gathering trough 924 are provided with a connection structure for providing a position as a connection structure on both sides of the seesaw crane boom band 942 of the sea level lower end portion SLD replacement tower crane, Replacement tower crane Seisio Crane Boom (942) Deep-sea energy resource connection axis in vertical rotation operation; and

The nuclear waste disposal and dispensing apparatus of the nuclear power plant equipment is provided with a means for transferring the salvaged resources to a transmission structure (254) inside the reactor main body (1) of the floating nuclear power plant of a marine power plant Transport equipment supplying material to the industrial site on the land 500m block unit double structure block tank facility as a connection structure Lifting of a marine power plant having a connection structure for establishing a position as a connection structure Nuclear power plant reactor main body (1) Internal connection structure (946) with a submarine track wiring (946), which is a connection structure in which each of the equipment of the marine power generation facility is located at one side of the deck of the floating deck deck and one side of the deck of the floating deck deck And the collection of energy resources and distribution input device of the deep seabed mineral. The crude oil borehole distribution and dispensing apparatus connecting structures may be provided with a nuclear reactor main body 1 of a floating nuclear power plant or a nuclear power generation nuclear waste treatment unit 811a of a nuclear power generation facility unit 811 of a nuclear power generation facility unit 811 The dual-structure block tank dust collector is used as a nuclear waste disposal facility for the operation of the nuclear power plant equipment constituting the connection axis position of the nuclear waste processing pipe manufacturing process (705) of the nuclear reactor facility. And a distribution input device of a marine power generation facility having a connection axis position of a nuclear reactor main body 1 of a floating nuclear power plant to constitute a nuclear waste disposal nuclear power plant operation of a nuclear power plant. (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear power plant (811) Double structure block tank Diving proceeds to the oscillator constituting the connecting shaft position of the nuclear waste disposal tube manufacturing process 705 of the nuclear reactor facility preparation movable adjustment control distribution input apparatus,

The distribution input device of the nuclear power generation facility 811 includes a holding tank upper barge hull 591 provided as a connection structure inside the reactor facility main body 1 of the floating power plant of the marine power plant, The hull safety equipment for distribution and input is provided as a connection structure having a connection structure submarine line wiring 946 to the holding tank lower barge hull 593 and the hull safety equipment is provided with a high strength bolt 603 and a high strength nut 604 are connected to the large block 614 through the hole 615 and the outer block tank 599 is connected to the double structure block tank holding tank 590 by a plurality of double structure block tank holding tanks 590, Large flange (615) to provide position for connection with both aft parts and stern parts. Rubber packing of gasket for connection of tank connection structure to gap (15) position. Strength flange 614 and the high strength bolts 603 and the high strength nuts 604 to the large flange 614 joining portion hole 615 of the connecting structure to adjust the position of the distributing and inputting device of the nuclear power generating facility portion 811 Hydraulic cylinder machine for equipment (619) and hydraulic equipment for transportation equipment (624) and hand tool hammer lancet connection structure with floating structure double structure of nuclear reactor plant nuclear reactor block tank pipe pier (928) and double structure block tank pipe Bridge (937) Disassembly coupling Hydraulic rotary cylinder machine (619) Double structure block tank with distribution dispenser (598) Connection structure Provide disassembly connection or horizontal double structure block tank (598) Connection structure Connection part At the same time, the tee elbow 44 is provided with a hydraulic rotary cylinder machine 619 for position adjustment as a connecting structure for disassembling and distributing dispenser, (SDU) of the hull deck hull deck (SDM) of the hull deck center (SDM) to the inside of the reactor installation main body (1) of the floating nuclear plant of the marine power plant, (SDL) Upper end of upper deck of ship (SDU) Holding tank Upper barge Ship hull (591) and holding tank Lower barge hull (592) Connecting structure Submarine line wiring (946) Facilities Separate towers Replacement towers Crane seesaw crane Boom area (942) Connected structure Mooring device and power generation facility Connection structure of marine power plant (593,594,595) Connected nuclear power plant equipment to distribution facility of nuclear power plant (811) ;

(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,

The distribution input device of the nuclear power generation facility unit 811 is a connection structure inside the reactor facility main body 1 of a floating power plant nuclear power plant of a marine power plant and is connected to a holding tank of the upper end portion SDU of the hull deck of the hull deck center portion SDM, A double structure block tank 598 for providing a position to a position having a submarine line wiring 946 as a connecting structure between a top barge hull 591 and a holding tank bottom barge hull 592 of a floating lowered end portion SDL of a floating octopus hull deck Submarine mineral resource exploration equipment located outside the outer block tank (599) It is provided as a connection structure of a power generation facility device for distributing and inputting marine power generation power to a location of a plurality of deepwater exploration underwater lights (843) And the distribution input device of the nuclear power generation equipment section 811 simultaneously arranges the harmful tidal control and barges for mounting the disaster prevention device, A plurality of column block tanks 590 are provided with a plurality of column block tanks 590 for providing a position as an external connection structure for the column block tanks, (614) connecting connection joint part processing hole (615) and the long hole hole (616) and the pin connecting shaft connecting structure are connected by the hydraulic cylinder screw (623), and the double structure block tank hull disassembly The coupling device of the thread 603a of the bolt of the coupling lug connection shaft bolt 603 and the screw 604b of the lug connection shaft decomposition coupling nut 604 is coupled to the hammer lancet hydraulic rotary cylinder machine 619, The distribution of the nut coupled to the pin connection shaft thread 603a can be prevented by providing a pin coupling with the pin coupling shaft 615 or by a hand tool provided at one side of the pin joint, (593,594,595) of the marine power plant, and a connection structure inside the reactor main body (1) of the nuclear power plant, the center of the hull deck (SDM) SDU) and a floating sediment hull deck bottom part (SDL) Floating upholstery hull deck upper part (SDU) Holding tank top barge hull 591 and bottom tank bottom barge hull 592 Each crane boom connection structure Mooring device Connection with power generation facility Connection structure of floating power plant of marine power plant Nuclear power plant of nuclear power plant (1) Consists of facility of nuclear power generation facility (811);

(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,

The distribution and input device of the nuclear power generation facility 811 is connected to the interior of the nuclear reactor main body 1 of the floating nuclear power plant of the marine power plant by connecting the upper part SDU of the hull deck of the hull deck center (SDM) (SDL) Floating Upholstery Sub hull deck top (SU) Holding tank top barge hull (591) and holding tank bottom barge hull (592) Connecting structure for providing position to a position with subsea line wiring (946) The double structure block tank combined traveling lug (607) at the upper and lower barge hulls of the upper and lower strut block tanks is combined with the horizontal and vertical forms at the respective portions of the strut tank upper barge hull (591) and the strut tank lower barge hull (592) A double structure block tank provided with a connection structure; a portable lug (607) having a plurality of processing holes (615) and an elongated hole (616) in a body; a horizontal pin connection shaft hole (615) 6 15 and a long hole 616 are formed on the upper portion of the upper block barge hull 592 and a vertical structure of the upper end barge hull 591 and the lower barge hull 592 are provided, Detachment-engaging portable lug pin connecting shaft 606 bound to several processing holes 615 among a plurality of block tank hull disassembly-type portable lug pin connecting shafts 606 bound to the processing holes 615 A block tank hull disassembly portable lug pin connecting shaft 606 having a single block tank hull disassembly portable lug pin connecting shaft 606 and a single row double row hitch disassembling portable lug pin connecting shaft 606;

Nuclear waste treatment Double structural block tank (941) Fixed float line on the upper part of the traffic system (941) Barge hull (592) and diving position control device on the side of a horizontal stowage block tank with level balance on both sides A double structure block tank-attached portable lug (607) provided with a vertically-coupled structure while leveling the barge line hull (592) of the fixed lifting hood while simultaneously performing diving to the bottom of the boat with a buoyancy control weight (949) Block tanks Hull disassembly coupling Portion lug pin connection shaft (606) Block tank with coupling Hull disassembly coupling Portion lug pin The connection block shaft (606) allows the vertical tie-rod block tank to be installed in a vertical coupling structure, (592) of the holding tank upper end of the reactor installation main body (1) of the buoyant reprocessing nuclear power plant, (615) of the lug hinge socket (613) and the nuclear waste disposal dual structure block tank (601) which provide the position of the ridge hinge connection structure with the ridge hinge A socket 613 and a concave-and-convex connection structure are selectively provided on the upper surface of the deck plate 590 and a lug hinge socket 613 is provided on the upper surface of each of the deck decks, (593,594,595) of landing block tanks (593,594,595), which are located at the upper end of the marine tunnel traffic device (941), are connected to each other in a unit of volume to provide a fixed lifting pad (593,594,595) (SLU) Barge hull and SLD Nuclear power plant Nuclear waste treatment Nuclear waste treatment Double structure Block tank Tube bridge (929) (593,594,595), or a combination of several double structure block tanks (607) with a double structure block tank with a barge hull at the top of the holding tank and a bottom tank barge at the bottom of the holding tank. Portable lug pin connection shaft 606 Several column block tanks 590 joined to the processing hole 615 of the body and the lug pin connection shaft 606 are used to prevent flooding of floats and flood prevention of floats from the sea level, The facility is equipped with a protection structure, and at the same time, the harmful tidal control and barge lines for mounting the disaster prevention device are connected to the control unit. The reactor structure of the nuclear power plant is upgraded and the barge lines for disaster prevention equipment are connected to the barge lines. (1) of the reactor plant main body (1) of a floating power plant of a marine power plant, and an upper end portion of the sea surface having a submarine line wiring (946) SLU) Submarine docking hull Deck top (SDU) Offshore power plant with connection structure Separate towers Replacement towers Crane seesaw crane Boom bar (942) Connecting structure Mooring system and power generation equipment Distribution system Connection structure (1) of the nuclear power plant of the power plant, (1) the nuclear power station of the nuclear power plant, (2) the mooring device and the diving buoyancy control device of the nuclear power station (593,594,595) (811) before nuclear reactor safety operation, and the connecting shaft of the nuclear waste treatment pipe manufacturing process (705) of the reactor facility as a connection structure capable of disassembling and coupling at a marine vessel manufacturing factory (593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and nuclear plant main body of nuclear power plant (1) Power generation seolbibu 811 double structure block precipitator tank dive in progress preparation movable adjustment control distribution of the hull for safety equipment constituting a connecting shaft of a nuclear reactor located in the nuclear waste processing plant pipe manufacturing process 705 of the input device,

The distribution input apparatus of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant. The nuclear power plant of the nuclear power plant at the bottom of the sea level surface (SLL) (938), which prevents the marine biogeochemistry and barnacles, which are located outside the body from connecting structures, to grow in the connection structure of the nuclear power plant, is treated as a nuclear waste treatment double structure block tank bridge at the bottom of the sea level (SLL) The subordinate structure block tank bridge pier 929 and the double structure block tank bridge pier 928 are installed outside the body at regular intervals and the distribution apparatus of the nuclear power generation facility 811 monitors the military equipment submarine (907) of the fish finder, while simultaneously establishing the detection of dynamics in the seabed, and at the same time, connecting the inside of the nuclear reactor main body (1) of the marine power plant to the floating nuclear power plant. (SDU) Marine power generation facility Alternative towers Replacement tower Cranes Seiso Crane Boom area (942) Connection structure Mooring device and power plant facility Connected structures Hull safety distribution Hull safety devices for operation and intercommunication satellites (962) Satellite weather forecast information collection machines (960) with connection structure are used to provide a connection structure inside the reactor main body (1) of a nuclear power plant (593,594,595) Marine power plant (593,594,595) Mooring device and diving buoyancy control device for nuclear power plant (672) and distribution facility of nuclear waste treatment and reactor installation of nuclear reactor facility Safety operation Before the operation of nuclear facility of nuclear power plant (811) The connection shaft of the nuclear waste treatment pipe manufacturing process (705) as a connection structure capable of disassembling and coupling at a marine vessel manufacturing factory (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear power generation plant (811) double structure block tank dust collector of the above land and ocean marine power plant is connected to nuclear The diving process ready controllable control distribution dispensing device for the hull safety equipment, which constitutes the connection axis position of the waste treatment line manufacturing process 705,

The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a plurality of anchor replacement crankcocks 846 as a connection structure inside a reactor facility main body 1 of a nuclear power plant, (811) as a connecting structure of the Nuclear Power Plant (811) while providing floating seaweeds to the seabed. Hull safety distribution and hull safety equipment and construction equipment for towing deck decks. (842) and submarine mineral resources (844) for submarine mineral resource reclamation with connection structure to the boom hook hook (18) inside the boom frame body by distributing both sides with the crane boom zone (942) (909) were collected by the connection structure, and the manganese nodule (909) was moved to the upper part of the deck (SDU) (909) of the submarine mineral resource manganese nodule (909) of the nuclear reactor main body (1) of the floating power plant of the marine power plant is supplied to the marine power plant, Construction of the lifting device to the upper deck (SDU) position Seaweed crane boom barriers (942) of tower crane replacement towers constitute the nuclear waste treatment of the nuclear reactor plant main body (1);

The distribution input device for the operation of the submarine mineral collection and construction machinery as the connecting structure of the nuclear reactor facility main body 1 of the floating power plant of the above marine power plant is as follows: Construction machinery equipments Seized crane boom zone And the pallet 844 for reclaiming the seabed mineral resources are disposed at the upper end of the sea surface (SLD) of the sea surface SLL and the upper end of the sea surface (SDL) SLU) to the top of the hull deck (SDU) of the floating crane, to adjust the position of the crane to the connection structure of the crane boom base (942) of the tower crane and to transport the manganese nuclide (909) The loading and unloading device for the operation of the seabed mineral collecting construction machine simultaneously provides the position control to the upper part of the floating deck hull deck (SDU) by the seesaw crane boom part (942) of the tower crane, The subsoil mineral resource collection site in the reactor main body (1) of the buoyant reprocessing nuclear power plant of the cattle is a connection structure for distributing and inputting the suction collecting machine (911) and the mineral extraction robot (912) of the mineral resource collecting equipment. It is a connection structure that receives the power generated by the floating oceanic power plant while arranging the resource collection and simultaneously controlling the position shift to the upper part of the floating deck hull deck (SDU) as a connection structure of the seesaw crane boom zone (942) (911) and minerals collecting robot (912) in the reactor main body (1) of the nuclear power plant. The submersible mineral collecting system is a distribution input apparatus for operating the mining equipment. Mineral collecting robots (912) and seaport crane boom units (942) of tower crane substitute construction equipment for construction of lifting equipment are constructed to collect submarine mineral resources;

A distribution input device for operating a seabed mineral collecting construction machine as a connection structure between a floating nuclear power plant 672 of a marine power plant and a reactor facility main body 1 of a nuclear power plant,

(SLU) with a submarine line wiring 946 as a submarine mineral resource collection connection structure to the inside of the reactor facility main body 1 of the nuclear power plant and the flood control sounding nuclear power plant 672 of the marine power plant, (SDU) Location Offshore power plant with location as a connection structure Lifting of marine power plant powered by individual mooring and power generation facilities Connection structure between nuclear power plant (672) and nuclear reactor plant main body (1) (593, 594, 595) to the seabed by the diving control device, and the seats are installed as the connecting structure. Also, the hull safety device for the safe distribution of the hull to the upper position of the deck deck of the floating deck, the hull safety device for the operation equipment, Nuclear Power Plant (672) and Nuclear Power Plant Nuclear Reactor (1) Lifting device of construction equipment (1) Construction machinery Replacement tower crane Seisio Crane Boom (942) The seismic crane boom zone (942) of the tow crane replacing the towing crane for the lifting device construction equipment while arranging the collection of the seabed mineral resources by the structure is provided with the position control to the upper part of the floating deck hull deck (SDU) As a connection structure that receives the power generated from the marine power plant, it is connected to a floating collection plant (672) of a marine power plant and a suction collection machine (911) and a mining robot (912) (911) and mineral extraction robots (912) and lifting equipment Construction machinery Fuselage tower crane Seisite crane Boom area (942) Submarine minerals Organize to collect resources;

A distribution input device for operating a seabed mineral collecting construction machine as a connection structure between a floating nuclear power plant 672 of a marine power plant and a nuclear reactor main body 1 of a nuclear power plant,

(672) of the offshore power plant and the nuclear plant main body (1) of the nuclear power plant are connected to each other by a submerged locating structure including a submerged mineral resource harvesting device on a suction collecting machine and a mining robot (909) Standing octopus Hull Deck upper part (SDU) Location Connection structure Movement structure to control conveying Construction machinery equipments Separate towers Replacement tower cranes Seisio crane Tower cranes with connection structure of boom zone (942) (886 ) Connecting structure of the connecting magnet magnet 645 and the suction collecting machine connected to the pneumatic conveying apparatus 916 and the connecting structure for conveying the manganese nodule 909 and the aliquot 632 for the elevator and the upper tank barge (591) at the upper end of the upper deck (SDU) of the hull deck, and a connection structure (842) for reclaiming seabed mineral resources (844) is equipped with a conveying system that adjusts the position of the ship's upper deck (SDU) to the floating deck hull deck top (SDU), while at the same time the submarine mineral collection and construction machine dispensing system is equipped with a seesaw crane boom 942) and at the same time the connecting structure of the conveyor 633 is located at the upper position of the floating deck hull deck upper part (SDU) in the submarine mineral resource collecting place of the submarine mineral resource located in the SDL of the floating hull deck hull deck Submarine mineral resource exploration equipment and connection structure for searching submarine mineral resource collecting process state while providing submarine mineral resource movement and submarine track (232) and submarine surveying glass underwater illumination light (843) A lighting device for providing a position with a wiring 946 is provided, and at the same time, a floating-type solar power plant 672 of a marine power plant and an atom Connected structures inside nuclear reactor facility (1) of power plant Inhalation collecting machine and connection structure Mineral collecting robot and submarine mineral resource collecting equipment All above mentioned submarine mineral resource collecting equipment included as a connection structure are collected at the water pressure of the deep sea floor and the flow rate of the deep sea The connection structure of each of the lever blocks 123 and the wire rope chain 915 for preventing loss of collecting equipment at the location of the undersea mineral resource collecting site, The bait (632) and the submarine excavation equipment are connected to each other to prevent loss by collecting equipment. In addition, all of the seabed mineral resource collecting equipment is equipped with a lever block (123 ) Wire rope connection structure Each of the gathering devices bound to the structure is moved to a position where the wound wire rope provided on the lever block (123) Hitting a while providing Let go to the seabed mineral gathering process state search Equipped the shift adjustment by picking equipment gakgae at the same time as the connection structure unmanned camera 184 belonging to the seabed exploration equipment connecting shaft; and

The connection structure includes an undersea camera resource search device, a searchlight 232, and a connection structure to connect the unmanned camera 184 to a position where the underwater illumination lamp 843 for the submarine survey lens glass is discharged to the illumination. While the process state scene transmission is being carried out, the distribution input device for operating the submarine mineral collection and construction machine simultaneously connects the container box latching device 129 of the container box 132 corresponding to the submarine mineral carrier to the unmanned camera 184) Submarine mineral collecting process State transmission of the sea surface (SLU) with the transmission of the scene Up to the hull deck upper part (SDU) position to the hull safety facility control room Location to the location of the control room Submarine cable (946) (672) of the offshore power plant and the reactor structure main body (1) of the nuclear power plant are connected to the intake structure collecting machine and the mining robot (SLU) with submarine track wiring (946) included in the submarine mineral resource collection equipment as a whole connection structure Internet connection network (50) to establish the location of the SDU hull safety facility control room inside the control room The undersea camera 184 receives the undersea mining process state scene transmitted from the monitor 51 of the server 51 and the control board 53 through the unmanned camera 184 while simultaneously receiving the connection structure mooring device and connection structure mineral resource collection (1) Inside of the nuclear reactor plant main body (1), which is equipped with the equipments for distributing the moving equipment of the equipments and the equipments for securing the seabed at the seabed while allowing the mineral resource collecting equipment to withstand the pressure of the deep sea bed and the flow rate of the deep sea bed. And the distribution apparatuses for the operation of the submarine mineral collection and construction machinery are provided, and the mooring device formed at the marine power station floating feeder nuclear power plant (672) And diverting buoyancy control device and nuclear waste disposal dispenser and nuclear reactor facility safety operation Before the safety operation Fusi Nuclear power plant division (811) to the reactor facility nuclear waste treatment pipe manufacturing process (705) (593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and the nuclear reactor main body of the nuclear power plant (1) Nuclear power generation The diving operation ready controllability control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility, the double structure block tank dust collector of the facility part 811,

The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a floating crane 846 as a connection structure of an anchor replacement crank 846 inside a reactor facility main body 1 of a nuclear power plant. The power plant is connected to the seabed. It is a distributing and inputting device. It is a top position of a floating deck deck with oceanic seating of a floating nuclear power plant. It is connected to a hull safety device and a connecting structure for construction safety equipment. A seaweed crane boom base 942 of a tower crane for replacement of a cruise ship crane base is divided and a float base 844 and a connecting structure 844 are connected to the hoist base 184, (942) of the seesaw crane boom (942) Movement control device Connects the structure to collect seabed mineral resources Upper deck (SDU) above the deck (811) supplied with electric power produced by an offshore power plant that provides a location of a submarine mineral resource with the position of the floating deck hull deck upper part (SDU) The power transmission unit (811d) connects the main body (1) of the nuclear power plant of the marine power plant with the connection structure of the power transmission unit (811d) to the seabed crane boom zone (942)

(593, 594, 595) of the marine power plant is a connection structure of the reactor main body (1) of a nuclear power plant. The distribution input device for operating the seabed mineral collecting construction machine,

Construction Equipment Equipments Seisie Crane Boat (942) for the replacement tower crane Seated on each side of the connecting structure Both the basin (842) and pallet (844) connection structure for reuse of seabed mineral resources are connected to the lower part of the sea surface (SLL) ) Positioning Movement Control Device Connection Structure from the Inside Submarine Mineral Resource Collecting Site to the Upper Sea Level Upper Part (SDU) Position of the Upper Sea Level Upper Part (SLU) in the Underwater Hybrid Substructure SDL of the Hull Deck Below the Seabed Crane Boom Stand (942) At the same time, the seesaw crane boom zone 942 is provided with a seesaw crane boom zone 942 for controlling the movement of the seabed mineral resource manganese nuclide 909 as a connection structure to the position of the upper part of the floating deck hull deck (SDU) At the same time, the inside of the nuclear reactor facility (1) of the nuclear power plant is distributed in the submarine mineral resource collection site, The seismic crane boom zone (942), with its mouth, provides for the collection of seabed mineral resources and at the same time a connection structure to control the movement of the hull deck to the upper deck (SDU) And a power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation facility 811 supplied with the power generated by the offshore power plant of the offshore power plant, (1) The operation is carried out by seismic crane boom zone (942) to regulate submarine mineral resources by the displacement control system;

The seesaw crane boom zone 942 distributing and inputting device for operating the seabed mineral collecting construction machine as a connection structure of the reactor facility main body 1 of the floating power plant nuclear power plant of the marine power plant,

The distribution and input device of the seesaw crane boom 942 is located at a position inside the seabed mineral resource collecting site and is connected to the upper end of the sea surface (SLU) (942) Connection structure Mooring device and connection structure Standing on the seabed with the connection structure for lifting and listening to the power supplied by the power generation facility, Hull safety distribution and connection to the connecting structure Hull safety equipment and construction machinery for operation Seito crane replacement tower crane Separate crane boom area (942) Seaside crane boom area (942) distribution structure with connection structure The system is equipped with an input device, and the position control is carried out to the upper part of the deck (SDU) A power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation equipment unit 811 supplied with electric power is connected to the main body 1 of the nuclear power plant of the marine power plant by the operation of the shuttle crane boom 942) is configured to collect seabed mineral resources with a displacement control device;

A distributing and inputting device for operating a seabed mineral collecting construction machine as a connection structure of a nuclear reactor main body 1 of a floating power plant of a marine power plant,

The distribution dispenser for operation of the construction machine includes a manganese nodule 909 for providing a location on the seafloor including a suction collecting machine, a connection structure minerals collecting robot and a submarine mineral resource harvesting equipment connection structure as a nuclear reactor connection structure of a nuclear power plant, It is provided as a connection structure, and it is installed as a connection structure, and it is moved to the upper part of SDU of the hull deck of the ship. Construction equipment equipment Construction equipment equipment Replacement towers of each tower Seisio crane boom of crane (942) Electric magnetic magnet The mooring nodule 905 is connected to the pipeline line conveying device 916 of the connecting structure suction collecting machine and at the same time the connection structure for the elevator allybeat 632 is connected to the upper part of the strut tank upper barge hull 591 (842) for collecting seabed mineral resources and a pallet (844) provided at the upper end of the upper part (SDU) of the floating deck hull deck top The construction and operation of the above-mentioned construction machinery is carried out by a construction machinery and equipment that adjusts the position of the ship's upper deck (SDU) to the position of the floating deck hull deck (Seaweed crane boom zone (942) And at the same time the conveyor 633 moves the conveyor 633 to the upper end of the floating deck hull deck upper part (SDU) in the undersea mineral resource collecting place, which is located inside the lower end SDL of the floating deck hull deck A submarine mineral resource searching apparatus 232 for searching the seabed mineral collecting process state and a submarine line wiring 946 for connecting a deep sea exploration underwater illumination lamp 843 as a connecting structure are provided At the same time, a suction collection machine, a mining robot and a submarine mineral resource collecting device are connected to the inside of the nuclear reactor main body (1) of the floating power plant of the marine power plant And a power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation facility 811 supplied with the power generated by the marine power plant of the marine power plant, The operation of the main body (1) is constituted so as to collect seabed mineral resources with the movement control device of the seesaw crane boom zone (942);

As the connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593, 594, 595), the distribution input device for operating the seabed mineral collecting construction machine,

The unmanned camera (184), which is provided as a connection structure inside the nuclear reactor main body (1) of the floating nuclear power plant of a marine power plant for operation of the submarine mineral collection construction machine, The undersea mineral resource collecting apparatus searching for the undersea mineral resource searching apparatus 232 and the deep sea exploration underwater illuminating lamp 843 are connected to the unmanned camera 184 for providing the position to the location where the illuminating is performed, The container box latching device 129 of the container box to be transferred to the control room is connected with the unmanned camera 184 to the hull safety equipment control room position located at the upper part of the sea surface (SLU) and the upper part of the hull deck (SDU) A line wiring 946 is provided in the reactor main body 1 of the marine power plant, or a connection structure suction intake machine and a connection structure Water harvesting robot with undersea mineral resources collecting equipment connected to the structure that contains the connection structure connecting shaft; and

(SDU) hull safety equipment control room with a submarine line wiring line 946. The Internet network 50 is connected to a monitor 52 of the internal control server 51 and a control unit The ship's undersea camera 184 receives the undersea mining process state scene transmitted to the inside of the board 53 while receiving the seabed mineral collecting process state scene at the marine power generation facilities, and the seesaw crane boom zone 942 of the tower crane for replacing each marine power generation facility. The distribution structure of the submarine mineral collection and construction equipment is as follows. The distribution structure of the submarine mineral collection and construction equipment is as follows. (1) inside the nuclear reactor plant (1) of the nuclear power plant, and (5) 95) Mooring device and diving buoyancy control device for nuclear power plant (672), nuclear waste disposal system for nuclear waste disposal and reactor facility safety operation Fukushima Nuclear Power Plant (811) (593, 594, 595) nuclear power plants (672) of the above-mentioned land and marine marine power plants, and a connection structure of the marine power plant Nuclear power plant reactor main body (1) Dual structure block tank reactor of nuclear power generation facility (811) is set to be ready for diving for hull safety facility constituting the connection axis position of nuclear waste treatment pipe manufacturing process (705) The regulated control dispense injector comprises:

The distribution input apparatus of the nuclear power generation facility unit 811 is an internal connection structure between the floating nuclear power plant 672 of a marine power plant and the nuclear power plant main body 1 of a nuclear power plant. The submarine line harness 946 is provided with a distribution structure to the connection structure. In addition, the connection structure of the mineral resource collecting equipment at the seabed is a diving control device provided with a connecting structure for enduring the water pressure of the deep sea floor and the flow rate of the deep sea floor The connection structure of the connection structure of the Bellows butterfly valve 305 and the connection structure of the diving control device connection structure 585 directly connects the conduit type 581 to the doctor ventilation inlet port 585a and the doctor ventilation outlet port 585b, While the distribution apparatus of the nuclear power plant unit 811 is provided with the compressed air generated in the air compressor 80 of the prime mover A single-force automatic pneumatic instrumentation device provided with a microswitch 580 is set in the timer 541 as an overpressure prevention scale indicator, or automatically set to the fire damper 583 without being manually depressed Pressure air is injected into the air cylinder 138 equipped as a connection structure and at the same time the damper spindle 584 connecting structure provides pressure air in the doctor ventilation 585 while the fire damper 583 performs the full closing and expansion The fire damper 583 may be provided with devices for controlling the interruption and supply of air and may be provided with a connection structure such as a pipeline automatic pneumatic conveying device 916, The connection structure provided with or provided with a connection structure such as the Bell-Butterfly valve 305 of the apparatus can be used for the sleep of the reactor installation main body 1 of the lifting type docking nuclear power plant of the marine power plant To control the control device be configured to accomplish the reactor equipment body (1) of a nuclear power plant, and;

The double structure block tank dust collector of the nuclear power plant 672 of the offshore and offshore marine power plants and the reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant is connected to the nuclear waste treatment pipe manufacturing process 705 of the reactor facility, The diving preparatory operation control regulating control dispensing device for the hull safety equipment,

The distribution input device of the nuclear power generation facility unit 811 receives the pressure air generated from the air compressor 80 of the prime mover into the reactor facility main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant, When the solenoid valve overpressure prevention switch 108 of each solenoid valve 76 and the on-time main switch button 66 of the main switch button 66 for the solenoid valve start switch button are manually pressed, the butterfly valve 305 And the main switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is fully closed to provide an operation interruption. Alternatively, when the start switch button &lt; RTI ID = 0.0 &gt; When the on-time main switch button 66 of the main switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is expanded so that the pressure air generated in the air compressor 80 passes through the pipeline line connection structureAnd a connection structure for providing a connection structure to a plurality of fire doors 154 and a plurality of hatch cover 153 bodies at the same time as a solenoid valve (not shown) of the reactor main body 1 of a floating power plant The solenoid valve overpressure prevention switch 108 and the butterfly valve 305 connection structure of the solenoid valve 76 are configured to perform an operation;

(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,

The distribution input device of the nuclear power generation facility unit 811 performs an operation in which the electronic control rotary hydraulic cylinder 35 is rotated as a connection structure between the floating nuclear power plant 672 of a marine power plant and the reactor facility main body 1 of a nuclear power plant At the same time, a plurality of fire doors 154 and a plurality of hatch cover 153 connection structures are opened as a connection structure, and the mineral resources provided in the seabed mineral collection site are connected to the inside of the body of the holding tank lower barge hull 592 The vacuum pump 635 for the conveying and lifting device and the power cable 71 are connected to each other in the empty space by the structure, and the distributing and inputting device of the nuclear power generation facility 811 is provided with the main switch button for the start switch button The vacuum pump 635 is rotated by manually depressing the on-time main switch button 66 of the vacuum pump 66, Mineral resources provided at the submarine mineral collection site located outside the body of the barge hull (592) are the connecting structure that provides the position movement to the inside of the body of the barge hull (591) at the top of the holding tank. 1) the internal hydraulic control rotary cylinder (35) hull safety equipment is constructed inside;

The distribution input device for operating the submarine mineral collection and construction machine as a connection structure of the nuclear reactor main body 1 of the floating power plant of the marine power plant includes a hull 206 for controlling the submersible- And the submarine mineral resource connection structure to replace the submarine mineral resource connection structure to provide the hull safety facility, or the submarine submarine mineral resource for controlling the diving position of the hull, (SLU) Floating upholstery Upper part of the upper deck (SDU) of the hull Deck of marine power generation facility which is positioned as a connection structure. Replacement Tower Cranes Seiso Crane Boom Stand (942) Connection Structure Make a power plant with mooring system and connection structure. A connection structure provided at a low mineral collection site, comprising a main body (1) of a nuclear power plant of a marine power plant as a distribution input device for operation of a construction machine;

As the connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593, 594, 595), the distribution input device for operating the seabed mineral collecting construction machine,

The mineral resources of the distributing and inputting apparatus for operation of the submarine mineral collection and construction machine are divided into a hollow space inside the lower tank barge hull (592) of the holding tank, a connecting structure diving position adjusting movement device for diving buoyancy control, Submarine mineral resources for diving buoyancy control, replacing submarine mineral resources, and a plurality of fire doors and a plurality of hatch covers (153) provided on the outer bulkhead of each part of the body of the holding tank lower barge hull (592) (916) to pass through a pipeline line automatic pneumatic conveying device

The solenoid valve overpressure prevention switch 108 of the connection structure solenoid valve 76 and the main switch for the solenoid valve start switch button of the connection structure solenoid valve 76 are connected to the ballast butterfly valve 305 of the diving control device of the pipeline, The connection structure of the button (66) is provided with a connection structure by a connection structure of the power cable (71), and the connection structure of the boat crane boom bar of the tower crane substituting the inside of the reactor installation main body (1) of the floating power plant of the marine power plant 942) Distribution system for distribution of mineral resources to the connection structure Moving device Construction equipment Consisting of connecting structure with connection to the structure and having a seated place at the seabed, but at the same time, the upper part of the sea surface (SLU) The marine power generation facilities that provide the location of each quay Alternative tower Crane seesaw crane Boom bar (942) Connection structure Mooring device (593,594,595) installed at the nuclear power plant (672) of the marine power plant, or the connection structure provided at the seabed mineral collection site by the power generation facility apparatus having the connection structure, And diving buoyancy control device and distribution device of nuclear waste disposal and nuclear reactor facility facility safety operation Before the operation of FUSSO nuclear power plant (811), the connection axis of nuclear waste treatment pipe manufacturing process (705) of reactor facility;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The diving preparation ready operation control regulating and distributing apparatus for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor plant of the double structure block tank dust collector of the nuclear power generation facility unit 811,

The distribution input device of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of a marine power plant and the reactor main body 1 of a nuclear power plant. In the submarine mineral resource collection equipment distributing and inputting apparatus, Tank (590) Upper barge hull (591) 500 m long to position to upper side position Double structure block tank A manganese nodule (909) with reserves of 5000 million meters of seabed, The connecting structure having a structure in which a plurality of the grounding baskets 183 and the nuclear plant construction unit 811 are connected to the inner position of the container box of the connection and disconnection structure of the nuclear power plant 811 is constituted by a submarine mineral garden air bag 849, The seepage crane boom base 942 of the tower crane is distributed to distribute both sides of the seabed crane boom base 942 to the hook hook 18 of the seesaw crane boom base 942 of the tower crane, The float basket 842 and the pallet 844 connecting structures are connected to the sea level basin 842 and the pallet 844 connection structure for collecting seabed mineral resources on both sides of the seesaw crane boom portion 942 of the tower crane, (SDD) of the upper part of the sea surface (SLU) to the position of the upper part of the hull deck (SDU) of the sea surface from the position of the submarine mineral resource collection place inside the lower part of the SDL (SDL) (909) of mineral resource manganese nodule (909) to the upper part of the ship's deck (SDU), while at the same time arranging the submarine mineral resource collection site inside the main body The distribution input device of the nuclear power generation facility 811 is provided to the position where the connection structure submarine line wiring 946 is provided, (SLU) levitated at the top of the sea surface (SDU) Located at the top of the deck of the ship (SDU) Separate towers Replacement tower Cranes Seisoka Crane Boom area (942) Mooring device connection structure (593, 594, 595) to the seafloor. Both sides of the seesaw crane boom zone (942) of the tower crane at the bottom of the sea surface provided inside the nuclear reactor facility main body (1) of the floating nuclear power plant of the marine power plant are submarine mineral resources and submarine mineral collection equipment A connecting structure for providing a distribution input device of the nuclear power generation facility 811, and constituting a nuclear power plant main body 1 of a floating power plant of a marine power plant;

The distribution input device of the nuclear power generation facility 811 of the mineral resource and the lifting device lifted by the floating pickling hull collecting device as a connection structure of the nuclear reactor facility main body 1 of the nuclear power plant of the marine power plant of the marine power plant (593,594,595)

The distribution input apparatus of the nuclear power generation facility unit 811 is a system in which a hydraulic structure of the connecting structure hydraulic hydraulic cylinder 39 is operated as a connecting structure inside the reactor facility main body 1 of the floating planted nuclear power plant of a marine power plant, The nodule 909 is provided inside the reactor installation main body 1 and the seesaw crane boom stand 942 hydraulic cylinder machine 624 of the tower crane substituting for crates positioned at the top of deck deck of the strand tank upper barge hull 591 The hydraulic system of the hydraulic cylinder machine 624 is provided with the load and piston seal 822 and the piston seal 823 and the booster seal 824 and the wear ring 825 and the slide ring 826, 828 and the O-ring 828 and the load seal 829 and the backup seal 830 and the load seal and backup seal 831 and the mist seal 832 and the pin cast seal 833 and the mist seal 834, A bushing ring 835, a piston ring 836 and a multistring 837, System 624 in nuclear power Equipped the distribution chute of seolbibu 811, a hydraulic pump connected to the high-pressure hose structure 190 and the high pressure of the conjugate through to the pipe and the solenoid valve (76) axis; and

The piston moves forward and backward within the hydraulic cylinder machine 624 and at the same time the seesaw crane boom stand 942 of the tow crane replacement tower crane is moved to the upper position of the deck deck of the holding tank upper barge hull 591 to the hydraulic cylinder machine 624, The submarine mineral resources that are recovered to the upper part of the upper deck (SDU) of the floating deck hull deck are provided with the national foreign debt reimbursement (SDU) at the top of the sea deck (SDU) at the top of the sea with the submarine line wiring (946) connected to the distributing and inputting device of the nuclear power plant (811) Crane boom (942) Mooring device of connection structure and connection structure inside reactor main body (1) of nuclear power plant. The distribution and input devices of the nuclear power plant 811 are provided in the reactor main body 1 of the magnetic power plant and the mooring device and the diving buoy control device and the nuclear waste generated in the nuclear power plant 672 of the marine power plant floating support 593,594,595, Dispensing device of treatment and reactor facility of nuclear reactor facility Before the safety operation, the connection axis of the nuclear waste processing pipe manufacturing process (705) of the reactor facility at Hue City Nuclear Power Plant (811);

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The diving preparation ready operation control regulating and distributing apparatus for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor plant of the double structure block tank dust collector of the nuclear power generation facility unit 811,

The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a furnace distributing and inputting apparatus for operating a mineral resource heat treatment operation of a floating power plant 672 of a marine power plant and a nuclear power plant Reactor main body (1) Internal connection structure Upper part of sea surface (SLU) with submarine track wiring (946) Upper part of upper deck (SDU) Upper marine power generation facility Replacement towers of different towers Crane seesaw crane Boom bar (942) Structures Mooring system and connection structure Submarine mineral resource lifted by power generation facility Submarine line wiring (946) Replacement towers with connection structure Seisio crane boom stand of crane (942) Body connection structure Internal boom hook hook (842) and a pallet (844) for collecting seabed mineral resources in the seabed crane boom (18), but the seabed crane boom stand (942) The reclaimed grass baskets 842 and 844 are provided with an upper surface SLL at the lower level of the sea surface SLL and a lower level SDL at the inner bottom of the SDL, At the same time, the distribution input device of the nuclear power plant 811 carries out the transportation of the seabed mineral resource manganese nodule 909 to the upper part of the floating deck hull deck (SDU) The distribution and input device of the nuclear power generation facility 811 is connected to the upper end of the sea surface (SLU) with the connection structure submarine line wiring 946, the upper part of the ship deck (SDU) (942) Connecting structure Mooring device and lifting of marine power plant Nuclear power plant nuclear reactor plant (1) Connected to the inside Structure of the nuclear power plant Made be configured reactor equipment unit to dispensing chute furnaces for heat treatment of mineral resources and movable;

(593,594,595) of the above-mentioned marine power plant, the furnace distributing and inputting device for operating the mineral resource heat treatment operation is a connection structure of the reactor main body 1 of the nuclear power plant of the marine power plant (593,594,595) ) Inside the submarine mineral resource collection site, the inhale collection machine and mineral extraction robot of mineral resource collection equipment are distributed and installed, and the location movement is carried out by the position movement control device. At the same time, the upper part of SDU And a blast furnace 948 having a furnace 948a of a blast furnace 948 is provided with a blast furnace 948 provided with a blast furnace and a furnace 948. The bottom of the blast furnace 948 is poured with molten manganese nuclide 909, (948) for the production of guide rails (597) and guide rails (618), and at the same time supply and supply And a connecting structure for providing the guide rail 618 for the block tank hull transportation device inside the reactor facility main body 1 of the nuclear power plant includes the production and supply of the iron plate 597 and the guide rail 618 as the double structure block tank pipe The guide rails 618 provided in the inner lower tank location connection structure of the inner block tank 596 of the dual structure block tank 598 connected with the nuclear waste treatment double structure block tank bridge 929 having the connection shaft of the bridge 937 The furnace distributor for the mineral resource heat treatment operation is provided with a train 771 for locating the internal block tank 596 with an internal train 771 for a marine tunnel apparatus of 100 KM / (597) of the high-strength stainless steel and the guide rail (618) are provided inside the nuclear reactor main body (1) of the nuclear power plant.The connecting shaft of the current device and the submerged buoyancy control devices and nuclear waste disposal distribution chute and reactor plant reactor plant safety operation before and after the manufacturing process 705, the nuclear waste disposal pipes of the reactor in a nuclear power plant seolbibu 811 of the;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) Dual structure block of the nuclear power plant (811) The tank dust collector is connected to the nuclear waste disposal pipe manufacturing process (705) of the reactor facility. The submarine energy and mining equipment constituting the connection axis position. Diving Progress Preparation for Facilities The operation control regulating control dispensing device,

The distribution input device of the nuclear power generation facility unit 811 is connected to the upper end of the sea level upper surface portion SLU with the submarine line wiring 946 as the internal connection structure of the reactor facility main body 1 of the floating planted nuclear power plant of the marine power plant, SDU) Offshore Generation Facility Seito Crane Replacement Tower Cranes Replacement Tower Crane Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom (SLD) of the sea surface (SLL) as a connection structure between the grate basket 842 and the palette 844 for collecting the seabed mineral resources at the same time, as a connecting structure on both sides of the seesaw crane boom band 942, (SDU) at the upper part of the sea surface (SLU) to the upper part of the deck (SDU) The distribution and dispensing apparatus of the facility unit 811 is equipped with a manganese nodule 909 as a connection structure for the seesaw crane boom band 942 by transporting the seabed mineral resource manganese nodule 909 to the upper end SDU of the floating deck hull deck At the same time, in the inside of the reactor facility main body (1) of the nuclear power plant of the marine power plant, the seesaw crane boom zone (942) is connected to the inside of the seabed mineral resource gathering place. And the hatching erectors 877 are provided for injecting the solidified manganese nodule 909 into the furnace as the manganese nodule 909 for crushing the crushed manganese nodules 909. At the same time, the file driver 882 of the plurality of construction machines 880, The position of the hammers 883 and the steam hammers 884, the hydraulic cranes 885 and the tower cranes 886 are adjusted to adjust the position of the hammers 883 and the crane 886. At the same time, the intake collection machine 911 for collecting the seabed mineral resources and the mineral picking robot 912) includes a construction machine excavator It is a connection structure to control the operation position movement as a connection structure. It is a connection structure of the reactor main body (1) of a floating power plant of a marine power plant. It is equipped with a construction machine distributing input device for operating submarine energy and mineral gathering equipment. Collecting resources into a plurality of construction machines 880;

The construction machine distributing and inputting apparatus for operating the submarine energy and mineral collecting equipment composed of the connection structure of the crane boom unit (74) of the reactor facility main body (1) of the nuclear power plant of the marine power plant (593,594,595)

(1) Inside the tower Replacement towers Replacement towers Crane seesaw crane Boom barge (942) Boom boom boom and boom girder (652) Multiple heavy oil tanks on both sides of the body Pressure hose 190 connected to the 500 m high-pressure hose 190 connected to the bottom of the heavy oil tank 795 by a plurality of high-pressure hoses 190 as a connection structure, (908) a plurality of drill rod pipe racks (854) connected to a drilling machine; a core drill (917) positioned at the fore end; a crude oil borehole (936) and a natural gas borehole (936) , A predetermined amount of piping files are provided, and at the same time, loess and cement are supplied to the pipe line of the pipe rod rack (854) through the passage of the pipe line, While at the same time fill the pipe files 500m high pressure hoses 190 connect fitting couplings (29) to a high pressure hose connection is connected to a plurality of connection structures shaft; and

The crude oil and the natural gas, both of which are provided with crude oil and natural gas reservoirs, are connected to boom hoists and boom hooks 652 of the crane boom area of the seesaw crane boom area 942 of the tower crane, The ingot basket 842 and the pallet 844 for collecting the undersea mineral resources are connected to the in-body boom hook hook 18 so as to form a weep basket 842 for collecting both undersea mineral resources of the seesaw crane boom girder 942, And the Palette 844 are located at the lower end of the sea level SLL of the sea level SLL and the SDU of the floodplain hull deck upper part SLU of the sea level upper part (909) of the submarine mineral resource to the upper part of the floating deck hull deck (SDU), and at the same time, the vertical movement of the nuclear reactor nacelle nodule (909) Crude oil, natural gas and undersea energy harvesting equipment, which provide lifting to the deck top deck at full operation, are located at the upper end of the sea surface (SLU) (SDU) Offshore power plant with location to the upper position Alternative towers Replacement towers Seiso crane of crane Boom of crane boom of boom zone (942) Boom of boom Boom and boom hook (652) Connection structure Connection to provide mooring device and power plant equipment The structure includes the connection axis of the nuclear waste processing pipe manufacturing process 705 of the reactor facility at the nuclear power generation facility 811;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The diving preparation ready operation control regulating and distributing apparatus for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor plant of the double structure block tank dust collector of the nuclear power generation facility unit 811,

The distribution and input device of the nuclear power generation facility unit 811 includes a nuclear power plant 672 of a marine power plant and the reactor facility of the nuclear power plant 1 of the nuclear power plant, A plurality of inner block tanks 596 and a plurality of outer block tanks 599 to the outside of the plurality of inner block tanks 596 and a first auxiliary tank 600 for a block tank, A vertical partition 605, a horizontal partition 609 and a steel beam 149 in the second auxiliary steel plate 601 for the block tank and the second auxiliary steel 600 for the block tank and the second auxiliary steel 600 for the block tank 601, Cutting processing is performed by a computer laser cutter 954 for each of the auxiliary steel plate 601, the vertical partition 605, the horizontal partition 609, the steel beam 149, the snap hole 602 and the partition wall manhole 610 At the same time, welding of the double structure block tank dust collector 794 is provided by a welder of the welding process, 4 Fifth guard wall distributing apparatus and fuel explosion control dispensing apparatus formed along the outer wall surface of the protective wall containment vessel 808 Nuclear reactor nuclear leakage leakage control dual structure block tank dust collector (794) Nuclear Reactor Nuclear Reactor (Nuclear Reactor) Nuclear Reactor (Nuclear Reactor);

The distribution and input device of the nuclear power generation facility unit 811 includes a vertical partition wall 605 in which a partition wall manhole 610 is formed inside a reactor facility body 1 of a floating planted nuclear power plant of a marine power plant and a horizontal partition wall 609, The hydraulic cylinder door 624 and the emergency stairs 631 are provided with a reactor installation main body 1 of a floating type pilot nuclear power plant by a welding process and a double structure block tank dust collector 794, The unit is provided with a hydraulic cylinder door 624 and emergency stairs 631, and is provided as a transportation device in the inside and outside of the double structure block tank dust collector 794 for control of the reactor facility nuclear radiation leakage control reactor. The shielding device is configured to operate the nuclear power plant;

A plurality of stopper plates 625 are connected to a cylindrical double structure block tank 598, a plurality of inner block tanks 596 and a plurality of outer block tanks 599, At the top and bottom of the dual structure block tank, the double structure block tank dust collector 794 is welded to the large structure flange bolt 794 and the large flange bolt connection double structure block tank dust collector 794, (1) of the nuclear plant of the marine power plant, a plurality of nuclear reactor nuclear waste (224) treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus are installed in the main body (1) of the marine nuclear power plant. And the barge hull 592 at the lower part of the holding tank. Alternatively, the nuclear reactor main body 1 of the floating nuclear power plant of the marine power plant may be divided into a plurality of reactor nuclear waste 224 It comprises a nuclear powered by the fuel control device to the explosion of a plurality of steel plate stopper 625 be configured to accomplish the reactor equipment body (1) and;

In the nuclear waste disposal unit dual structure block tank dust collector 794 of the nuclear power generation facility unit 811, a plurality of inner block tanks and a plurality of outer block tank vacancies are stored in the lower ends of the empty space before nuclear explosion, At the same time, the installation of the reactor floor of the double structure block tank precipitator 794 is provided with fixation by the reinforced concrete mat 225 and the steel beam 149 of the number of the road surface lower surface GLD thickness m, The barge hull 591 at the upper end of the holding tank is replaced with a reactor building 688 outside the inner block tank 596 having the nuclear fuel explosion preventive double structure block tank dust collector 794, Nuclear Reactor (Nuclear Reactor) Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Control distribution dispenser Dual structure block Tank dust collector (794) is installed in the marine power plant to supply the nuclear waste to the reactor main body (1) of the floating nuclear power plant of the marine power plant Discharging injection device and nuclear fuel explosion control Dispensing input device Double structure block A tank dust collector 794 is provided to generate electric power and the nuclear radiation leakage control dual structure block tank dust collector 794 operates the nuclear power plant;

The distribution and input device of the nuclear power generation facility 811 has a large amount of radiation generated inside the nuclear power plant main body 1 of the floating power plant of the marine power plant so that the nuclear fuel explosion control distribution input device A first wall pellet and a cladding for providing a second wall fuel rod protection; a third wall reactor pressure vessel, a fourth wall containment vessel and a fifth wall reactor building; and a reinforced concrete mat (225) A double structure block tank dust collector (794) is installed as a dispensing device and a nuclear fuel explosion control dispensing device in place of a five-layered protective wall, or a nuclear power plant is installed in the nuclear reactor main body (1) Of the nuclear reactor facilities are provided as a reactor nuclear waste disposal dispenser with double structure block tank reactor buildings (688) in the barge hull (591) at the upper end of the holding tank At the same time, the barge hull (592) at the bottom of the holding tank is provided with a plurality of nuclear reactor facilities such as a reactor facility of a nuclear power plant in the nuclear fuel explosion control distribution dispensing apparatus dual structure block tank dust collector (794) Control dual structure block tank cleaner 794 to operate the nuclear power plant;

The distribution and dispensing apparatus of the nuclear power generation facility unit 811 has a connection structure with a steam generator 810 and a steam dryer 786 installed outside the reactor pressure vessel 813. The nuclear power generation facility 811 A plurality of through holes are formed in the upper portion of the nuclear reactor building 688 corresponding to the fourth wall and the containment vessel 808 corresponding to the fourth wall of the distribution dispensing apparatus using cutters and construction machines at an angle of 45 degrees A plurality of safety valves 472 are connected to the block piping line 74 by means of bolts 24 and nuts 25 and a gasket The reactor building 688 may be provided with a flange coupling connection with the reactor building 688 or the distribution injector dual structure block tank dust collector 794 of the nuclear power generation facility 811 along the outer wall surface of the reactor building 688, The double structure block tank 598 having a diameter twice the diameter of the double structure block tank 598 Nuclear waste treatment storage External block tank (599) and radiation-type double pipe structure block piping line (74) By providing a connection structure, nuclear waste disposal dispensing equipment and nuclear fuel explosion control dispensing equipment The radiation leakage control dual structure block tank dust collector 794 is configured to operate the nuclear power plant;

The distribution unit of the nuclear power generation facility unit 811 includes a plurality of inner block tanks 596 and a plurality of outer block tanks 599 in the double structure block tank reactor building 688, The cement mixer equipment mixer machine 649 is installed in the pressure vessel 813 such as a furnace immediately before the large explosion of the nuclear reactor and the mixture of the nuclear fuel explosion-proof control article cooling water 287 and the loess mixture 927 ) Is installed in the pressure vessel (813) at the same time by injecting a fuel explosion-proof control article into the automatic injector double structure fire-fighting nozzle (10), and the inside of the reactor facility is cleaned before the earthquake A plurality of double-structured fire-fighting nozzle nozzles 10 are formed inside the pressure vessel 813 and inside the containment vessel 808, but the interior of the reactor facility, Dynamically automatic injection device A double structure fire-fighting nozzle 10 is provided with a plurality of internal cleaning processes, and at the same time, a nuclear fuel explosion-control dispensing device having a reactor facility of a double structure block tank dust collector 794, (1) of the reactor facility main body (1) of the nuclear power plant, and a double structure block tank of the nuclear reactor facility is installed in the reactor main body (1) of the nuclear power plant. It is equipped with a treatment distribution dispenser to prevent the explosion of the nuclear reactor facilities before and after safe operation of the reactor facilities, and to set up the operation of the nuclear reactors;

The distribution and dispensing apparatus of the nuclear power generation facility unit 811 forms a circulation water pump 242 connecting the cooling water 287 and the piping line 352 to the distribution and dispensing apparatus of the nuclear fuel explosion control apparatus. The mixture of the yellow loess mixture and the yellow loam mixture mixer machine (649) is mixed with the cooling water (287) so that the loess mixture is not solidified. At the same time, the cooling water (287) The pressure inside the pressure vessel 813 at the same time to clean the inside of the reactor immediately before and after the occurrence of the earthquake and at the same time to ensure the safe operation of the reactor facility capable of performing continuous power generation without being restricted by natural disasters A nuclear waste disposal and dispensing apparatus having a double structure block tank dust collector 794 for preventing nuclear explosion prevention nuclear radiation leakage control formed by maximizing nuclear fuel explosion Nuclear Fuel Explosion Control of a Multiple Nuclear Reactor Installed in a Nuclear Reactor Facility 1 of a Nuclear Power Plant Equipped with Dispenser Feeding Devices Reactor Facility Safe Operation Before and After Dual Structure Block Tank Dust Collector Reactor Operation ;

The distribution input device of the nuclear power generation facility unit 811 includes a double structure block tank dust collector reactor facility of a nuclear power generation system in which the outer wall surface of the nuclear reactor building of the dual structure block tank dust collector reactor equipment of the fifth wall (224) Radiation nuclear wastes (224) connected to one of the nuclear reactors of a nuclear power plant containing nuclear reactors (1) Nuclear reactors of the nuclear power plant The nuclear power generated at the time before and after operation of the nuclear power plant includes a steam turbine 267 generating nuclear fission in the nuclear reactor facility to generate steam 780 to rotate the steam turbine 267 to generate power, The nuclear power generator 772 for providing the power conversion produced from the nuclear power plant 267 and the steam turbine 267 and the nuclear power generator 772 A rotating rotor electromagnet coil 774 for a nuclear power generator installed along a circumferential surface of a connecting rotating shaft 198 and a rotating electromagnet coil 774 for rotating the rotor electromagnet coil 774 for the nuclear power generator, The nuclear plant generator 811 includes an armature coil 773 and a frame 775 for fixing the rotary shaft 198 to the nuclear power generator 772 and the steam turbine 267. The reactor installation safety Control of nuclear radiation leakage before and after operation Dual structure block tank dust collector (794) Reactor facility to operate nuclear power plant;

The distribution input device of the nuclear power generation facility unit 811 includes a cooling water pipe line 352 having a connection structure with the condenser 790 at a lower portion of the body of the steam turbine 267 of the nuclear power generation facility unit 811, A circulation water pump 242 for providing a connection with the piping line 169 and the cooling water 287 piping line 352 is provided at the front of the condenser 790 in order to perform a nuclear reactor radiation leakage control double structure block Tank Dust Collector (794) Configured to operate nuclear reactors at reactor facilities;

A feed pump 241 is formed at the rear end of the condenser 790 and outside the nuclear reactor facility and a purifier 809 is installed outside the reactor facility in front of the feed pump 241 A plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 in which the fuel of the uranium 812 is stored so that the inside of the reactor pressure vessel 813 The control rod 798 is installed in the core at a time so that the reactor can be provided with an emergency stop. However, at the same time, when the double structure block tank dust collector (794) In the nuclear reactor facility, the cooling water (287) and the mixture of the loess and the loess are put into the pressure vessel (813) at the same time, (794) The reactor structure is configured to operate the nuclear power plant;

The distribution input apparatus of the nuclear power generation facility unit 811 has a structure in which a clad pipe 682 for protecting the first wall pellet 683 and the second wall frit rod 689 is installed in a plurality of reactor installations from a seismic occurrence The safety valves 472 in which the plurality of temperature pressure sensors are formed in the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 are opened and the pressure vessel 813 of the upper block piping line Detonated nuclear waste 224 passes through the inner block piping 74a of the inner block tank 74 and the outer block piping 74b communicates with the fuel explosion-preventing control article cooling water stored in the inner block tank 596 The yellow loess mixtures which generate soap bubbles are transported to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241. In the inner bottom of each of the double structure block tanks 598, The wastes 224 may be stored for movement, The temperature block sensor control valve 472 connected to the lock tank 596 is opened and at the same time the outer block pipe 74b of the block piping line 74 is connected to the fuel block control water coolant And the loess mixtures which generate soap bubbles are transferred to the interior of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the feed pump 241. At the same time, The energy of the water is converted into kinetic energy, and the water is transferred to the interior of the nuclear reactor facility. At the same time, the inner block tank 596 and the outer block tank 599 are filled with the stored coolant and yellow soil mixtures, (794), which is an alternative to reactor building, is provided as a substitute injector for nuclear reactor building. Configuration be made to the nuclear power plant operation and can double the building block dust collector tank (794) equipment to provide a soil mixture, and;

The dispensing apparatus of the nuclear power generation facility unit 811 includes a remote control cutter and a robot 700 for disassembling the reactor facility of the nuclear power plant and a plurality of temperature pressures In the distribution input device of the nuclear power plant 811 in which the detection sensor safety valves 472 are closed, a plurality of temperature pressure detection sensor safety valves 472 are normally closed when the reactor is operated, (591) of the nuclear power plant to be installed on the ocean barge line (591);

The distribution and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear reactor radiation leakage control dual structure block tank dust collector 794 installed in the marine anti-submersible floating barge line, so as not to be restricted by the weather conditions of earthquakes and tsunamis The position of the nuclear power installation at 40m above the sea level is controlled by the mooring device and the diving and buoyancy control devices installed on the floodgate of the anti-submerged buoyant type, but also the flood control which is not affected by the earthquake and tsunami Nuclear power plants are constructed to operate nuclear reactors with a dual-structure block tank dust collector (794) to prevent nuclear reactors from exploding at nuclear power plants;

The distribution and input device of the nuclear power generation facility unit 811 may include a reactor structure including a double structure block tank dust collector 794 to prevent explosion of a reactor in a nuclear fuel chamber to prevent environmental pollution due to nuclear waste, Axis; and

The distribution and input device of the nuclear power generation facility unit 811 is a barge that provides safe and continuous operation of the nuclear power plant, guarantees the safety of the nuclear power generation facility, ensures the renovation of the reactor with continuous operation, In addition to providing the mooring device, the diving buoyancy control device, the nuclear waste disposal dispensing device, and the fuel explosion control distribution dispensing device, it is also possible to prevent pollution of the environment due to the nuclear waste, The nuclear waste disposal system of the non-explosion dual structure block tank dust collector is installed in the nuclear reactor main body 1 of the nuclear power plant, and the mooring device, the diving buoy control device, Waste Treatment Dispensing Apparatus and Nuclear Reactor Facilities Before the safety operation, FUSSIA Nuclear Power Plant (811) Water treatment tube manufacturing process of the connecting shaft (705);

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The diving preparation ready operation control regulating and distributing apparatus for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor plant of the double structure block tank dust collector of the nuclear power generation facility unit 811,

The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear plant power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean, and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) I composed and;

The distribution dispenser of the nuclear power generation facility unit 811 is installed at the top of the sea level 40 m so as not to be restricted by the weather condition, and the distribution power supply unit of the nuclear power generation facility unit 811 is provided with a floating nuclear power plant 672, (638), anchor chain (640), rocker bed (616), rotary table lathe machine (908) of crude drilling machine and buoyancy regulator piping line automatic pneumatic valve transport device (916), a vacuum pump (635), a high pressure multi-stage multi-stage disaster prevention pump (8) for a disaster prevention pump, and a double structural block tank dust collector (794) for controlling the hull barrel torsion tank. A Bell-rotor butterfly valve 305 of a diving control device of a piping line having a connection structure of a plug-through wire net 28 and a jet pump 157, a nuclear waste disposal control valve 305 of a nuclear waste disposal storage tank and a doctor venture 585, A solenoid formed in the hydraulic cylinder device 624 for the block inlet port 585a and the doctor ventilation outlet port 585b and the hydraulic cylinder door 624 for the block tank hull traffic control device and the hydraulic unit for the block- Valve (76) Diverge position control of each connecting valve and hull, Movement control of diving buoyancy control valve (949), Adjustment of throttling control, and operation of large Marine Nuclear Power Station floodgate (595) (595) operating structure at the same time as the ship's weight, sea level gravity and buoyancy are generated, and buoyancy generated by sea level gravity causes the large ocean nuclear power plant floodgate (595) to float slowly to the sea A plurality of bollards 638 for holding a ship mooring rope of a barge and a ship mooring canceller are connected to a strut tank upper barge hull 591 and a holding tank lower barge hull 592, The anchor 639 formed on the anchor chain 640 for connecting the bollard 638 and the mooring device anchor 639 is pierced by the winch 137 to the seabed (595) of a large marine nuclear power plant. (595) When an underwater anchor (595) is anchored to the barge hull by an anchor ring device and the sea floor depth is deeper than the continental shelf depth, crude oil (908) of the drilling machine for drilling, and the anchorage of the marine nuclear power station floating ship (595) of the above-mentioned large-scale marine nuclear power plant is provided with an anchor ring device, And the operation of the feed dog 185 is performed by folding the body of the feed dog 185 with the hydraulic cylinder hydraulic pressure key 623 formed at the hydraulic cylinder 623 of the mooring unit replacing the hydraulic cylinder hydraulic pressure pad 623,(595) of the marine nuclear power plant is lifted, or when the hydraulic cylinder (623) of the hydraulic cylinder is operated by the umbrella pushing operation of the main body (185), a large marine nuclear power plant lifting plant 595) Anchor bolting mooring arrangements with barge hull anchoring arrangements to adjust the height of barge elevation. Nuclear power plant flood control console (595) Double structure block tank Barge hull anchoring Anchor bolting Mooring device Nuclear power plant operation The equipment is configured to operate before and after operation of the nuclear power plant;

The distribution input device of the nuclear power generation facility unit 811 includes an air receiver tank 145 for an air storage tank for providing diving control of the floating pick-up hood into the reactor facility main body 1 of a floating power plant nuclear power plant of a marine power plant, An air liquefying apparatus cooling mechanism cooling fan 645 of the HV system and a heater fan (not shown) for floating the air balloon 78, the rubber balloon 914 and the tube 188 in the air 642), maritime pirates that cause war, and those who are engaged in international diplomatic disputes, are expelled from the global atmosphere by satellite launchers (643), satellites and airships, and at the same time, An air compressor 80 is installed in the reactor launching base 643 and the space rocket launching base 646. The air compressor 80 is installed in the reactor installation main body 1 of the reactor main body 1, At the same time, the tackle winch 137 operated by the compressed air supplied from the air compressor 80 is used as a dual structure block tank dispensing device of the nuclear power plant 811 of the Nuclear Power Plant Lt; / RTI &gt;

The distribution and input device of the nuclear power plant 811 includes a crane 861 installed at the top of the floating deck hull deck (SDU), a wire rope 19 included in the crane 861, a wire rope chain 915 And an air hose 109 connected to the front of the trolley winch 137 in front of and behind the air receiver tank at the rear of the air compressor 80 and an electric magnet magnet 645 A pipeline line automatic pneumatic conveying device 916 for conveying loess and cement by piping and high pressure hose, and a mixing equipment mixer machine 73 for providing a position in front of the pipeline automatic pneumatic conveying device 916 And a lever block 123 is provided for each tonnage capacity so as to be combined in units of a dual structure block tank 598 to provide a combined nuclear reactor facility of a marine nuclear power plant in units of a dual structure block tank 598, The distribution of the equipment 811 The apparatus is provided with a machining hole for male and female engaging in an iron plate bracket 165 which is coupled with a holding tank and a holding tank combining part by a bolt-nut, while securing the fastening object again with the turn- In the tank facility, there is a joint between the flange and the flange on the welded part which can withstand high pressure, and the distribution of the nuclear waste treatment reactor equipment (811) of the nuclear waste disposal reactor facility of the marine nuclear power plant The reactor is operated to operate the nuclear power plant;

The distribution and dispensing apparatus of the nuclear power generation facility unit 811 is arranged such that the rubber packing 32 of the gasket packing is connected to the intermediate portion of the gap between the large flange 614 and the large flange 614, The block tank assembly is provided with a large flange machining hole 615 with high strength bolts and nuts for connection to the inside and outside of the dual structure block tank 598 and to the double structure block tank flange 614 and other engaging flanges 614 , While at the same time the dual structure block tank flange 614 is connected to the dual structure block tank connection inside the reactor installation body 1 of the nuclear power plant and the high pressure stage multi stage pump 8 and the doctor ventilation fan 195 are operated The opening of the ballastere butterfly valve 622 is provided by the actuation of a valve disk in the Bellluster butterfly valve 622 which allows the float to provide floating humanoid hull diving on the seabed according to the opening of the manhole 610 and the hatch cover 153 Me, Dong The ship's floating hull is floated to the sea, and the barge hull at the bottom of the double structure vertical holding tank is formed into a nuclear waste disposal storage tank generated from the reactor, and the barge ship hull bottom support adjustment mechanism (616) The horizontal axis of the hinged joint of the vertical and horizontal hinges is connected to the long hole 606 of the lug pin 606, Distributor input device flood control The Bellactor Butterfly Valve (622) controls the operation of the nuclear power plant to provide hull diving;

The dispensing apparatus of the nuclear power generation facility unit 811 is provided with a guide rail 618 for deck deck upper end equipment transfer and a helicopter station 619 as the upper end of a floating deck deck deck, (623) for a semi-submerged operation line on which a double-structure block tank frame combination in the form of a folding umbrella is provided for a marine operation, and a hydraulic cylinder operation key (598) Combined tool fixture The band guide (621) is equipped with a hydraulic cylinder mounted on a semi-submerged working line (637), and at the same time The coupling facility of the double structure block tank of the distribution input device of the nuclear power generation facility unit 811 includes a control device for controlling floatation of the submarine diving submarine The motor control unit of the motor of the motor of the coupling motor of the dual structure block tank is provided with the twin butterfly valve 622 and the above- The interior equipment includes a hood 193, a retaining ring 194, a fan 195, a body frame 196, a body front reinforcing steel plate 197, a rotary shaft 198 and a rotor assembly 199, The frame 202 and the terminal box 203, the lifting bolts 204 and the terminal box cover 205, the rear rotation bearing 206 and the rear reinforcing steel plate 207 An assembly of the rotor 208, the protective cover 209, the rotor core 210, the stator core 211 and the stator windings 212 is provided and power is supplied to the motor body 192 of the motor, It is necessary to prevent the sinking in case of damage to the defective part of the ship and to construct the source structure of the extension time An electronic control device for providing a connection structure with the equipment doctor ventilation 585 of the HVAC system for one hour and the mineral resource intake port suction control device by adjusting the water pressure in the floating hood 58 is provided with switch button ON- A stopper plate 625 formed of a hydraulic cylinder door 624 for closing the door when the door is opened and closing the switch button off-state, and a stopper wire netting 28 for blocking access to the inlet of the inlet of the hull, Electronic control devices to ensure continuous operation of nuclear reactors for nuclear waste disposal facilities before and after the operation of nuclear reactors in marine nuclear power plants;

The distribution apparatus of the nuclear power generation facility unit 811 is provided with an air pipeline 181 for preventing sinking of the hull and an emergency engine 226 for extending the prevention of hull sinking prevention. (628) for the identification of the position of the double pipe structure tank, which is designed to prevent access to other ships during the safe marine assembly period, and at the same time, the rope for dismantling rope 629 and rope connecting knot claws 630 and at the same time the emergency step 631 facility into the block pylon 116 is provided with elevator alibault 636 and double structure block tank holding tank upper barge hull 591), a discharge suction vacuum pump (635) for adjusting the balance between the conveyor (633) for mineral and mechanical equipment conveying equipment and the lower tank barge hull (592) of the holding tank, and an air intake The air supply lines 634 of the inlet and outlet units, and at the same time, the distribution input unit parts of the nuclear power generation facility 811 are installed at marine vessel manufacturing plants and industrial sites in the heavy industry, The tugboat 666 is provided with a conveyor 633 for a mechanical equipment conveying device and a boom barge rubber balloon 628 for controlling the elevation of the barge line. Nuclear waste treatment of nuclear power plants at Fushy before the safe operation; Nuclear power plant (811);

The distribution input apparatus of the nuclear power generation facility unit 811 is a nuclear waste management system in which the nuclear power generation facility of the nuclear power plant can be prevented from exploding without being affected by earthquakes and tsunamis. Nuclear waste disposal and dispensing equipment that prevents pollution of the environment is a double structure block tank in which nuclear reactors in a nuclear fuel chamber are prevented from exploding. Nuclear reactor facilities In nuclear power plants, nuclear reactors formed from the first wall to the fifth wall The double structure block tank is formed of a plurality of double structure block tanks in a storage tank, and the double structure block tank is formed of an inner block tank and outer block tanks to prevent the explosion of the reactor. To ensure the safety of a nuclear power plant so that continuous operation can be carried out, and at the same time, And a nuclear explosion-proof double structure block tank dust collector (794) for preparing a repair safety guarantee and for treating the nuclear waste, the nuclear power plant connecting shaft

The nuclear reactor waste 224 that is exploded into the block piping line 74 passes through the double structure block tank reactor nuclear reactor facility to prevent the nuclear reactor room from exploding into the nuclear reactor facility body, And a robot 700 for cutting the nuclear reactor waste by the remote control during the decommissioning of the reactor facility of the nuclear power plant having a shortened life span at the same time. The internal explosion of the reactor pressure vessel 813 The safety valves 472 are closed so that the safety valves 472 are closed. In addition, when the reactor facilities are operated, the remote control device robots 700 In addition, it is necessary to establish the continuous operation of nuclear reactors for the nuclear waste disposal of marine nuclear power plants before the safety operation of reactor facilities, (1) of the nuclear power plant in which the nuclear reactor internal and external nuclear reactors are not detonated, and the nuclear waste And the nuclear power plant (671), the docking buoyancy regulator, the nuclear waste disposal and distribution system, and the nuclear reactor facility. The connection axis of the nuclear waste disposal dispenser equipment of the facility;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The nuclear waste disposal dispensing device of the reactor facility for the hull safety facility constituting the connection axis position of the nuclear waste disposal dispenser of the nuclear reactor facility, the dual structural block tank dust collector of the nuclear power generation facility (811)

The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a nuclear power plant main body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control to Prevent Explosion Dual Structure Block Tank Dust Collector (794) Nuclear Waste Treatment Unit Configuration be made for continuous operation of nuclear power plants operating in the distribution chute and;

The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility 811 includes water leaking from the valve of the nuclear power plant 672 and water in the building inside the nuclear power plant main body 1 of the floating nuclear power plant of the marine power plant The washing water in the case where the regenerated liquid of the ion exchange resin is a liquid is collected in the storage tank 216 and the nuclear waste disposal filtration is provided by the filter 217. At the same time, ) To measure the radioactivity and to confirm that there is no harm, water other than the washing water to be sent to the sea together with the cooling seawater is purified by the filter (217), while the filtered water and the distilled water At the same time as the reactor coolant is provided, the nuclear waste disposal and dispensing facility is equipped with monitoring posts 219 for monitoring the nuclear reactor facility of the floating nuclear power plant of a marine power plant 1) To prevent nuclear radiation contamination both inside and outside. At the same time, nuclear waste disposal and dispensing equipment is installed in the reactor main body (1) of the nuclear power plant, and a mooring device And diving buoyancy control device and nuclear waste disposal unit and nuclear reactor facility safety operation Fusi Nuclear Power Plant Division (811) double-structure block tank Dust Collector Nuclear waste disposal unit of nuclear reactor waste disposal unit

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) The nuclear waste disposal dispensing device of the reactor facility for the hull safety facility constituting the connection axis position of the nuclear waste disposal dispenser of the nuclear reactor facility, the dual structural block tank dust collector of the nuclear power generation facility (811)

The nuclear waste disposal and dispensing apparatus of the reactor facility of the nuclear power generation facility 811 includes a nuclear power plant 672 of a marine nuclear power plant and a reactor structure of nuclear power plant 1, 794), and a nuclear fuel explosion control distribution input device. It is also possible to install a plurality of nuclear reactor facilities on the barge of an anti-sinking double structure block tank of the ocean, and to prevent the earthquake and tsunami Nuclear power plant (811) Nuclear waste disposal system installed at 40m above the sea level to prevent the sinking Prevent sinking type barge line reactor facility Safe operation Reactor facility to establish safe operation facility Safety facility operation device Nuclear power Nuclear Power Generation in Nuclear Power Plants Nuclear Radiation Leakage Control to Prevent Explosion of Multiple Nuclear Reactor Facilities Dual Structure Block Tank House Configuration be made up the original operation to the exchanger 794 nuclear waste disposal distribution chute of a nuclear reactor plant, and;

In the nuclear waste disposal and dispensing apparatus of the reactor facility of the nuclear power generation facility 811, when the air contained in the inside of the building and the water contained in the inside of the reactor is gas, an activated film gas which weakens the radioactivity when the pressurized water reactor is operated The ventilation system of the power plant is provided with a plurality of symmetrical filters 214 for discharging the purified air to the outside air by the hold-up device 213 and discharging all of the ventilated air from the exhaust tower 215, (1) Nuclear waste treatment (811) of the nuclear power plant (811), in which nuclear waste disposal (224) treatment system is used to prevent nuclear radiation contamination inside and outside the reactor main body The distribution dispenser is provided with a nuclear power plant (672) inside the nuclear reactor main body (1) of the floating nuclear power plant of the marine nuclear power plant, At the same time, when the ion exchange resin and the filter medium are solid, the filter sludge and the used resin liquid are supplied to the storage tank 216 in the form of nuclear waste The paper and cloth contaminated with nuclear radioactivity are compressed to provide volume compression. At the same time, all of the nuclear waste is solidified into concrete and filled in the drum 220, and the inside of the nuclear waste disposal building site The nuclear waste storage 224 and the nuclear waste storage building 332 and the monitoring monitoring posts 219 are provided for the nuclear waste disposal of the forklift truck, 593,594,595) Nuclear power plant main body (1) Prevention of nuclear radiation contamination both inside and outside of a marine power station Mooring device and diving buoyancy system After the nuclear waste disposal apparatus and a distribution chute and before the reactor equipment safe operation of the reactor equipment at nuclear power seolbibu 811 double structure block dust collector tank of a nuclear reactor plant nuclear waste processing plant distribution chute in connection shaft;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, and the nuclear plant main body 1 (1) of the nuclear power plant. ) Nuclear Power Generation Facilities (811) to Nuclear Power Nuclear Waste Treatment Unit (811a) Dual Structure Block Tank Dust Collector Nuclear Waste Treatment Equipment for Nuclear Reactor Facilities Discharge Nuclear Waste (224) to the nuclear fuel cycle of the nuclear fuel industry The nuclear waste disposal dispenser equipment of the reactor facility for the constituting hull safety facilities,

The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear radiation leakage control dual structure block tank collector 794 into the nuclear power plant 672 of the marine power plant and the reactor facility body 1 of the nuclear power plant, ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control that Multiple Nuclear Reactors Can not Explode Dual Structure Block Tank Dust Collector (794) The nuclear power plant (811) 's nuclear waste disposal and dispensing facility is configured to operate the nuclear power plant;

The nuclear fuel cycle of the nuclear waste fuel plant of the nuclear waste treatment facility includes the nuclear fuel plant 593,594,595 of the ocean power plant and the nuclear fuel 683 used in the nuclear reactor main body 1 of the nuclear power plant, Uranium 812 can be processed at uranium fluoride 812 in a conversion plant 229 that allows for the processing of nuclear fuel 683 at the reprocessing plant 228, In the nuclear fuel cycle of the industry, as the enrichment plant 230, the nuclear fuel 683 is transferred to the carrier, while at the same time the uranium fluoride 812 is converted to uranium dioxide at the conversion plant 229, At the same time, the nuclear fuel cycle of the nuclear waste fuel industry is processed in the form of pellets 683 to provide a fuel rod 689. At the same time, the plutonium 801 processed in the reprocessing plant is fed to the conversion / processing plant 231 At the same time, these reprocessing fuel rods 689 again transport the nuclear fuel 683 to the nuclear power plant 672 by means of a carrier forklift, and at the same time, the nuclear power plant 672 , A reprocessing plant 228 and a concentration plant 230 and a conversion plant 229 and a conversion and processing plant 231 are installed at the top of a sea sinking anti-sinking type floating barge deck deck at the top of the sea, Connection axis; and

Nuclear waste (224) disposal unit, the nuclear waste (224) treatment of the nuclear fuel industry of the nuclear fuel industry preventing the nuclear radiation contamination from inside and outside is carried out into the reactor main body (1) of the nuclear power plant, (794), and a mooring device, a diving buoyancy control device, and a nuclear waste disposal dispenser installed in a nuclear power plant (672) of a marine power plant, Fusi Nuclear Power Generation Facilities (811) to connect nuclear waste disposal dispenser equipment of reactor facilities;

(593,594,595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants, as well as nuclear power plants Nuclear Reactor Facilities (1) Nuclear Power Generation Facilities (811) Nuclear Power Generation Nuclear Waste Treatment Facilities (811a) Double Structure Block Tank Collector Nuclear Waste Treatment of Discharge Facilities Discharge Nuclear Reactor (224) The nuclear waste disposal dispenser facility of a nuclear reactor facility for hull safety equipment,

The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear radiation leakage control dual structure block tank collector 794 into the nuclear power plant 672 of the marine power plant and the reactor facility body 1 of the nuclear power plant, ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Reactor Facility Nuclear waste disposal and dispensing equipment to operate the nuclear power plant;

The nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a comprising the nuclear power plant floating support 593,594,595 nuclear power plant 672 and the nuclear power generation facility unit 811 of the nuclear power plant main body 1 of the nuclear power plant,

The nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a includes the nuclear waste treatment unit 1 of the nuclear power plant and the nuclear power plant 672 of the marine power station 593,594,595, (224) include permanent heavy nuclear waste disposal facility equipment with a long half-life, including construction machine heavy equipment hoe (877) and excavator (845) to provide nuclear waste (224) And at the same time constituting the nuclear waste disposal system as construction equipment with the nuclear waste disposal facility 224, and at the same time, the nuclear waste disposal facility facility is constituted by fission in the nuclear reactor 811 to constitute a conversion into another material , The construction of nuclear waste (224) according to the depth of the strata and the depth of the seabed is carried out by construction machines. At the same time, nuclear waste disposal is carried out by the construction equipment heavy equipment hire (877) and excavator Be configured at the same time while the nuclear waste disposal apparatus, the vessel, made be configured nuclear waste in shipping the double tube structure, drum 220 containing the nuclear waste to the buried region in the nuclear waste 224 apparatus vessels and equipment;

The nuclear waste disposal apparatus transportation facility of the nuclear power generation nuclear waste disposal unit 811a includes a double pipe structure drum 601 containing nuclear waste at the upper end of the barge deck deck 591 provided with the space rocket 612 and the space rocket launching rods 646, (224) processing unit space rocket (612) and a space rocket launching unit (646) transportation facility, which is configured to transmit the nuclear waste (220) to the space rocket (612) (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear waste (224) treatment device inside and outside to prevent pollution of nuclear radiation Space rocket (612) and space rocket launcher (646) (593, 594, &lt; RTI ID = 0.0 &gt; 593, &lt; / RTI &gt; 594, &lt; RTI ID = 0.0 &gt; 595) The facility of the disaster prevention apparatus which constitutes the inside of the connection shaft of the nuclear power plant (672) and the reactor facility main body (1) of the nuclear power plant,

The facilities of the disaster prevention apparatus constituted inside the connection shaft include a flood control unit 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 inside a reactor facility main body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) The nuclear power plant is operated by the facilities of the disaster prevention apparatus to be constructed;

Nuclear Waste Treatment of Nuclear Power Plant (811) Dual Structure Block Tank Dust Collector Installations of offshore and offshore marine power plants equipped with nuclear reactors (593,594,595) Nuclear power plants (672) and nuclear reactor plant main body (1) And

In the disaster prevention apparatus equipment constructed inside the connection shaft, a disaster prevention line to which typhoons are latent is provided with an injection nozzle, a diaphragm rubber balloon 628, a rope rope 629, rope knot hooks 630 ), A marine cable car (256), an unmanned camera (184), a high pressure type multi-stage disaster prevention pump (8), a double structure nozzle hose and a double structure fire hose (9) The satellite weather forecast information collecting machine 960 of the weathering air bag 130 and the weather forecasting 958 and the electronic control unit of the disaster control pump control system and the control system 150 and the air supply (942) Connected structure It is constituted by facilities of disaster prevention device and at the same time disaster prevention facilities are equipped with facilities for disaster such as earthlamp and coastal cumulonimbus and cataclysm in which global warming phenomenon is resolved. At the same time, facilities for sound vibration and frequency disaster prevention equipment are provided, and at the same time, facilities for disaster prevention equipment are provided with facility facilities for disaster prevention equipment in accordance with the power of wind equivalent to artificial waterfall falling sound, And a radial type dispersing and disbursing device, a submarine mineral air bag 130, a substitute goods sail 959, and a seesaw crane of a towel crane (942) to provide the discharge of water over the sea and over the sea. At the same time, the sound emission frequency and sound wave vibration wave that substitute the radiation type dispersing and disrupting device are transmitted. At the same time, the facilities of the disaster prevention device are equipped with the wind along with the wind above the sea surface, and prevent the occurrence of the severe typhoon, (672) of the marine power plant, and a lightning rod (603) which is positioned at the top of the block pylon (116) at the upper deck deck of the marine power plant. The location of the lightning rod 500 on the rooftop of the control tower of the mooring tower 644 is provided in the lightning rod 500 of the block pylon tower 116, Weather observation equipment Radar (840) A lightning rod (500) that keeps the hull from lightning and lightning on the control tower is provided with peaceful earth environment preservation. In addition, a reactor structure disaster prevention device of a nuclear power plant with double structure block tank reactor At the same time, it is necessary to prepare a disaster prevention structure inside the reactor main body (1) of a nuclear power plant, and to install a disaster prevention structure Mooring device and diving buoyancy control device of nuclear power plant (672), distribution and input device of nuclear waste disposal and nuclear reactor facility safety operation Before the safe operation, FUJITSU nuclear power generation facility (811) The facility connection axis of the disaster prevention device to be constructed;

(811) nuclear waste treatment dual structure block tank dust collector reactor facility, and a marine power plant having a reactor facility of the marine ship manufacturing plant (593,594,595) Nuclear power plants (672) and reactor facilities of a nuclear power plant (1)

The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear plant power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean, and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control to Prevent Explosion Dual Structure Block Tank Dust Collector (794) Consists of Reactor Facility Connecting Shaft It is configured to be made up the original operation of the equipment and emergency devices;

The facilities of the nuclear power plant of the marine power plant (593,594,595) and the nuclear power plant of the nuclear power plant (1) include the nuclear power plant (811) A connection shaft (1) of the facility body

In the installation of the disaster prevention device of the nuclear power plant 811 constituting the inside of the connection shaft of the reactor installation main body 1 of the floating support type nuclear power plant, the number of injections for providing the ejection through the gap between the dual structure injection nozzles is naturally At the same time, the disaster prevention apparatus of the nuclear power generation facility unit 811 is provided with a shuttlecock for reducing the power of the wind, The air compressor 80 forms a piston-type air compressor 80 which is operative by an electronic control unit 88 and which is connected to the pressure reducing valve 85 and the safety valve 259 without an electronic control unit 88 The motor cover 252 and the motor cover 250 together with the belt cover 261 and the air suction filter 262 together with the first pressure check sensor 86 and the second pressure check sensor 87, And an oil cooler 151 are formed, The tank of the oil cooler 151 is provided with a cooling water inlet 287 and attached to the upper end of the channel base of the bed frame 286 to produce air together with the injection nozzle 10, The equipment of the disaster prevention device of the nuclear power plant 811 having the combination of the hose 947 and the high pressure hose 190 with the coupling 29 of the high pressure hose connection and the latent power of the typhoon at the same time, The disaster prevention device is installed at the upper and lower sides of the sea surface where the airflow 925 and the downward airflow 926 are controlled together with the yellow sand fine dust so that the disaster prevention and control are simultaneously performed. There are several manhole covers 152, several hatch covers 153 and several fire doors 154, which prevent the sailing vessel from losing its restoring power freely from a natural disaster of the typhoon,And the safety regulations of the International Maritime Safety Association are faithfully executed. At the same time, the nuclear power generation facilities 811, The discharge jetting number 38 for continuously dropping the jetting water gap is provided at the dropping point of the jetting jetting number 38 for dropping the power of the typhoon, With the number of ejection nozzles 38 forming a continuous falling drop, and at the same time, the same level of artificial waterfall roaring, which allows the power of the typhoon to be subdued, This scene, in which a strong typhoon is transformed into a warm wind, but at the same time, the power of the typhoon is reduced, is replaced by an unmanned camera (184) (593,594,595) of the marine power plant which was sent from the radar meteorological observation center to control the upward airflow (925) and the downward airflow (926) of the typhoon together with the dust dust. The unmanned camera 184 and the weather observation equipment radiosonde weather observation radar 840 are mounted inside the basket 1 inside the main body 1 and the basket 42 on which the lower end fillet is mounted, A rubber tube 947 for introducing air for the inside of the container for the inflow control device provided in a connection structure to the bottom line 945 and the submarine line wiring 946 and a furnace 948 of the furnace 948 for continuous operation of the furnace 948 Nuclear Radiation Leakage Control by the Bricks 948a In the interior of the double structure block tank dust collector 794, provision of the disaster prevention device of the nuclear power generation facility 811 is provided with the input of the raw material bricks 948a of the blast furnace 948, I (949) for diving buoyancy control, a thermocouple thermometer switch (950) for thermo-sensor, and a seesaw crane boom zone (942) for tow-crane replacement tower crane A large hydraulic power generator seesaw facility 944 is connected to the hydraulic aerator 943a of the marine seesaw hydroelectric power plant 943, the Phelpton aberger 943b for a large hydroelectric power plant, and the Francis turbines 943c for a large hydroelectric power plant, (952) of the non-powered pump for the energy control device of the water, which is provided with the hydraulic power supply and the connecting structure, and the hatch basket (951) and the military equipment submarine (953) A laser cutting machine 954 is provided to check the maintenance status of the facility facilities of the disaster prevention apparatus of the nuclear power plant (811) of the main body of the nuclear power plant of the marine power plant (1) (955), which is more powerful than nuclear bombs, is equipped with facilities for disaster prevention at the nuclear power plant (811). At the same time, the World War II, the Korean War and the Cheonan This is the first time that a group of military photographers and imitated statues, who have gathered the characters of the war criminals who made all the military actions and act factors of the act to promote the Yeonpyeong Island bombing and nuclear frenzy experiment, The center of the triangle The 1,200 km radius from the center of the Korean peninsula Coordinates set within the range of 2,400 km in diameter formed inside and outside the United Nations include 38 ° 20 '00 ° north latitude center of the Korean peninsula and 127 ° 17' Kangwon-do, Gangwon-do, Gangwon-eup, Gangsan-ri, 190 In the center of the Korean Peninsula of the Imayado, the inside of a 200-meter radius is called Northeast Asia No. 1, It is planned to set up a new concept of one of the United Nations' national capitals as an area of 1000 ㎢, while at the same time, a radius of 400 meters and a radius of 1 iri from the surface of the peninsula, The distance range is called Northeast Asia 1500 and the range of 1200 km from the center of the peninsula is called Northeast Asia 3000 and it is confirmed that the old ancestors' 811 are equipped with windmill wind turbine 957a for a wind power generator of a offshore wind power plant 957, disaster prevention nozzles 945 by an underground line and submarine line wiring 946, ) And the satellite weather forecast information collection machine (960) to the inside of the nuclear reactor facility main body (1) of the nuclear power plant and the connection axis of the disaster prevention device of the nuclear power generation equipment section (811) (593,594,595) installed at the nuclear power plant (672), the docking buoyancy regulator and the nuclear waste disposal and distribution system, and the nuclear reactor facility safety operation of the nuclear reactor facilities. The connection axis of the disaster prevention device of the reactor facility;

(811) nuclear waste treatment dual structure block tank dust collector reactor facility, and a marine power plant having a reactor facility of the marine ship manufacturing plant (593,594,595) Nuclear power plants (672) and reactor facilities of a nuclear power plant (1)

The facilities of the nuclear disaster prevention apparatus of the nuclear power generation facility 811 constituting the inside of the connection shaft of the nuclear power plant 1 include the floating nuclear power plant 672 of the offshore power plant and the nuclear power plant 671 of the nuclear power plant Nuclear Waste Dispensing and Discharging Apparatus Having Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector 794 and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A plurality of nuclear reactor facilities are installed on the barge of an anti- And 40m at the top of the sea level so as not to be restricted by the weather conditions of earthquakes and tsunamis. It is equipped with the installation position of the distribution input device of the nuclear power generation facility (811) to prevent sinking prevention barge line reactor facilities. Nuclear reactors that form a nuclear reactor safety operation device Nuclear power plant nuclear reactors that prevent multiple nuclear reactors from exploding Double structure block tank dust collector (794) Reactor system consists of disassembly device inside the connecting shaft to constitute the operation of the nuclear power plant;

The facilities of the disaster prevention device of the nuclear power plant 811 constituted by the floating power plant 593, 594, 595 nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant,

(593,594,595) of the marine power plant; (1) the connecting shaft of the nuclear reactor main body of the nuclear power plant; and

The facilities of the disaster prevention apparatus constituting the inside of the nuclear reactor connection axis include the nuclear reactor main body 1 of the nuclear power plant, the Vladivostok, the Uleungdo, the Dokdo and the Pohang in Russia according to the marine sovereign power line, (941), and at the same time, Yeosu and Jeju Island are connected to the Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941). At the same time, Pyeongtaek, Baekryeongdo and Shandong Peninsula Nuclear Waste Treatment Double Structure Block Tank Provides a connection to the Marine Tunnel Traffic System (941) and provides connections to Pohang and Japan's downstream areas through the nuclear waste disposal dual structure block tank marine tunnel transport system (941) It is necessary to establish the foundation of the Korean federal government, and at the same time to transform it into a one-day living zone, while at the same time, The rope knot claws 630 formed in the fishing pier rubber balloon and the wire rope net (19) in the fishery area provided by the equipment for military defense, It is like a kelp in the sea, so illegal fishing boats provide a net throw to fishing grounds. At the same time, rope knot hooks (630) can be used to limit the entry of illegal fishing boats (593,594,595) at the ocean power plant (673), the diving buoyancy control device and the nuclear waste at the nuclear power plant (672) of the ocean power plant. Nuclear waste treatment of FUJI Nuclear Power Plant (811) before safety operation of nuclear reactor facility installation and dispensing equipment Block precipitator tank reactor plant the land and support of the marine power plant in the ocean sikdok nuclear power plant and equipment connection of the emergency device which consists of a reactor internal equipment body (1) of a nuclear power plant provided with a connecting shaft axis;

(811) nuclear waste treatment dual structure block tank dust collector reactor facility, and a marine power plant having a reactor facility of the marine ship manufacturing plant (593,594,595) Nuclear power plants (672) and reactor facilities of a nuclear power plant (1)

(593,594,595) of the above-mentioned marine power plant The facilities of the nuclear power generation facility (811) constituting the inside of the main shaft of the nuclear power plant (1) include facilities of the floating power plant of the marine power plant (672) Nuclear waste treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus equipped with double structure block tank dust collector 794 for controlling nuclear radiation leakage into facility main body 1 A plurality of nuclear reactor facilities are connected to a barge of an anti- And the installation position of the distribution and input device of the nuclear power plant (811) is set to 40m above the sea level so as not to be restricted by the weather conditions of the earthquake and tsunami. Nuclear reactor safety equipment that forms the safety of Fusi reactor equipment Safety devices of nuclear power plants can not explode Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Configured to operate nuclear reactors;

The facility of the disaster prevention apparatus of the nuclear power plant 811 constituted by the nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant includes facilities of the marine power plant (593,594,595) Nuclear reactor plant main body (1) Connecting axis

The connection axis of the reactor main body 1 of the nuclear power plant is limited to the range of up to 29 km from the ground inside the reactor main body 1 of the nuclear power plant of the nuclear power plant 672 of the floating power plant of the marine power plant At the same time, several floodplains formed above the sea level above sea level 5 and 38 ° above the sea of the East Sea were equipped with military sensor sensors to prevent the production of military equipment. It also has a sensor detection device, but at the same time, it has a restriction to make nuclear facilities of Pyongando and Hamgyeongdo helpless. At the same time, when a nuclear missile is fired, it is formed as a defensive missile attached to the net at the firing position, To automatically shoot down enemy territory to launch its own nuclear missile At the same time, the end of the nuclear weapons buildup was immediately followed by the westward sea level in the sea above the sea and the 38th parallel to the sea in the East Sea. (958), which is more powerful than nuclear bombs, and which is more powerful than nuclear bombs, will be re-installed in each region within a radius of 1200km from the center of the Korean peninsula, And at the same time, it is located outside the area of 29 km above the ground. It is equipped with a sensor sensor for military defense and a disaster prevention netting device formed in a large number of flood control stations in the reactor main body 1 of a nuclear power plant in the ocean and airspace, (593,594,595) Mooring devices and diving buoyancy tanks formed at nuclear power plant (672) Equipment and Nuclear Waste Treatment Dispensing Equipment and Nuclear Reactor Facilities for Safe Operation of Nuclear Reactors Nuclear Waste Treatment of Nuclear Reactor Facilities of Reactor Facilities (811) (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants and the connection axis of the disaster prevention device consisting of the inside of the reactor facility main body (1) of the nuclear power plant;

(811) nuclear waste treatment dual structure block tank dust collector reactor facility, and a marine power plant having a reactor facility of the marine ship manufacturing plant (593,594,595) Nuclear power plants (672) and reactor facilities of a nuclear power plant (1)

The facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power generation facility include a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Configuration be made movable in a nuclear plant disaster prevention apparatus consists of internal equipment, and the connecting shaft;

The facilities of the nuclear power plant of the marine power plant 672 and the nuclear power plant 811 of the nuclear power plant 1 include the nuclear power plant 593,594,595 of the above ocean power plant, A connecting shaft (1) of the reactor installation main body

The vertical structure of the typhoon is provided together with the discharge type of jet 38 of the disaster prevention line which is disposed inside the facilities of the nuclear power generation facility unit 811 to prevent typhoons, , 10 km above the top of the sea level. The disaster prevention system, which provided a disruption device to the sea surface at the top of the SLD at the top of the troposphere at the top of the top of the sea, (958), and at the same time, a seismic crane boom stand (942) of a tow crane replacement tower crane is provided so that a rain cloud is provided to the seafloor 10 km below the sea level, Natural disasters such as artificial waterfalls such as unmanned disaster prevention waterways are installed in the facility of the disaster prevention apparatus of the nuclear power generation facility 811 at the same time The Typhoon is a dual structure of a seismic crane boom zone (942), a tow crane replacement tower crane, which was designed to allow the typhoon of latent heat of atomic bombs of thermal energy estimated to be one million in the past year's Hiroshima to fall into the Pacific Ocean and the Atlantic Ocean. Level piping line 958 for the disaster prevention apparatus, and at the same time, the human beings of the global village are provided with the disaster pumping control system and the electronic system of the control system 150 Control device connection structure The double structure high pressure hose (190) at the top of the sea surface of the connecting shaft provided at the upper part of the sea surface of the connection shaft is formed within 10 km of the coupling part of the high pressure hose (190) (958) Several floodplain decks Decks formed on the side of deck Replacement tower crane Seisio Crane Boom (942) At the same time, the seesaw crane boom zone 942 of the tower crane is provided with a downward flow 926 to convert the upwind flow 925 into an upward flow 925, The pipeline line (958), which is made of non-ferrous metal with better heat conduction efficiency than iron, is equipped with an image of the loess mixture, which is discharged from several double-structured fire-fighting nozzle (10) (1) to the inside of the nuclear power plant (1) Preventive conditions to prevent nuclear radiation leakage Double structure block tank dust collector (794) To connect the inside of reactor connection shaft And the establishment of a disaster prevention device to constitute, and at the same time, in accordance with the establishment of a new federal state in Northeast Asia, At the same time, nuclear plant facilities of land and ocean nuclear power plants. (1) Disaster prevention equipment is equipped with efficient nuclear power plant to maximize the production power while preventing the explosion of reactor facilities. At the same time, (1) of the nuclear power station of the nuclear power plant, the prevention of the sinking of the nuclear power plant, the prevention of the nuclear fuel explosion and the disaster prevention device of the distribution shaft are provided in the reactor main body 1 of the nuclear power plant, Nuclear reactors (811) for nuclear reactors Leakage control Dual structure block tank (794) Nuclear reactors (794) Reactor facilities A connection axis of the disaster prevention device constituting the connection axis;

(811) nuclear waste treatment dual structure block tank dust collector reactor facility, and a marine power plant having a reactor facility of the marine ship manufacturing plant (593,594,595) Nuclear power plants (672) and reactor facilities of a nuclear power plant (1)

The facility of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power generation facility unit 811 is composed of a floating nuclear power plant 672 of a marine power plant and a reactor structural body 1 of a nuclear power plant, A nuclear waste disposal and dispensing apparatus having a dust collector 794 and a nuclear fuel explosion control distribution dispensing apparatus are provided with a plurality of reactor facilities to be installed on a barge of an anti-sinking double structure block tank of the ocean, Nuclear power plant (811) installed at 40m above the sea level to prevent the use of restraint system. Sink prevention type barge line reactor facility equipped with position setting. Nuclear power generation Nuclear radiation leakage control Dual reactor block tank dust collector (794) atom To construct nuclear power plants;

The facilities of the nuclear disaster prevention system of the nuclear power generation facility 811 constituting the connection axis of the nuclear power plant 672 of the offshore power plant and the reactor main body 1 of the nuclear power plant are as follows: (593,594,595) Dual structure block tank (794) to control the nuclear radiation leak that constitutes nuclear power plant (672) and nuclear reactor plant main body (1) of nuclear power plant Nuclear waste treatment dual structure block tank pipe bridge 937) The connection shaft protection system provided with a connection structure capable of disassembling the connection shaft is composed of a connection shaft of a floating nuclear power plant (593,594,595) nuclear power plant (672) of a marine power plant and a nuclear power plant main body (1)

The facilities of the above-mentioned disaster prevention apparatus include a nuclear power plant, a nuclear power plant, a nuclear power plant, and a nuclear power plant, In addition to providing facilities for disaster prevention equipment in a better living environment, at the same time, the facilities of disaster prevention devices must not fall down to imitate the staggering steps of the storks and imitate the storks of the storks, In addition, the leaders of the international community will be equipped with disaster prevention equipment for disaster prevention equipment, including military water tanks, bombers, bombs and bullets And satellites, missiles, nuclear bombs and rocket bombs have been used to make room The facilities of the disaster prevention apparatus are provided, and the facilities of the disaster prevention apparatus are established by the international society codes and norms, and the facilities of the disaster prevention apparatus are provided to overcome the punctured global economic crisis. The provision of a disaster prevention device for a connection shaft that enables the world economy to be saved by fostering the environment friendly non-polluting energy industry, and at the same time, the facilities of the disaster prevention device constituting the inside of the connection shaft of the nuclear power generation facility 811, It is necessary to provide equipment for disaster prevention of connecting shafts that can prevent sinking accident of sailing vessel without any further casualties even if the ship sinks accidentally while sailing in the state. As the vessel of the device is being laid, the facilities of the disaster prevention device are arranged in accordance with the rights and duties of the Korean Federation of Northeast Asia The raw material is supplied to the blast furnace 948 located inside the steel mill so that the reprocessing is provided inside the reactor main body 1 of the nuclear power plant while the construction equipment heavy equipment is installed in the reactor main body 1, The connection axis is composed of a mooring device, a diving buoyancy control device, a nuclear waste disposal dispenser, and a nuclear reactor facility installed at a nuclear plant (593,594,595) nuclear power plant (672) Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Disaster Prevention Equipment Consisting of Connecting Shaft As a connecting structure capable of being disassembled and coupled at a marine shipbuilding factory, Nuclear Waste Treatment for Nuclear Power Plant Dual Structure of Nuclear Power Plant Equipments The fast reactor power plant is technically essential.

In a conventional reactor installation of a nuclear power plant according to the present invention, a reactor installation of a conventional nuclear power plant comprises a structure of a boiling water reactor and a pressurized water reactor using water, and a power reactor is mainly used for a light reactor Nuclear power plants equipped with pressurized water reactors in boiling water reactors and nuclear power plants equipped with multi-purpose high-temperature gas reactors in gas cooling furnaces and high-speed multiplying reactor facilities in new conversion paths are connected to land and the area of the islands. Nuclear reactors often explode due to natural disasters caused by spontaneous typhoons, earthquakes, tsunamis, forest fires, ash and volcanic ash before and after the volcanic eruption.

As shown in FIG. 1, during the operation of the conventional nuclear power plant in the conventional nuclear power plant, when each of the conventional nuclear power plants is close to each other from the time before and after the occurrence of the natural disaster, Which may have a significant impact on the safety of nuclear power plants.

[0001] The present invention relates to a dual-structure, high-speed multiprocessor nuclear reactor facility for a nuclear waste disposal nuclear power plant for nuclear power generation, and more particularly to a nuclear reactor leakage suppression dual structure block tank collector, The best nuclear safety and economical power generation nuclear reactors in the global nuclear power plant are mainly used in light water reactors, boiler water reactor, pressurized water reactor, gas cooling furnace reactor, multi-purpose high temperature gas reactor and new conversion furnace reactor Nuclear waste disposal system for Nuclear Power Plant Operation Nuclear radiation leakage control of Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Connection structure and sinking room The cooling water and the loess mixture of the fuel control deterioration control equipment provided in the nuclear waste disposal apparatus for nuclear power generation including connection to the distribution equipment of the transportation equipment facility which constitutes the foundation of the manufacture and installation of the floating nuclear power plant A double structure storage tank constituting the fuel explosion prevention control article insertion storage and a double structure block tank dust collector connection structure provided as double structure storage tanks for nuclear operation of nuclear waste processing shielding apparatus are connected to a pump and valve generators As nuclear waste disposal control is performed sequentially by nuclear radiation leakage control, the control of nuclear radiation leakage that efficiently improves the operation of nuclear reactors of a plurality of nuclear reactors by each nuclear power plant is provided inside the double structure block tank dust collector, , Safety operation before and after the nuclear power plant operation Alternative generation power production Nuclear power generation including hydroelectric power plant operation for wind turbine and thermal power plant to be installed in the tank. Nuclear power generation including dual-structure block tank dust collector is constructed as a double pipe structure piping line connection structure. The Nuclear Power Generation Facility is equipped with a nuclear power generation nuclear waste disposal unit, a nuclear power generation production unit, a traffic transportation unit of the construction machine that adjusts the position of the control shaft, and a power transmission unit that transmits power. The present invention provides the present invention which is constituted to constitute a double-structure high-speed-proliferation furnace reactor facility of a nuclear waste treatment nuclear power plant for nuclear power plants constituting a regulating apparatus construction machine control section,

In addition, according to the features of the embodiments of the present invention, the double-structure high-speed multiprocess reactor installation of a nuclear waste disposal nuclear power plant for a nuclear power plant is provided with a nuclear power plant reactor facility to ensure free navigation of an aircraft and a ship, Nuclear Waste Treatment for Nuclear Power Generation Dual Structure of Nuclear Power Plant Facility The nuclear reactor facility for fast breeder reactor is designed to comply with the safety rules set by the Ministry of Construction and Transportation of Korea in consideration of safety, In order to ensure the safe operation of the nuclear reactor plant's nuclear reactor facility from the strong wind wave with the revised regulations of the safety review committee, the nuclear reactor nuclear reactor plant body is installed at the lower 40M position of the sea level (SLL) Waste treatment system Double structural block tank pipe bridge Marine tunnel school The length of the device body is connected sequentially to the latitude of the equatorial line and the distance crossing the South Pole and the North Pole. At the same time, for the safety of the reactor plant of the nuclear power plant, Nuclear power plant nuclear reactor main body is at the top of the sea level (SLL) Nuclear waste treatment device Double structural block tank pipe bridge Marine tunnel communication device In the middle of the connecting position, there is a stationary floating docking station Comprising the power plant and the emergency shelter located at the upper part of the deck (SDU) Therefore, the supply of pollution-free electric power to each region of the global village is firstly transferred to the inside of the reactor facility of the nuclear power plant, and the electric power supply line is connected to the nuclear waste disposal unit, the double structure block tank bridge, and the marine tunnel transportation device. The nuclear reactor structure of nuclear power plant, The United Nations Security Council has agreed to dispose of all conventional warfare materials from nuclear bombs in an appropriate manner, and it is not possible for each country to possess nuclear materials for any reason in the land, and nuclear power plants Nuclear Weapons in the vicinity of Power Plants Many countries have nuclear waste treatment connection structures in nuclear power plant reactor facilities to prevent war and terrorism. Dual structure Block tank pipe bridge The distribution device of marine tunnel traffic equipment includes satellite launchers and space In order to prevent the damage of volcanic ash generation before and after spontaneous typhoon, earthquake, tsunami, forest fire, dust and volcanic eruption, Distribution of Preventing Ocean Tunnel Traffic Devices The submersible line is provided with submarine line injection nozzle connection and submarine line injection nozzle. Submarine line wiring is provided to the submarine line processing unit. Scientific Power Generation Equipment and Deep Sea Bottom Mineral Resources and Natural Gas Energy Resources Fuel Oil Excavation Equipment Feng Shui Power Generator Production Marine Power Supply to the Global Community Alternative Transport Equipment Facilities Nuclear Waste Treatment Double Structure Block Tank Bridge Marine Tunnel It is a connection structure of traffic apparatus and it is installed on the circumference surface of the existing reactor 4th wall containment vessel in preparation for the shutdown of the reactor facility and before and after the explosion of the nuclear reactor facility to eliminate the shutdown of the nuclear reactor facility and to prevent the explosion of the nuclear reactor facility. Structure block tank dust collector, and at the marine nuclear power plant barge In order to avoid the restriction of the weather condition from the natural disaster, it constitutes the installation position of the nuclear power generation facility at the upper 40m sea level and dives into the pump and valve of the drilling machine and buoyancy control device in the anchor and anchor chain of the mooring device. Nuclear power plant's nuclear reactor facility is constructed by double structure block tank dust collector to make the cessation of reactor explosion without being influenced by earthquake and tsunami by regulating installation position by regulating lead weights. It prevents environmental pollution due to nuclear waste, Nuclear Radiation Leakage Control without Nuclear Reactor Control Dual Structure Block Tank Dust Collector Discharging Unit to Operate Nuclear Power Plant Nuclear Reactor Nuclear Reactor for Nuclear Reactor Shielding Equipment Safety Half-Life Nuclear wastes have long half-lives that must be kept for thousands of years. The long-term half-life of the waste consists of a double tubular drum containing nuclear waste transported to the buried area and a barge deck with space rockets and space rocket launchers. The dual tubular structure of the drums was moved to the outer space with a space rocket equipped with a locating movement. The nuclear waste was fissioned from the nuclear reactor and converted into other materials. Construction equipment heavy-duty hammers and excavators were installed, A dual structure of a nuclear waste treatment plant for nuclear power plants that constitutes a burial in a glacier and constitutes a nuclear power plant composed of interconnected structures constituting deep buried ground in the sea or ocean to maximize the operation of a nuclear power plant. Fast Reactor Reactor Setup It will be to see the effect provided by the invention, and

In addition, according to the features of the embodiments of the present invention, it is possible to provide a reactor structure of a nuclear power plant, which is provided in the construction designing processes of nuclear explosion prevention measures suitable for the dual structure fast reactor furnace facility of nuclear waste disposal nuclear power plant facilities for nuclear power generation of land and sea Is the height of 40m above sea level is the height of safety passage of the ship with the heavy sea and the general maritime and maritime steel structures, considering the minimum height when refurbishing the bridge body, bridge bridge and nuclear power plant reactor main body, At 10km depth, the ship block tanks and the hulls at the bottom of the holding block tanks are also equipped with a tube-type bridge control device to control the deep water pressure, In order to be able to withstand various kinds of reactor facilities, KSD 3705 hot-rolled stainless steel, KSD 3705, the distribution unit of the nuclear reactor plant is designed to be rigidly supported until the deck deck renovation period in addition to the lifetime of the fixed lifting and floating lifting plates. Nuclear waste disposal of marine vessel alternative traffic facility is possible because it has the effect of connecting the land and the various parts of the island area to the inside of the reactor facility body. Double structure block tank bridge bridge Marine traffic equipment distribution device In order to withstand the natural disasters of the ocean composed of a plurality of reactor facilities of a nuclear power plant, nuclear waste and nuclear radiation pollutants of the reactor, which have the same exhaust gas outlet and entrance as the dust collector of the exhaust gas facility, A double pipe structure block piping line The reactor temperature control sensor of the safety valve detects the temperature of the inside of the reactor in the range of 700 ° C to 800 ° C and the pressure When the dangerous level of the high pressure is reached, the temperature and pressure sensor sends an alarm message to the computer in the safety control room, and at the same time, a plurality of temperature and pressure sensor safety valves are opened to each other. Nuclear wastes pass through and the nuclear waste is stored in each block tank, and the temperature-sensing sensor safety valve connected to the inner block tank at the bottom of the pressure vessel is opened. At the same time, as the outer block piping line, Of cooling water and soap bubble-producing loess mixtures were mixed with water The energy of the reactor is converted into kinetic energy. If the reactor is filled with cooling water and yellow soil mixture in the inside of the reactor pressure vessel and the fourth wall containment vessel, the reactor main body of the nuclear power plant constitutes the explosion stop, Is a block type piping line connection structure having a plurality of safety valve connection structures, and is configured to form a nuclear reactor main body of a nuclear power plant, and the nuclear radiation leakage control dual structure block tank dust collector of the nuclear reactor main body comprises: Nuclear power plant explosion-proof control materials are used to transport and store nuclear power, and nuclear power plants are shielded from nuclear pollutants. Of double structure block tank dust collector In addition, nuclear waste disposal is carried out inside the dual structure block tank dust collector at the same time that nuclear fuel leakage prevention and nuclear fuel explosion prevention to prevent nuclear reactor explosion prevention are performed. At the same time, the reactor facilities of nuclear power plants are connected to the nuclear power plants Nuclear waste treatment dual structure block consisting of the main body of the nuclear reactor of the nuclear power plant, which controls the treatment of nuclear waste to the outside of the tank dust collector, as well as the nuclear waste treatment of land and ocean nuclear power plants, The reactor facility of the nuclear power plant to be installed in the tank dust collector is equipped with a safety pressure valve and water pumps to provide a connection to the double pipe structure block pipe using the water energy of the water, To constitute a conversion into kinetic energy The reactor facility of a nuclear power plant usually uses a nuclear waste disposal system, and is a double structure block tank egg shape, which is a connection structure constructed along the outer wall surface of the former reactor building. The reactor structure of the nuclear power plant is constructed, And nuclear power plants for nuclear power plants, which make up a remarkable difference from the nuclear power plants in the world. By providing the reactor facilities to the world's marine and coastal marine power plants, it contributes greatly to the world economy and global peace. Will be.

FIG. 1 is a schematic diagram of a conventional boiling water reactor installation (802) showing an elemental configuration of a conventional boiling water reactor plant nuclear power plant according to the present invention. 802) Construction of lateral aspect of nuclear power plant.
Figure 1a is a schematic diagram of a conventional boiling water nuclear reactor (802) nuclear reactor plant (802), showing a component configuration of a conventional boiler water reactor plant (802) 688A) and a turbine building 688B and a waste building 688G in a diesel generator building 688E and a nuclear fuel building 688F in a control building 688C and an auxiliary building 688D.
FIG. 1 b is a side view of a conventional boiling water nuclear reactor (802) nuclear power plant showing the essential constitution of an embodiment formed by a conventional boiling water reactor (802) nuclear power plant according to the present invention. An elemental side view.
FIG. 1c is a side view of an elemental conventional boiling water nuclear reactor (802) nuclear power plant operating according to the present invention showing a configuration of a conventional boiling water reactor (802) nuclear power plant. An elemental side view.
FIG. 1d is a side view of a conventional boiling water reactor plant nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional boiling water reactor (802) nuclear power plant according to the present invention. An elemental side view.
1E is a schematic view of a conventional Fukushima boiling water reactor facility 802 according to the present invention, showing the essential constitution of an embodiment formed by the operation of a nuclear power plant, An elemental side view showing the operation of the nuclear power plant as a side view.
FIG. 1F is a schematic diagram of a conventional boiling water reactor (802) nuclear power plant operating at a nuclear power plant, showing the essential constitution of an embodiment of the present invention formed by operation of a nuclear power plant of a conventional boiling water reactor (802) Fig. 3 is a side view of the elemental side view.
FIG. 1G illustrates the operation of the conventional pressurized water reactor (803) of the nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the conventional pressurized water reactor (803) (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
1H is a schematic diagram of a conventional pressurized water reactor type nuclear reactor 803 according to the present invention. The conventional water reactor type nuclear reactor 803 shown in FIG. Fig. 3 is a side view of the element.
FIG. 1I is a schematic diagram showing an operation of a conventional pressurized water reactor (803) of a nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the conventional pressurized water reactor (803) (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
FIG. 1J shows a conventional pressurized water reactor (803) of a conventional nuclear power plant showing the essential constitution of an embodiment formed by operating a nuclear power plant of a conventional pressurized water reactor (803) according to the present invention. (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
1K is a sectional view of a conventional pressurized water reactor type nuclear reactor 803 according to the present invention. The pressure vessel 803 of the conventional pressurized water reactor type nuclear reactor 803 shown in FIG. (813) inside the pressure vessel (813) of the elementary pressurized water reactor (803) shown in FIG.
FIG. 11 is a structural schematic view of nuclear fission of nuclear fuel uranium 235 showing nuclear fission structure of nuclear fuel uranium 235 showing an essential constitution of a nuclear power plant according to an embodiment of the present invention.
FIG. 1 m is a side view partially showing a method of using a control rod for controlling a chain reaction of nuclear fuel fission in a nuclear reactor of a conventional nuclear power plant according to the present invention, and a side view showing a difference between an atomic bomb and a reactor And the lower drawing shows reactor fuel production and reactor steam generation system 1073 in which steam generator 810, pressurizer 814, and coolant 816 are shown in a side view of the process of producing plutonium in uranium 238, Diagram,
FIG. 1n illustrates the operation of a nuclear reactor furnace 804 reactor of a conventional nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional gas cooling furnace reactor 804 according to the present invention. (804) side view diagonal view of an elemental gas cooling furnace reactor as shown on the external side.
(A) is a schematic view of an elementary conventional gas cooling furnace reactor plant 804 showing the configuration of an embodiment formed from a conventional gas cooling furnace reactor facility 804 nuclear power plant according to the present invention, As shown in Fig.
FIG. 1 P is a side view showing a nuclear reactor operation operation mode of a nuclear reactor of a nuclear reactor of the related art, showing a configuration of an embodiment formed as a connection structure of a steam generator 810 of a conventional nuclear reactor nuclear reactor plant according to the present invention (810) of a nuclear reactor plant reactor installation.
FIG. 1q is a schematic diagram of a conventional multi-purpose high-temperature gas furnace reactor 805 showing the essential constitution of a conventional multi-purpose hot gas furnace 805 operated by a nuclear power plant, (804) lateral diagonal configuration of an elementary gas cooling furnace reactor arrangement showing the operation as an external side view.
FIG. 1 r is a schematic diagram of a conventional multi-purpose hot gas furnace 805 showing the construction of a conventional multi-purpose hot gas furnace 805 nuclear power plant according to an embodiment of the present invention. (805) side view showing the elemental multi-purpose high-temperature gas furnace.
FIG. 1s is a schematic diagram showing an essential conventional multi-purpose hot gas furnace 805 showing the construction of a conventional multi-purpose high temperature gas furnace 805 nuclear power plant according to the present invention, Equipment (806) An elemental multi-purpose hot gas furnace (805) and a new conversion furnace reactor (806) side view showing the decommissioning side view of nuclear power plant operation.
FIG. 1 (a) is a schematic view showing a nuclear power plant of a conventional nuclear power plant showing an essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the nuclear power plant of the present invention, Transition reactor installation (806) Side perspective configuration.
FIG. 1U is a schematic view of a nuclear power plant 672 according to an embodiment of the present invention in which a new conversion furnace reactor facility 806 of a conventional nuclear power plant 672 is installed in a reactor facility body of a nuclear power plant having a dual structure block tank dust collector The present invention relates to a dual structural block for the treatment of nuclear waste. The present invention relates to a new type conversion block provided in a reactor facility of a nuclear power plant having a tank dust collector. (806) An elemental nuclear waste A reactor structure of a nuclear power plant having a tank dust collector. A side view of a new reactor furnace facility (806) constructed in the present invention.
FIG. 1 v is a cross-sectional view of an elemental conventional nuclear power plant reactor building 688 showing the configuration of one embodiment of a conventional nuclear power plant according to the present invention, and an elemental reactor building 688) and a detailed side view of the fuel rod (689).
FIG. 1w illustrates the operation of the nuclear reactor plant 838 of a conventional nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of a nuclear power plant of a conventional high-speed breeder reactor facility 838 according to the present invention A schematic view of an elemental side view showing the external side.
1x illustrates the operation of the nuclear reactor of the nuclear reactor of the present invention in a conventional fast breeder nuclear reactor (838) nuclear power plant, (838) disassembled lateral strabismus configuration.
FIG. 1 (Y) is a side view of an elementary conventional fast breeder reactor facility 838 nuclear power station showing the configuration of one embodiment formed from a conventional fast breeder nuclear reactor facility 838 nuclear power plant according to the present invention, (838) side view of the reactor.
Figure 1z illustrates a method of processing nuclear waste according to the prior design of a plutonium disposal process 1040 in the dismantling of nuclear weapons from the disassembly facility 1030 of the nuclear base 1029 of the conventional nuclear power plant nuclear waste disposal method according to the present invention FIG. 2 is a schematic view of a conventional elemental nuclear waste disposal method showing the difference between the conventional nuclear waste disposal method and the conventional nuclear waste disposal method.
FIGS. 1A to 1Z are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the conventional constitution of the present invention. FIG.
2 is a schematic view of a conventional thermal power plant (1) having a double structure block tank reactor reactor for treating nuclear waste according to the present invention and having a power plant connection structure equivalent to that of the nuclear power plant (811) The thermal power generator 772 of the thermal power plant 626 shown in the external view in terms of the operation of the thermal power generator 772 of the conventional thermal power plant 626 showing the essential constitution of an embodiment formed by the thermal power generation operation of the thermal power plant 626, Operational Mode of Operation Element Side View External View.
FIG. 2a is a schematic view of a conventional nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (838) an elementary fast breeder nuclear reactor arrangement (838) exploded side view showing the decomposition of the nuclear operation of the nuclear power plant in a side view.
FIG. 2B is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A nuclear waste disposal apparatus for providing a nuclear waste disposal apparatus for recovering the nuclear waste, a nuclear waste disposal apparatus for operating a nuclear waste disposal apparatus, A nuclear waste disposal apparatus for a nuclear power plant of a nuclear power plant of the prior art.
FIG. 2c is a schematic view of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention. The nuclear reactor of the nuclear power plant providing the nuclear waste disposal apparatus for restoring the nuclear power plant, the nuclear reactor, the nuclear reactor, the nuclear reactor, Fig. 5 is a cross-sectional view of an elemental nuclear power plant operating at a nuclear power plant.
FIG. 2d is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. (811) Operation of a nuclear power plant having an evaporator structure (1005), a steam generator (810) and an intermediate heat exchanger (657) of a steam generator An elemental conventional nuclear power plant showing the construction of one embodiment The steam generator 810 and the intermediate heat exchanger 657 are separated from each other in a side view in a sectional view of the reactor 811 of the nuclear reactor of the conventional nuclear power plant, A steam generator 810 and an intermediate heat exchanger 657. FIG.
FIG. 2E is a schematic diagram of a boiler water reactor system 802 of a nuclear power generation facility 811 and a boiler water reactor system 802 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, Nuclear reactor facility (803) A conventional nuclear power plant showing an essential constitution of an embodiment formed by operation of a nuclear power plant is shown in cross section, and the nuclear power plant (811 ) Of boiling water reactor (802) and pressurized water reactor (803).
FIG. 2F is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (1) of a conventional nuclear power plant showing an operation method of a nuclear power plant of a conventional nuclear power plant showing the configuration of the nuclear power plant of the nuclear power plant (811).
FIG. 2G is a schematic view showing the structure of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention, the nuclear power generation facility 811 intermediate heat exchanger 657 and the evaporator structure of the steam generator The nuclear power plant in operation 810 of the nuclear power plant of the elementary conventional nuclear power plant showing the construction of the nuclear power plant having the nuclear power plant 1005 and the steam generator 810 and the evaporator 810 of the steam generator, The structure 1005 and the steam generator 810 are shown in side elevational view and in section. The nuclear power plant 811 intermediate heat exchanger 657 and the steam generator evaporator structure 1005 ) And the steam generator (810).
2H is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention in which a steam generator 810 of a nuclear power generation facility 811 is installed inside a nuclear power plant main body 1 of a nuclear power plant. Operation of Nuclear Power Plant Operation of Nuclear Power Plant Nuclear Power Plant (811) During Operation of Nuclear Power Plant Nuclear Power Plant (810) Operation of Nuclear Power Plant of Elementary Nuclear Power Plant Showing Side View of Steam Generator (810) 811) side view of the steam generator (810).
FIG. 2I is a schematic view illustrating a nuclear waste disposal apparatus 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Operation of the Nuclear Power Plant Having the Remote Control Cutter and the Robot 912 The Nuclear Power Plant Operation of the Elemental Conventional Nuclear Power Plant Showing the Configuration of the Embodiment The nuclear power plant of the nuclear power plant is operated inside the production power central control room 781 of the nuclear power generation facility unit 811 A nuclear waste disposal apparatus, a nuclear waste disposal method of a nuclear power plant having a cutter and a robot 912 by remote control, and a nuclear waste disposal method of a nuclear power plant ) Production power Central control room (781) Inside Nuclear waste disposal device Remote control Cutting machine and robot (912) Nuclear operation Disassembly of nuclear waste disposal method Side perspective Diagram.
FIG. 2J is a schematic diagram of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant 1071 of the nuclear power plant 811 is provided inside the reactor main body 1 of the nuclear power plant. The nuclear fuel cycle of the nuclear power plant unit 811 during the operation of the nuclear power plant of the conventional nuclear power plant showing the configuration of the nuclear power plant of the embodiment shown in FIG. (Nuclear Power Plant) (811) Nuclear Fuel Industry Cycle (1077) During Nuclear Power Plant Operation of Nuclear Power Plant
FIG. 2K is a schematic view showing a structure and an engine side showing an essential constitution of an embodiment formed for operation of a nuclear power plant of a TVA Paradise power plant steam turbine generator in the vicinity of a conventional Paradise, Kentucky, according to the present invention. And engine side elementary strap configuration.
FIG. 21 is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant Operation of Nuclear Power Plant Nuclear power generation facility (811) of elementary conventional nuclear power plant showing the configuration of one embodiment of the present invention is an elemental conventional nuclear power plant showing the operation mode of thermal power generation operation of a conventional thermal power plant as an exploded side view Nuclear power plant Nuclear power plant Operation of nuclear power plant Thermal power generation Operation aspect of disassembly side of operation method.
FIG. 2m is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant Operation of Nuclear Power Plant Nuclear power generation facility 811 of a conventional nuclear power plant showing the configuration of an embodiment of the present invention The turbine rotating blade 267 of a thermal power generation operation mode of a conventional thermal power plant and the operation operation of a steam locomotive (1) of a nuclear power plant showing a side view of the nuclear power plant (811).
2n is a nuclear power plant (nuclear power plant) 1 having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant 811, the steam pipe 779, and the high-temperature high-pressure steam inlet 780 of the steam or the strong gas, and the boiler operating core 711 inside the boiler, (783). FIG. 8 is a schematic view of an elemental view of the operation of the thermal power generation operation of the decomposition side thermal power plant of the nuclear power plant (811) during the operation of the nuclear power plant of the conventional nuclear power plant shown in side view.
FIG. 20 is a schematic view illustrating a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power generation facility 811 of the conventional nuclear power plant showing the construction of one embodiment of the nuclear power plant in which the construction of the nuclear power plant of the present invention is shown showing the construction of the embodiment, the connection structure of the conventional production power central control room 781 and transmission power measuring room transformer room 782 The thermal power generation operation of the thermal power plant, which shows the thermal power generation and operation methods of the nuclear power plant as a side view.
FIG. 2p is a view showing a reactor structure of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Lateral strap configuration diagram.
[Figure 2q] is a view showing a reactor structure of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Lateral strap configuration diagram.
FIG. 2 (a) is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant's Nuclear Power Plant's Nuclear Power Plant showing the conventional configuration of a hydroelectric power plant. Diagram showing the configuration of an electric motor pump for supplying diesel engine and generator power to each compressor and pump.
2 is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. Nuclear power plant operating nuclear power plant to recover before and after failure during operation of nuclear power plant Hydraulic power plant inside the hydroelectric power plant showing the existing structure Francis aberration, Pelton aberration pump aberration and turbine and guide vane Inside assembly model diagram and pump Aberration diagram.
FIG. 2 (a) is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, Diagram of motor and motor internal disassembly assembly.
FIG. 2U is a cross-sectional view showing a conventional multi-stage pump for showing the conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for treating nuclear waste according to the present invention. The control block diagram and the BF model are shown in the block diagrams of the front section and the front view and the sectional multi-stage pump system concept; Speed control method, and 3-pump direct-entry start-up method.
FIG. 2 (b) is a cross-sectional view of a conventional multi-stage pump for showing the conventional configuration of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention. Of the control system using the microcomputer and the digital pID control system is installed in the inverter system of the control system and the fire pump is discharged from the injection nozzle and the inverter system is combined with the control system. Diagram.
FIG. 2w is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, A partial sash construction view of a moving compressor, a stationary compressor, and a multi-stage screw compressor; and a front view operating configuration of an underground anchor bolt fixing.
FIG. 2x is a view showing a conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. (290) of the motor and a squeegee compressor connected to the motor.
FIG. 2Y is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, A suction filter 262 attached to the inside of the air dryer, and a suction filter attached to the inside of the air dryer 291. FIG.
FIG. 2Z is a schematic view of a conventional fire hydrant, showing a conventional structure of the internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. (179a) of a twin bullet type ground fire hydrant, an extinguishing type fire hydrant (179a), and a partial cross-sectional view showing a partial structure of an underground fire hydrant box manhole above a lower surface of a road surface of an underground twin fire hydrant And a fire hydrant 179 is attached to the water supply port 168 of the connection water pipe and the water discharge port 169 of the fire fighting unit 169. The fire hydrant box 169 is connected to the fire extinguisher 161 and the fire hydrant box 160, (A) large-scale fire hydrant facilities and (b) small-scale fire hydrant facilities, which are partially shown in the partial side view, Configuration.
[Figure 2a] to [Figure 2z] are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 3 is a view showing the structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) equipped with a hydroelectric power station on land and a connection structure with an island tunnels (672a).
FIG. 3A is a schematic view showing a structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) equipped with a hydroelectric power station on land and a connection structure with an artificial tunnel (672a).
FIG. 3B is a view showing the structure of the nuclear reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) equipped with a hydroelectric power station of coastal dam and a connection structure with an artificial tunnel (672a).
3C is a perspective view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, (111) of a sprinkler installation piping system sprinkler facility and a trench head, and a configuration diagram of a vibration alarm device (300).
[0064] FIG. 3D is a schematic view showing a conventional reciprocating pump piston 820 constructed in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, A partial side view showing the manner of operation of the pump 127 and a partial plunger pump 148 operation configuration diagram showing the manner in which the plunger 258 is operated in partial side view of the plunger pump 148, A side view showing the side surface of the hollow pump 311 and the hollow pump 140, and a side view of the operation side surface showing the installation state of the waste water pump 309 as a side view.
3E is a schematic view showing a conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention. 459) and the valve configuration of the water supply type general faucet (496) of the accessory and the piping accessories to provide the land and ocean reactor facilities,
FIG. 3f is a view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, Fig. 2 is a cross-sectional view of the main part of the pump during driving.
FIG. 3G is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, FIG. 2 is a perspective view of a plurality of valves formed in a prime mover. FIG.
FIG. 3h is a schematic view showing a conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention. How it works.
FIG. 3I is a schematic view showing a conventional configuration of the internal nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, The operation of the diaphragm pump 144 and the operation of the wing pump 327 are shown in the drawing. The inside of the rotary pump 337 and the external gear pump 326) Other rotary pump rotors 338 is a constructional view of the operation showing partial operation.
FIG. 3J is a diagram showing a conventional turbine pump (shown in FIG. 3B) showing a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention. The schematic diagram of the prime mover 339 and the self-priming pump 340 is shown in a perspective view showing the operation of the axial flow pump 341 and the mixed flow pump 342 of the propeller pump 146, 343) Diagram of the side view showing the operation of each pump in the visibility pump and impeller strainer.
FIG. 3K is a view showing a conventional structure of a conventional nuclear waste disposal system for a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 31 is a schematic view showing a conventional structure for constructing an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 3m is a view showing a conventional structure of a conventional nuclear waste disposal system for a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 3n is a schematic view showing a conventional automatic collection and collection system (hereinafter referred to simply as "the present invention"), which shows a conventional structure of a nuclear reactor structure of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
3O is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a block diagram showing a configuration of an embodiment showing a plurality of solenoid valve operation assemblies attached to a sensor; Fig.
FIG. 3p is a view showing a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. This is a diagram of the operating structure according to the typhoon and weather forecast in the atmosphere. It is a diagram of fire and disaster prevention methods for different types of fire to make initial evolution within 1 second after installation of spray nozzles and bed nozzles inside and outside the building.
FIG. 3q is a schematic diagram illustrating the structure of a nuclear reactor plant main body 1 having a double structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A schematic view of a plurality of construction machine bulldozers (855) operations showing the construction arrangement of a construction machine showing a construction machine.
3r is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, Of the operation of the trailer 894 to the tamping rollers 891 and the tire rollers 892 to the forklifts 858 and the dump trucks 860 and the concrete batching plant 865 and the machine bed 889 showing the configuration of the construction machine, Diagram of strabismus.
3 is a view showing the structure of a nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The six all-apparatuses 861p of the crane showing the configuration of the construction machine are connected to the scalloping device 861r on the gripping device 861q and the scraping device 861t and the weighing device 861u on the shovel device 861s Diagrammatic view of the operation of a pillar (861v).
3T is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, (813c) of the construction machine of the hull of the marine hydroelectric power station floating structure (593,594,595) constituting the upper part of the ship deck (SDU) of the marine power plant showing the construction machinery. The crusher 874) and the dredger (879).
FIG. 3U is a schematic view showing a structure of a nuclear reactor plant main body 1 having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, An excavator 856 showing a construction machine position adjustment structure of a hull position shift control of a marine hydroelectric power plant floating structure (593,594,595) constituting the upper part (SDU) of a dock hull deck of a marine power plant showing a construction machine and a hydraulic tank 819 of the plunger pump 148 and the radial plunger pump 148c.
FIG. 3v is a schematic diagram showing the structure of a nuclear reactor plant main body 1 having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A crawler type dump bottom 855a of a bulldozer 855 showing a construction machine position adjustment structure of a hull position shift control of a marine hydro-power plant docking station (593, 594, 595) constituting a dock top deck (SDU) A straight dozer 855c is attached to the wheel shaper 855b, an angle dozer 855e is attached to the dilutor dozer 855d, a tree dozer 855g is mounted to the hinge dozer 855f, and a hydraulic ripper 855i is mounted to the rake dozer 855h Diagram of a strapless structure of a mechanical connection structure.
FIG. 3w is a schematic view illustrating a structure of a nuclear reactor plant main body 1 having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A schematic view of the connection structure of a construction machine showing the arrangement of the position control of the construction machine of the marine hydroelectric power station floating attachment (593,594,595) constituting the upper part (SDU) of the dock of the marine power plant showing the construction machinery.
3x is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull locating and construction machine of an internal nuclear power generation facility 811, A crawler-type dozer 855a and a wheel-type dozer 855b, which show a construction machine position control structure for controlling the hull position movement of a marine hydro-power plant flotation receiver 593,594,595 constituting the upper part (SDU) of a marine power plant dock, (882) of a construction machine connecting structure to an excavator (856) and a skimmer (856f).
FIG. 3Y is a schematic view showing a structure of a nuclear reactor plant main body 1 having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, Ship's position showing the construction machinery Ship's construction equipment Ship's dock Ship's dock (SDU) Ship's docking station (593,594,595) Ripper and Luther (856g (861b) and all six devices of the crane (861p) and the drag cranes (887).
[Figure 3z] shows the structure of the nuclear reactor power plant of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention, the transportation transport section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, (857) showing the arrangement of the position control structure of the hull of the marine hydroelectric power plant floating structure (593,594,595) constituting the hull deck upper part (SDU) Of a fork lift truck (858) and a trailer (860a) of a dump truck (860).
[Figure 3a] to [Figure 3z] are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 4 is a schematic view showing a structure of a nuclear reactor power plant nuclear waste disposal unit 811a of a nuclear power plant 811, a nuclear power plant nuclear waste disposal unit 811a of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (591) and bottom tank barge hull (592) Double structure block tank (598) Auxiliary support coupling with central holding tank Separate Ports for connecting lugs Connecting axis 606 and a portable lug 607. The nuclear waste generation unit 811a of the nuclear power generation facility unit 811 is a component showing the configuration of the construction machinery control unit of the hull. Nuclear power plant installation.
FIG. 4a is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit of a nuclear power plant (811) within a nuclear power plant main body (1) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention 811a) of the marine power plant dock. The connection structure of the crude oil drilling rig showing the arrangement of the position control mechanism of the hull of the marine power station floating structure (593,594,595) on the deck upper part (SDU) Double structure block tank pipe bridge (937) and Nuclear waste disposal Oceanic tunnel transport equipment (941) Inside the crude drilling machine (908) Nuclear power plant Construction structure of the connection structure of the construction machine.
FIG. 4B is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, 811a), which shows the frontal side view of the steel structure inside the double pipe structure providing the steel plate bending method for the piping block of the marine power station floating pipe and the welding joint basic method, and the nuclear power plant showing the construction of the steel pipe manufacturing process Construction of a power plant.
FIG. 4c is a schematic view illustrating a structure of a nuclear reactor of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. 811a), a partial structural detail of the side section of the double-structure block tank connection section of the marine hydro-electric power plant lifting plant, and a dual-structure holding tank and a floating navigation system to explain the overall construction of the marine hydro- , Which shows the construction of a marine nuclear hydroelectric power plant floodplain distribution input device of the whole structure showing the decomposition and connection of the marine nuclear hydroelectric power plant as a block tank unit of a marine nuclear hydroelectric power plant, Marine Nuclear Hydroelectric Power Plant Floating Plant Nuclear Hydroelectric Power Plant Configuration of the body assembly method Fig.
FIG. 4D is a schematic view showing the structure of a nuclear reactor power plant nuclear waste disposal unit (1) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, 811a), bridge pier (928), pipe bridge (937) and marine tunnel (932) showing the configuration of the construction machine position control of the hull position movement control of the marine nuclear hydroelectric power station floodplain (593,594,595) (771) Nuclear hydroelectric power plant of the marine tunnel inside the traffic device (941).
FIG. 4E is a schematic view showing the structure of a nuclear power plant nuclear waste disposal unit (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, 811a) showing the decomposition coupling unit of a flood control block tank of a hydroelectric power station of a marine hydroelectric power plant.
FIG. 4f is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit of a nuclear power plant (811) within a nuclear reactor main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention 811a) is equipped with a marine safety tooling band guide device (621) at the top of a sea semi-submerging operation line to provide a welding connection assembly operation for each of double structural block tanks (598) of a floating hydro- A dual structure block tank side connection scheme showing the preparation process; a partial dual structure block tank 598 partially showing double structure block tank 598 and band guide 621; A schematic view of a hydroelectric power plant lifting hood assembly hull assembly.
FIG. 4g is a schematic view of a reactor structure of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. (1) Nuclear power plant facilities (811) Nuclear power plant Nuclear waste treatment facility (811a) Nuclear power plant equipment that constitutes the connection axis position Nuclear waste treatment Dispensing input device Marine hydro power plant Floating structure block tank 598), which is used to construct the connection assembly, is replaced with a tied-up winch 958 and connected to the inside of the reactor installation main body 1 of the nuclear power plant 959, the tugboat 636, 958) and a tie-line (636) to provide an alternative anchorage chain (640) to the anchor chain. The tugboat (636) A double structure block tank (598) of 500m unit of block tank pipe bridge (929) is connected to the sea water surface as a connecting structure to construct a temporary voyage passage for a ship. At the same time, a nuclear waste treatment double structure block tank bridge bridge (929) (598) Partial double structure Block tank (598) Unit part Partial side view Detailed construction of nuclear waste treatment double structure block tank bridge bridge (929) Nuclear power plant lifting stand.
FIG. 4h is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant nuclear waste disposal unit of the nuclear power plant (811) (593,594,595) showing the arrangement of the position adjustment mechanism of the construction machine for the hull position movement control of the marine hydroelectric power station floating structure (593,594,595) constituting the upper part (SDU) of the dock hull deck of the marine power plant with the vertical partition wall A large flange connection to a portable lug 607 and a portable lug pin 608 to a connecting lug coupling pin connection shaft 606. FIG.
FIG. 4I is a schematic view showing a structure of a nuclear plant including a double structure block tank dust collector for nuclear waste disposal according to the present invention. A concrete mixer 865 and a concrete finisher 866, which show the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant floodplain (593, 594, 595) constituting the marine power plant dock hull deck upper part (SDU) Truck (868) Diagram of a strapless connection of a construction machine connection structure.
FIG. 4J is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. ) Of a marine power station dock top deck (SDU) of a marine power plant with the asphalt finisher 871 and the asphalt spreader 874 attached to the hearth safety device 864 showing the configuration of the position control mechanism of the construction machine of the marine hydro- Of the boom (882a) and the diesel pile hammers (883) to the pile driver (872) and the pile driver (882).
FIG. 4K is a cross-sectional view of a nuclear reactor structure of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. ) Pump dredger 879a of the dredger 879 and the bucket dredger 879a of the dredger 879 showing the construction machine position control arrangement of the marine hydroelectric power station flood control 593,594,595 of the marine power station dock hull deck upper part (SDU) Diagram of Construction of Connecting Structure for Construction Machinery.
FIG. 4L is a schematic view showing the structure of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. (879l) Construction view of the connection structure of construction machine showing the regulation structure of the construction machine position of the hull position movement control of the marine hydroelectric power station floodplain (593,594,595) at the upper part of the dock hull deck of the marine power plant.
FIG. 4M is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (874) connection structure showing control structure of construction machine position adjustment of hull position movement of marine hydroelectric power plant floating attachment (593,594,595) constituting at upper part of SDU of marine power plant dock hull deck (SDU).
4n is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. ) Of the previous cylinder 126 showing the arrangement of the construction machine position adjustment of the hull position movement control of the marine hydroelectric power station floodplain 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) Plunger pump (148b) and radial plunger pump (148c).
4O is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) consisting of a marine hydroelectric power plant floating structure on the upper part of a ship's dock (SDU) of a marine power plant. Cylinder (126) .
4P is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of a nuclear power plant 811, A cylinder 126 showing a construction machine position adjustment structure of a hull position movement control of a marine hydroelectric power station floating ordinance 593,594,595 constituting a hull deck upper part (SDU), and a piston motor 885a of a hydraulic crane 885. Diagram of the strabismus of.
FIG. 4q is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Construction of a hydraulic system of a marine hydro-power plant (593,594,595) in the upper part of the ship's deck (SDU) Physician time chart.
4r is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant comprises a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of the nuclear power plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4 is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4T is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of a nuclear power plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
FIG. 4U is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of the nuclear power plant 811, Hydraulic power plant showing construction arrangement position regulation of hull displacement control of marine hydroelectric power station floating structure composed on upper part of hull deck (SDU).
FIG. 4v is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Hydraulic power plant showing construction arrangement position regulation of hull displacement control of marine hydroelectric power station floating structure composed on upper part of hull deck (SDU).
FIG. 4w is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Referring to FIG. 4w, the power generating and manufacturing unit 811b of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant, A schematic view of the connection structure showing the control structure of hydroelectric power plant construction machine for controlling the hull position movement of marine hydroelectric power plant floodgate on the upper part of the hull deck (SDU).
FIG. 4x illustrates a dual structure block tank scrubber for treating nuclear waste according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant having a dust collector for treating nuclear waste, a power generating and producing unit 811b of the nuclear power generating facility 811, Hydrodynamic power plant of Bernoulli theorem showing control arrangement of construction machine for hull position movement control of marine hydroelectric power station floating structure (593,594,595) at the upper part of hull deck (SDU).
[0064] FIG. 4 (d) is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Referring to FIG. 4, a nuclear power plant is installed in a nuclear power plant main body 1 of a nuclear power plant, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4z is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of a nuclear power generating plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
FIGS. 4A to 4Z are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention.
FIG. 5 is a schematic view illustrating a boiling water reactor installation 802 in a nuclear waste treatment reactor installation in a nuclear reactor installation part 811 of a nuclear reactor installation main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (802) of a nuclear power plant equipped with a dual-structure block tank dust collector to provide input (802) a nuclear power plant having a double structure block tank dust collector for elementary nuclear waste treatment showing decomposition coupling method FIG. 2 is a side view of a representative embodiment of the present invention showing a disassembly-type configuration of an embodiment comprising a reactor facility. FIG.
5a shows a boiler water reactor installation 802 in a nuclear reactor power plant 811 and a nuclear waste treatment reactor 781 in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention. A double structure block tank which constitutes an embodiment of a nuclear waste treatment reactor installation for providing input; a boiling water reactor installation (802) of a nuclear power plant having a dust collector; and a dual structure for elementary nuclear waste disposal The present invention relates to a reactor structure of a nuclear power plant having a block tank dust collector, and more particularly, to a boiling water reactor system (802) decomposing and coupling system of a nuclear power plant having a double structure block tank dust collector .
5b is a schematic view of a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. 802) Nuclear waste disposal reactor facility to provide a dual-structured block tank dust collector that constitutes one embodiment of a combined system. Boiling water reactor facility (802) of a nuclear power plant having a dust collector. The present invention relates to a reactor structure of a nuclear power plant having a dual structure block tank dust collector. The reactor structure of the present invention is a disassembly type structure. The reactor structure of a boiling water reactor (802) of a nuclear power plant having a dual structure block tank dust collector , Sectional view.
5c is a schematic view of a boiler water reactor installation 802 in a nuclear reactor power plant 811 inside a nuclear reactor reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. ) Dual reactor block reactor which constitutes one embodiment of the nuclear waste treatment reactor installation to provide the input. A boiling water reactor installation (802) of a nuclear power plant having a dual-structure block tank dust collector. The present invention relates to a reactor structure of a nuclear power plant having a dust collecting tank, a structure block tank dust collector, a double structure block tank, a nuclear waste disposal apparatus of a nuclear power plant having a dust collecting apparatus, Fig.
5D is a schematic view of a boiler water reactor installation (802) installed in a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention, ) Nuclear waste disposal reactor facility for providing input Nuclear waste reactor water reactor system (802) of a nuclear power plant having a dual structure block tank dust collector constituting an embodiment of the coupling system The decompositionally coupled deep reactor safety reactor facility side A double structure block tank for the treatment of nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the nuclear power plant having a double structure block tank dust collector Waste disposal equipment boiling water reactor facility (802) Deep - coupled safety reactor facility side, cross - sectional view.
FIG. 5E is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. FIG. 5E is a schematic view of a boiler water reactor (802) installed in a reactor facility main body (1) ) Nuclear waste disposal reactor facility for providing input Nuclear waste reactor water reactor system (802) of a nuclear power plant having a dual structure block tank dust collector constituting an embodiment of the coupling system The decompositionally coupled deep reactor safety reactor facility side A double structure block tank for the treatment of nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the nuclear power plant having a double structure block tank dust collector Waste Treatment Equipment Boiling Water Reactor Facilities (802) Deep - coupled Safety Reactor Facility Side, Cross - section Diagram.
5f is a schematic view of a boiler water reactor (802) installed in a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention, ) Nuclear waste disposal reactor facility to provide input Nuclear waste disposal facility (802) of nuclear power plant with dual structure block tank dust collector constituting one embodiment of coupling system Disassembly coupling type deep safety nuclear reactor facility side, An embodiment comprising a reactor facility of a nuclear power plant having a dual structure block tank dust collector for elementary nuclear waste disposal showing a loess mixture (927) for control goods soap bubble and a previous unprotected state nuclear explosion is shown in an exploded The present invention relates to a nuclear waste disposal apparatus for a nuclear power plant having a dual structure block tank dust collector Perspective configuration of a Rank-type nuclear reactor plant (802) combined degradation method depth safety nuclear reactor equipment-side, end surface processing of nuclear waste control supplies lather soil mixture 927 and the previous unprotected nuclear explosions for the FIG.
FIG. 5g is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) showing the structure of the reactor plant mooring system of the nuclear power plant as a construction machine for controlling the displacement of the marine hydroelectric power station floating structure of the deck upper part (SDU). The vertical partition wall 605 of the disassembling assembly and the portable lug coupling pin A large flange connection joint in the portable lug 607 and a portable lug pin 608 in the connection shaft 606 a processing hole 615 in the joint portion of the nuclear power hydroelectric power plant construction machine.
5H is a schematic diagram of a disaster prevention apparatus constructed in a plurality of marine nuclear power plants of a nuclear power generation facility 811 inside a nuclear power plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention FIG. 3 is a side view showing the construction of a disaster prevention apparatus constituting a plurality of elementary nuclear power plants showing the side of the disaster prevention apparatus showing the side view of the disaster prevention apparatus.
FIG. 5I illustrates an embodiment of a nuclear reactor plant main body 1 having a double structure block tank dust collector for treating nuclear waste according to the present invention. In FIG. 5I, The production of manganese nodules, a submarine mineral resource, and the production of manganese nodules of submarine mineral resources showing the operation mode of submarine submarine development into the nuclear reactor main body 1 of the elemental nuclear power plant, Diagram of a strapless arrangement of a scene.
5j illustrates an embodiment of the nuclear power plant 811 inside the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (1) of the elementary nuclear power plant of a nuclear power plant showing a scene in which natural gas or crude oil energy at the bottom of the sea floor and manganese nodule as a submarine mineral resource are produced at a tower crane seize crane boom zone (942) (811f) of the Nuclear Power Plant (811), which provides the production of manganese nodule for seafloor mineralization, showing the composition of the submarine development work.
FIG. 5K shows an embodiment of the nuclear power plant 811 inside the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (1) of the elementary nuclear power plant of a nuclear power plant showing a scene in which natural gas or crude oil energy at the bottom of the sea floor and manganese nodule as a submarine mineral resource are produced at a tower crane seize crane boom zone (942) A tower crane showing the construction of the operation structure of the submarine submarine development. A scene composed of the electronic control regulator construction machine control section 811f of the nuclear power generation facility 811 for preparing seabed mineral resource manganese nodule by the seesaw crane boom zone 942 Side view.
FIG. 5L shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with boiling water reactor facilities (802), pressurized water reactor facilities (803), gas cooling furnace reactor facilities (804) and multipurpose hot gas furnace reactor facilities 805) and a new type of reactor facility (806) and a fast breeder reactor facility (838) are shown in a side elevational view in the side view of a nuclear reactor plant (1) (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with a boiling water reactor (802) and a pressurized water reactor (803) And a gas cooling furnace reactor facility (804), a multipurpose hot gas furnace reactor facility (805), a new conversion furnace reactor facility (806), and a fast breeder reactor facility (838).
5m illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) nuclear power plant (672) of a marine ocean power plant and a boiling water reactor facility (802) of a nuclear power plant. ) Inside of the Nuclear Power Plant A number of nuclear reactors Installed at the ocean power plant showing the construction of the nuclear power plant The construction of the side view of the nuclear power plant consisting of the nuclear power plant (672) and the boiling water reactor facility (802)
5n illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, The reactor main body 1 of an elemental nuclear power plant showing a side view of the nuclear power plant operating structure consisting of a floating power plant (593,594,595) of a marine marine power plant (593,594,595) and a boiling water reactor plant (802) (Fig. 6). Fig. 6 is a side cross-sectional view of a nuclear power plant constructed at a nuclear power plant (672) and a boiling water reactor (802) at a nuclear power plant showing the construction of a nuclear power plant.
5a illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) of the offshore marine power plants and nuclear power plants (803), the side view of the nuclear power plant operating system, ) Inside flood control plant Numerous reactor installations showing the construction of the nuclear power plant Operation of the offshore plant at the ocean power plant (672) and the nuclear power plant with the pressurized water reactor system (803).
5p shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, (593,594,595) nuclear power plants (672) of the offshore marine power plants and nuclear power plants (803), the side view of the nuclear power plant operating system, ) Inside flood control plant Numerous reactor installations showing the construction of the nuclear power plant Operation of the offshore plant at the ocean power plant (672) and the nuclear power plant with the pressurized water reactor system (803).
FIG. 5q illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear cooling power plant (804) of nuclear power plant. 1) Inside flood control plant A number of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of nuclear power plant (672) and atomic power plant is composed of a gas cooling furnace reactor facility (804) Degree.
5r shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear cooling power plant (804) of nuclear power plant. 1) Inside flood control plant A number of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of nuclear power plant (672) and atomic power plant is composed of a gas cooling furnace reactor facility (804) Degree.
FIG. 5s shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear power plant is equipped with multipurpose hot gas furnace reactor facility (805). 1) Inside of the plant The installation of a number of nuclear reactors Installations of the marine power plant showing the construction of the nuclear power plant (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multipurpose hot gas furnace reactor facilities (805) Cross - sectional view.
5t shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear power plant is equipped with multipurpose hot gas furnace reactor facility (805). 1) Inside of the plant The installation of a number of nuclear reactors Installations of the marine power plant showing the construction of the nuclear power plant (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multipurpose hot gas furnace reactor facilities (805) Cross - sectional view.
FIG. 5U shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) Nuclear power plant (672) of marine ocean power plant and nuclear power plant, and a new conversion reactor facility (806) of ocean nuclear power plant. 1) Inside a floating plant A large number of nuclear reactors Installations of a marine power plant showing the construction of a nuclear power plant Construction of nuclear power plant (672) and a nuclear power plant with a new conversion reactor (806) Degree.
FIG. 5v shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine ocean power plant and nuclear power plant, and a new conversion reactor facility (806) of ocean nuclear power plant. 1) Inside a floating plant A large number of nuclear reactors Installations of a marine power plant showing the construction of a nuclear power plant Construction of nuclear power plant (672) and a nuclear power plant with a new conversion reactor (806) Degree.
FIG. 5w illustrates an embodiment of the nuclear power plant 811 inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) and ocean nuclear power plants (672), and nuclear reactors (838), which are shown in side elevation in the side view of nuclear reactors. ) Inside a floating plant A large number of nuclear reactors Installed at a nuclear power plant (672) of a marine power plant showing the construction of a nuclear power plant and a nuclear power plant equipped with a fast breeder reactor facility (838).
5x illustrates an embodiment of the nuclear power plant 811 in the reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) and ocean nuclear power plants (672), and nuclear reactors (838), which are shown in side elevation in the side view of nuclear reactors. ) Inside a floating plant A large number of nuclear reactors Installed at a nuclear power plant (672) of a marine power plant showing the construction of a nuclear power plant and a nuclear power plant equipped with a fast breeder reactor facility (838).
5E is a schematic view of a nuclear reactor nuclear waste disposal unit 811a of a nuclear power generation facility unit 811 inside a reactor facility body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) nuclear power plants (672) for offshore and offshore marine power plants, and nuclear power plants are equipped with a number of nuclear reactor facilities installed in nuclear waste treatment double structure block tank bridge (929). Nuclear power plant (672) that constitutes nuclear waste disposal Nuclear power plant (672) of marine power plant showing elemental structure showing side view of operation method of nuclear power plant Nuclear power plant has nuclear waste treatment double structure block tank bridge (672) arrangement of nuclear power plant scenes consisting of nuclear power plants (929).
5z is a nuclear power generation nuclear waste treatment unit 811a of a nuclear power generation facility 811 inside a nuclear power plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention. (593,594,595) nuclear power plants (672) for offshore and offshore marine power plants, and nuclear power plants are equipped with a number of nuclear reactor facilities installed in nuclear waste treatment double structure block tank bridge (929). Nuclear power plant (672) that constitutes nuclear waste disposal Nuclear power plant (672) of marine power plant showing elemental structure showing side view of operation method of nuclear power plant Nuclear power plant has nuclear waste treatment double structure block tank bridge (672) arrangement of nuclear power plant scenes consisting of nuclear power plants (929).
5a] to [5z] are diagrams illustrating an embodiment of a reactor installation of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 6 is a schematic view showing the construction of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The tumbler winch 137 and the wire rope 19 of the elevator machine room constructed of the decelerator 251 and the electric motor body 192 on the roof of the building and the building are attached to the upper portion of the steel tower 116 with the driving wheel roller 135 (256) Firefighting sensor pump (256) Firefighting and disinfection countermeasures The fire suppression line was constructed in such a way that it was able to evolve in less than one second, and the top of the mountain valley and the fire prevention and disaster prevention line around the beach were constructed. (256) of the nuclear power plant (811) showing the construction of the preventive control section of the emergency fire prevention sensor of the emergency fire prevention device (811).
FIG. 6a is a schematic view of a nuclear hydro power generation and production section of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, (811b) of the nuclear power plant 811 showing the configuration of the position adjustment mechanism of the hull of the marine hydroelectric power plant lifting console (593, 594, 595) constituting the marine power plant body dock hull deck upper part (SDU) Hydraulic power plant construction diagram of a connecting structure.
FIG. 6B is a schematic view of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. Production Production Department (811b) Marine Power Plant Body Dock Hydraulic power station or marine hydroelectric power plant (943) showing the arrangement of the construction machine position control of the hull position movement of the marine hydroelectric power station levitation stand (593,594,595) Aberration or pump aberration 264 and main valve 265 hydroelectric power plant construction machine connection structure.
6C is a schematic view of a nuclear hydro power generation and production unit (hereinafter, referred to as &quot; nuclear hydro power generation &lt; RTI ID = 0.0 &gt; production &lt; / RTI & (811b) Marine dock Body dock Marine hydroelectric power production and production department showing the arrangement of construction machine position control of hull position movement of marine hydroelectric power plant floating attachment (593,594,595) at the upper part of ship hull deck (SDU) Construction diagram of connection structure of construction machine.
6D is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing the power of the nuclear power generation facility unit 811 in the nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention (678p) Hydraulic power plant construction machine (678p) in the Han river system showing the regulation structure of the construction machine position of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the upper part of the deck of the marine power plant (SDU) Diagram of the connection structure.
FIG. 6E is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing power of a nuclear power generation facility unit 811 in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention TORICELLI 's theorem of hydroplaning structure of the marine hydroelectric power station (593, 594, 595) on the hull deck upper part of marine power plant dock (SDU) .
FIG. 6f is a schematic view of a nuclear hydro power generation production control unit (not shown) for generating a power of a nuclear power generation facility unit 811 inside a nuclear reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention. Structure of the microswitch 580 showing the arrangement of the construction machine position adjustment of the hull position movement of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part of the marine power plant deck (SDU) of the marine power plant. 183) and a diaphragm type pressure switch (104a) with a pneumatic-sensor pressure switch (104b).
FIG. 6G is a schematic view showing a structure of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for generating power of a nuclear power generation facility unit 811 in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention Marine power plant body dock Construction of a marine hydro power plant floating structure (593,594,595) on the upper deck (SDU) of the marine power plant Construction of the control of hull position control of the fire Fire temperature sensor showing the position control configuration Sensor sensor Bimetal (102) thermocouple configuration method A thermocouple thermometer switch 103 for detecting the temperature of the thermocouple 103 is provided at a measuring point 102d of the thermoelectric generator 102c and the thermocouple generator 102b.
6H is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing power of a nuclear power generation facility unit 811 inside a nuclear reactor facility main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention A plurality of gear pumps 326 and a vane pump 142 for showing the construction machine position adjustment structure of the hull position movement control of the marine hydroelectric power plant flood control consoles 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) Lt; RTI ID = 0.0 &gt; 474 &lt; / RTI &gt;
FIG. 6I is a schematic view showing the construction of a double structure block tank dust collector for nuclear waste disposal according to the present invention. (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Dependent reading compartment in the upper part.
FIG. 6J is a plan view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, and a water transportation facility 811c of a construction machine of a nuclear power generation facility 811, (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Diagram of the floatation of the floats in the upper part.
6k is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, and a water transporting unit 811c of a construction machine of a nuclear power generation facility 811, (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Diagram of the floatation of the floats in the upper part.
[61] FIG. 61 is a schematic view showing the structure of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. A structure for illustrating an embodiment showing a mountain top portion in which initial evolution occurs within one second for each type, a collecting pump of an elevator machine room for each building and a building, and a disaster prevention and disaster prevention device for disaster prevention prevention at a fire installation position A schematic cross sectional view of a distributing and inputting device of disaster control disaster prevention device showing hydroelectric power plant.
FIG. 6m is a cross-sectional view of the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. FIG. 8 is a side view showing a configuration of a nuclear disaster prevention and disaster control system of a nuclear power generation facility 811 showing an embodiment showing a disaster control disaster prevention device of a double pipe structure fire hose installation operation.
FIG. 6n is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Sectional structure of the disposal injection device of the disaster control disaster prevention device of the nuclear power generation facility 811 showing the configuration illustrating one embodiment showing the disaster control disaster prevention device of the accident prevention shutdown prevention part of the double pipe structure fire hose installation operation Degree.
FIG. 6 is a schematic view illustrating an internal structure of the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A trash pump fire extinguisher fire prevention type collecting tank and an alternate manometer turn type level balance pipe nozzle disaster prevention prevention part constituting an evolution, (811) Hydroelectric power plant of flood control disruption control device of distribution system of manometer turn type level balance pipe nozzle.
FIG. 6p is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The hydrothermal power generation unit 811 of the nuclear power plant 811 showing the construction of one embodiment showing the disaster control and disaster prevention device of the carbon dioxide gas fire extinguisher for preventing the disaster of the carbon dioxide gas fire extinguisher by the installation of the pipe nozzle collecting tank of the stepwise non- Installation of disaster control disaster prevention system.
FIG. 6Q is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Of a double vinyl tent nozzle type fire-fighting water supply system of a ridge line within a predetermined time or less from the beginning of a fire and an emergency disruption device installation method of a hurricane disruption device installation method of a nuclear power generation system showing an example of a disaster- A schematic diagram of an early stage fire of A fire and a side view configuration of a disaster control disaster control disaster control apparatus including a power plant of a nuclear power plant of the facility unit 811. [
FIG. 6 r is a diagram illustrating an example of an internal structure of a nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A three-stage stepped pump fire extinguisher that is adapted to evolve, a fire extinguishing system collecting tank, and an alternate manometurn type level balance pipe nozzle disaster prevention preventive system. Power generation facilities to be included in the nuclear power plant of nuclear power generation facility (811) Power generation facility to provide electricity to the power generation facilities of nuclear power plant Three-stage stepped pump fire extinguisher Collecting tank of fire preventive type and substitute manometer turn type level balance nozzle Dispensing disposing device of disaster control disaster prevention device Side view.
6 is a schematic view of a nuclear reactor power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Showing a configuration for illustrating an embodiment showing a disaster-controlled disaster prevention device for preventing a disaster of a disaster prevention preventive control unit constituting a ship 1078 having a conventional sinking ship and rescue force rescue force capable of failing to sink and prevent a strong wind wave 1101 The ship 1078 having the rescue force for the treatment of the nuclear waste of the nuclear power plant of the nuclear power generation facility 811 is transferred into the reactor main body 1 of the nuclear power plant to prevent the disaster of the nuclear power generation facility 811 Of the present invention is provided with a nuclear reactor power plant.
FIG. 6 t is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ The hatch cover 153, the lifesaving bed nozzle 172 and the rope rope 629 provided on the ship 1078 having the rescue force for nuclear waste disposal for nuclear power generation plant nuclear power plant of the nuclear power generation facility unit 811, An elevator alley bed 632, a conveyor 633, a bollard 638, an anchor 639, anchor chain 640 and helicopter 647 Equipped nuclear power plant A nuclear ballast (914) of a ship 1078 equipped with a rescue force rescue force rescue force resisting ability of a reactor plant of a nuclear power plant, which is included in the disaster prevention preventive control section of the nuclear power generation facility section 811, Side view.
FIG. 6U is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (925) of a typhoon and a downward airflow (926) air flow regulating device among the devices of the nuclear power plant (925) showing a constitutional example of a constitutional example showing a disaster- 811), a nuclear waste disposal apparatus for a nuclear power plant of a nuclear power plant, a garden hatch basket 951 for a harmful rust-inhale-suction dust collector, a flexible high-pressure hose 190, an introduction pipe 191, a blower 641, 642), a loess cement mixing equipment mixer machine 649, a crane boom frame 651, a crane boom hook 652, a rubber balloon 914, an air nozzle 923, a loess mixture 927 for soap bubbles, 934 and the cooling air bubble 939, The inside of the reactor main body 1 of the nuclear power plant having the disaster prevention nozzle 945, the submarine line wiring 946, and the double structure air introducing rubber tubing 947 inside the container for the throttle device is connected to the inside of the reactor main body 1 811) Nuclear power plant reactor facilities to provide protection against disruption Prevention of flood control Disaster prevention equipment (925) and downward airflow (926) for airflow control Nuclear waste treatment equipment and harmful rust A ventilator 641 and a heater fan 642 for maintaining the air, a yellow loess cement mixing equipment mixer machine 649, a crane boom base 651, and a flexible high pressure hose 190, an introduction pipe 191, a flexible high pressure hose 190, The crane boom hooks 652 and the rubber balloons 914 and the air nozzles 923 and the yellow soil mixture 927 for soap bubbles and the crude oil drills 934 and the cooling air bubbles 939 and the disaster prevention nozzles 945 and the seabed The line wiring 946 and the inside of the container for the needle- In structure air rubber tube probe 947 side diagram.
FIG. 6 (b) is a schematic view showing the construction of a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided on a ship 1078 equipped with a power generation facility nuclear waste disposal device of a nuclear power plant of the nuclear power generation facility 811, 626, elevator alibite 632, conveyor 633, bollard 638, anchor 639, anchor chain 640, and helicopter 647, as well as the rope knot claw 630, the emergency stairs 631, Atoms with Nuclear power plant nuclear reactor power plant disaster control disaster prevention device which is included in preventive disaster prevention control part of nuclear power generation facility part (811) inside nuclear power reactor facility main body (1) of power plant Rubber balloon of vessel (1078) 914) Side perspective view.
FIG. 6w is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided on a ship 1078 equipped with a power generation facility nuclear waste disposal device of a nuclear power plant of the nuclear power generation facility 811, 626, elevator alibite 632, conveyor 633, bollard 638, anchor 639, anchor chain 640, and helicopter 647, as well as the rope knot claw 630, the emergency stairs 631, Atoms with Nuclear power plant nuclear reactor power plant disaster control disaster prevention apparatus that provides protection to disaster prevention prevention part of nuclear power generation facility part (811) inside nuclear power reactor facility main body (1) of power plant Ship with resilience for life rescue force (1078) Rubber balloon (914 Side perspective configuration.
FIG. 6 (a) is a plan view of a reactor structure of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A peace-preserving message that restores peace-preserved message photo-shoots (958), more powerful than bombs, to each region within a radius of 1200 km from the center of the peninsula, to fulfill its duties under the rights and obligations of the establishment of a new federal state in Northeast Asia A nuclear waste disposal apparatus for a nuclear power plant of a nuclear power generation facility 811 showing a constitutional example illustrating a photo shoot 958 and a peace preserved message photo shoot 958 are installed in a radius It is a peace-preserving type that re-establishes each region within 1200km and fulfills its duties according to rights and duties according to the establishment of a new federal state in Northeast Asia. Fig. 8 is a side perspective view of the view photo shovel 958; Fig.
Figures 6a to 6f show a conventional boiling water reactor plant nuclear power plant according to the present invention. Figure 1 shows a conventional boiling water reactor plant nuclear power plant according to the present invention. (802) Elemental Conventional Boiling Water Reactor Facility (802) Illustrating the Outline of Nuclear Power Plant (802).
Figure 1a is a schematic diagram of a conventional boiling water nuclear reactor (802) nuclear reactor plant (802), showing a component configuration of a conventional boiler water reactor plant (802) 688A) and a turbine building 688B and a waste building 688G in a diesel generator building 688E and a nuclear fuel building 688F in a control building 688C and an auxiliary building 688D.
FIG. 1 b is a side view of a conventional boiling water nuclear reactor (802) nuclear power plant showing the essential constitution of an embodiment formed by a conventional boiling water reactor (802) nuclear power plant according to the present invention. An elemental side view.
FIG. 1c is a side view of an elemental conventional boiling water nuclear reactor (802) nuclear power plant operating according to the present invention showing a configuration of a conventional boiling water reactor (802) nuclear power plant. An elemental side view.
FIG. 1d is a side view of a conventional boiling water reactor plant nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional boiling water reactor (802) nuclear power plant according to the present invention. An elemental side view.
1E is a schematic view of a conventional Fukushima boiling water reactor facility 802 according to the present invention, showing the essential constitution of an embodiment formed by the operation of a nuclear power plant, An elemental side view showing the operation of the nuclear power plant as a side view.
FIG. 1F is a schematic diagram of a conventional boiling water reactor (802) nuclear power plant operating at a nuclear power plant, showing the essential constitution of an embodiment of the present invention formed by operation of a nuclear power plant of a conventional boiling water reactor (802) Fig. 3 is a side view of the elemental side view.
FIG. 1G illustrates the operation of the conventional pressurized water reactor (803) of the nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the conventional pressurized water reactor (803) (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
1H is a schematic diagram of a conventional pressurized water reactor type nuclear reactor 803 according to the present invention. The conventional water reactor type nuclear reactor 803 shown in FIG. Fig. 3 is a side view of the element.
FIG. 1I is a schematic diagram showing an operation of a conventional pressurized water reactor (803) of a nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the conventional pressurized water reactor (803) (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
FIG. 1J shows a conventional pressurized water reactor (803) of a conventional nuclear power plant showing the essential constitution of an embodiment formed by operating a nuclear power plant of a conventional pressurized water reactor (803) according to the present invention. (803) side view showing the elemental pressurized water reactor type nuclear reactor shown in FIG.
1K is a sectional view of a conventional pressurized water reactor type nuclear reactor 803 according to the present invention. The pressure vessel 803 of the conventional pressurized water reactor type nuclear reactor 803 shown in FIG. (813) inside the pressure vessel (813) of the elementary pressurized water reactor (803) shown in FIG.
FIG. 11 is a structural schematic view of nuclear fission of nuclear fuel uranium 235 showing nuclear fission structure of nuclear fuel uranium 235 showing an essential constitution of a nuclear power plant according to an embodiment of the present invention.
FIG. 1 m is a side view partially showing a method of using a control rod for controlling a chain reaction of nuclear fuel fission in a nuclear reactor of a conventional nuclear power plant according to the present invention, and a side view showing a difference between an atomic bomb and a reactor And the lower drawing shows reactor fuel production and reactor steam generation system 1073 in which steam generator 810, pressurizer 814, and coolant 816 are shown in a side view of the process of producing plutonium in uranium 238, Diagram,
FIG. 1n illustrates the operation of a nuclear reactor furnace 804 reactor of a conventional nuclear power plant showing the essential constitution of an embodiment formed by the operation of a nuclear power plant of a conventional gas cooling furnace reactor 804 according to the present invention. (804) side view diagonal view of an elemental gas cooling furnace reactor as shown on the external side.
(A) is a schematic view of an elementary conventional gas cooling furnace reactor plant 804 showing the configuration of an embodiment formed from a conventional gas cooling furnace reactor facility 804 nuclear power plant according to the present invention, As shown in Fig.
FIG. 1 P is a side view showing a nuclear reactor operation operation mode of a nuclear reactor of a nuclear reactor of the related art, showing a configuration of an embodiment formed as a connection structure of a steam generator 810 of a conventional nuclear reactor nuclear reactor plant according to the present invention (810) of a nuclear reactor plant reactor installation.
FIG. 1q is a schematic diagram of a conventional multi-purpose high-temperature gas furnace reactor 805 showing the essential constitution of a conventional multi-purpose hot gas furnace 805 operated by a nuclear power plant, (804) lateral diagonal configuration of an elementary gas cooling furnace reactor arrangement showing the operation as an external side view.
FIG. 1 r is a schematic diagram of a conventional multi-purpose hot gas furnace 805 showing the construction of a conventional multi-purpose hot gas furnace 805 nuclear power plant according to an embodiment of the present invention. (805) side view showing the elemental multi-purpose high-temperature gas furnace.
FIG. 1s is a schematic diagram showing an essential conventional multi-purpose hot gas furnace 805 showing the construction of a conventional multi-purpose high temperature gas furnace 805 nuclear power plant according to the present invention, Equipment (806) An elemental multi-purpose hot gas furnace (805) and a new conversion furnace reactor (806) side view showing the decommissioning side view of nuclear power plant operation.
FIG. 1 (a) is a schematic view showing a nuclear power plant of a conventional nuclear power plant showing an essential constitution of an embodiment of the present invention formed by the operation of the nuclear power plant of the nuclear power plant of the present invention, Transition reactor installation (806) Side perspective configuration.
FIG. 1U is a schematic view of a nuclear power plant 672 according to an embodiment of the present invention in which a new conversion furnace reactor facility 806 of a conventional nuclear power plant 672 is installed in a reactor facility body of a nuclear power plant having a dual structure block tank dust collector The present invention relates to a dual structural block for the treatment of nuclear waste. The present invention relates to a new type conversion block provided in a reactor facility of a nuclear power plant having a tank dust collector. (806) An elemental nuclear waste A reactor structure of a nuclear power plant having a tank dust collector. A side view of a new reactor furnace facility (806) constructed in the present invention.
FIG. 1 v is a cross-sectional view of an elemental conventional nuclear power plant reactor building 688 showing the configuration of one embodiment of a conventional nuclear power plant according to the present invention, and an elemental reactor building 688) and a detailed side view of the fuel rod (689).
FIG. 1w illustrates the operation of the nuclear reactor plant 838 of a conventional nuclear power plant showing the essential constitution of an embodiment of the present invention formed by the operation of a nuclear power plant of a conventional high-speed breeder reactor facility 838 according to the present invention A schematic view of an elemental side view showing the external side.
1x illustrates the operation of the nuclear reactor of the nuclear reactor of the present invention in a conventional fast breeder nuclear reactor (838) nuclear power plant, (838) disassembled lateral strabismus configuration.
FIG. 1 (Y) is a side view of an elementary conventional fast breeder reactor facility 838 nuclear power station showing the configuration of one embodiment formed from a conventional fast breeder nuclear reactor facility 838 nuclear power plant according to the present invention, (838) side view of the reactor.
Figure 1z illustrates a method of processing nuclear waste according to the prior design of a plutonium disposal process 1040 in the dismantling of nuclear weapons from the disassembly facility 1030 of the nuclear base 1029 of the conventional nuclear power plant nuclear waste disposal method according to the present invention FIG. 2 is a schematic view of a conventional elemental nuclear waste disposal method showing the difference between the conventional nuclear waste disposal method and the conventional nuclear waste disposal method.
FIGS. 1A to 1Z are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the conventional constitution of the present invention. FIG.
2 is a schematic view of a conventional thermal power plant (1) having a double structure block tank reactor reactor for treating nuclear waste according to the present invention and having a power plant connection structure equivalent to that of the nuclear power plant (811) The thermal power generator 772 of the thermal power plant 626 shown in the external view in terms of the operation of the thermal power generator 772 of the conventional thermal power plant 626 showing the essential constitution of an embodiment formed by the thermal power generation operation of the thermal power plant 626, Operational Mode of Operation Element Side View External View.
FIG. 2a is a schematic view of a conventional nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (838) an elementary fast breeder nuclear reactor arrangement (838) exploded side view showing the decomposition of the nuclear operation of the nuclear power plant in a side view.
FIG. 2B is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A nuclear waste disposal apparatus for providing a nuclear waste disposal apparatus for recovering the nuclear waste, a nuclear waste disposal apparatus for operating a nuclear waste disposal apparatus, A nuclear waste disposal apparatus for a nuclear power plant of a nuclear power plant of the prior art.
FIG. 2c is a schematic view of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention. The nuclear reactor of the nuclear power plant providing the nuclear waste disposal apparatus for restoring the nuclear power plant, the nuclear reactor, the nuclear reactor, the nuclear reactor, Fig. 5 is a cross-sectional view of an elemental nuclear power plant operating at a nuclear power plant.
FIG. 2d is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. (811) Operation of a nuclear power plant having an evaporator structure (1005), a steam generator (810) and an intermediate heat exchanger (657) of a steam generator An elemental conventional nuclear power plant showing the construction of one embodiment The steam generator 810 and the intermediate heat exchanger 657 are separated from each other in a side view in a sectional view of the reactor 811 of the nuclear reactor of the conventional nuclear power plant, A steam generator 810 and an intermediate heat exchanger 657. FIG.
FIG. 2E is a schematic diagram of a boiler water reactor system 802 of a nuclear power generation facility 811 and a boiler water reactor system 802 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, Nuclear reactor facility (803) A conventional nuclear power plant showing an essential constitution of an embodiment formed by operation of a nuclear power plant is shown in cross section, and the nuclear power plant (811 ) Of boiling water reactor (802) and pressurized water reactor (803).
FIG. 2F is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (1) of a conventional nuclear power plant showing an operation method of a nuclear power plant of a conventional nuclear power plant showing the configuration of the nuclear power plant of the nuclear power plant (811).
FIG. 2G is a schematic view showing the structure of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention, the nuclear power generation facility 811 intermediate heat exchanger 657 and the evaporator structure of the steam generator The nuclear power plant in operation 810 of the nuclear power plant of the elementary conventional nuclear power plant showing the construction of the nuclear power plant having the nuclear power plant 1005 and the steam generator 810 and the evaporator 810 of the steam generator, The structure 1005 and the steam generator 810 are shown in side elevational view and in section. The nuclear power plant 811 intermediate heat exchanger 657 and the steam generator evaporator structure 1005 ) And the steam generator (810).
2H is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention in which a steam generator 810 of a nuclear power generation facility 811 is installed inside a nuclear power plant main body 1 of a nuclear power plant. Operation of Nuclear Power Plant Operation of Nuclear Power Plant Nuclear Power Plant (811) During Operation of Nuclear Power Plant Nuclear Power Plant (810) Operation of Nuclear Power Plant of Elementary Nuclear Power Plant Showing Side View of Steam Generator (810) 811) side view of the steam generator (810).
FIG. 2I is a schematic view illustrating a nuclear waste disposal apparatus 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Operation of the Nuclear Power Plant Having the Remote Control Cutter and the Robot 912 The Nuclear Power Plant Operation of the Elemental Conventional Nuclear Power Plant Showing the Configuration of the Embodiment The nuclear power plant of the nuclear power plant is operated inside the production power central control room 781 of the nuclear power generation facility unit 811 A nuclear waste disposal apparatus, a nuclear waste disposal method of a nuclear power plant having a cutter and a robot 912 by remote control, and a nuclear waste disposal method of a nuclear power plant ) Production power Central control room (781) Inside Nuclear waste disposal device Remote control Cutting machine and robot (912) Nuclear operation Disassembly of nuclear waste disposal method Side perspective Diagram.
FIG. 2J is a schematic diagram of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant 1071 of the nuclear power plant 811 is provided inside the reactor main body 1 of the nuclear power plant. The nuclear fuel cycle of the nuclear power plant unit 811 during the operation of the nuclear power plant of the conventional nuclear power plant showing the configuration of the nuclear power plant of the embodiment shown in FIG. (Nuclear Power Plant) (811) Nuclear Fuel Industry Cycle (1077) During Nuclear Power Plant Operation of Nuclear Power Plant
FIG. 2K is a schematic view showing a structure and an engine side showing an essential constitution of an embodiment formed for operation of a nuclear power plant of a TVA Paradise power plant steam turbine generator in the vicinity of a conventional Paradise, Kentucky, according to the present invention. And engine side elementary strap configuration.
FIG. 21 is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant Operation of Nuclear Power Plant Nuclear power generation facility (811) of elementary conventional nuclear power plant showing the configuration of one embodiment of the present invention is an elemental conventional nuclear power plant showing the operation mode of thermal power generation operation of a conventional thermal power plant as an exploded side view Nuclear power plant Nuclear power plant Operation of nuclear power plant Thermal power generation Operation aspect of disassembly side of operation method.
FIG. 2m is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant Operation of Nuclear Power Plant Nuclear power generation facility 811 of a conventional nuclear power plant showing the configuration of an embodiment of the present invention The turbine rotating blade 267 of a thermal power generation operation mode of a conventional thermal power plant and the operation operation of a steam locomotive (1) of a nuclear power plant showing a side view of the nuclear power plant (811).
2n is a nuclear power plant (nuclear power plant) 1 having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant 811, the steam pipe 779, and the high-temperature high-pressure steam inlet 780 of the steam or the strong gas, and the boiler operating core 711 inside the boiler, (783). FIG. 8 is a schematic view of an elemental view of the operation of the thermal power generation operation of the decomposition side thermal power plant of the nuclear power plant (811) during the operation of the nuclear power plant of the conventional nuclear power plant shown in side view.
FIG. 20 is a schematic view illustrating a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power generation facility 811 of the conventional nuclear power plant showing the construction of one embodiment of the nuclear power plant in which the construction of the nuclear power plant of the present invention is shown showing the construction of the embodiment, the connection structure of the conventional production power central control room 781 and transmission power measuring room transformer room 782 The thermal power generation operation of the thermal power plant, which shows the thermal power generation and operation methods of the nuclear power plant as a side view.
FIG. 2p is a view showing a reactor structure of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Lateral strap configuration diagram.
[Figure 2q] is a view showing a reactor structure of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant (811) Nuclear power plant Lateral strap configuration diagram.
FIG. 2 (a) is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. Nuclear Power Plant's Nuclear Power Plant's Nuclear Power Plant showing the conventional configuration of a hydroelectric power plant. Diagram showing the configuration of an electric motor pump for supplying diesel engine and generator power to each compressor and pump.
2 is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. Nuclear power plant operating nuclear power plant to recover before and after failure during operation of nuclear power plant Hydraulic power plant inside the hydroelectric power plant showing the existing structure Francis aberration, Pelton aberration pump aberration and turbine and guide vane Inside assembly model diagram and pump Aberration diagram.
FIG. 2 (a) is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, Diagram of motor and motor internal disassembly assembly.
FIG. 2U is a cross-sectional view showing a conventional multi-stage pump for showing the conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for treating nuclear waste according to the present invention. The control block diagram and the BF model are shown in the block diagrams of the front section and the front view and the sectional multi-stage pump system concept; Speed control method, and 3-pump direct-entry start-up method.
FIG. 2 (b) is a cross-sectional view of a conventional multi-stage pump for showing the conventional configuration of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention. Of the control system using the microcomputer and the digital pID control system is installed in the inverter system of the control system and the fire pump is discharged from the injection nozzle and the inverter system is combined with the control system. Diagram.
FIG. 2w is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, A partial sash construction view of a moving compressor, a stationary compressor, and a multi-stage screw compressor; and a front view operating configuration of an underground anchor bolt fixing.
FIG. 2x is a view showing a conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. (290) of the motor and a squeegee compressor connected to the motor.
FIG. 2Y is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, A suction filter 262 attached to the inside of the air dryer, and a suction filter attached to the inside of the air dryer 291. FIG.
FIG. 2Z is a schematic view of a conventional fire hydrant, showing a conventional structure of the internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. (179a) of a twin bullet type ground fire hydrant, an extinguishing type fire hydrant (179a), and a partial cross-sectional view showing a partial structure of an underground fire hydrant box manhole above a lower surface of a road surface of an underground twin fire hydrant And a fire hydrant 179 is attached to the water supply port 168 of the connection water pipe and the water discharge port 169 of the fire fighting unit 169. The fire hydrant box 169 is connected to the fire extinguisher 161 and the fire hydrant box 160, (A) large-scale fire hydrant facilities and (b) small-scale fire hydrant facilities, which are partially shown in the partial side view, Configuration.
[Figure 2a] to [Figure 2z] are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 3 is a view showing the structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) equipped with a hydroelectric power station on land and a connection structure with an island tunnels (672a).
FIG. 3A is a schematic view showing a structure of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) equipped with a hydroelectric power station on land and a connection structure with an artificial tunnel (672a).
FIG. 3B is a view showing the structure of the nuclear reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) equipped with a hydroelectric power station of coastal dam and a connection structure with an artificial tunnel (672a).
3C is a perspective view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, (111) of a sprinkler installation piping system sprinkler facility and a trench head, and a configuration diagram of a vibration alarm device (300).
[0064] FIG. 3D is a schematic view showing a conventional reciprocating pump piston 820 constructed in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, A partial side view showing the manner of operation of the pump 127 and a partial plunger pump 148 operation configuration diagram showing the manner in which the plunger 258 is operated in partial side view of the plunger pump 148, A side view showing the side surface of the hollow pump 311 and the hollow pump 140, and a side view of the operation side surface showing the installation state of the waste water pump 309 as a side view.
3E is a schematic view showing a conventional configuration of the internal nuclear power plant 811 of the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention. 459) and the valve configuration of the water supply type general faucet (496) of the accessory and the piping accessories to provide the land and ocean reactor facilities,
FIG. 3f is a view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, Fig. 2 is a cross-sectional view of the main part of the pump during driving.
FIG. 3G is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, FIG. 2 is a perspective view of a plurality of valves formed in a prime mover. FIG.
FIG. 3h is a schematic view showing a conventional structure of the internal nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention. How it works.
FIG. 3I is a schematic view showing a conventional configuration of the internal nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, The operation of the diaphragm pump 144 and the operation of the wing pump 327 are shown in the drawing. The inside of the rotary pump 337 and the external gear pump 326) Other rotary pump rotors 338 is a constructional view of the operation showing partial operation.
FIG. 3J is a diagram showing a conventional turbine pump (shown in FIG. 3B) showing a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention. The schematic diagram of the prime mover 339 and the self-priming pump 340 is shown in a perspective view showing the operation of the axial flow pump 341 and the mixed flow pump 342 of the propeller pump 146, 343) Diagram of the side view showing the operation of each pump in the visibility pump and impeller strainer.
FIG. 3K is a view showing a conventional structure of a conventional nuclear waste disposal system for a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 31 is a schematic view showing a conventional structure for constructing an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 3m is a view showing a conventional structure of a conventional nuclear waste disposal system for a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
FIG. 3n is a schematic view showing a conventional automatic collection and collection system (hereinafter referred to simply as "the present invention"), which shows a conventional structure of a nuclear reactor structure of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a schematic view of a side operation showing the manner in which the tank is operated. Fig.
3O is a schematic view showing a conventional structure of a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, Fig. 3 is a block diagram showing a configuration of an embodiment showing a plurality of solenoid valve operation assemblies attached to a sensor; Fig.
FIG. 3p is a view showing a conventional configuration of an internal nuclear power plant 811 of a nuclear reactor main body 1 of a nuclear power plant having a conventional dual structure block tank dust collector for nuclear waste disposal according to the present invention. This is a diagram of the operating structure according to the typhoon and weather forecast in the atmosphere. It is a diagram of fire and disaster prevention methods for different types of fire to make initial evolution within 1 second after installation of spray nozzles and bed nozzles inside and outside the building.
FIG. 3q is a schematic diagram illustrating the structure of a nuclear reactor plant main body 1 having a double structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A schematic view of a plurality of construction machine bulldozers (855) operations showing the construction arrangement of a construction machine showing a construction machine.
3r is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull locating moving construction machine of an internal nuclear power generation facility 811, Of the operation of the trailer 894 to the tamping rollers 891 and the tire rollers 892 to the forklifts 858 and the dump trucks 860 and the concrete batching plant 865 and the machine bed 889 showing the configuration of the construction machine, Diagram of strabismus.
3 is a view showing the structure of a nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The six all-apparatuses 861p of the crane showing the configuration of the construction machine are connected to the scalloping device 861r on the gripping device 861q and the scraping device 861t and the weighing device 861u on the shovel device 861s Diagrammatic view of the operation of a pillar (861v).
3T is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, (813c) of the construction machine of the hull of the marine hydroelectric power station floating structure (593,594,595) constituting the upper part of the ship deck (SDU) of the marine power plant showing the construction machinery. The crusher 874) and the dredger (879).
FIG. 3U is a schematic view showing a structure of a nuclear reactor plant main body 1 having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, An excavator 856 showing a construction machine position adjustment structure of a hull position shift control of a marine hydroelectric power plant floating structure (593,594,595) constituting the upper part (SDU) of a dock hull deck of a marine power plant showing a construction machine and a hydraulic tank 819 of the plunger pump 148 and the radial plunger pump 148c.
FIG. 3v is a schematic diagram showing the structure of a nuclear reactor plant main body 1 having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A crawler type dump bottom 855a of a bulldozer 855 showing a construction machine position adjustment structure of a hull position shift control of a marine hydro-power plant docking station (593, 594, 595) constituting a dock top deck (SDU) A straight dozer 855c is attached to the wheel shaper 855b, an angle dozer 855e is attached to the dilutor dozer 855d, a tree dozer 855g is mounted to the hinge dozer 855f, and a hydraulic ripper 855i is mounted to the rake dozer 855h Diagram of a strapless structure of a mechanical connection structure.
FIG. 3w is a schematic view illustrating a structure of a nuclear reactor plant main body 1 having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, A schematic view of the connection structure of a construction machine showing the arrangement of the position control of the construction machine of the marine hydroelectric power station floating attachment (593,594,595) constituting the upper part (SDU) of the dock of the marine power plant showing the construction machinery.
3x is a schematic view of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull locating and construction machine of an internal nuclear power generation facility 811, A crawler-type dozer 855a and a wheel-type dozer 855b, which show a construction machine position control structure for controlling the hull position movement of a marine hydro-power plant flotation receiver 593,594,595 constituting the upper part (SDU) of a marine power plant dock, (882) of a construction machine connecting structure to an excavator (856) and a skimmer (856f).
FIG. 3Y is a schematic view showing a structure of a nuclear reactor plant main body 1 having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, a transportation transport section 811c of a hull position moving construction machine of an internal nuclear power generation facility 811, Ship's position showing the construction machinery Ship's construction equipment Ship's dock Ship's dock (SDU) Ship's docking station (593,594,595) Ripper and Luther (856g (861b) and all six devices of the crane (861p) and the drag cranes (887).
[Figure 3z] shows the structure of the nuclear reactor power plant of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention, the transportation transport section 811c of the hull position moving construction machine of the internal nuclear power generation facility 811, (857) showing the arrangement of the position control structure of the hull of the marine hydroelectric power plant floating structure (593,594,595) constituting the hull deck upper part (SDU) Of a fork lift truck (858) and a trailer (860a) of a dump truck (860).
[Figure 3a] to [Figure 3z] are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 4 is a schematic view showing a structure of a nuclear reactor power plant nuclear waste disposal unit 811a of a nuclear power plant 811, a nuclear power plant nuclear waste disposal unit 811a of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (591) and bottom tank barge hull (592) Double structure block tank (598) Auxiliary support coupling with central holding tank Separate Ports for connecting lugs Connecting axis 606 and a portable lug 607. The nuclear waste generation unit 811a of the nuclear power generation facility unit 811 is a component showing the configuration of the construction machinery control unit of the hull. Nuclear power plant installation.
FIG. 4a is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit of a nuclear power plant (811) within a nuclear power plant main body (1) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention 811a) of the marine power plant dock. The connection structure of the crude oil drilling rig showing the arrangement of the position control mechanism of the hull of the marine power station floating structure (593,594,595) on the deck upper part (SDU) Double structure block tank pipe bridge (937) and Nuclear waste disposal Oceanic tunnel transport equipment (941) Inside the crude drilling machine (908) Nuclear power plant Construction structure of the connection structure of the construction machine.
FIG. 4B is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, 811a), which shows the frontal side view of the steel structure inside the double pipe structure providing the steel plate bending method for the piping block of the marine power station floating pipe and the welding joint basic method, and the nuclear power plant showing the construction of the steel pipe manufacturing process Construction of a power plant.
FIG. 4c is a schematic view illustrating a structure of a nuclear reactor of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. 811a), a partial structural detail of the side section of the double-structure block tank connection section of the marine hydro-electric power plant lifting plant, and a dual-structure holding tank and a floating navigation system to explain the overall construction of the marine hydro- , Which shows the construction of a marine nuclear hydroelectric power plant floodplain distribution input device of the whole structure showing the decomposition and connection of the marine nuclear hydroelectric power plant as a block tank unit of a marine nuclear hydroelectric power plant, Marine Nuclear Hydroelectric Power Plant Floating Plant Nuclear Hydroelectric Power Plant Configuration of the body assembly method Fig.
FIG. 4D is a schematic view showing the structure of a nuclear reactor power plant nuclear waste disposal unit (1) of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, 811a), bridge pier (928), pipe bridge (937) and marine tunnel (932) showing the configuration of the construction machine position control of the hull position movement control of the marine nuclear hydroelectric power station floodplain (593,594,595) (771) Nuclear hydroelectric power plant of the marine tunnel inside the traffic device (941).
FIG. 4E is a schematic view showing the structure of a nuclear power plant nuclear waste disposal unit (1) of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, 811a) showing the decomposition coupling unit of a flood control block tank of a hydroelectric power station of a marine hydroelectric power plant.
FIG. 4f is a schematic view illustrating a structure of a nuclear power plant nuclear waste disposal unit of a nuclear power plant (811) within a nuclear reactor main body (1) of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention 811a) is equipped with a marine safety tooling band guide device (621) at the top of a sea semi-submerging operation line to provide a welding connection assembly operation for the double structure block tank (598) of the marine hydro- A dual structure block tank side connection scheme showing the preparation process; a partial dual structure block tank 598 partially showing double structure block tank 598 and band guide 621; A schematic view of a hydroelectric power plant lifting hood assembly hull assembly.
FIG. 4g is a schematic view of a reactor structure of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. (1) Nuclear power plant facilities (811) Nuclear power plant Nuclear waste treatment facility (811a) Nuclear power plant equipment that constitutes the connection axis position Nuclear waste treatment Dispensing input device Marine hydro power plant Floating structure block tank 598), which is used to construct the connection assembly, is replaced with a tied-up winch 958 and connected to the inside of the reactor installation main body 1 of the nuclear power plant 959, the tugboat 636, 958) and a tie-line (636) to provide an alternative anchorage chain (640) to the anchor chain. The tugboat (636) A double structure block tank (598) of 500m unit of block tank pipe bridge (929) is connected to the sea water surface as a connecting structure to construct a temporary voyage passage for a ship. At the same time, a nuclear waste treatment double structure block tank bridge bridge (929) (598) Partial double structure Block tank (598) Unit part Partial side view Detailed construction of nuclear waste treatment double structure block tank bridge bridge (929) Nuclear power plant lifting stand.
FIG. 4h is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant nuclear waste disposal unit of the nuclear power plant (811) (593,594,595) showing the arrangement of the position adjustment mechanism of the construction machine for the hull position movement control of the marine hydroelectric power station floating structure (593,594,595) constituting the upper part (SDU) of the dock hull deck of the marine power plant with the vertical partition wall A large flange connection to a portable lug 607 and a portable lug pin 608 to a connecting lug coupling pin connection shaft 606. FIG.
FIG. 4I is a schematic view showing a structure of a nuclear plant including a double structure block tank dust collector for nuclear waste disposal according to the present invention. A concrete mixer 865 and a concrete finisher 866, which show the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant floodplain (593, 594, 595) constituting the marine power plant dock hull deck upper part (SDU) Truck (868) Diagram of a strapless connection of a construction machine connection structure.
FIG. 4J is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. ) Of a marine power station dock top deck (SDU) of a marine power plant with the asphalt finisher 871 and the asphalt spreader 874 attached to the hearth safety device 864 showing the configuration of the position control mechanism of the construction machine of the marine hydro- Of the boom (882a) and the diesel pile hammers (883) to the pile driver (872) and the pile driver (882).
FIG. 4K is a cross-sectional view of a nuclear reactor structure of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. ) Pump dredger 879a of the dredger 879 and the bucket dredger 879a of the dredger 879 showing the construction machine position control arrangement of the marine hydroelectric power station flood control 593,594,595 of the marine power station dock hull deck upper part (SDU) Diagram of Construction of Connecting Structure for Construction Machinery.
FIG. 4L is a schematic view showing the structure of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. (879l) Construction view of the connection structure of construction machine showing the regulation structure of the construction machine position of the hull position movement control of the marine hydroelectric power station floodplain (593,594,595) at the upper part of the dock hull deck of the marine power plant.
FIG. 4M is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (874) connection structure showing control structure of construction machine position adjustment of hull position movement of marine hydroelectric power plant floating attachment (593,594,595) constituting at upper part of SDU of marine power plant dock hull deck (SDU).
4n is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. ) Of the previous cylinder 126 showing the arrangement of the construction machine position adjustment of the hull position movement control of the marine hydroelectric power station floodplain 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) Plunger pump (148b) and radial plunger pump (148c).
4O is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) consisting of a marine hydroelectric power plant floating structure on the upper part of a ship's dock (SDU) of a marine power plant. Cylinder (126) .
4P is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of a nuclear power plant 811, A cylinder 126 showing a construction machine position adjustment structure of a hull position movement control of a marine hydroelectric power station floating ordinance 593,594,595 constituting a hull deck upper part (SDU), and a piston motor 885a of a hydraulic crane 885. Diagram of the strabismus of.
FIG. 4q is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Construction of a hydraulic system of a marine hydro-power plant (593,594,595) in the upper part of the ship's deck (SDU) Physician time chart.
4r is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant comprises a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of the nuclear power plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4 is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4T is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of a nuclear power plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
FIG. 4U is a schematic view of a nuclear power plant with a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and manufacturing section 811b of the nuclear power plant 811, Hydraulic power plant showing construction arrangement position regulation of hull displacement control of marine hydroelectric power station floating structure composed on upper part of hull deck (SDU).
FIG. 4v is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of the nuclear power generating plant 811, Hydraulic power plant showing construction arrangement position regulation of hull displacement control of marine hydroelectric power station floating structure composed on upper part of hull deck (SDU).
FIG. 4w is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Referring to FIG. 4w, the power generating and manufacturing unit 811b of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant, A schematic view of the connection structure showing the control structure of hydroelectric power plant construction machine for controlling the hull displacement of a marine hydroelectric power plant floating structure constructed at the upper part of the hull deck (SDU).
FIG. 4x illustrates a dual structure block tank scrubber for treating nuclear waste according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant having a dust collector for treating nuclear waste, a power generating and producing unit 811b of the nuclear power generating facility 811, Hydrodynamic power plant of Bernoulli theorem showing control arrangement of construction machine for hull position movement control of marine hydroelectric power station floating structure (593,594,595) at the upper part of hull deck (SDU).
[0064] FIG. 4 (d) is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Referring to FIG. 4, a nuclear power plant is installed in a nuclear power plant main body 1 of a nuclear power plant, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
4z is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear power plant includes a main body 1 of a nuclear power plant, a power generating and producing section 811b of a nuclear power generating plant 811, Hydraulic power plant construction structure connection structure showing control structure of construction machine position of hull displacement control of marine hydro - power plant flood control station (593,594,595) at the top of hull deck (SDU).
FIGS. 4A to 4Z are diagrams illustrating one embodiment of a reactor installation of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention.
FIG. 5 is a schematic view illustrating a boiling water reactor installation 802 in a nuclear waste treatment reactor installation in a nuclear reactor installation part 811 of a nuclear reactor installation main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (802) of a nuclear power plant equipped with a dual-structure block tank dust collector to provide input (802) a nuclear power plant having a double structure block tank dust collector for elementary nuclear waste treatment showing decomposition coupling method FIG. 2 is a side view of a representative embodiment of the present invention showing a disassembly-type configuration of an embodiment comprising a reactor facility. FIG.
5a shows a boiler water reactor installation 802 in a nuclear reactor power plant 811 and a nuclear waste treatment reactor 781 in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention. A double structure block tank which constitutes an embodiment of a nuclear waste treatment reactor installation for providing input; a boiling water reactor installation (802) of a nuclear power plant having a dust collector; and a dual structure for elementary nuclear waste disposal The present invention relates to a reactor structure of a nuclear power plant having a block tank dust collector, and more particularly, to a boiling water reactor system (802) decomposing and coupling system of a nuclear power plant having a double structure block tank dust collector .
5b is a schematic view of a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. 802) Nuclear waste disposal reactor facility to provide a dual-structured block tank dust collector that constitutes one embodiment of a combined system. Boiling water reactor facility (802) of a nuclear power plant having a dust collector. The present invention relates to a reactor structure of a nuclear power plant having a dual structure block tank dust collector. The reactor structure of the present invention is a disassembly type structure. The reactor structure of a boiling water reactor (802) of a nuclear power plant having a dual structure block tank dust collector , Sectional view.
5c is a schematic view of a boiler water reactor installation 802 in a nuclear reactor power plant 811 inside a nuclear reactor reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. ) Dual reactor block reactor which constitutes one embodiment of the nuclear waste treatment reactor installation to provide the input. A boiling water reactor installation (802) of a nuclear power plant having a dual-structure block tank dust collector. The present invention relates to a reactor structure of a nuclear power plant having a dust collecting tank, a structure block tank dust collector, a double structure block tank, a nuclear waste disposal apparatus of a nuclear power plant having a dust collecting apparatus, Fig.
5D is a schematic view of a boiler water reactor installation (802) installed in a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention, ) Nuclear waste disposal reactor facility for providing input Nuclear waste reactor water reactor system (802) of a nuclear power plant having a dual structure block tank dust collector constituting an embodiment of the coupling system The decompositionally coupled deep reactor safety reactor facility side A double structure block tank for the treatment of nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the nuclear power plant having a double structure block tank dust collector Waste disposal equipment boiling water reactor facility (802) Deep - coupled safety reactor facility side, cross - sectional view.
FIG. 5E is a schematic view illustrating a dual structure block tank dust collector for nuclear waste disposal according to the present invention. FIG. 5E is a schematic view of a boiler water reactor (802) installed in a reactor facility main body (1) ) Nuclear waste disposal reactor facility for providing input Nuclear waste reactor water reactor system (802) of a nuclear power plant having a dual structure block tank dust collector constituting an embodiment of the coupling system The decompositionally coupled deep reactor safety reactor facility side A double structure block tank for the treatment of nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the nuclear power plant having a double structure block tank dust collector Waste Treatment Equipment Boiling Water Reactor Facilities (802) Deep - coupled Safety Reactor Facility Side, Cross - section Diagram.
5f is a schematic view of a boiler water reactor (802) installed in a reactor facility main body (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention, ) Nuclear waste disposal reactor facility to provide input Nuclear waste disposal facility (802) of nuclear power plant with dual structure block tank dust collector constituting one embodiment of coupling system Disassembly coupling type deep safety nuclear reactor facility side, An embodiment comprising a reactor facility of a nuclear power plant having a dual structure block tank dust collector for elementary nuclear waste disposal showing a loess mixture (927) for control goods soap bubble and a previous unprotected state nuclear explosion is shown in an exploded The present invention relates to a nuclear waste disposal apparatus for a nuclear power plant having a dual structure block tank dust collector Rank perspective configuration of reactor equipment (802) coupled decomposition method depth safety nuclear reactor equipment-side, end surface processing of nuclear waste control supplies lather soil mixture 927 and the previous unprotected nuclear explosions for the FIG.
FIG. 5g is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) showing the structure of the reactor plant mooring system of the nuclear power plant as a construction machine for controlling the displacement of the marine hydroelectric power station floating structure of the deck upper part (SDU). The vertical partition wall 605 of the disassembling assembly and the portable lug coupling pin A large flange connection joint in the portable lug 607 and a portable lug pin 608 in the connection shaft 606 a processing hole 615 in the joint portion of the nuclear power hydroelectric power plant construction machine.
5H is a schematic diagram of a disaster prevention apparatus constructed in a plurality of marine nuclear power plants of a nuclear power generation facility 811 inside a nuclear power plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention FIG. 3 is a side view showing the construction of a disaster prevention apparatus constituting a plurality of elementary nuclear power plants showing the side of the disaster prevention apparatus showing the disaster prevention apparatus shown in FIG.
FIG. 5I illustrates an embodiment of a nuclear reactor plant main body 1 having a double structure block tank dust collector for treating nuclear waste according to the present invention. In FIG. 5I, The production of manganese nodules, a submarine mineral resource, and the production of manganese nodules of submarine mineral resources showing the operation mode of submarine submarine development into the nuclear reactor main body 1 of the elemental nuclear power plant, Diagram of a strapless arrangement of a scene.
5j illustrates an embodiment of the nuclear power plant 811 inside the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (1) of the elementary nuclear power plant of a nuclear power plant showing a scene in which natural gas or crude oil energy at the bottom of the sea floor and manganese nodule as a submarine mineral resource are produced at a tower crane seize crane boom zone (942) (811f) of the Nuclear Power Plant (811), which provides the production of manganese nodule for seafloor mineralization, showing the composition of the submarine development work.
FIG. 5K shows an embodiment of the nuclear power plant 811 inside the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (1) of the elementary nuclear power plant of a nuclear power plant showing a scene in which natural gas or crude oil energy at the bottom of the sea floor and manganese nodule as a submarine mineral resource are produced at a tower crane seize crane boom zone (942) A tower crane showing the construction of the operation structure of the submarine submarine development. A scene composed of an electronic control device construction machine control section 811f of the nuclear power generation facility 811 for preparing seabed mineral resource manganese nodule by the seesaw crane boom zone 942 Side view.
FIG. 5L shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with boiling water reactor facilities (802), pressurized water reactor facilities (803), gas cooling furnace reactor facilities (804) and multipurpose hot gas furnace reactor facilities 805) and a new type of reactor facility (806) and a fast breeder reactor facility (838) are shown in a side elevational view in the side view of a nuclear reactor plant (1) (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with a boiling water reactor (802) and a pressurized water reactor (803) And a gas cooling furnace reactor facility (804), a multipurpose hot gas furnace reactor facility (805), a new conversion furnace reactor facility (806), and a fast breeder reactor facility (838).
5m illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) nuclear power plant (672) of a marine ocean power plant and a boiling water reactor facility (802) of a nuclear power plant. ) Inside of the Nuclear Power Plant A number of nuclear reactors Installed at the ocean power plant showing the construction of the nuclear power plant The construction of the side view of the nuclear power plant consisting of the nuclear power plant (672) and the boiling water reactor facility (802)
5n illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, The reactor main body 1 of an elemental nuclear power plant showing a side view of the nuclear power plant operating structure consisting of a floating power plant (593,594,595) of a marine marine power plant (593,594,595) and a boiling water reactor plant (802) (Fig. 6). Fig. 6 is a side cross-sectional view of a nuclear power plant constructed at a nuclear power plant (672) and a boiling water reactor (802) at a nuclear power plant showing the construction of a nuclear power plant.
5a illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) of the offshore marine power plants and nuclear power plants (803), the side view of the nuclear power plant operating system, ) Inside flood control plant Numerous reactor installations showing the construction of the nuclear power plant Operation of the offshore plant at the ocean power plant (672) and the nuclear power plant with the pressurized water reactor system (803).
5p shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, (593,594,595) nuclear power plants (672) of the offshore marine power plants and nuclear power plants (803), the side view of the nuclear power plant operating system, ) Inside flood control plant Numerous reactor installations showing the construction of the nuclear power plant Operation of the offshore plant at the ocean power plant (672) and the nuclear power plant with the pressurized water reactor system (803).
FIG. 5q illustrates an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear cooling power plant (804) of nuclear power plant. 1) Inside flood control plant A number of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of nuclear power plant (672) and atomic power plant is composed of a gas cooling furnace reactor facility (804) Degree.
5r shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear cooling power plant (804) of nuclear power plant. 1) Inside flood control plant A number of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of nuclear power plant (672) and atomic power plant is composed of a gas cooling furnace reactor facility (804) Degree.
FIG. 5s shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear power plant is equipped with multipurpose hot gas furnace reactor facility (805). 1) Inside of the plant The installation of a number of nuclear reactors Installations of the marine power plant showing the construction of the nuclear power plant (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multipurpose hot gas furnace reactor facilities (805) Cross - sectional view.
5t shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine marine power plant and nuclear power plant is equipped with multipurpose hot gas furnace reactor facility (805). 1) Inside of the plant The installation of a number of nuclear reactors Installations of the marine power plant showing the construction of the nuclear power plant (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multipurpose hot gas furnace reactor facilities (805) Cross - sectional view.
FIG. 5U shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, (593,594,595) Nuclear power plant (672) of marine ocean power plant and nuclear power plant, and a new conversion reactor facility (806) of ocean nuclear power plant. 1) Inside a floating plant A large number of nuclear reactors Installations of a marine power plant showing the construction of a nuclear power plant Construction of a nuclear power plant (672) and a nuclear power plant with a new conversion reactor (806) Degree.
FIG. 5v shows an embodiment of a nuclear power plant 811 inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of marine ocean power plant and nuclear power plant, and a new conversion reactor facility (806) of ocean nuclear power plant. 1) Inside a floating plant A large number of nuclear reactors Installations of a marine power plant showing the construction of a nuclear power plant Construction of nuclear power plant (672) and a nuclear power plant with a new conversion reactor (806) Degree.
FIG. 5w illustrates an embodiment of the nuclear power plant 811 inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) and ocean nuclear power plants (672), and nuclear reactors (838), which are shown in side elevation in the side view of nuclear reactors. ) Inside a floating plant A large number of nuclear reactors Installed at a nuclear power plant (672) of a marine power plant showing the construction of a nuclear power plant and a nuclear power plant equipped with a fast breeder reactor facility (838).
5x illustrates an embodiment of the nuclear power plant 811 in the reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plants (672) and ocean nuclear power plants (672), and nuclear reactors (838), which are shown in side elevation in the side view of nuclear reactors. ) Inside a floating plant A large number of nuclear reactors Installed at a nuclear power plant (672) of a marine power plant showing the construction of a nuclear power plant and a nuclear power plant equipped with a fast breeder reactor facility (838).
5E is a schematic view of a nuclear reactor nuclear waste disposal unit 811a of a nuclear power generation facility unit 811 inside a reactor facility body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) nuclear power plants (672) for offshore and offshore marine power plants, and nuclear power plants are equipped with a number of nuclear reactor facilities installed in nuclear waste treatment double structure block tank bridge (929). Nuclear power plant (672) that constitutes nuclear waste disposal Nuclear power plant (672) of marine power plant showing elemental structure showing side view of operation method of nuclear power plant Nuclear power plant has nuclear waste treatment double structure block tank bridge (672) arrangement of nuclear power plant scenes consisting of nuclear power plants (929).
5z is a nuclear power generation nuclear waste treatment unit 811a of a nuclear power generation facility 811 inside a nuclear power plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention. (593,594,595) nuclear power plants (672) for offshore and offshore marine power plants, and nuclear power plants are equipped with a number of nuclear reactor facilities installed in nuclear waste treatment double structure block tank bridge (929). Nuclear power plant (672) that constitutes nuclear waste disposal Nuclear power plant (672) of marine power plant showing elemental structure showing side view of operation method of nuclear power plant Nuclear power plant has nuclear waste treatment double structure block tank bridge (672) arrangement of nuclear power plant scenes consisting of nuclear power plants (929).
5a] to [5z] are diagrams illustrating an embodiment of a reactor installation of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention constitution of the related art.
FIG. 6 is a schematic view showing the construction of a nuclear reactor plant main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The tumbler winch 137 and the wire rope 19 of the elevator machine room constructed of the decelerator 251 and the electric motor body 192 on the roof of the building and the building are attached to the upper portion of the steel tower 116 with the driving wheel roller 135 (256) Firefighting sensor pump (256) Firefighting and disinfection countermeasures The fire suppression line was constructed in such a way that it was able to evolve in less than one second, and the top of the mountain valley and the fire prevention and disaster prevention line around the beach were constructed. (256) of the nuclear power plant (811) showing the construction of the preventive control section of the emergency fire prevention sensor of the emergency fire prevention device (811).
FIG. 6a is a schematic view of a nuclear hydro power generation and production section of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, (811b) of the nuclear power plant 811 showing the configuration of the position adjustment mechanism of the hull of the marine hydroelectric power plant lifting console (593, 594, 595) constituting the marine power plant body dock hull deck upper part (SDU) Hydraulic power plant construction diagram of a connecting structure.
FIG. 6B is a schematic view of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. Production Production Department (811b) Marine Power Plant Body Dock Hydraulic power station or marine hydroelectric power plant (943) showing the arrangement of the construction machine position control of the hull position movement of the marine hydroelectric power station floodplain (593,594,595) constituting the upper part of the deck (SDU) Aberration or pump aberration 264 and main valve 265 hydroelectric power plant construction machine connection structure.
6C is a schematic view of a nuclear hydro power generation and production unit (hereinafter, referred to as &quot; nuclear hydro power generation &lt; RTI ID = 0.0 &gt; production &lt; / RTI & (811b) Marine dock Body dock Marine hydroelectric power production and production department showing the arrangement of construction machine position control of hull position movement of marine hydroelectric power plant floating attachment (593,594,595) at the upper part of ship hull deck (SDU) Construction diagram of connection structure of construction machine.
6D is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing the power of the nuclear power generation facility unit 811 in the nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention (678p) Hydraulic power plant construction machine (678p) in the Han river system showing the regulation structure of the construction machine position of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the upper part of the deck of the marine power plant (SDU) Diagram of the connection structure.
FIG. 6E is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing power of a nuclear power generation facility unit 811 in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention TORICELLI 's theorem of hydroplaning structure of the marine hydroelectric power station (593, 594, 595) on the hull deck upper part of marine power plant dock (SDU) .
FIG. 6f is a schematic view of a nuclear hydro power generation production control unit (not shown) for generating a power of a nuclear power generation facility unit 811 inside a nuclear reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention. Structure of the microswitch 580 showing the arrangement of the construction machine position adjustment of the hull position movement of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part of the marine power plant deck (SDU) of the marine power plant. 183) and a diaphragm type pressure switch (104a) with a pneumatic-sensor pressure switch (104b).
FIG. 6G is a schematic view showing a structure of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for generating power of a nuclear power generation facility unit 811 in a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention Marine power plant body dock Construction of a marine hydro power plant floating structure (593,594,595) on the upper deck (SDU) of the marine power plant Construction of the control of hull position control of the fire Fire temperature sensor showing the position control configuration Sensor sensor Bimetal (102) thermocouple configuration method A thermocouple thermometer switch 103 for detecting the temperature of the thermocouple 103 is provided at a measuring point 102d of the thermoelectric generator 102c and the thermocouple generator 102b.
6H is a schematic view of a nuclear hydro power generation production control unit (hereinafter, referred to as &quot; nuclear hydro power generation production control unit &quot;) for producing power of a nuclear power generation facility unit 811 inside a nuclear reactor facility main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention A plurality of gear pumps 326 and a vane pump 142 for showing the construction machine position adjustment structure of the hull position movement control of the marine hydroelectric power plant flood control consoles 593, 594, 595 constituting the upper part of the marine power plant dock hull deck (SDU) Lt; RTI ID = 0.0 &gt; 474 &lt; / RTI &gt;
FIG. 6I is a schematic view showing the construction of a double structure block tank dust collector for nuclear waste disposal according to the present invention. (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Dependent reading compartment in the upper part.
FIG. 6J is a plan view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, and a water transportation facility 811c of a construction machine of a nuclear power generation facility 811, (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Diagram of the floatation of the floats in the upper part.
6k is a schematic view of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention, and a water transporting unit 811c of a construction machine of a nuclear power generation facility 811, (680), which shows the structure of the dam operation of the flood control facility showing the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the power plant body dock upper deck (SDU) The upper and lower floors of the river basin dam (680) shown in the upper part of the gate (293) of the river basin dam (680) 293) Diagram of the floatation of the floats in the upper part.
[61] FIG. 61 is a schematic view showing the structure of a nuclear power plant having a dual structural block tank dust collector for nuclear waste disposal according to the present invention. A structure for illustrating an embodiment showing a mountain top portion in which initial evolution occurs within one second for each type, a collecting pump of an elevator machine room for each building and a building, and a disaster prevention and disaster prevention device for disaster prevention prevention at a fire installation position A schematic cross sectional view of a distributing and inputting device of disaster control disaster prevention device showing hydroelectric power plant.
FIG. 6m is a cross-sectional view of the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. FIG. 8 is a side view showing a configuration of a nuclear disaster prevention and disaster control system of a nuclear power generation facility 811 showing an embodiment showing a disaster control disaster prevention device of a double pipe structure fire hose installation operation.
FIG. 6n is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Sectional structure of the disposal injection device of the disaster control disaster prevention device of the nuclear power generation facility 811 showing the configuration illustrating one embodiment showing the disaster control disaster prevention device of the accident prevention shutdown prevention part of the double pipe structure fire hose installation operation Degree.
FIG. 6 is a schematic view illustrating an internal structure of the reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A trash pump fire extinguisher fire prevention type collecting tank and an alternate manometer turn type level balance pipe nozzle disaster prevention prevention part constituting an evolution, (811) Hydroelectric power plant of flood control system Dispatching device of flood control disaster prevention device Manometric turn type level balance pipe Diagram of strabismus.
FIG. 6p is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. The hydrothermal power generation unit 811 of the nuclear power plant 811 showing the construction of one embodiment showing the disaster control and disaster prevention device of the carbon dioxide gas fire extinguisher for preventing the disaster of the carbon dioxide gas fire extinguisher by the installation of the pipe nozzle collecting tank of the stepwise non- Installation of disaster control disaster prevention system.
FIG. 6Q is a schematic view of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. Of a double vinyl tent nozzle type fire-fighting water supply system of a ridge line within a predetermined time or less from the beginning of a fire and an emergency disruption device installation method of a hurricane disruption device installation method of a nuclear power generation system showing an example of a disaster- A schematic diagram of an early stage fire of A fire and a side view configuration of a disaster control disaster control disaster control apparatus including a power plant of a nuclear power plant of the facility unit 811. [
FIG. 6 r is a diagram illustrating an example of an internal structure of a nuclear reactor power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A three-stage stepped pump fire extinguisher that is adapted to evolve, a fire extinguishing system collecting tank, and an alternate manometurn type level balance pipe nozzle disaster prevention preventive system. Power generation facilities to be included in the nuclear power plant of nuclear power generation facility (811) Power generation facility to provide electricity to the power generation facilities of nuclear power plant Three-stage stepped pump fire extinguisher Collecting tank of fire preventive type and substitute manometer turn type level balance nozzle Dispensing disposing device of disaster control disaster prevention device Side view.
6 is a schematic view of a nuclear reactor power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. Showing a configuration for illustrating an embodiment showing a disaster-controlled disaster prevention device for preventing a disaster of a disaster prevention preventive control unit constituting a ship 1078 having a conventional sinking ship and rescue force rescue force capable of failing to sink and prevent a strong wind wave 1101 The ship 1078 having the rescue force for the treatment of the nuclear waste of the nuclear power plant of the nuclear power generation facility 811 is transferred into the reactor main body 1 of the nuclear power plant to prevent the disaster of the nuclear power generation facility 811 Of the present invention is provided with a nuclear reactor power plant.
FIG. 6 t is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ The hatch cover 153, the lifesaving bed nozzle 172 and the rope rope 629 provided on the ship 1078 having the rescue force for nuclear waste disposal for nuclear power generation plant nuclear power plant of the nuclear power generation facility unit 811, An elevator alley bed 632, a conveyor 633, a bollard 638, an anchor 639, anchor chain 640 and helicopter 647 Equipped nuclear power plant A nuclear ballast (914) of a ship 1078 equipped with a rescue force rescue force rescue force resisting ability of a reactor plant of a nuclear power plant, which is included in the disaster prevention preventive control section of the nuclear power generation facility section 811, Side view.
FIG. 6U is a schematic diagram of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (925) of a typhoon and a downward airflow (926) air flow regulating device among the devices of the nuclear power plant (925) showing a constitutional example of a constitutional example showing a disaster- 811), a nuclear waste disposal apparatus for a nuclear power plant of a nuclear power plant, a garden hatch basket 951 for a harmful rust-inhale-suction dust collector, a flexible high-pressure hose 190, an introduction pipe 191, a blower 641, 642), a loess cement mixing equipment mixer machine 649, a crane boom frame 651, a crane boom hook 652, a rubber balloon 914, an air nozzle 923, a loess mixture 927 for soap bubbles, 934 and the cooling air bubble 939, The inside of the reactor main body 1 of the nuclear power plant having the disaster prevention nozzle 945, the submarine line wiring 946, and the double structure air introducing rubber tubing 947 inside the container for the throttle device is connected to the inside of the reactor main body 1 811) Nuclear power plant reactor facilities to provide protection against disruption Prevention of flood control Disaster prevention equipment (925) and downward airflow (926) for airflow control Nuclear waste treatment equipment and harmful rust A ventilator 641 and a heater fan 642 for maintaining the air, a yellow loess cement mixing equipment mixer machine 649, a crane boom base 651, and a flexible high pressure hose 190, an introduction pipe 191, a flexible high pressure hose 190, The crane boom hooks 652 and the rubber balloons 914 and the air nozzles 923 and the yellow soil mixture 927 for soap bubbles and the crude oil drills 934 and the cooling air bubbles 939 and the disaster prevention nozzles 945 and the seabed The line wiring 946 and the inside of the container for the needle- In structure air rubber tube probe 947 side diagram.
FIG. 6 (b) is a schematic view showing the construction of a nuclear reactor plant main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided on a ship 1078 equipped with a power generation facility nuclear waste disposal device of a nuclear power plant of the nuclear power generation facility 811, 626, elevator alibite 632, conveyor 633, bollard 638, anchor 639, anchor chain 640, and helicopter 647, as well as the rope knot claw 630, the emergency stairs 631, Atoms with Nuclear power plant nuclear reactor power plant disaster control disaster prevention device which is included in preventive disaster prevention control part of nuclear power generation facility part (811) inside nuclear power reactor facility main body (1) of power plant Rubber balloon of vessel (1078) 914) Side perspective view.
FIG. 6w is a schematic view of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention. A disaster-preventing and disaster prevention device constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101. [ A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided on a ship 1078 equipped with a power generation facility nuclear waste disposal device of a nuclear power plant of the nuclear power generation facility 811, 626, elevator alibite 632, conveyor 633, bollard 638, anchor 639, anchor chain 640, and helicopter 647, as well as the rope knot claw 630, the emergency stairs 631, Atoms with Nuclear power plant nuclear reactor power plant disaster control disaster prevention apparatus that provides protection to disaster prevention prevention part of nuclear power generation facility part (811) inside nuclear power reactor facility main body (1) of power plant Ship with resilience for life rescue force (1078) Rubber balloon (914 Side perspective configuration.
FIG. 6 (a) is a plan view of a reactor structure of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. A peace-preserving message that restores peace-preserved message photo-shoots (958), more powerful than bombs, to each region within a radius of 1200 km from the center of the peninsula, to fulfill its duties under the rights and obligations of the establishment of a new federal state in Northeast Asia A nuclear waste disposal apparatus for a nuclear power plant of a nuclear power generation facility 811 showing a constitutional example illustrating a photo shoot 958 and a peace preserved message photo shoot 958 are installed in a radius It is a peace-preserving type that re-establishes each region within 1200km and fulfills its duties according to rights and duties according to the establishment of a new federal state in Northeast Asia. Fig. 8 is a side perspective view of the view photo shovel 958; Fig.
6A to 6F are diagrams illustrating an example of a dual structure multi-purpose hot gas reactor installation of a nuclear waste disposal nuclear power plant for nuclear power generation according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention. Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the width, length, thickness, and the like of the components may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

×핀 몸체 직경∮;500×2×10∮mm)을 접속하면서 핀 연결축 끝단 부위로 가공된 나사산 위치에 너트로 분해결합을 하면서 동시에 예인선에 이송된 이중구조블록탱크는 반잠수작업선에 탑재되는 밴드지그대에 의해서 조립되는 지주탱크 상단의 바지선선체(가로×세로×높이×철판두께;600M×800M×40M×18mm)와 지주탱크 하단의 바지선선체는 관교량(가로×세로×4곳 모서리 직경×두께×제작단위;15M×15M×π15M×24m m×1Km)에 지주탱크와 내부 블록탱크의 둘레면으로 구성되는 외부블록탱크에 각개로 결합 구성된 크기는 소형의 해양발전소 부양식독(가로×세로×높이;600M×800M×800M)에 중형의 해양발전소 부양식독(가로×세로×높이;2Km×3.2Km×2Km)와 대형의 해양발전소 부양식독(가로×세로×높이;10Km×10Km×10Km)으로 해양수심에 따라 구성 작동하면서 동시에 휴대용 러그 핀이 러그 연결축의 가공 홀에서 볼트 너트 체결되면서 동시에 러그 핀이 이탈되지 않도록 핀 꺾기로 설치를 마무리하고 지주탱크 하단의 바지선 선체의 받침대 조절기구 작키베드 와 코아드릴(직경 350Ø 또는 400Ø)로 구비된 홀 캇팅 굴착 드릴 장치가 탑재되어 구성된 해양수력발전소는 침몰방지 부력조절 장치에 의해 해상에서 조립되면서 지주탱크 상단의 바지선 선체의 상단의 갑판데크 상단과 하단의 각개 위치로 구성하는 분사노즐(노즐구멍 지름 3mm 또는 5mm 노즐수량 70개소 7마디로 된 방사선 형식의 틈새와 490여 개 노즐구멍이 구비된 장치노즐)과 배관노즐 몸체(B) 내부에 소방호스 내수압을 갖춘 방화수에 의해 분사노즐 틈새로 토출분사수와 커텐물막이 토출되면서 다수개로 타오르는 불기둥을 감쪽하는 순간에 제거하면서 동시에 태풍과 토네이드기류의 흐름을 조절하는 수해조절설비의 수해조절기계의 분배투입장치 다수개의 분사노즐은 본체 내부로 마련하고나,동시에 상기 원자력발전 핵폐기물처리용 이중구조블록탱크 집진기를 구비한 원자력 발전소의 원자로설비 설치 조절을 마련하는 조절축의 핵폐기물처리 이중구조블록탱크 해양터널교통장치와 해양 원자력수력발전소 부양식독의 분배투입장치 원자력 발전소설비에는,그 어떠한 악 조건의 기상상태에서도 안전항해 선박이 복원력을 상실하지않으면서 선원과 승객들의 침몰 사상자가 발생 되지 않으면서 동시에 바지선선체의 관교량 물체의 하중을 분산시키고 부침조절장치 분배투입장치들로 해양원자력 수력발전소설비 개보수를 마련하고나,동시에 지구촌 원자력발전소 설비와 다수개의 원자로설비 원전가동을 마련하고나,동시에 차폐장치의 원자로설비 핵폐기물처리용 이중구조블록탱크 집진기를 구비한 원자력 발전소설비와 원자력 발전소의 원자로설비 분배투입장치 탑재 가동용과 해양환경산업 경제발전에 따른 건설기계의 해상크레인들을 포함하여 마련한 것을 본 발명 원자력발전용 핵폐기물처리 원자력 발전소설비의 이중구조 고속증식로 원자로설비에 합당하게 구성하였다.The present invention relates to a nuclear reactor waste nuclear reactor plant having a dual structure. The main constituent of the nuclear reactor reactor reactor is a double structure firefighter injection nozzle apparatus which is formed of KSD 3705 hot rolled stainless steel material at the top of the sea surface and the upper surface of the earth. At the same time, at the same time, nuclear power plant facilities are equipped with a double structure block tank holding tank and a double structure block tank barge hull having a cylindrical shape with KSD 3705 hot rolled stainless steel pipe and an inner block tank installed outside the circumferential surface of the holding tank Material selection is provided by KS D 3705 steel (KS symbol: STS x HP, ST-Steels S-Steel H-Hot P-Plate) which forms nuclear plant facilities with steel plates supporting and reinforcing outer block tanks. Marine Nuclear Hydroelectric Plant Facilities The floodplain size includes a small floodplain and a small floating vestibule block block tank top pants The size of the hull is as follows: width × length × height × thickness of steel plate (T), 600M × 800M × 40M × 30mm, medium lifting stand and medium lifting stand type block block tank top barge hull size, width × length × height × The length of the barge hull at the top of the tanks (2 mm x 3.2 km x 40 m x 32 mm) and the large floats and the large floats of the floodgate block block tanks are as follows: width x length x height x thickness of steel plate, 10 km x 12 km x 40M x In the standard crossing the earth in three forms of 35mm, 40.000km nuclear waste treatment double structure block tank pipe bridge marine tunnel traffic equipment facility is prepared and the above standard specification of the marine nuclear hydroelectric power plant equipment distribution apparatus × depth × 4 corner diameter × thickness of iron plate × length of production unit, 15M × 15M × π 15M × 35mm × 0.5km), and the bridge pier of the marine tunnel traffic equipment of the bridge bridge is set to 5M in diameter, The diameter of the pipe pier is 1M to 5M above the laddual connection M diameter and additional double band structure tank pipe bridge construction several band guides and several construction machines are installed and the pipe bridge is positioned at 300m height to the top of the sea surface Marine Nuclear Hydroelectric Power Plant Facilities Distribution Sinking prevention device A number of banding ships for the resident vessels and several construction machines were installed, and then the altitude of the SLL and the bottom of the sea level were adjusted to within 100M, so that all marine vessels were prevented from sinking. And the nuclear waste treatment double structure block tank of the nuclear power plant, the nuclear power plant constituting the reactor facility body of the nuclear power plant having the reactor dust collector, and the marine tunnel transportation apparatus of the regulating shaft which regulates the flow of the reactor facility, In the power plant, there is an inner block tank, an inner block tank, and an inner block tank. The length of the pin connecting shaft for connecting the portable lug to the outer wall is 800 mm, the diameter is 300 mm, the thickness of the iron plate of the portable lug is 150 mm, and the pin connecting shaft is interposed between the portable lug and a machining hole ) Has a portable lug pin (length x

× pin body diameter ∮; 500 × 2 × 10 ∮ mm), the double structure block tank transferred to the tug line at the same time while being disassembled with the nut at the thread position processed to the end of the pin connection shaft is mounted on the semi-diving operation line (Width × length × height × thickness of steel plate: 600M × 800M × 40M × 18mm) at the top of the holding tank assembled by you and the barge hull at the bottom of the holding tank, The size of each unit is composed of a holding tank and an outer block tank consisting of a circumferential surface of the inner block tank at 15M × 15M × π 15M × 24m × 1Km in diameter × thickness × unit size. (Length × height × height: 2Km × 3.2Km × 2Km) and a large marine power plant flood control stand (width × length × height: 10Km × 10Km × 10Km ) While operating according to the ocean depth, while the portable lug pin Finishing the installation by bolting to prevent the lug pin from being detached at the same time as the bolt nut is tightened in the connection hole of the connecting shaft. Hole cutter equipped with key bed and core drill (diameter 350 Ø or 400 Ø) on the barge hull at the bottom of the holding tank The marine hydroelectric power plant constructed with excavation drill unit is composed of a spray nozzle (nozzle hole diameter of 3 mm or more) which is composed of the upper and lower deck decks at the top of the barge hull at the top of the holding tank, 5 mm Nozzle number 70 nozzles (7 nozzles) and 490 nozzle nozzles) and piping Nozzle body (B) Fire hose with internal water pressure The number of ejection nozzles As the curtain wall is ejected, a large number of burning pits are removed at the same time, and at the same time, A plurality of injection nozzles are provided inside the main body, and at the same time, a nuclear reactor plant having a double structure block tank dust collector for treating the nuclear power generation nuclear waste, Nuclear waste treatment of regulating shafts to provide installation control Dual structural block tank Marine tunnel transport equipment and marine nuclear hydroelectric power station Separate input devices for nuclear power plant Nuclear power plant equipment is equipped with a safety voyage At the same time, it is necessary to distribute the load of the pipe bridge objects of the barge hull and to adjust the equipment of the marine nuclear hydroelectric power plant by the distributing and feeding devices of the inflow control device. At the same time, At the same time, a plurality of nuclear reactors Nuclear reactor facility for waste equipment Nuclear power plant facility equipped with double structure block tank dust collector for nuclear waste disposal Nuclear power plant installation of nuclear power plant Reactor facility distribution loading device Operation and marine environment industry Nuclear waste disposal for nuclear power plants Nuclear power plants for nuclear power plants Dual structures for nuclear power plants High-speed propagation furnaces were constructed to meet nuclear reactor facilities.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 show a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to an embodiment of the present invention and a double structure block tank dust collector for nuclear waste disposal showing a reactor facility configuration of the nuclear power plant It is a schematic diagram of the main parts of a nuclear power plant facility and nuclear power plant's nuclear power plant assembly process.

Referring to FIG. 5, in a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, a boiler water reactor apparatus (802) of a nuclear waste treatment type double structure block tank having a dual structure block tank dust collector for elementary nuclear waste treatment showing a decomposition coupling method (802) of a nuclear power plant having a tank dust collector An exemplary embodiment of a reactor installation of a nuclear power plant is shown in FIG.

As shown in FIG. 5, in a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment,

Nuclear power plant facilities include nuclear reactor power plants (593,594,595) of marine power plants (673,594,595) and nuclear reactors of nuclear power plants (1). A nuclear power plant and a reactor facility having a double structure block tank 598 for controlling nuclear nuclear waste disposal shielding apparatus and a dual structure block tank collector 794 of nuclear nuclear waste disposal shielding apparatus, ;

As shown in FIG. 5, in the nuclear waste disposal facility of the reactor facility of the nuclear power plant, the yellow soil mixtures mixed with the cooling water are introduced into the core 681 inside the reactor and outside the core 681, If the mixed yellow loess mixtures are filled with nuclear waste disposal apparatuses inside the reactor core 681 and outside the reactor core 681, nuclear fuel collision of the nuclear reactor chamber is controlled and at the same time, The waste treatment is carried out during the operation of the nuclear power plant, and the nuclear waste treatment dual structural block tank dust collector (794) constituting the marine nuclear power plant's marine nuclear power plant (593,594,595) and the nuclear waste treatment dual structure block tank bridge marine tunnel transportation equipment ) Reactor shafts of nuclear power plants having nuclear waste treatment dual structure block tank precipitators 794 as connection shafts;

5, the double structure block tank installation of the nuclear waste disposal dual structure block tank dust collector 794 includes an inner block tank 596 and an outer block tank 599, which can be disassembled and coupled, The double structure block tank cleaner 794 of the nuclear power plant is provided with a double structure block tank 598 by cutting and welding processes with connection structures and at the same time providing a double structure block tank cleaner 794 Devices to provide nuclear waste treatment of the reactor plant to the dual structure block tank scrubber 794;

As shown in FIG. 5, the double structure block tank dust collector 794 includes a double structure block tank dust collector 794 with connection structure construction machine crane 861 that can be disassembled and coupled at a marine vessel manufacturing factory. A nuclear power plant 811 constituted by the interior of a nuclear reactor facility main body of a nuclear power plant provided with a nuclear reactor;

As shown in FIG. 5, the nuclear reactor facility 811 includes a boiler water reactor 802, a pressurized water reactor 803, and a gas cooling furnace reactor A nuclear power plant 811 constituted by the inside of a reactor facility main body of a nuclear power plant provided separately from a nuclear power plant 805, a multi-purpose high temperature gas furnace 805, a new conversion furnace reactor facility 806 and a fast propagating furnace reactor facility 838, A nuclear waste nuclear waste disposal unit 811a;

As shown in FIG. 5, the layered structure having the control shaft for controlling the nuclear waste capacity into the storage tanks of the nuclear reactor nuclear waste processing unit 811a is installed in the nuclear reactor facility main body 1 of the nuclear power plant, , Nuclear power plants in safe and sustainable nuclear power plants Nuclear reactors to prevent nuclear fuel explosion Pre- and post-nuclear power plants Replacement power generation Production of power generation Hydroelectric power plants for wind power generators and thermal power generators to be installed in production Production of nuclear power plants including alternative generation power A power generation and production section 811b of a nuclear power generation facility unit 811 constituted of a reactor facility main body of a nuclear power plant;

5, the double structure block tank reactor 794 of the power production and production section 811b is provided with a plurality of inner block tanks 596 and a central portion of the outer block tanks 599, The double structure block tank reactor 794 is opened to move the crane boom 651 of the locomotion control device construction machine crane 861 to the carrier having the operation of the crane boom hook 652 and the conveyor 633 The dual structure block tank 598, while providing the individual reactor facilities to be adjusted, is constructed inside the nuclear reactor facility body of the nuclear power plant which provides transportation by means of a marine installation connection structure capable of disassembling and coupling in the manufacture of industrial field launch dock A transportation unit 811c of the construction machine of the nuclear power plant 811;

As shown in FIG. 5, the transportation transport unit 811c of the construction machine is installed in the reactor main body 1 of the nuclear power plant, and the capacity of the storage tanks of the nuclear nuclear waste disposal shield apparatus is adjusted ;

5, the control shaft is connected to a power transmission line (not shown) for disassembling and coupling the reactor main body 1 of the nuclear power plant to the strut block tank 590 of the reactor main body nuclear power generation facility 811 of the individual nuclear power plant A nuclear waste treatment dual structural block tank pipe bridge 928 of a dual structure block tank 598 with a unit 811d and a disassembly coupling structure of a connection shaft of a double structure block tank pipe bridge marine tunnel transport apparatus 941, A plurality of openings in the reactor main body 1, and a distribution shaft in which the openings are distributed to the storage tanks of the reactor facility manufacturing apparatus and the nuclear waste processing shielding apparatus;

As shown in FIG. 5, the distribution shaft includes transformers (not shown) for transmitting the power of the nuclear power plant 811 constituting the interior of the nuclear reactor facility of the nuclear power plant providing the capacity to the storage tanks of the nuclear waste treatment shielding apparatus A power transmission portion 811d provided on the rear side of the vehicle body;

As shown in FIG. 5, the power transmission unit 811d is provided with an exhaust gas facility (not shown) that can withstand the natural disasters of the nuclear reactor main body 1 of the nuclear power plant before and after the operation of the reactor, And a nuclear reactor facility main body of a nuclear power plant provided with an exhaust gas outlet and an inlet which are the same as the dust collector of the nuclear power plant 811e;

5, the control facility 688C and the auxiliary building 688D are installed in the reactor building 688A and the turbine building 688B of the nuclear power plant, (688E), a nuclear fuel building (688F), a waste building (688G), and a power plant building (688Z) with connection structures. The control unit 811f of the electronic control and regulating device constructs the control unit 811f of the crane boom of the position movement control device construction machine crane 861, (651) and the conveyor (633) are separated from each other by an electronically controlled regulating device, and the operation of the carrier is controlled by a control device An electronic control regulating device construction machine control unit 811f of the magnetic power generation facility unit 811;

As shown in FIG. 5, the electronic control apparatus construction machine control unit 811f is provided with storage tanks for the nuclear nuclear waste disposal shielding apparatus constructed inside the nuclear reactor facility main body 1 of a nuclear power plant, The nuclear power generation facility 811 including a control shaft for adjusting the capacity of the nuclear power plant in the reactor main body 1 of the nuclear power plant can prevent the explosion of the nuclear fuel in the reactor main body 1 of the nuclear power plant, In the barge hull 591 at the upper end of the double structure holding tank, a power production facility for the nuclear reactor power plant production and distribution unit 811b is provided. At the same time, in the barge hull 592 at the bottom of the dual structure holding tank, The screw control section 811g of the nuclear power generation facility section 811 is connected to the holding tank 590 to control the block tank position movement control device The lug 607 and the lug connection shaft bolt 603 are connected to the disassembly-coupling portable lug-coupling lug pin connection shaft 606. The position adjustment of the adjustment shaft 604 and the axes of the respective adjustment axes is performed by a reactor Further comprises a screw adjusting portion 811g of the nuclear power plant 811 provided inside the facility body 1;

5, the double structure block tank reactor 794 is provided with a double structure block tank sorter 794 and a double structure block tank sorter 794. The double structure block tank reactor 794 includes a double structure block tank reactor 794, A reactor vessel is installed on both sides of the fore and aft ends of the plurality of inner block tanks 596 with a crane boom hook 652 and a conveyor 633 operation on the crane boom base 651 of the position movement control apparatus construction machine crane 861 A nuclear power plant consisting of a nuclear waste disposal unit and a double structure block tank dust collector (794) provided with a safe and continuous nuclear radiation leakage control of a nuclear power generation facility (811) provided inside a reactor facility of a nuclear power plant provided with a position- And the operation of the nuclear power plant is provided inside the reactor main body 1 of the nuclear power plant, but the amount of production power can be freely adjusted, and at the same time, The nuclear waste disposal tank 295 disposed at the upper part of the double structure block tank dust collector 794 is provided sequentially without preparing the disaster preparedness and the reactor facilities of the nuclear power plant are mixed with each other, The nuclear reactor facility of the nuclear power plant of the nuclear power plant operates the nuclear waste treatment reactor providing the transfer of the loess mixtures to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the feed pump 241, If the yellow waste mixture mixed inside the core 681 and outside the core 681 with the nuclear waste treatment and control cooling water is filled into the core 681 inside the reactor and outside the core 681, The nuclear reactor control of the nuclear reactor of the nuclear power plant of the land and the ocean of the nuclear power plant of the mainland (1) In order to maximize the production power and to prevent explosion of nuclear reactors with dual structure block tank dust collector, the reactor facilities should be equipped with a waterproofing system to prevent sinking of marine nuclear power plants and prevent nuclear fuel explosion inside the reactor main body 1 of the offshore nuclear power plant. One Nuclear Waste Treatment Double Structure Block Tank Pipes Construction of the connection axis of the disaster prevention equipment and the construction machine that can withstand the marine tunnel transportation device (941) and the natural disaster of the sea, Operation of nuclear reactors with wind turbines, thermal power generators, and hydro generators that are used in the production of electricity production. Replacement power generation equipment before and after the breakdown of nuclear reactor facilities, and maritime tunnel transport equipment (941) And a construction machine provided with a disaster prevention device and a movement control device .

Referring to FIG. 5A, a reactor structure (1) of a nuclear power plant having a double structural block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor (811) 802) Nuclear waste disposal reactor facility for providing input A dual structure block tank reactor constituting an embodiment of a combined system A boiling water reactor facility (802) of a nuclear power plant with a dust collector (802) The present invention relates to a reactor structure of a nuclear power plant having a dual structure block tank dust collector and a boiling water reactor system (802) of a nuclear power plant having a double structure block tank dust collector (802) Configuration Road,

As shown in FIG. 5A, it is preferable that the subordinate docks 593, 594, 595 of the marine power plant constituting the nuclear power plant 672 and the nuclei of individual reactor facilities constituted inside the reactor main body 1 of the nuclear power plant, Double structure block tank pipe pier (928) and dual structure block tank pipe bridge (937) composed of waste structure double structure strut block tank (590) and double structure block tank (598) Nuclear Power Plant Reactor Facility Provided by Nuclear Power Plant (672) Disassembly Combination of Tank Dust Collector (794) and Dual Structural Block Tank (937) Disassembled Combination of Nuclear Power Plant (811) Nuclear Waste Treatment Plant Manufacturing Process The distribution shaft 705 of the distributor shaft 705 is connected to the double block tank 598 of the distribution shaft 705 by means of an inner block tank 596 which provides a position to the center of the double structure block tank 598, (596) outside (597) as a high-strength stainless steel steel plate (597) in an outer block tank (599) which provides a positional connection to the cutting and welding processes at the industrial site. A double structure block tank (598) The first auxiliary steel pipe 600 for the block tank and the second auxiliary steel pipe 601 for the block tank are connected to the distributing and inputting device of the connection structure of the cutting process and the welding process A large flange 614 for providing a position as a connection structure of the connection shaft to the fork-and-stern connection position of the double structure block tank 598 is provided with a large flange connection flange joint portion machining hole 615, A large flange 614 for providing a position of a nuclear plant is provided with a drill lathe and a cutter for the cutting tool, The stopper plate (625) of the distribution shaft (705) of the tube manufacturing process is constructed such that the double structure block tank (598) of the distribution shaft (705) And an overhead crane 861 and a conveyor 633 which are supplied with the double structure block tank 598 into the conveying process in accordance with the sequence of bending, cutting and conveying while passing through the pre-marking process. (597) of the high-strength stainless steel, the steel plate (597) of the high-strength stainless steel is bent perpendicularly to the forming bending machine by the foaming and roll foaming bending machine (625) of the distribution shaft (705) of the pipe manufacturing process is bent in the form of a round bend (c) at the bending (a) and the V-bending (b) Type bending machine and bending method The bending and cutting process of the high-strength stainless steel steel plate 597 is performed by a three-bending roller bending machine of a roller bending process machine and a bending type machine, while simultaneously performing the bending and cutting process with the overhead crane 861 and the conveyor (633) The carrier is provided with a welding position shift control to the banding joint portion of the steel plate (597) of the high-strength stainless steel, while the welding machine, the cutting tool, the drill lathe and the cutter are provided at the banding joint portion The dual structure block tank 598 is provided with a large flange 614 which provides a position to the connection of the large flange 614 which provides a position for the fore and aft connection, (625) is provided as a connection structure of the distribution shaft (705) of the pipe manufacturing process of the manufacturing and processing shelf process and is connected to the inner block tank (596) and the inner block tank The inner block tank 596 is moved to the overhead crane 861 and the conveyor 633 to the inside of the outer block tank 599 at the same time that the outer block tank 599, The double structure block tank 598 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process of the nuclear power generation facility 811 is installed inside the reactor facility body of the nuclear power plant having the double structure cylindrical connection structure, To operate the nuclear power plant;

5A, the double structure block tank 598 constituting the nuclear power plant includes a plurality of outer block tanks 599 outside the plurality of inner block tanks 596, The first auxiliary steel 600 for the block tank and the second auxiliary steel 601 for the block tank and the vertical partition 605, the horizontal partition 609 and the steel beams 149, The second auxiliary steel plate 601 for the tank, the vertical partition 605, the horizontal partition 609, the steel beam 149, the snap hole 602 and the partition wall manhole 610 are cut and processed by a computer laser cutter And a welding process welder is provided to provide a double structure block tank dust collector 794 into the reactor facility body 1 of the fifth protective wall nuclear power plant constructed along the outer wall surface of the fourth protective wall containment vessel 808 The dual structure of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process including the nuclear power generation facility unit 811 The vertical partition wall 605 and the horizontal partition wall 609 constituted by the partition wall manhole 610 are provided with the double structure block tank 598 constituting the nuclear power plant operation, The hydraulic cylinder door 624 and the emergency stairs and the stairs 631 of the traffic apparatus are composed of a welding process and are equipped with a traffic device of a reactor block explosion preventive double structure block tank collector 794 and a double structure block tank dust collector 794 A double structure block tank 703 of a distribution shaft 705 of a nuclear waste processing pipe manufacturing process composed of a nuclear plant construction unit 811 inside a nuclear reactor plant main body 1 of a nuclear power plant, A plurality of stopper plates 625 constituting the operation of the nuclear power plant are formed by a bending type bending type bending machine, a press braking type bending machine and a bending type bending type bending machine The bending steel plate 625 is formed by a bending method using a machine and three bending type rolling bending machines of the high-strength stainless steel steel plate 597 while the bending steel plate 625 is equipped with a double structure block tank 598 and a plurality of outer block tanks 599. A plurality of inner block tanks 596 and a plurality of outer block tanks 599 are individually welded to the upper and lower ends of the block tanks and the large flange A double structure block tank 598 consisting of a bolting connection device egg type coupling structure and a welding process assembly of the plugging plate 625 can be manufactured by assembling a plug- Explosion-proof double structure block tank dust collector 794 of a plurality of nuclear reactor equipments constituting the reactor main body 1 of the nuclear power plant, The dual structure block tank precipitator 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process is divided into a nuclear waste disposal apparatus and a nuclear fuel waste explosion control apparatus provided with a welding process assembly and a bolting coupling assembly, The nuclear waste is stored in one place in a plurality of inner block tanks and a plurality of outer block tanks at the lower end of the empty space of the outer block tanks, The road surface lower surface (GLD) reactor installation of the block tank is composed of an inner block tank 596 fixed with a reinforcing concrete mat 225 of thickness m and a steel beam 149 and having a plurality of double structure block tanks 598, The nuclear fuel is injected into the third wall of the reactor composed of the inside of the reactor, and is provided as a distributing and inputting apparatus for nuclear waste disposal and a distributing and inputting apparatus for nuclear fuel explosion control, And the nuclear power generation facility unit 811 of the reactor facility main body 1 of the nuclear power plant, the dual structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process is used to operate the nuclear power plant ;

5A, a large amount of radiation is generated inside the nuclear reactor facility in the reactor installation constituting the nuclear power plant, and the reactor installation securely holds the first wall pellet 681 and the second wall fuel rod 689, Of the reactor building (688) consisting of a cladding tube (682) for protecting the nuclear reactor pressure vessel (810) and a fifth wall reinforcing concrete mat (225) for the fourth wall containment vessel (808) 688 are replaced by five-layered protective walls, and a nuclear waste disposal and dispensing apparatus having nuclear waste disposal dispensing apparatus and nuclear fuel explosion control dispensing apparatuses, The nuclear power generation facility unit 811 in the nuclear power plant 811 of the nuclear power plant 811, and the dual structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process;

As shown in FIG. 5A, the double structure barge hull 591 at the lower end of the holding tank of each control shaft is provided with a dual structure for controlling the nuclear radiation leak into the SDM of the hull deck, A block tank dust collector 794 is installed in the inner block tank 596. At the center of the plurality of inner block tanks 596, there are provided respective nuclear reactor facilities for the nuclear waste disposal shielding device operated at the nuclear power plant, A guide rail 618 is installed to the left and right sides of the deck deck and a crane 861 of 5000 ton capacity is installed on the guide rails 618) with a dual structure block tank scrubber (794) constructed by substituting a five-layered protective wall inside the barge hull with nuclear reactor waste disposal The nuclear waste disposal reactor facility is provided with a double-structure, three-dimensional (three-dimensional), three-dimensional (three-dimensional) And a construction transportation transport part for adjusting the position of each of the control shafts provided as a connection structure at one end of each of the control shafts, and is configured as a nuclear power generation facility 811 inside the reactor main body 1 of the nuclear power plant The reactor structure constituting the operation of the nuclear reactor is provided with a double structure block tank collector 794 of a distribution shaft 705 of the nuclear waste processing tube manufacturing process, (1) of the nuclear power plant of the nuclear power plant, exhaust gas emission equivalent to the dust collector of the exhaust gas facility capable of withstanding the natural disaster of the sea The nuclear waste and nuclear radiation pollutants in the nuclear reactor facility consisting of the inlet and the inlet are transferred to the double-structure block tank collector (794) and the double-pipe block piping line (74) The temperature of the safety valve of the safety valve when the temperature of the reactor inside the nuclear reactor is in the range of 700 to 800 degrees and when the pressure of the high pressure reaches the dangerous level, At the same time that the pressure sensor transmits an alarm message to the computer in the safety control room, the reactor facilities of the nuclear power plant are opened with a plurality of temperature pressure sensors and safety valves, and at the same time, (74a), nuclear waste is exploded and nuclear waste is stored in each block tank, and the pressure vessel (813) At the same time that the temperature-sensing sensor safety valve 472 connected to the sub-block tank is opened, the outer block piping line 74b of the nuclear reactor facility is provided with a fuel explosion-proof control article stored in the inner block tank, 99, a thermocouple thermometer sensor switch 103 having a connection structure with a pressure gauge 101 and a temperature sensing sensor bimetal 102, a level pressure switch 104 for flow rate check operation, a flow meter 105 for flow rate check, And a safety valve 472 of a pipeline line automatic pneumatic valve conveying device 916 to connect the plurality of through holes at an upper end portion of the reactor building 688 at a constant inclination angle of 45 ° with a laser cutting machine, At the same time as the hole processing is being performed, the reactor installation constitutes a double piping line 74 having a double pipe structure in a plurality of through holes, and a plurality of safety valves 472 are provided with a bolt 24 and a nut 2 5 is provided with a flange connecting connection by a gasket 32 and a double structure block tank 598 having a diameter twice the diameter of the reactor building 688 along the outer wall surface of the reactor building 688 is provided with a nuclear waste treatment The outer block tank 599 is connected to the nuclear reactor 599 through a radiation type connection structure to distribute the nuclear waste to the nuclear reactor. A distribution shaft 705 of a nuclear waste processing pipe manufacturing process consisting of a nuclear fuel explosion-preventing control article immediately before the explosion of the reactor outside and a nuclear power generation facility section 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of land and ocean, ) Dual structure block tank cleaner 794;

5A, the steam generator 810 installed outside the pressure vessel 813 of the dual structure block tank dust collector 794 and the steam drier 786 are connected to the reactor installation constituting the nuclear power plant, And the reactor building of the double structure block tank dust collector 794 corresponding to the fifth wall and the containment vessel 808 corresponding to the fourth wall of the nuclear reactor facility is provided with a plurality of inner block tanks 596 and a plurality of outer Block tank (599) Distribution fuel injecting device for control of nuclear fuel explosion control separately The fuel loom (158) and the cement mixing equipment mixer machine (649) are installed to prevent explosion of nuclear fuel into a pressure vessel (813) Control product Cooling water 287 and a mixture of loess such that soap bubbles are generated are put into the pressure vessel 813 at a time by an automatic injection device to control the equipment and clean the inside of the reactor facility after the earthquake occurs A number of firefighter nozzles 10 constitute a fuel explosion control device inside the pressure vessel 813 and inside the containment vessel 808, and a fuel explosion control system that automatically performs the cleaning process inside the nuclear reactor facility without the input of man and robot It is equipped with distribution dispenser and nuclear fuel explosion prevention control goods as distribution dispensers of nuclear waste disposal system in the inside and outside of the nuclear reactor facility and the nuclear power plant of the nuclear power plant of the land and ocean (1) 811) of the distribution shaft 705 of the nuclear waste treatment line manufacturing process;

As shown in FIG. 5A, internal cleaning of the nuclear reactor facility constituting the nuclear power plant operation is performed by cleaning the inside of the nuclear waste disposal pipe manufacturing process distribution shaft 705, the double structure block tank collector 794, The cooling water 287 constituting the circulating water pump 242 connected to the cooling water inlet 352 of the distribution inlet cooling water piping line and preventing the yellow loam mixture from solidifying is supplied to the mixer machine 649 ) Is mixed with the mixture of the loess mixture, and is put into the pressure vessel 813 at a time. After the earthquake stops, the inside of the reactor is cleaned by the circulating water pump 242 immediately, so that continuous nuclear power generation (794) for preventing the explosion of the reactor, which constitutes the safety operation of the nuclear reactor equipments, And a nuclear power plant (811) inside the nuclear reactor plant main body (1) of a nuclear power plant of land and ocean, as a distribution input device for nuclear fuel explosion control. The dual structure block The tank dust collector 794 is configured to operate the nuclear power plant;

As shown in FIG. 5A, in the nuclear power plant (811) of the nuclear reactor facility, there are installed a nuclear reactor core A nuclear power plant comprising a plurality of nuclear reactors and a combined connection structure inside a nuclear power plant including a plurality of double structure block tanks (794) for storing wastes (224) The power generation facility unit 811 includes a steam turbine 267 generating fission in a plurality of nuclear reactors to generate steam by the heat to generate power by rotating the steam turbine 267, An atomic power generator 772 for converting power and an atom (s) installed along the circumference of a rotating shaft 198 connecting the steam turbine 267 and the atomic power generator 772, A rotating rotor electromagnet coil 774 for a power generator and a non-rotating armature coil 773 for a nuclear power generator installed along the circumferential surface of the rotating electromagnet coil 774 for rotating the nuclear power generator and the steam turbine 267 And a frame 775 fixed to the rotary shaft 198 integrally with the nuclear power generator 772 and the rotary shaft 198. The nuclear power plant 811 is installed in the reactor main body 1 of the nuclear power plant The nuclear power plant is operated by the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process composed of the nuclear power generation facility unit 811;

5A, the nuclear power generation facility 811 of the reactor facility is connected to a condenser 790 in the lower part of the steam turbine 267 of the nuclear power plant 811, And a circulation water pump 242 connected to the cooling water inlet 352 of the piping line and the cooling water inlet 352 of the cooling water piping line to the piping line 169 by a waterproof path in front of the condenser 790, A dual structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility 811 inside a reactor facility main body 1 of a nuclear nuclear power plant A water supply pump 241 is provided at the rear of the condenser 790 and outside the nuclear reactor facility and a purifier is installed at the outside of the reactor in front of the water supply pump 241 809) A plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 in which the enriched uranium 812 fuel is stored and the pressure vessel 813 of the reactor facility is connected to the inside of the reactor internal piping line in front of the purifier 809, A safety device control rod 798 is installed in the inside of the reactor main body 798 to automatically insert the control rod 798 into the reactor main body 1 of the nuclear power plant in the offshore and offshore, The nuclear power generation facility unit 811 in the nuclear power plant 811 of the nuclear power plant 811, and the dual structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process;

As shown in FIG. 5A, the nuclear power generation facility 811 of the reactor facility of the nuclear power plant includes a first wall pellet 683 and a second wall pillar 689, The collision of the cladding pipe 682 with the seismic force of the seismic force sensor 682 caused by the seismic force of the seismic intensity 5 causes the plurality of temperature pressure sensing sensors to be formed inside the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 The explosive nuclear waste 224 passes through the inner block piping 74a of the block piping line 74 at each position of the upper end portion of the pressure vessel 813 while the safety valves 472 are opened and the outer block piping 74b The nuclear fuel explosion-proof control article cooling water 287 and the yellow loess mixture 927 for soap foam stored in the inner block tank 596 are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241 And the internal lower end positions of the respective portions of the double structure block tank 598 are provided with, The reactor 224 is moved and stored and the thermal pressure sensing sensor safety valve 472 connected to the inner block tank 596 of the pressure vessel 813 is opened and at the same time the reactor installation of the nuclear power plant is connected to the outer block The pipeline 74b is connected to the fuel block 813 and the fourth protective wall containment vessel 808 by a water pump 857 for supplying cooling water and yellow loess mixture 158 of fuel explosion prevention control product stored in the inner block tank 596 At the same time as the transfer is being carried out, nuclear fuel explosion prevention control articles, which are prepared by converting kinetic energy of the position energy of water into cooling water and loess mixture 927 for soap bubbles, are supplied to the inner block tank 596 and the outer block tank 599 If the inside of the reactor facility is filled with the cooling water (287) and the mixture of the loess mixture (927) for the soap bubble, the explosion of the reactor facility is terminated and at the same time, A double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility unit 811 in a nuclear reactor facility main body 1 of a nuclear power plant on land and in the ocean, The plant is configured to operate as a nuclear plant;

As shown in FIG. 5A, the nuclear power plant (811) of the reactor facility of the nuclear power plant is equipped with a remote control cutting or submarine mineral collection robot 912 at the time of dismantling the reactor facility of the nuclear power plant operating the nuclear power plant When the explosion of the pressure vessel 813 of the reactor facility is stopped, the plurality of temperature-sensing sensor safety valves 472 are closed and the plurality of the temperature-sensing sensor safety valves 472 are normally closed (Nuclear Power Plant) to install a large number of nuclear reactors in the offshore barge (591). Before and after the operation of the Nuclear Power Plant, a number of nuclear reactors were installed in the anti-sinking barges of the ocean. The dual structure block 705 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process consisting of the nuclear power generation facility 811 inside the reactor facility main body 1 of the power plant The nuclear power plant (811) facility of the reactor facility of the above-mentioned nuclear power plant is equipped with a nuclear power plant (407 meters) at the top of the sea level so as not to be restricted by the weather condition of the earthquake and tsunami, (811), and the position of the nuclear power plant can be controlled by the mooring device and the diving buoyancy adjusting device formed on the sinking type barge line, so that a plurality of nuclear reactors of the nuclear power plant which are not affected by the earthquake and tsunami can explode The nuclear power plant 811 of the reactor facility controls the leakage of nuclear radiation to prevent the explosion of the reactor facility of the nuclear fuel chamber to prevent environmental pollution due to nuclear waste The dual-structure block tank dust collector (794) is installed in the marine nuclear power plant to ensure safe and continuous operation of the nuclear power plant. (593,594,595) to ensure the safety of the nuclear power plant and to ensure the repair of the reactor facility by continuous operation, the nuclear power plant in the nuclear power plant of the land and the ocean (1) A step of constructing a double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste processing pipe manufacturing process consisting of a power generation facility unit 811 and a nuclear plant of the nuclear power plant before and after the operation of the nuclear power plant, The nuclear power plant (811) facility of the reactor facility of the nuclear power plant includes a mooring device constructed on the barge by nuclear waste disposal, a diving buoyancy control device, a nuclear waste disposal dispenser and a nuclear fuel explosion control dispensing device, To prevent the environment from being contaminated by nuclear waste, control the leakage of nuclear radiation so that the inside and outside nuclear reactor facilities do not explode. Control of diving buoyancy and mooring arrangements at the ocean power plant floating plant (593,594,595) nuclear power plant (672) into the nuclear plant main body (1) of the nuclear power plant (672) by the distribution input devices of the double structural block tank reactor (794) (1) nuclear reactor facility of nuclear power plant of land and sea by means of disaster prevention apparatus equipped with apparatus and nuclear waste disposal apparatus and nuclear reactor facilities to withstand natural disasters of the sea, The nuclear power generation facility unit 811 of the nuclear waste treatment plant is operated by the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process so that the nuclear power plant of the nuclear power plant is operated. Electric power generation equipment and nuclear waste disposal Marine tunnel transport equipment (941) Disaster prevention equipment and transportation equipment with position control and construction of nuclear power plant It is preferable to further comprise a wind power generator, a thermal power generator, and a hydraulic power generator,

Referring to FIG. 5B, in a nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention, a nuclear reactor is installed in a nuclear reactor power plant 811, (802) of a nuclear waste disposal facility (802) of a nuclear power plant having a double structure block tank dust collector constituting an embodiment of a nuclear waste disposal reactor installation combining method (802) The present invention relates to an explosion-proof nuclear reactor plant having a dual structure block tank dust collector (802) of decomposition-coupling type Side, sectional configuration road,

As shown in FIG. 5B, preferably, the dual structure block tank of the nuclear power plant 811 constituting the reactor main body 1 of the nuclear power plant of the land and sea is divided into a distribution shaft The nuclear waste disposal pipe manufacturing process 705 of the marine nuclear power plant constituting the distribution shaft 705 is connected to the nuclear waste disposal pipe manufacturing process 705 into the reactor facility body 1 of the nuclear power plant, The small diameter electric resistance welded pipe 706 manufactured by the nuclear power generation facility unit 811 can be used as the raw material 707 and the uncoil 708 And the shaping 712 process to the ring leveling 709 and the side trimming 710 to the cutting and roughing connection 711 while the equipment of the nuclear power plant 672 performs the welding and the inner and outer bead removal 713 Completion of Ultrasonic and Vortex Test (714) The welding heat treatment 715 of the nuclear power plant 672 is equipped with the centrifugal molding 718 by means of the air cooling 716 and the water cooling 717 while the cutting 719 of the nuclear power plant 672 is subjected to the flatness test 720 and at the same time the structural tube 721 calibrating 722 facility of the nuclear power plant 672 is used to control the process of the facility from the intermediate load 723 and the induction heating furnace 724 to the SRM 725 standard 732 to provide a visual inspection 731 with a weight and length measuring instrument 730 and an ultrasound and vortex test 729 with a hydrostatic test 728, a hot cut 726 and a chamfer 727, And a cooling stand 738 having a galvanized steel pipe 735 and a galvanized steel pipe 736 and a boiler tube 737 for the general piping 734, (1) A double structure block tank dust collector 794 and a double structure block tank (not shown) are formed to produce a small diameter electrical resistance welded pipe 706 manufactured in the nuclear power generation facility unit 811. (593,594,595) Nuclear power plant (672) of the marine power plant of the connection shaft provided for the connection structure of the bridge (937) disassembly-connectable connection structure is connected to the nuclear power plant (811) of the nuclear power plant main body Dual Structure Block Tank Dust Collector Nuclear waste treatment plant Consists of a distribution shaft (705) of the manufacturing process to form a nuclear power plant and nuclear reactor facility;

As shown in FIG. 5B, the center-cage-shaped electric resistance welded pipe 739 to the floating power plant 593, 594, 595 nuclear power plant 672 of the marine power plant constituting the distribution shaft 705 is made of a coil mage- The nuclear power plant 672 facility simultaneously controls the ultrasound 744 and the test 744 with the cage forming unit 742 connected to the side trimming unit 744 to control the ultimate formation 745 (739) Production distribution equipment for nuclear power plant Reactor facility of nuclear power plant (1) Double structure block of nuclear power generation facility (811) of nuclear power plant Tank dust collector Nuclear waste treatment plant Dispensing axis of manufacturing process And the large diameter steel pipe 747 of the steel pipe 746 for the oil industry oil industry to the nuclear power plant 672 facility of the marine power plant of the marine power plant constituting the distribution shaft 705 is connected to the edge milling machine 748 ) And a three-roll banding machine (749) and a post-banding machine (750) The production is made at the nuclear power generation facility 811 of the reactor installation main body 1 of the nuclear power plant which controls the production with the input devices, The outer surface weld 754 of the nuclear power plant 672 facility is also welded to the outer surface weld 754 of the nuclear power plant 672 through the tube sizing 755, the tube cross section 756, the X-ray test 757, the cold expanse 758, The spiral welded steel pipe 760 of the nuclear power plant 672 facility is provided with the structure pipe of the uncoiling 761 while the shipment 759 process is provided to the nuclear power plant 672 by the distribution and dispensing apparatuses. And the non-coated piping 763 of the steel pipe pile 762 is cleaned by the primary coating 767 of the outer brass cleaning 764 and the inner brass cleaning 765 and the inner surface 766, ) And at the same time, the coated steel pipe (769) of the nuclear power plant (672) is provided with ultrasonic waves and X-ray inspection (770) (747) of the oil pipeline for the oil industry (746) was constructed to be the nuclear power plant (672) facility by distributing and supplying equipment, and at the same time, the reactor facility of the nuclear power plant was destroyed by the explosion (593,594,595) Nuclear power plant (672) equipped with a dual structure block tank dust collector (794) to be installed in the reactor main body (1) of the nuclear power plant with the distribution input devices Equipment and diving buoyancy control and distribution of nuclear waste treatment and reactor installation of nuclear reactor facilities Safety operation Before the start of operation of nuclear shipbuilding manufacturing process (705) of nuclear reactor waste treatment plant at the Hue City Nuclear Power Plant (811) It is preferable that the plant is composed of a nuclear plant and a reactor facility,

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) In addition, it is also possible to insert the nuclear power plant equipment and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the nuclear reactor facility. At the same time, according to the manufacturing process according to the safe design of the nuclear reactor facility body of the nuclear power plant, (598) of the metal structure for the steel structure for manufacturing and installing the reactor main body is provided with a steel plate (597) made of high-strength stainless steel so as to provide a marking process, and at the same time, The overhead crane 861 and the conveyor 862, which are fed into the double structure block tank 598 in accordance with the cutting and conveying process sequence, (597) of a high-strength stainless steel is bent at right angles to a foaming bending machine using a foaming machine and a roll foaming machine according to the thickness of a steel sheet of a high-strength stainless steel steel plate (633) The bending process of the bending type (b) and the round bending type (c) is carried out, while the bending process of the press braking type, the bending type roller bending process machine and the bending roll bending process machine A bending process of a high-strength stainless steel steel plate 597 and bending of the steel plate 597 are performed while the upper end of the high-strength stainless steel steel plate 597 is bent by the overhead crane and the conveyor 633, At the same time as installing the ceiling crane and conveyor (633), the equipment of the nuclear power plant is equipped with welding machine, cutting tool, drill lathe and cutter A large flange (598) having a large flange (614) for providing a position for a stern connection with a bow of the double structure block tank (598) while performing a welding process to the banding joint portion of the high-strength stainless steel plate (597) 614 are provided as a nuclear plant main body connection structure of a nuclear power plant of a manufacturing and processing shelf process with a certain size of stopper steel plates 625 and are arranged in a position outside the inner block tank 596 and the inner block tank 596 The inner block tank 596 is moved to the inner position of the outer block tank 599 and the position of the inner block tank 596 is adjusted to the overhead crane 861 and the conveyor 633 (593,594,595) equipped with a dual structure cylindrical connection structure inside the nuclear reactor facility of a nuclear power plant after completing the welding process, the dual structure block Nuclear waste treatment double structure block tank bridge 929 and dual structure block tank pipe bridge 937 and nuclear waste treatment dual structure block tank marine tunnel transport device 941) a plurality of distribution shafts and a double structure block tank 598 for distributing to the disassembly-connectable connection structure of the connection shaft to provide the discharge to the facility of the tube manufacturing process (705) of the reactor main body 1 of the nuclear power plant, To be operated.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) (588) of the double structure block tank (598) are provided with a plurality of holes (584) extending from both sides of the distribution shaft constituting the facility and the reactor facility to the nuclear power plant facility and the nuclear reactor facility, The first auxiliary steel pipe 600 for the block tank and the second auxiliary steel plate 601 for the block tank and the horizontal partition wall 609 and the steel beam 149 The second auxiliary steel plate 601 for the block tank, the second auxiliary steel plate 601 for the block tank, the vertical partition wall 605, the horizontal partition wall 609, the steel beam 149, the snap hole 602, (610) Each machine is equipped with a laser cutting machine, And the vertical partition wall 605 and the horizontal partition wall 609 in which the partition wall manhole 610 is formed are provided with a traffic device hydraulic cylinder door 624 and an emergency structure block tank 598. [ The stair step (631) equipment is provided with traffic devices provided by a welding process, and when the inside and outside are refurbished with a double structure block tank facility, the stair step (631) ) Is a press braking type bending machine, a bending type roller bending machine and three bending roller bending machine of the bending bending machine of the section steel bending and bending process with the bending and bending machine of high tension stainless steel (597) While at the same time the nuclear plant installation is provided with a double structure block tank 598, which is provided with a plug-and-loop fastening assembly of a dual structure block tank 598 having a cylinder- A plurality of inner block tanks 596 and a plurality of outer block tanks 599 are connected to the upper and lower ends of the double structure block tanks by a welding process and a large flange bolting connection device coupling structure is provided in an egg- (593,594,595) dual structure block (1) into a nuclear power plant and a nuclear reactor main body (1) at the same time as a plug- The double structure block tank bridge pier 928 of the tank 598 and the nuclear waste treatment double structure block tank pipe bridge 929 and the dual structure block tank pipe bridge 937 and the nuclear waste disposal dual structure block tank marine tunnel transportation device 941) Multiple distribution shafts that distribute to the connection structure capable of disassembling and coupling the connection shaft and discharge, It is configured to be made and equipment nuclear reactor plant operations.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) A double structure block tank 598 is installed in the reactor main body 1 of the nuclear power plant, and at the same time, the double structure block tank 598 is inserted into the nuclear reactor main body 1 of the nuclear power plant, (593,594,595), which is composed of mooring device, diving buoyancy control device and marine tunnel traffic pipe manufacturing process (705), which are connected to the marine vessel manufacturing plant in the marine vessel manufacturing plant. And barge ship hull can be prevented from sinking and buoyancy control device can be assembled and installed, while at the same time, The nuclear power plant unit 811 configured to control the nuclear power plant facility and the reactor facility within the nuclear power plant main body 1 of the nuclear power plant with the power of 1000000k w / h, And the supply power is regulated by the power transmission control unit 811d for generating and delivering the generated power from the power production and manufacture unit 811b of the marine hydroelectric power plant, and at the same time, the nuclear power plant facility and the reactor facility main body 1, (593,594,595) Double structure block tank pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank pipe bridge (929) and double structure block tank pipe bridge (937) And nuclear waste treatment dual structure block tank marine tunnel transport device (941) multiple distribution axes and distributions to distribute to disassemblyable connection structure of connection shaft to provide discharge It is configured to be made separately admission teeth of the double structure block tank nuclear power plant facilities and nuclear reactor plant operations.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant equipment is inserted into the nuclear reactor facility main body 1 of the nuclear power plant through the power transmission unit 811d as well as the nuclear power plant facility and the nuclear reactor facility by inserting both sides of the distribution shaft constituting the facility and the reactor facility, Voltage substation 690 provided in the power plant and the voltage 684 to the transformer 96 via the primary substation 691 while being supplied with the power 685 generated by the marine hydroelectric power plant constituting the connection, A connection shaft for providing power 685 to the dual structure block tank bridge 937 including the large-scale plant 698 and the flood control console 705, (697) manufacturing of high-strength steel plates and the supply of electric power (685) to steel beam beam (149) and equilateral-beam steelmaking (839) The tank pipe bridge pier (928) is equipped with a diameter of 5M and is provided in the form of a reducer (35) per 1 km of water depth. At the same time, the diameter of the pipe pier is 5M and the diameter is increased by 1M A double pipe structure tank pier in the same form as the band guide 621 which provides connection of the flange 614 of the large flange 614 provided at the top of the deck deck to the semi-submerged operation line 637 of the nuclear power plant, (617) for construction is equipped with disassembly and coupling, and at the same time, a nuclear power plant and a nuclear power plant are installed in the main body (1) of a double structural block tank (598) (928) and nuclear waste disposal binaries A number of distributions to distribute and discharge the detachable connection structures of the block tank pipe bridge (929), the double structure block tank pipe bridge (937) and the nuclear waste disposal double structure block tank marine tunnel traffic device (941) It is divided into shafts and distribution dispensers, which are constructed to operate the dual structure block tank nuclear plant and nuclear reactor plant.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The inserts are inserted into the nuclear plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility, and at the same time, the junction of the bridge type saddle formwork 617 to the nuclear power plant facility is provided with various types of jigs A disaster shelter is provided while providing an attachment to the jig 22 by welding while providing a counter mooring device for replacing the breakwater 400 in the territory of the territorial dispute, A plurality of jig processing holes 615 and a plurality of jig breakers 185 are connected and disassembled simultaneously by connecting the coupling processing hole 615 and the plurality of jig breakers 185 to the link stand 249, And an anchor replacement level crane 846 and a bridge pillar level foundation base 851 are installed at the side and lower sides of the saddle form frame 617 for the anchor replacement crankshaft of the nuclear plant 1) of the worm crank 846 which replaces the anchor bolt 133 is located at the center of the key bed 616 that provides the connecting structure at the lower end of the holding tank 590 of the barge hull, While an operation of the hydraulic cylinder 623 provided with the anchor 848 is provided and at the same time an anchorage is provided to the nuclear power plant facility by the anchor replacement crank 846 at the seabed at the bottom of the nuclear power plant, The directional control of the webbing retractor 185 fixed to the borehole of the undersurface of the wreck crank 846 attached to the lower part of the pier of the pier is fixed by the actuator for operating the hydraulic cylinder 623 At the same time, (593,594,595) Dual structure block tank (598) Double structure block tank pipe pier (928) and nuclear waste treatment Double structure block tank pipe bridge (929) and dual structure block It is divided into a number of distribution axes that divide the tank bridge bridge (937) and a disassembly-connectable structure of the connection shaft of the nuclear waste disposal double structure block tank (941) Block Tank Nuclear Power Plant Facilities and Nuclear Reactor Facilities.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) (2) The nuclear power plants are installed in the reactor main body (1) of the nuclear power plant, and at the same time, they are inserted into the nuclear power plant facilities and the nuclear reactor facilities through both sides of the distribution shaft constituting the facility and the reactor facilities. A transportation transport section 811c of the floating construction hood position moving construction machine constituting the control of the nuclear power plant facility inside the reactor facility main body 1 of the nuclear power plant providing the movement control and disassembling assembly of the hulls 593,594,595, The double structure block tank 598 is moved to a marine assembly site by a tug line 636 constituted by a distributing / And at the same time, an assembling connection is provided by underwater operation to a nuclear power plant facility, a semi-submerged operation line 637, a band guide 621, and at the same time, a double structure block tank 598 is installed at a pipe bridge, The tugboat 636, together with the movement control and disassembly assembly of the marine tunnel transportation device and the marine hydroelectric power plant floodgate, sets the buoyant flag rubber balloon 628 and the rope 629 for confirming the diving position to the rope knot hooks The double ballast block tank 598 is connected to the outside of the double structure block tank 598 while the ballast rubber balloon 628 is formed as a medallion, (1) while maintaining the air inlet condition, the electronic control valve operation status, and the air hose (109) and pump hose status check, while providing diving and floating function checks. (593,594,595) Dual structure block tank tank (598) Dual structure block tank pipe bridge (928) and nuclear waste treatment double structure block tank bridge (929), double structure block tank bridge bridge (937) and nuclear waste (941) Double-structure block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connection shaft and provide the discharge. Nuclear power plant equipment and nuclear reactor plant equipment So as to be operated.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The semi-submerged operation line 637 to the nuclear power plant equipment is provided to the double-structured block tank 598 at both sides of the distribution shaft constituting the facility and the reactor facility, While the safety work is provided by the band guide 621 and the hydraulic cylinder key 623 while the barge hull 591 at the upper end of the holding tank is exposed at the upper end of the sea level SLL, The buoyancy regulating butterfly valve 622, the hydraulic cylinder door 624 and the hydraulic cylinder hatch cover 153 are separately connected to the tugboat 636, The cargo ship is provided with an anchorage at the ship sinking prevention stay line 634 while the water is being discharged to the outside of the tank and at the same time the block steel tower 116 composed of the diaphragm-type steel pipe 149 and the pipe, the emergency stairs 631 and the elevator 632 The ceiling crane crane 861 is mounted on the steel tower 116, the emergency stairs 631, and the elevator 632 of the nuclear power plant while being laid on the upper end of the barge hull deck deck at the upper end of the holding tank At the same time, the bottom tank barge hull 592 of the holding tank 592 is secured to the upper end of the upper end of the upper end of the barge hull deck deck of the holding tank at the sea level upper end portion SLU, , The emergency stairs 631, the bolts for connecting the elevator and the block unit lug connection shaft, and the block unit block pylon 116 for the lug connection shaft coupling and disassembling nut are provided inside the block steel tower 116, (593,594,595) Double structural block tank block (598) Double structure block tank pipe bridge (928) and nuclear waste treatment Double structure block tank bridge (929) Nuclear power plant facilities and reactor facilities ) And a dual structure block tank bridge 937 and a nuclear waste treatment dual structure block tank marine tunnel traffic device 941. A plurality of distribution shafts and distributing devices , Which is composed of a double structure block tank nuclear power plant facility and nuclear reactor nuclear power plant operation.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) At the same time, the nuclear power plant equipment is provided with an emergency staircase 631, an elevator 632, and an aerial tower 644 of a mooring tower 644, which are installed in the nuclear power plant facility and the nuclear reactor facility through both sides of the distribution shaft constituting the facility and the reactor facility. A lightning rod 500 is formed on the top of the block pylon 116, which is a metal rod with a sharp tip for preventing damage to the lightning strike when a thunderstorm occurs, and at the same time, a position is provided at the upper end of the lightning rod 500 And the weather zone information transmitted from the satellite 611 of the communication system is transmitted to the weather station At the same time, while providing diary information to the weather observation station, the control department of flood control facilities can prevent the natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods and droughts, (593,594,595) Dual structure block tank (598) Double structure block tank bridge pier (928) Nuclear waste treatment Double structure block tank bridge (929) Double structure block tank bridge (937 ) And Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) Double-structured block tank divided into a plurality of distribution shafts and distributing input devices that distribute to the disassembly-connectable connection structure of the connecting shaft, And nuclear reactor nuclear power plants.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) (2) The nuclear power plants are equipped with nuclear power plant facilities and nuclear reactor facilities through both sides of the distribution shaft constituting the facility and reactor facilities. At the same time, An unattended camera 184 for unmanned on-boarding and an adevalon 77 of the meteorological observation equipment are installed in a basket 42 provided in the lower part of the meteorological observation apparatus in which the flood control process for the nuclear power plant facility is constituted, The burner boom 920 is provided to adjust the position of the burner boom and the fuel gas supply hose 694 to the nuclear power plant facility The hose 694 of the gas transportation means which is lighter than air by the shackle 23 and the lug 21 is connected to the inside of the disaster prevention hose 9 The multi-stage pump 8 and the air generated by the air compressor 80 at the rear of the water shutoff valve 40 and the air compressor 80 are connected to the receiver tank 145 and the air storage tank, A water turbine boom 920, a high-pressure storage tank receiver tank 145, and a large-capacity hydroelectric power generator 944, which are located inside the large-capacity hydroelectric power generator 944, In the event of an emergency in the event of the generation of harmful gas during storage of the non-office kit 918, natural gas 922 and crude oil 841 from the storage tank and the storage tank, The cement 931 and the clay loops 158 and the cement 931 to recover the drilling space with the loess soil 158 and the cement 931 after the crude oil 841 is collected and produced. And a blender 73 as a device for mixing the loess soil 158 and the blast furnace 158. At the same time, the helicopter station 619, the crew work room, the control room, and the crew cabin cabin room machine room are provided in the nuclear power plant facility. At the same time, the satellite launch pad 643 and the space rocket launch pad 646, which provide the launch of the satellite 611 and the space rocket 612, are positioned on the left side of the safety control room of the nuclear power plant, The position of the mooring unit bollard 638 is provided with an anchoring vessel and at the same time a space between the artificial satellite 611 and the space rocket 612 is provided inside the artificial launching platform 643 and the space rocket launching platform 646, (593,594,595) Dual structure block tank (598) Double structure block tank pipe bridge (928) and nuclear waste treatment dual structure block tank bridge bridge (929) Double structure block tank pipe bridge (937) and nuclear waste treatment double structure block tank marine tunnel traffic equipment (941) are divided into multiple distribution axes and distribution input devices that distribute to disassembly connection structure of connection axis and prepare discharge. And to construct the nuclear power plant and nuclear power plant of the dual structure block tank.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) In addition, the air compressor (80) facility is provided with a function to prevent the harmful red tide from breeding, and at the same time, A drilling machine 908 for supplying crude oil to the machine room 908 while providing installation on the seabed with the hose 109 and the nozzle 923 and a pipe for the toothed gear The rack 854 is provided with a crane (not shown) of the wire rope 19 of the overhead crane 861, which provides a connection rotation operation and at the same time provides positional shift control of the drilling machine 908 A pipe rack 854 of 15 meters in length providing a position at the upper end of the drilling machine 908 for providing the shoveling of the boom 65 while simultaneously providing the hooking of the tug- And at the same time, in the center of the barge hull at the bottom of the holding tank (590) at the bottom of the seabed at a depth of 10 km, the core drill (917) (593,594,595) double structure block tank (598) double structure block tank bridge pier (928) and nuclear waste treatment double structure block tank bridge (929) of nuclear power plant facility and nuclear reactor facility main body ) And double structure block tank bridge (937) and the nuclear waste treatment double structure block tank marine tunnel traffic device (941) connection shaft. The axis of the distribution and allocation input device, separated by a double structure of a block tank nuclear power plant facilities and nuclear reactor plant operations consist be achieved.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant equipment and the nuclear reactor facilities are inserted through both sides of the distribution shaft constituting the facility and the reactor facilities, and at the same time, the nuclear power plant facilities are provided with the nuclear power plant facilities The hydraulic cylinder device 623 and the hydraulic rotary cylinder 620, which are equipped with a nuclear power plant facility control process, which is constituted by a transportation and dispensing device for hull position control by the transportation conveying part 811c of the floatation moving facility construction machine, It is equipped with installed band guide (621) and hand tool hammer and wrench, And air compressors (80), while at the same time, the air pressure regulating device and the water pressure regulating device in the block tank in the nuclear power plant equipments are installed in the portable tank It is possible to provide a coupling with the lug 607 machining hole 615 and the pin linking shaft 606 for the portable lug coupling and at the same time to provide a coupling with the lug coupling shaft bolt 603 screw thread and lug coupling split nut 604 At the same time, a portable lug pin 608 is provided in the bolt thread end machining hole, and at the same time, the pin 608 is broken by a pin to the nuclear power plant equipment and the nut is fixedly coupled to the double structure block tank line The submarine wiring is provided and at the same time, the power is supplied to the land, and the pump and the air compressor (80) are operated before the occurrence of the harmful tide and before the harmful tide and the typhoon, Shaped flexible high pressure hose 190. At the same time, the disaster prevention water of the water pressure inside the pump piping line hose is provided with discharging water discharge jet number and radial type curtain water film through the nozzle gap, (925) and a downward current (926), it is necessary to prepare the power of the typhoon and prevent the global warming, and to transform the people of the nuclear bomb manufacturing party, which is equivalent to the harmful red tide, To the unmanned camera 184 to the wireless device radar of the computer system 611 of the computer system combined with the information exchange communication means of the Internet network 50 which peacefully resolves the international social dispute, (593,594,595) of the hydro-electric power station in the main body of the nuclear power plant (1) The double structure block tank bridge pier 928 of the block tank 598 and the nuclear waste treatment dual structure block tank pipe bridge 929 and the double structure block tank pipe bridge 937 and the nuclear waste disposal dual structure block tank marine tunnel transportation device (941) is divided into a plurality of distribution shafts that distribute to the connection structure capable of disassembling and disassembling the connection shaft, and a distribution input device, and are configured to operate the dual structure block tank nuclear power plant and the nuclear reactor nuclear power plant.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant equipment and the nuclear reactor facilities are inserted through both sides of the distribution shaft constituting the facility and the reactor facilities, and at the same time, the nuclear power plant facilities are provided with the nuclear power plant facilities (811c) of the construction equipment of the floating structure of the hull, the hull, the hull, the hull, the hull, and the hull, , While at the same time collecting submarine mineral resources and dissolving iron ore immediately Nuclear waste treatment dual structure block tank to control supply of iron ore, crude oil (841) and pollution-free natural gas (922) to the countries of the world while processing manganese nodule in furnace (909) The facility is equipped with a maritime trade volume control system and a double structure block tank pipe bridge 928 and a nuclear structure 598,594,595 double structure block tank 598 of a hydroelectric plant Waste treatment Double structure block Tank pipe bridge (929), double structure block tank pipe bridge (937) and nuclear waste treatment double structure block tank marine tunnel traffic device (941) , Which are divided into a number of distribution shafts and distribution input devices, and are configured to operate the nuclear power plant and the nuclear power plant of the double structure block tank.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) In addition to providing installation in nuclear power plants facilities and reactor facilities through both sides of the distribution shaft constituting the facilities and reactor facilities, it is also necessary to provide facilities for cooperation with the international community for economic development, and at the same time, , While at the same time keeping all military materials and bomb manufacturing experiments confined to the designated areas of the sea, and establishing peace preservation as a management form of the international peacekeeping force, the unmanned camera (184) After confirming winning for countries and individuals with a large number of acquisition points, While at the same time providing a maritime anti-piracy annihilation device that emits and exits in a specific area of the sea bass while changing one of the engine propeller 146 and the skewer 147, In addition to the construction of a pirate ship with docking vessels, diving into the water, or at the same time maintaining the close relationship between the fire and the disaster prevention materials, the communication equipment of the Internet control system before and after the fire, Pump electronic control unit, high performance submersible pump (36), air compressor (80), air storage tank and wire rope, multiple frames and mobile transport equipment Helicopter, connection structure including adverbalon and airship, Nuclear reactor plant (1) Inland hydroelectric plant Floating plant (593,594,595) Double structure block tank (598) double structure block tank bridge pier (928), nuclear waste treatment dual structure block tank pipe bridge (929), dual structure block tank pipe bridge (937) and nuclear waste treatment dual structure block tank marine tunnel traffic device ) It is divided into a number of distribution axes which distribute to the connection structure capable of disassembly coupling of the connection shaft and the distribution shaft and the distribution input device, and the dual structure block tank nuclear power plant facility and the nuclear power plant nuclear power plant are operated.

As shown in FIG. 5B, a reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste (1) an internal nuclear power generation facility (811) a nuclear power generation nuclear waste treatment section (811a) The nuclear power plant facilities are equipped with the flood control process for the nuclear power plant facilities, and the fire-fighting and disaster control equipment is installed in the nuclear power plant facilities. Shaped nozzle 15 and a straight gap 15 are provided in the piping nozzle while a fire is generated when a fire occurs and a plurality of radiation curtain water films 39 and A plurality of linear straight-line curtain membrane members 39, and at the same time, a gas of death occurring in the event of a fire (163) , Which is composed of vertical and horizontal curtain walls that make up the world's uninhabited earth. Pump and valve connection structure of the electronic control unit is composed of fire, drought, typhoon, typhoon, flood, (685) as an electronic control pump fire fighting and disinfection device consisting of fire-fighting and disaster prevention control device in the global village along with the prevention of disasters such as droughts and landslides. At the same time, (593,594,595) Double structure block tank bridge pier (928) of dual structure block tank (598) and nuclear waste treatment dual structure block tank bridge bridge (929) and dual structure block tank bridge bridge (937) and nuclear (941) Multiple distribution shafts and distributing inputs to distribute to a disassemblyable connection structure of the connection shaft to provide the discharge Are separated by teeth are configured to be made double the building block tank nuclear power plant facilities and nuclear reactor plant operations.

Referring to FIG. 5C, the reactor structure of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor main body 1, a nuclear waste reactor treatment reactor 811, 802) Nuclear waste disposal reactor facility for providing input A dual structure block tank reactor constituting an embodiment of a combined system A boiling water reactor facility (802) of a nuclear power plant with a dust collector (802) The present invention relates to a reactor structure of a nuclear power plant having a dual structure block tank dust collector. The reactor structure of the present invention is a disassembly type system. Side configuration of coupling method Road,

As shown in FIG. 5C, preferably, the double structure block tank dust collector of the nuclear power generation facility 811 constituting the nuclear reactor plant main body 1 of the nuclear power plant and the nuclear waste disposal nuclear power plant 672 of the nuclear power plant, The mooring device, the diving buoyancy regulating device and the nuclear power plant 672 distribution dispensing device formed in the distribution shaft 705 of the process tube manufacturing process are connected to the marine power plant flood control module 593, 594, 595 ) Nuclear Power Plant (672) The distribution input unit controls the production to the inside of the nuclear reactor facility main body (1) of the nuclear power plant as a disassemblable coupling structure at the marine vessel manufacturing factory of the connection shaft of the nuclear waste treatment pipe manufacturing process (705) An inner block tank 596 for providing a position to the center of the double structure block tank 598 of the distribution input unit double structure block tank 598 constituted in the nuclear power generation facility unit 811 and an inner block tank The double block structure tank 598 is provided with a high-strength steel plate 597, which is connected to the cutting process and the welding process connection The double structure block tank pipe bridge bridge marine tunnel traffic device 941 is connected to the nuclear waste disposal and dispensing device of the nuclear power plant 672 at one end of the double structure block tank 598 produced by the distributing device of the structure, The first auxiliary steel section 600 and the second auxiliary steel plate 601 are manufactured as a connection and disconnection device for the cutting process and the welding process, A large flange 614 for providing an overlapping structure with the shaft connection structure is formed by arranging a large flange 614 for providing a position of a nuclear reactor facility connection portion of a nuclear power plant with a plug steel plate 625 of a certain size to a nuclear power plant The double structure block tank 598 provided with the design of the nuclear power plant distribution dispenser may be made of steel plate 597 made of high strength stainless steel, The double structure block tank 598 is provided with a ceiling crane 861 and a conveyor 633 carrier which are supplied to the conveying process in the order of bending and cutting and conveying and at the same time the nuclear waste disposal distribution input The apparatus is provided with a forming and rolling mortar bending machine in accordance with the thickness of the iron plate (597) of a high-strength stainless steel for the nuclear power plant equipment and the double structure block tank (598) (598) The high-strength stainless steel plate of the equipment (597) The bending machine of the stainless steel bending machine is to perform the bending process in the form of a right angle bending (a), a V-bending b) and a round bending While at the same time the bending machine of the double structure block tank 598 is provided with a press bending type press braking type bending machine and a bending type roller bending machine and three bending roller bending machine While simultaneously adjusting the position of the banding welded joint of the high-strength stainless steel steel plate 597 with the carrier of the overhead crane 861 and the conveyor 633, the welded joint region is welded to the welder, the cutting tool, The double structure block tank 598 is provided with a connecting portion of a large flange 614 for providing a stern connection position with the double structure block tank 598, A large flange 614 for providing a position to a position is formed as a connecting structure of a manufacturing and shelving process to a marine power plant Form dock (593 594 595) configured to be made reactor equipment body (1) of a nuclear power plant 672 and a nuclear power plant, and;

As shown in FIG. 5C, in the nuclear reactor facility constituting the nuclear power plant, a dual structure barge hull 591 at the lower end of the holding tank of each control shaft is provided with a double structure for controlling nuclear radiation leak into the SDM of the hull deck A block tank dust collector 794 is installed in the inner block tank 596. At the center of the plurality of inner block tanks 596, there are provided respective nuclear reactor facilities for the nuclear waste disposal shielding apparatus operated at the nuclear power plant, A guide rail 618 is installed to the left and right sides of the deck deck and a crane 861 of 5000 ton capacity is installed on the guide rails 618) with a dual structure block tank scrubber (794) constructed by substituting a five-layered protective wall inside the barge hull with nuclear reactor waste disposal The nuclear waste disposal reactor facility is provided with a double-structure, three-dimensional (three-dimensional), three-dimensional (three-dimensional) And a construction transportation transport part for adjusting the position of each of the control shafts provided as a connection structure at one end of each of the control shafts, and is configured as a nuclear power generation facility 811 inside the reactor main body 1 of the nuclear power plant The dual structure block tank precipitator 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process being constructed to operate the nuclear power plant;

As shown in FIG. 5C, the nuclear reactor facility constituting the above-described nuclear power plant includes an exhaust gas facility (not shown) which can withstand the natural disaster of the ocean into the reactor main body 1 of the nuclear power plant The nuclear waste and nuclear radiation pollutants of the reactor facility having the exhaust gas outlet and inlet equivalent to the dust collectors of the nuclear waste disposal site are disposed in the dual structure block tank 794, And the nuclear radioactivity contaminants are detected by the temperature and pressure sensors of the plurality of the temperature-sensing sensor safety valves, and the temperature of the inside of the reactor is 700 to 800 degrees and the pressure of the high- When this danger level is reached, the temperature and pressure sensor sends an alarm message to the computer in the safety control room, At the same time that the reactor facility is open to each of a plurality of temperature pressure sensing sensors and safety valves, the nuclear reactor facility is provided with a nuclear reactor (74a) inside each pressure vessel, As the wastes are stored, the temperature-sensing sensor safety valve 472 connected to the inner block tank at the lower end of the pressure vessel 813 is opened, and at the same time, the outer block piping line 74b of the reactor installation is provided with the fuel explosion prevention The control device is connected to the thermocouple thermometer sensor switch 103 having a connection structure with the automatic charging device flashing warning lamp 99, the pressure gauge 101 and the temperature sensing sensor bimetal 102, the level pressure switch 104 for flow rate check operation, A flow rate check flow meter 105 and a safety valve 472 of a piping line automatic pneumatic valve conveying device 916 are connected to the upper end of the reactor building 688 at a constant 45 ° inclination angle A plurality of through holes are formed in a plurality of through holes and a plurality of safety valves 472 are formed in the plurality of through holes, while a through hole is formed by a laser cutting machine, a construction machine and a drilling machine, A flange connection is provided to the block piping line 74 by bolts 24 and a gasket 32 to the nuts 25 and a diameter 2 of the reactor building 688 along the outer wall surface of the reactor building 688 A double structure block tank 598 of double size is provided with an outer block tank 599 for storing nuclear waste treatment and a radiation type connection structure in a single location to distribute nuclear waste processing and distribution fuel injecting apparatus and nuclear fuel explosion control apparatus. (681) inside the nuclear reactor facility and outside the reactor core (681) with nuclear fuel explosion-proof control goods immediately before the reactor explosion, and the nuclear power plant equipment (1) inside the nuclear reactor main body (811) of the nuclear waste disposal pipe manufacturing process, the double structure block tank dust collector (794) of the distribution shaft (705) constituting the nuclear power plant;

5C, the reactor installation constituting the nuclear power plant is connected to a steam generator 810 and a steam dryer 786 installed outside the pressure vessel 813 of the double structure block tank dust collector 794, And the reactor building of the double structure block tank dust collector 794 corresponding to the fifth wall and the containment vessel 808 corresponding to the fourth wall of the nuclear reactor facility is provided with a plurality of inner block tanks 596 and a plurality of outer Block tank (599) Distribution fuel injecting device for control of nuclear fuel explosion control separately The fuel loom (158) and the cement mixing equipment mixer machine (649) are installed to prevent explosion of nuclear fuel into a pressure vessel (813) Control product Cooling water 287 and a mixture of loess such that soap bubbles are generated are put into the pressure vessel 813 at a time by an automatic injection device to control the equipment and clean the inside of the reactor facility after the earthquake occurs A plurality of firefighter nozzles 10 constitute a fuel explosion control device inside the pressure vessel 813 and inside the containment vessel 808, and a fuel explosion control system that automatically performs the cleaning process inside the nuclear reactor facility without inputting human and robot It is equipped with distribution dispenser and nuclear fuel explosion prevention control goods as distribution dispensers of nuclear waste disposal system in the inside and outside of the nuclear reactor facility and the nuclear power plant of the nuclear power plant of the land and ocean (1) 811) of the distribution shaft 705 of the nuclear waste treatment line manufacturing process;

As shown in FIG. 5C, internal cleaning of the reactor facility constituting the operation of the nuclear power plant is performed by cleaning the inside of the nuclear waste disposal pipe manufacturing process distribution shaft 705, the double structure block tank dust collector 794, The cooling water 287 constituting the circulating water pump 242 connected to the cooling water inlet 352 of the distribution inlet cooling water piping line and preventing the yellow loam mixture from solidifying is supplied to the mixer machine 649 ) Is mixed with the mixture of the loess mixture, and is put into the pressure vessel 813 at a time. After the earthquake stops, the inside of the reactor is cleaned by the circulating water pump 242 immediately, so that continuous nuclear power generation (794) for preventing the explosion of the reactor, which constitutes the safety operation of the nuclear reactor equipments, And a nuclear power plant (811) inside the nuclear reactor plant main body (1) of a nuclear power plant of land and ocean, as a distribution input device for nuclear fuel explosion control. The dual structure block The tank dust collector 794 is configured to operate the nuclear power plant;

As shown in FIG. 5C, in the nuclear power plant (811) of the nuclear reactor facility, there are installed a nuclear reactor core A nuclear power plant comprising a plurality of nuclear reactors and a combined connection structure inside a nuclear power plant including a plurality of double structure block tanks (794) for storing wastes (224) The power generation facility unit 811 includes a steam turbine 267 generating fission in a plurality of nuclear reactors to generate steam by the heat to generate power by rotating the steam turbine 267, An atomic power generator 772 for converting power and an atom (s) installed along the circumference of a rotating shaft 198 connecting the steam turbine 267 and the atomic power generator 772, A rotating rotor electromagnet coil 774 for a power generator and a non-rotating armature coil 773 for a nuclear power generator installed along the circumferential surface of the rotating electromagnet coil 774 for rotating the nuclear power generator and the steam turbine 267 And a frame 775 fixed to the rotary shaft 198 integrally with the atomic power generator 772 and the rotary shaft 198. The nuclear plant 811 is installed in the reactor main body 1 of the nuclear power plant on land and in the ocean. The nuclear power plant is operated by the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process composed of the nuclear power generation facility unit 811;

5C, the nuclear power generation facility 811 of the reactor facility is connected to a condenser 790 and a cooling water supply unit 810, which is provided under the body of the steam turbine 267 of the nuclear power generation facility unit 811, And a circulation water pump 242 connected to the cooling water inlet 352 of the piping line and the cooling water inlet 352 of the cooling water piping line to the piping line 169 by a waterproof path in front of the condenser 790, A dual structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility 811 inside a reactor facility main body 1 of a nuclear nuclear power plant A water supply pump 241 is provided at the rear of the condenser 790 and outside the nuclear reactor facility and a purifier is installed at the outside of the reactor in front of the water supply pump 241 809) A plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 in which the enriched uranium 812 fuel is stored and the pressure vessel 813 of the reactor facility is connected to the inside of the reactor internal piping line in front of the purifier 809, A safety device control rod 798 is installed in the inside of the reactor main body 798 to automatically insert the control rod 798 into the reactor main body 1 of the nuclear power plant in the offshore and offshore, The nuclear power generation facility unit 811 in the nuclear power plant 811 of the nuclear power plant 811, and the dual structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process;

As shown in FIG. 5C, in the nuclear power generation facility 811 of the reactor facility of the nuclear power plant, a first wall pellet 683 and a second wall pillar 689, which protect the second wall pillar 689, The collision of the cladding pipe 682 with the seismic force of the seismic force sensor 682 caused by the seismic force of the seismic intensity 5 causes the plurality of temperature pressure sensing sensors to be formed inside the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 The explosive nuclear waste 224 passes through the inner block piping 74a of the block piping line 74 at each position of the upper end portion of the pressure vessel 813 while the safety valves 472 are opened and the outer block piping 74b The nuclear fuel explosion-proof control article cooling water 287 and the yellow loess mixture 927 for soap foam stored in the inner block tank 596 are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241 And the internal lower end positions of the respective portions of the double structure block tank 598 are provided with, The reactor 224 is moved and stored and the thermal pressure sensing sensor safety valve 472 connected to the inner block tank 596 of the pressure vessel 813 is opened and at the same time the reactor installation of the nuclear power plant is connected to the outer block The pipeline 74b is connected to the fuel block 813 and the fourth protective wall containment vessel 808 by a water pump 857 for supplying cooling water and yellow loess mixture 158 of fuel explosion prevention control product stored in the inner block tank 596 At the same time as the transfer is being carried out, nuclear fuel explosion prevention control articles, which are prepared by converting kinetic energy of the position energy of water into cooling water and loess mixture 927 for soap bubbles, are supplied to the inner block tank 596 and the outer block tank 599 If the inside of the reactor facility is filled with the cooling water (287) and the mixture of the loess mixture (927) for the soap bubble, the explosion of the reactor facility is terminated and at the same time, A double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility unit 811 in a nuclear reactor facility main body 1 of a nuclear power plant on land and in the ocean, The plant is configured to operate as a nuclear plant;

As shown in FIG. 5C, the nuclear power plant (811) of the reactor installation of the nuclear power plant is equipped with a remote control cutter or a submarine mineral harvesting robot 912 at the time of dismantling the nuclear reactor plant of the nuclear power plant operating the nuclear power plant When the explosion of the pressure vessel 813 of the reactor facility is stopped, the plurality of temperature-sensing sensor safety valves 472 are closed and the plurality of the temperature-sensing sensor safety valves 472 are normally closed (Nuclear Power Plant) to install a large number of nuclear reactors in the offshore barge (591). Before and after the operation of the Nuclear Power Plant, a number of nuclear reactors were installed in the anti-sinking barges of the ocean. The dual structure block 705 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process consisting of the nuclear power generation facility 811 inside the reactor facility main body 1 of the power plant The nuclear power plant (811) facility of the reactor facility of the above-mentioned nuclear power plant is equipped with a nuclear power plant (407 meters) at the top of the sea level so as not to be restricted by the weather condition of the earthquake and tsunami, (811), and the position of the nuclear power plant can be controlled by the mooring device and the diving buoyancy adjusting device formed on the sinking type barge line, so that a plurality of nuclear reactors of the nuclear power plant which are not affected by the earthquake and tsunami can explode The nuclear power plant 811 of the reactor facility controls the leakage of nuclear radiation to prevent the explosion of the reactor facility of the nuclear fuel chamber to prevent environmental pollution due to nuclear waste The dual-structure block tank dust collector (794) is installed in the marine nuclear power plant to ensure safe and continuous operation of the nuclear power plant. (593,594,595) to ensure the safety of the nuclear power plant and to ensure the repair of the reactor facility by continuous operation, the nuclear power plant in the nuclear power plant of the land and the ocean (1) A step of constructing a double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste processing pipe manufacturing process consisting of a power generation facility unit 811 and a nuclear plant of the nuclear power plant before and after the operation of the nuclear power plant, The nuclear power plant (811) facility of the reactor facility of the nuclear power plant includes a mooring device constructed on the barge by nuclear waste disposal, a diving buoyancy control device, a nuclear waste disposal dispenser and a nuclear fuel explosion control dispensing device, To prevent the environment from being contaminated by nuclear waste, control the leakage of nuclear radiation so that the inside and outside nuclear reactor facilities do not explode. Control of diving buoyancy and mooring arrangements at the ocean power plant floating plant (593,594,595) nuclear power plant (672) into the reactor plant main body (1) of the nuclear power plant (672) by the distribution input devices of the double structural block tank reactor (794) (1) nuclear reactor facility of nuclear power plant of land and sea by means of disaster prevention apparatus equipped with apparatus and nuclear waste disposal apparatus and nuclear reactor facilities to withstand natural disasters of the sea, The nuclear power generation facility unit 811 of the nuclear waste treatment plant is operated by the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process so that the nuclear power plant of the nuclear power plant is operated. Electric power generation equipment and nuclear waste disposal Marine tunnel transportation equipment (941) Disaster prevention equipment and transportation equipment to be equipped with position control system It is preferable to further comprise a wind power generator, a thermal power generator, and a hydraulic power generator,

5C, the inner block tank 596 and the outer block tank 599, which provides a position outside the inner block tank 596, The nuclear plant installation can control the double structure block tank 5988 to control the nuclear radiation leakage by controlling the position movement to the ceiling crane 861 and the conveyor 633 to the inside position of the block tank 599, (593,594,595) nuclear power plant (672) of the nuclear power plant and provided in the reactor main body (1) of the nuclear power plant by the distribution input nuclear waste treatment devices of the dual structural block tank dust collector (794) Control equipment and nuclear waste disposal Dispensers and reactor installations of nuclear reactors Safety operations Before the start-up of the nuclear fission facility (811) to the nuclear waste treatment plant manufacturing process (705) It is preferable to include a nuclear power plant (672) facility,

Referring to FIG. 5D, a reactor structure (1) of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor (811) 802) Nuclear waste disposal reactor facility for providing input Nuclear waste water reactor facility (802) of a nuclear power plant having a double structure block tank dust collector constituting an embodiment of a coupling system (802) A double structure block tank for the treatment of one nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the present invention having a double structure block tank dust collector Nuclear waste treatment equipment boiling water reactor facility (802) Deep-coupled safety reactor equipment side, sectional view ,

Referring to FIG. 5E, a reactor structure (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor (811) 802) Nuclear waste disposal reactor facility for providing input Nuclear waste water reactor facility (802) of a nuclear power plant having a double structure block tank dust collector constituting an embodiment of a coupling system (802) A double structure block tank for the treatment of one nuclear waste. An embodiment of a reactor plant of a nuclear power plant having a dust collector. The reactor structure of the nuclear reactor of the present invention having a double structure block tank dust collector Nuclear waste treatment equipment boiling water reactor equipment (802) Deep-coupled safety reactor equipment side, Roads,

5D and 5E, it is preferable that the double structure block tank dust collector of the floating power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant are connected to the reactor The diving preparation ready operation control dispenser input device screw control unit 811g constituting the connection axis of the nuclear waste disposal pipe manufacturing process 705 of the facility is provided with the screw control unit 811g for the diving process preparation, The double structure block tank hull disassembly-type portable lug 607 provided in a horizontal and vertical type coupling structure at each part of the holding tank upper barge hull 591 and the holding tank lower barge hull 592 includes a plurality of lug processing holes 615 and Double-structured block tank Tank for horizontal displacement Double structure block tank with elongated hole (616) for disassembly and displacement device Hull disassembly coupling Portable lug pin Connecting shaft (606) Double hole perpendicular to processing hole (615) (606) and an elongated hole (616) for a displacement unit of a block-unit double structure block tank hull disassembly position shifting control unit are provided in the structure block tank double hull disassembling portable lug pin connecting shaft (606) A plurality of processing holes 615 provided at respective portions in the vertical form of the connecting portion of the double structure block tank holding tank 590 and the barge hull 591 at the top of each of the double structure block tank holding tanks and the barge hull 592 at the bottom of the double structure block tank holding tank, Detachable portable lug pin connecting shaft 606 bound to several lug machining holes 615 of the plurality of connecting shafts 606 bound to the one-piece connecting shaft 606 The double-structure block tanks 598 having the coupling shaft 606 and the double-structure block tanks 598 are provided with the coupling control shaft 606. The double-structure block tanks 598 are used to construct the holding tank 590. At the same time, The anti-sunken stay line 634, (593, 594, 595) nuclear power plants (615) of the marine power plant by providing the pre-distribution input with the distribution input devices of the marine power plant, the screw control section (811g) The diving progression ready controllable dispensing and dispensing apparatus screw adjusting unit 811g constituting the connection axis of the floating waste processing plant (593,594,595) nuclear power plant (615) facility nuclear waste treatment pipe manufacturing process (705) of the marine power plant comprises a double structure block tank 598) Connecting tank at the lower part of the holding tank (590) Barge line Connected to each part of the hull Block unit of diving control device Double structure block tank (598) Bellows butterfly valve for hull inflation control device (622) The suction port 585a of the doctor pollution 585 of the disaster prevention pump 8 and the diving control device and the discharge port 585b of the doctor ventilation 585 and the hydraulic cylinder door 624 for the double structure block tank hull traffic control device Wow (625) and double structure piping line Automatic pneumatic valve transport device (916) and engine control power motor control module (106) Connection area Barge line Connected to each part of the hull Construction of each diving process is carried out at the same time, (593,594,595) Nuclear power plant (615) The submersible control device of the facility is provided with a horizontal double structure block tank holding tank (590) which is converted into a vertical holding block tank (590) (593,594,595) nuclear power plant (672) facility of the marine power plant prepared for the preparation for the proceeding includes the butterfly valve 622 of the anti-sinking retention line 634, the high pressure multi-stage emergency protection pump 8 and the doctor ventilation The nuclear power plant 672 is installed in the distributing and inputting apparatuses of the sinking residence line 634 for the nuclear power station 594, 595, 596 and the nuclear power plant 672 for the nuclear power plant 672,(1) Nuclear power plant (1) Nuclear power plant (1) Nuclear power plant (1) Nuclear power plant (1) Nuclear power plant 811 comprises a screw control unit 811g of a diving operation ready controllable dispensing and dispensing apparatus having a connection shaft of a nuclear waste processing line manufacturing process 705 of a reactor facility;

5D and 5E, the double structure block tank 598 constituting the operation of the nuclear power plant includes a plurality of outer block tanks 599 and a plurality of block tank tanks 598 outside the plurality of inner block tanks 596, The first auxiliary steel pipe 600 for the block tank and the second auxiliary steel pipe 601 for the block tank, the vertical partition wall 605, the horizontal partition wall 609 and the steel beam 149, And the second auxiliary steel plate 601 for the block tank, the vertical partition wall 605, the horizontal partition wall 609 and the steel beam 149, the snap hole 602 and the partition wall manhole 610 are cut and cut with a computer laser cutter Process is performed and welding is performed by a welder of the welding process so that a double structure block tank precipitator 794 is installed inside the reactor facility main body 1 of the fifth protective wall nuclear power plant constructed along the outer wall surface of the fourth protective wall containment vessel 808 ) Of the distribution shaft (705) of the nuclear waste processing pipe manufacturing process consisting of the nuclear power plant (811) Configuration be made up the original operation to lock the tank (598) and;

5D and 5E, in the double structure block tank 598 constituting the nuclear power plant operation, the vertical partition wall 605 constituted by the partition wall manhole 610 and the horizontal partition wall 609 are provided with a communication device hydraulic cylinder The door 624, the emergency stairs and the stairs 631 are formed by a welding process and are provided as a traffic device of the reactor explosion-proof double structure block tank dust collector 794 and are provided with a double structure block tank dust collector 794, The double structure block tank 598 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process consisting of the nuclear power generation facility 811 inside the nuclear reactor facility main body 1 of the nuclear power plant, To operate the nuclear power plant;

As shown in FIGS. 5D and 5E, the diving operation ready controllable dispensing and inputting apparatus constituting the connecting shaft to the screw adjusting unit 811g includes a double structure block tank holding tank 590, A double structure block tank hull breaker portable lug 607 formed on each barge line is provided with a connecting shaft 606 and a thread 603a of a lug connecting shaft coupling bolt 603a and a thread 603b of a lug connecting shaft coupling and disassembling nut 604 And the lug pins 608 on the lug coupling pin connection shaft 606 are connected to the hydraulic rotary cylinder machine 619 for the position adjustment of the traffic apparatus equipment distribution input unit and the block unit of the traffic device double structure block tank hull disassembly adjustment And a plurality of lug processing holes 615 provided in the double structure block tank hull disassembly and connection portable lug 607 and a block unit double structure block tank hull disassembly Move joint position The horizontal double structure block tank 598 with the elongated hole 616 for the regulating device has a double pipe structure with a double structure block tank hull disassembly in the tugboat 636 provided on the semi diving operation line 637 (621) and the sinking ship (621) for the disassembly coupling control unit of the block unit dual structure block tank inside the reactor main body (1) of the nuclear power plant in the same form as the bridge saddle formwork (617) A connecting structure capable of performing diving coupling is provided by pre-distributing the hull diving position adjusting movement device of the prevention stay line 634 and the diving buoyancy control weight 107 to the double structure block tank holding tank lower barge hull 592 (1) atomic structure of a nuclear power plant which is assembled as a connection structure having a connection structure of a nuclear reactor building (688) to a nuclear reactor main body (1) of a nuclear power plant, The double structure block tank dust collector of the power generation facility unit 811 is constituted of the diving progression ready controllable dispensing apparatus screw control unit 811g having the connection shaft of the nuclear waste treatment pipe manufacturing process 705 of the reactor facility, The power transmission portion 811d provided with transformer devices for transmitting the power of the nuclear reactor facility main body 1 of the nuclear power plant having the screw control portion 811g and the connection shaft and the power of the nuclear power generation facility portion 811, The double structure block tank holding tank lower barge hull 592 constituting the connecting shaft of the nuclear reactor installation main body (1) of the nuclear reactor plant (1) 688 and an outlet power source 686 and an outlet power source 687 for the voltage 684 and the power 685 and to provide the production power to the location- Devices, The shift control device for power supply shifts from the superhigh-voltage substation 690 to the primary substation 691 through seven strands of steel wire 692 and a transmission wire diameter 695 of 54 strands of aluminum wire 693 And the double structure block tank holding tank lower barge hull 592 constituting the connecting shaft of the power transmitting portion 811d is provided with a connection structure having a submarine line wiring connection structure, and a marine tunnel crossing railway substation And the production power supply at the primary substation 691 from the high voltage substation 690 provided with the production power supply shift regulating device transformer 96 of the power generation unit 696 and the voltage 684 of the intermediate substation 697 and the power 685 A large-scale factory 698 and a stop-and-wait factory 699 are provided to provide a production power supply to a position having a submarine line wiring connection structure. At the same time, a primary substation 691 constituting a connecting shaft of the power transmission unit 811d In the secondary substation 700 that receives the production power supply (951) and a transformer (952) that provide a connection structure with a submarine line wiring connection structure that provides a production power supply distribution to the Sodae plant (701) and a home (702) And the connection structure is provided with a connection structure for providing the production power supply distribution discharge, which is provided with the step foot hook 703 and the cable balance ultra high voltage wire balance insulators 704, (GLD) is a connecting structure with a connection structure that provides production electric power supply distribution discharge which is provided as wiring through the underground line (GLD) on the land. (1) a nuclear power plant (811) of a nuclear power plant with distribution and input devices for distributing production power supply of a nuclear power plant main body (1) The power transmission unit 811d including the connecting shaft of the nuclear waste treatment pipe manufacturing process 705 of the nuclear reactor facility is connected to the household 702 including the solar heating house, And a power transmission unit 811d provided with transformers for transmitting the power of the nuclear power plant 811 of the nuclear reactor main body 1 of the nuclear power plant include a transformer connection structure having a submarine line wiring connection structure (634), which provides for lifting of a sinking ship, is provided in the nuclear power plant facility, and a structure is provided to connect the nuclear power plant to the inside of the reactor main body (1) of the nuclear power plant. The double structure block tank dust collector 794 for controlling the nuclear radiation leakage of the structure block tank 598 is provided with a facility inside the reactor facility body 1 of the nuclear power plant, Nuclear power plant (672) Mooring device, diving buoyancy control device, nuclear waste disposal dispenser and nuclear reactor facility safety facility Fukushima Nuclear Power Plant (811) And a diving operation ready controllable dispense and input screw control unit 811g having a connection shaft of the pipe manufacturing process 705. [

As shown in FIGS. 5D and 5E, in the reactor installation constituting the nuclear power plant, an enormous amount of radiation is generated inside the reactor installation, and the reactor installation can securely secure the first wall pellets 681, (688) of the reactor building (688) consisting of a cladding tube (682) for protecting the first wall reactor vessel (689) and a fifth wall reinforcing concrete mat (225) for the third wall reactor pressure vessel (813) A nuclear waste disposal dispensing apparatus having a double structure block tank dust collector 794 constructed by replacing the reactor building 688 with a five-layered protective wall, and nuclear fuel explosion control dispensing apparatuses, A nuclear power plant (811) inside the main body (1); a dual structure block tank (794) of a distribution shaft (705) of a nuclear waste processing pipe manufacturing process;

As shown in FIGS. 5D and 5E, in the reactor installation constituting the nuclear power plant, the double structure barge hull 591 at the lower end of the holding tank of each control shaft controls the nuclear radiation leak into the SDM of the hull deck A double structure block tank dust collector 794 is installed at the center of the plurality of inner block tanks 596. At each of the aft and theft sides of the inner block tanks 596, A guide rail 618 is installed to the left and right sides of the deck deck and a crane 861 having a capacity of 5000 tons is installed at the SDU position of the double structure barge hull 591 hull deck upper part A nuclear waste disposal with a dual structure block tank dust collector 794 constructed by replacing a five-fold protective wall inside the barge hull while being constructed of reactor facilities on the guide rail 618 At the same time that the distribution apparatus and the nuclear fuel explosion control distribution dispensing apparatus are installed, the nuclear waste disposal reactor facility is provided with a double structure, a double structure, and a double heterogeneous structure in the safety place where the crane 861, And a plurality of construction transportation transport parts provided at one end of each of the control shafts and provided as a connection structure to adjust the position of the respective control shaft. The nuclear reactor is installed in the nuclear reactor facility 811 in the reactor main body 1 of the nuclear reactor The dual structure block tank cleaner 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process being constructed;

(593,594,595) nuclear power plants (672) of the offshore and offshore marine power plants and nuclear power plant main unit (1) nuclear power generation facility unit (811), as shown in FIGS. 5D and 5E, The distributing and inputting apparatus for the nuclear power plant equipment for the damping buoyancy preparation ready operation control constituting the connection axis position of the nuclear waste processing pipe manufacturing process 705 of the nuclear reactor facility, Nuclear waste treatment dual structural block tank marine tunnel traffic device (941) which establishes connection between land and book of nuclear power plant nuclear power plant (672) of nuclear power plant and reactor main body (1) of nuclear power plant, Nuclear waste treatment double structure block tank marine tunnel traffic facility (941) facility of nuclear power plant is provided at the upper part of pier (928) by double structure block tank pipe bridge (937) And the nuclear waste treatment dual structure block tank bridge 929 is connected to a nuclear waste treatment dual structure block tank bridge bridge 929 facility at the sea level lower end SLD 40D of the sea level SLL (929) connection of the nuclear waste disposal double structure block tank bridge (929) to the double structure block tank marine tunnel traffic facility (941), and the nuclear waste disposal dual structure The connection shaft of the block tank pipe bridge 929 is provided with a diaphragm buoyancy advance preparation operation control for controlling the capacity of the reactor main body 1 of the nuclear power plant. However, the connection shaft of the pipe bridge 929 is a double structure column block tank pipe The double structure block tank holding tank pipe bridge 928 is provided with the insertion of the connecting shaft of the nuclear waste treatment double structure block tank bridge bridge 929 through both sides to the upper end of the pipe bridge 937 of the pier bridge 928, An empty space for regulating the distribution of the capacity of the floating nuclear power plant 672 of the marine power plant to the inside upper end of the pipe bridge 937 is provided to the double structure block tank 598 of the double structure block tank 598 The inner block tank 596 is positioned outside the inner block tank 596 and the inner block tank 596 and the outer block tank 599 are positioned outside the body of the inner block tank 596, Tank (598) Dual structure block tank with connection structure inside the body The marine tunnel transport system (941) is located in the nuclear waste treatment dual structure block tank bridge bridge (929) and double structure stay block tank pipe bridge bridge (928) (593,594,595) Nuclear power plants (672) of the marine power plant are equipped with the construction equipment located inside the hull of the distribution input device of the anti-sinking rescue ship (634) The base (851) (1) of the nuclear power plant, the distribution input device having the connection structure with the floating power plant (672) of the marine power plant is connected to the submarine line of the submarine line injection nozzle connection port Nuclear power plant (672) that provides sinking prevention by sink prevention resident line (634) with nozzle and submarine line connection structure Construction equipment and reactor main body of distribution input device located inside the hull of equipment (1) Nuclear power The double structure block tank dust collector is connected to the screw control part 811g of the power generation equipment part 811 by the distribution of the nuclear power plant equipment for the damping buoyancy preparation operation control control constituting the connection axis position of the nuclear waste treatment pipe manufacturing process 705 of the reactor facility (1) of the nuclear power plant (1) and a screw of a nuclear power plant (811) of the nuclear power plant, The partitioning device of the block tank coupling portable lug 607 constituting the connection shaft position of the nuclear waste processing pipe manufacturing process 705 of the nuclear reactor facility is connected to the branching unit 811g by pipe bridges 937, (593,594,595) Nuclear power plant equipment that is not formed at the upper part of the double structure block tank bridge (937) of the nuclear power generation facility part (811) of the nuclear power plant is composed of a strut tank upper barge hull (591) And the holding tank lower barge hull 592. The holding tank upper barge hull 591 is provided with nuclear power generator facilities and the holding tank lower barge hull 592 is provided with reactor facilities, A plurality of double structure block tank-combined portable lugs 607 formed separately from the block tank 590 and a plurality of double-structure block tank hull disassembly-type portable lugs 607 provided at respective portions thereof, (603) and lug pin (608) of the shaft bolt (603a) and the lug pin (608) are combined with each other to form a nuclear reactor. Each of the floating type floats 593, 594, 595 provided for the main body 1 is provided with the flow type flood control 593, 594, 595 nuclear power plant equipment in which the holding block tanks 590 are arranged in the unit of the depth of the sea surface SLL Nuclear power plant facilities are provided, but the volume of the double structure block tanks is divided into 500m3 units, and the small-scale floating vending machines (593) are connected to the medium and large floating vending machines (594,595) The structure is divided into a plurality of block tank hull disassembly portable lugs 607 provided at respective portions of the double structure block tank combined portable lug 607 and a plurality of blocks (606) to the block tank hull disassembly portable lug connecting shaft bolt (603) and the block tank hull disassembling portable lug connecting screw (603) of the disassembling coupling nut (604) Nuclear power plant nuclear waste treatment double structure block tank with connection structure to a marine tunnel traffic facility (941) and a dual structure strut block tank pipe bridge pier (928) are connected to a sink prevention rescue line (634 ) Distribution system of the distribution hull deck deck The mooring crane (846) for replacing the mooring device anchor on the seabed is connected to the hydraulic cylinder machine (624) and the key bed (616) (593, 594, and 595), the connection structures provided for preventing the sinking of the nuclear power plant are connected to the submarine line of the submarine line injection nozzle connecting port into the reactor main body 1 of the nuclear power plant, (593,594,595) Nuclear power plants are installed with position-controlled connection structures with the connection structure of four-nozzle and submarine line wiring, and construction equipment connecting structures that provide positions on the hull deck deck of the nuclear power plant facilities. The nuclear reactor facility main body 1 of the power plant is connected to the hydraulic cylinder machine 624 and the key bed 616 by a mooring crank 846 for mooring anchor replacement on the seabed. (593,594,595) Nuclear power plant for the sinking prevention constituting the above nuclear power plant facility is equipped with a double structure block tank pipe bridge (937) at the upper position of 40 meters, And general maritime and maritime steel structures. The height of the sailing vessel safety, the collision prevention, the bridge bridge bridge, and the reactor facility of the nuclear power plant (1) (593,594,595) of the reactor facility main body (1) of the nuclear power plant which provides the nuclear power plant facility as a connection structure, and distributes it to the anti-sinking restrainers (593,594,595) (593,594,595) nuclear plant installation of the nuclear reactor plant main body (1) has a double structure block tank (598) connected to the nuclear power plant facility. The distribution system of the nuclear power plant equipment (593,594,595) Double structure block tank (598) of multiple flow type flood control unit with flow-type barge and fixed barge equipped with empty space of distributing control unit The double structure block tank bridge piers 928, which are provided with an empty space and supported, Unit and double structural block tank The pipe bridge pier (928) provided in units of 500 cubic meters of volume is provided with connecting structure to provide fixation to the seabed at intervals of 500M, and the construction equipment is provided in the nuclear power plant facilities, (846) for replacing anchorage anchor replacement crane (846) located at the lower foundation (851) for bridge pier level foundation, while the nuclear plant installation is provided with a fixed installation connection structure, (1) The main structure of the reactor plant of the nuclear power plant (1) The connection structure of the facility (1) The sinking structure of the distribution shaft of the distribution shaft which provides the sinking to the inside of the nuclear power plant (593, 594, 595) distribution shafts constituting the distributing shafts are provided with the distribution shafts (593, 594, 595) (590) Upper barge deck Deck Decks Girdle and sea level top barge to provide position on the sea level at the bottom 40m Barge deck Top barge above sea deck to position on top deck On deck top, (1) facility of nuclear power plant provides electric power supply of environmentally friendly pollution-free energy industry, while many nuclear power plants, wind power plants and hydro power plants are provided with separate power generation devices The seabed mineral resources collection site is located at the top of deck deck of submarine mineral resource collection area and floating upkeep dock (593,594,595) located in the lower part of floating deck hull deck deck (SDL) 116) to the steady position is the weather station observation station, flood control unit, top barge, deck deck, (1) The submarine line injection nozzle is connected to the submarine line injection nozzle and the submarine line connection distribution line of the nuclear reactor plant main body (1) (593, 594, 595) deck deck top of a floating vane fixture (593, 594, 595) that provides a position with a shaft structure, the aircraft emergency landing site is equipped with a nuclear reactor plant main body (1) (811) of the nuclear power plant (811), and the control unit (811f) of the nuclear power plant (811), the reactor main body (1) of the nuclear power plant, the operation of the carrier for the distribution shaft construction machine, The electronic control device of the nuclear power plant 811 constituted by the interior of the nuclear reactor facility of the nuclear power plant (811f), the electronic control and regulating device construction machine control unit (811f) controls the sub-assembly distributing and inputting device to inject the subsea line injection nozzle into the submarine line injection nozzle connecting port into the reactor installation body (1) of the nuclear power plant Nuclear waste treatment double structure block tank with connection structure with wire connection structure The marine tunnel transportation equipment (941) equipment is equipped with a double shaft block bridge tank bridge bridge (929) The double structure block tank 598 having the connection shaft of the double structure block tank bridge 937 as the connection structure of the pipe bridge 937 body is provided with the inner block tank 596 installed at the lower end position of the inner block tank 596 The inner block tank 596 is provided with a guide rail 618 for the hull vehicle transporter and is provided with an internal train 771 for a marine tunnel apparatus at a speed of 100 km per hour, Wow A positional connection is made to the lower end portion connection structure of the guide rail 618 which provides a position at the lower end of the inside of the inner block tank 596 which provides a position as an individual space connection structure in an empty space inside the outer block tank 599 The connection structure equipment provided at the position of the empty space for providing the position to the inner lower end of the outer block tank 599 for providing the position by the outer connection structure of the guide rail supporter 852 and the inner block tank 596, And the natural gas and crude oil transportation facilities are connected to a pipeline line automatic pneumatic valve transport device 916. The tugboat 636 and semi-submerged tanks 636 are installed in the reactor main body 1 of the nuclear power plant, The operation line 637 and the sinking prevention stay line 634 of the sinking ship can be provided as well as the nuclear plant installation and the reactor installation and dispensing apparatus of the nuclear power plant and the construction machinery equipment (941) of the nuclear waste treatment double structural block tank is installed on the substrate of the nuclear reactor main body (1) of the nuclear power plant connecting the land and the book to each other by completing the installation process to a position where disassembly and assembly are possible. (593, 594, 595) having a distribution axis for exposing the upper surface of the sea surface to the inside of the nuclear reactor facility main body 1 of the nuclear power plant with the construction machine equipments, the electronic control adjusting device construction machine control section 811f of the nuclear power generation facility section 811 (593,594,595) installed at the ocean power plant (672), the diving buoyancy control device, the distribution and input device of the nuclear waste disposal, and the nuclear reactor facility safety operation of the nuclear reactor facility. 811) to the connection shaft of the nuclear waste treatment pipe manufacturing process (705) of the nuclear reactor facility, to a disassembly-connectable connection structure at the marine vessel manufacturing factory Is preferably configured to also,

(593,594,595) nuclear power plants (672) of the offshore and offshore marine power plants and nuclear power plant main unit (1) nuclear power generation facility unit (811), as shown in FIGS. 5D and 5E, The dust collector is connected to the nuclear waste disposal pipe manufacturing process (705) of the nuclear reactor facility, and the submerging process preparation control operation control apparatus constituting the nuclear power plant facility of the nuclear reactor plant (705) is connected to the upper and lower barge hulls The nuclear power plant nuclear waste disposal unit 811a is installed in the nuclear waste disposal unit of the nuclear power generation nuclear power plant 811a as follows: the nuclear power plant 593,594,595 of the marine nuclear power plant 672 ) And a submarine line of a submarine line injection nozzle connection to the inside of a reactor facility main body (1) of a nuclear power plant, and a connection structure having a submarine line wiring connection structure (593, 594, 595) of the submerged marine power plant which is located at the bottom of the holding tank tank 590, which is positioned at the lower end of the center of the holding tank upper barge hull 591 provided at the connection structure of the nuclear power plant, 592) and a plurality of column block tanks 590 for providing a position as a connection structure around the center of the barge hulls 591, 592 are disposed in the upper portion of the strut tank upper barge hull 591) Connecting block top block (590) Connection part of tank top (590) Barge hull (591,592) to provide connection structure for distribution shaft part Provide adjustment of position of distributing shaft to each connecting part, A plurality of processing holes 615 and a lug elongated hole 616a for a hull unit disassembling and coupling position adjusting unit of the block unit double structure block tank The screw thread 603b of the coupling tank 603 and the screw thread 603b of the lug coupling shaft coupling bolt 603 and the nut screw thread 603b of the lug coupling shaft coupling and disassembling nut 603, The block tank hull disassembly portable lug 607 and the block tank mated portable lug fins 608 may be used to provide the flood control (593, 594, 595) nuclear power plant disassembly and coupling control of the anti-sinking offshore power plant, Mooring system and flood control barge Shipbuilding bed (616) for hull balancing system The connecting structure is equipped with the protection system of the marine power plant (593,594,595), the prevention of the sinking of the nuclear power plant facilities, ) Dual structure providing the position with submarine line injection nozzle and submarine line wiring connection structure of submarine line injection nozzle connection to nuclear power plant (672) and nuclear reactor facility main body (1) of nuclear power plant The construction machine equipment comprising the connection shaft and the distribution shaft of the block tank tube bridge 937 is connected to a floating nuclear plant (593,594,595) nuclear power plant (672) of the anti-sinking offshore power plant and a protection connection Structure of Nuclear Power Plant Nuclear Waste Treatment Screening Unit Dual structure block tank for nuclear radiation leakage of reactor facility Nuclear power plant nuclear waste disposal unit 811a of nuclear power plant 811 of nuclear power plant with distribution and dispensing device of dust collector 811a, (593,594,595) nuclear power plant 672 of the marine power plant and nuclear power generation nuclear waste treatment unit 811a of the nuclear power plant 811 of the nuclear power plant to provide a connection structure (593, 594, 595) atoms of the nuclear reactor nuclear waste treatment section (811a) are connected to the distribution input device of the double structure block tank coupling lug (607) The power plant 672 includes a double structure block tank combined portable lug 607 provided as a connecting structure in horizontal and vertical type coupling structures at respective portions of the upper barge hull 591 of the holding tank 590 and the lower tank barge hull 592 of the holding tank A horizontal pin connecting shaft processing hole 615 having a plurality of processing holes 615 and a long hole 616a and a pin connecting shaft processing hole 615 and a long hole hole 616a perpendicular to the body, And a plurality of processing holes 615 provided at respective portions in the vertical form of the connecting portion of the tank 590 and the upper end barge hull 591 and the holding tank 590 and the lower barge hull 592 of the respective holding tanks 590 The connection shaft 606 bound to the plurality of processing holes 615 of the plurality of connection shafts 606 is removed so that the coupling structure of the nuclear power plant 672 is provided by a single connection shaft 606 connection structure, The double structure stowage block tank (590) facility of the connecting shaft (606) (672) facilities at the sea level by means of distributing and inputting connection structures capable of disassembling and disassembling nuclear power plants (672) by pre-distributing molybdenum refueling lines (634) The horizontal lower portion of the tank 590 is connected to the vertical holding block tank 590 by a vertical holding block tank 590 provided as a connecting structure at each connecting portion of the lower portion connecting barge hull, The submergence control device of the nuclear power plant 672 provided with the position adjustment switching device 634 as the connection control structure connection structure lines 634 and the sink prevention resisting line 634 is provided at the lower end SLD of the sea surface (593,594,595) of the submerged marine power plant (1), and the nuclear waste disposal shielding facility (593,594,595) Nuclear power plant (672) of marine power plant equipped with excavation equipment and mooring equipment provided on the anti-sink stay line (634) as a distribution input device of double structure block tank dust collector for nuclear radiation leakage control (1) Nuclear power plant nuclear power plant (811) Nuclear power plant nuclear waste treatment facility (811a) Nuclear waste treatment facility (811a) to provide connection structure Dispensing and input equipment Excavation equipment and mooring equipment, (593,594,595) nuclear power plant (672) of a marine power plant of a nuclear waste treatment unit (811a) and a nuclear reactor main body (1) of a nuclear power plant. The rotary table lathe machine 908 equipment of the machine is provided with the distribution of the reactor facility nuclear power plant constituted by the nuclear reactor facility main body 1 of the nuclear waste treatment section 811a (593,594,595) of the sinking prevention marine power plant which is located at the upper part of the sea surface (SLU) of the sea surface (SLL). The rotary table lathe machine (593,594,595) of the hull deck upper part (SDU) drilling machine room 908 are connected to the boom hoist boom 654 of the crane boom 651 of the overhead crane 651 which is provided at the upper end of the drill machine room and the boom hook 652 and the wire ropes 19 The pipe rack 854 in the waiting preparation state for excavation is provided with a plurality of pipe racks 854 provided as connection structures of the sea level lower end SLD of the sea level SLL The core drill 917 is provided with a drilling hole 936 as an excavator rotating body and at the same time an excavating hole 936 is provided at the excavation hole 936 provided as a connection structure with the core drill 917, The worm crank 846 is connected to a hydraulic cylinder Preventing line (634) provided in a construction machine operation connection structure mounted on each of the strut block tank upper barge hulls provided as a connection structure between the system (624) and the key bed (616) (593,594,595) of crude oil borehole (936) in nuclear power plant facilities Subsurface connection of crude oil and natural gas discharged from the location of the marine power plant with a submarine line wiring Substructure of the upper deck (SDU) And the ceiling crane 651 that is provided at the upper end of the lower end of the block steel tower 15 of the nuclear power plant facility as a connection structure is provided with a ceiling crane 651, The rotary table lathe machine 908 of the crude drilling machine, which provides a position as a linkage structure, comprises a rotary table lathe machine 908, And a plurality of hydraulic cylinders 623 for drilling for providing a position in the line-opposing central portion. Alternatively, a plurality of tool keys 623 may be provided for controlling the movement of the tool, The rotary table lathe machine 908 of the conventional drilling machine is provided to be connected to the position movement control device rotation body of the connection structure which is pushed to the center position of the line counterclockwise and spread out from the central portion opposite to the line center to the outside, A plurality of pipe racks 854 connected to the crankshaft 908 at a point located at the bottom of the oil borehole 936 located at the seabed, (936), which is equipped with a connecting structure located at the connecting structure of the crude oil at the time of the crude oil at the time of the crude oil, 936 of the rotary shaft for excavation of the crude oil borehole (936) And the nuclear waste treatment reactor apparatus nuclear reactor operation distribution apparatus consisting of the nuclear reactor facility main body 1 of the nuclear waste treatment unit 811a is connected to the wire rope 65 of the overhead crane 651 (854) for crude oil piping racks (854) for drilling machines for crude oil in drilling machines Rotary table lathe machines for drilling machines (908) Blocks for rotary drilling of the body Unit blocks Hydraulic rotary cylinder machines for tank hull disassembly and adjustment devices ) To the top of a rotary table lathe machine 908 of a drilling machine for crude oil with a number of hydraulic cylinder actuators 623 for drilling to position it as a connection structure at the opposite center of the line, 936 to perform the operation of the rotary table lathe machine 908 of the drilling machine for crude oil to finish the drilling of the crude oil bore hole 936 and simultaneously to the position of the oil bore hole 936 (886) and the boom hooks (652) of the tower crane (886) and the boom hook (652) of the tower crane (886) 652) In the vertical rotation operation, all the deep-sea energy resources are raised to the top of the deck deck, and at the same time, the distribution input device constituting the nuclear waste disposal of the nuclear plant operation of the reactor facilities is the floating care plant of the submergence prevention ocean power plant (593,594,595) Crude oil and natural gas discharged from the crude oil borehole (936) inside the facility are connected to crude oil and natural gas discharged from the crude oil borehole (936) inside the nuclear power plant. Operation of the nuclear power plant is started. At the same time, crude oil and natural gas crude oil boreholes, which are located in the connection structure of crude oil borehole (936) (936) where the deep-sea energy resources have been completely lifted to the upper deck deck and the deep-sea crude oil borehole (936) where the excavation has been completed. (593,594,595) of the power plant. The nuclear plant is equipped with a mooring device and a diving buoyancy control device to secure a stable mooring at the sea. At the same time, the nuclear waste incineration treatment core drill 917 to the nuclear reactor bore 936 and at the same time to operate the nuclear reactor with the reactor facility body 1 of the nuclear waste treatment unit 811a;

As shown in FIG. 5D and FIG. 5E, the distribution input apparatus constituting the sinking restraining line 634 as a connecting structure of the nuclear plant facility of the marine power plant of the nuclear waste disposal unit 811a (593,594,595) In the nuclear power plant equipment of the nuclear waste processing unit 811a, the anchor replacement crankshaft 846 connected to the construction machine is connected to the core drill 917 drilling hole 936 and the hydraulic cylinder machine 39 is operated The worm crank 846 is pushed into the excavation hole 936 and the worm crank 846 compresses and expands inside the excavation hole 936 to form a crevice tool And at the same time the guide bar 185 fixes the lower end portion of each holding tank so that the barge with anti-drifting barge hulls can be seated in the deep sea, And marine power generation (593,594,595) Stacked tank top barge with mooring device to nuclear power plant equipment Construction machine mounted on hull barge to locate the connection structure Hull anti-drift prevention wrench Crank (846) Mooring devices (593,594,595) in the nuclear power plant (672) and the distribution of the diving buoyancy control device and nuclear waste disposal in the nuclear power plant (672) of the nuclear power plant Before the safe operation of the nuclear reactor facilities of the nuclear reactor and the nuclear reactor facility, the nuclear power generation facility of the nuclear power generation facility 811a of the nuclear waste processing unit 811a at the connection shaft of the nuclear waste treatment pipe manufacturing process 705 of the nuclear reactor facility, It is preferable to include a connection structure capable of disassembling and coupling the power plant,

Referring to FIG. 5F, a reactor structure (1) of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is installed in a nuclear reactor (811) 802) Nuclear waste treatment reactor installation providing dual injection structure Dual structure block construction constituting one embodiment of coupling system Boiling water reactor installation (802) of a nuclear power plant having a dust collector Degradation coupling type deep safety reactor installation side, An example of a reactor installation of a nuclear power plant having a dual structure block tank dust collector for elementary nuclear waste disposal showing a loess mixture 927 for a process control article soap bubble and a previous unprotected state nuclear explosion scene is described as an explosion- Of the present invention showing the construction of a deep-safety nuclear reactor of a nuclear power plant having a double structure block tank dust collector according to the present invention. (802) Deep-coupled safety reactor for decompositionally coupled equipment Nuclear waste disposal control equipment for cross-section Nuclear waste control for soap bubbles (927) and strabismus configuration of the former unprotected nuclear explosion scene Road,

As shown in FIG. 5F, it is preferable that the reactor facility of a nuclear power plant having a double structure block tank dust collector for processing a conventional nuclear power nuclear waste includes a nuclear power plant from a natural disaster, And the worst situation in the history of nuclear power generation occurred due to the explosion of nuclear reactors or stoppages. In addition to this, it is necessary to meet the reliability of electric power consumers. At the same time, Drilling machine with a certain angle of 45 ° at the upper part of the nuclear reactor building, cutting machine, cutting machine, turning machine, machine cutter, construction machine, crane and conveyor. Connect multiple safety valves to the block piping line with bolts, nuts, gaskets and flanges. As well as a nuclear-waste treatment storage block tank and a radiation-type connection structure are constructed in eight double-structure block tanks of double the size of the reactor building along the circumference of the outer wall of the nuclear reactor building. The nuclear power plant design process of a very serious and dangerous level has emerged to restore the credibility of the electric power consumer. The best nuclear safety and economical global nuclear power plant. Nuclear Radiation Leakage Control of Nuclear Reactor Facilities for Nuclear Reactor Installations The necessity of proper installation of nuclear reactors in distribution tower of double structure block tank reactors has been emphasized and the design and experiment as a solution to safety and economical problem have been continued. At the same time, A dust collector by a block tank nor 5z and 5y so as to provide a restoring the reliability of the power consumer of the reactor of a nuclear power station plant having a supposed to be the reference description.

Referring to FIG. 5G, the inside of a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention is transferred to a nuclear power plant dock (593,594,595) showing the structure of the reactor facility mooring system of a nuclear power plant as a construction machinery to control the hull position movement of a marine hydroelectric power plant floating structure consisting of the upper part of the hull deck (SDU) A large flange connection to a portable lug 607 and a portable lug pin 608 to a pin connection shaft 606. A joint hole machining hole 615. Nuclear hydroelectric power plant construction machine connection structure Mooring-

5G, preferably, the nuclear power plant 811 composed of a floating nuclear power plant (593, 594, 595) nuclear power plant 672 of the offshore and offshore marine power plants and a nuclear power plant main body 1 of the nuclear power plant, The power generating and producing unit 811b includes a dual structure block tank dust collector as a plurality of generators for nuclear waste disposal and power generation of a nuclear reactor facility, The distribution and input device of the power generation and production section 811b is connected to the main body 1 of the nuclear power plant 1 and includes a plurality of generator distribution input devices for generating the marine power station 593,594,595 for the marine power generation, (593,594,595) Nuclear power plant (672) and connection structure inside nuclear reactor facility main body (1) of nuclear power plant Spray nozzle connection port Submarine line wiring (946) Positioned as connection structure with connection structure Nuclear waste treatment Double structure Block tank bridge (929) Combined distribution injecting device and flood control station (593,594,595) Nuclear power plant (672) Mooring control device Providing a connection structure and simultaneous flood control (593,594,595) Nuclear power plant (672) Facility Is a connection structure inside a marine power plant at each point of a floating deck deck deck which is provided as a connection structure of a position shifting distribution dispenser. A double structure block tank is a double structure block tank of a nuclear detonation type inside a deck deck. (593,594,595) Nuclear power plant (672) facilities of the offshore power plant of the power plant of the reactor facility are installed inside the nuclear power plant (672), the offshore wind power plant (957) and the ocean seesaw hydroelectric power plant (943) A nuclear power generator 772 provided outside the wind turbine 957a for the environmentally friendly wind power generator and a double structure block tank dust collector 794 for controlling the nuclear radiation leakage for the deck deck interior, Transformers that provide power to the nuclear power plant (811) to each distribution shaft inside the reactor facility main body (1) of the nuclear power plant by providing connection to each line distribution shaft with a connection structure having a fixed connection structure with a large hydroelectric generator And a power transmission unit 811d provided to the reactor main body 1 of the nuclear power plant, the nuclear waste treatment dual structure providing the connection structure with the connection structure of the submarine line injection nozzle and the submarine line wiring 946 Block tank pipe bridge (929) Combined distribution input device It is a connection structure of a plurality of marine power generation devices and a distribution input device of floating marine type mooring device. (593,594,595) of nuclear power plant (672) of nuclear power plant and nuclear power plant (811) of nuclear power plant (811b) The dual structure block tank dust collector is equipped with a plurality of generators for nuclear waste disposal and power generation of the nuclear reactor facility, and the power generating and manufacturing section (811b) constituting the connecting shaft reactor facility distributes and inputs nuclear power plants. ;

As shown in FIG. 5G, the electric power production and manufacture of the nuclear power plant 811 composed of the floating power plant (593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant (811b) Power generators equipped with multiple generators for power generation Power generation and distribution unit of the connection axis Power generation and distribution unit of the manufacturing division (811b) Replacement of marine power generation units (593,594,595) A distribution input apparatus constituting a large hydroelectric power plant 944 connection structure of a marine Seisoh hydroelectric power plant 943 constituting a nuclear power plant for a plurality of power generation apparatuses is provided for the power generation and power generation (944) of the large-scale hydroelectric generator Seiso hydroelectric power plant (944) of the marine seisio hydroelectric power plant (943) A large hydraulic power generator body of the Shizuo hydroelectric power plant 943 is connected to a head tank 189 for a pressure tank located above the top of the barge and a reducer 35 A plurality of inlet pipes 191 are connected to the upper end of the marine sheath hydroelectric power plant 943 and the discharge port at the rear of the head tank 189 by a connection structure with the head tank 189, The pump aberration 943a of the turbine 267 and the Pelton aberration 943b of the turbine 267 to the lower part of the body of each of the large hydroelectric generator seiso hydroelectric power plant 944 which are located in the interior of the Shizuo hydroelectric power plant 943 have a Francis turbine 943c ) And the discharge port (270) at the rear of the water supply port (269), and at the same time, the hydro-electric power generation distribution input device in the ocean is equipped with the flow velocity of the current, Flow rate conversion with mechanical energy A tower crane that performs a vertically rotating operation with a large hydrostatic generator shear facility 944 having a sheath center shaft frame 673 that provides mechanical energy conversion to an inlet pipe 191 in the form of a hydraulic pipe riser 35 (593,594,595) nuclear power plant 672 of a marine power plant and a nuclear reactor main body 1 (1) of a nuclear power plant, which are equipped with a large hydropower distributing and inputting apparatus which is provided with a seesaw crane boom stand A large hydropower distributing and dispensing device is installed in the inside of the nuclear reactor to further operate the nuclear reactor;

As shown in FIG. 5G, a large-capacity hydroelectric generator seesaw facility 944 for further constructing the reactor operation of the nuclear reactor is provided with a rotational speed detector for hydroelectric power generator for providing a position at the top of the center of the rotational shaft 944q An exciter 944b for a dc generator that supplies current to the motor field coil of the alternator providing a position at the lower end of the hydrostatic generator rotational speed detector 944a, A rotary shaft 944i of the low speed cooler and a rotary shaft 944e of the low speed cooler are connected to the ring gear 944c and the upper rotary bearing 944d and the rotary bearing 944e, the stator coil 944f, the stator frame 944g, The braking device ring 944j and the jack 944k of the braking device and the low-speed rotary shafts 9441 are positioned at the upper end of the central portion of the rotary shaft 944q, and at the same time, the large hydrostatic generator seesaw facility 944 is connected to the rotary shaft 944q The connection structure The power generation assembly is provided with the turbine 267 for turbine hydraulic power generation unit, the turbine rotary support 944n, the casing 944o, the guide vane and the impeller 944q, The kinetic energy possessed by the water is converted into mechanical energy to the introduction pipe 191 having a pressure tube shape of the pressure reducer 35 as a mechanical energy. In the large hydraulic power generator sheathing plant 944, A seesaw crane boom zone 942 of a tower crane that provides a central shaft frame 673 to perform a vertical rotation operation to a large hydroelectric generator seesiter 944 having a multi-stage entrainment type man- (593,594,595) of a marine power plant with a connection structure of a power generation plant to produce power by arranging a large-scale hydropower generator installation device. To make the operation more efficient;

As shown in FIG. 5G, the electric power production and manufacture of the nuclear power plant 811 composed of the floating power plant (593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant (811b) dual structure block tank dust collector is provided as a plurality of generators for nuclear waste disposal and power generation of a nuclear reactor facility, and a power generation and production section 811b and a nuclear power generation facility section 811 The distribution input device of the power transmission portion 811d provided with the power transmission transformers is provided with the power generation and production portion 811b of the large hydroelectric generator seesaw facility 944, And the power transmission unit 811d are connected to the inside of the reactor installation main body 1 of the nuclear power plant as the deck deck reactor installation dual structure block tank dust collector 794 of the marine nuclear power plant The power generation and production unit 811b is provided with a distribution power supply unit for generating a large power generation capacity of 1,000,000w / h at intervals of 10km, A connection structure including a hydroelectric generator seeside facility 944 and an environment friendly wind power generator windmill 957a controls power supply to the transformers 96 of the large capacity substation and simultaneously transmits power to the connection structure of the transmission line 775 In the steel tower 776, a predetermined amount of generated power is supplied, and the generators provided in the respective connecting structures are connected to a plurality of marine power plants by a nuclear waste treatment dual structure block It is possible to supply a certain amount of generated power to the distributing and loading device connecting structure in the process of connecting the large flange 614 of the tank pipe bridge 929, The lever block 123, the chain block 648, and the turnbuckle 850 are connected to a dual structure block (not shown) (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Internal connection structure of submarine line injection nozzle connecting port and submarine line wiring (946) And the dual structure block tank bridge bridge (929) joint distribution dispenser is provided with a large hydrostatic generator seisior facility (944) having a multi-stage entrainment type manometer (902) of a tower crane, and a device for generating electrical energy to provide a power generation facility. 593,594,595) Large hydropower distributor and dispenser is installed inside the nuclear power plant facility to make the operation of nuclear power plant more effective;

As shown in FIG. 5G, the electric power production and manufacture of the nuclear power plant 811 composed of the floating power plant (593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant The double structure block tank dust collector of the power transmission unit 811d provided as transformers for transmitting the power of the power generation unit 811b and the nuclear power generation facility unit 811 is provided with a plurality of generators for nuclear waste treatment and power generation (593,594,595) of a marine power plant is connected to the reactor main body (1) of a nuclear power plant, and is connected to a power generating and producing unit (811b) A vertical partition wall 605, a horizontal partition wall 609, a diaphragm manhole 610, a manhole cover 152 and a hatch cover 153 are connected to the line partitioning and charging device for electric power supply. Reactor facility And the hydraulic cylinder door 624 is provided as a connection structure in the hatch cover 153. The dual structure block tank 598 is provided with a distribution unit connection structure lever block 123, a chain block 648, (850) and connected to each other horizontally, or a connecting structure for providing a nuclear reactor main body, a nuclear waste treatment dual structure block tank bridge 929 (see FIG. 9) is installed in consideration of the lateral loads of the floating- (593,594,595) nuclear power plant (672) inside the nuclear reactor plant main body (1) of the nuclear power plant which has the height of 1.5 times the width of the pipe bridge (929) Nuclear waste disposal system for dredging and diving buoyancy control system and nuclear waste disposal system and reactor facility safety operation of nuclear reactor facility At FUJI nuclear power plant (811) Disassembly and disassembly in the marine vessel manufacturing factory of the power transmitting portion 811d provided with the transforming devices for transmitting the power to the power producing and producing portion 811b of the nuclear power generating facility 811 with the connecting axes of the bales 705 It is preferable to include them as possible connection structures,

Referring to FIG. 5H, a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is installed inside a nuclear reactor main body 1, A lateral side view configuration of a disaster prevention apparatus showing a configuration of a disaster prevention apparatus constituting a plurality of elementary marine nuclear power plants showing the side of the disaster prevention apparatus showing the construction,

(593,594,595) nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and nuclear power plant main body (1) nuclear power generation facility part (811) electronic control device A distributing and charging device for a connection shaft disaster control device for constituting a distributing and inputting device for a production equipment device in a block tower is connected to the electronic control device construction machine control part 811f (593,594,595) of the offshore power plant is connected to the connection shaft of the nuclear power plant facilities. The distribution input device for the disaster prevention device, the lifting device and the production facility equipments includes the auxiliary power plant of the marine power plant (593,594,595) (1) of the reactor facility main body (1) Submarine line injection nozzle connection Submarine line (946) (SDU) at the upper end of the deck deck of the holding tank upper barge hull 591 at the upper part of the SDU, the upper end of the deck deck includes a machining hole 615 for connecting the isosceles- The nut 25 and the washer 26 provide the connection of the equilateral hexahedron 839 with the spanner hand tools but the connecting shaft of the nuclear power plant equipment is connected to the seesaw crane boom of the tower crane for position- The block unit block steel towers 116 provided with the respective connection structures are inserted into the lug processing holes 20 of the block unit block steel towers 116 to be engaged with the shackles 23 of the position adjusting and moving device, The nuclear power plant facility is provided with a block unit block pylon 116 by assembling and transporting a block unit block pylon 116 to a seesaw crane boom block 942 of a tower crane, , An emergency step 631 is provided, The emergency stairs 631 provided at the step of the block pylon 116 are installed to the position of the bollard 638 of the lower steam airship 589 of the mooring tower 644, The emergency stairs 631 of the connecting device structure may be installed at the position of the overhead crane 651 and the elevator altitude 632 to the lower center portion of the lower end portion of the airship 589, The location of the four decks includes a block unit boom with a connection structure of 500m in height, and several seismic crane boom units (942) of crane provided at the bottom of the sea, (593,594,595) Nuclear power plant reactor main body (1) Submarine line wiring (946) Nuclear power plant with connection structure Nuclear waste treatment to establish the location Dual structure block tank pipe bridge (929) The block unit block of the equipment that is provided as a connection structure to protect the floating mooring operation by the connecting structure is equipped with the emergency stairway (631) in the steel tower (116), and the marine power station's lifeline (593,594,595) Nuclear waste treatment Double structure Block tank bridge (929) Joint distribution Discharging device Connected shaft connection structure Floating station Joint operation Operation protection Nuclear power plant (811) Electronic control equipment Construction machinery control unit (1) 811f) Distribution facility for disaster control equipment consisting of a disruption device, a lifting device and a production facility device for the block tower;

As shown in FIG. 5h, the connection structure of the marine power plant with the lifting plant (593,594,595) of the nuclear power plant is connected to the nuclear power plant (811) of the block steel tower, and the electronic control equipment construction machine control unit (811f) The distribution dispensing apparatus for the apparatus includes an atomic power generation facility unit 811, an electronically controlled apparatus (not shown) which constitutes a connection shaft connection structure of a nuclear power plant facility for providing disaster prevention water delivery to a top position of an upper end block tower 117 of the mooring tower 644, (811f) A distributing and inputting device for the disaster control device includes a supporting tank upper barge hull (591), a connecting structure at the upper deck deck, a high pressure multi-stage multi-stage disaster prevention pump (8) Pressing on the main switch button (66) of the main switch button (66) for the starter switch button of the high pressure multi-stage emergency protection pump (8) into the machine room will perform the pump operation Or when the main switch button 66 is manually depressed to the off-time main switch button 66, the pump operation is stopped. However, the high pressure multi-stage disaster prevention pump 8 is stopped by the double structure disaster prevention hose 9) and the disaster prevention water (7), the disaster prevention water (7) is discharged to the fire prevention disaster double structure pipe nozzle (10) Dispensing device The dispensing device for the disaster control device of the construction machine control section (811f) is provided with a fire prevention disposal double pipe nozzle (10) for mounting transportation equipment and a fire prevention disposal double pipe nozzle (10) and the water supply pipe connection Fixed fire prevention disaster prevention double structure pipe Connection line of the nozzle (10) Wire rope (19) and connection device Shackle (23) The airship 78 and the radio sonde 134 (10) Protection connection wire rope (19) and double structure of gas transportation which is lighter than air Discharging hose (9) Connected to the inside of the connection shaft The disaster control apparatus production facility apparatuses of the connection axis electronic control apparatus construction machine control section 811f of the nuclear power plant facility are provided with the high performance underwater pump 36 and the air (80) is provided with a connection structure of a disaster control device by means of a top connection structure of a floating deck deck deck, or a distribution input device for disaster control device of a connection axis electronic control device construction machine control section (811f) of the nuclear power plant facility The equipment is installed as a connection structure with a connection structure of submarine line wiring (946) into the nuclear reactor main body (1) of the nuclear power plant. Nuclear waste treatment double structure block tank bridge 929) Coupling dispenser The emergency unit (631) is installed in the block tower block (116) provided in the connection shaft connection structure equipment provided with the emergency stoppage devices or the production facility devices to protect the flood prevention device. (593,594,595) Nuclear power plants and nuclear reactors of nuclear power plants (1) Nuclear waste treatment Double structure block tank bridge (929) Installed with floating soundproofing device (811) Electronic control equipment Construction machinery control unit (811f) Disconnection unit, lifting unit and production facility Equipment for distributing equipment for equipment to block tower connection And a distributing and inputting device for the shaft disaster control device as a connection structure capable of disassembling and coupling at a marine ship manufacturing factory.

(593,594,595) nuclear power plants (672) of the offshore and offshore marine power plants equipped with the reactor structure of the nuclear waste disposal double structure block tank dust collector of the nuclear power generation facility unit (811) and the nuclear power plant The facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the reactor facility main body 1 are such that the facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power generation facility section 811 are the same as those of the floating nuclear power plant 672 of the marine power station, Nuclear waste treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus having nuclear reactor radiation leak control dual structure block tank dust collector 794 inside nuclear reactor facility main body 1 of power plant A plurality of nuclear reactor facilities are connected to a marine anti- The installation of the tank barge and the distribution of the nuclear power plant 811 at the top of the sea level 40 m above sea level, Nuclear reactor leak prevention control system that prevents multiple nuclear reactors of nuclear power plants from exploding Nuclear reactors leak safety control system to prevent nuclear plant explosion Structure Block Tank Dust Collector (794) Configured to operate nuclear reactors at reactor facilities;

As shown in Fig. 5H, in the facility of the disaster prevention device of the nuclear power generation facility 811 constituted by the floating plant (593,594,595) nuclear power plant 672 of the marine power plant and the connection axis of the reactor facility main body 1 of the nuclear power plant, The facility of the disaster prevention apparatus includes a dual structural block tank dust collector 794 for controlling the nuclear radiation leakage constituting the nuclear power plant 672 of the ocean power plant, the nuclear power plant 672 of the marine power plant, (937) The bridge shaft disaster prevention system equipped with connection structure capable of disassembling coupling shaft is composed of a floating nuclear power plant (593,594,595) nuclear power plant (672) and a nuclear power plant reactor main body (1) ) And the disaster prevention apparatus are equipped with a stork of a superpower and a weak station composed of a leader of a superpower in the inside of the connecting shaft of the reactor main body (1) of the nuclear power plant In addition to providing facilities for disaster prevention in a more environmentally friendly environment, the facilities of disaster prevention equipment should not fall down to imitate the staggering steps of the storks, The equipment of the disaster prevention device of the connecting shaft which imitated the step and the crotch is not damaged by the gap of both legs of the sutra is provided and the leader people of the international society are distributed to the land The dismantled material tanks, bombers, bombs, bullets, satellites, missiles, nuclear bombs and rocket bombs are equipped with disaster prevention equipment for the connecting shafts that do not conduct manufacturing experiments on land. We have set up the codes and norms to provide facilities for disaster prevention to overcome the punctured global economic crisis, The facility of the re-installation apparatus is provided with a facility for installing a disaster prevention device for a connection shaft that can save the world economy by fostering an environment friendly non-polluting energy industry using electric power, and at the same time, The facility of the disaster prevention device of the connecting shaft which makes the sinking accident of the sailing vessel impossible to occur without any further casualties even if the ship's sinking accident often occurs while the weather condition of the bad condition and the bombing state are sailing, With the ship of lifesaving device in accordance with the 3D image design of the ship, it is necessary to prepare the mission according to the rights and obligations according to the establishment of the new federal state of Northeast Asia, and at the same time, the facilities of the disaster prevention device are located inside the steelworks The furnace 948 is provided, and the reprocessing is provided in the reactor main body 1 of the nuclear power plant with the heavy equipment of the construction machine, The connection axis of the disaster prevention device of the nuclear power generation equipment division (811) is composed of the mooring device and the diving buoyancy control device formed in the marine power plant flood control console (593,594,595) nuclear power plant (672) Pre-operation Nuclear Radiation Leakage Control in Nuclear Power Generation Facilities (811) Before Operation The double structure block tank dust collector (794) is connected to the disconnection device inside the connecting shaft. .

Referring to FIG. 5i, an internal structure of a reactor installation 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to an embodiment of the present invention includes a bottom natural gas Production of manganese nodules from seafloor mineral resources showing the operation mode of subsurface submarine development into the reactor main body (1) of an elemental nuclear power plant showing a scene in which a crude energy resource and a manganese nodule as a submarine mineral resource are shown in side cross- A strapless configuration of the scene providing the image,

Referring to FIG. 5J, an electronic control regulating device construction machine controller 811f of the nuclear power generation facility 811 is installed inside the nuclear reactor facility main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. ) Is a side view in which the natural gas or crude energy resources of the bottom of the seabed and the manganese nodule, which is a submarine mineral resource, are produced by the tower crane Seisoka Crane Boom Zone (942) The nuclear power plant (811) is installed inside the reactor main body (1) of the nuclear power plant which provides the production of the submarine mineral resource manganese nod that shows the construction of the operation mode of the floating submerged submarine development inside the nuclear reactor main body (1) An electronic control adjusting device construction machine control unit 811f of the electronic control unit,

Referring to FIG. 5K, an electronic control unit construction machine control unit 811f of the nuclear power generation facility 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. ) Is a side view in which the natural gas or crude energy resources of the bottom of the seabed and the manganese nodule, which is a submarine mineral resource, are produced by the tower crane Seisoka Crane Boom Zone (942) A tower crane that shows the construction of the operation structure of the underwater submarine development facility inside the reactor facility main body 1 of the elementary nuclear power plant shown in FIG. 1. The submarine crane boom base 942 of the nuclear power generation facility 811 The side construction of the scene consisting of the control regulating device construction machine regulator 811f,

As shown in FIGS. 5I and 5J and 5K, preferably, the nuclear power plant of the marine power plant and the reactor main body 1 of the nuclear power plant 1, the nuclear power generation facility 811 of the marine power plant, (811f) The disaster prevention control distribution dispensing apparatus of the connection shaft constituting the dispensing and dispensing apparatus of the disaster prevention apparatus, the lifting apparatus and the production facility apparatus in the block steel tower comprises the disaster prevention pump control system and the control system (150) The electronic control distribution and input device of the fire fighting and disinfection operation machinery room is located in the main body of the reactor facility (1) of the nuclear power plant (593,594,595) of marine power plant, the submarine line injection nozzle connection, submarine line wiring (946) (8) and a connection structure (8) to provide a position to the interior of the machine room connection structure. The emergency fire control electronic control device of the multi-stage pump control panel control box (2) of the spring type multi-stage pump control panel is positioned as an internal connection structure of the electronic control facility operation control box (2) of the control system for operating the electronic control facility (1), a pump internal check valve (5), an internal check valve (6) for preventing backflow of the pump, a nipple (110) for connecting the air hose, A fixed frame 11 for fixing the position of the multi-stage disaster prevention pump 8, the fire hose 9, the fire disaster prevention pipe nozzle 10 and the multi-stage multi-stage disaster prevention pump 8, and a detection sensor 12 The electronic control unit connection structure of the nuclear power plant equipment is provided with an overcurrent (electric current control unit), which is provided as an internal connection structure of the control box 2 of the power source power source 46, The breaker breaker 61 and the power source section 62, the inverter 47 for the electronic control unit, the inverter VCO 48, the access pointer 49, the monitor 52 of the internal control server 51 of the Internet network 50 and the control board 53, And a rechargeable battery 37 having a connection structure with the wireless communication control module 55 of the short-range wireless communication device and the wireless communication antenna 54 and the wireless communication control module 55 of the short- The fire-fighting and emergency electronic control devices of the nuclear power plant facility are connected to the display 56 and the electronic control unit ADIC 57 and the electronic control unit MCU 59 of the switch input circuit 58 and the DAC A main switch button 66 for the start switch button and an auxiliary switch button 67 for setting the positions of the analog input 64 and the digital input 65 of the display screen 63 to the electronic circuit connection structure, Computer Input for Display Input (68) and Current It is possible to provide a position as a connection structure between the name plate 69, the memory 70, and the power supply power line 71 of the pressure setting value, which is the set pressure value of the pressure value, The power energy source 46 provides power to the electronic control devices of the fire fighting and disinfection operation machine room and supplies the power to the nuclear power plant of the marine power plant (593, 594, 595) (946) as a connection structure Nuclear waste treatment to provide a connection structure Dual structural block Tank tube bridge (929) Combined distribution input device Floating control device Provided with connection structure to protect the disaster prevention and production facility equipment And the electronic control unit of the disaster prevention operation machine room of the nuclear power plant facility, and the electronic control unit connection structure, the floating structure of the marine power plant (593,594,595) atom (1) of a power station and a nuclear power plant, and an electronic control device line distributing and inputting device of a fire-fighting disaster prevention machine room. Nuclear power generation equipment section (811) Electronic control adjusting device Construction machinery control section (811f) Disaster prevention device and lifting device And a connecting device for distributing the input and output devices for the production equipment to the block steel tower. Dispersing control distribution dispensing device To constitute the operation of the reactor plant of the nuclear power plant;

As shown in FIGS. 5I and 5J and 5K respectively, the nuclear power generation facility 811 of the nuclear reactor facility main body of the nuclear power plant, the connecting shaft connection of the electronic control adjusting apparatus construction machine control section 811f of the floating nuclear power plant (593,594,595) (593,594,595) of the marine power plant is connected to the inside of the reactor main body (1) of the nuclear power plant, and the electronic control of the fire fighting and disinfection operation machine room A safety valve 258 and a low pressure shutoff valve 83 for an electronic control unit and a safety valve 258 of an emergency valve 84 and a pressure reducing valve 85 are connected to the connection structure of the piping 89 having the apparatus and the line dispensing device. The bolts 24 and the nuts 25 and the washer 26 and the rubber packing 32 of the gasket for piping connection are connected to the gap 15 of the pipe connection flange 28 of the pipe 89, Each having a connection structure, but at the same time, the connection of the pipe 89 The first pressure check sensor 86 and the second pressure check sensor 87 and the bypass pipe line 89 for piping connection of the electronic control unit 88 and the collecting tank 34 to the reducer 35 And a connection structure to the tee elbow 44 of the elbow with piping connection. In the piping 89, the disaster prevention water 7 of the fire control and disaster control equipment is stored, The main switch button 66 for the start switch button of the connection shaft multi-stage emergency protection pump 8 of the mechanical control unit 811f and the emergency switch auxiliary switch button 67 for spraying the disaster prevention water, (593,594,595) Nuclear Reactor Facilities of Nuclear Power Plant Nuclear waste treatment facilities that provide the connection structure of nuclear power plant with submarine track wiring (946) as connection structure inside the main body (1) Double structure block tank bridge Bridge (929) Dispensing injectors To protect the flooded disaster and production facilities (593,594,595) of the marine power plant and the nuclear plant main body (1) of the nuclear power plant as the connection structure of the electronic control device of the fire fighting and disinfection operation machine room and the line distribution input device in the equipment provided as one connection structure, Electronic control equipment for fire fighting and disinfection operation machinery room Nuclear power generation equipment (811) for line distribution input equipment Electronic control equipment Control unit for construction machine (811f) Discharging device and lifting device for production equipment facility Disassembly control Dispensing injecting device that constitutes the connecting shaft Discharge Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Operation;

As shown in Figs. 5I and 5J and 5K respectively, the lifting device of the construction machine control part 811f, the lifting device of the connecting shaft of the marine power plant constituting the distribution input device for the lifting device and the production equipment device 593,594,595) Fire-fighting and disaster control device with connection shaft connection structure of reactor main body (1) of nuclear power plant In the distribution dispatching device for operation of nuclear power plant facilities, Discharge pump (8) Connection structure with connection structure to fore part The pipe connection detour line of the water collection tank (34) is connected to the reed switch (35) and the tee elbow (44) of the elbow with piping connection. The disaster prevention water 7 of the fire fighting and disinfection control equipment is stored in the piping 89 of the connection structure of the power plant facilities or the disaster prevention water of the fire prevention disaster control equipment of the fire prevention disaster control pump 8 7) and When the main switch button 66 for the start switch button of the high pressure type multi-stage disaster prevention pump 8 is depressed by hand at the position of the on-time main switch button 66, the operation of the pump is performed, If the user pushes the off-time main switch button (66) by hand, it stops the operation of the pump. Also, the connection structure of the nuclear power plant equipment Before and after the operation of the high pressure multi-stage emergency protection pump (8) (33) is provided with a high performance submerged pump (36) for piping connection and connection structure helicopter (647) having a connection structure, a claw (13) for an electronic control device for providing a mounting position on the body, The connection structure is constructed such that the disaster prevention water 7 having the internal water pressure of the double structure fire hose 9 for providing the position as the connection structure for the forward part of the fire fighting disaster prevention double structure nozzle 10, Before and after Stage multi-stage disaster prevention pump 8 while simultaneously performing the operation of the pump by manually pressing the switch button 66 at the position of the on-time main switch button 66 of the start switch button of the high-pressure multi-stage emergency protection pump 8, The connection structure provided in the body is provided with a suction suction pipe 3 and an outlet pipe 4 for electronic control and an internal high pressure shutoff valve 5 and an internal pump check valve 6 and a solenoid valve 76 The disaster prevention water (7) having the water pressure of the connection structure of the nuclear power plant facility is provided to move to the position of the fire prevention disaster double structure nozzle (9) through the pipe, (1) Nuclear waste disposal Double structure block tank bridge (929) Internal disconnection structure of fire fighting and disaster control equipment facility providing location equipped with submarine track wiring (946) It is possible to equip the equipment with the connection structure to protect the teeth and the production facility equipment and the electronic control device line dispatching device of the fire fighting and disinfection operation machine room or the connection structure with the water pressure of the connection structure of the nuclear power plant. (593, 594, 595) nuclear power plant and a nuclear reactor plant main body 1 of a nuclear power plant, and electronic control device line distributing and inputting devices of a fire fighting and disaster prevention machine room, a nuclear power generation facility 811, ) Disconnecting device for disaster prevention device, lifting device, and production facility device Connection shaft that constitutes a block tower A disruption control distribution dispensing device To constitute the operation of a reactor plant of a nuclear power plant;

As shown in FIGS. 5I and 5J and 5K, the distribution input device of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power plant and the inside of the reactor facility main body 1 of the nuclear power plant, Distribution system of mineral resource collection equipment as a connection structure Moving device Construction machinery connection structure to a location equipped with a submarine line wiring (946), and distribution of the mineral resource collection equipment on the seabed, The diving control device connecting structure provided with a connection structure for enduring the flow velocity of the deep sea bed The connecting structure of the Bell-rotor butterfly valve 305 and the diving control device connecting structure doctor ventilation 585 The doctor ventilation inlet 585a and A distribution type injection device of the nuclear power generation facility unit 811 is provided with a direct conduit type 581 and a base type conduit type 582 through a doctor ventilation outlet port 585b, A single-force automatic pneumatic instrument device provided with a micro-switch 580 while being provided with the pressure air generated by the air compressor 80 is set to the time limiter 541 by an overpressure prevention scale indicator, Pressure air is injected into the air cylinder 138 as a connection structure to the fire damper 583 automatically while the damper spindle 584 is connected to the fire damper 583 inside the doctor ventilation 585, And the distribution device of the fire damper 583 is provided with devices for controlling the interruption and supply of the air, but it is also possible to provide a device for controlling the supply of air to the pipeline automatic pneumatic conveying device 916), a connection structure such as a ballast butterfly valve (305) of a diving control device of a pipeline is provided, Configuration be made to the reactor equipment body (1) of a nuclear power plant to control the dive control device of formula dock reactor equipment of a nuclear power plant body (1) and;

The double structure block tank dust collector of the nuclear power plant 672 of the offshore and offshore marine power plants and the reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant is connected to the nuclear waste treatment pipe manufacturing process 705 of the reactor facility, The diving preparatory operation control regulating control dispensing device for the hull safety equipment,

As shown in FIGS. 5I and 5J and 5K, the distribution input device of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power plant and the inside of the reactor facility main body 1 of the nuclear power plant, The solenoid valve overpressure prevention switch 108 and the solenoid valve start switch button main switch button 66 of the respective solenoid valves 76 provided with the pressure air generated in the air compressor 80 of the prime mover are turned on When the main switch button 66 is manually depressed, the butterfly valve 305 is opened and pressed by hand to the off-time main switch button 66 of the main switch button 66, the butterfly valve 305 When the connection structure is completely closed to provide an operation interruption or when the main switch button 66 for the start switch button is manually depressed to the on-time main switch button 66, the connection structure of the butterfly valve 305 is expanded to open the air In the compressor (80) And a plurality of hatch covers 154 and a plurality of hatch covers 153 are connected to each other through a pipeline line structure, and at the same time, The solenoid valve overpressure prevention switch 108 and the butterfly valve 305 connection structure of the solenoid valve 76 of the reactor installation main body 1 are configured to perform an operation;

(593, 594, 595) nuclear power plants 672 of the offshore and offshore marine power plants and the reactor facility main body 1 of the nuclear power plant 1, the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5I, 5J and 5K, The dual structure block tank dust collector is installed in the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility. The diving process preparation control operation of the diesel-electric power generation facility for the hull safety facility comprises the steps of: The distributing and inputting device is provided with an operation for rotating the hydraulic control rotary cylinder 35 for electronic control as a connecting structure between the floating plant control nuclear power plant 672 of a marine power plant and the nuclear reactor plant main body 1 of a nuclear power plant, A plurality of fire doors 154 and a plurality of hatch cover 153 connection structures are opened so that the mineral resources provided at the seabed mineral collection site are located inside the holding tank lower barge hull 592 The vacuum pump 635 for the transport lifting device and the power cable 71 are connected to each other in the empty space by the connection structure, and the distribution input device of the nuclear power generation facility 811 is connected to the main switch for the start switch button The vacuum pump 635 is rotated by manually depressing the on-time main switch button 66 of the button 66. The distributing and inputting device of the nuclear power generation facility unit 811, Mineral resources provided at the seabed mineral collection site located outside the body of the ship 592 is a connection structure for providing a positional movement to the inside of the body of the upper tank barge hull 591 of the holding tank, (35) hull safety equipment for electronic control;

As shown in Figs. 5I and 5J and 5K respectively, the distributing and inputting apparatus for operating the seabed mineral collecting construction machine as a connection structure of the nuclear reactor main body 1 of the floating power plant of the marine power plant, Diving position control device connection structure diving buoyancy control buoy (206) is selected as the connection structure to replace the submarine mineral resource connection structure to provide hull safety equipment, or to adjust the diving position of the hull, The submerged minerals are installed at the upper part of the sea surface (SLU), the upper part of the ship's deck (SDU ) Top location Offshore power plant with location as connecting structure Separate towers Replacement tower Cranes Seiso Crane Boom area (942) Connection structure Configuration be made to the mooring device and the reactor equipment main body 1 of the support sikdok nuclear power plant of the marine power plant by the connection structure arranged on the sea bed mineral gathering place in power generation equipment with a connecting structure to the distribution chute for a construction machine operation, and;

As shown in FIGS. 5I and 5J and 5K, the connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593, 594, 595) The mineral resources of the distribution input device for operation of the submarine mineral collection and construction machine are as follows: the submerged structure of the connecting structure of the hull in the empty space of the body of the lower tank barge hull (592) And the submarine mineral resources for controlling the diving buoyancy are replaced by the submarine mineral resources of the hull, and a plurality of fire doors and a plurality of hatch covers 153), a connecting structure connecting shaft having a connection structure to a pipeline automatic pneumatic conveying device (916) passing through the pipeline, and a bellows The connection structure of the solenoid valve overpressure prevention switch 108 of the connection structure solenoid valve 76 and the main switch button 66 of the solenoid valve start switch button while having the connection structure with the butterfly valve 305 is connected to the power line 71) The connection structure is provided and the marine power plant is installed in the nuclear reactor plant. (1) The inside of the nuclear reactor plant is replaced with a tower crane. The tower crane is connected to the crane boom zone (942) (SLU) Floating upholstery on the deck (SDU) Upper part of the deck (SDU) Upper part of the marine power facility to provide the position as a connection structure Separate float Replacement tower crane seiso crane boom (942) connection structure Power generation equipment with mooring device and connection structure (593,594,595) of the nuclear power plant (673), diving buoyancy control devices and nuclear waste disposal facilities installed in the nuclear power plant (672) of the marine power plant. Disassembly and Dismantling Equipment Reactor Facility Safety Operation Before the Fusi Nuclear Power Plant (811), the connection shaft of the nuclear waste disposal pipe manufacturing process (705) of the reactor facility is connected to the disassembly- As shown in FIG.

As shown in Figs. 5I and 5J and 5K respectively, the lifting device of the construction machine control part 811f, the lifting device of the connecting shaft of the marine power plant constituting the distribution input device for the lifting device and the production equipment device 593,594,595) Fire-fighting and disaster control equipment with connection shaft connection structure of reactor main body (1) of nuclear power plant The operation distribution dispenser of nuclear power plant facilities is equipped with disaster control water 7) is provided with a plurality of positioning gaps (15) for the position-regulating movement device (10) for providing a position to the fire-fighting disaster prevention double-structure nozzle nozzle (10) The disaster prevention water 7 having the water pressure outside the processing hole 20 is discharged to the outside of the body of the fire disaster prevention double structure pipe nozzle 10 while simultaneously discharging the discharge jet number 38 of the fire disaster prevention control article and the fire disaster prevention control article Big The disaster prevention water 7 of the tangue water film 39 is discharged at a position of the plurality of processing holes 20 at the positions of the linear circular discharge jet 38 and the plurality of processing hole 20 gaps 15, (38) A water curtain (39) is provided in the form of a drop spray, but the flue gas is surrounded by a non-flammable gas to block the supply of air to prevent combustion and to cool down the combustion product to the ignition point temperature (593,594,595) nuclear power plants and nuclear reactor plant main body (1) of the marine power plant, and the main body of the nuclear power plant, Electronic control equipment Line distributing and inputting equipment Nuclear power generation equipment (811) Electronic control control device Disconnection device of the construction machine control part (811f) Discharge device for the lifting device and production equipment device My The distribution system of nuclear power plant of the nuclear power plant is constructed so as to constitute the nuclear power plant of the nuclear power plant, and the construction equipment of the construction machinery control section (811f), the lifting plant of the connection shaft and the ocean power plant constituting the distribution apparatus of the production facility apparatus (593,594,595 ) Fire fighting and disaster control equipment with connection shaft connection structure of nuclear reactor plant main body (1) of nuclear power plant The operation distributing and inputting device of nuclear power plant facilities is required to perform initial evacuation in 1 second or less to the operation distribution equipment of nuclear power plant facilities The ejection number 38 of the fire-fighting disaster prevention control article that provides the initial evolution immediately before the arrival of fire by the fire fighting control 40 of the fire-fighting disaster control article is the disconnection number 38 of the connection structure disaster prevention material 39 of the fire disaster prevention control article The number of the ejection nozzles 38 is set to the number of the machining holes 20 at the position of the gap between the straight circular ejection nozzles 38 and the plurality of machining holes 20 The discharge type injection nozzles 38 of the radiation type emit discharge drops in the form of water film curtains 39. In the nuclear disaster prevention system of the nuclear power plant equipment, the combustion is closed by the incombustible gas, (167), which has a water pressure located inside the body of the fire extinguisher (164) inside the body of the fire extinguisher 109) and the fire-fighting hose body, the fire-fighting disaster prevention water of the nuclear power plant facility which establishes the position as the connection structure is provided with the mixed disaster prevention water mixed with the powdery loess (158) which generates soap bubbles mixed with the fire- The portable wireless communication terminal 82 of the high pressure type multi-stage disaster prevention pump control system 150 in the disaster prevention pump operation machine room and the safety control room and the disaster prevention pump operation control (66) and a connection structure for providing disaster prevention water spraying power supply power supply control box is connected to the safety control room and the disaster prevention pump operation machine room The coupling 29 for piping connection is provided with a connection structure of the coupling body 30 and the coupling body 31. The coupling 29 is connected to the fire fighting unit 40 and the helicopter 647 by a double structure fire hose (593,594,595) of a marine power plant by providing a fire-fighting electronic control unit with a fire-prevention electronic control unit at the top of a floating deck deck, Nuclear waste treatment double structure block tank bridge (929) providing a connection structure with disaster prevention nozzle (945) and subsea line wiring (946) as connection structure The emergency step 631 of the traffic device of the block unit block tower 116 is provided as a line dispensing device in the equipment for providing the connection structure for protecting the production equipment devices by the fish-fighting emergency fire control electronic control device, The distributing and inputting device connection structures are provided with a fire control electronic control device inside the nuclear reactor main body 1 of the nuclear power plant, and the mooring device and the diving buoyancy control device formed in the nuclear power plant 672 of the marine power plant floating support (593,594,595) Nuclear waste disposal equipment and nuclear reactor facility safety facility operation Fusi Nuclear power plant division (811) to nuclear waste processing pipe manufacturing process (705) Nuclear power plant nuclear reactor connection facility shaft construction machinery control section (593,594,595) of nuclear power plant (1) Nuclear reactors of the nuclear power plant (1) The fire-fighting and disaster control unit is a connection and disconnection structure of a nuclear power plant. It is composed of a connection structure capable of disassembling and coupling at a marine vessel manufacturing factory.

As shown in FIGS. 5I and 5J and 5K, the distribution input device of the nuclear power generation facility 811 is connected to the internal connection structure of the nuclear power plant 1 of the floating power plant of the marine power plant, (SDU) Marine power plant Seisio crane in a tower crane Replacement tower in a crane Boom in a crane boom area (942) Boom boom in a boom area (652) Boat hook (652) The weather resource basket 842 and the pallet 844 for collecting mineral resources are provided as a connection structure on one side of both sides of the seesaw crane boom girder 942 and are connected to a garden basket 842 for collecting seabed mineral resources and a pallet 844) SLD at the bottom of sea level (SLL) as connection structure Upstream levitation of the sea level upper part (SLU) at the submarine mineral resource gathering place inside SDL at the lower part of the hull deck (SDL) The distribution and dispensing apparatus of the nuclear power plant 811 is capable of performing the position shift of the manganese nodule 909 to the position of the upper part of the floating deck hull deck (SDU) by transporting the seabed mineral resource manganese nodule 909, Crane boom zone (942) as well as a marine power plant at the same time. Inside the reactor main body (1) of the nuclear power plant in the submarine mineral resource collection site, the seesaw crane boom zone (942) The excavator 845 and the hatcher erector 877 for the drill for the deep sea excavation equipment prepare the solidified manganese nodule 909 as a manganese nodule 909 for crushing, And the diesel hammer 883 and the steam hammer 884 and the hydraulic crane 885 and the tower crane 886. At the same time, machine( 911 and the mineral collecting and collecting robot 912 are connection structures for adjusting the operation of the excavator and the connection structure of the construction machine to connect the reactor main body 1 of the floating power plant of the marine power plant, It is equipped with a construction machine distribution equipment for operation of mineral collection equipment, and is composed of a number of construction machines (880) for the collection of seabed mineral resources;

As shown in FIGS. 5I and 5J and 5K, the dual structure block tank dust collector is connected to the nuclear waste disposal unit 811a of the nuclear power generation facility 811 of the nuclear power generation facility 811, The nuclear waste treatment of the nuclear power plant equipment constituting the connection axis position of the process pipe manufacturing process 705 constitutes the operation of the nuclear power plant by the distribution input apparatuses and the floating pickpockets 593,594,595 of the offshore and offshore marine power plants, Nuclear power plant nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear power generation facility (811) nuclear power generation facility (811) nuclear power generation nuclear waste treatment unit (811a) (934) of crude oil and natural gas crude oil borehole facilities of nuclear power plant facilities constituting the connection axis position of pipe manufacturing process (705) and nuclear waste In the re-distribution input device, the nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is provided with a submarine line wiring 946 as a connection structure inside the reactor facility main body 1 of the floating nuclear power plant of a marine power plant In the deep seabed mineral resource collecting site, a yard basket 842 for collecting manganese nodules 909 and a pipeline line automatic pneumatic conveying device 916 for a position-and-control mobile device are connected to a suction sampling machine 911 and a submarine mineral resource collection (912) of mining machines for the extraction of drinking water from nuclear power plants (593,594,595) equipped with nuclear power plant (672), the diving buoyancy control device and the nuclear waste disposal unit and reactor installation Before Safety Operation Fusi Nuclear Power Plant (811) Reactor Nuclear Waste Treatment Plant Manufacturing Process (705) Nuclear Power Plant Reactor Facility Connection Shaft Construction Machinery Control Section (811f) (593,594,595) Nuclear power plants Reactor facilities of the nuclear power plant Connection shaft of the nuclear power plant (1) Connection structure of the fire fighting and disaster control device Distribution for operation of nuclear power plant facilities It is preferable to include as a connecting structure capable of disassembling and coupling at a marine shipbuilding factory with input devices.

As shown in Figs. 5I and 5J and 5K, the connection structure between the floating power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant, (909), which is located at the seafloor position connection structure including mineral resource collection equipment, is installed at the upper part of the deck (SDU). The connection structure of the electric magnet magnet 645 and the suction collecting machine provided in the tower crane 886 having the connection structure of the seesaw crane boom frame 942 of the septic tank (632) for the elevator and the float line (591) at the top of the strut tank (591) Connected structures provided at the upper end of the upper deck (SDU) of the hull deck Submarine minerals The reclaiming basket 842 and the connecting structure pallet 844 are transported to the location connection structure of the floating deck hull deck upper part (SDU), while at the same time the submarine mineral collection and construction machine distributor / Mechanical equipment Seagoing Crane Boat (942) for tower crane Replacement of Conveyor (633) at the same time as the connection structure is made up of a submarine mineral resource collection site inside the submarine mineral resource located in the lower part of the deck (SDL) (SDU) to the top of the deck hull deck top (SDU), while simultaneously navigating the submarine mineral collection process to the submarine mineral resource exploration equipment and connection structure search lamp (232) and undersea surveying lens An underwater lamp 843 for a glass is provided with a lighting device for providing a position to a position having a submarine line wiring 946 as a connection structure, (672) of nuclear power plant of nuclear power plant and connection structure inside reactor main body (1) of nuclear power plant of both power plants Inhalation collecting machine and connection structure Mineral collecting robot and submarine mineral resource collecting equipment The above submarine mineral resource collection equipment Each of the lever blocks 123 and the wire rope chains 915 for preventing the loss of collection equipment at the location inside the seabed mineral resource collecting place and the wire rope chains 915 As the connection structure, it is necessary to prevent the loss of the altimeter by connecting the collecting equipments with the alibite (632) for the elevator for submarine diving and the connection structure of the submarine excavation equipment. However, the underwater mineral resource collecting equipment is located inside the submarine mineral resource collection site The lever movement of the lever block 123 can be controlled by controlling the movement of the harness, The wire rope provided on the body of the lick (123) is rolled up and loosened so that the position of the picking equipment can be controlled while the unmanned camera (184) belonging to the submarine exploration equipment is operated to detect the submarine mineral collecting process And an unmanned camera (184) connecting structure for providing a position to a position where the underwater illumination lamp (843) for a submarine surveying lens glass is discharged to the illumination by the submarine mineral resource search equipment and the searchlight (232) , The submarine mineral collection and construction machine operation distribution dispensing apparatus is configured to connect the container box latching device 129 of the container box 132 corresponding to the submarine mineral carrier to the connection state setting screen (SDU) of the upper end of the sea surface (SLU) with the transmission of the status scene of the submarine mineral collection process to the unmanned camera (184) (946) Connections to marine power plants provided as a connection structure Connected to the inside of a reactor facility main body (1) of a nuclear power plant (672) and a nuclear power plant Structure of suction structure (SLU) with submarine track wiring (946) included as a connection structure to the submarine mineral resource collection equipment for machinery and mining robots. SDU Upper part of hull deck (SDU) Hull safety facility control room Internet The submarine mineral collecting process state scene transmitted from the unmanned camera 184 to the monitor 52 of the internal control server 51 of the network 50 and the control board 53 is transmitted and at the same time, And connection structure Mineral resource collection equipment Distribution input The operation equipment distribution is equipped with the construction machinery, In order to withstand the water pressure of the deep sea bed and the flow rate of the deep sea bed, it is necessary to arrange the distribution and input devices for the operation of the submarine mineral collection and construction machine inside the nuclear reactor main body 1 of the nuclear power plant, (705) of nuclear reactor waste disposal pipe manufacturing process at the nuclear power generation facility (811) before the safety operation of the nuclear reactor waste disposal apparatus and the nuclear reactor waste disposal apparatus and the nuclear reactor waste disposal apparatus, As a connecting structure capable of disassembling and coupling at a marine shipbuilding factory.

(593, 594, 595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants and the nuclear reactor main body (1) of the nuclear power plant as shown in each of FIGS. 5i and 5j and 5k, The nuclear power plant nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the facility unit 811 is connected to the dual structure block tank dust collector of the nuclear power plant facility constituting the connection axis position of the nuclear waste treatment pipe production process 705 of the reactor facility The nuclear waste disposal and dispensing apparatus for operation is provided as a nuclear waste disposal and dispensing apparatus for the nuclear waste disposal and dispensing apparatus of the nuclear power plant facility as a nuclear waste disposal unit 811a for distribution facility of the facility protection facility as a connection structure of the nuclear power plant, The sea surface (SLL) of the sea surface (SLL) providing the position to the position having the connection structure submarine line wiring (946) to the interior of the reactor facility main body (1) of the floating power plant nuclear power plant of the marine power plant The reactor main body (1) of the floatation type nuclear power plant having a position at the end (SLU) is a connecting structure at the upper end of the floating deck top deck, and is a block unit for positioning the inside of the reactor main body (1) The bulkhead steel tower (116) has a safety control room which is located at the left-hand side of the upper deck deck of the floating roof of the nuclear power plant. However, many countries with nuclear weapons have a nuclear- Nuclear waste disposal dispenser consisting of reactor main body of nuclear power plant Nuclear waste disposal dispenser equipped with satellite launcher and space rocket launching site satellite and space rocket for nuclear waste disposal device, Earthquakes, tsunamis, wildfires, dust and volcanic eruptions A flood to prevent the damage of ash The equipment management room of the weather forecasting station (958) for observing the weather forecast for the control of the preliminary preventive flood control is provided as a nuclear reactor main body of the nuclear power plant, and the peripheral equipment of the block pylon (116) A helicopter stop 619 for providing a position as a positional connection structure around the upper center of the deck deck, a satellite 962, a satellite launch pad 643, and a space rocket 961 ) 646 of the space rocket launcher 646 are installed in the vicinity of the launch pad 643 and the space rocket launcher 646 to be connected to the satellite launch pad 643 and the space rocket launch pad 646 And a connection structure inside the reactor main body 1 of the nuclear power plant is provided with a connection structure having a submarine line wiring 946, Deck deck top Deck top control Deck control Decks Deck decks to prevent natural reproduction of harmful tidal microbes (921) to provide loess (158) for connection to structures Deck decks Fire fighting control control Soap mixed with cooling water The seabed position where the natural foaming loess (158) of the foaming powder is provided as the upper part of the deck deck deck of the dwelling deck and the harmful tidal microorganism (921) from the seabed is prevented from propagating, The natural loess soil 158 is supplied into the basket 951 as a floating basket 951 and the harmful tidal microorganism 921 is stored in the harmful rust-inhalation dust collector, The natural bottom soil 158 is supplied to the seabed at the lower bottom position of the deck deck body bottom of the floating deck deck although the harmful tidal microorganism 921 is placed at the breeding position The position control device tackle winch 137 and the seesaw crane boom girder 942 and the wire rope 19 and the wire rope chain 915 of the tower crane substituting tower crane are connected to the driving wheel rollers 135 for the position- While the natural loess soil 158 is introduced into the seabed, the moving device tuna winch 137 and the seesaw crane boom bar 942 of the tower crane substitute for crates are positioned and moved while the air compressor 80 ) And a connection type air hose (109) are provided with a net type air hose (109) for supplying oxygen and air to the sea bed, and a fire control control article arrangement for protecting the marine environment is provided, (593,594,595) Nuclear power plant's nuclear reactor facility The marine environment protection facility, which is located at the position of the connection structure inside the main body (1) and equipped with the submarine line wiring (946), is a connecting structure to protect marine environmental facilities around the deck deck (593,594,595) of the nuclear power plant is provided with one distribution and dispensing apparatus connection structure, and the nuclear power plant nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power generation facility unit 811 The nuclear waste treatment for the operation of the nuclear power plants constituting the connection axis position of the nuclear waste treatment pipe manufacturing process (705) of the nuclear power plant of the nuclear power plant constituting the dual structural block tank dust collector is constituted so as to operate the nuclear power plants by the distribution input devices;

(593, 594, 595) nuclear power plants 672 of the offshore and offshore marine power plants and the reactor facility main body 1 of the nuclear power plant 1, the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5I, 5J and 5K, (811a) of the nuclear power plant nuclear waste disposal unit (811a) of the nuclear plant and the natural gas crude oil borehole facility, which constitute the connection axis position of the nuclear waste processing pipe manufacturing process (705) 934) In the nuclear waste disposal dispensing apparatus, the nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is connected to the internal structure of the nuclear reactor facility 1 of the nuclear power plant (593,594,595) The crude oil drilling rig 934, which provides the connection structure with the upper center of the upper part of the floating deck hull deck upper part (SDU) (901) of drilling machine for drilling of crude oil at the nuclear power plant facility, and a drilling machine which is located at the bottom of the ceiling crane (651) A plurality of hydraulic cylinders 623 for drilling to provide a position to the opposite center of the circular table line with a rotating body of the body, The position control device is provided as a rotary table lathe machine 908 by a plurality of keys 623 which are brought into a position opposite to the line center, and the nuclear waste disposal and dispensing apparatus of the nuclear power plant equipment includes a rotary table lathe machine (902), and a plurality of keyboard keys (623) are extended to a central portion of the connection structure (908) A plurality of pipe racks 854 connected to a position of a crude oil borehole 936 for continuously positioning the single pipe racks 854 at a predetermined position and providing a connection structure at the sea floor, The crude oil borehole (936), which is equipped with a connecting structure to provide the position as a structure, is provided with a crude oil borehole (936) by a core drill (917) for excavation, and at the same time, And a pipe rack 854 for connecting the crude drill rods to the wire ropes 19 are provided with a rotary drum drilling machine 908 of a rotary table lathe machine 908 of a drilling machine for crude oil drilling in a drilling machine machine room, A rotary table with a hydraulic rotary cylinder (619) is provided with a plurality of hydraulic cylinders (623) The crude oil borehole dispensing and dispensing device is operated to complete the excavation of the crude oil borehole 936 while simultaneously delivering the crude oil and natural gas discharged from the location of the oil borehole 936 to the replacement tower The seismic crane boom zone (942) of the crane is connected to both sides to provide the nuclear waste disposal site of the nuclear power plant facility. The seismic crane boom zone (942) (593,594,595) connected to the main body (1) of the marine power plant by providing a lift to the top of the marine power plant Connected with the crude oil and natural gas crude oil borehole distribution input device providing the connection structure with the submarine line wiring (964) The nuclear reactor facility main body 1 of the floating feeder nuclear power plant is provided with the structures, The nuclear waste disposal unit 811a of the magnetic power generation facility unit 811 is connected to the nuclear waste disposal unit 811a of the nuclear power plant facility 811a for the operation of the nuclear power plant equipment constituting the connection axis position of the nuclear waste treatment pipe manufacturing process 705 of the reactor facility To constitute the operation of the nuclear power plant by the distribution and dispensing apparatuses;

(593, 594, 595) nuclear power plants 672 of the offshore and offshore marine power plants and the reactor facility main body 1 of the nuclear power plant 1, the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5I, 5J and 5K, (811a) of the nuclear power generation facility (811) of the nuclear power generation facility (811a) of the nuclear power plant equipment constituting the connection axis position of the nuclear waste processing pipe manufacturing process (705) (934) of the crude oil borehole facility and the nuclear waste disposal dispensing apparatus for the deep sea water energy resource and mineral gathering, the nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is provided with a nuclear waste disposal apparatus of the marine nuclear power plant, (1) A deep-sea mineral resource collection site providing a location with a submarine line wiring (946) as an internal connection structure is used to collect manganese nodules (909) A mining robot 912 of a suction sampling machine for submerged mineral resource harvesting 912 and a mining collecting robot 912 for connection of a pipeline line automatic pneumatic conveying device 916 for a positioning mobile device 924) is provided with a connecting structure for establishing a position as a connection structure on both sides of the seesaw crane boom portion 942 of the SLD replacement tower crane. However, the seesaw crane boom portion 942 of the tower crane substituting tower crane, In the vertical rotation operation, the deep-sea energy resource connection axis and the deck deck are lifted up to the top, and the nuclear waste disposal and dispensing apparatus of the above nuclear power plant facilities is provided with a means for supplying the salvaged resources to the nuclear facility of the marine nuclear power plant 1) Internal transport vehicle (254) As a connection structure, transportation equipment supplying material to the industrial site on land. 500m block unit by double structure block tank facility as connecting structure. (1) Internal connection structure of the marine power plant with connected structure to the oceanic power plant with connection structure. (1) Transport equipment with submarine line wiring (946) In the lower part of the deck deck, the equipment of the marine power generation facilities is provided with a connection structure for providing a position on one side of the floating deck deck, and the crude oil and natural gas are collected as the connection structure of the deep sea mineral energy collection device, The borehole distribution and dispensing apparatus connecting structures include a nuclear reactor facility main body 1 of a floating nuclear reactor plant and a nuclear reactor waste treatment section 811a of a nuclear power generation facility unit 811 of a nuclear power generation facility unit 811, The tank dust collector is used for the operation of the nuclear power plant equipment constituting the connection axis position of the nuclear waste processing pipe manufacturing process (705) Nuclear waste disposal involves the installation of nuclear reactors by means of dispensing devices and the distribution and dispensing of offshore power plants with the location of the connection axis of the nuclear reactor main body 1 of the floating nuclear power plant of a marine power plant. It is desirable that the nuclear waste disposal plant is constructed and operated to be operated.

(593, 594, 595) nuclear power plants (672) of the above-mentioned offshore and offshore marine power plants and the nuclear reactor main body (1) of the nuclear power plant as shown in each of FIGS. 5i and 5j and 5k, The diving operation ready controllability control dispensing input device constituting the connection shaft position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility is constructed by dividing the double structure block tank dust collector of the facility unit 811 into the distribution The input device is connected to the upper tank barge hull 591 and the lower tank barge hull 593, which are connected to each other within the reactor main body 1 of the buoyant cooking nuclear power plant of the marine power plant, The high-strength bolts 603 and the high-strength nuts 604 are connected to a large-scale plan (not shown) in the hull safety equipment, (614) a hole for connecting the processing hole (615) to the connecting structure, or a plurality of double structure block tank holding tanks (590) connected to the outer block tank (599) Location Large connecting flange (615) Tank connection to gap clearance (15) Position Rubber packing (32) of gasket for connecting structure Structures are connected to large flange (615) The bolts 603 and the high strength nuts 604 are fastened to the large-diameter flange 614 joining portion hole 615 of the joining structure to form the hydraulic rotary cylinder machine 619 for the positioning device of the distribution input device of the nuclear power plant 811 Hydraulic cylinder machine (624) for transportation equipment and double structure block tank pipe bridge (928) and double structure block tank bridge bridge (937) of nuclear reactor plant of flood control station nuclear plant are connected to the hammer lanch structure. Hydraulic cycle The double structure block tank 598 of the double structure block tank 598 can be disassembled and connected to the cylinder machine 619 and the double structure block tank 598 is connected to the connection structure connection tee elbow 44, A hydraulic rotary cylinder machine 619 for a position adjusting device, a hydraulic cylinder machine 624 for a communication equipment, and a hand tool hammer ranch 624 are provided at the joint portion of the large flange 614, (SDU) of the hull deck hull deck (SDU) of the hull deck center (SDM) and the lower deck hull deck (SDL) of the hull deck hull deck (1) inside the nuclear plant main body (1) of the floating nuclear power plant of the ocean power plant, (SDU) Upper part of holding tank Upper barge hull (591) and holding tank lower barge hull (592) Connecting structure Submarine line wiring (946) Marine power plant to support sikdok cheyong seesaw crane tower crane boom (942) connected to mooring structures and power plants connected to the device structures (593,594,595) configured to be made nuclear power plant nuclear power seolbibu distribution chute (811) and;

(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The operation control regulating and distributing apparatus for the diving operation preparatory operation for the hull safety equipment constituting the position of the connecting shaft of the nuclear power plant 705 includes a distributing and inputting apparatus of the nuclear power generating facility unit 811, (1) The connection structure inside the hull of the hull deck center (SDM) of the ship's upper deck (SDU) at the upper part of the strut tank top barge hull (591) and the float bottom hull deck bottom (SDL) holding tank bottom barge hull (592) A dual structure block tank 598 that provides a location to a location with a seabed line wiring 946 as a connection structure; a submarine mineral resource exploration device external to the connection structure external block tank 599; (843) for the navigation of the deep sea exploration submarine, and the connection structure of the power plant equipment for distributing and supplying the marine power generation power to the location of the submarine navigation submarine (843) The distribution and input device of the nuclear power plant (811) is provided with a repair system of the floating power plant of the offshore power plant as a connection structure of the barge lines for loading harmful tidal control and disaster prevention device, A lamp fixture may be provided at an outer wall of the outer block tank 599 of the plurality of the support block tanks 590 provided at a predetermined interval and may be provided with a joint portion processing hole 615 and a long hole 616 Pin connection Axial connection structure Double-structure block tank with coupling with hydraulic cylinder switch (623) Disassembly of hull Portable lug Connecting bolt (603) Bolt threads 603a and the lug connecting shaft disassembly coupling nut 604 thread 604b are coupled to each other by a hammer lancet hydraulic rotary cylinder machine 619 and are provided with a pin coupling hole 615, It is possible to prevent the detachment of the nut bound to the pin connecting shaft thread 603a. However, the distributing and inputting device of the nuclear power generating unit 811 can provide a stable anti- (593,594,595) Nuclear power plant nuclear reactors (1) Connection structure inside the main body of the nuclear power plant (SDM) Substructured poison hull deck upper part (SDU) and floodgate hull deck lower part (SDL) Upper part (SDU) Upper tanks (591) Upper barge hull (591) Lower tank barge hull (592) Connection structure Marine power generation facility with submarine line wiring (946) Individual crane boom bar Connection structure Mooring device and connection Power generation facility Configuration be made to the connection structure value the reactor equipment body (1) of the flotation plant of the marine power plant sikdok nuclear power plant to the distribution chute of a nuclear power seolbibu 811 and;

(593, 594, 595) nuclear power plants 672 of the offshore and offshore marine power plants and the reactor facility main body 1 of the nuclear power plant 1, the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5I, 5J and 5K, The dual structure block tank dust collector is installed in the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility. The diving process preparation control operation of the diesel-electric power generation facility for the hull safety facility comprises the steps of: (SDU) of the hull deck center (SDM) and the upper deck (SDU) of the deck hull deck (SDL) of the hull deck (SDL) of the marine power plant, (SU) holding tank upper barge hull 591 and the holding tank lower barge hull 592 are connected to each other and provided with a submarine line wiring 946, The double structure block tank combined lug (607) at the upper and lower barge hulls of the lock tank is connected to the horizontal and vertical type coupling structure (607) at each part of the strut tank upper barge hull (591) and the strut tank lower barge hull A horizontal pin connection shaft processing hole 615 having a plurality of processing holes 615 and an elongated hole 616 in the body of the double structure block tank combined lug 607 and a pin connection shaft processing hole 615 perpendicular to the double pin structure shaft, And a plurality of processings (not shown) provided in the vertical structure of the upper end barge hull 591 and the lower barge hull 592, which are connected to the connecting block of the column block tank 590, Removes the block tank hull disassembly-type portable lug pin connecting shaft 606 bound to several processing holes 615 among a plurality of block tank hull disassembly-type portable lug pin connecting shafts 606 bound to the hole 615 Portable tank tank hull disassembly and carrying A block tank hinged with a lug pin connecting shaft 606 and a barge hull 592 of a fixed lifting stand at the upper end of a nuclear waste disposal double structure block tank marine tunnel traffic device 941, A diving position adjusting movement device for a hull and a diving buoyancy adjusting load 949 for adjusting the diving buoyancy are mounted on one side of a horizontal stowage block tank having a level balance on both sides, ) Double structure provided with a vertical type coupling structure with loss of level balance on both sides Combined portable tank lug (607) Single block tank Hull disassembly Portable lug pin connecting shaft (606) Block tank provided with coupling Hull disassembly Portable lug pin The horizontal stowage block tank by the connection shaft 606 is constructed as a vertical type coupling structure, and at the same time, The position of the joining portion of the deck deck bottom bottom of the holding tank upper barge hull 592 of the reactor installation main body 1 and the processing hole 615 of the lug hinge socket 613 for providing the position of the concave- A double structure block tank is provided at the upper part of a marine tunnel traffic device (941) with a connection lug hinge socket (613) of a stationary floatation type holding tank and a support block tank (590) A landing block (not shown) of a stationary floodplain (593, 594, 595) provided at the top of the nuclear waste disposal double structure block tank marine tunnel traffic device (941) by providing a lug hinge socket (613) (593, 594, 595) connection structures, while simultaneously connecting the tanks to the upper end of the sea surface (SLU) of the sea surface (SLU) of the barge hull and the lower surface of the sea level (SLD) (593, 594, 595), which provide a coupling to the nuclear waste treatment dual structure block tank bridge bridge (929) of the reactor plant main body of the nuclear power plant, and the distribution tank is provided with the upper tank barge hull and the holding tank Coupling of several dual structure block tanks to the lower barge hull Coupling of the portable lug 607 and the double structure block tank Portion of the lug pin connecting shaft 606 The number of the several lugs 607 coupled to the processing hole 615 of the body and the lug pin connecting shaft 606 The holding block tanks (590) are used to prevent sinking floods from the sea level and to protect the floodgate lifting device with the connecting structure of the hull safety equipment. At the same time, the harmful tidal control and barge lines for mounting the disaster prevention device are connected. Of the nuclear power plant, and the barge lines for mounting the disaster prevention device are equipped with the inflow control device and the interconnection structure, (1) Internal connection structure of power plant (1) Upper part of sea surface (SLU) with submarine line wiring (946) Auxiliary type of hull Deck upper part (SDU) Cranes Seisoke Crane Boom (942) Connected structure Mooring device and power generation facility Distribution installation device Connected structures Nuclear power plant Nuclear power plant Nuclear power plant's reactor facility is provided inside the main body (1) Marine power plant (593,594,595) Nuclear power plant (672) and the nuclear waste treatment pipe manufacturing process (705) of the nuclear reactor waste disposal apparatus and the nuclear reactor waste facility treatment facility at the nuclear power plant (811) As a connection structure capable of disassembling and coupling at a marine shipbuilding factory.

Referring to FIG. 51, an embodiment of a nuclear power plant 811 is installed inside a nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention. (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with a boiling water reactor (802), pressurized water reactor (803), gas cooling furnace reactor (804), and multipurpose hot gas reactor (1) of the elementary nuclear power plant of a nuclear power plant showing a side view of a nuclear power plant operating system consisting of a nuclear power plant (805), a new type conversion reactor facility (806) and a fast breeder reactor facility (838) (593,594,595) Nuclear power plant (672) of a marine power plant showing the construction method of nuclear plant nuclear power plant and nuclear power plant are equipped with boiling water reactor facility (802) and pressurized water reactor A side view of a nuclear power plant type nuclear power plant consisting of a facility 803, a gas cooling furnace reactor facility 804, a multipurpose hot gas furnace reactor facility 805, a new conversion furnace reactor facility 806 and a fast breeder reactor facility 838 Straight configuration Road,

As shown in FIG. 5L, the nuclear power plant nuclear power plant 671 of the marine nuclear power plant is connected to the nuclear power plant nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 into the nuclear power plant main body 1 of the nuclear power plant, (804), a gas cooling furnace reactor (804), a multipurpose hot gas furnace reactor (805), and a new type high pressure gas reactor (805) are installed in a dual structural block tank dust collector (794) (593,594,595) nuclear power plants (672) of each offshore power plant in the nuclear power plant scene consisting of a reactor facility (806) and a fast breeder reactor facility (838) Each of the nuclear reactor facilities 802, 803, 804, 805, 806, and 838 constituting the double structure block tank dust collector 794 for nuclear waste treatment on the connection axis of the nuclear power generation nuclear waste processing unit 811a of the facility unit 811, A nuclear waste disposal and dispensing apparatus having a double structure block tank precipitator 794 in the form of a nuclear radiation leakage control source statistic in a nuclear reactor power plant 672 and a nuclear reactor main body 1 of a nuclear power plant, (811) at the top of the sea surface (40 m) to prevent the earthquake and tsunami from being affected by the weather conditions, (672) of nuclear power plant (672) of nuclear power plant and nuclear plant safety operation device that establish safety of nuclear reactor facility safety before and after safety operation of nuclear power plant In order to prevent the explosion of a plurality of individual nuclear reactor installations (802, 803, 804, 805, 806, and 838) of nuclear power generation inside the main body (1) As shown in FIG. 51, a plurality of individual reactor installations 802, 803, 804, 805, 806, and 838 constituting the nuclear radiation leakage control dual structural block tank dust collector 794 provided as a connection axis of the nuclear power generation nuclear waste processing section 811a of the non- First, a boiling water reactor reactor installation 802 is provided so that a nuclear power plant can be operated in a floating nuclear power plant 672 of a marine power plant and a nuclear power plant main body 1 of a nuclear power plant; First, in the control of the output of the boiling water reactor installation 802, the boiling water reactor installation 802 uses the hard water 654a as the moderator 676 and the coolant 816 to boil it, (Void) generated in the moderator 676 by boiling in addition to generating steam of about 70 kg / cm 2, while the hard water 654a is light water, that is, ordinary water .

      Secondly, when the control rod 798 is drawn out, the reactivity of the reactor increases and the output increases.

     Thirdly, when the boiling is promoted and the void is increased, the density of the moderator 676 is decreased, and the deceleration efficiency of the neutrons 675 is lowered, so that the negative reaction is applied.

     In the fourth case, when the reactivity of the positive and the negative reactivity generated by the withdrawal of the control rod 798 are balanced, the reactor output is stabilized.

     In the fifth case, when the control rod 798 is inserted, the opposite phenomenon occurs. Therefore, as the void decreases and the density of the moderator 676 increases, the efficiency of decelerating the neutrons 675 increases and a positive reactivity is applied to the reactor .

     In the sixth case, when the reactor is balanced with the negative reactivity applied by the control rod 798, the reactor is stabilized at a new output. Thus, the boiling water reactor assembly 802 has self controllability by voids.

     Next, the heat generated in the fuel rod 689 in the core 791 is transferred to the coolant 816.

     Next, in the boiling water reactor installation 802, heat transfer in the boiling region is utilized.

     In the ninth, since the size of the heat flux flowing due to the temperature difference between the heat transfer surface and the coolant 816 is obtained in many experiments and the heat transfer is lowered in the boiling boiling region where boiling is intense, the fuel covering material 681 may be burned out. And the operation is restricted so that it does not reach the transition boiling region at the time of the middle and operation and during the operation.

     The heat generated in the fuel rod 689 is transferred to the coolant 816 in the tenth.

    Since the cooling water 287 is recirculated and the flow rate of the cooling water 287 is increased to increase the flow rate of the refrigerant flowing through the core 791, (816) recirculation system is provided.

     The twelfth one is that when the reactor installation is combined with the turbine generator 772, the reactor installation output can follow the turbine load.

     In the boiling water reactor installation 802, if there is a change in the load at the final stage, the control device 798 first adjusts the reactor installation output by increasing or decreasing the flow rate of the insertion or recirculation of the control rod 798.

As shown in FIG. 51, secondly, a pressurized water reactor installation 803 is provided, and the nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant are operated. In the pressurized water reactor (803) nuclear power plant, the pressurized water reactor (803) is provided with a primary use in PWR for the coolant compilation in the pressurized water reactor design editing In the first system, it is set at about 315 degrees Celsius. At the same time, the first-order pressure is usually 2000 psig and 15 MPa, and the 654a number at 150 times the pressure is not boiled, Water is sent to the steam turbine (267) in most designs of the secondary system, making water vapor at a temperature of 275 degrees Celsius and a pressure of 900 psig and a pressure of about 6.2 MPa.

     The stability of such a pressurized water reactor type reactor (803) is such that when the pressurized water reactor is provided with a very stable production, but when the RBMK (graphite reduction speed boiling water pressure tubular reactor) But the design of this RBMK is considered one of the Chernobyl boiling water pressure tubular reactor installations.

     This fuel assembly of the fuel pressurized light-water reactor is used in a pressurized light-water reactor of the NS Savannah, a nuclear passenger cargo ship, and the fuel in the pressurized light-water reactor uses a constant-enriched fuel of 235U.

     (U02) powders are melted and melted, they are heated and sintered. However, at the same time, the production of ceramic pellets made of uranium dioxide is carried out. (Zirconia), helium is injected into the zirconia rods to help heat transfer, but the finished fuel rods are bundled with bundles of fuel-fuel assemblies, which are called aggregate bundle fuels, It is loaded.

    It is very important to prevent a chain reaction from occurring in the core of a nuclear reactor facility that does not allow a rapid chain reaction in a pressurized water reactor (803) of the nuclear power plant of the nuclear power plant. However, when the chain reaction occurs, , Or 200 to 300 fuel rods of a pressurized water reactor, 150 to 250 fuel assemblies, or simultaneously enter uranium at 80, It is maintained at 14X14,17X17 pieces of about 100 tons.

     The pressurized water reactor (803) fuel bundle of the nuclear power plant operating at the nuclear power plant is provided at about 4 meters, and at the same time, there are many pressurized light water reactors with many pressure vessel control of the pressurized light water reactor and many pressure vessel controls of the military primary pressurized water reactor Adjust it to positive.

     In the pressurized water reactor type nuclear reactor facility 803 for operating the nuclear power plant, since the neutron is absorbed immediately, the reactor system is controlled by reducing the chain reaction by the pressurized light reactor. Therefore, the control pump of the entire pressure relaxation system is included. Is to provide high concentration of neutrons in a large number of emergency stopping cooling water, but also CANDU is an auxiliary means to enable the boric acid to quench the chain reaction. .

     In addition, the control rod enters the fuel assembly from the pressure vessel and is usually used when the first nuclear power plant is started or when the nuclear power plant is shut down. At the same time, the fuel assembly is regulated to a height at the reactor plant, The fuel rod of the stabilized fuel pellets of the barrier wall and the first barrier pellet was burnt inside the radioactive material generated by the fuel rod. The second barrier wall was enclosed with the nuclear fuel pellets and put into a metal tube of a special alloy as a nuclear fuel rod The small amount of gas that is released is a reactor vessel provided with a 20 cm thick steel containing the nuclear fuel assemblies in the reactor vessel which is the third barrier wall at the same time to provide a seal to the second barrier wall.

In addition, the shielded concrete wall, which is the fourth barrier wall, prevents the leakage of the radioactive material as a concrete wall surrounding the nuclear reactor facility. In the containment vessel of the fifth firewall, the safety system and the whole space At the same time, the biological shielding wall of the 5-1 barrier wall is provided with a final biological shielding wall as a thick building 70 to 100 cm outside the steel, and at the same time, It is a container and a dome form, and it is a safe nuclear building to prevent the leakage of radioactive material, but at the same time, it provides an external shielding of radioactive material in case of an accident.

In the pressurized water reactor (803) nuclear power plant operation, during the pressurization water reactor installation (803), the amount of exposure that a general CT photographer and an airplane crew normally receive can be a standard.

Uranium fission and reactor facilities As mentioned above, 99.3% of stable uranium 238 is contained in natural uranium, 0.7% of unstable uranium 235 which can cause fission, and at the same time, domestic nuclear reactor types are mainly PWR ) And pressurized water reactor (PHWR). At the same time, the water reactor is a type of conventional nuclear reactor (803) operated by Kori, Yonggwang and Uljin, mainly supplied by the United States. (H ₂ 0) as a moderator (676), which is a material promoting the fission reaction using concentrated uranium (U-235, 4-5%) as a fuel, and at the same time one year or one year and six months Once the reactor is shut down, the fuel must be replaced.

In the meantime, the heavy water type reactor is a type supplied from Canada, which is currently in operation in Wolsong. As a characteristic, the reactor is horizontal and uses natural uranium (U-235, 0.72%) as fuel, moderator (676) ₂ O) and a portion of the fuel can be replaced daily.

As shown in FIG. 51, thirdly, a gas cooling furnace reactor facility 804 is provided to operate the nuclear power plant 672 of a marine power plant and the reactor main body 1 of a nuclear power plant In the structure of the gas cooling furnace reactor 804, the gas cooling furnace is a reactor facility 804 formed by providing graphite as a moderator 676 and carbon dioxide as a coolant 816, and natural uranium And the condensed uranium 235 and the use of carbon dioxide as the coolant 816. At the same time, the thermal efficiency equivalent to the thermal power is provided by the high-temperature and high-pressure vapors of the strong vapor condition, The structure is made up of nuclear power.

A nuclear reactor facility using gas as a coolant 816 to the gas-cooling furnace reactor facility 804, a calderhall type of graphite-retarded natural uranium fuel type, carbon dioxide gas (CO ₂ ) as its reforming type, and a high temperature gas- (CO ₂ ) is supplied to the cooler 816 as a cooler hole type reactor, which is a nuclear reactor type reactor with a deceleration natural uranium fuel type reactor, and an improved version thereof, while using helium (He 176) The generic name of the reactor used by. The structure of a gas-cooled furnace reactor (804), which is a typical reactor cooling furnace reactor developed in the UK, using natural uranium as fuel, graphite as a moderator 676, carbon dioxide gas as a coolant 816, and the like.

As shown in FIG. 51, the gas-cooling furnace reactor facility 804 formed by the nuclear power plant operation of the nuclear power plant is provided with a coolant 816 as a coolant 816 inside the reactor pressure vessel 813 of the gas- And carbon dioxide gas is supplied from the carbon dioxide gas 164 and the coolant 816 provided in the gas cooling furnace reactor facility 804 The helium 176 is provided as a coolant 816 and at the same time the connection structure inside the reactor pressure vessel 813 formed by the operation of the nuclear power plant is connected to the recirculation pump 239 and the water feed pump 241, The steam 780 and steam are cooled in the pump 242, the cooling water 287, the turbine 267, the generator 772, the fuel rod 689 and the steam pipe 779 and the steam pipe 779, Which is a cooling device of the apparatus for making the core 791, A control rod drive housing 798a provided inside the heat exchanger 793 and the control rod 798, a control rod drive shaft 798b and enriched uranium 812, and a gas cooling furnace reactor facility 804 ) To make nuclear power.

As shown in FIG. 51, the fourth step is to prepare the nuclear reactor 805 with the multi-purpose high-temperature gas so as to operate the nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant The use of graphite as a moderator 676 is provided for the structure of the reactor facility 805 and the use of helium gas 176 is used for the coolant 816, At the same time, the fuel is composed of enriched uranium 235 (812) and thorium, and the heat of the helium gas (176) is transferred to water to generate nuclear power by steam generation. At the same time, A condenser 790 serving as a cooling device of the apparatus for cooling the water vapor by cooling the steam 241, the turbine 267, the generator 772, the intermediate heat exchanger 657, the fuel rod 689 and the steam 780, A control rod 798 and a coolant 816, Power is configured to be made for atomic power to multi-purpose high-temperature gas of a power plant (672) into the reactor plant (805) connected to the structure.

As shown in FIG. 51, graphite is used as a moderator 676 in the structure of the reactor facility 805 of the nuclear power plant 672 multi-purpose high temperature gas, and helium gas 176 is used as the coolant 816 At the same time, as the fuel, enriched uranium 235 (812) and thorium are used, and the heat of the helium gas 176 is transferred to water to generate nuclear power by steam generation. At the same time, In the operating mode, the internal structure 805a of the Pebble-Bed type high-temperature gas path in which the primary cooling system is housed is provided with the heat shield 805b, the through-hole stopper 805c, the auxiliary circulator 805d, the control rod reservoir 805e, The control unit 805g and the auxiliary circulating unit 805h and the auxiliary heat exchanger 805i and the core support structure 805j and the prestressed concrete reactor vessel 805k and the PCRV safety valve 805l, A fuel inlet 805m, a helium circulation unit 805n, and PCRV The HTR-module reactor structure 805p includes a spherical fuel outlet pipe 805q, a boron refining furnace system 805r, a reflector region control rod 805s, A gas circulating unit 805w and a high temperature gas pipe 805x, a surface cooler 805y and a heat insulating material 805z, and at the same time, the fuel supply pipe 805t, the water supply pipe 805u, The use of enriched uranium 235 (812) and thorium and the heat of helium gas 176 are transmitted to water to generate nuclear power by steam generation. At the same time, 241, a turbine 267, a generator 772, an intermediate heat exchanger 657, a fuel rod 689 and a steam 780, and a condenser 790 and a control rod 798 and the coolant 816 to connect the reactor facility 805 to the multi-use hot gas of the nuclear power plant 672 It can be configured to achieve a nuclear power plant in plaiting.

As shown in FIG. 51, the fifth step is to prepare the input of the reactor facility 806 by the new conversion type and to operate the nuclear power plant 671 of the marine power plant and the reactor main body 1 of the nuclear power plant And a new conversion furnace facility 806 constituting a connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811, The new type conversion furnace facility 806 is provided with the coolant 816 as the hard water 654a for increasing the utilization of the fuel 683 and the hard water 654a as the coolant 816 The water 654 and the steam 780 are separated from the steam drum 792 which is generated at a high temperature 780 while the fuel is being raised between the fuel and the steam 780 is simultaneously discharged to the steam pipe 779 through the turbine 267 While simultaneously rotating the turbine 267 A heavy water 654b is used as the moderator 676 and a heavy water 654b is used as the moderator 654b in the plurality of individual nuclear reactor facilities 802,803,804,805,806,838 of the nuclear power generation while providing the electric power production in the generator 772, The use efficiency of the uranium 812 is increased so that the mixture of the plutonium 801 and the natural uranium 812 is mixed with the mixer mixer machine 649. At the same time, The operation of the nuclear reactor (806) is provided with the rotation operation of the turbine (267) by the use of the fuel (683), and the nuclear radiation leakage control of the nuclear reactor facility is provided A double shaft block tank dust collector 794 a connection shaft for supplying a nuclear power generation nuclear waste treatment unit 811a of a nuclear power generation facility 811 to a new type conversion reactor installation 806 into a nuclear power plant 810 and a nuclear power generation facility 811, won (811a) Double structure block of the power generation nuclear waste treatment unit (811a) Dual pipe structure piping line (74) for positioning the inside of the tank dust collector (794). (74) Temperature sensor of the safety valve When the temperature sensor of the safety valve reaches the dangerous state of the high temperature and high pressure state of the reactor inside the nuclear reactor 700 to 800 degrees Celsius, the temperature pressure sensor is connected to the computer of the safety control room The explosion nuclear waste is passed through the inner block piping line 74a of the pressure vessel 813 at each location to provide a double structure The block tank precipitator 794 stores the nuclear waste at each location, and the pressure vessel 813 is connected to the internal double structure block tank at the lower end thereof. The sensor safety valve 472 is opened and at the same time, the outer block piping line 74b is provided with the explosion-proof control article of the nuclear fuel explosion-proof control fuel element fuel 683 stored in the inner block tank, A thermocouple thermometer sensor switch 103 having a connection structure with a pressure gauge 101 and a temperature sensing sensor bimetal 102, a level pressure switch 104 for flow rate check operation, a flow rate meter 105 for flow rate check, And a safety valve 472 of a line automatic pneumatic valve conveying device 916. At the same time, a plurality of through holes are formed in the upper end portion of the reactor building 688 at a predetermined angle of 45 degrees with a laser cutter and a construction machine drill machine The block piping line 74 while forming the double pipe structure piping line 74 in the plurality of through holes at the same time and the bolts 24 and the nuts 25 The gasket (32) A double structure block tank dust collector 794 having a diameter twice the diameter of the reactor building 688 along the circumference of the outer wall of the reactor building 688 is provided with a connecting connection, Nuclear waste disposal unit and nuclear fuel (683) explosion control distribution dispenser combined with a block tank (599) to form a radiation-like connection structure Reactor facilities inside reactor core (681) and reactor core (681) The nuclear fuel explosion prevention control articles are provided in a plurality of nuclear reactor connection structures inside the main body 1 of the nuclear power plant of the land and the ocean at the same time as the nuclear fuel explosion prevention control articles, 1) Nuclear Fuel Explosion Prevention Nuclear Reactor Leakage Control of Nuclear Waste Shielding and Nuclear Reactor Facilities that Operate Nuclear Power Plant Operations Dual Structure Block Tank Dust Collector (794), and at the same time, a double-structure block tank dust collector (794) for preventing detonation of the nuclear fuel (683) of nuclear fuel into the reactor main body (1) of the floating nuclear power plant of the marine power plant at the same time. In addition, it is necessary to construct a nuclear reactor (806) structure for conversion and to further operate the nuclear power plant. In addition, a mooring device, a diverting buoyancy control device, a distribution input device and a reactor installation Nuclear power plant nuclear waste disposal unit (811) in nuclear power plant (811) Nuclear power plant nuclear waste disposal unit (811) 811a) a connection shaft for providing the input of a reactor installation (806) with a new type of conversion; and a connection structure capable of disassembling and coupling at a marine ship manufacturing factory There.

As shown in FIG. 51, the sixth step is to prepare the fast breeder reactor facility 838 so that the nuclear power plant can operate in the floating nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant (FBR) 838 constituting a double structural block tank dust collector 794 for nuclear waste treatment on the connection axis of the nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811, A nuclear waste disposal dispensing apparatus having a double structure block tank dust collector 794 in the form of a nuclear radiation leakage control source statistic into a nuclear power plant 672 of a power plant and a reactor facility main body 1 of a nuclear power plant, (683) Explosion control distribution dispenser A large number of reactor facilities are installed in the marine anti-sunken double structure block tank flood control station. (811) at 40m above the sea level to prevent the sinking of the nuclear power plant and to prevent the sinking of the nuclear power plant. (811a) of the nuclear power plant (811), which prevents the nuclear power plant (811a) from exploding into the nuclear power plant (672) and the nuclear reactor main body (1) of the nuclear power plant, (FBR, 838) constituting the nuclear radioactive leak control dual structure block tank dust collector (794);

As shown in FIG. 5L, the fast breeder reactor facility (FBR) 838 constituting the connection axis of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power generation plant, (FBR) 838 in the double structure block tank precipitator 794 of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant contains enriched uranium A mixture of enriched uranium 812 and natural uranium 812 and plutonium 812 concentrated at about 20% of the fuel rod 812 is provided around the fuel rod 689 and surrounded by natural uranium 812 at the same time. The fuel is supplied from the uranium 238 (653a) to the plutonium 801 in the fuel rod 689. However, the plutonium 801 is provided for entry and exit, ), The liquid metal sodium Since the neutralizer 675 does not need to be decelerated to the FBR reactor 838 at the same time, the moderator 676 is not contained, and the heat generated in the reactor installation in the intermediate heat exchanger 657 is subjected to intermediate heat exchange At the same time the heat exchanger 658 converts the water 654 into steam 780 as the heat of the liquid sodium and the steam turbine 267 turns to the steam 780, (811a) of the nuclear power generation facility (811) to the inside of the nuclear reactor facility main body (1) of the floating nuclear power plant of the marine nuclear power plant, (FBR, 838) connection shaft constituting a structural block tank precipitator (794), and

As shown in FIG. 51, a dual structure block tank precipitator 794 of a connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 includes a double pipe The structural block piping line (74) is provided with a nuclear waste location transfer passage by means of a nuclear waste location movement control device. However, a plurality of temperature radioactive pollutants are detected by the temperature pressure sensor of the safety valve. When the dangerous state of the high temperature and high pressure state is reached from 700 to 800 degrees, the temperature and pressure sensing sensor transmits an alarm message to the computer of the safety control room, and at the same time, The explosive nuclear waste passes through the internal block piping line 74a of the pressure vessel 813 and the nuclear waste And the temperature blockage pressure sensor sensor valve 472 connected to the inner double structure block tank at the lower end of the pressure vessel 813 is opened while the outer block piping line 74b is provided with the fuel explosion stored in the inner block tank Prevention control device Automatic injection device for fuel explosion prevention control device Thermocouple thermometer sensor switch (103) with connection structure of flashing warning light (99), pressure gauge (101) and temperature sensor bimetal (102) And the safety valve 472 of the pipeline automatic pneumatic valve conveying device 916 and the connection structure by the pressure switch 104 and the flow meter 105 for checking the flow rate of the air flow and at the same time, A plurality of through holes at an angle of 45 ° may be formed by a laser cutting machine and a construction machine drilling machine to form a through hole. At the same time, a double pipe structure block pipe line 74 is formed in a plurality of through holes, Piping line 74 A plurality of safety valves 472 are provided with flange connecting connections by bolts 24, nuts 25 and gasket 32, but also at the same time along the outer circumferential surface of reactor building 688 The double structure block tank dust collector 794 having a diameter twice the diameter of the reactor building 688 is provided with a nuclear waste disposal input device And nuclear fuel (683) explosion control distribution dispenser to supply nuclear reactor facilities inside nuclear reactor core (681) and core (681) outside nuclear reactor explosion control reactors just before nuclear explosion control land and sea nuclear power plant main body (1) (683) explosion-proof control equipment, which are installed at the same time as a plurality of nuclear reactor connection structures inside the nuclear reactor main body (1), so as to prevent explosion of nuclear fuel in the nuclear reactor main body (1) And nuclear waste disposal shielding system and nuclear reactor leakage control of nuclear reactor waste disposal control system (794), and at the same time, the nuclear power plant explosive nuclear power plant of the ocean power plant, (FBR, 838) structure to the nuclear reactor plant to make the operation of the nuclear power plant more effective. However, the structure of the double structure block tank dust collector (794) formed in the floating nuclear power plant (672) Dual Structure Block Tank Dust Collector (794) equipped with nuclear reactor radiation leakage control of nuclear reactor facility in Fuehsien Nuclear Power Plant Division (811) before nuclear reactor facility safety operation of mooring device, diving buoyancy control device, ) Nuclear power plant nuclear waste disposal unit (811a) of nuclear power generation facility (811), reactor fuel plant (FBR, 838) The connection axis is composed of a connection structure that can be disassembled at marine shipbuilding factories.

As shown in Figure 51, in a reactor installation of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment,

As shown in FIG. 51, the nuclear power plant equipment includes nuclear power plant 672 of floating power plant 593,594,595 of a marine power plant and nuclear power plant reactor main body 1 of nuclear power plant. A nuclear reactor and a nuclear reactor having a dual structure block tank 598 for controlling nuclear reactor facility nuclear radiation leakage of the apparatus and having a dual structural block tank collector 794 of a nuclear reactor nuclear waste treatment shielding apparatus, And operation of nuclear power plants in the ocean;

As shown in FIG. 51, in the nuclear waste treatment facility of the reactor facility of the nuclear power plant, the yellow soil mixtures mixed with the cooling water are injected into the nuclear core 681 inside the reactor and outside the reactor core 681, If the mixed yellow loess mixtures are filled with nuclear waste disposal apparatuses inside the reactor core 681 and outside the reactor core 681, nuclear fuel collision of the nuclear reactor chamber is controlled and at the same time, The waste treatment is carried out during the operation of the nuclear power plant, and the nuclear waste treatment dual structural block tank dust collector (794) constituting the marine nuclear power plant's marine nuclear power plant (593,594,595) and the nuclear waste treatment dual structure block tank bridge marine tunnel transportation equipment ) Reactor shafts of nuclear power plants having nuclear waste treatment dual structure block tank precipitators 794 as connection shafts;

As shown in Figure 51, the dual structure block tank arrangement of the nuclear waste treatment dual structure block tank scrubber 794 includes an inner block tank 596 and an outer block tank 599, which can be disassembled, The double structure block tank cleaner 794 of the nuclear power plant is provided with a double structure block tank 598 by cutting and welding processes with connection structures and at the same time providing a double structure block tank cleaner 794 Devices to provide nuclear waste treatment of the reactor plant to the dual structure block tank scrubber 794;

As shown in FIG. 5L, the double structure block tank dust collector 794 is equipped with a double structure block tank dust collector 794 with connection structure construction machine crane 861, which can be disassembled and coupled at a marine vessel manufacturing factory. A nuclear power plant 811 constituted by the interior of a nuclear reactor facility main body of a nuclear power plant provided with a nuclear reactor;

As shown in FIG. 51, the reactor installation for preventing nuclear explosion of nuclear fuel in the nuclear power plant 811 includes a boiling water reactor 802, a pressurized water reactor 803, and a gas cooling furnace reactor A nuclear power plant 811 constituted by the inside of a reactor facility main body of a nuclear power plant provided separately from a nuclear power plant 805, a multi-purpose high temperature gas furnace 805, a new conversion furnace reactor facility 806 and a fast propagating furnace reactor facility 838, A nuclear waste nuclear waste disposal unit 811a;

As shown in FIG. 51, the layered structure having the control shaft for controlling the nuclear waste capacity into the storage tanks of the nuclear reactor nuclear waste processing unit 811a is installed in the reactor facility 1 of the reactor facility main body 1 of the nuclear power plant , Nuclear power plants in safe and sustainable nuclear power plants Nuclear reactors to prevent nuclear fuel explosion Pre- and post-nuclear power plants Replacement power generation Production of power generation Hydroelectric power plants for wind power generators and thermal power generators to be put into production Production of alternate generation power A power generation and production section 811b of a nuclear power generation facility unit 811 constituted of a reactor facility main body of a nuclear power plant;

As shown in FIG. 51, the double structure block tank reactor 794 of the power production and production section 811b is provided with a plurality of inner block tanks 596 and a central portion of the outer block tanks 599, The double structure block tank reactor 794 is opened to move the crane boom 651 of the locomotion control device construction machine crane 861 to the carrier having the operation of the crane boom hook 652 and the conveyor 633 The dual structure block tank 598, while providing the individual reactor facilities to be adjusted, is constructed inside the nuclear reactor facility body of the nuclear power plant which provides transportation by means of a marine installation connection structure capable of disassembling and coupling in the manufacture of industrial field launch dock A transportation unit 811c of the construction machine of the nuclear power plant 811;

As shown in FIG. 51, the transportation transport unit 811c of the construction machine is installed in the nuclear reactor main body 1 of the nuclear power plant so as to adjust the capacity to the storage tanks of the nuclear nuclear waste disposal shielding apparatus ;

As shown in FIG. 51, the control shaft is connected to a power transmission path (not shown) for disassembling and coupling the reactor main body 1 of the nuclear power plant to the strut block tank 590 of the reactor main body nuclear power generation facility 811 of the individual nuclear power plant. A nuclear waste treatment dual structural block tank pipe bridge 928 of a dual structure block tank 598 with a unit 811d and a disassembly coupling structure of a connection shaft of a double structure block tank pipe bridge marine tunnel transport apparatus 941, A plurality of openings in the reactor main body 1, and a distribution shaft in which the openings are distributed to the storage tanks of the reactor facility manufacturing apparatus and the nuclear waste processing shielding apparatus;

As shown in FIG. 51, the distribution shaft includes transformers (not shown) for transmitting power of a nuclear power plant 811 constituted inside a reactor facility body of a nuclear power plant providing capacity to storage tanks of a nuclear waste treatment shielding apparatus A power transmission portion 811d provided on the rear side of the vehicle body;

As shown in FIG. 51, the power transmission unit 811d is provided with an exhaust gas facility (not shown) that can withstand the natural disasters of the nuclear reactor main body 1 of the nuclear power plant before and after the operation of the nuclear reactor safety- And a nuclear reactor facility main body of a nuclear power plant provided with an exhaust gas outlet and an inlet which are the same as the dust collector of the nuclear power plant 811e;

The control facility 688C and the auxiliary building 688D are installed in the reactor building 688A and the turbine building 688B of the nuclear power plant, (688E), a nuclear fuel building (688F), a waste building (688G), and a power plant building (688Z) with connection structures. The control unit 811f of the electronic control and regulating device constructs the control unit 811f of the crane boom of the position movement control device construction machine crane 861, (651) and a conveyor (633) are constructed inside the reactor facility body of a nuclear power plant which separates the operation of the carrier from the electronically controlled regulating device and provides the electronically controlled operation of the carrier E-regulating control of construction machinery of self-development seolbibu (811) control unit (811f) and;

As shown in FIG. 51, the electronic control apparatus construction machine control unit 811f is provided with storage tanks for nuclear nuclear waste disposal and shielding apparatus consisting of nuclear reactor facility main body 1 of a nuclear power plant, The nuclear power generation facility 811 including a control shaft for adjusting the capacity of the nuclear power plant in the reactor main body 1 of the nuclear power plant can prevent the explosion of the nuclear fuel in the reactor main body 1 of the nuclear power plant, In the barge hull 591 at the upper end of the double structure holding tank, a power production facility for the nuclear reactor power plant production and distribution unit 811b is provided. At the same time, in the barge hull 592 at the bottom of the dual structure holding tank, At the same time that the nuclear reactor facility of the power plant is provided, the screw control section 811g of the nuclear power generation facility section 811 is connected to the holding tank 590, The lug 607 and the lug connection shaft bolt 603 are connected to the disassembly-coupling portable lug-coupling lug pin connection shaft 606. The position adjustment of the adjustment shaft 604 and the axes of the respective adjustment axes is performed by a reactor Further comprises a screw adjusting portion 811g of the nuclear power plant 811 provided inside the facility body 1;

As shown in FIG. 51, the double structure block tank reactor 794 includes a double structure block tank reactor 794 in which the double structure block tank reactor 794 is provided with a double- A reactor vessel is installed on both sides of the fore and aft ends of the plurality of inner block tanks 596 with a crane boom hook 652 and a conveyor 633 operation on the crane boom base 651 of the position movement control apparatus construction machine crane 861 A nuclear power plant consisting of a nuclear waste disposal unit and a double structure block tank dust collector (794) provided with a safe and continuous nuclear radiation leakage control of a nuclear power generation facility (811) provided inside a reactor facility of a nuclear power plant provided with a position- And the operation of the nuclear power plant is provided inside the reactor main body 1 of the nuclear power plant, but the amount of production power can be freely adjusted, and at the same time, The nuclear waste disposal tank 295 disposed at the upper part of the double structure block tank dust collector 794 is provided sequentially without preparing the disaster preparedness and the reactor facilities of the nuclear power plant are mixed with each other, The nuclear reactor facility of the nuclear power plant of the nuclear power plant operates the nuclear waste treatment reactor providing the transfer of the loess mixtures to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the feed pump 241, If the yellow waste mixture mixed inside the core 681 and outside the core 681 with the nuclear waste treatment and control cooling water is filled into the core 681 inside the reactor and outside the core 681, The nuclear reactor control of the nuclear reactor of the nuclear power plant of the land and the ocean of the nuclear power plant of the mainland (1) In order to maximize the production power and to prevent explosion of nuclear reactors with dual structure block tank dust collector, the reactor facilities should be equipped with a waterproofing system to prevent sinking of marine nuclear power plants and prevent nuclear fuel explosion inside the reactor main body 1 of the offshore nuclear power plant. One Nuclear Waste Treatment Double Structure Block Tank Pipes Construction of the connection axis of the disaster prevention equipment and the construction machine that can withstand the marine tunnel transportation device (941) and the natural disaster of the sea, Operation of nuclear reactors with wind turbines, thermal power generators, and hydro generators that are used in the production of electricity production. Replacement power generation equipment before and after the breakdown of nuclear reactor facilities, and maritime tunnel transport equipment (941) And a construction machine equipped with a disaster prevention device and a movement control device.

Referring to FIG. 5m, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants (672) and boiling water reactor facility (802) of nuclear power plant. 1) In-house flood control A number of nuclear reactors Installed at the ocean power plant showing the construction of the nuclear power plant at the nuclear power plant (672) and the boiling water reactor (802) at the nuclear power plant ,

5n, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) nuclear power plant (672) of a marine ocean power plant and a boiling water reactor facility (802) of a nuclear power plant. ) Inside of the Nuclear Power Plant A number of nuclear reactors Installed at the ocean power plant showing the construction of the nuclear power plant Construction of the nuclear power plant consisting of the nuclear power plant (672) and the boiling water reactor (802)

As shown in FIGS. 5M and 5N, nuclear power plants (593,594,595) and nuclear power plants (672) of the offshore and offshore marine power plants and nuclear power plant main body (1) The boiling water reactor reactor facility 802 constituting the connection shaft of the nuclear waste disposal dispensing apparatus of the dual structure block tank reactor reactor facility in the processing unit 811a,

Preferably, the nuclear plant (673) of the offshore and offshore marine power plants (593,594,595) and the nuclear reactor plant main body (1) and the nuclear power generation facility (811) of the nuclear power plant, Block tank Dust collector Nuclear waste treatment of reactor facilities Nuclear waste at the connection axis of equipment Nuclear waste treatment of nuclear reactor equipment for hull safety equipment, which constitutes treatment of nuclear waste (224) into nuclear fuel cycle of nuclear fuel industry. A distribution shaft of the nuclear power generation facility 811 is connected to the floating nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant, And the nuclear waste disposal and dispensing apparatus having the nuclear radiation leakage control dual structure block tank dust collector 794 and the nuclear fuel waste disposal apparatus (811) at the top of the sea level (40 m) to prevent the earthquake and tsunami from being affected by the weather conditions. Of a nuclear power plant to prevent the explosion of nuclear reactors of nuclear power plants. The reactor of the nuclear power plant is designed to prevent the explosion of nuclear power plants. (593,594,595) nuclear power plant (672) of the marine power plant, and the nuclear power plant (1) of the reactor main body (1) of the nuclear power plant, The nuclear reactor nuclear waste processing unit 811a comprising the nuclear reactor nuclear waste processing unit 811, (811a) nuclear power plant reactor facilities, around the launch pad of satellite and space rocket on the deck deck floor of 1 meter thickness of natural loam and disaster prevention equipment construction deck deck deck of natural loam and disaster prevention At the same time, a 60m diameter circular ocher block disaster prevention wall is to be installed at a height of 3m and height of 15m around the launching platform. At the same time, if the satellite and space rocket are fired at the launch pad and the space launch pad at the top of deck deck, When an enormous amount of fuel is burned, a high temperature is generated, and at the same time, the combustion heat of high temperature and high pressure generated by the emission of satellite and space rocket is 60m in diameter. Circular ocher block The fire prevention wall has high temperature and high pressure combustion heat block, A ship safety device, and at the same time, The lane boom zone (942) is 60m in diameter and 15m in height and 15m in height. The block tank hull disassembly unit is moved to the dual bridge structure tank bridge pylon construction bridge saddle formwork (617), and temporarily installed on the circumference surface of the satellite launch pad and space rocket launch pad At the same time, a manganese nodule (909) formed on the top of the deck deck is stacked on the deck deck with a thickness of 2 m. However, after the satellite and the space rocket are fired, At the same time, it is equipped with a hull movement control device in the position of the depth of 10 meters or the depths of the sea, and at the same time, the movement of the hull is dependent on the length of the couch, A hydraulic rotary cylinder machine 619 and a hydraulic cylinder machine 624, while a plurality of hydraulic cylinder operations are provided, and at the same time, If the hull is set back, the hull is retreated and the sea shelter station is moved when the rear hull is prepared at the same time. However, the ship shelter of the shelter station is set up as an auxiliary station (593,594,595) The chain is provided in the reactor main body (1) of the nuclear power plant and the mooring device and the diving buoyancy control device formed in the nuclear power station (593,594,595) nuclear power plant (672) of the marine power plant and the reactor installation And a connection structure capable of being disassembled and coupled at a marine shipbuilding factory with the connection axis of the reactor facility of the nuclear power generation nuclear waste disposal unit 811a at the Fushy nuclear power plant 811 before the safety operation, (593,594,595) Nuclear Power Plants (672) and Nuclear Power Plant Reactor Facilities (1) Atomic Plants of Land and Ocean Offshore Power Plants The boiling water reactor reactor facility 802 constituting the connecting shaft of the nuclear waste disposal dispensing apparatus of the dual structure block tank dust collector reactor facility in the nuclear power generation nuclear waste treatment section 811a to the power generation facility section 811 includes: The distribution dispensing apparatus of the nuclear waste disposal and dispensing apparatus 811 is provided with a nuclear waste disposal distribution system including a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 inside a reactor facility main body 1 of a nuclear power plant And the nuclear fuel explosion control distribution dispenser. It is necessary to install a large number of reactor facilities on the barge of the anti-sinking double structural block tank of the ocean and to prevent the earthquake and tsunami from being restricted by weather conditions. Suction-prevention type barge line reactor facility equipped with distribution dispenser installation position setting of the facility unit 811 Nuclear reactor leakage control to prevent multiple nuclear reactors in a nuclear power plant in a nuclear power plant from being detonated. Dual structure block tank dust collector (794) Prepare a reactor boiler water reactor reactor facility (802) The boiling water reactor reactor facility (802) constituting the connection shaft of the nuclear waste disposal dispensing apparatus of the nuclear reactor plant is constructed by boiling water to form steam to form a turbine rotation operation Water is supplied into the reactor pressure vessel 813 and the control rod 798 and the recirculation pump 239 and the pressure vessel 813 are provided in the boiling water reactor 802 of the double structure block tank reactor reactor facility, And a pressure control pool 240 for confining the steam to the outside of the reactor, and a steam pipe 779 line outside the reactor consists of a turbine 267 and a generator 772, The steam 780 provides cooling power at the condenser 790 while the steam 780 provides the cooling water 287 at the same time. At the same time, the water pump 241 moves the hard water 654a into the inside of the reactor and recirculates the hard water 654a into the purifier 809. At the same time, the cooling water 287 is moved to the circulating water pump 242 in the condenser 790 (287) is discharged from the condenser (790) to the outside of the condenser (790), and the cooling water (287) is discharged to the nuclear power plant of the offshore power plant A connection structure is formed between the floating power plant nuclear power plant 672 of a marine power plant and the nuclear power generation facility 811 and the nuclear power generation nuclear waste treatment unit 811a into the nuclear power plant main body 1 of the nuclear power plant, The nuclear waste disposal apparatus and the nuclear waste disposal apparatus are provided with the block piping lines 74 of the nuclear waste disposal apparatus and the nuclear waste disposal dispatch apparatus, When the detection sensor is operating in the nuclear power plant, if the danger of 700 to 800 degree high temperature and high pressure inside the reactor is reached, the temperature and pressure sensor will send an alarm message to the computer in the safety control room, The explosive nuclear wastes are passed through the inner block piping line 74a of the pressure vessel 813 at each location and the nuclear waste is stored in each of the double structure block tanks, The temperature control sensor safety valve 472 connected to the external block piping line 74b is opened and at the same time, (683) Automatic injection device for explosion-proof control device Thermocouple thermometer sensor switch (103) with a flashing warning light (99), pressure gauge (101) and temperature sensor bimetal (102) The operation level pressure switch 104 and flow meter 105 for flow rate check and the safety valve 472 connection structure of the pipeline line automatic pneumatic valve conveying device 916 are provided so that a predetermined angle of 45 degrees A plurality of through holes of the double pipe structure block piping line 74 are provided with a through hole processing by a laser cutting machine and a construction machine drilling machine while the double structure block tank piping line 74 is provided with a double pipe structure block pipe line 74 While simultaneously providing a plurality of safety valves 472 to the block piping line 74 with flange connections to the bolts 24 and the nuts 25 with the gasket 32, 688 The outer block tank 599 for the nuclear waste treatment storage and the double structure block tank dust collector reactor unit are combined into a radiation type connection structure in a double structure block tank 598 having a diameter twice the reactor diameter along the outer wall surface. Nuclear waste disposal unit and nuclear fuel (683) Explosion control distribution dispenser with nuclear reactor facility inside reactor core (681) and reactor core (681) (683) explosion-proof control items in the reactor main body (1) of the nuclear power plant of the nuclear power plant so that the reactor nuclear fuel (683) of the reactor main body (1) The structure of the boiling water reactor reactor (802) to prevent explosion is provided in the reactor structure of the dual structure block tank dust collector (794) And the nuclear power plant of the marine power plant (672), the docking buoyancy control device and the nuclear waste disposal and distribution system of the nuclear reactor, Nuclear power plant nuclear waste disposal unit (811a) Double structural block tank dust collector (794) Connection shaft to construct boiler water reactor reactor facility (802) into nuclear reactor facility to make nuclear power operation more. As a connection structure that can be decomposed and bonded at the same time.

The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a nuclear power plant main body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control Dual Structural Block Tank Dust Collector (794) Boiling water atom By providing the input of the reactor plant (802) configured to be made movable, and nuclear power plants;

As shown in FIGS. 5m and 5n, the boiling water reactor reactor facility 802 constituting the connection shaft of the nuclear waste disposal dispensing apparatus of the dual structure block tank dust collector reactor boils water to make steam, A control rod 798, a recirculation pump 239 and a pressure vessel 813 are connected to the interior of the reactor pressure vessel 813 in the boiling water reactor 802 of the double structure block tank reactor reactor installation. And a pressure control pool 240 for keeping water in the lower part of the reactor and a turbine 267 and a generator 772 in the steam pipe 779 line outside the reactor, And the steam 780 remaining at the same time provides the cooling action in the condenser 790 while the steam 780 is switched to the cooling water 287. At the same time, The hard water 654a is discharged into the discharge port 809, The cooling water 287 is transferred to the circulating water pump 242 while the cooling water 287 is discharged to the outside waterproofing passage of the condenser 790 at the same time, The distribution and input device of the nuclear power plant 811 to the inside of the nuclear power plant of the marine power plant of the marine power plant is provided with the buoyant pilot nuclear power plant 672 of the marine power plant and the nuclear power plant main body of the nuclear power plant 1) a connection shaft of the nuclear power plant 811 inside the reactor; and

As shown in FIGS. 5M and 5N, the nuclear waste disposal unit 811a is connected to the nuclear waste disposal unit 811a so that the nuclear waste disposal unit and the nuclear waste disposal unit can be transferred to the nuclear waste If the temperature sensor of the safety valve of the safety valve is in operation of the nuclear reactor, the risk of the high temperature and high pressure state of 700 to 800 degrees inside the reactor is reached At the same time that the temperature and pressure sensing sensors provide alarm messages to the computers of the safety control room, the plurality of temperature and pressure sensing sensor safety valves are opened, and the internal block piping line 74a of the pressure vessel 813 at each location is exploded Nuclear wastes pass through and are connected to the inner block tank at the bottom of the pressure vessel (813) while nuclear waste is stored at each location of the double structure block tank The explosion prevention control device for the fuel 683 stored in the inner block tank is connected to the automatic injector flasher warning lamp 99 and the pressure gauge 101 ) Thermocouple thermometer sensor switch 103 having a connection structure with a temperature sensor bimetal 102 and a level pressure switch 104 for flow rate checking operation and a flow meter 105 for flow rate check and piping line automatic pneumatic valve transportation A plurality of through holes of the double pipe structure block pipe line 74 are passed through the laser cutter and the construction machine drilling machine at a predetermined angle of 45 degrees to the upper end of the reactor building 688 by connecting the safety valves 472 of the apparatus 916 Hole processing is provided while a double pipe structure piping line 74 is formed in a plurality of through holes of the dual structure block tank reactor reactor facility, and at the same time, a plurality of safety valves 472 are connected to the block A flange connecting connection is provided to the bolt 24 and the nut 25 by the gasket 32 in the pipe line 74 and at the same time a double structure having a diameter twice the diameter of the reactor building 688 In one block tank 598, an outer block tank 599 for storing nuclear waste treatment and a dual structure block tank dust collector reactor unit are combined into a radiation type connection structure to form a nuclear waste disposal dispensing apparatus and nuclear fuel 683, A nuclear reactor facility is installed inside reactor core (681) and reactor core (681). It is equipped with reactor control equipment to prevent explosion of nuclear fuel just before reactor explosion. (683) as a plurality of explosion-proof control apparatuses of the nuclear reactor facility connection structure to prevent the explosion of nuclear reactors (683) of the nuclear reactor main body (1) of the nuclear power plant by the boiling water reactor reactor facility (794) of the double structure block tank (794) to be installed in the nuclear reactor facility to further operate the nuclear power plant. In addition, the mooring device, the diving buoyancy control device and the nuclear waste treatment (811) Nuclear power plant nuclear waste disposal unit (811a) Double structure block tank dust collector (794) Nuclear reactors boiler water reactor in reactor facility And a connecting shaft for providing the operation of the nuclear power plant by providing input of the power plant 802 to the ship.

(593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and the double structure block tank of the nuclear reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the offshore and offshore marine power plants as shown in FIGS. 5M and 5N, The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, A connection structure to the inside of the nuclear reactor facility main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant is provided at the position of the tower top block 116 of the control room of the mooring tower 644, Equipment radar (840) At the top of the control block top block pylon (116), the distribution and input device of the nuclear power plant (811) simultaneously maintains the lightning rod (500) (SLU) equipped with a submarine line wiring (946) to the interior of the nuclear reactor facility main body (1) of a nuclear power plant. (942) Connection structure Mooring device and power generation facility Distribution installation device for hull safety operation Connection structure of nuclear power plant is equipped with the main body (1) of the nuclear power plant inside and the marine power plant lifting plant 593,594,595 Mooring device and diving buoyancy control device of nuclear power plant (672) and nuclear waste disposal device and reactor installation of reactor facility Safety operation Before nuclear power plant of nuclear power plant (811) And the connection axis of the process (705) as a connection structure capable of disassembling and coupling at a marine vessel manufacturing factory.

As shown in FIGS. 5M and 5N, the double structure block tank dust collector of the floating power plant 672 of the offshore and offshore marine power plants and the reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant are connected to the reactor The diving preparation ready operation control regulating and distributing apparatus for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the facility is characterized in that the distribution input apparatus of the nuclear power generation facility unit 811 includes (672) of the nuclear power plant and the inside of the nuclear reactor main body (1) of the nuclear power plant. The power generated at the manufacturing plant of the nuclear reactor main body of the marine nuclear power plant is connected to the distribution input device (96) of a large-capacity substation, and a power transmission line and a connection structure are connected to a transmission tower by a predetermined amount (597) manufacturing plant for high-strength stainless steel, steel beam (149), and steel section (839) manufacturing plant to produce small-diameter piping and large-diameter piping and large- At the same time as providing the power line supply, the nuclear waste treatment dual structure block tank marine tunnel traffic apparatus (941) apparatus is provided with the production of the standard specification and the dual structure block tank bridge pipe bridge 929 The tank pipe pier (928) facility is provided with a standard 5M diameter, and the double structure block tank pipe pier (928) diameter is enlarged to 5M and 1M above the Reducer (35) type joint per 1km of water depth A semi-submerged working line 637, a double structure block tank at the upper part of the deck plate 621, and a connecting flange 614 provided at the connection structure. (1) Nuclear power plant equipment (811) Double structure block tank The dust collector is connected to the hull safety facility which constitutes the connection axis position of nuclear waste treatment pipe manufacturing process (705) of nuclear reactor facility. (1) of the nuclear power plant (1) of the nuclear power plant (1) and the nuclear power plant (672) of the marine power plant, Structure Tank Bridge Bridge Saddle Same shape as the formwork 617 Block equipment of the distribution dispenser Combination of the tie-in unit Mobile construction band Sinking ship (621) Ship sinking prevention line (634) Deck deck Upper position (617) of the double structure tank bridge bridge type saddle formwork (617) by the position movement control, and the inside of the reactor installation main body (1) of the nuclear power plant is connected to the disaster prevention nozzle 945) is connected to the upper part of the sea surface (SLU) with the submarine line wiring 946. The upper part of the deck of the hull deck (SDU) is connected to the seaweed crane boom area (942) (928) as the connection structure of the power generation facility equipment, and the connection structure to be supplied with the power generated from the offshore power plant of the floating power plant, 1) to constitute nuclear waste disposal of reactor facilities;

As shown in FIGS. 5m and 5n, various types of jigs can be used as the connection structure to the inside of the nuclear reactor plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant, 22) In the body-slit engaging hole 20, there is provided a link to the interlocking link band with a slit-coupled tool grinding machine 185 having a plurality of sharp ends. In the grating interlocking machine 185, (22), a plurality of processing holes (20), and a plurality of guide ribs (185). At the same time, the anchor replacement crankshaft (846) and the pillar level foundation foundation support (851) (1) of the main body of a floating power plant of a marine power plant (1) to constitute the nuclear waste disposal of the nuclear power plant of the marine power plant, and the maintenance of the marine power plant Ready Nuclear Power Plants (672) Nuclear power plant reactor main body (1) Internal connecting structure Upper part of sea surface (SLU) with submarine line wiring (964) Floating upholstery Ship upper part of SDU (marine power generation facility) Alternate towing crane Shiite crane Boom bar 942) connecting structure, and a double structure block tank pipe bridge (928) as a connection structure between the mooring device and the power generation facility device. The power supply provided by the offshore power generation plant is provided, Nuclear waste treatment of reactor facilities to be supplied is to be provided inside nuclear reactor facility main body (1) of nuclear power plant, and mooring device and diving buoy control device and nuclear waste disposal device (593,594,595) formed in nuclear power plant (672) (811) of the nuclear reactor waste disposal pipe manufacturing process (705) before the safety operation of the reactor installation of the distribution apparatus and the reactor facility Gyeolchuk; it included with this connection structure as possible decomposition combined in a marine vessel manufacturing plant, and is composed.

5O, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants (672) and Nuclear power plant (803) 1) In-house flood control system A number of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of a nuclear power plant (672) and a nuclear power plant is composed of a pressurized water reactor (803) ,

Referring to FIG. 5P, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants (672) and Nuclear power plant (803) 1) Inside flood control plant A large number of nuclear reactor installations A floating offshore plant in the offshore power plant showing the construction of the nuclear power plant (672) and a pressurized water reactor (803) in the nuclear power plant. ,

(593,594,595) nuclear power plants 672 of the above-mentioned offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5O and 5P, The double-structure block tank reactor 801 includes a pressurized water reactor reactor installation 803 connected to a nuclear reactor nuclear reactor waste processing unit 811a of a nuclear reactor installed in a nuclear reactor reactor reactor, and a pressurized water reactor reactor installation 803) is equipped with a nuclear waste disposal dispenser and a nuclear waste disposal dispenser equipped with a floating radioactive leaking control double structure block tank dust collector 794 inside a nuclear plant power plant 672 of a marine power plant and a reactor facility main body 1 of a nuclear power plant, 683) Explosion-Controlled Dispensing Apparatus A number of reactor facilities are installed in the barge of an anti-sinking double structure block tank of the ocean, and the stage of earthquake and tsunami Nuclear power plant (811) installed at 40m above the sea level to prevent the use of restraint system. Sink prevention type barge line reactor facility equipped with position setting. Nuclear Radiation Leakage Control to Prevent Explosion of Multiple Nuclear Reactor Nuclear Power Plants Dual Structure Block Tank Dust Collector (794) Install a pressurized water reactor reactor facility (803) in the nuclear reactor facility to constitute the operation of the nuclear reactor;

5O and 5P, the pressurized water reactor reactor facility 803 of the connection shaft of the nuclear power generation nuclear waste processing unit 811a preferably generates high temperature water without generating steam by applying pressure, Water and steam 780 are exchanged in the generator 810 to provide steam turbine rotation while the pressurized water reactor 803 is filled with the fuel and water and the control rod 798 and the pressure vessel 798 inside the reactor pressure vessel 813, A steam generator 810 and a coolant pump 243 are provided below the steam generator and a turbine 267 and a generator 772 are provided between the pressure vessel 813 and the steam generator 810, The cooling water 287 is injected into the condenser 790 and the cooling water is discharged to the waterproof path through the water pump 241 connected to the condenser 790 while the water is supplied to the steam generator 810, Lifting station of power station The nuclear waste disposal unit 811a is provided with a nuclear waste location transfer passage through a double pipe structure piping line 74 for positioning the nuclear power plant in the nuclear reactor facility main body 1, The nuclear waste disposal apparatus and the nuclear waste location transfer passage are provided in the nuclear waste disposal dispensing apparatus by the block piping lines 74 having the dual pipe structure. At the same time, the reactor facility main body 1 of the nuclear power plant, And a plurality of nuclear radioactive contaminants inside the nuclear waste disposal unit 811a of the nuclear power generation facility 811. When the temperature sensor of the safety valve is in operation, To 800 ° C, the temperature and pressure sensor does not send an alarm message to the computer in the safety control room. At the same time, a plurality of temperature-sensing sensor safety valves are opened, and explosive nuclear waste flows through the inner block piping line 74a of the pressure vessel 813 at each location, and nuclear waste The temperature control sensor safety valve 472 connected to the inner block tank at the lower portion of the pressure vessel 813 is opened and at the same time, the outer block piping line 74b is connected to the automatic block- A thermocouple thermometer sensor switch 103 having a connection structure with a flashing warning lamp 99, a pressure gauge 101 and a temperature sensing sensor bimetal 102, a level pressure switch 104 for flow rate check operation and a flow rate meter 105 and a safety valve 472 connection structure of the pipeline automatic pneumatic valve conveying device 916 to form a double pipe structure 45 at an angle of 45 degrees at the upper end of the reactor building 688. [ A plurality of through holes in the piping line 74 are provided with a through hole processing by a laser cutting machine and a construction machine drilling machine while a double pipe structure piping line 74 is formed in a plurality of through holes of the double structure block tank dust collector reactor facility At the same time, a plurality of safety valves 472 are connected to the block piping line 74 by bolts 24 and a gasket 32 to the nuts 25, The outer block tank 599 for storing nuclear waste treatment and the dual structure block tank dust collector reactor unit are combined in a radiation type connection structure in a double structure block tank 598 having a double size of the reactor diameter along the surface, (683) Explosion Control Dispense injector to install reactor installations inside the reactor core (681) and outside the reactor core (681) Nuclear fuel immediately before the reactor explosion (683) Nuclear Power Plant Nuclear Waste Treatment Unit (811a) with Nuclear Reactor Facility Dual structure block tank inside Nuclear Reactor Facility (1) Inside the connecting shaft, a pressurized water reactor reactor facility (803) 593,594,595) Mooring device and diving buoyancy control device of nuclear power plant (672), distribution and input device of nuclear waste disposal, and reactor facility safety operation of nuclear reactor Nuclear power plant nuclear waste treatment section (811a) Double structure block tank dust collector (794) A pressurized water reactor reactor installation (803) inside the nuclear reactor facility is provided to make the operation of the nuclear reactor more possible. As a structure.

(593,594,595) nuclear power plants 672 of the above-mentioned offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5O and 5P, The diving operation ready controllable control and distribution input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor installation of the dual structure block tank dust collector, The input device is provided with a plurality of floating dishes installed on the seabed with an anchor replacement crane 846 as a connection structure in a nuclear plant main body 1 of a nuclear power plant and a floating planting nuclear power plant 672 of a marine power plant Installation of the distribution system of the nuclear power generation facility (811), which is provided as a connection structure, to the top position of the deck deck for hull safety distribution, hull safety devices for operation and construction equipment, The seismic crane boom of the crane (942) is divided into two parts by the connection structure and is connected to the boom hook hook (18) inside the boom frame body. Submarine mineral resources (842) and submarine mineral resources (909) of the submarine mineral resource net (909) is prepared by the connecting structure providing the seaweed mineral resource net (909), and the position of the manganese nodule (909) (909) of the submarine mineral resource manganese nodule (909) of the reactor main body (1) of the marine power plant of the marine power plant of the marine power plant is lifted to the upper part of the deck (SDU) The construction equipment of the tower crane for the construction equipment is replaced by a seismic crane boom zone (942) which constitutes the nuclear waste disposal of the reactor plant main body (1) of the nuclear power plant, Seawater crushing boom area (942) of the tower crane for construction equipment equipments is connected to both sides of the submarine mineral resource by the connection structure of nuclear reactor facility main body (1) of nuclear power plant. The float basket 842 and pallet 844 of the sea bottom surface SLL of the sea surface SLL of the sea surface SLL of the sea surface SLL at the position inside the undersea mineral resource collecting place inside the lower end SDL of the flood- It is necessary to adjust the position of the ship's upper deck (SDU) to the connecting structure of the boat crane boom (942) of the tower crane and to transfer the seabed mineral resource nuclide (909) SDU) to the seesaw crane boom zone (942) of the tower crane, while at the same time, the distribution input unit for operation of the seabed mineral collection and construction machinery is equipped with a floating At the location of the submarine mineral resource collection site in the reactor main body (1) of the cattle, a submerged mineral resource collection is provided as a connection structure for distributing and inputting the suction collection machine (911) and the mineral extraction robot (912) of the mineral resource collection equipment At the same time, it is equipped with a seismic crane boom zone (942) as a connecting structure to control the position shift to the upper part of the floating deck hull deck (SDU), and it is a connecting structure supplied with power generated by the floating oceanic power plant. The main body 1 is connected to a suction collecting machine 911 and a mining robot 912 as a submersible mineral collecting construction machine operation distributing input apparatus. The suction collecting machine 911 and the mineral collecting robot 912 ) And a seized crane boom zone (942) of a tower crane replacing the construction equipment of the lifting device to construct an underwater mineral resource collection;

5O and 5P, as a connection structure between the floating nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant, the distribution input device for operating the seabed mineral collecting construction machine (SLU) equipped with a submarine track wiring (946) as an underwater mineral resource collection site inside the reactor main body (1) of the nuclear power plant of the nuclear power plant (672) SDU) Location of offshore power plant to provide position as a connection structure Lifting of marine power plant receiving power by each mooring device and power generation facility Connection structure between nuclear power plant (672) of nuclear power plant and main body (1) of nuclear power plant Diving (593,594,595) are distributed to the seabed with the adjustment device, and the seats are installed as the connecting structure. Hull safety equipment and construction machinery equipment and marine power plant lifting plant Nuclear power plant (672) and nuclear reactor plant Nuclear power plant's lifting device of main body (1) Construction machinery Replacement tower crane Seisio crane Boom bar (942) At the same time as the collection of resources is being carried out, the seesaw crane boom zone (942) of the tower crane for replacement of the lifting device construction machine crane is installed at the marine power plant of the floating cargo ship at the upper part (SDU) (911) and minerals collection robot (912) inside the reactor main body (1) of the nuclear power plant and the nuclear power plant of the marine power plant (672) (911) and minerals extraction robots (912) of the mineral resource collection equipment and lifting equipment construction machines Phosphorus seesaw be made to the seabed mineral resources collected by the crane boom 942 and configuration;

As shown in Figs. 5o and 5p, as a connection structure between the floating nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant, the distribution input device for operating the seabed mineral collecting construction machine, The manganese which is located as a submarine location connection structure including submarine mineral resource harvesting equipment on the suction collection machine and the minerals collecting robot as the connection structure inside the reactor main body (1) of the nuclear power plant of the nuclear power plant (672) (909) Standing octopus Hull deck top (SDU) Location Connected structure Positioning Moving and connecting structure Construction machinery equipment Separate towers Replacement tower crane Seesaw crane Tower crane (886) with connection structure of boom area (942) A connection structure for connecting the electric magnet magnet 645 and the suction collecting machine provided in the piping line automatic pneumatic transportation device 916 and the manganese nodule 909 The connection structure submarine basket 842 for reclaiming seabed mineral resources and the connection structure palette 844 provided at the position on the top of the floating elevator upper hull deck upper part (SDU) of the elevator alabite 632 and the strut tank upper barge line 591, (SDU) to the upper part of the deck of the ship (SDU), while the submersible mining construction and distribution equipment of the submarine mineral collecting and installation equipment is equipped with the construction machinery equipment Seago crane boom zone (942) connection tower crane replacement tower crane And at the same time the connecting structure of the conveyor 633 is to move the submarine mineral resource located in the bottom of the floating deck hull deck (SDL) to the upper position of the floating deck hull deck upper part (SDU) The submarine mineral resource exploration equipment and the link structure search lamp (232), which are used to search the submarine mineral collecting process state as a link structure, (843) for submarine survey lens glass are provided with a lighting device for positioning the submarine line wiring (946) as a connection structure, and at the same time, a lighting device for a floating power plant (672) of a marine power plant and a nuclear power plant (1) Inside the reactor main body (1) Suction collecting machine and connection structure Mineral collecting robot and submarine mineral resource collecting equipment The above submarine mineral resource collecting equipment included in the connection structure are collecting equipment at the water pressure of the deep sea floor and the flow rate of the deep sea floor As a connection structure between the lever block 123 and the wire rope chain 915 for preventing the loss of the collection equipment at the location inside the seabed mineral resource collecting place after the loss of damage occurs, an alibate for elevator for the submarine diving 632) and submarine excavation equipment location connection structure to prevent loss by collecting equipment binding, but all submarine mineral resource collecting equipment shall be located at submarine mineral resource collection place The position of the wire rope of the lever block 123 is controlled so that the wound wire rope provided on the body of the lever block 123 is wound and unwound while the position of the wire rope connecting structure of the lever block 123 is adjusted. (184) connected to the undersea surveying equipment, while the submarine mineral resource search equipment and the searchlight (232) are connected to the connection structure, (184) that connects the underside camera (184) to a location where the underwater light (843) for underwater exploration lens glass is discharged to the illuminated location. The submarine mineral collection and construction machine operation The distribution dispensing device for the container box 132 of the container box 132 corresponding to the submarine mineral carrier, 129) connected to the hull deck upper part (SDU) of the ship upper end of the sea (SLU) with the unmanned camera (184) Submarine line wiring (946) Lifting of marine power plant provided as a connection structure Connected to the inside of nuclear reactor facility (1) of nuclear power plant (672) and atomic power plant of the nuclear power plant Submerged minerals collecting equipment integrated structure (50) of the internal control server (51) of the internal control server (51) for setting the position of the upper end of the sea surface (SLU) with the submarine line wiring (946) ) And the control board (53) are transferred from the unmanned camera (184) to the marine power generation facility The connection structure of the mineral resource collecting equipments The distribution structure of the operation equipments is equipped with the construction equipments for the seabed, while the mineral resource collecting equipments are able to withstand the water pressure of the deep sea bed and the flow rate of the deep sea bed. The distribution facility of the submarine mineral collection and construction machinery is provided inside the nuclear reactor main body (1), and the mooring device, the diving buoyancy control device and the distribution input device of the nuclear waste disposal device formed in the ocean power plant floating nuclear power plant (672) And the connection axis of the nuclear waste processing pipe manufacturing process (705) of the reactor facility from the Fuzhou Nuclear Power Plant (811) prior to the safety operation of the reactor facilities of the reactor facility, as a connection structure capable of being disassembled and coupled at the marine vessel manufacturing factory .

As shown in FIGS. 5O and 5P, the dual structure block tank (1) of the nuclear power plant (673) of the maritime power plant of the land and ocean and the nuclear power plant of the nuclear power plant (1) The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, The flood control station (672) of the offshore power station and the float crank (846) as anchor replacement crane (846) inside the reactor main body (1) of the nuclear power plant are connected to the seabed as a distribution structure Dependent deck with marine seating of the nuclear power plant installed on the deck Deck to the top of the hull safety distribution Loading hull safety equipment and connection structure Construction equipment connection structure The float 844 is divided into a septic crane boom frame 942 of the tower crane for replacing the quartz crane and a float 844 for the submarine mineral resource reclamation having a connection structure with the hook hook 18, (942) of the seesaw crane boom (942), and the submerged mineral resource collection is carried out by the connection structure of the seismic crane boom (942). The seagoing crane boom is installed at the upper part of the deck hull deck (SDU) (811d) provided as transformers for transmitting the power of the nuclear power plant unit (811) supplied with power generated by an offshore power plant (SDU) provided in a marine power plant. The power transmission unit (811d) The operation of the nuclear reactor main body 1 of the seesaw crane boom zone 942 is configured to collect the seabed mineral resources by the movement control device;

As shown in Figs. 5o and 5p, the distributing and inputting apparatus for operating the submarine mineral collection and construction machinery as a connection structure of the nuclear reactor plant main body 1 of the nuclear power plant of the marine power plant (593,594,595) (942) Connection structure Both sides of the connecting structure Submarine Mineral resources Reclaimed landing basin (842) and Palette (844) Connecting structure Lower part of sea level (SLL) of sea level surface (SLD) (SDU) of the upper end of the sea surface (SLU) in the submarine mineral resource collection place inside the SDL of the hull deck. The seesaw crane boom base (942) And at the same time the seesaw crane boom zone 942 controls the movement of the seabed mineral resource manganese nodule 909 as a connecting structure to the position of the upper part of the floating deck hull deck (SDU) (942) and at the same time, the inside of the reactor facility main body (1) of the nuclear power plant is provided with an intake picking machine and a mineral picking robot of mineral resource collecting equipment in the submarine mineral resource collecting place, 942) is a marine power plant that provides a collection of seabed mineral resources and at the same time has a connection structure to control the position of the floating deck hull deck top (SDU), or to provide a position as a connection structure of the deck top deck (SDU) The power transmission unit 811d is provided as a transformer for transmitting the power of the nuclear power plant 811 supplied with power. The power plant 811d is connected to the main body 1 of the nuclear power plant of the marine power plant, (942) is configured to collect seabed mineral resources with a displacement control device, and the nuclear facility of the marine power plant (1), the seisite crane boom unit (942) distribution dispenser for operating the construction and operation of the seabed minerals and construction equipment is connected to the seabed crane boom unit (942) Upper part of sea surface (SLU) with line wiring (946) Upper part of sea hull deck (SDU) Location of marine power generation facility Replacement towers of different towers Crane seesaws Crane boom area (942) Connection structure Mooring device and connection structure It is provided with a power supply for the flood control connection structure. It is provided with seats on the seabed, and it is installed on the upper deck of the deck deck. The flood control connection structure is used for safety distribution of hull safety devices and construction equipment. A seaside crane boom zone (942) is connected to the submarine mineral resource harvesting equipment. A power transmission unit 811d provided with transformers for transmitting the power of the nuclear power plant 811 supplied with the power generated by the offshore power plant while having a positional shift control to the position of the upper part of the octane hull deck (SDU) (1) operation of the nuclear plant of the marine power plant of the marine power plant as a connection structure is constituted so as to collect the seabed mineral resources by the movement control device of the seesaw crane boom zone (942), and the reactor of the floating power plant of the marine power plant In the distribution input device for operation of the submarine mineral collection construction machine as a connection structure of the facility body (1), the distribution input device for the operation of the construction machine is provided with a suction collection machine and a connection structure mineral collection robot And a manganese nodule (909) connecting structure for providing a location on the seabed including a submarine mineral resource harvesting equipment connection structure. Moving to the upper part of the hull deck top (SDU) Moving to the connecting structure Construction equipment Equipments Replacement towers Replacement towers Crane seats Crane boom (942) Electrical magnet Magnet (645) At the same time that the manganese nodule 909 is transported to the pipeline line conveying device 916 of the collecting machine, the connection structure of the elevator allybeat 632 for the connecting structure is connected to the upper end of the floating tank top barge hull 591, (842) and a pallet (844) for collecting seabed mineral resources, which are provided at the upper end of the SDU, and the distribution dispenser for operation of the construction machine is installed at the upper part of the floating deck hull deck (SDU) Construction Machinery Equipment to Provide Adjustment of Location Movement The marine power generation facility is connected to the seisio crane boom zone (942) of the tower crane for the replacement of each crane, and the conveyor (633) Inside the submarine mineral resource collection site that is located inside the SDL, the conveyor 633 is provided at the upper end of the floating deck hull deck upper part (SDU) The submarine mineral resource search equipment 232 and the deep sea exploration submarine underwater light 843 are connected to each other while providing an illuminating device at a position provided with a submarine line wiring 946. At the same time, (1) Transformers for transferring the power of a nuclear power plant 811 supplied with power generated by a marine power plant of a floating ocean harvesting plant including a suction collecting machine, a mining robot and a submarine mineral resource collecting device in a connection structure (811d) connected to the main body (1) of the nuclear power plant of the marine power plant as a connection structure, 942 made be configured seabed mineral resources collected by positioning control device and;

As shown in Figs. 5o and 5p, the distribution structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593,594,595) of the marine power plant, The unmanned camera 184, which is provided as a connection structure inside the nuclear reactor main body 1 of the floating nuclear power plant of a marine power plant of a marine power plant, is provided with an unmanned camera 184 for searching the state of the submarine mineral collecting process The submarine mineral resource search equipment 232 and the deep sea exploration underwater illumination lamp 843 are connected to the unmanned camera 184 that provides the location to the location where the illumination is emitted to the lighting structure. Container box in a container box Connect the bolt closure device (129) to the unmanned camera (184) to the upper part of the sea surface (SLU) to the upper part of the hull deck (SDU) (946) to the control room of the hull safety facility control room, and the connection structure inside the nuclear reactor main body (1) of the marine power plant's floating nuclear power plant, the intake structure and the mining robot and the submarine mineral resource (SLU) with a connection line of the connection structure including the harvesting equipment connection structure and the sea bottom surface (SLU) with the submarine line wiring (946) Upper end of the ship hull deck (SDU) ) Receiving the undersea mining collecting process state scene transmitted from the unmanned camera 184 into the monitor 52 of the internal control server 51 and the control board 53 and at the same time the seesaw of the tower crane replacing each marine power generation facility Crane boom zone (942) Connected structure Mooring equipment and mineral resource collection equipment Distributing input moving equipment Construction machine Distribution structure to the connection structure and submarine mineral collection construction machine The connection structure that allows the operation of the distribution dispenser to be seated from the sea floor is provided as a connection structure for mineral resource collection equipment. The connection structure for supporting the hydrothermal pressure of the deep sea bed and the flow rate of the deep sea bed, (593,594,595) installed at the ocean power plant (673), the mooring device and the diving buoyancy control device for the nuclear power plant, and the distribution and input device of the nuclear waste disposal and the reactor facility safety operation. (811) as a connecting shaft of the nuclear waste processing pipe manufacturing process (705) of the reactor facility, and a connection structure capable of being disassembled and coupled at a marine vessel manufacturing factory.

As shown in FIGS. 5O and 5P, the dual structure block tank (1) of the nuclear power plant (673) of the maritime power plant of the land and ocean and the nuclear power plant of the nuclear power plant (1) The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, (672) of a marine power plant and nuclear reactor plant main body of a nuclear power plant (1) Distribution system of mineral resources collection equipment Moving device Construction machinery Connecting structure to a location equipped with submarine line wiring (946) The distribution structure of all the mineral resource collection equipment in the seabed and the submarine is provided as a connecting structure that can withstand the water pressure of the deep sea floor and the flow rate of the deep sea floor. The device connection structure The connection structure of the Bellows butterfly valve 305 and the diving control device connection structure doctor ventilation 585 The direct connection between the duct type ventilation port 585a and the doctor ventilation outlet port 585b, Base piping type 582 while the distribution input device of the nuclear power generation facility 811 is provided with the pressure air generated by the air compressor 80 of the prime mover and at the same time is provided with a single- The pneumatic instrumentation is set by the driver in the timer 541 with an indication of overpressure prevention scale, or the air cylinder 138 equipped with the connection structure to the fire damper 583 automatically, without being manually depressed, And at the same time, the damper spindle 584 connection structure provides the pressure air while the fire damper 583 performs the full closing and expansion within the doctor ventilation 585, The fire damper 583 is provided with devices for controlling air supply and air supply, but may be connected to a pipeline line automatic pneumatic conveying device 916 such as a pipeline line diving control device The connection structure provided with or provided with a connection structure such as the butterfly valve 305 is a diving control device of the reactor installation main body 1 of a floating type docking nuclear power plant of a marine power plant, (672) of the offshore and offshore marine power plants and the reactor structure main body of the nuclear power plant (1) and the nuclear power generation facility (811) of the offshore and offshore marine nuclear power plants, The diving preparation ready operation control and distribution input device for the hull safety equipment constituting the connection axis position of the pipe manufacturing process 705 is connected to the distribution input device of the nuclear power generation facility unit 811 The solenoid valve overpressure (pressure) of each solenoid valve 76, which is supplied with the compressed air generated in the air compressor 80 of the prime mover into the nuclear reactor facility main body 1 of the nuclear power plant, When the on-time main switch button 66 of the solenoid valve start switch button main switch button 66 is pressed by hand, the butterfly valve 305 is opened and the main switch button When the off-time main switch button 66 of the start switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is fully closed to provide an operation interruption, When the switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is opened to allow the pressurized air generated in the air compressor 80 to perform the operation through the pipeline connection structure, A connection structure for providing a connection structure to a door 154 and a plurality of hatch cover 153 main bodies includes a solenoid valve overpressure prevention switch (not shown) of a solenoid valve 76 of a reactor installation main body 1 of a floating power plant of a marine power plant (593,594,595) nuclear power plants (672) of the land and marine marine power plants and the nuclear reactor main body of a nuclear power plant (1) nuclear power plants The diving operation ready controllability control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor installation of the dual structure block tank dust collector of the facility unit 811, The hydraulic control rotary cylinder 35 as the connection structure between the floating rotary feeder nuclear power plant 672 of the marine power plant and the nuclear reactor plant main body 1 of the nuclear power plant At the same time, a plurality of fire doors (154) and a plurality of hatch cover (153) connection structures are opened in the connection structure, so that mineral resources provided in the submarine mineral collection site are collected in the bottom tank barge hull (592) The vacuum pump 635 for conveying and lifting apparatus, and the power cable 71 are connected to each other through a connection structure. In addition, the distribution input device of the nuclear power generation facility unit 811 is provided with a start switch When the on-time main switch button 66 of the main switch button 66 for the button is manually depressed, the vacuum pump 635 is rotated. However, the distribution input device of the nuclear power generation facility unit 811, Mineral resources provided at the submarine mineral collection site located outside the body of the holding tank bottom barge hull (592) are the connecting structure that provides the position movement to the inside of the body of the barge hull (591) (1) inside the nuclear reactor plant of the buoyant reprocessing nuclear power plant, the hydraulic control rotary cylinder (35) for the electronic control;

As shown in Figs. 5o and 5p, the distribution installation device for operating the submarine mineral collection and construction machine as a connection structure of the reactor facility main body 1 of the floating power plant of the marine power plant includes a diving position- The connecting structure selected as the connecting structure diving buoyancy control weight (206) is to replace the submarine mineral resource connection structure to provide the hull safety facility, or to adjust the submersible docking position of the hull and the connecting structure submarine mineral resources for diving buoyancy control. (SDU) Upper position of the upper deck (SDU) of the sea surface Upper part (SDU) of the upper part of the sea surface (SDU) The marine power generation facilities that provide the location of each quay Alternative tower Crane seesaw crane Boom bar (942) Connection structure Mooring device (1) of the marine power plant's buoyant pilot nuclear power plant is composed of a distributing and inputting device for the operation of the construction machinery, and the marine power plant (593,594,595) Nuclear power plant nuclear reactor facility The connection structure of the main body (1) The submarine mineral collection system The distribution and input device for the operation of the construction machine, the minerals resources of the distributing and inputting device for operating the submarine mineral collection construction machine, Tank bottom barge hull (592) Hull connection structure in the hollow space inside the body Submersible position control Mobile device and diving buoyancy control rod (949) replace the submarine mineral resources, The lower tank barge hull (592) of the holding tank, a plurality of fire doors and a plurality of hatch covers A connection structure connecting shaft having a connection structure to a pipeline automatic pneumatic conveying device 916 through which the pipeline line 153 passes, and a connection structure with a ballast butterfly valve 305 of the diving control device of the pipeline At the same time, the connection structure of the solenoid valve overpressure prevention switch 108 of the connection structure solenoid valve 76 and the main switch button 66 of the solenoid valve start switch button is provided with a connection structure by the connection structure of the power line 71, (1) Inside of the ship tower Replacement tower Cranes of the crane Cranes Boom bar (942) As a connection structure Mineral resource collecting equipment Distributing input Moving equipment Distribution equipment to the submarine (SDU) top connection structure at the top of the sea level (SLU). (942) of the tower crane in the marine power generation facility tower tower crane (942) Connected structure Power plant facility equipped with mooring device and connection structure and connected structures at the submarine mineral gathering place, (593,594,595) installed at the ocean power plant (673), the mooring device and the diving buoyancy control device for the nuclear power plant, and the distribution and input device of the nuclear waste disposal and the reactor facility safety operation. (811) as a connecting shaft of the nuclear waste processing pipe manufacturing process (705) of the reactor facility, and a connection structure capable of being disassembled and coupled at a marine vessel manufacturing factory.

As shown in FIGS. 5O and 5P, the dual structure block tank (1) of the nuclear power plant (673) of the offshore and offshore marine power plants (593,594,595) and the nuclear power plant main body (1) The pressurized water reactor reactor facility 803 of the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the reactor facility constituting the dust collector reactor facility,

The pressurized water reactor reactor facility 803 of the connecting shaft of the nuclear power generation nuclear waste processing unit 811a is connected to the floating nuclear power plant 672 of the marine power plant and the nuclear reactor facility main body 1 of the nuclear power plant, A nuclear waste disposal dispenser with a tank dust collector 794 and a fuel 683 explosion control dispensing dispenser A method of disposing a plurality of nuclear reactor facilities on a barge of an anti-sunken dual structure block tank, Of the sea surface with 40 m above sea level to prevent the submergence of the submerged barge line reactor installation with the installation position of the distribution and input device of the nuclear power generation facility 811. Nuclear power plant leak detection control dual structure block tank that prevents multiple nuclear reactors from exploding To provide a pressurized water reactor nuclear plant 803. In the oscillator 794 configured reactor equipment be made movable and the original reference;

5O and 5P, the pressurized water reactor reactor facility 803 of the connection shaft of the nuclear power generation nuclear waste processing unit 811a generates high-temperature water without generating steam by applying pressure to the steam generator 810, The water and the steam 780 are exchanged with each other so that the steam turbine is rotated and the inside of the pressurized water reactor 803 is filled with the fuel and water and the control rod 798 and the pressure vessel 813 side A steam generator 810 and a coolant pump 243 are provided below the steam generator and a turbine 267 and a generator 772 are provided between the pressure vessel 813 and the steam generator 810 The cooling water 287 is injected into the condenser 790 and the cooling water is discharged to the waterproof path through the water pump 241 connected to the condenser 790 while the water supply to the steam generator 810 is performed, Nuclear power plant A double pipe structure piping line (74) for positioning the inside of the nuclear reactor main body (1), and a nuclear waste locating passage for the nuclear waste locating movement control device to connect the nuclear radioactive pollutants to the nuclear waste nuclear waste treatment section (811a) So that the nuclear waste disposal apparatus and the nuclear waste location transfer passage are provided as the nuclear waste disposal dispensing apparatus by the block piping lines 74 having the double pipe structure, and at the same time, the connection axis of the reactor facility main body 1 of the nuclear power plant; And

As shown in FIGS. 5O and 5P, the nuclear power generation nuclear waste disposal unit 811a of the nuclear power generation facility 811 includes a plurality of temperature radioactive pollutants, and a temperature pressure sensing sensor of the safety valve is activated If the risk of high-temperature and high-pressure inside the reactor reaches 700 to 800 degrees Celsius, the temperature and pressure sensor will transmit the alarm message to the computer in the safety control room. At the same time, The nuclear waste is passed through the inner block piping line 74a of the pressure vessel 813 and the nuclear waste is stored in each of the double structure block tanks and the pressure sensor 813 is connected to the inner block tank. At the same time as the safety valve 472 is opened, the outer block piping line 74b is connected to the fuel block explosion prevention control The thermocouple thermometer sensor switch 103 having a connection structure with the automatic injector flashing warning lamp 99, the pressure gauge 101 and the temperature sensing sensor bimetal 102, the level pressure switch 104 for flow rate check operation, The flow check flow meter 105 and the safety valve 472 connection structure of the pipeline automatic pneumatic valve transport apparatus 916 are provided to connect the upper end of the reactor building 688 to the upper end of the dual pipe structure piping line 74 A plurality of through holes are formed through the laser cutting machine and the construction machine drilling machine while simultaneously forming the double pipe structure piping line 74 in the plurality of through holes of the double structure block tank dust collector reactor facility, Valves 472 are provided on the block piping line 74 with flange connections to the bolts 24 and the gasket 32 to the nuts 25 and at the same time the reactor diameter 2 In one double structure block tank 598, the outer block tank 599 for nuclear waste processing storage and the dual structure block tank dust collector reactor unit are connected to the nuclear waste disposal dispensing apparatus and the nuclear fuel assembly 683) Explosion control distribution dispenser with nuclear reactor facility installed inside nuclear reactor core (681) and nuclear reactor (681) with explosion prevention control items just before nuclear reactor explosion (683) (811a) equipped with nuclear reactor dust collector dual tank reactor dust collector, a pressurized water reactor reactor installation (803) is installed in the connection shaft, and a mooring structure (593,594,595) installed at a marine power station floating turbine Equipment and diving buoyancy control equipment and nuclear waste disposal Dispensers and reactors Reactor facilities Safety operations Before the operation of the atomic power plant (811) Power plant nuclear waste treatment unit (811a) Double structure block tank dust collector (794) Discharge at the marine vessel manufacturing plant by providing a pressurized water reactor reactor facility (803) It is preferable to include and configure it as a linkable structure.

Referring to FIG. 5q, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of nuclear power plant of land and ocean marine power plant and reactor cooling facility (804) of nuclear power plant, (1) Inside flood control system A plurality of nuclear reactor facilities A floating oceanic power plant showing the construction of the nuclear power plant Operation of nuclear power plant (672) and a nuclear cooling power plant equipped with a gas cooling furnace reactor (804) Configuration,

Referring to FIG. 5R, an embodiment of the nuclear power plant 811 is installed in the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of nuclear power plant of land and ocean marine power plant and reactor cooling facility (804) of nuclear power plant, (1) Inside flood control system A plurality of nuclear reactor facilities A floating oceanic power plant showing the construction of the nuclear power plant Operation of nuclear power plant (672) and a nuclear cooling power plant equipped with a gas cooling furnace reactor (804) Configuration Road,

As shown in FIGS. 5q and 5r, it is preferable that the nuclear power plant 672 of the marine power plant of the land and sea is installed in the reactor main body 1 of the nuclear power plant, The gas cooling furnace reactor facility 804 constituting the double structure block tank precipitator 794 for treating the nuclear waste of the nuclear power generation nuclear waste processing unit 811a of the connection shaft is connected to the nuclear power generation nuclear waste processing unit 811a The gas cooling furnace reactor facility 804 constituting the dual structure block tank dust collector 794 for treating the nuclear waste of the connection shaft is connected to the inside of the nuclear reactor facility main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant Nuclear Waste Dispensing and Discharging Apparatus with Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector 794 and Nuclear Fuel Explosion Control Distribution Dispensing Apparatus A plurality of nuclear reactor facilities are connected to an off- The installation of the barge line and the installation position of the distribution and input device of the nuclear power plant (811) are set up at the top of 40m above sea level so as not to be restricted by the weather conditions of the earthquake and tsunami. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant The nuclear reactor power plant 811a of the nuclear power generation facility 811 is connected to the nuclear power plant 811a of the nuclear power generation facility 811a through a gas cooling furnace 804 installed in the connection shaft of the nuclear power generation nuclear waste treatment unit 811a, In the gas-cooled furnace facility 804 constituting the double structure block tank dust collector 794 for the axial nuclear waste treatment, The nuclear power plant (811a) of the nuclear power plant (811a) of the nuclear power plant (811a) is connected to the nuclear power plant (672) Double Structure Block Tank Dual Structure Block Tank Dust Collector (794) Among Radioactive Nuclear Waste Treatment Reactor Facilities In the gas cooling furnace reactor facility (804) that is equipped with reactor facilities, graphite is provided with a moderator (676) 816 may be provided with a gas cooling furnace reactor 804 with carbon dioxide 164 and the use of natural uranium 812 and enriched uranium 235 812 for the fuel of the nuclear reactor 804, , And a carbon dioxide coolant (816) at the same time, it is possible to provide a high-temperature and high-pressure steam having a strong gas condition, or to provide a nuclear power plant with a thermal efficiency equal to the thermal power, A gas cooling furnace reactor 804 constituting the turbo block tank dust collector 794 is formed on the circumference of the gas cooling furnace reactor facility 804 of the nuclear power plant reactor facility, Double Structure Block Tank Radioactive Nuclear Waste Treatment Reactor Facility and Nuclear Fuel 683 Nuclear waste treatment unit 811a equipped with double structure block tank dust collector reactor facility inside reactor body 1 of nuclear power plant with explosion prevention control equipment In the shaft, a gas cooling furnace reactor installation (804) is provided, and at the same time, a mooring device, a diving buoyancy control device, a distribution input device and a reactor installation device for nuclear waste treatment, which are formed in a nuclear power plant (672) (811a) Nuclear power generation nuclear waste treatment unit (811a) Double structure block tank dust collector (794 ), And a connection shaft for constructing a reactor cooling facility (804) to be installed inside the nuclear reactor facility to further operate the nuclear power plant, as a connection structure capable of disassembling and coupling at a marine ship manufacturing factory.

As shown in Figs. 5q and 5r, the double structure block tank (1) of the nuclear power plant (673) of the offshore and offshore marine power plants (593,594,595) and the nuclear reactor plant main body The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, The submarine mineral resource collecting equipment distributing and inputting device is connected to the inside of the nuclear reactor plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the offshore power plant is connected to the upper side surface position of the upper barge hull 591 of the strut block tank 590, 500 meters long, double structure block tanks are used to connect multiple tanks. The manganese nuclides (909) of reserves of 100 million tons are located at 5000 meters underwater around the world including the Pacific Ocean. The connecting structure having the connection structure to the inner position of the distribution box connecting structure container box of the landing basket 183 and the nuclear power generation facility section 811 is composed of an air pocket 849 for the seabed mineral garden and a seesaw crane The undersea mineral resource collecting yard basket 842 and the pallet 844 connection structure for distributing both sides of the boom bridge structure 942 and providing a position to the hook hook 18 of the seesaw crane boom frame 942 of the tower crane, (842) and Palet (844) connecting structures for collecting seafloor mineral resources on both sides of the tower crane (942) are connected to the lower part of the sea bottom (SLD) of the sea surface (SLL) (SDU) at the upper part of the sea surface (SLU) to the upper part of the deck (SDU) of the floating deck hull at the location of the submarine mineral resource collection site, or to transport the manganese nodule (909) At the same time, it is necessary to adjust the position of the SDU to the position of the submerged mineral resource collection site within the reactor main body 1 of the floating power plant of the marine power plant, The distribution input device of the nuclear power generation facility unit 811 is located at the upper end of the sea level upper end portion (SLU) upright posture hull deck upper part (SDU) which provides the position with the connection structure submarine line wiring 946 (942) Connection structure of mooring system Floating plant of marine power plant which allowed to install flood control station (593,594,595), which was supplied with power generation facility, on the seabed The seepage crane boom base 942 of the tower crane at the lower end of the sea surface provided inside the reactor installation main body 1 of the reactor vessel main body 1 is divided into submarine mineral resources and submarine mineral collection (1) of the marine power plant's nuclear power plant (1), and the marine power plant (593,594,595) of the nuclear power plant is constructed as a connection structure for providing the distribution input device of the nuclear power generation facility (811) The distribution input device of the nuclear power generation facility 811 of the mineral resource and the lifting device lifted by the floating picket hull collecting device as a connection structure of the nuclear reactor facility main body 1 of the nuclear power plant 811, A hydraulic cylinder 39 is operated as a connecting structure inside a reactor facility main body 1 of a floating planted nuclear power plant of a marine power plant, and hundreds of tons of manganese nodules 909 generated annually are supplied to the inside of the reactor installation main body 1 (591), which is located at the top of deck deck, and a seized crane boom base (942) of tower crane, which is located at the top of deck deck. Hydraulic cylinder machine (624) At the same time, the hydraulic cylinder machine 624 internal equipment includes a load-and-piston seal 822, a piston seal 823, a booster seal 824, a wear ring 825, a slide ring 826, A backup seal 830 and a load seal and backup seal 831 and a mist seal 832 and a pin seal 833 and a multistage seal 834 and a bushing 828, a load seal 829, a backup seal 830, 835 and the piston ring 836 and the multistring 837 are provided with a hydraulic cylinder machine 624 for distributing and supplying the nuclear power plant 811. The high pressure hose 190 and the high pressure piping and the solenoid The connecting shaft of the coupling with the valves 76 and the piston in the hydraulic cylinder machine 624 are moved forward and backward while the holding tank upper barge hull 591 is moved to the upper position of the deck deck, The crane boom zone 942 is connected to the manganese nodule 217 by the hydraulic cylinder machine 624, The submarine mineral resources recovered to the top of the upper part of the floating deck hull deck (SDU) are provided with the nuclear power plant 811, (SLU) equipped with submarine line wiring (946) Upper part of the sea surface (SDU) Marine power generation facility Alternative towers for seaports Replacement tower Cranes Seisoka Crane Boom area (942) Mooring system of connecting structure (1) of the nuclear power plant The connection structure for providing the power generation facility of the nuclear power plant is provided with the distribution input device of the nuclear power generation facility (811) inside the nuclear power plant main body (1) of the nuclear power plant, (593,594,595) Mooring devices, diving buoyancy control devices and nuclear waste disposal devices installed in nuclear power plants (672) After the safety operation before during nuclear power seolbibu 811 connecting shaft of the nuclear waste disposal tube manufacturing process 705 of the nuclear reactor plant in; included in the connection structure possible decomposition combined in a marine vessel into a manufacturing plant, and is composed.

As shown in Figs. 5q and 5r, the double structure block tank (1) of the nuclear power plant (673) of the offshore and offshore marine power plants (593,594,595) and the nuclear reactor plant main body The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, (672) of the ocean power plant and the blast furnace distributing and inputting apparatus for the mineral resource heat treatment operation are connected to the internal structure of the reactor facility main body (1) of the nuclear power plant of the marine power plant and the floating nuclear power plant of the nuclear power plant (672) (SDU) Upper deck (SDU) Upper marine power generation facility Replacement towers for individual towers Crane seesaw crane Boom bar (942) Mooring system with connecting structure Connected structure Submarine mineral resource lifted by power generation facility Subsea line wiring (946) Seaport replacement tower crane Seisio crane Boom stand (942) Body connection structure Submarine to inner boom hook hook (18) (842) and a pallet (844) for harvesting mineral resources. However, both side connection structures of the seesaw crane boom stand (942) of the tower crane are provided with a yard basket (842) (SLD) of the sea surface (SLL) to the position of the SDU of the upper part of the sea surface (SLU) to the upper part of the deck of the hull deck (SDU) in the submarine mineral resource collection place inside the lower part of the deck At the same time, the distribution input device of the nuclear power generation facility 811 is provided with the control of the movement of the seabed mineral resource manganese nodule 909 to the upper part of the floating deck hull deck (SDU) The distributing and inputting apparatus of the entire facility unit 811 is composed of an upper part of a sea surface (SLU) having a connection structure with a submarine line wiring 946, an upper part (SDU) of an oceanic power generating facility, and a seesaw crane boom part 942 of a tower crane Mooring device and marine power plant lifting plant Nuclear power plant's nuclear reactor facility Connected structure inside the main body (1) As a connection structure to provide the power plant equipment, the reactor main body of the nuclear power plant is made into the furnace distributing and inputting device for operating the mineral resource heat treatment. (1) of a nuclear power station of a marine power plant, the furnace distributing and inputting apparatus for operating the mineral resource heat treatment is composed of a reactor main body 1 of a nuclear power plant of a marine power plant (593,594,595) ) Inside the submarine mineral resource collection site, the inhalation collection machine and mineral extraction robot of mineral resource collection equipment are distributed and placed (948) provided with a furnace which is located at the upper end of the upper part of the floating deck hull deck (SDU) while at the same time being equipped with a locating movement conveying unit ) The operation of the furnace (948) that produced the steel plate (597) and the guide rail (618) of high-strength stainless steel by injecting seabed mineral resource manganese nodule (909) into the inside of the body, And a connecting structure for providing the guide rail 618 for the block tank hull transportation device inside the reactor facility main body 1 of the nuclear power plant includes the production and supply of the iron plate 597 and the guide rail 618 Nuclear waste treatment dual structure block with connection shaft of structure block tank pipe bridge 937 Double block internal tank tank 596 internal structure of double structure block tank 598 connected by pipe bridge 929 Inside bottom position connection structure The furnace distributing and charging device for operating the mineral resource heat treatment is provided with a guide rail 618 disposed at an inner position of the inner block tank 596 having an internal train 771 for a marine tunnel device of 100 KM / Is provided inside the nuclear reactor main body 1 of the nuclear power plant as a connection structure for transporting the material of the steel plate 597 of the high-strength stainless steel and the guide rail 618 to the electric motor 771 for providing the power to the marine power plant Mooring and diving buoyancy control devices and nuclear waste disposal equipment and nuclear reactors installed in the Nuclear Power Plant (672) at Nuclear Power Plant (Nuclear Power Plant) (811) And a connecting shaft of the first shroud 705 as a connection structure capable of being disassembled and coupled at a marine vessel manufacturing factory.

Referring to FIG. 5, an embodiment of the nuclear power plant 811 is installed in the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multi-purpose high-temperature gas furnace reactor facilities (805). (1) In-house flood control system A number of nuclear reactor facilities A floating nuclear power plant (673) and a nuclear power plant are equipped with a multipurpose hot gas furnace reactor facility (805) Side cross-sectional strabismus configuration Road,

5t, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plants (672) and nuclear power plants are equipped with multi-purpose high-temperature gas furnace reactor facilities (805). (1) In-house flood control system A number of nuclear reactor facilities A floating nuclear power plant (673) and a nuclear power plant are equipped with a multipurpose hot gas furnace reactor facility (805) Side cross-sectional strabismus configuration Road,

As shown in Figs. 5S and 5T, it is preferable that the nuclear power plant 672 of the marine power plant, the nuclear power plant 671 of the ocean power plant, and the nuclear power plant 811 of the nuclear power plant, The multipurpose hot gas furnace reactor 805 constituting the dual structure block tank dust collector 794 for treating the nuclear waste in the connection shaft of the processing unit 811a is connected to the multipurpose hot gas The reactor facility 805 is provided with a nuclear waste disposal dispensing apparatus 804 having a flood control station 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant. And nuclear fuel (683) Explosion control Distribution input device It is necessary to install a large number of reactor facilities on the barge of an anti-sink structure of double structure block tank of the ocean, and to be restricted by weather condition of earthquake and tsunami (811a) at the nuclear power plant (811) at the top of the sea level, which is 40m above sea level, and the installation position of the distribution shaft of the connection shaft of the nuclear power generation nuclear waste treatment unit (811a) Safety building equipment for safe operation Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant (811) Nuclear power plant nuclear waste disposal unit (811a) Multi-purpose high temperature gas of connection axis is used to prepare nuclear reactor facility (805) to operate nuclear power plant;

As shown in FIGS. 5S and 5T, in the multipurpose hot gas furnace reactor 805 constituting the double structure block tank dust collector 794 of the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility 811, The use of graphite as the moderator 819 and the use of the helium gas 176 as the coolant 816 while simultaneously providing the use of enriched uranium 812 and thorium for the fuel, 176 are transferred to the water to separate the water and the steam 780 from the steam drum 792 where the steam 780 is generated and at the same time the steam 780 is supplied to the turbine 267 through the pipe (593,594,595) of the marine power plant while providing the electric power production within the generator (772) by the rotation of the turbine (267) and the connection axis of the nuclear reactor facility main body (1) of the nuclear power plant The generation nuclear waste disposal unit 811a (74) Nuclear waste location movement path is provided to regulate the movement of nuclear waste, but nuclear radioactive contaminants are stored in a number of temperature and pressure sensor sensors When the temperature and pressure sensor of the valve reaches a dangerous state of 700 to 800 degree high temperature and high pressure inside the nuclear reactor while the nuclear power plant is operating, the temperature and pressure sensor sends an alarm message to the computer of the safety control room, The detonated nuclear wastes are passed through the inner block piping line 74a of the pressure vessel 813 at each point while opening each of the temperature and pressure sensing sensor safety valves and the nuclear waste The temperature-sensing-sensor safety valve 472 connected to the inner double structure block tank at the lower end of the pressure vessel 813 is opened, (683) explosion prevention control fuel material explosion prevention control article stored in the inner block tank is connected to the automatic injector flasher warning lamp (99), the pressure gauge (101) and the temperature sensor bimetal (102) ), A thermostat thermometer sensor switch 103 with a connection structure, a level pressure switch 104 for flow rate checking operation, a flow valve for flow rate checking 105, and a safety valve for pipeline automatic pneumatic valve transport device 916 A plurality of through holes are formed in the upper end portion of the nuclear reactor building 688 at a predetermined angle of 45 degrees by a laser cutting machine and a construction machine drilling machine to form a through hole, The block pipe line 74 is formed while the double pipe structure block piping line 74 is formed in the through hole and the flange is connected to the plurality of safety valve 472 facilities by the bolts 24 and the nuts 25 and the gasket 32, At the same time, A double structure block tank dust collector 794 having a diameter twice the diameter of the reactor building 688 along the outer wall surface of the building 688 is provided with an outer block tank 599 for storing and storing the nuclear waste, (683) Explosion Control Distribution Apparatus for Reactor Installations Reactor Installations Inside Reactor Inside Core (681) Outside Core (681) Nuclear Fuel Before Explosion (683) Explosion Prevention Control Equipment (1) of the nuclear power plant in the offshore and offshore, and at the same time, provided with nuclear fuel explosion-proof control articles, the explosive nuclear fuel explosion of the reactor main body (1) of the nuclear power plant (794) distribution of nuclear reactor radiation leakage control of nuclear reactor waste disposal system and nuclear reactor facilities, which form nuclear power plant operation, Dual structure block tank (794) to prevent nuclear fuel explosion prevention inside nuclear reactor main body (1) of floating nuclear power plant of both power plants. (794) Multi-purpose high temperature gas reactor installation (805) , And the mooring device, diving buoyancy control device and nuclear waste disposal dispenser and nuclear reactor facilities installed in the marine power plant floating feeder nuclear power plant (672) (794) Nuclear power plant (811) Nuclear power plant nuclear waste treatment unit (811a) Multi-purpose high temperature gas reactor facility (805) into reactor facility Which are connected to each other in the marine vessel manufacturing plant.

(593,594,595) nuclear power plants 672 of the offshore and offshore marine power plants and nuclear power plant main body 1 of the nuclear power plant as shown in FIGS. 5S and 5T. The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, In the reactor installation of the nuclear power plant constituted by the floating nuclear power plant 672 of the marine power plant and the nuclear reactor main body 1 of the nuclear power plant, a plurality of nuclear reactor radiation leakage control dual structure block tank dust collectors 794, A plurality of outer block tanks 599, a first auxiliary steel pipe 600 for a block tank and a second auxiliary steel plate 601 for a block tank are provided outside the plurality of inner block tanks 596, Direct The first auxiliary steel pipe 600 for the block tank, the second auxiliary steel plate 601 for the block tank, the vertical partition wall 605, and the horizontal support wall 605, the horizontal partition wall 609 and the steel beam 149, It is also possible to provide a machining cut with a computer laser cutter 954 for each of the partition 609 and the steel beam 149 and the snap hole 602 and the partition wall manhole 610, The fifth guard wall distributor and the fuel explosion control distribution dispensing apparatus formed along the outer wall circumferential surface of the fourth protective wall containment vessel 808 are provided with the nuclear reactor radiation leakage control dual structure block tank dust collector (794) Facility of marine power plant Nuclear power plant of nuclear power plant Nuclear power plant Nuclear power plant Nuclear waste treatment shielding device Dual structure block tank dust collector (794) In the distribution input apparatus of the power generation facility unit 811 A vertical partition wall 605 in which a diaphragm manhole 610 is formed inside a reactor installation main body 1 of a floating planted nuclear power plant of a marine power plant and a horizontal partition wall 609 and a communication device hydraulic cylinder door 624 and an emergency staircase 631, A nuclear reactor plant main body 1 of a floatation type nuclear power plant is provided in the welding process and a hydraulic cylinder door 624 for preventing explosion of the reactor and an emergency staircase 631 are provided in the double structure block tank dust collector 794, ) Reactor facility nuclear radiation leakage control dual structural block tank dust collector (794) In case of renovation inside and outside, it is equipped as a transportation device to constitute the operation of the nuclear power plant as a nuclear waste disposal screening device of nuclear power plant;

As shown in FIGS. 5S and 5T, a plurality of stopper steel plates 625 are connected to a cylindrical double structure block tank 598, a plurality of inner block tanks 596, And a plurality of outer block tanks 599 are individually welded to the upper and lower ends of the double structure block tanks. The double structure block tank dust collector 794 and the large flange bolt connection double structure block tank dust collectors 794 are connected to the double structure The block tank dust collector (794) may be in the form of an egg, or may be equipped with a plurality of reactor nuclear waste (224) disposal input devices and nuclear fuel explosion control distribution input devices into the nuclear reactor main body (1) The facilities are divided into the reactor facility by the barge hull 591 at the upper end of the holding tank and the barge hull 592 at the lower end of the holding tank, or a plurality of reactor facility bodies 1 of the floating planting nuclear power plant of the marine power plant The reactor nuclear waste 224 reactor and the nuclear fuel explosion control apparatus are provided with a plurality of stopper plates 625 to constitute the nuclear reactor main body 1;

As shown in FIGS. 5S and 5T, a plurality of inner block tanks and a plurality of outer block tanks 794 are provided in the distributor / dispenser double structure block tank dust collector 794 of the nuclear power generation facility unit 811, At the same time, the reactor floor of the double structure block tank precipitator 794 is provided with a reinforcing concrete mat 225 having a thickness of the road surface lower surface (GLD) The barge hull 591 at the upper end of the holding tank is replaced with the reactor building 688 outside the inner block tank 596 having a single fuel explosion-proof double structure block tank dust collector 794 The nuclear fuel pellets 683 are installed in the third wall of the reactor main body formed by introducing the reactor facilities of the nuclear waste disposal shielding apparatus of nuclear reactors of nuclear power plants of the nuclear power plants on land, And simultaneously a nuclear fuel explosion control dispensing apparatus and a dual structural block tank dust collector 794 are installed to supply a plurality of nuclear reactor nuclear waste disposal dispensing apparatuses and nuclear fuel explosion control distributing apparatuses into the nuclear reactor main body 1 of a floating nuclear power plant of a marine nuclear power plant. A double structure block tank sorter 794 for supplying power to the nuclear reactor radiation leakage control dual structure block tank dust collector 794 while generating electric power;

As shown in FIGS. 5S and 5T, a large amount of radiation is generated inside the nuclear reactor installation of the nuclear reactor main body 1 of the floating nuclear reactor of the marine nuclear power plant in the distribution and injection apparatus of the nuclear power generation facility unit 811 Wherein the reactor installation includes a nuclear fuel explosion control dispensing device and a cladding for providing a first wall pellet and a second wall fuel rod protection to ensure safety, a third wall reactor pressure vessel, a fourth wall containment vessel, Reactor Concrete Mat (225) Reinforced Concrete Mat (688) Reinforced Concrete Mat (225) Double structural block tank dust collector (794) replacing five layered protective walls is equipped with a distributing and dosing device and a nuclear fuel explosion control dispensing device. Nuclear Power Generation in the Nuclear Reactor Facility (1) A number of nuclear reactor facilities are installed on the barge hull (591) at the upper end of the holding tank with double structure block tank reactor buildings (688) And at the same time, the barge hull 592 at the lower end of the holding tank is provided with a nuclear fuel explosion control distribution dispensing apparatus dual structure block tank dust collector 794 such as a nuclear reactor facility of a land nuclear reactor. And the nuclear radiation leakage control dual structural block tank dust collector 794 is installed to operate the nuclear power plant;

As shown in FIGS. 5S and 5T, the steam generator 810 and the steam drier 786, which are installed outside the reactor pressure vessel 813, are connected to the distributor / dispenser of the nuclear power plant 811, A plurality of through holes 808 are formed at an angle of 45 degrees at an upper end portion of the nuclear reactor building 688 corresponding to the fifth wall and the containment vessel 808 corresponding to the fourth wall of the distribution and injection apparatus of the nuclear power generation facility unit 811, Holes are formed by cutting machines and construction machines, while a double pipe structure block pipe line 74 is formed in the plurality of through holes, and at the same time, the reactor facility arranges a plurality of safety valves 472 in the block piping line 74, The nuclear power plant 811 may be provided with a flange coupling connection by a nut 24 and a nut 25 and a gasket 32. Alternatively, (794) facility is a double-diameter A combination of the outer block tank 599 for storing the nuclear waste treatment and the block piping line 74 of the radiation type double tube structure is provided at one place of the double structure block tank 598, Control the nuclear radiation leakage of the reactor plant with explosion control dispensing devices; configure the nuclear plant to operate with a dual structure block tank scrubber (794);

As shown in FIGS. 5S and 5T, the dual structure block tank reactor building 688 is provided with a plurality of inner block tanks 596 and a plurality of outer block tanks 599 ) Each of the nuclear fuel explosion control dispensing apparatus is provided with a loess (158) cement mixing equipment mixer machine 649 so as to provide the input to a pressure vessel 813 such as a furnace immediately before a nuclear reactor explosion, The control agent cooling water 287 and the loess mixture of the loess mixture 927 are injected into the pressure vessel 813 at the same time by injecting the fuel explosion prevention control article into the automatic injector double structure fire- Automatic injection device that cleans internal cleaning of reactor facilities before earthquake occurs A plurality of double structure fire-fighting nozzle nozzles (10) are formed inside the pressure vessel (813) body and inside the containment vessel (808) this Automatic reactor injector with no double structure firepipe nozzle (10) and internal combustion engine with explosion-proof double structure block tank dust collector (794) nuclear fuel explosion A double structure block tank of a plurality of nuclear reactor equipments installed in a nuclear reactor plant main body 1 of a nuclear power plant, which is provided with a control distribution dispensing apparatus and nuclear fuel explosion prevention control articles, and a nuclear reactor radiation leak control dual structure block tank dust collector 794 And nuclear waste disposal and dispensing apparatus at the time of renovation of the outside, and the explosion prevention control equipment of the nuclear reactor facility before and after the safe operation of the nuclear reactor facility is put into operation so as to operate the nuclear power plant;

As shown in FIGS. 5S and 5T, the inside of the reactor installation of the nuclear power plant 811 is internally cleaned by the cooling water 287, the piping line 352, The mixture of the yellow loess mixture and the yellow mortar mixture mixer machine (649) is prepared in the cooling water (287) forming the circulating water pump (242) for connecting and connecting the loess mixture to the solidification, (287), a mixture of loess and loess is put into the pressure vessel (813) at the same time to clean the inside of the nuclear reactor immediately after and immediately after the earthquake. At the same time, A nuclear reactor waste containing nuclear reactor radiation leak control dual structure block tank dust collector (794) that can prevent the explosion of the reactor to maximize safety operation of the nuclear reactor facility And a nuclear fuel explosion control distribution dispensing device installed in the reactor main body (1) of the nuclear power plant, the nuclear fuel explosion control distribution dispensing devices of the nuclear reactor facility are installed in the reactor main body (1) The dual structure block tank dust collector reactor installation of the nuclear power generating plant is provided with a double structure of the fifth wall from the first wall of the nuclear reactor to the distribution reactor of the nuclear power generation facility unit 811, Block Tank Dust Collector Nuclear Reactor (Nuclear Power Plant) Nuclear Reactor (Nuclear Power Plant) Nuclear Reactor (Nuclear Power Plant) Nuclear Reactor The nuclear power plant of claim 1, The power generation includes a steam turbine 267 generating nuclear fission in the nuclear reactor facility to generate steam 780 to generate power by rotating the steam turbine 267, A rotatable rotor electromagnet coil 774 for a nuclear power generator installed along a circumference of a rotary shaft 198 connecting the steam turbine 267 and the nuclear power generator 772, A nonrotating armature coil 773 for a nuclear power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for a nuclear power generator and a rotor fixed to the nuclear power generator 772 and the rotary shaft 198 to the steam turbine 267. [ And a frame 775 that provides a frame 775 to the nuclear reactor control unit 811 to control the nuclear reactor radiation leakage before and after the operation of the nuclear reactor facility. The dual structure block tank dust collector 794 operates the nuclear reactor The piping line of the cooling water 287 connected to the condenser 790 and the lower portion of the main body of the steam turbine 267 of the nuclear power generation facility unit 811 is connected to the distribution input apparatus of the nuclear power generation facility unit 811, And a circulation water pump 242 for providing a connection with a piping line 169 and a cooling water piping line 352 to the front side of the condenser 790 are connected to a radioactive- A water supply pump 241 is connected to the rear end of the condenser 790 and to the outside of the nuclear reactor facility in the distribution and charging apparatus of the nuclear power generation facility unit 811, A plurality of coolant pumps 243 are installed in the piping line inside the nuclear reactor facility in front of the purifier 809 and the uranium 812 fuel The stored nuclear reactor A safety device control rod 798 is installed inside the reactor pressure vessel 813 outside the pressure vessel 813. When a vibration occurs due to an earthquake, the control rod 798 is automatically inserted into the reactor pressure vessel 813, The reactor is equipped with an emergency stop. At the same time, in the dual structure block tank dust collector 794, the nuclear water reactor 287 and the mixture of the loess and the loess are put into the pressure vessel 813 at the same time, (794) of the nuclear reactor radiation leak control dual structure block tank dust collector before safe operation of the nuclear reactor facility, and the nuclear reactor is installed in the nuclear reactor facility unit (811) In a plurality of nuclear reactor installations, a cladding tube 682 protecting the first wall pellet 683 and the second wall flare rod 689 is formed from a seismic generation stronger than the magnitude 5, The safety valves 472 formed with the plurality of temperature pressure sensors immediately before the explosion in the reactor pressure vessel 813 and the fourth wall containment vessel 808 are opened and the pressure vessel 813 and the upper block piping line 74 of the respective portions are opened. The explosive nuclear waste 224 is passed through the inner block piping 74a of the inner block tank 74a and the outer block piping 74b is filled with the nuclear fuel explosion-proof control coolant and soap bubbles The generated yellow loess mixtures are transferred to the interior of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the feed pump 241 and the nuclear waste 224 is supplied to the inner lower ends of the respective portions of the double structure block tank 598 And the temperature control sensor safety valve 472 connected to the inner block tank 596 of the pressure vessel 813 is opened and at the same time the outer block piping 74b of the block piping line 74 is opened The fuel explosion prevention control (not shown) stored in the inner block tank 596 The water cooling water and the yellow loam mixtures that generate soap bubbles are transferred to the interior of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241 while simultaneously generating cooling water and soap bubbles When the energy of the water in the loess mixtures is transferred to the inside of the reactor facility by converting the energy of the water into kinetic energy, and simultaneously filling the inner block tanks 596 and the outer block tanks 599 with the stored coolant and ocher mixtures, A double structure block tank (794) facility for preventing explosion of a reactor is provided as a substitute injection device of a reactor building, or a double structure block tank for providing a mixture of a cooling water and a loess mixture And a dust collector (794) for operating the nuclear power plant. The distribution and input device of the nuclear power generation facility (811) The nuclear power plant 811 having the remote control cutter and the robot 700 at the time of the sieve work and the plurality of the temperature pressure sensor safety valves 472 for stopping the explosion inside the reactor pressure vessel 813 to be closed The distribution input facility is provided with a facility safety operation of a nuclear power plant in which a plurality of temperature pressure sensing sensor safety valves 472 are normally closed when the reactor is operated or a plurality of nuclear reactors are installed on the ocean barge 591 The nuclear power generation facility unit 811 is provided with a plurality of nuclear reactors to be installed in the marine anti-sinking restraining barge line Nuclear Radiation Leakage Control Dual structural block tank dust collector (794) installed to prevent the earthquake and tsunami from being restricted by weather conditions And the docking and buoyancy control devices are used to control the position of the buoyant buoys and the buoyant buoyant buoys of the buoyant type. The nuclear waste disposal system of the nuclear power generation facility 811 is constructed such that the nuclear waste is prevented from being polluted by the nuclear waste, A reactor building having a double structure block tank dust collector 794 for preventing explosion of a reactor in a nuclear fuel chamber is connected to a marine nuclear power plant connection shaft and a distribution and input device of the nuclear power generation facility unit 811 is provided with a safe and continuous operation To ensure the safety of nuclear power plants and to ensure the renovation of nuclear reactors through continuous operation, A dredging buoyancy control device, a nuclear waste disposal dispensing apparatus, and a nuclear fuel explosion control dispensing apparatus are provided at the same time, but at the same time, the nuclear waste is prevented from polluting the environment, A nuclear waste disposal system of a double structure block tank dust collector in which internal and external reactors do not explode is installed in the nuclear reactor main body 1 of the nuclear power plant or a mooring device formed in the marine nuclear power plant floating nuclear power plant 672 Diversity buoyancy control device, nuclear waste disposal dispenser and nuclear reactor facility safety operation Disassembly at the marine vessel manufacturing plant with the connection axis of the nuclear waste disposal pipe manufacturing process (705) It is composed of connecting structure that can be combined.

Referring to FIG. 5U, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants (672) and the nuclear power plant is equipped with the new conversion reactor facility (806) (1) Inside flood control system Many nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of a nuclear power plant (672) and a nuclear power plant with a new conversion reactor facility (806) Configuration,

Referring to FIG. 5V, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants (672) and the nuclear power plant is equipped with the new conversion reactor facility (806) (1) Inside flood control system Many nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of a nuclear power plant (672) and a nuclear power plant with a new conversion reactor facility (806) Configuration Road,

As shown in FIGS. 5U and 5V, it is preferable that the nuclear power plant 672 of the marine power plant is installed in the nuclear power plant 671 of the marine power plant and the nuclear power plant 811 of the nuclear power plant 811 is installed inside the nuclear power plant main body 1 of the nuclear power plant. The new conversion furnace facility 806 constituting the double structure block tank precipitator 794 for treating nuclear waste as a connection axis of the nuclear waste processing unit 811a,

The new conversion furnace facility 806 constituting the double structure block tank dust collector 794 for treating nuclear waste on the connection axis of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 is provided with a floating- A nuclear waste disposal dispensing apparatus having a dual structure block tank dust collector 794 in the form of a nuclear radiation leak control source statistic into a nuclear reactor power plant 672 and a nuclear reactor facility main body 1 of a nuclear power plant and a nuclear fuel 683 explosion control The distribution facility is divided into a plurality of nuclear reactor facilities for installation in the barge of the anti-sinking double structure block tank of the ocean, and the distribution of the nuclear power plant 811 at the top of the sea level of 40 m so as not to be restricted by the weather conditions of the earthquake and tsunami. Suction prevention type barge line reactor facility with input device installation position setting Reactor facility safety operation device to form safety facility before and after safety operation (811a) of the nuclear power plant 811a of the nuclear power plant 811, which prevents the plurality of nuclear reactors of the nuclear power plant from exploding into the nuclear power plant 672 of the two power plants and the nuclear power plant main body 1 of the nuclear power plant The nuclear reactor radiation leakage control dual structural block tank dust collector 794 provided in the shaft is constructed so as to operate the nuclear reactor with the new conversion furnace reactor facility 806;

As shown in FIG. 5U and FIG. 5V, in the structure of the new conversion furnace facility 806 constituting the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811, the new conversion furnace facility 806 are provided with the coolant 816 as the hard water 654a for increasing the degree of utilization of the fuel 683 and the hard water 654a as the coolant 816 so as to be heated to a high temperature The water 654 and the steam 780 are separated from the steam drum 792 where the steam 780 is generated and simultaneously the steam 780 is transferred to the turbine 267 through the steam pipe 779 while the rotation of the turbine 267 The heavy water 654b is used as the neutralizer 654b as the moderator 676 and the neutral water 654b is used as the neutralizer 654b as the neutralizer 654b, (675) absorption is weak, so that the utilization efficiency of uranium (812) The mixing operation of the plutonium 801 and the natural uranium 812 with the mixer mixer machine 649 and the rotation operation of the turbine 267 by using the nuclear fuel 683 for the operation of the reactor facility 806 at the same time A double structure block tank dust collector (794) equipped with nuclear reactor leakage control of nuclear reactor facility in Fuehsien Nuclear Power Plant (811) before nuclear reactor facility safety operation of reactor facility. Nuclear power generation A nuclear waste disposal unit 811a, a connection shaft for supplying a new type of reactor facility 806,

As shown in FIGS. 5U and 5V, the double pipe structure piping line 74 for providing a position inside the double structure block tank precipitator 794 of the connecting shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811, Nuclear waste location transfer path is provided by the nuclear waste location control device. However, the temperature sensor of the safety valve of the safety valve detects the number of the nuclear radiation pollutants by the temperature sensor within the reactor. When the dangerous state of the high pressure state is reached, the temperature and pressure sensing sensors transmit an alarm message to the computer of the safety control room, and at the same time, In the inner block piping line 74a, explosive nuclear wastes are passed through and the nuclear waste is stored in each place of the double structure block tank dust collector 794, The temperature blockage control valve 472 connected to the lower end internal double structure block tank of the reactor 813 provides an opening and at the same time the outer block piping line 74b is provided with the fuel explosion- (683) Automatic input device for explosion-proof control goods Thermocouple thermometer with sensor flashing warning light (99), pressure gauge (101) and temperature sensor bimetal (102) Sensor switch (103) And a safety valve 472 of a pipeline line automatic pneumatic valve conveying device 916 and at the same time a constant 45 Holes are formed by a laser cutting machine and a construction machine drilling machine at the same time, and a double pipe structure piping line 74 is formed in a plurality of through holes at the same time, and a plurality of block piping lines 74 The safety valve 472 is provided with flange connecting connections by means of bolts 24 and nuts 25 and gaskets 32 and at the same time to the flanges of the reactor building 688 along the outer wall surface of the reactor building 688 (794) One piece of equipment includes a nuclear waste disposal dispenser and nuclear fuel (683) explosion control unit which is combined with an external block tank (599) for nuclear waste disposal and storage and a radiation type connection structure. The reactor is installed in the reactor core inside the reactor core (681) and outside the reactor core (681). Prevention of nuclear fuel explosion immediately before the reactor explosion. Connected to the nuclear reactor main body (1) (1) of nuclear power plant nuclear power plant nuclear power plant nuclear power plant explosion prevention nuclear power plant nuclear power plant nuclear power plant nuclear power plant nuclear power plant nuclear power plant (683) to the nuclear reactor main body (1) of the floating nuclear power plant of the marine power plant at the same time, while maintaining the distribution of the dual structure block tank dust collector (794) A dual structure block tank dust collector (794) is used to construct the new reactor conversion facility (806) structure for the nuclear reactor plant to further operate the nuclear power plant. A mooring device and diving buoyancy Control unit and nuclear waste disposal unit and reactor installation of reactor facility Safety operation Before the operation of the double structure block tank dust collector (794) equipped with the nuclear radiation leakage control of the reactor facility in Fusi Nuclear Power Plant (811) The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 and the connection shaft for providing the new nuclear power reactor facility 806 for the conversion, The connection structure includes a possible degradation in the plant, and coupling is preferably comprised.

(593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and nuclear power plant main body 1 of the nuclear power plant as shown in Figs. 5u and 5v. A dust collector is installed in a nuclear waste disposal facility of a reactor facility, a construction machine for operating a submarine energy and mineral collection equipment constituting a connection axis position of the process (705), and a diving process preparation for a hull safety facility. (SLU) floodgate hull deck having a submarine line wiring 946 as an internal connection structure of a nuclear reactor facility main body 1 of a floating power plant nuclear power plant of a marine power plant is installed in the distribution input apparatus of the nuclear power generation facility unit 811, (SDU) Marine power generation facility Seisio crane in tower crane Alternative tower crane Boom of crane boom of boom zone (942) Boom of boom boom and boom hook (652) The sketches 842 and 844 are provided on both sides of the seesaw crane boom girder 942 as connection structures and are connected to the yard basket 842 and the pallet 844 for collecting seabed mineral resources at the same time, (SLD) at the lower end of the sea surface (SLD), the position of the submarine mineral resource collection site inside the lower SDL of the hull deck (SDL) At the same time, the distribution and input device of the nuclear power generation facility unit 811 moves the manganese nodule 909 to the seabed mineral resource manganese nodule 909 to the upper end of the floating deck hull deck (SDU) (1) of the offshore nuclear power plant of the marine power plant at the same time as the seaside crane boom zone (942) connection structure in the submarine mineral resource gathering place inside the reactor main body (1) of the marine power plant, The excavator 845 and the hatcher erector 877 for the submarine excavation equipment of the system skewer drill prepare the solidified manganese nodule 909 as a manganese nodule 909 for crushing, The diesel hammer 883 and the steam hammer 884, the hydraulic crane 885 and the tower crane 886 are provided for the file driver 882 of the submarine 880, The suction collecting machine 911 and the mineral picking and collecting robot 912 are connected to each other by a construction machine excavator and a connecting structure to provide an operation position shift control. The connection structure of the nuclear plant main body 1 of the floating power plant of the marine power plant (880) for the collection of seabed mineral resources with the construction machine distribution equipment for the operation of the submarine energy and mineral collection equipment, and the construction of the nuclear power station of the marine power plant (593,594,595) In the main body 1 Crane boom (74) Construction equipment for operation of submarine energy and mineral collection equipment consisting of connecting structures, connected to the inside of the reactor facility main body (1) of floating power plant of marine power plant, A boom of a crane boom of a seismic crane boom zone 942 and a boom girder 652. A plurality of heavy oil tanks are provided on both sides of the body and a 500m high pressure hose 190 connected to the bottom of the heavy oil tank 795 along the depth of the sea floor. 29) A double structure high pressure hose (190) connected by a plurality of high pressure hoses (190) as a connection structure is provided and at the same time, a plurality of drill rod pipe racks (854) as a connection structure of a rotary table lathe machine (908) (917) located at the location of the natural gas borehole (936), the crude oil borehole (936) and the natural gas borehole (936) Drilling rod pipe (854) The supply line is provided to the piping line through the body to fill the gaps between the piping files with the loess and cement. At the same time, the high pressure hose (190) The crude oil and natural gas, both of which are provided with crude oil and natural gas reservoirs inside a tank provided with a connection structure on both sides of the double structure high pressure hose 190, are connected to the seesaw crane boom section 942 of the tower crane, Boom Boom and Boat Hooks (652) The undersea mineral resource collecting yard basket 842 and the pallet 844 for collecting undersea mineral resources are connected to the boom hook hooks 18 on the inside of the body, The collecting basin basket 842 and the pallet 844 for collecting resources are disposed at a position within the undersea mineral resource collecting place inside the lower end portion SDL of the flooded lower end SLD of the sea level SLL, U) to the top of the deck (SDU) of the floating deck hull and to transport the manganese nodule (909) from the submarine mineral resource to the upper deck (SDU) Crude oil and natural gas and undersea energy harvesting equipment, which lifts up to the top deck deck position by a vertical rotation operation into the nuclear reactor plant main body (1) of the nuclear power plant, is located at a position with the connection structure submarine line wiring (946) (SDU) Upper position (SDU) Marine power generation facility providing position to the upper position Seismic crane in the tower crane for the replacement of each crane Boom and boom hooks (652) of the crane boom of the boom zone (942) The connection structure is a connection structure for providing a mooring device and a power generation facility device. The connection structure of the nuclear waste treatment pipe manufacturing process (705) of the reactor installation at the nuclear power generation facility (811) It is configured to include a connection structure capable decomposition combined in a manufacturing plant.

(593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and nuclear power plant main body 1 of the nuclear power plant as shown in Figs. 5u and 5v. The diving operation ready controllable control dispensing input device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process 705 of the nuclear reactor facility of the nuclear reactor facility, A nuclear waste disposal dispensing apparatus and a nuclear fuel explosion control dispensing dispenser equipped with a flood control unit 672 of a marine power plant and a nuclear waste disposal control dual structure block tank dust collector 794 inside a reactor facility body 1 of a nuclear power plant, A number of nuclear reactors are installed on the barge of an anti-sinking dual structure block tank of the ocean, and a sea level surface to prevent the earthquake and tsunami from being affected by weather conditions. Nuclear power plant (811) with 40m length distribution and injection device installation position Prevention of sinking type barge line Nuclear reactor facility Safety operation Nuclear reactor facility safety device to establish safe operation Nuclear power plant safety operation device A nuclear reactor leak detector for controlling a nuclear reactor leakage preventing control structure for preventing a nuclear reactor from being detonated, a nuclear reactor installed in the nuclear reactor facility, a dual structure block tank dust collector (794) The anchor 639 and the anchor chain 640 of the mooring device for adjusting the height of the nuclear power plant 672 of the floating power plant 593, 594, 595 of the marine power plant are installed in the distribution input device of the nuclear power generation facility 811 at an upper sea level of 40 m, A rotary bed lathe machine 908 of the crude bed-boring drilling machine, a buoyancy regulating pipe line automatic pneumatic valve conveying device 916 and a vacuum pump (635), a high-pressure multi-stage multi-stage disaster prevention pump (8) for a disaster prevention pump, and a double structure block tank dust collector (794) for controlling the hull barrel torsion tank. The empty space of the nuclear reactor facility and the tank inlet, And a jet pump 157 connection structure between the nuclear waste treatment storage tank and the doctor ventilation 585 of the nuclear waste treatment storage tank 585 and the doctor ventilation inlet 585a of the nuclear waste treatment storage tank 585, A hydraulic cylinder door 624 for a block tank hull traffic control device and a hydraulic cylinder device 624 for a block unit dual structure block tank hull disassembling and regulating device and a solenoid valve (76) (949) for controlling the diving position of the hull and the diving buoyancy adjusting device (949), and the equipment of the large-scale marine nuclear power plant floating structure (595) (595) operating structure at the same time as the weight of the hull, sea level gravity and buoyancy are generated, and buoyancy generated by the sea surface gravity is applied to the large oceanic power plant floating ocean pond (595) A plurality of bollards 638 for hull anchoring of ship mooring equipment and hull anchoring of vessels are formed on upper deck of bucket hull 591 and lower deck deck of strut tank bottom barge hull 592, And an anchor 639 formed in the anchor chain 640 for connecting the anchor 639 to the mooring anchor 639 is pierced to the seabed by a winch 137, (595) with the anchorage system of the barge hull, while the sea floor depth is deeper than the depth of the continental shelf, the rotary tilting machine (595) of the large marine nuclear power plant marine anchorage anchorage device is provided with an anchor ring device, and the hydraulic equipment of the mooring device replacing the mooring device anchor It is also possible to provide an operation by folding the main body of the feed dog 185 with the feed dog feeder 185 formed in the cylinder hydraulic feeder key 623 and the hydraulic cylinder operating key 623, (595) When the barge hull is removed and the hydraulic cylinder (623) operates by pushing the umbrella body of the flywheel (185), a large marine nuclear power plant floating feeder (595) barge hull anchor is formed (595) double structure block tank barge hull anchor bolting mooring equipment reactor installation (1) (1) of a nuclear power station of a marine power plant is connected to a distribution facility of the nuclear power generation facility unit (811) so as to be installed in a nuclear power plant main body (1) of a marine power plant, An air recuperator tank 145 for an air storage tank for providing diving control, an air liquefier cooling device cooling fan 645 for an HVAC system, an air balloon 78, a rubber balloon 914 ), A heater fan (642) for floating the tube (188) in the air, a maritime pirate causing a war, and a party of the belligerent party causing the international diplomatic dispute to be expelled from the global atmosphere to the satellite launch pad (643), satellites and airships, and at the same time, a buoyant tower (644) for controlling and controlling nuclear bombs and missiles inside the reactor main body (1) of the buoyant pilot nuclear power plant, An air compressor 80 is provided in the satellite launch pad 643 and the space rocket launch pad 646. At the same time, the tackle winch 137, which operates as compressed air supplied from the air compressor 80, Before the operation of the nuclear power plant, the nuclear power plant is operated by the dual structure block tank dispensing device of FUJI nuclear power plant (811);

As shown in FIGS. 5U and 5V, the distribution and input device of the nuclear power plant 811 includes a crane 861 installed as a float upper deck (SDU) A rope 19, a wire rope chain 915 and an air hose 109 connected to the front of the trolley winch 137 in front of and behind the air receiver tank at the rear of the air compressor 80, (SDL) is provided with an electric magnet magnet 645, a pipeline line automatic pneumatic conveying device 916 for conveying the loess and cement by piping and high pressure hose, and a pipeline line automatic pneumatic conveying device 916 for positioning the pipeline automatic pneumatic conveying device 916 And a lever block 123 provided for each tonnage capacity is provided in units of dual structure block tanks 598. The dual block tank 598 is provided for each of the marine nuclear power plants Combining reactor facilities, The distribution and dispensing apparatus of the nuclear power generation facility unit 811 is provided with an iron plate bracket 165 to be coupled with the holding tank and the holding tank combining part with the bolt nut while securing the binding object again with the turnpike 640, Hole, and the double structure block tank facility is provided with a welding portion capable of withstanding high pressure at the joint portion of the flange and the flange, and a welding portion capable of enduring the safe operation of the nuclear waste treatment reactor of the marine nuclear power plant, The facility is configured to operate the nuclear power plant with the distribution and input devices of the nuclear power plant 811;

As shown in FIGS. 5U and 5V, the rubber packing 32 of the gasket packing is inserted into the gap of the large flange 614 in the distribution dispensing apparatus of the nuclear power plant 811, The double structure block tank assembly is provided with a large flange processing hole 615 with high strength bolts and nuts and a double structure block tank flange 614 with another structure inside and outside the double structure block tank 598, The double structure block tank flange 614 is connected to the flange 614 and at the same time the double structure block tank flange 614 is connected to the double structure block tank connection inside the reactor installation body 1 of the nuclear power plant and the high pressure multi- The valve disk operation inside the Bell-rotor butterfly valve 622, in which the fan 195 of the doctor's ventilation is operated to allow the floating humanoid hull diving to be provided on the seabed according to the opening of the manhole 610 and the hatch cover 153, Rusty Butter The lyre valve 622 is opened, and at the same time, the floodgate hull is floated to the sea, and the barge hull at the bottom of the double structure vertical holding tank is formed into a nuclear waste treatment storage tank generated from the reactor, (616) and the lug pin connection shafts (606) that are coupled to the elongated hole (616) of the longitudinal and horizontal hinge joints of the double structure block tank unit to maintain the nuclear reactor waste disposal facility of the marine nuclear power plant The nuclear power plant 811 may be controlled by the control of a Bell-Butterfly valve 622 which is provided with a distributing and inputting device for the flood control system 811, A guide rail 618 for feeding deck deck upper end equipment and a helicopter stop 619 as an upper end of a floating deck deck deck, The coupling unit of the block tank includes a hydraulic cylinder operation key 623 for a semi-submerged operation line for performing a marine operation of a double structure block tank frame combination in the form of folding umbrella, a tank frame coupling separation and a double structure block tank (598) Combined tool unit (621) The hydraulic cylinder is installed on the anti-diving work line (637) by the band guide unit (621). At the same time, the coupling device of the double structure block tank of the distribution input device of the nuclear power generation facility unit 811 is provided with a control device for controlling the floatation of the submarine submerged sea surface of the submersible barge line control valve, a ballast butterfly valve 622, (191) The motor body (192) of the combined power motor of the double structure block tank is equipped with the motor The interior of the electric motor body 192 of the power motor includes a hood 193, a retaining ring 194, a fan 195, a body frame 196, a body front reinforcing plate 197, a rotary shaft 198, 199, the front rotation support 200, the stator assembly 201, the motor protection casting frame 202, the terminal box 203, the lifting bolts 204, the terminal box cover 205, the rear rotation support 206, The rotor 202 is provided with a rear reinforcing steel plate 207, an air gap 208 and a protective cover 209, a rotor iron core 210, a stator core 211 and a stator winding 212 to provide power to the motor body 192 ), The equipment doctor ventilation 585 of the HVAC system is provided to switch to the rotating body and to provide the necessary time for the source structure to prevent sinking and to extend the sinking time in case of damage to the partial defects of the hull, In order to establish a connection structure with the intake system of mineral resource intake, The self-control device includes a hydraulic cylinder door 624 for opening the switch button on-the-door when the switch button is off, a hydraulic cylinder door 624 for closing the door when the switch button is off, 28), and electronic control devices, which constitute a continuous operation of the nuclear reactors of the post-nuclear waste disposal reactor before and after the operation of nuclear reactor nuclear reactors;

As shown in FIGS. 5U and 5V, the distribution apparatus of the nuclear power plant 811 includes an air pipeline 181 for preventing sinking of the hull and an emergency engine 226 for extending the prevention of hull sinking, The coupling unit of the block tanks is provided with an air-producing bubble-flag rubber balloon (628) for identifying the position of the double-pipe structure tank, At the same time, the lifting and lowering apparatus is provided with a rope 629 for detachment rope and a rope connecting knot claw 630. At the same time, the emergency staircase 631 facility inside the block pylon 116 is provided with an elevator alibate 636, A discharge suction vacuum pump 635 for adjusting the balance between the conveyor 633 for the mining and mechanical equipment conveying device and the holding tank lower barge hull 592 to the outside of the double structure block tank holding tank upper barge hull 591, Sink The air supply lines 634 of the air suction and discharge device for lifting the hull of the ship, and at the same time, the distribution input device parts of the nuclear power generation facility 811 are manufactured at the marine vessel manufacturing factory and the heavy industry field (SLL), and a conveyor 633 for a mechanical equipment conveying device is formed and the elevation of the barge line is adjusted by providing an air-formed diaphragm rubber balloon 628 The nuclear power generation facility unit 811 includes a nuclear power plant, a nuclear power plant, a nuclear power plant, and a nuclear power plant, Of the nuclear power plant is not affected by the earthquake or tsunami, so that the reactor facility of the nuclear power plant can not explode. A nuclear waste disposal and dispensing apparatus that prevents contamination of the environment due to nuclear waste in the distribution and dispensing apparatus of the entire facility unit (811) is a double structure block tank reactor in which the nuclear reactor room is not detonated. A nuclear reactor waste treatment storage tank formed from one wall to a fifth wall, and a plurality of double structure block tanks, wherein the double structure block tank is formed of an inner block tank and an outer block tank, A block tank dust collector (794) is provided, and a safety guarantee for a nuclear power generation facility is provided so that safe and continuous operation can be performed. At the same time, a safety guarantee for the renovation of the nuclear power plant is provided, A nuclear-explosion-proof double structure block tank dust collector 794 is connected to a nuclear power plant connecting shaft and a reactor main body The nuclear waste (224) detonated into the block piping line (74) is passed through the double structure block tank reactor reactor which prevents the nuclear reactor nuclear reactor explosion inside, and at the same time, the nuclear waste And a robot 700 for performing a remote control cutting operation for disassembling the reactor installation of a nuclear power plant having a shortened life span at the same time. When the internal explosion of the reactor pressure vessel 813 stops, The safety valves 472 are closed so that the safety valves 472 are closed, and at the same time, when the reactor facility is operated, the safety control valves 472 are closed, In order to prevent nuclear waste, nuclear power plants are required to operate nuclear reactors at nuclear power plants, The nuclear waste disposal apparatuses of the dual structure block tank dust collector reactor apparatus are installed into the nuclear reactor facility main body 1 of the nuclear power plant in which the nuclear reactor internal and external nuclear reactors are not detonated, (672) of the marine nuclear power plant, and the docking buoyancy control system and the nuclear waste disposal and distribution system of the nuclear reactor. It is composed of connection shafts of waste disposal dispenser equipment as connection structures that can be disassembled at marine ship manufacturing plants.

(593,594,595) nuclear power plant 672 of the above-mentioned offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5U and 5V, A nuclear waste disposal dispensing apparatus for a nuclear reactor safety facility for a hull safety facility constituting a connection axis position of a nuclear waste disposal dispensing apparatus of a nuclear reactor facility comprises a dual structure block tank dust collector, A nuclear waste disposal and dispensing apparatus having a floating radiation double-structure block tank dust collector 794 inside a nuclear power plant 672 of a marine power plant and a reactor facility main body 1 of a nuclear power plant, In addition to the installation of multiple reactor facilities on the barge of an anti-submergence dual structure block tank of the ocean, the installation of the reactor is not restricted by the weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant (794) nuclear waste disposal reactor to allow continuous operation of the nuclear power plant with the distribution and input devices, and the nuclear power plant 811), the nuclear waste disposal dispenser installation includes the water leaking from the valve of the nuclear power plant (672) into the nuclear reactor main body (1) of the floating nuclear power plant of the marine power plant, In the case where the liquid is a liquid, the washing water is collected in the storage tank 216, the nuclear waste disposal filtration is provided by the filter 217, In the nuclear waste disposal dispenser equipment, water other than the wash water to be sent to the sea together with the cooling seawater for measuring the radiation level by the radiation meter 218 and confirming that there is no harm is filtered by the filter 217 At the same time, filtered water and distilled water are provided as reactor coolant, and at the same time, nuclear waste disposal and dispensing apparatus facilities are provided with monitoring posts 219 for monitoring, so that the nuclear facilities of the floating nuclear power plant of a marine power plant 1) To prevent nuclear radiation contamination both inside and outside. At the same time, nuclear waste disposal and dispensing equipment is installed in the nuclear reactor main body (1) of the nuclear power plant, and a mooring device And diving buoyancy control device and nuclear waste disposal dispenser and nuclear reactor facility safety operation Fusi Nuclear Power Plant Division (811) Standing in the connecting shaft of the double-tank structure block precipitator In the nuclear waste disposal distribution of the nuclear reactor facility equipment device; comprising the manufacturing plant on the marine vessel in the connection structure is combined decomposition possible and configuration.

Referring to FIG. 5w, an embodiment of the nuclear power plant 811 is installed in the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plants (672) and nuclear reactors (838) in the offshore and offshore marine power plants (838). 1) Inside flood control system A number of nuclear reactors Installed in a marine power plant showing the construction of a nuclear power plant Construction of a nuclear power plant (672) and a nuclear fuel plant with a fast breeder reactors facility (838) dhk,

Referring to FIG. 5x, an embodiment of the nuclear power plant 811 is installed inside the reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention, (593,594,595) Nuclear power plants (672) and nuclear reactors (838) in the offshore and offshore marine power plants (838). 1) In-house flood control plant A plurality of nuclear reactors Installed in a marine power plant showing the construction of the nuclear power plant Construction of nuclear power plant (672) and nuclear power plant is composed of a fast breeder reactors facility (838) ,

As shown in FIGS. 5w and 5x, it is preferable that the nuclear power generation nuclear waste of the marine power plant 672 and the inside of the nuclear reactor facility main body 1 of the nuclear power plant are disposed inside the nuclear power generation facility 811, The FBR reactor 838 constituting the double structure block tank precipitator 794 in the form of a raw statistic for nuclear waste disposal as a connection axis of the processing unit 811a is connected to the nuclear reactor of the nuclear power plant 811 The fast breeder reactor facility (FBR, 838), which consists of a dual structural block tank collector (794) for nuclear waste disposal through a nuclear waste disposal unit (811a), is equipped with a floating nuclear power plant (672) A nuclear waste disposal dispensing apparatus having a dual structure block tank dust collector 794 in the form of a nuclear radiation leak control source statistic into the nuclear reactor main body 1 and a nuclear fuel 683 explosion control distribution dispatch apparatus The installation stage of the nuclear reactor installation to prevent sinking of the ocean, the installation of the double structure block tank, and the installation position of the distribution input unit of the nuclear power plant (811) at the top of the sea level to prevent the earthquake and tsunami from being restricted by weather conditions. (672) of nuclear power plant (1) of nuclear power plant and nuclear power plant of nuclear power plant (1) of nuclear power station of nuclear power plant Nuclear Radiation Leakage Control System Provided at the Nuclear Power Plant Nuclear Waste Treatment Unit 811a of the Nuclear Power Generation Facilities 811 to prevent the Nuclear Power Generation Nuclear Power Plants from Explosion A high speed propagation nuclear reactor The facility (FBR, 838) is used to operate the nuclear power plant;

As shown in FIG. 5w and FIG. 5x, the fast breeder reactor facility (FBR) 838, which is connected to the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility 811, (FBR) 838 constituting the double structure block tank dust collector 794 of the nuclear power generation facility unit 811 inside the nuclear reactor facility main body 1 of the nuclear power plant is provided in the center portion of the fuel rod 689, A mixture of enriched uranium 812 and natural uranium 812 and plutonium 812 in which the enriched uranium 235 812 is concentrated to about 20% is provided and at the same time the fuel rod 689 is surrounded by natural uranium 812 The fuel is supplied from the uranium 238 (653a) to the plutonium (801) in the fuel rod (689), but the plutonium (801) The coolant 816 is filled with a liquid metal nat It is not necessary to reduce the neutron 675 to the FBR reactor 838 at the same time so that the moderator 676 is not included and the heat generated in the reactor installation in the intermediate heat exchanger 657 At the same time, the heat exchanger 658 transforms the water 654 into the vapor 780 by the heat of the liquid sodium, so that the steam turbine 267 provides rotation Nuclear Power Generation and Maintenance of Marine Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant 811 Nuclear Power Plant Nuclear Power Plant 811a (FBR, 838) connection shaft constituting the double structure block tank precipitator 794,

As shown in FIGS. 5w and 5x, the FBR 838 is positioned inside the double structure block tank dust collector 794 of the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 (74) Nuclear waste location transfer path is provided to control the location of the nuclear waste. However, a number of temperature and pressure sensors are connected to the reactor. When the internal temperature reaches a dangerous state of 700 to 800 degree high temperature and high pressure, the temperature and pressure sensor sends an alarm message to the computer of the safety control room, and at the same time, The explosive nuclear wastes are passed through the inner block piping line 74a of the pressure vessel 813 at each location and are passed through the double structure block tank dust collector 794 As the wastes are stored, the temperature pressure sensing sensor safety valve 472 connected to the inner double structure block tank at the lower end of the pressure vessel 813 opens. At the same time, as the outer block piping line 74b, Explosion prevention control device Automatic injection device for fuel explosion prevention control device Thermocouple thermometer sensor switch (103) with a flashing warning light (99), pressure gauge (101) and temperature sensor bimetal (102) And the safety valve 472 of the pipeline automatic pneumatic valve conveying device 916 and at the same time to the upper end of the reactor building 688. The level pressure switch 104, A plurality of through holes are formed at a predetermined angle of 45 degrees by a laser cutting machine and a construction machine drilling machine to form a through hole. At the same time, a double pipe structure piping line 74 is formed in a plurality of through holes A plurality of safety valves 472 are connected to flanges by means of bolts 24, nuts 25 and gaskets 32. At the same time, A double structure block tank dust collector 794 having a diameter twice the diameter of the reactor building 688 is provided with a nuclear waste disposal and distribution system (683) Explosion-Controlled Dispensing Apparatus Provides Reactor Facilities Inside Reactor Inside Core (681) and Outside Core (681) Nuclear Fuel Explosion Prevention Controls Just Before Nuclear Explosion Onshore and Offshore Nuclear Power Plants (683) explosion-proof control appliances, which are installed in the nuclear reactor main body (1) to prevent explosion of the nuclear fuel. (794) of the nuclear reactor waste disposal shielding device and the nuclear radiation leakage control control system of the nuclear waste disposal control tank (794). At the same time, the nuclear power plant is operated in the nuclear power plant main body 1 of the floating nuclear power plant of the marine nuclear power plant (FBR, 838) structure to the nuclear reactor facility to make the operation of the nuclear power plant more effective. However, the structure of the double structure block tank dust collector (794) A double structure block tank dust collector equipped with a mooring device, a diving buoyancy control device, a nuclear waste disposal dispensing device, and a nuclear radiation leakage control device of a reactor facility at a nuclear reactor facility (811) (794) Nuclear power generation facilities (811) Nuclear power generation nuclear waste treatment facility (811a) Fast breeder nuclear reactor facilities (FBR, 838) A serial connection axis; includes with this connection structure as possible decomposition combined in a marine vessel manufacturing plant and consists,

(593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and nuclear power plant main body 1 of the nuclear power plant as shown in FIG. 5w and FIG. 5x, The nuclear waste disposal dispensing apparatus of the reactor facility for the hull safety equipment constituting the connection axis position of the nuclear waste disposal dispensing apparatus of the nuclear reactor facility of the nuclear reactor facility is divided into the nuclear waste disposal processing distribution input The apparatus includes a nuclear waste disposal and dispensing apparatus having a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 inside a reactor facility main body 1 of a nuclear power plant, The installation of multiple nuclear reactors to the barge of the anti-sinking double structure block tank of the ocean and the restriction of the weather condition of the earthquake and tsunami Nuclear power plant (811) Nuclear waste disposal system installed at 40m above the sea level to prevent the sinking Prevent sinking type barge line reactor facility Safe operation Reactor facility to establish safe operation facility Safety facility operation device Nuclear power Nuclear Power Generation in Nuclear Power Plants Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) to prevent multiple nuclear reactor installations from exploding. Nuclear waste disposal and dispensing devices in nuclear reactors constitute nuclear reactors; 811) Nuclear waste disposal and dispensing equipment for nuclear reactor facilities is equipped with an activated membrane type gas hold-up device (213) for reducing radioactivity when the pressurized water reactor is operated when the air contained in the interior of the building and the water contained in the reactor interior is gas. ), While the ventilation of the power plant is vented by a plurality of symmetrical filters (214) while discharging purified air to the outside air (224) for the prevention of nuclear radioactive contamination inside and outside the nuclear reactor main body (1) of the floating nuclear power plant of a marine power plant by providing exhausted air from the exhaust tower (215) The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility 811 configured to perform the nuclear waste disposal includes a nuclear power plant 672 inside the nuclear power plant 672 of the floating nuclear power plant of the marine nuclear power plant, In the case of the ion exchange resin and the filter medium being solid, the filter sludge and the used resin liquid are stored and stored in the reservoir of the radioactive contaminated paper, cloth, work clothes and shoes. The nuclear waste in the tank 216 is stored and filled in concrete in the drum 220. However, the paper and cloth contaminated with nuclear radiation contamination are subjected to volume compression, At the same time, the nuclear waste storage building 332 and the monitoring post 219 for monitoring are installed in the nuclear waste disposal building premises, (593,594,595) of the marine power plant to prevent nuclear radioactive contamination inside and outside the main body of the nuclear power plant (1), and a mooring device formed at the marine power plant floating nuclear power plant (672) Diverse buoyancy control device and nuclear waste disposal dispenser and nuclear reactor facility safety operation Before the operation of the FUZHOU Nuclear Power Plant (811) Double structure block tank Dust collector Nuclear waste disposal equipment of the nuclear reactor facility Dispensing device As a connection structure capable of disassembling and coupling at marine shipbuilding factories.

(593,594,595) nuclear power plant 672 of the offshore and offshore marine power plants and nuclear power plant main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant as shown in FIGS. 5W and 5X, Nuclear waste in nuclear reactor nuclear waste disposal unit (811a) Nuclear waste disposal reactor in double reactor block tank reactor Nuclear waste disposal reactor in connection facility Nuclear waste nuclear reactors for hull safety equipment constituting treatment of nuclear waste (224) The nuclear waste disposal and dispensing apparatus of the facility is installed in the nuclear waste disposal dispenser apparatus of the nuclear power generation facility 811 in the nuclear power plant 672 of the marine nuclear power plant and the reactor main body 1 of the nuclear power plant A nuclear waste disposal dispensing apparatus and nuclear fuel explosion control dispensing apparatus having a nuclear radiation leak control dual structure block tank dust collector 794; It is necessary to set up the installation on the barge of the double sink block structure tank and to set the installation position of the distribution system of the nuclear power plant (811) at the upper 40m above sea level so as not to be restricted by the weather condition of the earthquake and tsunami. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control to Prevent Explosion of Several Nuclear Power Plants Double Structure Block Tank Dust Collector (794) Reactor The facility consists of a nuclear waste disposal and dispensing facility of the nuclear power plant (811) of the facility. The nuclear fuel cycle of the nuclear waste fuel plant of the nuclear waste disposal facility includes a nuclear power plant (593,594,595) 672), spent nuclear fuel 683 in the reactor main body 1 of the nuclear power plant, and uranium 81 2 may provide processing at the conversion plant 229 for processing the nuclear fuel 683 at the reprocessing plant 228 and uranium fluoride 812 at the same time, In the nuclear fuel cycle, the enrichment plant 230 is provided with a transfer of the nuclear fuel 683 to the carrier, while at the same time the uranium fluoride 812 is converted to uranium dioxide at the conversion plant 229, The nuclear fuel cycle of the nuclear waste fuel industry is processed in the form of pellets 683 to provide fuel rods 689 and at the same time plutonium 801 processed in the reprocessing plant is transferred to the fuel rods 689 And at the same time these reprocessed fuel rods 689 again transport the nuclear fuel 683 to the nuclear power plant 672 by means of a carrier forklift and at the same time transport the nuclear fuel 672 to the nuclear power plant 672, The plant 228, the concentration plant 230, The conversion plant 229, the conversion and processing plant 231 are installed at the upper part of the sinking prevention type floating barge deck deck 40 m above the sea level of the sea, and the nuclear fuel cycle connection axis of the nuclear fuel industry and the nuclear waste (224) The nuclear waste 224 is treated as a nuclear fuel cycle of the nuclear fuel industry to prevent internal and external nuclear radiation pollution, and a double structure block tank dust collector 794 is installed in the nuclear reactor main body 1 of the nuclear power plant, (593,594,595) Mooring device and diving buoyancy control device and nuclear waste disposal and dispensing device in nuclear power plant (672) Nuclear power plant equipment (811) Nuclear waste disposal facility of the facility Including nuclear waste disposal facility of connection structure capable of disassembly and disassembly at marine shipbuilding factory with connection facility facility It is.

Referring to FIG. 5 (a), the nuclear reactor nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 is installed inside the reactor facility body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention. For example, a number of nuclear reactors (593,594,595) in the offshore and offshore marine power plants (672) of nuclear power plants and nuclear power plants in the nuclear waste treatment double structure block tank bridge (929) (672) that constitutes the nuclear waste disposal of the nuclear power plant (672) and the atomic power plant of the nuclear power plant of the marine power plant showing the elemental structure showing the operation method of the nuclear power plant side view, A lateral configuration of the nuclear power plant 672 in the nuclear power plant scene including the bridges 929,

Referring to FIG. 5Z, a nuclear reactor nuclear waste treatment unit 811a of a nuclear power generation facility 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention. For example, a number of nuclear reactors (593,594,595) in the offshore and offshore marine power plants (672) of nuclear power plants and nuclear power plants in the nuclear waste treatment double structure block tank bridge (929) (672) that constitutes the nuclear waste disposal of the nuclear power plant (672) and the atomic power plant of the nuclear power plant of the marine power plant showing the elemental structure showing the operation method of the nuclear power plant side view, Nuclear power plants 672 in a nuclear power plant scene consisting of bridges 929 Arrangement Side Sections Construction Roads,

(593, 594, 595) nuclear power plants 672 of the offshore and offshore marine power plants and the nuclear reactor facility main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant as shown in Figs. 5 (a) Nuclear waste in nuclear reactor nuclear waste disposal unit (811a) Nuclear waste disposal reactor in double reactor block tank reactor Nuclear waste disposal reactor in connection facility Nuclear waste nuclear reactors for nuclear safety equipment that constitute treatment of nuclear waste (224) The nuclear waste disposal and dispensing apparatus of the facility is installed in the nuclear waste disposal dispenser apparatus of the nuclear power generation facility 811 in the nuclear power plant 672 of the marine nuclear power plant and the reactor main body 1 of the nuclear power plant A nuclear waste disposal dispensing apparatus and nuclear fuel explosion control dispensing apparatus having a nuclear radiation leak control dual structure block tank dust collector 794; It is necessary to set up the installation on the barge of the double sink block structure tank and to set the installation position of the distribution system of the nuclear power plant (811) at the upper 40m above sea level so as not to be restricted by the weather condition of earthquake and tsunami. Nuclear reactor leak detection control system (794) Nuclear radiation leak control to prevent multiple nuclear reactors from exploding at nuclear power plants Nuclear power plant leak detector (794) Nuclear Reactor Facilities Nuclear waste disposal and dispensing devices are used to operate nuclear reactors;

As shown in FIGS. 5Y and 5Z, the nuclear power generation nuclear waste treatment section (nuclear power generation nuclear power generation facility) comprising the nuclear power plant 592, 593, 595 nuclear power plant 672 of the offshore power plant and the nuclear power generation facility 811 of the nuclear reactor facility main body 1 of the nuclear power plant The nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a of the nuclear power plant 811a is installed in the nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a at the nuclear power plant main body 1 of the nuclear power plant and the ocean power plant floating power plant 593,594,595 nuclear power plant 672 The long half-life nuclear waste 224 from the reprocessing process may be used as a permanent nuclear waste disposal facility for long-lived wastes, including a heavy construction equipment heavy excavator 877 and an excavator 845 to produce nuclear waste 224 The nuclear waste disposal facility is constructed by constructing a nuclear waste disposal facility in the polar ice glacier at the same time as the nuclear waste disposal facility facility, And constructing the conversion of the nuclear waste 224 into construction machines according to the depths of the ground and the seabed. At the same time, the construction machine heavy equipment hoe 877 and the excavator 845 nucleus The nuclear waste disposal system is constructed so that the nuclear waste disposal apparatus is installed in the nuclear waste disposal apparatus ship and the nuclear waste disposal apparatus drum 220 containing the nuclear waste is transported to the nuclear waste disposal site 224, Lt; / RTI &gt;

As shown in FIGS. 5 y and 5 z, the nuclear waste disposal unit transport facility of the nuclear power generation nuclear waste processing unit 811 a includes a barge deck deck 591 equipped with a space rocket 612 and a space rocket launcher 646 The nuclear waste 224 processing unit space rocket 612 and the space rocket launching unit 646 constituting the double pipe structure drum 220 containing the nuclear waste at the upper end position are mounted on the space rocket 612 to be transferred to the space space, (593,594,595) nuclear power plant (672) of nuclear power plant and nuclear reactor facility main body (1) of nuclear power plant equipped with transportation facilities to prevent nuclear radioactive contamination from the nuclear waste (224) processing device space rocket (612) And the Space Rocket Launcher (646) transport facility to be used for nuclear waste disposal.

(593, 594, 595) nuclear power plants (672) of the offshore and offshore marine power plants and nuclear power plant main body (1) nuclear power generation facility part (811) of the nuclear power plant as shown in FIGS. 5 The dust collector is connected to the nuclear waste disposal unit 811a of the nuclear waste disposal pipe manufacturing process 705 of the reactor facility and the nuclear waste disposal unit 811a of the nuclear waste disposal unit 811a, (593,594,595) nuclear power plant (672) of a submergence preventing marine power plant and a connection structure inside the reactor facility main body (1) of a nuclear power plant are connected to the nuclear waste disposal and dispensing apparatus of the nuclear waste disposal unit (811a) The large flange 614, which provides the position of the nuclear waste disposal dispensing apparatus with the connection structure having the submarine line injection nozzle of the line injection nozzle connection port and the submarine line wiring connection structure, A double structure block tank 598 and a column block tank 590 are connected to each other so as to construct an equator (EL) on the South Pole (SP) and the North Pole (NP) A double structure block tank 598 is provided in the form of a double structure block tank barge at the same time, and at the same time, the distributing and inputting device of the double structure block tank barge line is provided with a sinking prevention stay line 634, (593,594,595) nuclear power plants of marine power plants to prevent the sinking of the nuclear power plants and to provide the whole connection of nuclear power plant facilities, Structure block Tank pipe bridge (929) Double structure block tank bridge pipe (937) with connection shaft at the same time Construction of connection structure on one side of double structure block tank pipe bridge pier (928) At the same time, a submersible vessel (995) is installed in the deep sea basin to distribute and install the nuclear power plant facilities, and precise measurement of the flow velocity other than the sea water depth and the sea water pressure at the installation position of the double structure block tank pipe pier (928) At the same time, at the installation position of the double structure block tank pipe bridge 928, the installation of the balloon flag rubber balloon 628 and the distribution and input device of the nuclear power plant equipment are provided with the direction indication and the depth depth recognition notation, The installation location of the double structure block tank bridge pier 928 for hanging the wire rope 915, the diving position adjusting mobile unit of the hull and the diverting buoyancy weight 949 is provided at the lower end of the rubber balloon 628 , The respective double structure block tank pipe bridge 928 is towed to the tugboat 636 and transported to the same sink retention lines 634 as those of the floating power plant 593,594,595 of the marine power plant, (614) for double structure block tank coupling to provide a connection structure with connection structure of submarine line wiring (946) to the injection nozzle of the injection nozzle connection port as a connection structure inside the nuclear reactor facility main body (1) of the magnetic power plant (593,594,595) Mooring equipment of nuclear power plant (593,594,595) Nuclear power plant (672) and main body of nuclear power plant (1) Nuclear power plant (811) a nuclear waste disposal and dispensing device of the nuclear waste disposal unit 811a to constitute a nuclear reactor facility;

As shown in FIGS. 5Y and 5Z, the transportation transportation unit 811c of the construction machine for establishing connection with the nuclear waste disposal unit 811a of the reactor facility main body 1 of the nuclear power plant, the nuclear power generation facility unit 811, The distribution dispenser of the reactor installation construction machine constituted by the disposal dispenser is provided with the transfer equipment of the nuclear power plant to the immersion prevention residence line (634) in the distribution dispenser of the reactor facility construction machine of the nuclear power plant facility, When the water depth of the installation point is 300 meters after the nuclear power plant facility is transferred, the pile column is increased by 50 meters from the water depth to be attached to the seesaw crane boom zone 942 of the tower crane for the position- (845), rock drill rigs (847), drilling machines (876), horses and anti-erectors (877) Distribution of construction machinery of nuclear power plant equipment A plurality of construction machines 880 are installed in the sink prevention rescue line 634 at the same time as the entrance ditches and are connected to a pile driver 882, a diesel pile hammer 883, a steam hammer 884, a hydraulic crane 885, A tower crane 886, a crawler crane 887, a truck crane 888, a Mecadam roller 889, a tandem roller 890, a tamping roller 891, a tire roller 892, a tractor 893, and a trailer 894 The distribution and input devices of the nuclear power plant construction machines are provided with a ram 895, a lead 896, a cooling water cooler 897, a helmet A fuel pump 900, a cam 901 and a fuel tank 902 as a distributing and inputting device of a nuclear power plant equipment construction machine and at the same time a base of a plurality of double structure block tank pipe bridge piers 928, The boom front fins 904, the caddy work 905 and the boom front fingers 904 of the starting device 903, The level balance of the nuclear waste treatment double structure block tank bridge bridge 929 is checked while providing the dual structure block tank pipe bridge 928 at each location, Tank, or a combination of the double structure block tanks may be provided as a connection structure. Alternatively, a plurality of double structure block tank ropes may be provided at several sea surface top exposed site double structure block tank pipe piers 928 (593,594,595) of the connection structure of the distribution system of the construction machine and the marine power plant (593,594,595) by the mooring device while maintaining the operation of the actuator (848) in the construction machine cab, Nuclear Power Plant Reactor Facility (1) Nuclear Power Generation Facility (811) Nuclear waste treatment facility (811a) is connected to the transportation transport unit (811c) of the construction machine. (593,594,595) nuclear power plants of a marine power plant as a distribution input device of a nuclear power plant construction machine constituting a nuclear power plant;

As shown in FIGS. 5Y and 5Z, the transportation transportation unit 811c of the construction machine for establishing connection with the nuclear waste disposal unit 811a of the reactor facility main body 1 of the nuclear power plant, the nuclear power generation facility unit 811, The distribution dispenser of the reactor installation construction machine comprising the processing dispensing dispenser is such that the nuclear dispenser dispenser of the above nuclear plant installation includes the nuclear plant assembly at 500 m intervals inside the double structure block tank pipe pier (928) The connected nuclear waste treatment dual structure block tank bridge bridge 929 connects the strut block tank 590 with the water tank of the sea level SLL to form a double structure block tank 500m3 unit volume connection structure At the same time, the nuclear waste disposal double structure block tank bridge 929 is connected to the anchor chain 639 and the anchor chain 640 provided on the crane boom section 942 of the tow crane replacement tower crane, And at the same time winding up the wind turbine 958 of the rotating body and releasing the anchor 639 and the wire rope chain 915 with the tumbler winch 958, (593,594,595) of the submergence prevention structures of the submergence prevention marine power plant and the transport connection structure providing the transportation position by the connection structure having the submarine line connection structure to the injection nozzle of the injection nozzle connection port as the connection structure inside the reactor installation body (1) (1) Nuclear power generation facility (811) Nuclear waste treatment facility (811a) The construction transportation system (811c) of the construction machine that provides connection to the nuclear waste treatment facility (811a) The connection structure of the equipments that protect the distribution input device of the construction machine is composed of the nuclear power plant facilities;

As shown in FIGS. 5Y and 5Z, the transportation transportation unit 811c of the construction machine for establishing connection with the nuclear waste disposal unit 811a of the reactor facility main body 1 of the nuclear power plant, the nuclear power generation facility unit 811, Nuclear waste treatment system consisting of the nuclear power plant facility and the reactor facility construction equipment consisting of the above nuclear power plant equipment and the nuclear power plant equipment consisting of the above-mentioned processing distribution apparatus and the nuclear power plant facility, the dual structure block tank pipe bridge (929) The apparatus equipment includes a connection structure inside the reactor facility main body 1 of the nuclear power plant and a loop structure that is wound around a rotating tug winch 958 and loosens the anchor chain 640 with a tug- (959), but at the same time, the substitute goods sail (959), while providing the tugboat (636) operation assistance of the nuclear power plant facilities, the nuclear waste treatment double structure block tank bridge (929) A double structure block tank (598) at one side is connected to the sea surface to perform a combined work process. The ship is provided with a provisional passage and a nuclear waste treatment double structure block tank pipe bridge (929) The provisional passage is to temporarily hold the combined work of the nuclear waste treatment dual structure block tank bridge (929) nuclear power plant facilities at one location of 500m in the work, The double structure block tank (598) is connected to the outside of the outer block tank (599) by an even number of connecting parts and an odd number of connecting parts (5) Nuclear waste treatment in the nuclear reactor main body (1) of the nuclear power plant by providing the connection part as a connection structure Double structure block tank pipe bridge (929) (1) A connection structure with a submarine line wiring connection structure to the injection nozzle of the injection nozzle connection port while providing the distribution input devices of the construction equipment of the nuclear reactor power plant while providing the provisional passage of the sailing vessel (593, 594, 595) of the submerged marine power plant with the transport connection structure providing the transportation position to the nuclear reactor main body 1 of the nuclear power plant with the mooring devices are connected to the nuclear waste processing section 811a of the nuclear power generation facility section 811 (811c) of the construction machine to constitute nuclear plant facility as a connection structure of the equipment for protecting the distribution input device of the nuclear reactor construction equipment which consists of the nuclear waste disposal dispensing device;

As shown in FIGS. 5Y and 5Z, the transportation transportation unit 811c of the construction machine for establishing connection with the nuclear waste disposal unit 811a of the reactor facility main body 1 of the nuclear power plant, the nuclear power generation facility unit 811, Nuclear waste treatment system consisting of the nuclear power plant facility and the reactor facility construction equipment consisting of the above nuclear power plant equipment and the nuclear power plant equipment consisting of the above-mentioned processing distribution apparatus and the nuclear power plant facility, the dual structure block tank pipe bridge (929) (593, 594, 595) of the offshore power plant is connected to the distribution input device for pipe bridge cracking and dismantling by means of a coupling detachment hinge (27) to an outer position of the outer block tank (599) The lug pin connecting shaft 27a of the hinge 27 of the hinge 27 of the pawl rug 21 at the portion abutting against the provided hook lug 21 and the connecting shaft 27b of the long shaft for the hinge are provided for the hingeStructures that connect the double structure block tank connection to the block tank at a fixed distance from each other are connected to the connection structure inside the reactor installation body (1) of the nuclear power plant. Connection with injection nozzle and submarine wire connection structure of the nozzle connection port (593,594,595) Nuclear power plants' nuclear reactors (1) Nuclear power plants (811) Nuclear power plants (811) Nuclear waste treatment units 811a of the construction machine, or a nuclear waste disposal dispensing device of the transportation transportation part 811c of the construction machine to provide a dispenser / dispenser for a nuclear reactor construction machine, In the distributing and dispensing apparatus of the nuclear reactor construction machine, the handle lever 935 is attached by welding, Structure block Tank connection location Separate connection and disassembly Disassembly by means of a locking device (185) and separator (22) Dual structure block tank Disassembly coupling is provided as a connection structure and block unit double structure block tank hull disassembly (593,594,595) Internal connection structure of the nuclear power plant Installation of the spray nozzle and submarine line (946) of the nozzle connection port Connection structure (937) Coupling dispenser and lifting dock of marine power station (593,594,595) Mooring device of nuclear power plant facility Fixed lifting console of marine power plant to be protected by connecting structure (593,594,595) Nuclear power plant facilities are connected to each other at the location of the double structure block tank. (593,594,595) of the offshore power plant with provision of disassembly and coupling of the double structure block tank by the ship (22) Nuclear power plant (672) Mooring device, diving buoyancy control device, nuclear waste disposal dispenser and nuclear reactor facility safety facility Fukushima Nuclear Power Plant (811) 705 as a connection structure capable of being disassembled and coupled at a marine vessel manufacturing factory.

 Preferably, the nuclear plant (673) of the offshore and offshore marine power plants (593,594,595) and the nuclear reactor plant main body (1) and the nuclear power generation facility (811) of the nuclear power plant, Block tank Dust collector Nuclear waste treatment of reactor facilities Nuclear waste at the connection axis of equipment Nuclear waste treatment of nuclear reactor equipment for hull safety equipment, which constitutes treatment of nuclear waste (224) into nuclear fuel cycle of nuclear fuel industry. , The nuclear waste disposal and dispensing equipment remodeling facility of the reactor facility of the nuclear power generation facility 811 includes a nuclear radiation power control dual structure 672 of the marine power plant and nuclear reactor main body 1 of the nuclear power plant, A nuclear waste disposal dispensing apparatus having a block tank dust collector 794 and a nuclear fuel explosion control dispensing apparatus. The installation stage is also provided for the barge line of the anti-sinking double structure block tank, and the installation position of the distribution input device of the nuclear power plant (811) is set to 40m above the sea level so as not to be restricted by the weather condition of earthquake and tsunami. Nuclear Power Plant Nuclear Power Plant Nuclear Power Generation Nuclear Power Generation Nuclear Power Generation Nuclear Power Generation (811a) Nuclear Radiation Leakage Control System The nuclear reactor waste treatment unit (811a) of the nuclear power generation nuclear waste treatment facility (811a) includes a nuclear power plant maintenance facility (794), a nuclear power plant treatment facility (593,594,595) Nuclear power plant Main body (1) Inside Nuclear power plant (672) Reactor in case of failure inside reactor (811) In preparation for when the search operation period, take more than three months provided for blocking the reactor pipe line to a safety valve (472) and or, at the same time, nuclear power seolbibu 811 providing replace the boiler (783) the operation of thermal power connecting shaft; and

As shown in FIGS. 5 (a) and 5 (5), a nuclear power plant nuclear waste disposal unit 811a has a connection structure to supply a high-temperature, high-pressure steam for emergency power generation, In the period of renovation work, power supply is replaced by thermal power generation facilities to ensure safety of nuclear power generation facilities by safe and continuous operation of nuclear power plants. In the case of renovation of nuclear power plant facilities, (593,594,595) of nuclear power plant (673), diving buoyancy control device and distribution and input device of nuclear waste treatment, and the nuclear power plant of nuclear power plant (1) Before nuclear reactor facility safety operation of nuclear reactor facility At FUJITO nuclear power plant division (811), nuclear waste disposal of reactor facilities The connecting shaft of the power plant; included with this connection structure as possible decomposition combined in a marine vessel manufacturing plant, and is composed.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal dual structure block tank dust collector of the nuclear power generation facility 811, Nuclear power plant nuclear reactor facility (1) The facilities of the disaster prevention apparatus that constitute the inside of the connecting shaft include the floating nuclear power plant of the ocean power plant (672) and the reactor facility of the nuclear power plant Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Apparatus with Dual Structure Block Tank Dust Collector (794) Controlling Nuclear Radiation Leakage into Main Body (1) A plurality of nuclear reactor facilities are installed on the barge of an anti- The installation location of the nuclear power plant (811) at the top of the sea level (40 m above sea level) to prevent the earthquake and tsunami from being affected by weather conditions, Nuclear reactor leak control with double barriers to prevent the explosion of nuclear reactors of nuclear power plants Nuclear reactor leak control with double structure block tank Dust collector (794) Nuclear power plant (811) Nuclear waste treatment Double structure block tank Dust collector of the nuclear power plant (811) Nuclear power plant (593,594,595) of the power plant, the connection shaft of the reactor main body (1) of the nuclear power plant and the installation of the disaster prevention device constituting the inside of the connection shaft, The balloon 628, the rope 629, the rope knot 630, the marine cable car 256, And a double structure fire hose (9), a dual structure firefighting nozzle (10), an undersea mining air bag (130) and a weather forecast Observation (958) satellite weather forecast information gathering machine (960), substitute goods sail (959), electronic control unit of air defense pump control system and control system (150), seisphere of air supply device and tower crane replacement Crane boom area (942) Connected structure It is composed of facilities of disaster prevention device. At the same time, facilities of disaster prevention equipment are equipped with facilities of sound vibration frequency disaster prevention device in the disaster area where global warming phenomenon is overcome, At the same time, the equipment of the disaster prevention device is provided with facilities for moving equipment of the disaster prevention device in accordance with the power of wind equivalent to that of artificial waterfall falling down alternately providing the connection structure of the seesaw crane boom bridge 942 And a radial type dispersing and dismounting device, a submarine mineral deposit bag (130), a substitute goods sail (959), and a septic crane boom (942), the emission of water from above and above the sea is provided. At the same time, sound emission frequency and sound wave vibration wave which substitute radiation type dispersion and disaster prevention device are transmitted, At the same time, the facilities of the disaster prevention device are equipped with the wind and the wind over the sea surface to prevent the occurrence of typhoons in advance, while at the same time disaster prevention devices of nuclear waste treatment pipe manufacturing process (705) There are overhead lightning arresters (500), which are located at the top of the deck deck top block pylon (116) The location of the lightning rod 500 is provided on the rooftop of the control tower of the mooring tower 644 in the equipment of the lightning rod 500 of the block pylon tower 116 while forming the mounts of the runes 77 and the airship 78, The radar (840) was designed to maintain a peaceful earth environment with a lightning rod (500) that kept the hull from the lightning and lightning in the control tower, and to provide a safe environment for the earthquake of the reactor facilities disaster prevention device of the nuclear power plant equipped with double structure block tank reactor. In addition, it is necessary to prepare a disaster prevention device structure in the reactor main body (1) of the nuclear power plant and to provide a mooring device and a diving buoyancy control device (672) formed at the marine power station floating nuclear power plant (672) And nuclear waste disposal dispenser and nuclear reactor facility safety operation Before Fusi Nuclear Power Plant division (811), we construct nuclear waste treatment connection axis of reactor facility Is constructed as a connection structure that can be disassembled and coupled at a marine shipbuilding factory with the connection axis of the disaster prevention device.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal dual structure block tank dust collector of the nuclear power generation facility 811, (1) of the reactor plant of the nuclear power plant, the facilities of the disaster prevention apparatus constituting the inside of the connecting shaft are such that the distribution input apparatus of the nuclear power generation facility section (811) includes the nuclear power plant of the marine power plant (672) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Apparatus with Dual Structure Block Tank Dust Collector (794) Controlling Nuclear Radiation Leakage into Main Body (1) A plurality of nuclear reactor facilities are installed on the barge of an anti- The installation stage and the location of the distribution facility of the nuclear power plant (811) at the top of the sea level (40 m above the sea level), so as not to be restricted by the weather conditions of the earthquake and tsunami. Nuclear Safety Leakage Control System for Nuclear Power Generation Nuclear Power Plant Nuclear Reactor Leakage Control Nuclear Power Plant Nuclear Power Plant Leakage Control Double Structure Block Tank (593,594,595) nuclear power plant (672) of the marine power plant and the nuclear reactor main body (1) of the nuclear power plant are connected to the inside of the reactor main body (1) (1) of a nuclear reactor plant (1) of a floating power plant of a marine power plant, and an inner shaft of a connection shaft of the reactor main body (1) of the floating nuclear power plant In the facilities of the disaster prevention device of the nuclear power plant 811 constituting the nuclear power plant 811, the number of injections for jetting through the gap between the dual structure jetting nozzles is in the form of an injection nozzle It is also possible to prevent the occurrence of harmful tidal conditions by providing a disaster prevention device as a facility for disaster prevention devices in addition to the prevention of natural disasters in advance, And the air compressor 80 is operated by the electronic control unit 88 and the pressure reducing valve 85 and the safety valve 86 without the electronic control unit 88. [ 259 are provided together with the first pressure check sensor 86 and the second pressure check sensor 87 and the motor belts 252 and the motor shoes 250, the belt cover 261 and the air suction A filter 262 and an oil cooler 151 are formed and a tank of the oil cooler 151 is provided with a cooling water inlet 287 and attached to the upper end of the channel base of the bed frame 286, As well as means for producing air, The equipment of the disaster prevention device of the nuclear power plant 811 having the combination of the hose 947 and the high pressure hose 190 with the coupling 29 of the high pressure hose connection and the latent power of the typhoon at the same time, The disaster prevention device is installed at the upper and lower sides of the sea surface where the airflow 925 and the downward airflow 926 are controlled together with the yellow sand fine dust so that the disaster prevention and control are simultaneously performed. There are several manhole covers 152, several hatch covers 153 and several fire doors 154, which prevent the sailing vessel from losing its restoring power freely from a natural disaster of the typhoon, The ship is located above the left and right sides of the ship and the vessel, so that the ship is prevented from sinking in any case, and at the same time, the safety regulations of the International Maritime Safety Association are faithfully executed. At the same time, in the facilities of the disaster prevention device of the nuclear power generation facility unit 811, there is provided an ejection device for providing a falling drop of the jetting water 38, which provides a fall that lowers the power of the typhoon, A discharge jet which continuously forms an ejection of the jet number 38 and forms a continuous drop jet, while at the same time discharging the fall of the storm, such as the artificial waterfall roar of the same level, This scene, in which a fierce and violent typhoon is converted into a warm-air wind along with the number 38, but at the same time, the power of the typhoon is reduced, is transmitted to the floating observation weather station by the unmanned camera 184, (593,594,595) of a marine power plant which was sent from the Meteorological Observation Center to control the upward airflow (925) and the downward airflow (926) The unmanned camera 184 and the weather observation equipment radiosonde weather observation radar 840 are mounted inside the basket 42 on which the lower end fillet of the adboards 77 is mounted in the reactor installation main body 1 of the fire station, A rubber tube 947 for introducing air for the inside of the container for the inflow control device provided in the connection structure to the disaster prevention nozzle 945 and the submarine line wiring 946 by an underground line and a furnace for continuous operation of the furnace 948 The raw material bricks 948a of the blast furnace 948 are inserted into the facilities of the nuclear power generation facility 811 inside the nuclear radiation leakage control double structure block tank dust collector 794 with the raw material bricks 948a of the furnace 948 (949) for diving buoyancy control, a thermocouple thermometer switch (950) for thermostatic sensor, and a seesaw crane boom bar (950) for towing replacement tower crane 942) The hydraulic aerator 943a for the hydrothermal power generator of the marine sheath hydroelectric power plant 943, the Phelpton turbine 943b for the large hydroelectric power plant, and the Francis turbines 943c for the large hydroelectric power plant, (952) of the non-powered pump for the position energy control of the water, which is provided with the hydroelectric power generating device of the water purifier 944 and the connection structure of the water purifier 954, and the military equipment submarine 953 ) Is equipped with a computer laser cutting machine 954 to monitor the maintenance status of the facility facilities of the disaster prevention device of the nuclear power plant of the marine power plant (1) and the nuclear power plant of the marine power plant (1) The preservation type message photo shovel (955) was set up as the disaster prevention device of the nuclear power plant division (811), and at the same time, the World War II, the Korean War, It is a collection of portraits and fictitious figures that collect the characters of the war criminals who have fallen to the whim of all the elements of military action and behavior that are pursuing nuclear accidents and nuclear explosion experiments. The coordinates of the bronze statues are set within the 2,400km diameter range that forms the United Nations within and outside the center of the iron triangle center of the Korean peninsula at 1,200 km radius. There are 38 degrees 20 minutes 00 seconds north latitude, 127 degrees east latitude Kangwon-gun, Gangwon-do, Republic of Korea Kangsan-ri 190 Donggwon-eup Gangsan-ri 190 km from the center of the peninsula in the eastern part of the territory of Korea. It is called as No. 1 Northeast Asia within a radius of 400 meters and radius of 1 kilometer from the circumference of Northeast Asia. And 45 Northeast Asia, we set up an area of 1000 ㎢ which is one of the new concept of the United Nations. At the same time, a peace preserved message photo shovel (955) is set up, which is called Northeast Asia 1500 km from the center of the Korean peninsula and 1500 km from the center of the Korean peninsula, called 3000 Northeast Asia, And at the same time the wind power generator windmill 957a of the offshore wind power plant 957, the underground line disaster prevention nozzle 945 and the submarine line wiring 946 are connected to the facilities of the disaster prevention device of the nuclear power generation facility unit 811, (959) and a satellite weather forecast information collection machine (960) installed in the reactor main body (1) of the nuclear power plant as a facility for connecting the disaster prevention device of the nuclear power generation facility (811) (593,594,595) Mooring devices and diving buoyancy control devices in nuclear power plants (672) and nuclear plant waste disposal systems After copper ago when nuclear power connection emergency equipment of a nuclear reactor plant in seolbibu 811 axis; is configured to include a connection structure capable decomposition combined in a marine vessel into a manufacturing plant.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal double structure block tank dust collector facility of the nuclear power generation facility 811, The facility of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear reactor plant main body 1 of the nuclear power plant is the facility of the disaster prevention apparatus of the nuclear power generation equipment section 811 constituting the inside of the connection shaft of the nuclear reactor main body 1 of the nuclear power plant, A nuclear waste disposal dispensing apparatus and a nuclear fuel explosion control dispensing dispenser equipped with a flood control unit 672 of a marine power plant and a nuclear waste disposal control dual structure block tank dust collector 794 inside a reactor facility body 1 of a nuclear power plant, A plurality of reactor facilities are installed in the barge of an anti-sunken double structure block tank of the ocean, and a step of installing seawater so as not to be restricted by the weather condition of an earthquake or a tsunami Nuclear power plant (811) at the top 40m Nuclear reactor type facility with anti-sink type barge line facility installed with position setting Safe operation Nuclear reactor facility safety device to establish safe operation Nuclear power plant safety operation device Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Nuclear Reactor Leakage Control to Prevent Explosion of Nuclear Reactor (794) Nuclear Reactor (593,594,595) Nuclear Power Plant The facilities of the nuclear power plant 811 constituted by the power plant 672 and the inside of the reactor facility main body 1 of the nuclear power plant are provided with the reactor facility main body 1 of the nuclear power plant of the floating power plant 593,594,595, (1) of the nuclear reactor plant (1) of the nuclear power plant, In accordance with the sovereignty line, Vladivostok, Uleungdo, Dokdo and Pohang are connected to Russia, and the energy resource transportation is provided as a nuclear waste disposal dual structure block tank marine tunnel traffic system (941). At the same time, Yeosu and Jeju Island are treated as nuclear waste disposal double structure block (941). At the same time, Pyeongtaek, Baekryeongdo, and Shandong Peninsula are connected to the Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941) (941), and at the same time, establishing the foundation of the new Northeast Asian Nationa, and at the same time transforming it into a one-day living zone, while simultaneously establishing the NLL sovereignty zone Illegal fishing lines and all military vessels in other countries that come and go to the island are allowed to pass by permission to enter the sovereignty area. The rope-knot hooks (630) formed on the netting of the flagpole rubber balloon and the wire rope (19) are like kelp in the sea, so illegal fishing boats are allowed to throw a net on the fishing ground and simultaneously restrict access to rope knot illegal fishing boats. (630) to provide national security by means of disaster prevention devices that prevent thrusting nets from being caught in the throat nets, and at the same time, Safe operation of the mooring device, diving buoyancy control device, nuclear waste disposal dispenser and reactor installation of the reactor plant, provided in the nuclear reactor plant main body (1) of the nuclear power plant, and the mooring device and diving buoyancy control device formed in the nuclear power plant (672) Nuclear Waste Treatment of FHI Nuclear Power Plant (811) Double structure block tank Dust collector of offshore and offshore marine power plants equipped with reactor facilities Form dock nuclear power plants and nuclear power plant reactor equipment main body 1, the connecting shaft connecting the axis of the equipment of the emergency device constituting the interior of the; included in the connection structure possible decomposition combined in a marine vessel into a manufacturing plant, and is composed.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal dual structure block tank dust collector of the nuclear power generation facility 811, (1) of the nuclear reactor plant (1) The facilities of the disaster prevention apparatus constituting the inside of the connecting shaft are the same as those of the nuclear power plant (811) The facilities of the disaster prevention apparatus include a nuclear waste disposal and dispensing apparatus having a floating nuclear power plant 672 of a marine power plant and a reactor structure main body 1 of a nuclear power plant and a nuclear radiation leakage control dual structure block tank dust collector 794, Nuclear Fuel Explosion Control Distribution Dispenser A number of nuclear reactors are installed on the barge of an anti-sinking dual structure block tank of the ocean. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant (794) nuclear reactor leakage control control system to prevent nuclear power plants from exploding, and to operate nuclear reactors at the nuclear reactor plant (794), the nuclear power plant (672) and nuclear reactors The facilities of the nuclear disaster prevention apparatus of the nuclear power generation facility 811 constituting the inside of the facility main body 1 include the connection axis of the nuclear power plant main body 1 of the nuclear power plant of the marine power station 593,594,595, The connection shaft of the reactor main body 1 of the nuclear power plant is connected to a floating nuclear power plant 672 of a marine power plant and a reactor of a nuclear power plant In addition to providing a limited range within the main body (1) from the ground up to 29 kilometers (29 kilometers) above sea level, several floodplains formed over the sea surface and north of the sea at 5 degrees along the sea and 38 degrees above the sea of the East Sea, It is equipped with a sensor sensor for military defense that enhances the surveillance function to prevent the production of military equipment by installing a sensor sensor. At the same time, it has a restriction to make nuclear facilities of Pyongando and Hamkyeongdo helpless, The missile is fired at the top of the firing position and is formed as a defensive missile attached to the net so that when the missile is fired by the other party, it automatically induces the atomic explosion to occur in the other region to give up all military provocation At the same time, it immediately strengthens the nuclear weapons, 5, and a 38-degree northward over the Pacific Ocean in the East Sea, equipped with sensors for military defense sensors installed in the floodplain, and at the same time, a peace- In addition, it is necessary to re-install each region within a radius of 1200km from the center to fulfill its duties according to rights and duties according to the establishment of a new federal state in Northeast Asia. At the same time, (593,594,595) installed in the nuclear reactor facility (1) of the nuclear power plant in the offshore and the airspace, and the distribution device of the dredging buoyancy control device and nuclear waste disposal in the nuclear power plant (672) Nuclear power plant equipment and reactor facility safety operation Before the operation, Nuclear waste treatment of nuclear facilities of the facility (811) Double structure block tank Dust collector of the offshore and offshore marine power plants equipped with reactor facilities (593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) As a connection structure capable of disassembling and coupling at marine shipbuilding factories.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal dual structure block tank dust collector of the nuclear power generation facility 811, (1) In the facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power plant, the facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the above nuclear power generation facility include a floating nuclear power plant 672 of a marine power plant, Nuclear waste treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus equipped with dual structure block tank dust collector 794 for controlling nuclear radiation leakage into the nuclear reactor facility main body 1 of a power plant A plurality of nuclear reactor facilities are connected to a marine anti- The installation of the tanker barge and the installation of the nuclear power plant 811 at the top of the sea level 40 m above sea level, Nuclear reactors that prevent submergence of nuclear reactors that can not explode Nuclear power plants Nuclear power plants Nuclear reactors that can prevent explosion Nuclear power plant leak prevention Controlled double structure block tank dust collector (794) It is composed of disaster prevention equipment which is composed of the inside of the connection shaft of the nuclear reactor facility. The nuclear power plant of the marine power generation plant (672) and the reactor main body of the nuclear power plant (593, 594, 595) nuclear power plant of the above-mentioned marine power plant, and the disaster prevention device (811) of the nuclear power generation facility part (811) (38) of the disaster prevention line that hides the typhoon inside the facility of the typhoon, The disaster prevention device of the power generation facility unit 811 is provided with a disaster prevention device installed at the upper surface of the lower part of the sea level (SLD) within the troposphere 10 km above the upper part of the sea level, The disaster prevention water is provided at the top of the North Pole by an atmospheric circulation passage for a pipe level pipeline (958) for a dual structure disaster prevention device at an equatorial point, and at the same time, a seisike crane boom zone (942) At the same time, natural disasters such as artificial waterfalls, such as unmanned disaster prevention waterways, are installed in the facilities of the nuclear disaster prevention facility of the Nuclear Power Plant Division (811), and at the same time, the typhoon is released into Hiroshima The number of atomic bombs is estimated to be one million. Thermal energy The latent heat of atomic bombs is stored sequentially in the Pacific and Atlantic waters. (942) of tower crane replacement tower crane is installed as a connection structure with pipe-level piping line (958) for dual structure disaster prevention device. At the same time, humanity of the global village cleans up sadness and suffering from disaster disaster The double structure high pressure hose 190 of 500 m in the upper part of the sea surface of the connection shaft provided in the manufacturing of the disaster control pump control system and the electronic control unit connection structure of the control system 150 is connected to the high pressure hose 190, 29), and at the same time, a tube level piping line (958) is formed at the side of a deck deck of a float, and a septic crane boom (942) And at the same time, the seesaw crane boom zone 942 of the tower crane is provided with a switchover of the descending airflow 926 to the ascending airflow 925, And at the same time, a yellow loess mixture having discharges from several double-structured fire-fighting nozzle 10 is installed in a pipeline line 958 having a tube level of a non-ferrous metal whose thermal conduction efficiency is better than that of iron, In addition, the harmful red tide breeding as well as the typhoon are provided inside the main body 1 of the marine nuclear power plant at the same time as the precaution condition is controlled by the nuclear radiation leakage control double structure block tank dust collector 794, The nuclear facilities of the Nuclear Reactor (Nuclear Power Plant) and the Nuclear Reactor Facility (Nuclear Power Plant). 1) It is possible to maximize the production power by operating the nuclear power plant efficiently with the disaster prevention equipment, (1) to prevent sinking of the nuclear reactor main body (1) of the marine power plant and to prevent the explosion of the nuclear fuel and to install the disaster prevention device structure of the distribution shaft to the nuclear reactor plant main body 1 ), And a mooring device, a diving buoyancy control device, a nuclear waste disposal dispenser, and a nuclear reactor facility installed in a marine power plant floating nuclear power plant (672) Equipment Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Included as connection structure capable of disassembly and disassembly at a marine ship manufacturing factory by means of disconnection facility of disaster prevention device which constitutes inside reactor connection axis.

As shown in FIGS. 5Y and 5Z, the floating nuclear power plants 672 and 593 of the offshore and offshore marine power plants equipped with the nuclear waste disposal dual structure block tank dust collector of the nuclear power generation facility 811, The facilities of the disaster prevention apparatus constituting the inside of the connecting shaft of the reactor main body 1 of the nuclear power plant are the same as those of the floating nuclear power plant 672 of the marine power station ) Nuclear waste disposal and dispensing device with nuclear reactor radiation leak control dual structure block tank dust collector (794) inside nuclear reactor facility main body (1) of nuclear power plant Nuclear fuel explosion control distribution dispensing device and nuclear fuel explosion control distribution injecting device A step of providing installation on the barge line of the double structure block tank and a step of installing the nuclear power generation facility 811 at the upper 40 m of the sea level so as not to be restricted by the weather condition of the earthquake and tsunami Nuclear reactors that prevent the explosion of a large number of nuclear reactors in a nuclear power plant Nuclear reactor leakage that prevents the explosion of nuclear reactors in a nuclear power plant (593,594,595) Nuclear power plant (672) of a marine power plant and atomic power plant (672) of a nuclear power plant. In the facilities of the disaster prevention apparatus of the power generation facility unit 811, the facilities of the above-mentioned disaster prevention apparatus control the nuclear radiation leakage constituting the nuclear power plant 672 of the marine power plant's floating support (593,594,595) (794) and a nuclear waste treatment double structure block tank bridge (937). The facilities of the connected shaft disaster prevention apparatus are as follows: the axis of connection between a floating nuclear power plant (593, 594, 595) nuclear power plant (672) of a marine power plant and a reactor main body (1) of a nuclear power plant; 1) In the inner part of the connecting axis, the weaker countries, consisting of the storks of the superpower and the leaders of the weaker countries, composed of the leaders of the powerful nations, cooperate with each other in order to provide facilities for disaster prevention in a better living environment The facilities of the disaster prevention device are equipped with a disaster prevention device of the connecting shaft which prevents the stork from tearing down the stomach by imitating the stomping of the stomach and preventing the stomach from being damaged by the gap between the stomachs of the stomach after the stomach And the leaders of the international community in each country are planning to dispose of the disaster prevention equipment and the distribution Tanks, bombers, bombs, bullets, satellites, missiles, nuclear bombs, and rocket bombs are equipped with disaster prevention equipment for connecting shafts that do not conduct manufacturing tests on land, but facilities for disaster prevention equipment are established by international norms and codes The disaster prevention system was installed to overcome the puncture and the global economic crisis, but the disaster prevention system was equipped with facilities for disaster prevention equipment for the connection axis that was able to save the world economy by fostering environmentally friendly, pollution- At the same time, the facilities of the disaster prevention device constituting the inside of the connection shaft of the nuclear power generation equipment section 811 cause the sinking accident of the ship during the weather condition of the bad condition and the bombardment state often occurs. However, It is necessary to provide facilities for the disaster prevention device of the connecting shaft which can prevent the sinking accident, At the same time, while providing the vessels, the facilities for disaster prevention devices were set up in the blast furnace (948) located inside the steelworks, and the construction equipment heavy equipment At the same time, the facility connection shaft of the disaster prevention device of the nuclear power generation facility section 811 is provided with a mooring device formed in the nuclear power plant 672 of the marine power station floating warehouse (593, 594, 595) Diving buoyancy control device and nuclear waste disposal Dispatching device and nuclear reactor facility safety operation Before the operation Fusion Nuclear power generation equipment division (811) Nuclear radiation leakage control Double structure block tank dust collector (794) As a connection structure capable of being disassembled and coupled at a marine shipbuilding factory by means of a connecting shaft The invention is a reactor of a nuclear power station plant having a nuclear waste disposal double structure block dust collector tank for technical base.

Preferably, the double structure block tank dust collector of the nuclear plant (673) and the nuclear reactor main body (1) and the nuclear power generation facility (811) of the nuclear power plant of the land and ocean marine power plants (593,594,595) The diving progression-ready controllable control and dispensing apparatus for the hull safety equipment constituting the connection axis position of the process pipe manufacturing process 705 includes the distribution input device of the nuclear power generation equipment unit 811, (672) and the interior of the nuclear reactor plant main body (1) of the nuclear power plant, the marine bioglass and barnacles, which are positioned as connection structures outside the nuclear reactor plant at the bottom of the sea level surface (SLL) The electrode plate node 938, which can not be grown in the connection structure, is connected to the nuclear waste treatment double structure block tank bridge 929 at the bottom of the sea level surface (SLL) The distribution apparatus of the nuclear power plant 811 may be provided with a sonar 907 of a fish finder that monitors the military equipment submarine, (SLU) to provide a connection structure with a submarine line wiring (946) connected to the inside of the nuclear plant main body (1) of a floating nuclear power plant of a marine power plant while providing a detection of dynamics in the sea. Upper deck (SDU) Offshore power plant Alternative towers Replacement tower Cranes Seisoka Crane Boom area (942) Connection structure Mooring device and power generation facility Connection structure Hull safety distribution Hull safety device and intercommunication satellite (962) Connection (960) of satellite satellite weather forecasting system to provide a connection structure inside the nuclear reactor main body (1) of the nuclear power plant, and to support the marine power generation (593,594,595) Mooring device and diving buoyancy control device for nuclear power plant (672), nuclear waste disposal system for nuclear waste disposal, and nuclear reactor facility facility safety operation Fukushima Nuclear Power Plant (811) And a connection shaft of the pipe manufacturing process 705 as a connection structure capable of being disassembled and coupled at a marine vessel manufacturing factory.

Referring to FIG. 6, within the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, a nuclear power plant 811, The tie winch 137 and the wire rope 19 of the elevator machine room constructed of the speed reducer 251 and the electric motor body 192 on the roof of each building and the building are connected to the driving wheel roller 135 by the upper part of the steel tower 116, The fire prevention and disaster prevention line was constructed in the summit of the mountain valley and around the beach which constituted the fire prevention disaster prevention line which made attachment and the fire evacuation prevention product of the cable car (256) (256) of nuclear power generation facility (811) showing prevention arrest prevention control part of nuclear power generation facility division (811) Firefighting disaster prevention article of firefighting sensor pump Straight configuration of emergency disaster prevention device Road,

As shown in FIG. 6, cable car (256) equipment of the nuclear power generation facility unit 811 is provided with a high and low acid 395, a nuclear waste treatment double structure block tank bridge bridge 929, (685), which includes all of the ridge lines below the surface of the mountain range (GLL), high and low building buildings near the beaches of the sea bath, and the rooftop firefighting cabin (394) The steel tower 116 is fixed with an anchor bolt 133 by means of a hand tool and then a driving wheel roller 135 and a pair of wheel rails 135 formed of several wire ropes 19 are fixed on the steel tower, And a tug winch 137 is installed below the steel tower 116 at each corner of a mountain top portion and a building building roof firefighting operation cabin 394, The speech winch 137 is connected to the generator 213 of the power plant 267 and the engine & A power source 46 produced from the machine 226 is connected to a transformer 96 connected to several electric wires and a motor power motor 192 provided with a micro control function by receiving power of a telephone pole 95 and several compressors And a plurality of power motors 192 for controlling the sensor of the electromagnetic valve 192. The control unit 106 is connected to the fire cable car 256 through the vinyl tent (10) hole (20) for distributing the load of the object of the fire water (7) inside the fire hose (9) to the water collecting tank (43) And a fire sensor pump body formed by the airship 78 and the rope 131 in the respective adboards 77 and the voltage 684 of the transformer 96 of the substation is provided for each industrial house and the earth houses of the submarine .

Referring to FIG. 6A, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention includes a main body 1 of a nuclear power plant, a nuclear power plant 811, (811b) Marine power plant body dock The power production and production department of the nuclear power generation facility (811) showing the regulation structure of the construction machine position of the hull position movement control of the marine hydroelectric power plant lifting stand (593,594,595) 811b) Hydroelectric power plant construction Construction of the connecting structure of the strainer Construction of the road,

6A, a conceptual diagram 678c of a conventional influent-type power plant and a conceptual diagram 678d of a reservoir-type power plant are shown in a conceptual diagram 678c of an influent- Or the adjustment paper 680a, the flow rate exceeding the maximum use amount is not utilized for power generation but is discharged in an invalid manner.

As shown in FIG. 6A, the waterway is separated according to the terrain, and in this method, the construction cost is not so great, but the generated electric power differs depending on the natural flow rate. Also, since this natural flow rate also varies with the season, In Korea, there is no power plant of this type, but in an abundant river such as Russia (Siberia) or Brazil, an inflow-type power plant that uses natural flow as it is for power generation is constructed and operated, The power plant is a power plant with a large reservoir that can regulate the seasonal changes in the flow rate of the river. It is a power plant that stores the water remaining in the feng shui and discharges it to the dry season to effectively utilize the river flow over a long period of time (usually one year).

As shown in FIG. 6A, the reservoir type power plant is precious because the water system of Korea is relatively small in flow rate. Among them, the Soyang River Power Plant in the North River and the Chungju Power Plant in the South Han River are multi-purpose dams built as a reservoir power plant. In terms of effective reservoir, there are about 1.9 billion [t] of Soyanggang Dam and about 1.8 billion [t] of Chungju Dam. In the case of a low water flow system, , The difference between the amount of water withdrawn from the river and the amount required for power generation is stored in the adjustment paper or discharged to cope with load fluctuation over several hours or several days. This method is different from the influent type power plant 678c in that the maximum amount of the power plant can be designed to be considerably larger than the amount of water taken in the river. In addition, there are many cases where peak load is shared, which is sometimes referred to as peak power generation.

As described above, a double structure block tank for nuclear waste disposal is installed in the nuclear reactor main body 1 of a nuclear power plant having a nuclear reactor dust collector, and a marine hydroelectric power plant lifting plate (678c) and the conceptual diagram of the reservoir plant (678d) showing the construction machine position control arrangement of the hull locomotion control of the hydroelectric power plant of the construction machine connection structure (678e) (SDU) of a marine power plant dock hull deck upper part (SDU) to a power production and manufacture part (811b) of a nuclear power generation facility part (811) inside a nuclear power plant main body (1) of a nuclear power plant having a nuclear waste power plant, (593, 594, 595) of the marine hydroelectric power plant comprising the above-mentioned marine hydroelectric power plant part The readers 593, 594 and 595 are connected to a hydraulic rotary cylinder 620 of a rack and pinion type NRP which is a rotary cylinder, a butterfly valve 622 for controlling the buoyancy of the band guide 621, And the hydraulic ladder 607 and the portable lug pin 608 are attached to the vertical partition wall 605 and the pin linking shaft 606 for connection to the portable lug, Flange connection connector joint part machining hole 615 The construction machine connection structure and bridge bridge 928 and the pipe bridge 937 are connected to the inside of the marine tunnel traffic device 941 by the oil drilling machine 908 and the bridge bridge 928, Inside the tunnel bridge (937) Inside of the marine tunnel traffic device (941) The marine tunnel traffic device internal train (771) is composed of hydroelectric power control facilities by disassembly and connection with the construction machinery connection structure, If classified according to the function, the water intake equipment 680n and the water supply equipment 680o (680p) and waterproofing facilities (680q) are the facilities that utilize the flow rate and the free fall, while the construction machinery position control of the marine hydroelectric power plant flood control (593,594,595) Theoretical hydraulic power for controlling the flow rate of the seaweed is inputted to the aberration, and the aberration and the generator are rotated, and the water intake equipment 680n and the water supply equipment 680n, which are equivalent to the arrangement of the multi- 680o), a power generation facility (680p), a waterproof facility (680q) and a hydroelectric power plant (943).

Referring to FIG. 6B, a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention includes a nuclear reactor main body 1, (811b) Marine power plant body dock Hydraulic or hydroelectric power plant aberration or pump aberration showing the construction of the position control system of the hull position control of the marine hydroelectric power plant floodplain (593,594,595) constituting the upper part of the hull deck (SDU) Main valve (265) Hydroelectric power plant Construction machine Straight configuration of connecting structure Road,

As shown in FIG. 6B, the amphibious power plant of a conventional hydroelectric power plant or a marine hydroelectric power plant aberration or pump aberration 264 and a main valve 265 hydraulic power plant construction machine connection structure is a kind of coordination knowledge or a reservoir type power plant This is a power plant that pumps water from the lower reservoir to the upper reservoir by using a pump of the nuclear power plant at the midnight or at the end of the week when the electricity demand is low and uses it at peak load. There are two types of mixed pumped-storage power plants, which have natural inflows from the lower reservoirs, and which have a natural inflow at the upper reservoir.

As shown in FIG. 6B, the conventional power plants are located in Cheongpyeong (400,000 kW), Samrangjin (600,000 kW), Muju (60,000 kW), Sancheong (700,000 kW) 1 million [kW]), all of which are the latter's power plant,

As shown in the figure, as shown in the figure, the nuclear power plant for nuclear power generation has a double structure block tank, a power generating and manufacturing section 811b) of the hydro-electric power plant showing the regulation structure of the position of the construction machinery of the marine hydro-power station flood control station (593,594,595) constituting the upper part of the ship's deck hull (SDU) , It should always be constructed so that the flow rate required for power generation can be safely taken and the loss of dropping and flow rate is minimized as much as possible. Hydropower facilities in hydroelectric power plants can be classified according to their functions. Hydraulic facilities divided into 4 types of water supply facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) (593, 594, 595) of the hydro-electric power plant, which shows the configuration of the position control mechanism of the construction machine, the hydraulic power for operating the flow rate of the seaweed is input to the aberration, The hydraulic equipment which is divided into four types of water intake facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) which are equivalent to the arrangement of the multi- (593, 594, 595) of the hydro-electric power plant, which shows the arrangement of the position control mechanism of the construction machine, Theoretical hydraulic power is input to the aberration, and the aberration and the generator are rotated. The water intake equipments 680n, 680o, 680p, and 680q, which are equivalent to the arrangement of the multi- And a multistage entry flow hydraulic power generator 944 of the power plant 943.

Referring to FIG. 6C, there is shown a dual structure block tank dust collector for nuclear waste disposal according to the present invention. The nuclear water power generation production control Submarine power plant body dock Hydraulic power plant showing construction equipment position control structure of marine hydroelectric power station floating structure (593,594,595) on hull deck upper part (SDU) Construction configuration of connecting structure construction road,

As shown in Fig. 6C, in the conventional tidal power plant, the above-mentioned tidal power generation is a power plant for converting the potential energy due to the tidal difference of seawater into electric power, and it is preferable that the installation place is as large as possible. When the seawater is pushed by the tide, it is guided to the reservoir built on the shore. When the tide is escaped, the seawater stored in the reservoir is dropped into the sea. As in the case of pumped storage, And a tidal power plant in Reims estuary in France is famous for the use of tidal cars up to 13 [m] as an example of operation of the tidal power plant. Here, we are developing 240 kW of 10,000 [kW] and 24 of 240 km [kW] using a tidal car of maximum 13 [m] and average 8.5 [m]. There must be a sea of at least 10 m above sea level, and the condition that this coast is suitable for the construction of the reservoir should be met.

 As shown in FIG. 6C, in the past, a tidal power generation plan is being planned in several places around Chungcheongnam-ri only in Korea. It is known as a very favorable candidate for constructing a power plant with a maximum tidal pitch of 7.9 m, a land area of 120 m ², a dike length of 2.1 km, and a facility capacity of 400,000 kW.

  For reference, [Table 2] shows the average (tidal difference) at major points in the world (here, the average is even more than 4.6 [m]).

 [Table 2] Even the average at major points in the world

As shown in the figure, as shown in the figure, the nuclear power plant for nuclear power generation has a double structure block tank, a power generating and manufacturing section 811b) of the hydroelectric power plant 233 showing the construction machine position adjustment structure of the hull position movement control of the marine hydroelectric power plant flood control console (593, 594, 595) constituting the upper part of the dock hull deck of the marine power plant body (SDU) Since it is a facility that uses flow and fall, it should always be built so that the flow necessary for power generation can be safely taken, and loss of drop and flow can be minimized as much as possible. Hydropower facilities in hydroelectric power plants can be classified according to their functions. Hydraulic facilities divided into 4 types of water supply facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) The hydraulic system of the hydro-power plant (943), which shows the configuration of the position control mechanism of the hull of the marine hydro-power plant, is a hydraulic turbine, which serves as an input to the aberration, Hydraulic equipments which are divided into four types of water intake equipments (680n), water supply equipments (680o), power generation equipments (680p) and waterproof equipments (680q) which are equivalent to the arrangement of the multi- The hydraulic system of the hydroelectric power plant showing the configuration of the position control mechanism of the hull position movement of the marine hydroelectric power plant floating posture (593, 594, 595) The power generator 680p, and the waterproofing facilities 680q, which are equivalent to the arrangement of the multi-stage multi-stage pump 2, And a multistage entry flow type hydraulic power generator 944 of the power plant 943. FIG.

As shown in FIG. 6C, the nuclear power plant for nuclear power generation has a double structure block tank, a nuclear reactor power plant having a reactor dust collector, The hydraulic structure of the hydroelectric power plant showing the regulating structure of the construction machine position of the hull locomotion control of the marine hydroelectric power plant flood control station (593,594,595) constituting the upper part of the power plant dock hull deck (SDU) It should be constructed so that the required flow rate for power generation can be safely taken, and loss of drop and flow rate is minimized as much as possible. Hydropower facilities in hydroelectric power plants can be classified according to their functions. Hydraulic facilities, which are divided into 4 types of water intake facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) (593,594,595) of the hydro-electric power plant, the hydraulic power plant which controls the position of the hull structure of the hydro-power plant, (680n), a power plant (680p), a waterproof facility (680q), and a hydroelectric power plant (943), which are equivalent to the arrangement of the multi-stage pump (2) 944) devices.

 As shown in FIG. 6C, in the reactor main body 1 of the nuclear power plant having the reactor structure of the nuclear waste treatment dual structure block tank reactor for nuclear power generation, the power generating and producing section 811b of the nuclear power generating facility section 811 The water tank 292 and the circular dams 680 containing the disinfectant water of the disaster prevention water in the natural water and the control water stored in the circular prefabricated water tank 292 located at the top of the mountain and the circular dam 680, The installation process and the flood control facility which control the flood damage with the construction machine to cope with have already been established as the new federal state of Northeast Asia. Minute 00 second latitude latitude 38 degrees 20 minutes 00 seconds Korea Republic Gangwon-do Cheolwon-gun Gangwon-do Gangsan-ri Mountain 190 intellectual center of the peninsula in the center of the peninsula 1200k radius of the circumference of the circumference 2400km circumference (1) of the nuclear power plant with equipment consisting of a non-powered pump (393) inside the nuclear power plant, an electronic sensor valve and an unmanned camera (184) of the control system in the water tank, The flood control automation facility is constructed to control the flood control process by inputting the input device.

As shown in FIG. 6C, a construction machine of a reactor plant of a nuclear power plant equipped with a nuclear waste disposal double structure block tank nuclear reactor for nuclear power generation generally includes a hydraulic power generation control apparatus for controlling water storage inside a main body, Weather data from the barge hull at the top of the holding tank and the barge hull at the bottom of the holding tank to provide weather information to the marine tunnel traffic system constituting the flood control. (672a) distribution device in the connection structure of nozzle, non-powered pump and cable car in the water storage tank and round dams equipped with pumps, valves, and weather information received through the equipment radar. A water treatment vessel that improves the flood disaster that constitutes the dispensing device of the flood control machinery for flood control facilities. In addition to constructing the distributing and input device for the construction machinery for marine hydroelectric dams in water storage tanks and marine tunnel transportation equipment for facilities, each circular water tank located at the top of the mountain selects stainless steel plate or plastic material which does not rust, The water tank is composed of double structure block tanks, and the water is stored in the inner block tank, and the water is stored in the outer block tank A heating device is attached to the outer wall, and a heating device is provided in the middle between the inner block tank and the outer block tank so that the air conditioner of the cooling device, the heating fan for cooling the air, and the cooling fan are further constituted.

As shown in FIG. 6C, the nuclear power generation nuclear waste treatment dual structure block tank is installed inside the reactor main body 1 of the nuclear power plant having the reactor dust collector as the power production and manufacture section 811b of the nuclear power generation facility section 811 There is a case that the water tank equipment equipped with the tanks for controlling the storage and flow of the water is sometimes caused to sink into the water while the ships are out of balance due to the strong wind waves and the sea crane is mounted on the upper part of the hull deck deck After being constructed, the engine or water turbine generator is operated and power is supplied to the control pump unit. However, considering that it is used as a ship for marine control after it is fixed and bound to a bollard which is a wire rope or rope at the rear of a tugboat, Fixed type double pipe structure tank Bridge construction bridge type saddle formwork It is possible to construct a pier with a depth of 0.1 ~ 0.5km unit to connect and connect.

As shown in FIG. 6C, the nuclear power generation nuclear waste treatment dual structure block tank is installed inside the reactor main body 1 of the nuclear power plant having the reactor dust collector as the power production and manufacture section 811b of the nuclear power generation facility section 811 The marine power plant is equipped with a nuclear reactor plant to be separated and connected according to the depth of the ocean so that the water does not sink even in a bad weather condition in an area having a depth of 10 km or more, It is the injection nozzle that contains the disinfection and disinfection by discharging the disaster prevention material at a higher place, farther than the conventional standard firefighting window, more rapidly and more rapidly, and the disaster prevention nozzle is composed of the small pipe 14 and the air (10) connected to the rear end of the piping of the high pressure multi-stage pump (8) and a disconnection nozzle (10) connected to the disaster prevention hose (9) The nozzle includes a nozzle support frame (11), a hook (13), a hook (18), a wire rope (19), and a shock absorber The nut 25 and the washer 26 are used to fasten the iron plate 165 and the flange 28 with the springs 186 and the hooking lugs 21 and the safety pins shackle 23 and the bolts 24, And a high-pressure submersible pump controller (not shown) including a system including a high-performance submersible pump 36 and a high-pressure bottom-up pump control device by means of a cellular phone 82 of a communication means and a cable car 256 engine 226, Waste treatment Double structure block tank This equipment is formed in the reactor main body (1) of a nuclear power plant having a reactor dust collector.

Referring to FIG. 6D, the power production and production unit 811b of the nuclear power generation facility unit 811 is installed inside the nuclear power plant main body 1 of a nuclear power plant having a nuclear waste treatment dual structural block tank reactor nuclear power plant nuclear power plant according to the present invention, (678p) Construction of hydroelectric power plant in the Han River system showing the arrangement of the construction machine position control of the hull position movement control of the marine hydroelectric power plant flood control station (593,594,595) constituting the upper part of the dock of the marine power plant (SDU) Straight configuration of mechanical connection structure Road,

As shown in FIG. 6D, preferably, the nuclear power plant for nuclear power generation has a double structure block tank, a nuclear power plant having nuclear reactor, 811b), a mixed-type pumped-storage power plant that has a natural inflow from the river and pumping only the insufficient water from the lower reservoir, and a silo-type power plant (267) that generates electricity with no natural inflow at all. There are two types of pump. When the pump is pumped, the turbine aberration generates electricity to the motor generator attached to the rotating shaft. In this case, the valve next to the pump aberration should be opened. And a nozzle hole 20 is formed in the turbine 267. The nozzle hole 20 is formed in the turbine 267, (100,000 KW), Cheongpyeong (600,000 KW), Muju (600,000 KW), Sancheong (600,000 KW), and Cheongpyeong (KW)), and Yangyang (1 million KW). In the latter, the latter is a power plant 267, which, unlike the above-mentioned method, The turbine 267, which is the hole 20, maintains the axial thrust balance and the rotational speed of the aberration is adjusted while balancing the pressure of the turbine blades. When the hydrostatic power generator 944 rotates the Francis turbine 943c and the Pelton aberration (943b), electric power is generated by an eco-friendly wind power generator (957), and power is supplied by an electric motor and a search lamp. In the bottom of the sea surface, Using aberration flow due to submergence while diving And the generator (35) is connected to a dam dam on land to generate energy due to the height difference. In the generator in which the power supply of the tidal generator is connected to the search lamp by the power cable, And a double structure block tank dust collector for treating nuclear waste, which is provided with a plurality of water film formations in the gap between the nozzle for preventing forest fire and forest protection and life saving after the valve is opened and fully closed on the lower side of the generator (1) of a nuclear power plant equipped with nuclear power plant (811), the structure of the position control structure of a hull of a marine hydroelectric power plant installed in the upper part (SDU) of a hull deck of a marine power plant body dock The structure of the micro switch 580 and the limit switches 580 and the diaphragm type pressure switch 183, Position 104a and pneumatic-sensor pressure switch 104b Hydraulic power generation facility Equipment for fire-fighting and disaster prevention equipped with connection structure. .

Referring to FIG. 6E, the power generation and production unit 811b of the nuclear power generation facility unit 811 is installed inside the nuclear reactor facility main body 1 of the nuclear power plant having the nuclear reactor waste treatment double structure block tank nuclear reactor for nuclear power generation according to the present invention, (593,594,595) composed of marine hydroelectric power plant on the upper part of the ship's deck (SDU) of the marine power plant Toricelli's theorem showing the regulating structure of the construction machine position control of the hull position movement Hydraulic power plant construction road,

As shown in FIG. 6E, the nuclear power generation nuclear waste treatment dual structure block tank is installed in the reactor main body 1 of a nuclear power plant having a reactor dust collector as a power generation and production section 811b of the nuclear power generation facility section 811 A water pipe 191 from a water tank or a crude water tank to a water turbine inlet of a power plant is generally called a water pressure pipe 191 and a water pipe 191 for supporting the water pipe 191 The hydraulic pipe (191) is called the hydraulic pipe, and the straight line with the shortest possible distance should be used depending on the location of the water tank (680m) and the power plant. Considering the water head, the flow rate in the pipe is set to 3 ~ 5 [m / s]. In addition, the number of hydraulic pipes (191) is one for each aberration, but when the number of high-lifts is small, there may be one for two aberrations.

As shown in FIG. 6E, the nuclear power generation nuclear waste treatment dual structure block tank is installed in the reactor main body 1 of a nuclear power plant having a reactor dust collector as a power generation and production section 811b of the nuclear power generation facility section 811 The pressure due to the water hammer action acts as the internal pressure, so the thickness t [cm] of the pipe must be determined to be sufficiently large enough to withstand the maximum water pressure applied to the pipe, to the diameter D [cm], the maximum pressure P [kg / ㎠], allows the steel material stress (Yes tension) to σ [kg / ㎠], the joint efficiency of tube η [%], free thickness of the corrosion Ε [cm], the tube thickness t [cm] is calculated by the following formula.

다음 수차 이후에는 방수로가 사용된다.

A watertight path is used after the next aberration.

This is a water channel for discharging the water coming out of the aberration to the original river, and the place where this and the main stream of the stream are joined is called the waterproof hole (169).

As shown in FIG. 6E, the nuclear power generation nuclear waste treatment dual structure block tank is installed in the reactor main body 1 of a nuclear power plant having a reactor dust collector as a power generation and production section 811b of the nuclear power generation facility section 811 The structure of the waterproofing canal is almost the same as that of the above-mentioned waterway, but it is necessary to select a place as deep as possible as possible to smooth the flow of the river, and to discharge it in the same direction as the flow of the river.

As described above, the principle of hydroelectric power generation will be described as follows.

Thermal energy from coal, oil, and other underground resources among the energy resources currently on the earth is destined to be depleted in the future and is expected to develop nuclear power in recent years, but water energy is infinite as long as the universe exists I can think.

As shown in FIG. 6E, the nuclear power generation nuclear waste treatment dual structure block tank is installed in the reactor main body 1 of a nuclear power plant having a reactor dust collector as a power generation and production section 811b of the nuclear power generation facility section 811 In Korea, recently, large dams have been constructed and artificial reservoirs have been made to regulate, develop, and irrigate the floods. Water has pressure, position energy, and is held as a form of potential energy in nature many. This position energy can be changed into kinetic energy and pressure energy, or kinetic energy alone, so that it can be converted into mechanical energy.

( P = rHQ kg m m / sec), the generated power of water P kg m m / sec is expressed by H m, the flow rate is Q m 3 / sec, and the specific weight of water is r kg / Therefore, hydraulic power is determined by dropping and flow rate. Falling is usually constant when the status of stream or source is determined, and flow rate is related to watershed and rainfall. The output generated here is proportional to the product of fall depends on the plant's top packaging hydropower is to increase the output of this time to change the artificially leading to concentrate their water in one place, and were it should be selected for the development points to get the big-head now use quantity Q [㎥ / s] falls into the aberration when the effective drop H [m] falls and the power P _o [kW]

( P _o = 9.8 QH [kW]), which is usually called hydrodynamic.

As shown in FIG. 6E, when the theoretical hydraulic power is inputted to the aberration and the aberration and the generator are rotated while the aberration output P _t and the generator output P _g are respectively a η _t and η _g , respectively, ( P _t = 9.8 QHη _t [kW]) ( P _g = 9.8 QH η _t η _g [kW]).

As shown in the figure, as shown in the figure, the nuclear power plant for nuclear power generation has a double structure block tank, a power generating and manufacturing section 811b) of the hydroelectric power plant 943 showing the configuration of the position control mechanism of the construction machine for adjusting the hull position movement of the marine hydroelectric power plant flood control consoles 593, 594, 595 constituting the upper part of the deck of the marine power plant body dock (SDU) Since the facility utilizes flow and dropping, it should always be built so that it can safely take up the flow rate required for power generation and also reduce losses of dropping and flow. Hydropower facilities in hydroelectric power plants can be classified according to their functions. Hydraulic facilities divided into 4 types of water supply facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) (593,594,595) of the hydro-electric power plant, the hydraulic power plant which controls the position of the hull structure of the hydro-power plant, The multistage hydraulic power of the hydroelectric power plant 943 with the water intake facility 680n, the water supply facility 680o, the power generation facility 680p and the waterproof facility 680q, which is equivalent to the arrangement of the multi- Generator 944 devices.

Referring to FIG. 6F, an electronic control regulating device construction machine controller 811f of the nuclear power generation facility 811 is installed in the nuclear reactor main body 1 of a nuclear power plant having a double structural block tank dust collector for nuclear waste disposal according to the present invention. The structure of the micro-switch 580 showing the construction machine position adjustment structure of the hull position movement control of the marine hydro-power station floating pick-up device 593, 594, 595 constituting the upper part of the marine power plant body dock hull deck (SDU) Sensor pressure switch 104b to the micro-switch 183 and the diaphragm-type pressure switch 104a.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The micro switch 580 and the limit switch 183, which detect whether the door is opened or closed or the presence or absence of the workpiece, are required to be in contact with the object, Contact type sensor. The differences between these switches are slightly different in structure and usage. The microswitch 580 is a relatively small, non-sealed structure with a built-in contact mechanism in the molded article case and is mainly used for a measuring device or a detector of a small mechanical device. The limit switch (183) is used for production facilities that require mechanical protection from places where durability is required due to waterproof, rust-proof structure, or external force, and micro-switches with built-in micro switches in a solid die-cast case. Therefore, the limit switch 183 is also referred to as an encapsulated micro switch 580. In this micro switch 580, the micro switch is one type of the limit switch 183, which means that the limit switch 183 is very small. The microswitch 580 is widely used as an important component for operation and control, and is an element that can switch large power despite small shapes.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The microswitch 580 to the electronic control regulating device constituting the microcomputer 580 directly operates with the prescribed force so that the falling speed of the contact repeats switching irrespective of the operating speed. It is also referred to as a precise snap action switch or a sensitive switch because it has high repeatability to faithfully repeat certain operating characteristics, and the switch operates on small forces and movements.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The structure of the microswitch 580 is used as an actuator portion for transmitting an external force to an internal mechanism. Since the micro-switch 580 has a repetition accuracy of about 0.01 to 0.1 mm, it is more accurate. Therefore, the switching frequency of the micro switch for detection is about 60 to 400 switching operations per minute. The life span is about 1 million times, but it depends on the usage environment. The shortcomings of the microswitches are as follows.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, Advantageously, it is capable of opening and closing a small and large-capacity electric power, and it is highly resistant to vibration and shock because it has high repetition accuracy and motion of hysteresis by using a precision snap action mechanism. Therefore, This is because there are some contact bounces or chattering by using metal contacts first. Therefore, compared with solidification devices such as electronic parts, stress concentration type Because of its short lifetime, noise is generated during operation and return, which is often an advantage. In this circuit, the circuit is limited to the opening and closing capabilities, a structurally complete sealing is not so constrained to the use of an explosive atmosphere in the environment model of the lead terminal is a terminal care is desired sex work because it is not completely closed.

      <Microswitch Technical Data Sheet>

6F, since the limit switch 183 is one of the most representative object detection ON / OFF sensors of the mechanical sensor is the limit switch 183 and the micro switch 580, While the action of the electrical contact is changed by the external action, the lifetime of the contact reaches about 10 million times. In addition, since the allowable current of the contact part can be switched to a relatively large power compared to the external appearance, the snap operation mechanism provides a fast switching time in the range of 1 to 15 ms. Therefore, it is necessary to confirm whether the protection structure of the switch is suitable for the environment do.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The contacts of the limit switch 183 and the micro switch 580 have a finite lifetime in the protection circuit of the limit switch 183. [ Particularly, when the power supply which is being supplied to the device using the induction action is cut off, the magnetic field is reduced, and as a result, the pressure corresponding to the power supply voltage a number of times is the amount indicating the magnitude of the force, And the force acting on the normal direction. The state of a substance Among gases, liquids and solids, solids are different from gases and liquids. In solid, there is no flow due to pressure, so the directionality of the force is preserved. In other words, the pressure is directional, and the pressure at one point also varies greatly depending on the direction. In contrast to solids, liquids such as p gases, liquids flow with the bias of force, so the pressure is not directional and the pressure of the same magnitude is applied to the surface in any direction at some point. Therefore, one pressure value is determined for one point. It is called Pascal's name in the name of B. Pascal (1623-1622) who discovered the isotropic nature of this fluid. Pascal Pa (= N · m ^-2 ), which is used as a unit of pressure in SI units, is named after him.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, , The pressure measurement is a key factor in understanding the state of the fluid, along with the temperature, and its power and weight are deduced from its measurement. In the unit for indicating a pressure, but many are being used, the type of the pressure range, it depends on the object to be measured, the calibration means by this absolute pressure sensor an absolute pressure sensor to a reference pressure by a vacuum (p = OP _a) The absolute pressure of the medium is measured. Therefore, the absolute pressure sensor is equipped with a gauge in a vacuum space. This gauge consists of a thin diaphragm which is deformed according to the pressure to be measured. Space forming a vacuum is not able to form an ultimate vacuum of about 0.1P uses _a relative pressure. This corresponds to about a millionth of atmospheric pressure.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The relative pressure sensor by the relative pressure sensor measures the differential pressure based on the atmospheric pressure given by P _amb . Atmospheric pressure is not a constant value but a pressure that varies with topographic and meteorological changes. Since the differential pressure sensor can be divided into a positive pressure sensor and a vacuum sensor for measuring negative pressure, the differential pressure sensor is not so different from the relative pressure sensor in the measurement principle, which measures the differential pressure between two given pressures The diaphragm type pressure switch 104a is determined by the difference in pressure provided to maintain the current state by the repulsive force of the spring and the tension of the spring.

6F, the upper part SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, , The differential pressure switch can be used with the following three functions. Therefore, the pressure switch 104 is used as a pressure switch operated from 0.25 to 8 bar using P ₁ , and the vacuum switch is used as P ₂ is used as a vacuum pressure switch that detects the range of -0.25 to -1 bar. The differential pressure switch uses both P ₁ and P ₂ , and the detection range is adjustable between -1 and 8 bar. The switching differential pressure is regulated by a spring, so that the pressure of P ₁ is at least 0.25 bar higher than the pressure of P ₂ , taking into account the influence of the hysteresis.

As shown in the drawing, as shown in the figure, the inside of the nuclear reactor facility main body 1 of the nuclear power plant is provided with the electronic control regulating apparatus construction machine control unit 811f of the nuclear power generation facility unit 811, The electronic control regulator arrangement in the upper part (SDU) includes a micro-switch, which shows the construction machine position control arrangement of the hull locomotion control of the marine hydroelectric power station levitation stand (593, 594, 595) constituting the marine power plant body dock hull deck upper part (SDU) Sensor pressure switch 104b to the diaphragm type pressure switch 104a and the micro switch 183 and the limit switch 580 to the structure of the hydraulic pressure generating device 580. [

Referring to FIG. 6G, an electronic control unit construction machine control unit 811f of the nuclear power generation facility unit 811 is installed inside a reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. ) Of the marine power plant body dock The hull deck top (SDU) of the marine power plant body dock consists of the upper part of the ship (SDU) (102e) of the thermoelectric generator 102b and the thermoelectric power generator 102c in accordance with the thermocouple construction method 102a of the fire thermoelectric temperature sensor sensor bimetal 102 that shows the construction machine position adjustment configuration of the thermoelectric generator 102c. Thermocouple Thermometer Switch (103) for Detecting Sensing while distinguishing Thermocouple (103)

6G, the upper portion SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control portion 811f of the nuclear power generation facility 811 inside the reactor main body 1 of the nuclear power plant, (593,594,595) of the marine hydroelectric power plant floating structure (DTU) constructed at the upper part of the deck of the ship's dock (SDU) of the marine power plant. A thermocouple thermometer switch 103 for a sensing sensor 103 thermocouples 103a and 103b are provided while dividing a reference point 102e at a measurement point 102d of the thermoelectric generator 102b and the thermoelectric generator 102c according to the thermocouple configuration method 102a of the sensor bimetal 102, And Fig.

6G, the upper portion SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control portion 811f of the nuclear power generation facility 811 inside the reactor main body 1 of the nuclear power plant, In the electronic control regulating apparatus constituting the electronic device, in the fire heat sensor, the temperature indicates the magnitude of the motion or vibration energy possessed by an atom or a molecule, and the energy is heat. That is, temperature is a type of physical state quantity, but it can not be measured directly, but it should be measured by converting it into other physical quantities such as displacement, pressure, resistance, voltage and frequency. Although ordinary materials and electronic devices can be temperature sensors because their electrical characteristics change with temperature, those suitable for the purpose of use are used in terms of detection temperature range, precision, temperature characteristics, reliability, mass productivity, and price have.

As shown in Fig. 6G, measurement of temperature includes contact measurement in which the temperature sensor is in thermal contact with an object to be measured so that the temperature of the temperature sensor is equalized (thermal equilibrium state). In this method, the sensor itself must withstand the measurement object temperature and perform a predetermined operation. On the other hand, there is a non-contact type measurement using a thermal radiation without touching the object with the sensor. The sensor at this time is a visible or infrared radiation detector and is independent of the temperature of the sensor itself and the temperature of the object to be measured.

           <Contact method and non-contact method>

As shown in Fig. 6G, in the configuration of the sensor, the semiconductor temperature sensing element in which the electrical resistance greatly changes in accordance with the temperature change is called a thermistor. Especially, it is used as a thermistor temperature sensor that is stable against temperature and has good reproducibility of temperature characteristics. Most of the thermistors that are used are ceramic thermistors, classified by their basic characteristics. They are NTC (negative temperature coefficient) thermistors with a negative temperature coefficient whose electrical resistance decreases exponentially as the temperature rises. Conversely, A positive temperature coefficient (PTC) thermistor with a significantly increased resistance and a positive temperature coefficient as a whole, or a critical temperature resistor (CTR) with the same characteristics as the NTC but with a sudden decrease in electrical resistance in any temperature economy, . When it is simply called a thermistor, it often refers to an NTC thermistor. PTC, CTR can not be used as a temperature sensor in a wide temperature range, but it is convenient to detect whether or not the temperature exceeds a specific temperature (a temperature at which the resistance rapidly changes).

For example, when a current is supplied to the PTC, it is heated. When the temperature exceeds the rapid temperature, the resistance is increased, so the current is reduced and the heat is not generated. Therefore, it is attached to the electronic thermo-cooker to keep the internal temperature constant or attach to the drier or drier The switch can be operated.

As shown in Fig. 6G, in the case of an NTC thermistor, a thermistor whose electrical resistance continuously changes with a negative temperature coefficient is sometimes abbreviated as NTC. At present, thermistor constant is about 2000 ~ 5000K, temperature range is about 300 ℃, and thermistor is originally sintered at 100 ℃ or more. . But it does not change permanently, as all materials have aging. In the following figure, the relative value when the stability at 100 ° C is 1 is shown, and it can be seen that the stability becomes lower as the temperature becomes higher. This depends on the material and sintering conditions of the thermistor, but when used at a low temperature of about 100 ° C, the change due to this cause can be ignored. If there is a change in the low temperature, it is considered that moisture or solvent penetrated by the damage of the external shape.

As shown in FIG. 6G, the PTC thermistor is used as a current limiting element (fuse function element), a constant-temperature heat generating element, and a temperature sensor of an electric appliance because the structure of the PTC thermistor is simple have. That is, the characteristic that a large current is initially blurred and then decreases and is suppressed by a minute current is used for a self-erasing, reliable motor for a color TV which requires a high heating current or a circuit for preventing an excessive current, There are starterless switches. If the voltage applied to the device exceeds a certain value at the time of use, the current increases as the voltage increases and eventually breakdown occurs. Therefore, consideration should be given to the breakdown voltage and a safety margin for the rated operating voltage should be established.

6G, the upper portion SDU of the body of the marine power plant body, which is provided as the electronic control regulating device construction machine control portion 811f of the nuclear power generation facility 811 inside the reactor main body 1 of the nuclear power plant, , The classification of the thermocouple shall include the type symbol, the grade of the tolerance, the wire diameter of the wire, the length of the outer diameter of the protective pipe (if there is a protective pipe), the material of the protective pipe, the name (if there is a protective pipe, Thermocouple).

Example ●: K class 1 1.00mm thermocouple

Example ●: J class 2 thermocouple with 0.05mm 6 550mm magnetic protection tube

In the type of thermocouple (103n), the wire constituting the thermocouple is in contact with the high temperature, and the following conditions must be satisfied.

First, the heat will be great.

Secondly, the dispersion of the temperature-thermo-electric characteristic is small,

Third, the thermal power characteristics should be continuous and linear.

The fourth should be stable thermally, chemically, and mechanically.

In addition,

Finally, it is easy to process and the price is low.

It is widely used thermocouple and it is standardized as 7 kinds of B, R, S, K, E, J and T according to the constituent materials. The table below shows the operating temperature range and characteristics of the thermocouple configuration.

The thermocouple bimetallic bimetal 102 thermocouple configuration method 102a is composed of a change of the measurement point 102d and the reference point 102e with the generation of the heat current 102b and the generation of the thermoelectric power 102c .

Fluorescent lamps have a light bulb in it, so do not throw it away when you replace it, you can easily see that the U-shape is slightly stretched when you close the bulb glass and close the match fire. When the match fire is turned off, it is restored to its original state.

This is because a metal with a large thermal expansion and a small metal are bonded to each other and the thermal expansion is bent to a smaller side. This is called bimetal.

Electric rice cookers, electric irons, gas cookers, gas water heaters, and thermostats of refrigerators all use these things.

        <Thermocouple temperature range and characteristics>

As shown in Fig. 6G, the thermocouple can be selected as needed according to the use of the temperature-sensitive contact 103u and the protective pipe 103p for protecting the element wire from direct contact with the object, atmosphere or the like.

As shown in FIG. 6G, it can be measured when the temperature of the surface of the object is relatively low in the absence of the protective tube 103o. In the presence of the protective tube 103r, the protective tube 103p is used. However, in industrial use, it is used in a protective pipe for purposes such as mechanical strength, heat resistance and corrosion resistance. The thermocouple with the protective pipe 103p is composed of a temperature-side terminal 103t, a protective pipe, and a thermocouple wire. Protection tubes include metal protection tubes using stainless steel sheaths (103v) and non-metallic protection tubes such as aluminum foil. In addition, insert a thermocouple wire into a metal tube (metal sheath) such as a cistern (103s) for use in a place with a high temperature or a bad environment, tightly fill the insulator around the thermocouple wire, There is a cistern that prevents corrosion and deterioration by inserting insulation and keeping the wire wire in an airtight state. This is faster than thermocouples with protective tubes, has excellent heat resistance and vibration resistance, and can bend to a certain degree. The external dimension is about 0.2 to 8 mm and can be soldered to the object to be measured.

As shown in Fig. 6G, in the compensating wire 1031, it is ideal to directly connect the thermocouple to the instrument in order to measure the use temperature of the thermocouple. However, if the distance between the measurement point and the instrument is long, The price will increase. Therefore, a conductor having the same or similar characteristics as the thermocouple is used. This conductor is referred to as a compensating conductor 103l. The compensating wire 103l has almost the same thermoelectric characteristics as the thermocouple used in combination in a considerable temperature range including room temperature and is connected between the thermocouple and the reference contact 103m by this, 103m) is compensated by using a pair of conductors to be insulated. The connection of the thermocouple and the compensating wire is to be connected to the plus side of the thermocouple at the plus side of the compensating cable 103l and the minus angle of the thermocouple at the minus side of the compensating cable 103l.

As shown in Fig. 6G, the thermocouple thermometer system 103a is provided with a potentiometer 103d for the amperemeter temperature, a metal A 103e, and a metal B 103f at the temperature limits 103b and 103c, Is generated 103g and is provided as thermocouples 103j and 103k in the thermocouple 103d and the thermocouple contact 103i and as the reference contacts 103m in the compensating wire 103l.

As shown in FIG. 6G, the thermocouple is electrically connected to one end of two types of conductors for the purpose of generating thermoelectric power, and the thermocouple wire is connected to a metal wire or alloy wire serving as both ends of the thermocouple. The contact point shall be such that it is maintained at a constant temperature (eg freezing point) at the junction of the thermocouple, conductor, compensating wire (103h) and conductor. 103p must be a tube which is attached to the temperature-side contact 103i or the wire so as not to come into direct contact with the object to be heated, atmosphere, etc. Therefore, the compensating wire 103h is almost the same as the thermocouple used in combination at a considerable temperature range including room temperature As a pair of conductors that have a thermoelectric power characteristic and are used to compensate the temperature difference between the connecting portion of the thermocouple and the reference contact, When the reference contact point 103m is 0, the power should be determined to be a predetermined thermal power that generates a virtual thermocouple (reference thermocouple) corresponding to the temperature of the temperature-measuring contact point.

Therefore, the RTD 103w is widely used together with a thermocouple or a thermistor among the contact-type temperature sensors. Among them, the platinum RTD 103w is most stable and has a wide temperature range and is widely used for temperature measurement requiring high accuracy. In general, metals have a so-called positive temperature coefficient, in which the electrical resistance increases in proportion to the temperature, and the higher the purity of the metal, the larger the temperature coefficient. The temperature resistance (103w) is made of pure metals such as platinum, nickel, and copper. Widely used in standard thermometers and industrial measurement is a high purity (99.999% or more) platinum wire. As shown in the following table.

Figure 2-25 (a) shows the temperature change of the metal resistance when the resistance at 0 ℃ is 1. That is, since the resistance of platinum is 100.0? At 0 占 폚 and 139.16? At 100 占 폚, the temperature coefficient of resistance of platinum is 0.39% / 占 폚. Since the resistivity of pure metal is very small, it has a structure that uses a thin and long metal wire to increase the resistance value, and protects mechanically and chemically using a protective pipe 103p.

As shown in Fig. 6G, the platinum wire 103y is wound around the mica 103x and covered with the protective pipe 103p.

First, platinum resistance thermometer (103w) is most stable among practical sensors, widely used in temperature measurement where temperature range is high and high accuracy is required. The disadvantage is that the structure of the resistance element is complicated, the shape is large, the response is slow, and it is vulnerable to mechanical shock or vibration.

Secondly, in the copper temperature-measuring resistor 103w

It is a stable device with high purity, low cost and low dispersion of temperature characteristics after platinum. However, copper has a small resistivity, large shape, easy to oxidize at high temperature, and a narrow temperature range.

Thirdly, in the nickel resistance device 103w

Although it is cheaper than platinum and has a large resistance value, the inflection point of the temperature coefficient is found around 340 ° C. Also, the temperature resistance characteristics due to impurities are dispersed and it is difficult to obtain a compatible nickel wire.

Fourth, platinum-cobalt RTD (103w) contains 0.5% cobalt in a trace amount. The resistance value and resistance temperature coefficient for cryogenic temperature are larger than platinum, and the types and characteristics of RTDs are described as below.

As described above, in the nuclear power plant's nuclear reactor facility main body 1, it is arranged in the upper part SDU of the marine power plant body dock hull deck, which is provided as the electronic control regulator construction machine control part 811f of the nuclear power generation facility part 811 The electronic control regulating installation includes a thermal heat sensor according to the thermocouple construction method 102a of the fire heat temperature sensor detection sensor bimetal 102 which shows the construction machine position control arrangement of the marine hydroelectric power plant flood control 593,594,595, The thermocouple thermometer switch 103 for the sensing sensor is separated from the measurement point 102d of the generation 102b and the thermoelectric power generation 102c while the reference point 102e is separated from the thermocouple 103c. The marine power generation provided to the inside of the nuclear reactor facility main body 1 of the nuclear power plant as the electronic control regulating device construction machine control section 811f of the nuclear power generation facility section 811 with the magnetism 103z connection structures to the platinum line 103y, Electronic regulating control equipment that make up the body dock deck upper hull (SDU) is preferably configured in a marine power plant body dock deck upper hull (SDU).

Referring to FIG. 6H, an electronic control unit construction machine control unit 811f of the nuclear power generation facility unit 811 is installed inside the reactor facility body 1 of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to the present invention. ) Of the marine power plant body dock The hull deck top (SDU) of the marine power plant body dock consists of the upper part of the ship (SDU) A partial side view showing a partial side view of the relief valve 474 in the vane pump 142 and a plurality of gear pumps 326 showing the construction machine position adjustment arrangement of the vane pump 142,

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, The gear pump 326 of the gear pump 326 at a delivery pressure of 35 to 175 kgf / cm ² and a capacity of 5 to 300 L / min is currently produced and marketed have. Gear pumps are widely used because they are simple in structure, high in reliability, easy to operate and maintain, and relatively inexpensive. The gear pump (motor) is divided into an external gear pump and an internal gear pump. External gear pumps can be classified as spur, helical and helical thermal pump depending on the type of gear used.

As shown in the drawing, the detailed description of the external gear pump 326a

Figure 2-27 shows an example of an external gear pump.

As shown in Fig. 6H, the gear pump is characterized by a pair of gears, a gear case incorporating the gears, four shaft bearings, a gear side plate, and the like, and the number of parts is smaller than that of other pumps. Unlike reciprocating pumps with oval valves, high speed operation is possible, and the gear type and gear type are appropriately selected, even if the viscosity of the used oil is high, because the gear pump does not require a valve at the entrance. The pump efficiency of about 70 to 80% can be easily obtained without the same obstacle. The gear pump causes a pumping action when the drive gear rotates and rotates while driving the variable gear. When the gears mesh with each other, the contact between the two gears is line contact, thus blocking the inlet side (low pressure) and the outlet side (high pressure). When the teeth of the gear are separated from each other at the inlet side, the volume of the suction chamber is increased by the volume occupied by one tooth, so that the hydraulic oil is sucked up by a slight vacuum. The sucked hydraulic oil is pinched between the gear teeth and the outer periphery of the casing and is sent to the discharge chamber. When the teeth are engaged with each other in the delivery chamber, the delivery chamber volume is reduced by the displacement amount when the teeth are engaged with each other, and hydraulic oil is extruded from the delivery chamber to the delivery port.

On the other hand, the internal gear pump 326b will be described as follows.

As shown in FIG. 6h, the internal gear pump operates similarly to the external gear pump. The internal gear pump consists of an external gear rotating around the center of the pump as shown in Figure 2-28, an internal gear eccentric from the center of the pump and a crescern-shaped spacer rotating in contact with the outer gear . When the inner gear is turned to be the drive gear and the outer gear is rotated, the hydraulic oil enclosed between the inner and outer gear teeth and the spacer surfaces is transferred from the suction chamber to the discharge chamber together with the rotation of the gear. In the figure, the intake port (269) and the discharge port (270) are drawn as if they are directly pierced on the outer periphery of the casing. However, the inlet and outlet of the actual internal gear pump are halfway between the inner contact and the spacer end, It is cut into a long shape and pierced on the end plate of the pump. When the inner gear is engaged with the outer gear and the outer gear is driven, the discharge chamber (high pressure chamber) and the suction chamber (low pressure chamber) are interrupted at the inner contact point and the inner and outer gears are separated from each other in the suction chamber. As a result, the pressure in the suction chamber becomes vacuum and sucks hydraulic oil. The sucked hydraulic oil is sandwiched between both sides of the spacer and the valley portions of the inner and outer gears, and is transferred to the delivery chamber. In the delivery chamber, as the gear rotates, teeth of the inner and outer gears mesh with each other, and the volume of the tapered portion gradually decreases, so that the hydraulic oil is transported to the delivery port 270. When the internal gear pump is worn out, the efficiency of the internal gear pump is lowered rapidly.

As shown in Fig. 6H, the gear pump is advantageous in that it is compact, lightweight and inexpensive, and can withstand severe operating conditions (dust contamination, rise in oil temperature, overload) The limit of oil temperature is up to about 65 ℃ when used in machine tools, but it is used up to about 80 ℃ in construction machines and about 100 ℃ in a short time. The viscosity of suitable oil is 30-80 cst.

For a gear pump with a standard involute tooth profile,

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, The basic components constituting the vane pump are an intake port, a delivery port, a drive circuit electron, a vane, a cam ring and a casing. The vane flows through the groove in the rotor and changes the enclosed space surrounded by the vanes and the rotor of the cam ring according to the shape of the cam ring. As the airtight space increases, it is sucked in the intake port, and the airtight space is reduced again while passing through the turning point in accordance with the rotation of the rotor. The delivery pressure of the first stage as a general industrial 70kg _{f /} cm ^{2, 2} dan 140kg _{f /} cm ^2, the capacity 4ℓ / min~280ℓ / min vane pump is usually commercially produced. In recent years it has been the advent of single-stage pump ^{_{150kg f / cm 2 ~140kg f /}} cm 2 as a high-speed high-pressure.

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, , The vane pump is classified into fixed capacity, variable capacity type and pressure balance type and complaint type. The vane pump currently being manufactured has the following form.

First, a balanced vane pump 142a, a second unbalanced vane pump 142b, a third constant capacity vane pump 142a, and a fourth variable capacity vane pump 142b, The vane pump is a case where the axial load received by the pump shaft is dynamically balanced or unbalanced. The distinction between a constant capacity pump and a variable capacity pump is a function of changing the discharge amount during operation. Therefore, kinematically, the balanced vane pump corresponds to a constant capacity pump and the unbalanced vane pump corresponds to a variable capacity pump.

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, In the electronically controlled regulating device constituted in the first and second stages of the vane pump other than the vane pump, two single-stage vane pumps are connected in series, and one-stage pump discharge oil is supplied to the second- It generates double pressure, but there is no change in flow rate. This pump uses two vane pumps so that the load distribution valves are used to distribute the loads at the same rate at each end.

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, The following two pumps are connected to two large-sized and medium-sized or medium-sized and small-sized pumps in parallel in one body and are rotated by a single drive shaft to obtain two hydraulic pressure sources It is used when you want.

In the complex pump, two or more pumps are driven on the same axis and the valves necessary for circuit such as relief valve, no-load valve and check valve are installed,

Theoretical discharge rate of vane pump

Unbalanced ( Q = 2 πDeWn ) (2.12)

Equilibrium type < Q = 4 πDeWn = 4 eWn ( πD -bz )>

Where b is the thickness of the vane, D is the diameter of the cam ring, e is the eccentricity, z is the number of vanes, and W is the width of the vane.

On the other hand,

First, the advantages of a vane pump

First, the vane pump has less pulsation pressure than other pumps.

Second, it is smaller than the driving power of the pump.

Third, the pressure drop does not occur even when the tip of the vane is worn.

Finally, relatively few faults and easy maintenance.

Also: In the disadvantage of the vane pump

First, the vane, the rotor, and the cam ring are in contact with each other, so that the degree of work must be set, and it is necessary to select high quality materials.

Second, it requires careful attention to the viscosity and cleanliness of the oil.

The number of parts is large.

In the fire fighting and disinfection system of a reactor plant in a nuclear power plant, hydraulic energy is transferred from the pump to the actuator along the piping. Proper hydraulic components are needed to control the system to meet the requirements for power, torque, speed, direction, etc. These are the valves.

These valves are largely divided into function, pressure control valve, direction control valve, and flow control valve. By combining these valves according to their functions, hydraulic systems with various characteristics can be constructed. Therefore, the hydraulic control valve is the most diverse and main component of the hydraulic system.

These pressure control valves can be classified as follows according to the purpose of use and structure.

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, The relief valve 474 in the electronic control regulating device that constitutes the valve is a valve that constantly maintains the pressure of the circuit as a valve that limits the maximum pressure of the circuit. The control pressure is sensed at the inlet P port of the valve. This valve is necessary in the hydraulic circuit and is a safety valve that prevents the circuit from being damaged by overload.

First, a direct-acting relief valve 474a is shown in the direct-acting relief valve 474a. The poppet is pressed against the valve seat by the spring, and the spring can be adjusted using the handle, so that the relief setting pressure is adjusted. When the differential pressure is smaller than the spring force, the valve is closed while the pressure oil is blocked. When the differential pressure becomes larger than the spring force, the pressurized oil pushes the poppet and flows into the tank. The pressure at which the oil starts flowing into the tank is called cracking pressure, and the pressure when the valve is fully opened and the discharge amount of the hydraulic pump is all sent to the oil tank is referred to as the pressure at the time of full flow, and this is the set pressure of the relief valve.

Also, the difference between pressure and cracking pressure at full flow rate is called pressure override, and direct type relief valve has a large pressure override. In the figure, when the pressure of the P port is close to the set pressure, the poppet lifts to the right and a gap is created between the valve seat and the poppet. The oil is discharged to the tank through this gap. At this time, since the pressure energy of the oil in the circuit is changed into the velocity energy, the poppet is not opened or the pressure drop suddenly occurs and the sheet surface is hit hard. Such a phenomenon of repeated operation is referred to as chattering, which causes severe noise and damages the valve seat.

6H, the upper part SDU of the body of the marine power plant dock, which is provided as the electronic control regulating device construction machine control part 811f of the nuclear power generation facility 811 inside the reactor facility main body 1 of the nuclear power plant, The balanced piston type relief valve 474b is provided with

Although the structure is more complicated than the direct-acting type, the function of the relief valve is assured and the chattering phenomenon can be prevented, which is widely used in general industrial machines. The balanced piston type relief valve consists of a capacity control section consisting of a main valve and a spring for escaping excess oil in the circuit, and a pilot section for controlling the operation of the main valve and regulating the pressure.

Meanwhile, in the pressure reducing valve 460, the pressure reducing valve 460 is a valve that controls the secondary pressure by lowering the branch circuit pressure to the main circuit pressure, and is a secondary pressure constant type And a differential pressure constant type 460b for reducing the pressure on the outlet side at a predetermined ratio with respect to the pressure on the inlet side.

First, in the secondary pressure constant pressure reducing valve 460a, the structure of the secondary pressure constant pressure reducing valve is shown in Fig. 3-4. Below the set pressure, the poppet valve is closed, and the pressure at both ends of the spring is the same. The spring is pushed downward by the action of the main spring, and the whole flow of the pump is discharged without resistance of the inlet pressure . When the pressure at the outlet becomes higher than the set pressure, the poppet valve opens and the pressure oil flows out to the drain line. At this time, both ends of the spring generate pressure difference due to the flow rate through the choke, and the spool moves upward to reduce the opening of the flow path of the outlet, thereby controlling the outlet pressure to be the set pressure.

The following figure shows the structure of pressure differential pressure regulator (pressure compensating type) in the pressure differential constant pressure regulator (460b). If the force of the fluid is ignored, the balance of the force acting on the valve becomes p ₂ × A = p ₃ × A + spring force and the difference of p ₂ - p ₃ is kept constant.

An electronic control adjusting device 811f of the nuclear power generation facility 811 of the nuclear reactor main body 1 of the nuclear power plant and an electronic control adjusting device 811f of the nuclear power plant main body dock hull deck upper part (SDU) The sequence valve or the auto pressure control valve 469 will be described as follows.

In an oil pressure circuit having two or more branch circuits, the operation order is an otovalue which regulates the operation by the pressure of the circuit or the motion of the hydraulic cylinder.

This kind of valve is a direct acting type pressure control valve as shown in Figure 3-6, and the flow path between the primary side and the secondary side is closed by the adjustment spring. The pilot pressure is directed downward through the passage of the lower cover and pushes the spool upwards.

When this force becomes larger than the spring force, the flow path opens. The valve has the function shown in the figure according to the combination of the upper cover and the lower cover. In addition, there is a check valve built in to allow backflow from the secondary side to the primary side, and it is used as a sequence valve, a counter balance valve, a brake valve, and the like.

The other counterbalance valves described above are described as follows

For a flow in one direction, a set back pressure is given, while a flow in the opposite direction is a free-flowing valve.

The directional control valve is used to control the flow direction of the hydraulic oil to control the flow direction of the hydraulic oil and to start, accelerate, decelerate, stop and maintain the current state of the cylinder or hydraulic motor. Valve.

This direction change valve will be explained as below.

The directional control valve is classified into a poppet type in which balls or pistons are attached to or separated from a sheet, a rotary spool type in which the spool is rotated around the shaft, and a direct spool type in which the spool is moved in the axial direction , Manual operation spring return type, push button operation spring return type, hand lever operation type, hand lever operation position fixing type, and pedal operation spring return type can be classified according to the operation method. In addition, the directional control valve is represented by several connected squares, indicating the state of the flow path in the valve, the number of the conversion positions, the number of the connection ports, the operation method, and the like at the neutral position.

First, the 2/2-way valve

The 2/2-way valve is used to open and shut off the pressure flow. That is, whether it flows into the P port or not depends on the position of the spool according to the operation lever.

The following are for 3/2-way valves

The 3/2-way valve is used for direction control to open the pressure flow in one direction and shut off in the other direction. This valve is designed so that when the spool is in the neutral position,

block and it is open from A port to T port. When an external force is applied to the lever, the spool is returned to the neutral position by the spring when the P port and the A port are connected and the external force acting on the lever is removed.

And for 4/2-way valves.

The 4/2-way valve is used to control the bidirectional flow of pressure. This valve is connected to P → B and A → T from the normal position. When operation force is applied, the pressure flows from P → A to B → T. It is used for clamping, unclamping, forward and backward movement of double acting cylinder.

The following 4/3-way valves are described as follows.

Spool wool is in neutral position, P port is completely disconnected from all ports, all ports are connected, and P port and T port are connected, and only A port and B port are connected.

An electronic control adjusting device 811f of the nuclear power generation facility 811 of the nuclear reactor main body 1 of the nuclear power plant and an electronic control adjusting device 811f of the nuclear power plant main body dock hull deck upper part (SDU) In the check valve 451, the valve 451 limits the flow of pressure oil to only one direction, and is a valve for suppressing the flow in the opposite direction. It is operated by the pressure of the hydraulic oil in the hydraulic circuit and secures the flow path in only one direction. By preventing backflow, movement of the actuator is ensured. There are an in-line check valve 451a and an angle check valve 451b.

The operation and characteristics of the flow control valve will be described below.

By changing the flow rate of the pressure oil, the moving speed of the hydraulic motor or the hydraulic cylinder can be changed. It is the flow control valve that controls the flow rate. In other words, the flow control valve can be said to control the speed of the hydraulic motor or cylinder. First, the channel of the model shown in Fig. 3-16 is called a chock, and the channel shown in Fig. 3-17 is called an orifice.

The orifice is to adjust the flow rate by changing the cross-sectional area of the flow path, and the flow rate of the choke is controlled by the long and thin flow path, which is longer than the cross-sectional area.

However, even if it is a telescopic mechanism, it is strictly choked or orifice. In other words, as the area (flow rate) increases, the orifice decreases, while when the area (flow rate) decreases, the choke becomes. Although the method of controlling the flow rate is different in this way, the orifice side is not influenced by the viscosity (temperature) of the oil and the choke side is influenced by the viscosity. Therefore, there are two kinds of flow control valve. One of them is a throttle valve that only tightens the flow rate. However, this simple throttle valve can not cope with a change in pressure or a change in viscosity. Therefore, pressure-compensated flow control valves and temperature-compensated flow control valves appear.

The above-described pressure compensating flow control valve will be described as follows.

The flow rate through the throttle passage of a constant cross-sectional area changes in accordance with the pressure difference before and after the throttle. That is, the change of the pressure changes the flow rate of the actuator without changing the degree of opening and closing of the valve. These points are problematic in hydraulic circuits where load and pressure fluctuations are frequent. In order to solve this fundamental problem, it is necessary to always flow a constant flow rate, and a pressure compensating device is required to keep the pressure difference before and after the throttle.

In order to keep the flow rate constant, a valve equipped with a mechanism for maintaining the pressure before and after the throttle is called a flow control valve. This type of flow control valve automatically adjusts the size of the orifice as the system pressure changes. This is possible by the use of a spring action pressure compensated spool which reduces the size of the orifice when the upstream pressure increases relative to the downstream pressure. Once the valve is installed, the pressure drop of the valve is maintained at a constant value, and the flow rate can be kept constant since the valve is almost constant.

Figure 3-18 above shows a cross section of a pressure compensated flow control valve. The valve basically consists of a main spool and a pressure compensation spool, and the adjustment knob adjusts the size of the outlet orifice by adjusting the position of the main spool. The upstream pressure of the main spool acts on the left side of the pressure compensation spool through pilot line A. The downstream pressure of the main spool acts on the right side of the pressure compensation spool through pilot line B. If the upstream pressure of the main spool is relatively too high relative to the downstream pressure (i.e., the pressure drop is too large), the pressure compensation spool will move to the right against the force of the spring, Keep the pressure drop constant to keep the flow rate almost constant.

On the other hand, the temperature compensated flow control valve is described as below.

As the temperature of the hydraulic oil increases, the viscosity decreases. Therefore, the temperature change of the hydraulic oil causes a change in the flow rate through the flow control valve. Hydraulic fluid with low viscosity can easily flow through the orifice than with viscous hydraulic fluid, so the temperature rise of the hydraulic fluid increases the flow rate of the selected flow control valve. Therefore, there is a flow rate control valve with temperature compensation that employs a mechanism that minimizes the occurrence of flow rate fluctuations due to temperature changes.

The temperature compensated flow control valve incorporates a temperature sensing element whose orifice size is proportional to the temperature rise. Figure 3-19 is a representation of a pressure-temperature compensated flow control valve with a check valve.

The following high-performance submersible pump 36 is selected in accordance with the specifications of the person skilled in the art and is equipped with a safety hook 13 on the handle and a wire rope 19 on the hook 18 for use as an anti- (28) type with the design of flange according to the specification of flange size in the delivery port (discharge port, 270) as shown in the table below and the following figure.

An electronic control adjusting device 811f of the nuclear power generation facility 811 of the nuclear reactor main body 1 of the nuclear power plant and an electronic control adjusting device 811f of the nuclear power plant main body dock hull deck upper part (SDU) The special features are the high power with the high torque, the light weight and the overheating prevention are provided by the separate design, but the tunnel is being constructed in civil engineering and construction work or the subway construction and the sewer construction .

Here, in the detailed description of the fire sensor pump device, fire fighting and disinfection systems for early fire and lifesaving of a large fire include a water supply valve (495) for a tap water supply pipe (14) 533), the middle elbow connection joint portion should be constructed as a fire water control valve as a valve of the flow meter 105 for checking the fire water quality after attaching the elbow 44 with the elbow socket bushing screw, The water supply piping 14 is connected to the hole hose 9 for detecting the fire detection sensor by means of the nozzle hose and the paraffin 100 is inserted into the hose 9. [ And the water supply pressure corresponding to the water pressure inside the hose is also capable of preventing the fire. The air for supplying the gas and the non-combustible gas 164 are also supplied A fire hose nozzle for a paraffin stop is disposed forward to suppress the ignition of the flame 235 and the flame 236 while at the same time detecting the initial ignition point, (1) of the atomic power plant (8) to the inside of the reactor main body (1) of the nuclear power plant, And an electronic control unit provided at an upper portion SDU of the body of the marine power plant provided with the unit 811f.

Referring to FIG. 6I, a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is installed inside a reactor facility main body 1, and is connected to a traffic conveying unit 811c of a construction machine of a nuclear power generation facility unit 811 Dock of a marine power plant Dock A ditch dam dam showing the configuration of the dam operation of a flood control facility showing the construction arrangement of the construction machine of the marine hydroelectric power plant flood control station (593,594,595) on the upper deck (SDU) (680), which is a step of constructing a distribution input device of a hydrological regulation device of a first regulated shaft lifting control dam provided with a hydrological control regulating part of a plurality of floating relief dams at an upper end position of a hydrant (293) (293) at the top of the floodgate.

As shown in FIG. 6I, at the upper end portion of the water gate 293 of the riverbed hump dam 680, a plurality of floats among the plurality of floats among the plurality of floats are located on the first floodplain hull deck upper part (SDU) (SDU) at the top of the hull deck (SDU), which is located in the river, to control the movement of the moving ship located at the deck. 680) so that the crane (861) inside the floodplain compartment can carry out ship movement control at the position of the upper part of the deck of the ship (SDU) in order to pass freely without collision with the car on the ground surface. (933) and the second lifting docking port (SDU) at the top of the ship deck (SDU). (811c) of the nuclear power plant (811) inside the reactor main body (1) of the nuclear power plant.

The following is used for the engine type rock drilling machine (847) facility, it is used as a rock drilling machine when the concrete structure is easily opened by the engine type at the site of collapse of various concrete structure. When the concrete structure is crushed, the bit of the novy, It is an equipment type that can be used for Breka. It has two engines in one cylinder of 75cc engine type. Its capacity is 1.1L, its weight is 15Kg, its power source is volatile, oil is 12: 1 and its striking power is 14.3J And the crushing capability is 2.200 / min. However, it is preferable to use a compressor type reciprocating stone type. However, it is preferable that several striking bits 940 are formed on the body of the rock drilling machine 847 in the construction.

A striking bit is formed in the jack body feature.

1) Maximum working diameter: ¢ 51mm

2) Working depth: 2.54m

3) Adjustable rotation speed

4) Underwater blasting operation, Noiseless vibration free operation

In the specification,

1) Steel type: 41/4 "× 1" hex

2) Number of rotations: 0 to 300 RPM

3) Weight: 30kg

4) Length: 66cm

5) Width: 46cm

6) Pressure: 105-140 bar

7) Flow rate: 26-34 LPM

Referring to FIG. 6J, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is connected to a transportation transport section 811c of the construction machine of the nuclear power generation facility section 811, Dock of a marine power plant Dock A ditch dam dam showing the configuration of the dam operation of a flood control facility showing the construction arrangement of the construction machine of the marine hydroelectric power plant flood control station (593,594,595) on the upper deck (SDU) (680), which is a step of constructing a distribution input device of a hydrological regulation device of a first regulated shaft lifting control dam provided with a hydrological control regulating part of a plurality of floating relief dams at an upper end position of a hydrant (293) (293) at the top of the floodgate,

6J, the upper part SDU of the body of the marine power plant body, which is provided as the transportation transport part 811c of the construction machine of the nuclear power generation facility 811, inside the reactor facility main body 1 of the nuclear power plant, The position of the top of the water gate (293) of the riverbed dam (680), which shows the construction machine position control arrangement of the marine hydroelectric plant floodplain (593,594,595) constituting the marine hydroelectric plant, Docking dock Docking deck (SDU) Docking station located at the dock and the second docking dock located in the river Docking deck (SDU) The first docking station and the second docking station, Floating docking dock Upper part of the riverbed dam (680) as a hull deck upper part (SDU) mooring platform A floating cargo port The first and second lifting docking docks of the crane units 861 and 862 secure the safe operation of the car and the ship 933 of the underpass dam, It is preferable that the system is composed of the dispensing and inputting apparatuses provided as the transportation unit 811c of the construction machine of the nuclear power plant 811 equipped with the ship transit control silent inflow and extinguishing water film device as the ship upper deck (SDU)

Referring to FIG. 6K, the nuclear waste disposal system for nuclear waste according to the present invention includes a double structure block tank dust collector, Dock of a marine power plant Dock A ditch dam dam showing the configuration of the dam operation of a flood control facility showing the construction arrangement of the construction machine of the marine hydroelectric power plant flood control station (593,594,595) on the upper deck (SDU) (680), which is a step of constructing a distribution input device of a hydrological regulation device of a first regulated shaft lifting control dam provided with a hydrological control regulating part of a plurality of floating relief dams at an upper end position of a hydrant (293) (293) at the top of the floodgate,

As shown in FIG. 6K, at the upper end portion of the water gate 293 of the riverbed dam 680, a plurality of floats among the plurality of floats among the plurality of floats are connected to the first float dock top deck (SDU) (SDU), which is located on the upper part of the hull deck (SDU), which is located in the river, and a second lifting console, The upper and lower portions of the riverbed dam 680 can be freely moved without colliding with cars on the road surface. The cranes 861 in the lifting compartment are provided with an overhang dam capable of controlling the movement of the ship at the upper portion SDU of the ship hull deck (933), and the second floating docking dock of the ship's hull deck upper part (SDU) And a distributing and inputting apparatus constituting a transportation transportation unit 811c of the construction machine of the nuclear power generation facility unit 811 equipped with the teeth.

Referring to FIG. 61, a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention is provided with power for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the reactor main body 1 (811d) of the marine power plant, each of the fire types of which will evolve in less than one second, and the buildings, buildings, elevators, and elevators of each building. Disclosure of Dispensing Dispenser Disclosed and Discharged from Hydroelectric Power Plant Discharge Discharge Apparatus Showing Structural Example Illustrating Disaster Prevention Apparatus Definite Sectional Configuration Road,

As shown in FIG. 61, a power transmission unit (not shown) for transmitting disaster prevention preventive control power to the nuclear reactor facility unit 811 into the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment, The flushing water 7 having the flushing control step 811d is formed in the form of 490 circular ejection nozzles 38 and the curtain water film 39 to form the roof of the elevator machine room In the correction pump and the fire fighting equipment installation position, eight water curtain water films 39 distribute the body load of the fire cable car 256 by the buoyancy of the ad-hoc balloon 77 and the airship 78 to extend the life of the facility, (10), the flue gas mixture for controlling the flow of water to the connection structure of the cable car can be controlled by the pipe nozzle (10), so that the global fire and the large fire inside and outside the building An elevator and a firefighting cable car 256 that provide rapid movement to the equipment in which the flood control process is formed inside the nuclear reactor main body 1 of the nuclear power plant according to the movement of the fluid so as to achieve the forest fire evolution within 1 second A plurality of pumps are attached to the fire sensor pump, and at the same time, the tongue winch 137 for the water gate opening / closing control device is supplied with air supplied from the air compressor 80 to develop the air shutoff valve, And a tongue winch 137 for a hydrant opening and closing control device for providing a simultaneous operation is provided in a rooftop firefighting cabin 394 and at the same time a drive wheel roller 135 is mounted on a steel tower 116 of a plurality of mountains 395, While the tackle winch 137 for the gate opening and closing control device of the rooftop fire fighting operation cabin 394 is controlled by the vibration control device 396 and the speed control device 397 And a disk braking device 399 serving as a brake is provided while winding the gears and the wire rope of the electric motor rotation transmission 398. At the same time, the oil pressure cylinder 396, the air pressure cylinder 396, And a power transmission unit 811d for transmitting disaster prevention preventive control power to the nuclear power plant 811 into the reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment with the switches. And a plurality of dispensing apparatuses.

As shown in FIG. 61, the facilities for the flood control process include a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant The heat is distributed to the oil cooler 151 without the air cooler 80 and the inner cooler 170 and the aft cooler 182 that are pumped to about fifty times the fall by the non-dynamic water hammer pump 393, And a multistage screw air compressor 147. At the same time, the lifesaving air tube 130 is provided with a suction port 269 and a discharge port 270 so as to be detachably coupled to the air tub 130 and the lifespan basket 42, a bed nozzle 172 serving as a life-saving structure, loess for control 158, an arson 159, and a vinyl tube for pressure air storage, and at the same time, (393) And a check valve (6) and an isolation valve (5), which are capable of transferring the fluid to the fluid pressure control tank (303) In addition to the evolution, the system connection of a large number of valves to the inside of a hydroelectric power plant is also equipped with a pressure control valve and direction control And a power transmission unit 811d for transmitting the disaster prevention preventive control power of the nuclear power plant 811 to the system connection device of the valve classified as the valve and the flow rate control valve.

As shown in FIG. 61, the facilities for the flood control process include a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flow rate check flow meter 105 for checking the flow rate of the flow rate to the detection sensor in which the flood control process is formed detects the water level of the sensor bimetal 102, the sensor thermocouple thermometer 103, A temperature and pressure change sensor provided to perform a valve opening and closing operation to provide a position to each of the partial elements by pressure switches 104 which are installed at the upstream side of the pump inlet port 269, Is provided with a high pressure isolation valve in the middle of the pump suction connection flange 28 and a high pressure isolation valve 5 is a control operating part of an automatic pneumatic valve for providing disaster prevention water transfer control, The solenoid valve 76 and the butterfly valve 305 are formed in the disaster prevention piping line 89 as a collective term of the valves operated by the control operation unit signal, A steel plate 165 and a machining hole 20 are provided on the flange joint in front of the water amount intake port for providing a position in the tank 34 according to the suction port specification with a certain dimension and the filtering function of the filter And the filtered disinfecting water passes through the suction and confluence pipe 3 and passes through the isolation valve 5 and the check valve 6 and is provided with the function of disposing of the nozzle Power transmission system that connects the pressure control valve for providing the disaster prevention device and the system connection device of the valve classified as the direction control valve and the flow rate control valve to transmit the power for preventing and controlling disaster prevention of the nuclear power plant 811 And a unit 811d.

 As shown in FIG. 61, the facilities for the flood control process include a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant And a plurality of hatch covers 153 and a plurality of fire doors 154 are provided as a connection structure while providing a rotation operation when the electronic control hydraulic cylinder 620 is manually depressed to the on- ) The connection structure is opened and the mineral resources provided at the seabed mineral collecting site is a connection structure for providing a position to the inside of the holding tank lower barge hull 592. The vacuum pump 635 connection structure and the power cable 71 of the main body of the barge hull 592 by pressing the on-time main switch button 66 of the main switch button 66 for the start switch button by hand, the vacuum pump 635 rotates, Mineral resources provided at the submarine mineral collection site to provide an offshore location are located within the barge hull (592) to provide submarine mineral storage, while marine tunnel transport equipment (941) It is a system connection device of a pressure control valve, a direction control valve, and a flow control valve, which are equipped with a pipe nozzle disposing fire prevention system which ensures the function of expansion and full closing while being constructed as a solid connection structure even in the event of a disaster, And a power transmission unit 811d for transmitting the disaster prevention preventive control power of the power generation facility unit 811 to the power supply unit 811d.

As shown in FIG. 61, the facilities for the flood control process include a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant The basket 42 provided in the fire fighting cable car 256 to be injected into a fire occurrence area where flame is generated for the first time in the event of a fire in which a flood control process is formed is connected to a control device The fire extinguishing water having a constant water pressure inside the disaster prevention pipe is discharged through the valve opened to the disaster prevention pipe and reaches the plurality of injection nozzles 10 in the fire occurrence area, The discharge jet 38 for discharging the jet of water at a constant water pressure is provided with a disaster prevention pipe 89 at the lower end of the high pressure multi-stage pump inside the machine room, A first pressure check sensor 86, which is a detection sensor attached to the junction connection emergency valve 84 of the head tank 189 as the initial starting area and the hydraulic pressure control regulating valve 85, The pump operation is temporarily stopped while maintaining the hydraulic pressure of a certain standard by providing the operation again to the pump 53. At the same time, the disaster prevention piping line 89 is connected to the disaster prevention piping line 89 of the water supply system and the floor surface MFG) A pressure control valve for providing a fire-fighting disaster prevention device in a pipe nozzle type which is provided with a water pressure sensing regulating pressure reducing valve (85) And a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor facility body 1 of the nuclear power plant provided with the system connection unit of the nuclear power plant 811. [ It is configured as being preferred.

The following are rockets (612) for launching satellites and spacecraft from previous nations

Hado is a nuclear rocket (612) formed in the future satellite.

As shown in the following figure, which is composed of the power transmission portion 811d for transmitting the disaster prevention preventive control power of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant,

As shown in the following figure, which is constituted by a power transmission portion 811d for transmitting disaster prevention preventive regulation power of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant,

 And a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the reactor main body 1 of the nuclear power plant as shown in the following figure, the structure is a pure silicon single crystal structure.

As shown in FIG. 61, the power transmission unit 811d for transmitting the disaster prevention preventive control power of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant, It is composed of a method to reduce the damage of noise vibration by materials other than bombs during excavation.

The lower drawing is a detailed description of the power-saving metal used in the transformer 96. Fig.

As shown in FIG. 61, in the main body 1, the following is a submarine mineral collection robot 912, and the above-mentioned 912 is formed of a shape memory alloy.

When a battery made of new material stores electricity (685) with the above-mentioned battery when the lightning strikes, an energy bank of an untethered global village is prepared.

And a power transmission unit 811d for transmitting the disaster prevention preventive control power of the nuclear power plant 811 to the reactor main body 1 of the nuclear power plant as shown in the following figure, We will explain,

In a superconductor, the following description is given.

And a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant as shown in the following figure.

As shown in the following figure, which is composed of a power transmission unit 811d for transmitting disaster prevention preventive control power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, in the superconducting power generator, Explain.

As shown in FIG. 61, a power transmission unit 811d for transmitting disaster prevention preventive and regulating power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant, The details of the development of the computer and the new material inside the reactor main body 1 of the power plant will be described as follows.

First, according to the development of the IC and the computer

Currently, integrated circuits are used in many ways in our lives. Electronic circuits, electronic clocks, cameras, televisions, and so on. In addition, it is used in many fields such as airplane and train reservation, bank credit card and so on.

Because integrated circuits are parts of electrical products or computers, they do not know where they are used on the surface. However, the size of a small electronic calculator or a wristwatch can roughly estimate the size of an integrated circuit.

The reason why integrated circuits have become so popular in our lives is the invention of transistors. In 1946, a vacuum tube was used to develop a computer that did not fit into today's compact electronic calculators. The vacuum tube had poor performance and the number was 18,000, so it was often broken and it was hard to repair. Since the appearance of transistors, computers have become smaller, perform better, and can do much more quickly.

As shown in FIG. 61, a power transmission unit 811d for transmitting disaster prevention preventive and regulating power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant, The fourth generation is a computer that uses a vacuum tube inside a reactor facility body (1) of a power plant. The fourth generation is the first generation. The second generation uses transistors. The third generation uses ICs. The fourth generation uses LSIs or VLSIs. It is the fourth generation. And the computer that will be equipped with artificial intelligence to judge, calculate and process is called the fifth generation.

The following are the characteristics and limitations of silicon

The reason for using silicon as an IC material is as follows.

First, silicon has a very stable oxide film. And the surface of the germanium transistor is changed by moisture or the like to change its properties. When silicon is baked at a high temperature, an oxide film is formed on the surface, and the properties of silicon which is stable, high in purity and excellent in insulation remain intact.

Second, silicon is a hole element semiconductor with one element. Unlike compound semiconductors, which are difficult to control due to their small electrical properties due to minute differences in compound composition, silicon is a hole element and therefore easy to control.

Third, it is possible to make large crystals that can be made highly pure and have no defects at all.

Fourth, silicon is easy to obtain raw materials. Silicon is the next element of oxygen on Earth, and is present everywhere in soil, stone, glass, and so on.

As shown in FIG. 61, the performance of the silicon integrated circuit inside the main body 1 is getting better at an amazing rate every year, but there is a limit to finely processing silicon.

Especially, the main thing is the speed at which electrons move, which depends on the material. In order to operate the transistor faster, a new semiconductor is needed that can move electrons at high speed.

Third, for new compound semiconductors,

Gallium and arsenic are being studied as representative compound semiconductors for high-speed transistor operation. Using gallium and arsenic can treat heat three to six times faster than silicon. This material has a high speed of electron transfer and various properties that are not found in silicon, but it is not clear yet.

After 10 years of gallium and arsenic, development will reach its limit, what will happen next?

In that era, materials will be made according to purpose, rather than using naturally occurring materials. An example of such a superlattice is superlattice, in which several layers of thin semiconductor material are stacked. These materials can transport electrons several times faster than ever before.

Of course, these materials simply can not be melted and hardened. The development of a technique for depositing semiconductors very slowly in a vacuum, such as space, has allowed us to create superlattices.

Fourth, computers can be made without semiconductors

As shown in FIG. 61, a power transmission unit 811d for transmitting disaster prevention preventive and regulating power from the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant, The IC, the heart of a computer that moves into the nuclear reactor plant (1) of a power plant, can be made without a semiconductor. Even if it is not silicon, it is possible to have an on / off function when an external signal is input.

Josephson devices using superconductors

Josephson devices using niobium, lead, and the like use superconducting phenomena with a resistance of zero, and can work much faster and with less power than current integrated circuits.

● Molecular Electronics

It is trying to make a computer resembling a human brain by using the fact that the state of a molecule changes or the state of an organism cell changes by slight movement in a molecule.

In the fifth optoelectronics,

Optoelectronics refers to electronics using light-related devices, such as optical communication or laser discs.

Current telephone lines use a thin copper wire to transmit signals. In optical communication, a laser beam is passed through an optical fiber made of quartz glass to transmit a signal.

The center of optoelectronics is light emitting devices such as semiconductor lasers and light emitting diodes. However, since silicon can not make light emitting devices, compound semiconductors are used instead of silicon.

The material depends on the color of light emission (wavelength). Gallium arsenide and indium phosphorus are used for infrared rays, gallium aluminum and arsenic are used for red, and gallium phosphorus is used for green for visible areas.

Finally, about the development of new materials

How will new materials be developed in the future? Obviously, the era of simply synthesizing materials is coming to an end. Once upon a time, alchemy was the reason for this, because there was no knowledge of electrons, atoms, etc. about the material.

However, now, knowledge of the molecular structure and properties of the material has increased. From now on we will be able to develop new materials by controlling the fine structure of the material, specifically the structure of the atomic size.

In order to do this, the semiconductor, metal, and organic materials must not be admitted to specific materials, and they must be restructured at the atomic level. A surprising number of new materials will be born again as we experiment with atomic composition methods that will add tens of thousands or even tens of thousands of atoms.

As shown in the following figure, which is composed of a power transmitting portion 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the reactor main body 1 of the nuclear power plant, , 620) are shown in the following table.

The following side view is an excavator used on land, but with an excavator 845 equipped with a skew drill

So that the hydraulic cylinder 623 and the excavator 845 are combined and disassembled by the crane 861.

After disassembling the hydraulic cylinder 623 and the excavator 845 after the excavation work, the bolt hammer for detaching the bolt nut for the pillar foundation column work is used to nail the nut to raise the foundation pier at the bottom of the bottom of the sea. Barge main body (591) This equipment is mounted on the deck deck.

A power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the inside of the reactor installation main body 1 of the nuclear power plant is provided with a nichrome wire The heater fan 642 for inserting the air is formed when the electric heater of the fan 659 is installed inside the doctor ventilation 585 and the cold air is installed at the front or the rear of the fan 196, The cooling device and the hot air balloon are devices used in the transformer room 782, the central control room 781, and the like in the engine 226 and the like of the power generator.

As shown in FIG. 61, comprises a power transmission unit 811d configured to transmit disaster prevention preventive and regulating power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, A guide vane 142 of a blower to be used together with the gas turbine is formed inside the marine power plant.

Is a type of several blowers (941) mounted inside the air conditioner (1)

The impeller 143 of the body of the blower 941 as shown in the following figure is constituted by the power transmission portion 811d for transmitting the disaster prevention preventive control power of the nuclear power generation facility 811 to the nuclear reactor main body 1 of the nuclear power plant, And a bearing 200 and the like on the rotary shaft 198. As shown in FIG.

A power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant as shown in the following figure, List.

As shown in the above figure, which consists of the power transmission unit 811d for transmitting the disaster prevention preventive control power of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant, It is a position explanatory view of the operation method of the press (pressure) switch.

And the power transmission unit 811d that transmits the disaster prevention preventive control power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant as shown in the above figure, It is.

A vacuum pump (a Vacum pump) is constructed as shown in the following figure, which is composed of a power transmission portion 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the reactor main body 1 of a nuclear power plant. And 635 are connected to the lower condenser manifold valve of the condenser to inject the Freon gas again.

The figure below shows an external perspective view and internal frontal view of a small air conditioner (DIPY-5KV) capacity.

And a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant as shown in the following figure, Fig.

 And a power transmission unit 811d for transmitting the disaster prevention preventive control power of the nuclear power plant 811 to the inside of the reactor facility main body 1 of the nuclear power plant as shown in the following figure, It is.

And a power transmission unit 811d for transmitting disaster prevention preventive control power from the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant as shown in the following figure, And is installed in the compression chamber 402.

A power transmission unit 811d for transmitting disaster prevention preventive control power of the nuclear power generation facility 811 to the reactor main body 1 of the nuclear power plant as shown in the following figure, The efficiency of welding of boiler standard is explained as follows.

First, we explain the kind of welding method as follows.

Welding is a method of locally bonding two or more metals in number, and about 40 types are currently used. Among the relatively important ones, some of the methods that are considered to be particularly important for those who are engaged in welding jobs are as shown in Table 2-1. These can be roughly divided into three types of welding, soldering and pressure welding.

<Table 2-1 Metal welding method>

Fusion welding is also called melting welding, in which molten metal is supplied or melted to the part to be welded. In this case, the base material (welded material) is also melted and no pressure is applied.

The pressure is applied to the part to be connected and it is heated as heat by combustion flame or electric current of gas or it is sucked as a function of surface tension in the gap of surface where other molten metal is connected without heating, The gravitational force is applied to bond.

Various cutting methods are used for cutting materials, welding joints (gouging), gouging, and the like in welding. Among these methods, there are methods using gas flame and arc as well as mechanical cutting. However, methods other than mechanical cutting are particularly related to welding. Among the coating metal arc welding and gas welding methods, oxygen and acetylene welding methods are particularly used Therefore, we will concentrate on this, and submerged arc welding and inert gas arc welding are also important welding methods, so we will put more weight than other welding methods.

Secondly, in opening according to coated arc welding,

Coated arc welding is currently the most commonly used welding method and is often called electric welding.

In this welding method, welding is carried out by using the heat of arc generated between the welding rod to be coated and the welding object to be welded.

The principle of this welding method is shown in Figure 2.1. An alternating current or a direct current voltage is applied between the welding electrode and the workpiece (or the base material) held in the holder to cause an electric arc in the gap.

The strong arc of the electric arc (temperature about 6,000 ℃) melts the welding rod and the base metal. The welding electrode is made of metal vapor or the metal is melted into water droplets and welded to the melting glass. I make it.

When two materials are welded, when the material (base material) is thick, a groove is formed in the following portion, and the groove is filled as a welding metal and joined. The weld bead at this time is a bead surface, and the surface of the bead shows a wavy shape due to the solidification of the weld.

The welding rod is coated on the outer surface of the metal core wire. The cladding is decomposed by arc heat and is stabilized so that the arc does not turn off due to the role of the gas generated by the decomposition. The generated gas or slag covers the molten metal to protect the molten metal from the outside air to prevent oxidation and nitrification, The chemical reaction improves the molten metal and sometimes adds other elements needed for the weld metal.

Since the gas generated by the coating agent does not protect and protect the molten metal from being adversely affected by the air, the welded portion is weakened and weakened, so that the welding electrode is not used in the present day.

In the above picture, welding power source of AC or DC is used as welding machine. Other welding apparatuses include welding cables, welding rod holders, hand shields or helmet tools, and other tools required by welders.

Third, in the nature of Arc,

A voltage is applied between the electrode and the workpiece, and once it is contacted, an electric arc is generated that emits a bright blue light. A large current (about 50 to 400A) flows through this arc, which is divided into electrostatic and negatively charged electrons by the dissociation of metal vapor and various gas molecules therearound, And the anode, so that the arc current flows.

First of all, when using direct current welding power for shielded arc welding with polarity, this is referred to as direct current welding, and when an alternating current welding machine is used, it is referred to as alternating current welding.

For red welding, it is divided into two polarities depending on whether a welding rod is connected to the anode of the welding machine.

Straight polarity When a welding rod is connected to the cathode of a welding machine (abbreviated D.C.S.P.)

Reverse oplaritv When the electrode is connected to the positive electrode of the welder (abbreviated D.C.R.P.)

In the early days of electric arc welding, the coating of the electrode was not developed well, so the DC welding machine was used a lot, but after that, a good amount of arc welding electrode was produced, so the AC welding machine with low price was used a lot. Lt; / RTI &gt;

As shown in FIG. 61, the arcing structure constituted by the power transmission portion 811d for transmitting the disaster prevention preventive and regulating power of the nuclear power generation facility portion 811 to the inside of the reactor facility main body 1 of the nuclear power plant, We will explain it as follows.

There is a phenomenon that the arc does not turn in the right direction during the welding, but it is sideways. This is particularly so in the end or the first part of the weld that the arc is tilted as the wind blows into the inside of the weld, thereby preventing the welding operation from sticking to the desired spot. This phenomenon is called arc blow or self-deflection.

The phenomenon of this arc tip does not occur at the center of the workpiece.

As a preventive measure against arc

First, use AC welding instead of DC welding.

Secondly, it is most effective to use a method of welding a plate of the same material as the backing starp (about 15 cm ² ) to extend the weld line at the beginning and the end, and the first method is most effective.

Next, in the case of coated arc welding,

First of all about welding machine

The arc welder (Welder, 853) is designed to allow large currents to flow at a low voltage, suitable for welding, including DC arc welders and AC arc welders. There is also a single welder for one welder and a multi-welder for more than two people.

First, there are two types of DC arc welding machine (853), DC arc welding machine, and 2.2 degree DC arc welding machine. AC generator is used as an AC motor to rotate a DC generator to generate welding DC. In arc welding, it is very important to adjust the welding current according to the welding object. In this type of welding machine, there is a control dial on the instrument panel to adjust the current. In addition, there is a switching switch to match the positive polarity and the reverse polarity because it is a direct current, and a positive or negative sign (+) or negative (- have.

As shown in the above figure, a motor is usually used as a three-phase induction motor (commonly called a three-phase motor in the market). When connecting a welding machine to a power source, . In this case, if one line of thin wire is exchanged with another line, whether the direction of rotation is correct or not is immediately known as the direction of rotation is indicated in the welding machine.

2.3 is a selenium rectifying DC arc welding machine. Inside this welding machine, it is rectified to direct current by seren rectifier with external AC current. This selenium rectification type DC welding machine has developed recently and has no rotating part, low no load loss (power consumption when not welding), quiet, cheap and easy to repair, it compensates many defects of conventional rotary type, Has recently become popular. However, compared to an AC welder, it is still expensive and inefficient.

Secondly, AC arc welding machine (853) equipment has been used very much since the stability of arc was obtained by AC by the development of welding rod. AC welding machines are widely used because they are relatively simple, cheap, and easy to repair. In addition, it is effective in preventing the arc from leaking.

The following three types of AC welding machines are mainly used depending on the method of current adjustment.

First, the movable iron-arc AC arc welder 853 and the sparging-type AC arc arc welder 853 are used for the movable iron-arc AC arc welder 853.

As shown in the principle diagram of 2.4 °, the current adjustment of the movable iron core AC arc welder is carried out by installing a _third iron core M ₃ in addition to the iron cores M ₁ and M ₂ of the transformer and changing the degree of easy passage of the leakage magnetic flux Adjust the size of the welding current. The normal case is of the n secondary windings _21, by switching the tabs on the n ₂₂ and the adjustment of a large range of current fine tuning is often that a movable iron piece.

The current adjustment of the movable-ring type is adjusted as a method of changing the value of the leakage positive tangent by moving the primary coil with respect to the secondary coil as indicated at 2.5 °,

That is, when the adjustment handle is turned, the primary winding is raised. The distance between the primary winding and the secondary winding varies in the secondary winding, so that the magnitude of the welding current flowing through the secondary winding changes.

In the saturable reactor type, as shown in Fig. 2.6, there is adopted a method in which a reactor is inserted in a secondary circuit in a straight line and excited as another power source (rectifier C), and the saturation degree of the magnetic circuit is changed to change the effective loudspeaker . In addition to being easy to adjust the current, this method can also use the variable resistor (C) in the figure to adjust the welding current farther away from the remote control welder.

As shown in FIG. 61, attention is paid to the use of a third welder constituted by the power transmission portion 811d for transmitting the disaster prevention preventive and regulating power of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant As follows.

First, in terms of usage rate, the ratio of the time the arc is splashed between the welding rod and the base material on the secondary side of the welding machine in the welding plant is usually about 40%, and the remaining 60% is the time when the arc is resting without splashing. The reason why I can not continue to use the welding machine indefinitely is the temperature rise of the welder. When I think about 1 ~ 1.5 hours related to the temperature rise, the arc spattering time is about 60%.

Next, let's think about whether or not a welder will be able to use a certain amount of welding machine when it is working with some welding machine. This usage rate is called the allowed usage rate. In other words

Here, the rated secondary current is shown in the nameplate of the welder, and the rated duty rate is also indicated as a percentage of duty cycle.

For example, assuming now that a welder with a rated current of 300A is actually welded with a current of 200A,

However, the rated utilization rate of this welder is 50%.

Therefore, it can be seen that continuous use at this time does not interfere.

Next, in repair maintenance of the welder,

It is necessary to examine the presence or absence of welding by measuring the insulation resistance or the primary no-load current at least once a year for comprehensive maintenance of the welder.

Also, when using the welding machine in the following places, it is not good to specify the welding machine in advance and do not use the specially manufactured one.

First of all, it is recommended to be used in places that are exposed to windy weather from outdoors, places where harmful corrosive gas is present in places where the ambient temperature is below -10 ℃, and places where there is a lot of steamy vapors or explosive gas in places where water vapor or humidity is high. There are places and places with a lot of dust, etc. Therefore, the welder should not be used in such a place for a long time.

In the specification of the third welding current and voltage,

When the need arises to measure the arc current, it should be measured by inserting an ammeter in the secondary circuit. There is an ammeter for portable ac voltage measurement on the market. It should be noted that the capacity of the current is several hundred amperes, so you must purchase a large capacity. In general, if you have a maximum 300A scale and a 600A scale, you will not be able to use it.

The following shows the inert gas arc welding (inert gas arc welding and carbon dioxide arc welding) as shown below.

First, in its opening, in its principles and merits,

In principle, inert gas arc welding is a major welding method widely used for welding various metals in which conventional arc welding is difficult to weld by gas welding.

In this welding method, as shown in 2.37 ° and 2.38 °, the nugget's tungsten rod or metal electrode in the atmosphere of inert gas (inert gas), which does not react with the metal even at high temperatures such as argon or helium, The arc is generated between the objects to be welded and welded with the heat.

There are two methods, as shown in the figure, Teak Welding (TIG; 2.37 degrees) and MIG Welding (MIG; 2.38 degrees).

(TIG) welding is an inert gas tungsten-arc welding (TIG), which uses a tungsten rod as an electrode. It is welded to the filler metal by a welding method such as gas welding. The rod is welded while melting in arc.

2.39 degrees It is the bottom (TIG) welding of aluminum aluminum small runowout. It holds torch in the right hand and nude electrode (low rod) in the left hand.

However, in the thin plate, only the arc heat is welded without using the naked electrode.

Because tungsten is hardly consumed (monoconsumable), it is also called inert gas welding.

The product names are Heli arc, Heli weld, Argon arc, Argou weld and so on.

(MIG) welding is an inert gas metal arc welding method (MIG after the head of inert gas metal arc welding) or a method for generating arc by continuously sending (continuously) the electrode wire of the filler material instead of the tungsten electrode. Consumable (also referred to as consumable gas) inert gas arc welding.

2.40 degrees is MIG welding of aluminum alloy tank, Torch is the right hand.

Carbon dioxide arc welding (CO ₂ arc welding) is known as a promising welding method recently used for testing carbon steel welding using Co ₂ gas instead of inert gas for MIG welding.

In the following advantages

Inert gas arc welding is an excellent welding method and has the following advantages.

First, there is no need for cloning and flax.

In general arc welding or gas welding, it is necessary to use coating or flux to prevent oxidation and nitriding of molten metal, but in inert gas arc welding, there is no need for such welding because it is welded in inert gas. The operation is very simple because no mechanical or chemical treatment is required to remove the post-slag or residual (used and remained) flux.

In addition, in the case of aluminum (Al), magnesium (Mg), stainless steel or the like, there is no possibility that the welded portion is corroded by the residual flux as in the conventional welding.

This is because the inert gas arc welding is mainly used for light alloy or stainless steel.

The following is easy to weld in all positions and is efficient

In general, the arc of inert gas arc welding is very safe, has few spatter and is relatively easy to operate.

Because it is welded in all posture, more heat concentration and welding efficiency are good, when used in thin tube, welding speed is fast and deformation after welding is small.

In addition, it is very advantageous for welding copper alloy or light alloy having good thermal conductivity (heat transfer efficiency).

Unlike submerged-arc welding, it is advantageous in many ways because it can be directly welded and welded.

The quality of the third welded item is excellent.

The inert gas arc welded part is generally superior to the welded part of other arc welding or gas welding in terms of ductility (strength), strength (strength), airtightness (dense metal), and corrosion resistance Do,

In the case of an inert gas arc welding, the facility cost is rather high and the inert gas is rather expensive. However, since the welding work cost is rather low, it is widely used today, and aluminum alloy, magnesium alloy, stainless steel, nickel alloy, It is used for welding of carbon steel and low alloy steel and surface hardening. Especially titanium alloy, zirconium alloy, etc., only inert gas arc welding is used for welding metal which is likely to come into contact with oxygen or nitrogen in the atmosphere at high temperature will be.

In addition, TIG welding is generally suitable for thin plates with a thickness of 0.6 to 3 mm , and thick plates with a thickness of about 3 mm or more.

In other words, (MIG) welding is more efficient than (TIG) welding.

In his kind

Inert gas arc welding and related welding methods are roughly divided into the following types.

In TIG welding, there is a manual method in which a welder manually manipulates the electrode parts generating the arc, that is, torch and welding rod, in place of automatic, automatic operation using a machine, There are three kinds of semiautomatic, which are morter and semi-automatic,

In addition, there is an arc spot welding in which welding is performed as a spot instead of a continuous long welding, and a special (TIG) soil is also used for arc cutting, which will be described next in sequence.

In addition, the twin arc method of generating an arc between two tungsten rods as a heat source, such as atomic hydrogen arc welding, is also used by TIG welding.

(2) In the characteristics of the inert gas tungsten arc (TIG) welding,

In TIG welding, alternating current or direct current is used, and the polarity has a very large influence on the welding result.

First, the flow of electrons and ions flowing through the arc in direct current welding of DC welding is as shown in 2.41.

In the positive polarity, the ions of the metal vapor and the inert gas are directed to the electrode, and the electrons strongly impact the base material, so that the penetration becomes intensively deep.

Since the electrode does not exothermically (generate heat) as a collision of a slow gas ion, it can flow at least a large current with a diameter. (Not described below)

It is called disaster prevention to prevent disaster by type of big fire, typhoon, tsunami or earthquake. It removes parasite which is full in the stomach, and it eradicates pest by spraying insect repellent such as mosquito fly insect and eradicates harmful red tide In the present invention, "disaster prevention" and "control" are clearly distinguished and separated. The disaster prevention refers to the activity before the disaster and the control refers to the disaster recovery activity after the disaster.

 We decided to divide the large fire and large fire in the neighborhood living area and pledged to prepare the reapplication. All of the disaster prevention of this city was prevented by the pain and sadness caused by disaster, and praying for the hopeful tomorrow, As a process, the bar-type nozzle is used as a tank cleaner, and the worker is able to continuously use the equipment of the crane (861) .

In the above picture, typhoon and rainfall are transferred into the reactor main body 1 of the nuclear power plant under the condition of the air temperature and the air distribution condition at the altitude of the upper atmosphere of the sea surface. A plurality of construction machines 880 installed on the side surfaces of several barge hulls 581 constituted by a power transmitting portion 811d constituted by a trough 653 having a height of a troposphere, The search for the elevation of the atmosphere prior to the formation of the storm-like descending air current 926 into the upward air stream 925 (changing the course) is based on this, and typhoons and floods are the occasion to block the source block .

As shown in FIG. 61, a power transmission unit 811d configured to transmit disaster prevention preventive and regulating power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, And the conventional typhoon prediction method according to the weather observation.

The center pressure is usually about 970 ~ 930hPa, and it is very strong when it is below 930hPa, and the maximum wind speed on the ground reaches 50m / s or more.

Table 6. Pressure drop in typhoon

The record of the central pressure is 912hPa, which was observed on September 3, 1935, at 891.7hPa in Key West, Florida, USA, and the next at 21st March 1934, at the Muro Damisama in Japan. The record of the sea was recorded at about 400 nautical miles east of Luzon Island in the Philippines, at 886.7 hPa observed on the ship "Sapaerea" on August 18, 1927, and when the typhoon "Marge" landed on our country on August 23, 1951 was the peak season, It is the second record with a value of 887hPa from the sea.

The following is an explanation of the typhoon forecasting method. It is the most important problem to anticipate the typhoon's career and the movement of the typhoon quickly. However, the current advanced meteorology and forecasting techniques are incomplete. Until now, many researchers have used statistical methods and ephemeral methods by numerical model as objective forecasting method of typhoon movement.

The KMA uses statistical methods such as PC method, Climate method, Cliper method, and similar method. In mechanical method, Korean typhoon model is operated as a weather forecast computer to predict the predicted position of typhoon objectively. In addition, the following methods, which are synonymous with weather maps, are used as reference data to select the most likely route.

The width of the speed forecast is not shown, but the range of the probability source is set by imagining the maximum speed as long as possible without causing any disaster prevention. Therefore, when the velocity is slowed near the turning point, the actual and actual movement is likely to differ greatly. The probability source varies from time to time as the position and velocity of the typhoon change. Therefore, whenever a new weather data is available, it should be placed on the boundary with new typhoon information that is corrected and announced.

As described above, in the past, it was delivered by broadcasting media. However, it is very insufficient to prevent the damage of typhoon, and the present invention is a technique of a remarkable difference from the previous one. The rainfall cloud 653 and the cold air lump descending airflow 926 are introduced into the tank-level manomethen doctor ventilation 585 and the air chamber 402 by the upward flow 925 ), Which is a remarkable difference from the prior art level.

In the following figure, an air cylinder 138 or an actuator installation is provided in the front section of the fire damper 583 inside the reactor vessel main body 1 of the nuclear power plant and inside several of the doctor ventilation 585.

In 1982, when the ship was built in Smedberg, Norway, the fire damper (583) could not be operated and the ship would need to be rated as Class A, but the inventor of the present invention devised a damper operating drill (107) The vessel has been registered with the International Maritime Safety Association as the A grade in the ship stability class F, and the national level has been improved.

And a power transmission unit 811d for transmitting disaster prevention preventive control power to the nuclear power plant 811 into the reactor main body 1 of the nuclear power plant.

And a power transmission unit 811d for transmitting disaster prevention preventive control power to the nuclear power plant 811 to the inside of the reactor installation main body 1 of the nuclear power plant as shown in the following figure. ) Installation method is also shown.

Already in the 14th century, with the tides of tidal and ebb tide in the foreground of the lance tidal power plant, some of the coastal areas of Holland and England in Europe have been using the power of tide and ebb, or tide, The following records have been written about these waterbirds: "The inhabitants use the sea in various forms in real life. One example is a waterbath in the back of the coast. Build a dam in the subdued area, and make a gate with two doors. These doors are opened by the force of the flowing tide, and after the time of high tide they are closed tightly by the force of the tide. The waters that are trapped in it will be turned back to the sea in return for being released back to the sea. "

In the case of the United States, a tidal mill was constructed in 1635 using the forces of tide and ebb. However, this tidal mill was insignificant in terms of energy production.

The facility that uses electricity to generate electricity is currently located at the mouth of the Lans River in France. On the next page is a panoramic view of the Lance Tidal Power Plant. A striking feature of the Lance Power Station is the 24 new turbines that use the energy of the flowing water as instantaneous power. When the seawater flows in, the wings of the turbine (267) are pushed by the force of the water and turn and generate electricity.

During high tide, each turbine becomes part of the dam (680) and seawater is trapped in the reservoir. As the seawater recedes and falls, the doors of each turbine open, and the power begins to regenerate back into the sea.

This unique turbine 267 also acts as a motor. Once the power is supplied, the pump will be moved, and the flow of seawater will be increased to increase the overall output.

In the present invention, the conventional reactor building (688) along the outer wall surface of the existing nuclear reactor building (688) of the land and marine nuclear power plant, which efficiently improves the operation of the nuclear reactor, (2) Double-structured block tanks of double diameter The double-structured block tanks for nuclear waste disposal at a single site The reactor building is a radiation-like connection structure consisting of a double piping block piping line (74) and a plurality of safety valves The explosion-proof control product of the nuclear fuel rod, which is a mixture of cooling water and a mixture of soap and a dispersant, which is formed at the toothpaste level for the purpose of preventing nuclear fuel collision, is stored in the former nuclear reactor building. And to control nuclear fuel explosion prevention control devices and nuclear waste generated before and after operation of nuclear power plants. Nuclear power generation facilities formed by nuclear waste disposal units and along the outer wall of nuclear reactor buildings Dual structure block tanks for nuclear reactor facilities of land and marine nuclear power plants connected to each other Nuclear waste treatment equipment and nuclear fuel explosion control with reactor buildings The connection structure is constituted by the distributing device of the device.

As shown in the following figure, which is constituted by a power transmission unit 811d for transmitting disaster prevention preventive control power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, in the wave power generator of the power generating plant,

In 1909, he announced that someone invented a blue generator. The person who invented this proved to be able to turn the waves that shake the sea into energy.

This generator was to send the power of the wave caught by the board in the water to the spinning machine to turn the generator.

However, it only ended up lighting a few light fixtures hanging on the power cord. As the oddly shaped devices sank by storm, the people of the world forgot about it.

However, this design was not outrageous. As technology advances in recent years, it has been found that it can be the basis of an effective generation device.

In recent years, several wave power devices have been newly developed. In the meantime, the interest of the world gathered in the design which can develop on a large scale.

This is to fill a concrete frame with a water-sensitive liquid or gas in the concrete frame near the shore. The force of the waves coming from this frame passes through the liquid in the bag and is transferred to the coastal power plant.

Another kind of wave power generator is showing good. This is what you see in the picture below, which is not much different from the principles of the 1909 wave generator.

The generator is located about 10 meters from the coast to the sea. The surging wave rushes the third aberration, and the waves are pushed to the outside of the device and turn the other three aberrations.

The power generated by a single wave is only 5,000 watts, but enough to supply clean, cheap power to remote islands.

In order to produce power on a large scale with the power of waves, more intensive research is needed in the future.

In the use of sound electromagnetic waves,

Hado is a classification of the aquifer class into 10 levels.

As shown in FIG. 61, a nuclear reactor main body 1 of a nuclear power plant comprises a power transmission portion 811d for transmitting a disaster prevention preventive and regulating power to the nuclear power generation facility 811, And a power transmission unit 811d for transmitting disaster prevention preventive control power of the nuclear power generation facility 811 to the inside of the nuclear power plant 1 of the present invention as shown in the following figure. A construction machine (880), a Shiso (935) crane (861), and a boom table (651) were used.

The above-mentioned energy is supplied to each corner portion of the outside of the hull bottom, and a plurality of anchors and anchor bolts 133 for replacing anchors are provided. The anchor bolts 133 are fixed to the bottom floor of the sea floor A mooring device; A hydraulically-adjustable safety control unit hatch cover 153 at a predetermined distance from the lower end of the hull bottom, a skeleton bed 616 for adjusting the level of a tank frame under- An excavator 845 for a central position holding tank at the upper end of the hull deck, where a plurality of hull anchoring bollards 638 are provided at a predetermined distance from the upper end of the hull deck (SDU) at the upper end of the hull bottom; A piping line for connection carver to protect the pipe rack 694 and a drilling machine 908 for crushing crude oil to the upper part of the holding tank, A plurality of electronically controlled valves in the tank internal safety control device and a fishing net 910 for reserving water from the center position holding tank integrally provided with the natural gas and crude oil drilling equipment to the outside wall outside the holding tank, And a cathode ray tube 184 formed inside and outside the tank,

However, officially, according to the international convention, the range from the ground to the upper reaches up to 29 Km is restricted to that range. Therefore, as described above, there are several sea-level and sea- In the floating dock, a sensor for detecting military defenses is installed so as to enhance the monitoring function so as to prevent the production of military equipment, thereby making nuclear facilities of Pyongan Island and Hamkyung Province helpless. Therefore, In order to allow the enemy missile to be launched automatically when the missile is fired, the missile will be located at an altitude of 29km above the ground. A military defense sensor detector consisting of a number of floating docks And the construction of the net disaster prevention system in the marine and the airspace, and the construction of the earth-friendly peaceful disaster-free global village constitutes the main body as the safety connection structure inside the main body of the marine nuclear power plant, As shown in FIG. 61, the distribution system of the reactor structure of the double structure block tank nuclear reactor is connected to the inside of the reactor main body 1 of the nuclear power plant, And a power transmission unit 811d for transmitting the disaster prevention preventive control power to the power generation facility unit 811. [

Referring to FIG. 6M, a power transmission system for transmitting disaster prevention preventive adjustment power of a nuclear power generation facility unit 811 to a nuclear reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention 811d of the nuclear power plant 811 showing a structure for illustrating the embodiment showing the disaster-controlled disaster prevention device of the fire-prevention hose installation operation of the dual-pipe fire hose and the wire rope and the injection nozzle, Side Lateral Construction of Controlled Disaster Prevention Equipment Road,

The fuel supply piping line 811d constituting the flood control process is constructed by the power transmission unit 811d for transmitting the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, A fire pipe nozzle 10, which is called a nozzle composed of a hose of a pipe nozzle and a pipe body in a double pipe structure form, is connected to the bottom of the injection nozzle body (Width × length × height: 2500 mm × height) to the upper part of the body (B) with a spray nozzle body (B) detachably assembled to the upper part (C) of the spray nozzle body above the lower part of the body 2500 m m × 2000 m m, which is made of a wire rope or a rope net, is installed. Inside the basket 42, the fuel supplied from the gas fuel supply pipe line is supplied for emergency use A gas burner 173 for cooking, which is attached to the lower portion of the burner 173 and attached under the vinyl tent 77 formed in a double structure in the form of an ad balloon (length × width × length: 10M × 10M × 10M) The unmanned igniter 187 is installed and the outer circumferential surface of the adverbon is wrapped with the wire rope 19 or the rope 131 like a mesh and bound to the lower portion of the adobe with the rope 131, A radiosonde 134 as a meteorological observing instrument for observing the diurnal state of a farther place at a higher position and at the same time providing a mounting of the multi-stage pump 184 on the lower part of the injection nozzle body B, The multi-stage pump 8, the disaster prevention piping line 89, the disaster prevention water passage 17, the collecting tank 34 having the dual pipe structure, the fire extinguisher 40, the stack opening 45, Electronic control unit Inside piping of communication equipment of microcomputer system A plurality of valves for controlling the flow of the flow rate, an air compressor 80, a generator 124, an engine 144, a cylinder 138 configured in the doctor ventilation, and a tumbler winch 137, And the fire hydrants 179 are connected to the internal combustion engine 185 and the tubes 188 and the head tank 189 and the high pressure hose 190. The iron structure and the pump internal impeller 143 ), A power transmission unit (hereinafter referred to as a "fire sensor pump body") for transmitting the disaster prevention preventive adjustment power of the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant 811d). &Lt; / RTI &gt;

As shown in FIG. 6 (m), the fire sensor pump in which the flood control process was formed was firstly packed with a vinyl coating on rolled steel for KSD 3507 general piping, and the connecting capillary connected to the nozzle body was an aluminum alloy for casting KSD 2331 And KSD 3699 hot rolled stainless steels. The temperature sensor can be replaced with a bimetallic or bulldon tube to a paraffin sensor. The diesel engine , The fire pump to solenoid solenoid valves and other standardized general purpose hose pipes to supply liquid and gas at the same time in the form of double tube structure according to their sizes, , While the pipe nozzle type 1 is designed in the order of 200 mm, 180 mm, 150 mm, 130 mm, 100 mm, 80 mm, and 50 mm in diameter (200 × 180) mm, (180 × 150) mm, (150 × 130) mm, (130 × 100) mm, (100 × 80) mm, and (80 ×) 50) mm, (50 × 25) mm It is composed of 14 types of standard, tube nozzle connected to hose part and tube nozzle of many linear straightening hole, so that buildings or single houses and road facilities The working area of the line of defense in the protection zone is composed of multi-variable type and standard, so that the general fire of the building belonging to the different fire class, fire and forest fire of wood, forest, paper, As the fire evolved from the early days and the human life was saved as fire-fighting and disaster prevention countermeasures by a large number of adverbons and airships, many disaster disasters were extinguished, and at the same time, the installation location was set in the center of the Korean Peninsula, This flood control process consisting of a power transmission unit (811d) for transmitting the disaster prevention control block power of the nuclear power seolbibu 811 into the reactor equipment body (1) is preferred.

As shown in FIG. 6 (m), a fire-fighting nozzle 10 used as a plurality of pipe nozzles inside a marine power plant having a flushing control process is provided with a thickness of 2 mm or more. In the case of installation, the nozzle joint portion is divided into seven stages, and the basic 1-type nozzle is named "Nominal 100" 234, "Nominal 90" 235 "Nominal 75" 236 and " A plurality of firefighter nozzles 10 formed by dividing the "name 50" 238, the "name 40" 239, and the "name 25" 240 into 65 "237" (Diameter: 360 mm, vinyl coated flow pipe 60) with the elbow, tee elbow 44 and the pipe nozzle 10 attached to the fire fighting / disaster prevention piping line 168, Quot; 50 x 40 "245 and" nominal 40 x 25 " 244, and " "(246) In the case where a firefighter nozzle is constructed at a higher position as in the case of this type 1, the tube nozzle is a basic 2 type, and has a plurality of eight-node gap 15 at the normal position of the injection nozzle, A hole 26 is formed at the edge of the flange 28 at the junction of the flange 28 and a tee elbow 44 for connection with the disaster prevention pipe connected to the joint at the lower end of the flange 28, The rope 131 is roped at the upper end of the nozzle body 10 with the rope 131 so as not to be temporarily detached from the shackle 23, the bolt 24 and the nut 25 at the two flange machining holes 20 The rope 137 is pulled up from both sides of the shackle 23 in the direction opposite to the binding position, and then the rope 137 is disassembled and the rope 137 is disassembled. At the same time And a 15 m fire hose nozzle 10 is installed in the firefighting nozzle nozzle 10 at the same time as the spray nozzle 10 is provided with a triangular winch 137, The fire-fighting nozzle 10 is provided with a plurality of sets of fire-fighting nozzle nozzles 10 at a distance of 1 km, 2 km and 3 km, It is preferable that the flood control step is constituted by the power transmission unit 811d that transmits the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the power transmission unit 811d.

The disaster prevention water 7 is supplied to the disaster prevention hose 9 while the high pressure piston type disaster prevention pump 8 which supplies the disaster prevention water 7 to the upper end of the mooring tower as shown in FIG. The disaster prevention water is discharged to each of the crane boom stand 651 and the disaster prevention nozzle 10 provided between the nozzle 10 and the connection of the fire hose connection and the water supply pipe connection fixed type disaster prevention nozzle 10, A weather shelf device provided with a wire rope 19 and a shackle 23 and a connection flange 28 for connection to the flood control nozzle 28. A basin in which a pile at the lower end of the lower part of the ad- (42) The connection line for protecting the disaster prevention nozzle at the bottom (19) The hose of the gas transportation means lighter than the air is connected to the inside of the disaster prevention hose by a double structure. The fire-fighting nozzle nozzle (10) Distribution of Providing a device, and, at the same time it is preferred, this process consisting of a flood control barrier disaster power transmission unit (811d) for transmitting prevention control power of a nuclear power plant reactor plant body (1) into the nuclear power seolbibu 811 of.

6 m, the hose 109 and the high-pressure hose 190 are provided in the facilities of the balloon 77 and the airship 77 equipped with the flood control process, (158) is compressed air generated by an air compressor to prevent disaster, and air supply is provided while separating cold air and hot air, which are always compressed and mixed together, at the same time It is equipped with an alternative method to fix by wire rope and frame. It is equipped with a double structure fire extinguisher according to weather condition. It is combined with fire extinguishing equipment system which is controlled by internal equipment of the fire extinguisher body and electronic control of communication means. At the same time, the mixer section of the disaster prevention pump is equipped with a T-elbow coupler gas- At the same time as the carbon dioxide 174 gas cylinder 171 is provided as an inlet, carbon dioxide is supplied as a powder and a compressed liquid gas to the gas cylinder 171 for storing the halon gas 175 while ensuring the function of initial evolution 15 times faster than the fire water And is provided in a piping line (89) at the back of a high-pressure three-stage multi-stage pump composed of the gas inlet mixer (191), so that a normal port injection system is used. In the port injection system, It is preferable that the flood control step is constituted by the power transmission unit 811d that transmits the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant.

As shown in FIG. 6M, a suction port is formed around the impeller 143 inside the protective cover of the mouth-shaped multi-stage disaster prevention pump 8, The head tank 189 is connected to the suction pipe and the discharge pipes 3 and 4 so as to increase the water pressure of the fire water in a state of a very high pressure and at the same time the head tank has a capacity of 8 liters And 16 bar. When a predetermined pressure is reached at the same time, a large-sized pipe (14) of a certain size and a pipe (14) of the pump discharge port of the front part of the head tank and a pipe It is equipped with a connecting elbow and a tee elbow (44) to be able to withstand the high pressure, so that the installation position can be precisely set up, and the nuclear power plant This flood control process consisting of a power transmission unit (811d) for transmitting the disaster prevention block of the power control unit 811 is preferred.

As shown in Figure 6 (m), preferably, after the water supply pipe 14 formed with the flood control process is connected to the disaster prevention pipe 14 for disaster prevention, and then the injection nozzle connection is connected to the pipe connection subsidiary reducer 35 ), The name of the standard size of the standard body, which is made up of the pipe body which is adjusted to the standard size of 75 × 65 (243) and the name of 90 × 75 (242) 244) in the name of 50 × 40 (245) in the order of 40 × 25 "(246), the injection nozzle body is connected to the injection nozzle body in an antenna type so that the installation is allowed, and the injection nozzle injects the nozzle body of a certain length into the nozzle body And the pipe 14 is connected to or connected to the piping 14 in the middle as one set and connected to the rear end of the piping of the floor of the machine room by the piping 14. In the case of connecting the piping 14 to the piping 14, (35), and then the boom of the disaster prevention nozzle body (14), and then the piping connection reducer (35). In addition, in the disaster prevention piping system for disaster prevention, bolts (24), nuts (25) and washers 26 are connected to the flange connection processing hole 20 in the circumference of the disaster prevention nozzle flange 28 and a nozzle gap 15 between the flange 28 and the flange 28 is provided with a coupling on the concave portion, , The nozzle body (B) is constituted by a basic 2-type connecting structure and is provided with a power transmission mechanism for transmitting the disaster prevention preventive adjustment power of the nuclear power generation facility unit (811) into the reactor facility main body (1) of the nuclear power plant It is preferable that the flood control step is constituted by the transfer unit 811d.

Referring to FIG. 6n, the nuclear rooftop of the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste disposal according to the present invention is connected to the nuclear rooftop 811, And double pipe structure fire hose installation operation Roof tank and pressure tank that make initial fire and rescue structure easily within 1 second in indoor fire A water supply device Water connection pump A fire extinguisher that shows an example showing an example showing a fire extinguisher. Dispense control of the facility part (811) Dispensing device of the disaster prevention device Double pipe structure Side of operation method of fire hose installation operation, sectional configuration Road,

6N, it is preferable that the inside of the nuclear reactor facility main body 1 of the nuclear power plant is provided with a wire rope and spray nozzle for preventing disaster prevention of the nuclear power plant 811, Rooftop tanks and pressure tanks and water supply equipment that will simplify initial evacuation and rescue in less than one second. Connected Waterworks Connections In pump fire extinguishers, washers (26) are installed at 0.5 mm or 5 mm And at the same time, a rooftil tank, a pressure tank, and a water supply device connected to the water supply pipe of the water pump, the discharge jet 38 is connected to the radiation curtain water film 39 and the straight discharge The number of injections can be controlled quickly and accurately, more rapidly, more continuously, and more quickly, by operating valves and high-pressure multi-stage pumps (8) The spray jet 38 for continuously discharging the ink into the nozzle gap 15 is applied to a versatile range of preventive measures for preventing the spread of a large-sized fire and preventing disasters. In addition, And the water supply device water supply connection pump The fire extinguisher installation is provided with the observing equipment of the meteorological observation system on the upper part of the discharge jetting water curtain water film and at the same time the large number of the airship 78 and the advertisement balloon 77 are piled up over the ground surface, As the disaster prevention equipment for providing the air generated by the air compressor 80 to the air hose 109 and the connecting nipple 110, is installed inside the pipe nozzle body of the dual structure type, (1) of the nuclear power plant to prevent the disaster from interfering with the nuclear power plant (811). This flood control process adapted to reach a power transmission unit (811d) is preferred.

As shown in FIG. 6N, the inside of the reactor facility main body 1 of the nuclear power plant is protected from disaster prevention of the nuclear power generation facility 811 by the wire rope, the injection nozzle, and the double pipe structure. Rooftop tanks and pressure tanks and water supply systems that will simplify initial evolutions and life schedules. Connected water pump installations include high and low mountain 395 cable car (256) and offshore double structure block tank bridge bridges (937) Nuclear waste treatment Dual structural block tank Marine tunnel transport equipment (941) Connections to the rooftop tanks, pressure tanks and water supply equipment at the same time while maintaining a continuous supply of electricity (685) Connections Pump fire extinguisher facilities include the surface of mountainous mountain ranges GLL) Building of high and low buildings near the bottom ridge line and beach near the seaside beach Rooftop fire control cabin (394) A driving wheel roller (16) for fixing a steel tower (116) by an anchor bolt (133) and a plurality of wire ropes (19) And a tug winch 137 to the lower part of the steel tower 116 is installed at each of the mountain top part and the building roof top driving cabin 394 in the building, The power supply 46 produced from the generator 944 of the power generation plant 943 and the engine generator 226 is connected to the transformer 96 connected to several electric wires 71 And the electric pole 95 are supplied with electric power from the distributing and inputting device of the power transmitting portion and the motor 192 having the micro control function and the several air compressors 80 and several electromagnetic motors, 192) control module 106, and at the same time, A 256 is connected to the vinyl tent 43 type collecting tank 34 composed of a pump extinguisher 124 attached to the wire rope 19 and the load distribution of the object of the fire water 7 inside the fire hose 9 And a fire sensor pump is provided with a plurality of add-ons 77, airships 78 and ropes 131 on the fire-fighting nozzle hole 20 and the life-saving basket 42, and at the same time, (684) of the transformer (96) of the substation is regulated in the housing of the nuclear power plant to provide the disaster prevention preventive adjustment power to the inside of the reactor facility main body (1) of the nuclear power plant It is preferable that the flood control process is configured with the unit 811d.

As shown in FIG. 6N, the inside of the reactor facility main body 1 of the nuclear power plant is protected from disaster prevention of the nuclear power generation facility 811 by the wire rope, the injection nozzle, and the double pipe structure. (1) of the reactor plant (1) of the nuclear power plant is provided with the power supply from the power transmission section constituting the regulating shaft to the distribution shaft A multi-stage pump 8 and a diaphragm pump 144 connected to the diaphragm pump 144 are connected to a power motor 198 of the multi-stage multi-stage pump 8, After the piston 127 and the cylinder 126 are attached to the crank handle handle formed by the crank 248 and the link stand 249 above the crank handle 538 and the hose (not shown) formed by the prime mover 80, 109) The fire extinguisher and the fire extinguishing material are installed in the fire fighting cable car 256 while the air piping line 181 composed of the fire extinguisher 110 and the intercooler 170, It is preferable that the flood control step is constituted by the power transmission unit 811d that transmits the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the inside of the main body 1. [

As shown in FIG. 6N, the inside of the reactor facility main body 1 of the nuclear power plant is protected from disaster prevention of the nuclear power generation facility 811 by the wire rope, the injection nozzle, and the double pipe structure. Of the hydroelectric power plants 943 constituting the control shaft into the main body 1 are provided with the rooftop tank and the pressure tank and the water supply equipment water pump connecting water pump fire extinguisher equipment which will simplify the initial evolution and lifesaving Or the power generator 46 is not supplied from several engine generators 226, it is possible to provide a non-powered water hammer pump 393 for controlling a plurality of natural disaster prevention Inside the nuclear reactor facility main body (1) of the nuclear power plant of the distribution shaft constituted, the flood control facility is explained as follows.

As shown in FIG. 6N, the inside of the reactor facility main body 1 of the nuclear power plant is protected from disaster prevention of the nuclear power generation facility 811 by the wire rope, the injection nozzle, and the double pipe structure. And the pressure tank and the water supply device connected to the water tank. In the pump fire extinguisher system, a nozzle gap (15) formed around the circumference of the pipe (14) of the injection nozzle (10) ) Evolve rapidly and precisely and slowly with a plurality of linearly sprayed water film discharging nozzles 38, and fire flames 236 are evolved rapidly and prevent a large fire. As a result, The length of the piping of the high and low mountains around the mountain and the road and neighboring houses, such as the arrangement of a telephone pole, The roof tanks, the pressure tanks and the water supply equipment at the time of connection. The pipe fire extinguisher facilities are equipped with steel plates, small and large pipes are used, small pipes are provided with disaster prevention water transfer devices, And a nozzle gap 15 of a straight line with a bolt and a nat is provided at a length of 4 meters so as to be connected to a high pressure multi-stage high pressure pump 8 while checking the connection, and at the same time, At the same time, while preparing the ejection, prepare a 20-nozzle performance test on the roof tanks, pressure tanks and water supply connection water connection pump fire extinguisher equipment, and at the same time arrange the gap (15) According to the installation height of the curtain water film, the length of the installation and the snowy winter when the weather condition deteriorates, a fire-fighting nozzle is provided so as not to freeze the road, To improve the quality of life in the work environment of the workplace and to eliminate the fog around the road surface, it is necessary to improve the safety of the vehicle driver by extending the field of view ahead of the road. And at the same time to protect the crops of farmers and vinyl house agricultural and industrial complex engaged in agriculture, to the water supply connection pump fire extinguisher equipment at the same time, and to prevent the breakage of the plastic house, At the same time, the water supply of the valley is provided, and at the same time, the disaster prevention water (17) of the 1 degree inclination angle (16) of the ridge line which provides the control role to the water supply connection pump extinguisher facility, (16) Dispose of the water by disposing the water around the disaster prevention pipe and around the disaster prevention pipe. In summer, On top of the lakeshore Resort area Cooling the heat on a hot day on a coastline A foggy area that covers the perimeter of the highway is equipped with a partitioned water column that provides the emission from multiple straight nozzle holes, At the same time, it is necessary to arrange traffic communication to eliminate the mist from the water pump connection pump fire extinguisher equipment, but also to prevent the loss of grain loss by arranging disaster prevention device to prevent the proximity of autumn grasshopper sparrow grasshopper to the fields at the same time. The maintenance of large buildings and the maintenance of the bridge management of the large scale steel structure, and at the same time, it is connected to the distribution shaft to the water supply connection pump pump fire extinguisher equipment, and to the wide area. The mixture of the ground water and the loess soil stored in the storage tank and the control dam is supplied to the pumping pump 304 of the control dam, The water control valve 409 is opened to discharge a large amount of the yellow loam mixture control water into the ocean to prevent the occurrence of the harmful tidal breeze and to prevent disaster prevention of the nuclear power generation facility 811 into the reactor main body 1 of the nuclear power plant It is preferable that the flood control process is constituted by the power transmitting portion 811d for transmitting the preventive adjustment power.

Referring to FIG. 6O, within the reactor main body 1 of a nuclear power plant having a dual structural block tank dust collector for treating nuclear waste according to the present invention, a disaster prevention preventive control section of the nuclear power generation facility 811 is installed within 1 second A three-stage stepped pump fire extinguisher that is configured to achieve initial evolution, and a fire extinguishing water collecting tank and an alternate manometer turn type level balance pipe nozzle disaster prevention preventive unit. (811) of the nuclear power plant (811) Distribution control of disaster control disaster prevention device Manometer turn type level balance pipe Straight configuration of the nozzle Road,

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant The flood control disaster prevention apparatus includes a plurality of nozzles connected to the distribution shaft and connected to the water pump 304 and the piping and the fire hose 9 while opening the valve 409 of the intake dam to store the water stored in the peak intake water dam 680, (10) are provided to make the connection of the flood control facilities across the lower crest ridge forests of the crest of the crest, so that the flood control can be overcome quickly. In the control unit for preparing the power production, Pump (304) At the same time as installing power to the machine room, the nuclear power plant (811) is equipped with nuclear reactors of nuclear power plants to prevent natural disasters such as forest fires, dust storms, heavy snow, extreme winds, typhoons, floods and droughts, The fire extinguishing water 7 constituting the adjustment shaft constituting the irrigation adjustment is made to flow into the introduction pipe 191 through the intake ports 269 of several head tanks 189 of the corner ridges, A spring type safety valve 473 is provided in front of the inside of the tank of the suction port 269 of the collecting tank 34 formed below the discharge port introduction pipe 191 of the tank 189, The check valve 453 is fully opened and closed by the flow velocity so that the pressure is rapidly increased to the inside of the collecting tank 34 in which the safety valve 473 is completely closed, Type check valve 453 is closed when the pressure rise 389 disappears at the same time, but the air pressure in the high-pressure ball tank 303 is lowered by the action 389, (7), When the pressure in front of the safety valve 473 is lowered, the safety valve 473 is opened by the force of the spring 186 and the fire water 7 flows into the introduction pipe 191 again. And a plurality of water hammer pumps 393 of stepped ridges 389 of the water hammer action 389 while at the same time providing the lug 21 and the connecting shafts 382 on the sides of the deck deck side of the floating hydro- (198) and the boom zone, it is composed of the position movement control devices on the regulating shaft to the inside of the nuclear reactor main body (1) of the nuclear power plant, and the displacement control of the marine hydroelectric power plant floating posture (593,594,595) And a power transmission unit 811d that transmits disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant. Is recommended.

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant The disaster control and disaster prevention apparatus includes a disaster prevention nozzle 9, a multi-stage multi-stage pump 8, a high performance underwater pump 36, a disaster prevention pipe 14, and a portable wireless communication terminal 82 of a multi- A switch button 66 for operating a high-pressure multi-stage pump for spraying fire water according to weather forecasts, a multi-stage pump control board 53, The power source 46 is installed inside the stage multi-stage pump control box 2, and at the same time, the flood control and disaster prevention device in which the flood control process is formed is connected to the power source line 80 by the inverter 47, (62) After the power cable (80) is installed by the brake (61) for overcurrent breaker, it is provided on the inside of the control room and the machine room by the on / off control switch button of each pump and in close cooperation with the crew to the transportation equipment (73) A multi-stage pump is provided in which a piston operation is provided by a high pressure isolating isolation valve 5, a check valve 6 and an emergency valve 84, and a high pressure isolating valve 5, And the check valve 6 for the check valve for check is used as a reciprocating pump, the plunger pump 148 can be used safely in the nuclear reactor main body 1 of the nuclear power plant to prevent disaster prevention control power of the nuclear power generation facility 811 It is preferable that the flood control process is constituted by the power transmission portion 811d that delivers the water.

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant The disaster prevention nozzle of the flood control disaster prevention device is constructed so that the disaster prevention nozzle can be separated and joined to the fire prevention nozzle frame 11 and the lower support frame fire nozzle frame 11 and the vertical support fire prevention nozzle frame 11 And the injection nozzle claws 13 and the hook hooks 18 and the hook hook claw firefighting nozzle frame 11 and the hook hook hooking claw hole 20 are provided to protect the injection nozzle and the nozzle hose The wire rope 19 and the wire rope knot hooking hole 20 to the disaster prevention nozzle are used for protecting the fire-fighting nozzle by attaching the injection nozzle and the nozzle hose to each other, and the hooking lug 21 and the hooking lug The processing hole 20 or the connection hooking safety pin shackle 23 is provided with an injection nozzle and a nozzle hose disassembly coupling and is connected to the evapotranspiration tool coupling body 30 and the evacuation equipment coupling coupling 29, A paraffin stopper for a fire occurrence detection sensor replaces the packing 32 as a nozzle gap after the coupling body 31 of the disaster prevention equipment coupling male thread body 31 is manufactured and provided and the coupling rubber packing 32 is provided at an intermediate portion inside the female thread If the fire extinguishing system is replaced with a new fire extinguishing system in order to suppress the fire and flame in the event of a fire, it will not damage the environment at least for a small fee And a power transmitting portion 811d for transmitting the power of the flood control equipment to the inside of the reactor installation main body 1 of the nuclear power plant to be guided in the direction The.

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant The flood control disaster prevention device is connected to the distribution shaft inside the reactor facility main body 1 of the nuclear power plant so that the water stored in the acid intake water dam 680 is discharged to the water pump 304 and the pipe And a plurality of nozzles 10 connected to the fire hose 9 are provided so that the flood control facilities are connected to the entire lower crest line of the crest of the crest of the crest, The nuclear power generation facility unit 811 receives power from the power transmission control unit and supplies power to the power pump 304. At the same time, (1) of the reactor plant of the nuclear power plant, which provides the flood control facility to prevent the natural disaster of a number of natural disasters, The multi-stage pump control box (2) of the high pressure inside the machine room is connected to the detection sensor (104) for providing the fire water quantity check on the inner wall surface of the inner wall at the low water level, The pump operation is stopped and the disaster prevention water reaches a predetermined water level. In the fire water level detection sensor device, a ball tap (499) in the form of a circle is attached to the sensing cord (41) by a small thin wire serving as a lever, And when the ball tab 499 is moved downward, the pump operates. When the position of the ball tab 499 is fixed horizontally, the operation of the pump is stopped. The tabs 499 are provided with a coupling with the sensing rope 41 and at the same time the sensing distance of the sensing rope 41 is set at 90 ° or 120 ° and at the same time the high acid low acid collecting tank is made into a double- The water inside the collecting tank (34) is opened and closed by an air compressor (80) which can be adjusted before and after the disaster, so that the fire can be easily evacuated within one second And the power transmission unit 811d for transmitting the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant.

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant In the disaster control disaster prevention apparatus, the air hose which is thinner and smaller than the disaster prevention hose (9) is disposed inside the disaster prevention hose (9) of the level system applied to the previous industrial site, (1) inside the nuclear reactor plant (1) while being connected to the motors of the elevator speed reducer (251) and the collecting tank (34) provided on the roof of a number of mountain tops and a large number of large buildings, It is preferable that the flood control step is constituted by the power transmission unit 811d that transmits the disaster prevention preventive adjustment power of the nuclear power generation facility unit 811 to the power transmission unit 811d.

As shown in FIG. 6O, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention device, there are provided the disaster prevention material CO2 (174) in the industrial safety control room and the inside of the machine room, which are equipped with carbon dioxide and halon gas inside the pipe nozzle moving type fire sensor pump, And a mixer for mixing the natural loess with the disaster prevention water using the natural loess and the loess powder 158 while the carbon dioxide 174, the halon gas 175 and the natural loess 158 are mixed with the disaster prevention water, The natural loess (158) is the present reality that is used as a ship and helicopter relief equipment by the helicopter, Is a phenomenon that it can not prevent the work from being caught by the boiler, and it prevents the disaster from being disastrous. In this way, the power transmission unit (811d).

Referring to FIG. 6P, the prevention of firefighting of the nuclear power plant 811 of the nuclear power plant 811 can be easily performed inside the nuclear reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment according to the present invention. The hydrostatic power of the nuclear power plant 811 showing the construction of the embodiment showing the disaster-controlled disaster prevention device of the carbon dioxide gas fire extinguisher for preventing the disaster of the carbon dioxide gas fire extinguisher by the installation of the pipe nozzle collecting tank of the step- Power generation facility Disaster control Disaster prevention device Dispensing device Side configuration aspect Road,

As shown in FIG. 6p, the power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility 811 to the inside of the nuclear reactor facility main body 1 of the nuclear power plant includes a flood control disaster prevention device The water stored in the peak intake water dam 680 is connected to the distribution shaft inside the reactor installation main body 1 of the nuclear power plant while the water intake pump 304 and the piping and the fire hose 9 is provided with a plurality of nozzles 10 connected to the water supply pump 304 to provide the connection of the flood control facility to the entire ridge line of the lower crest of the crest, At the same time, the Nuclear Power Generation Facilities (811) have nuclear power plants that provide flood control facilities to prevent natural disasters such as forest fires, snow, heavy snow, extreme weather, typhoons, floods, The fire extinguishing water 7 constituting the control shaft is introduced into the power transmission unit 811d that transmits the flood control equipment power of the nuclear power generation facility unit 811 configured to perform flood control to the interior of the reactor facility main body 1 The water is sent to the pipe 191 and stored in the intake ports 269 of several head tanks 189 of the ridge lines and then the fire water 7 is supplied to the tank 189 through the collecting tank The spring type safety valve 473 in the front of the tank in the suction port 269 of the control valve 34 is completely closed by the flow velocity and the pressure rises suddenly into the collecting tank 34 in which the safety valve 473 is completely closed The lift type check valve 453 is opened so that the fire water is pumped out by the pressure and simultaneously the pumping water is pumped by the water hammer action 389 so that the pumping water can be pumped up to about 50 times of the drop. The valve 453 is closed, The safety valve 473 is opened by the force of the spring 186 when the pressure in front of the safety valve 473 provided for pumping the fire water 7 by the air pressure inside the ball tank 303 is lowered and then the fire water 7 Is introduced into the inlet pipe 191 and repeatedly operated as described above to continuously supply the positive water while being constructed of several water hammer pumps 393 in the stepped ridge line of the water hammer action 389. At the same time, A plurality of deck decks on the side of the deck side are provided with lug 21 and rotary shaft 198 and boom rods arranged in the reactor main body 1 of the nuclear power plant to adjust the position of the regulating shafts to the marine hydro- 593, 594, and 595) is configured to constitute propulsion of the hydroelectric power generation device.

Referring to FIG. 6q, the nuclear reactor main body 1 of a nuclear power plant having a double structural block tank dust collector for nuclear waste treatment according to the present invention is installed in the nuclear reactor main body 1 by means of a non- A method of supplying a double vinyl tent nozzle type fire prevention water within a time of less than one second to anyone who can easily fire A fire early and to prevent a disaster by installing a hurricane annihilation device is disclosed in U.S. Pat. (A) Firefighting, which includes the power generation facilities of the nuclear power plant of the power generation facility (811)

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a double-tinted tent (43) facility composed of flood control facilities inside the reactor facility main body (1) of a nuclear power plant has a sensing strap (41) (42) for storing the disaster prevention material, a tent tent and the plastic pack (43) of the double structure structure, and the disaster prevention material are stored in a basket plastic bag of a predetermined size, and then the upper part of the site containing the disaster prevention material Flange joint area that is provided by connecting with sensing wire and equipped with fixed distance from outside wall to inside of building and outer wall of land structure. And a sensing wire is connected to an electronic control sensing sensor for providing a position on the upper side of a displacement type control valve for providing an electronic control sensing sensor provided at a unit, and at the same time, a sensing wire is connected to a corner of a plurality of double vinyl tents 43 However, the tent fastening frame may be fixed to the tent fastening frame so as to fix the tether 41 at eight to four places, or the tent fastening frame may be fixed to the tent fastening frame. Alternatively, (295) and fire hose (9), which are located at the top of the mountain, are used for preventing natural disasters such as forest fires, snow, snow, heavy rain, typhoons, floods, droughts and landslides. It is preferable that the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 is connected to the flood control disaster prevention apparatus having the flood control process formed therein.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention system, fire trucks are dispatched after the previous fire, so fire fighting water and firearms are purchased by firefighters dedicated to fire trucks. The fire suppression in this way is sprayed on the firefighting house However, in the reactor plant main body 1 of the nuclear power plant according to the present invention, a flood control process for regulating the flow rate of the flue was provided to the distribution input device 811 of the flushing control facility. The equipment to the flood control disaster prevention device that was designed to be distinguished from the conventional technology is used in the standard fire prevention specification The nozzle body (B) is provided with a standardized standard so that the nozzle body (B) is composed of a basic type 1 and a basic type 2, while the installation is provided at the top and bottom of the mountain, and at the same time, The prevention of natural disasters such as forest fires, yellow dust, heavy snow, heavy snow, typhoons, floods, droughts and landslides in the plastic pack 43, the water tank 295 and the fire hose 9, And a power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the reactor facility body 1 of the nuclear power plant 811. [

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention device, the initial ignition source material that formed the flood control process was ignition caused by firebug such as lights park, match fire and candle, friction of flint between falling rocks, Fire after burning into a pillar of fire, leading to a large fire due to the generation of ash fire material. At the same time, a large fire is a public building of a building in a mall, a wooden building, and a fire suppression within the range of a fire belonging to the type of fire. It is a flood control disaster prevention system that does not spread fire and pillar and does not cause human injury. It is necessary to provide a precise setting of the full closing position of a plurality of multiple nozzle nozzles, to assure initial evolution, to provide installation at the top and bottom of the mountain while ensuring the lifesaving structure, and at the same time, (43), a tank tank (295) and a fire hose (9), which are located at the top of a mountain, are used for prevention of natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods, droughts and landslides. It is preferable that the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the facility body 1 is connected to the flood control disaster prevention apparatus in which the flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant Disaster-controlled disaster prevention systems include fire-control facilities, fire-fighting systems, fire-fighting systems, fire-fighting equipment, fire-fighting fire, high mountains, It is the case that the burning of the leaves is enlarged. The enclosure inside the building is equipped with the countermeasures in case of fire, and at the same time the fire prevention is the best way. Combined with fire water in the field, it is possible to enclose the combustible with incombustible gas in less than 1 second, Fire fighting and disaster prevention measures were prepared immediately before fire engine and fire helicopter were dispatched while providing the same loam painting as putting 8 layers of mixture of loess mixture on the object by sucking choking action and water, It is installed at the top of the mountain and at the same time while providing the life structure at a constant interval of 50 m where the swamp composition is formed. At the same time, the vinyl pack (43) which is easy to move, the tank tank (295) Dust, landslide, flood, drought, landslide, etc. The prevention of natural disasters can be prevented by installing a power transmission unit (not shown) for transmitting the flood control equipment power of the nuclear power generation facility 811 to the reactor main body 1 of the nuclear power plant 811d) is connected to a flood control disaster prevention device in which a flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the disaster control disaster prevention device, a variety of pipe nozzle holes are provided in a plurality of mountains, buildings, and the outside in general, in the disaster prevention fire fighting equipment which is mobilized by the ignition source providing material and the substance for suppressing ignition, A paraffin-sensor type pipe with dual sensors for passive disaster prevention and active flood control is installed at the location where a large number of pipe holes are formed with a paraffin stopper. The fire extinguisher hose 9 and the fire extinguisher hose 9 are provided with a fire extinguisher, The power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility body 1 of the nuclear power plant in order to prevent a plurality of natural disasters such as heavy snow, extreme weather, typhoon, flood, And a flood control disaster prevention device in which a flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention system, the ignition material of the first fire site and the disaster prevention material are maintained in close relation with each other, and communication equipment of the Internet control system before and after the fire, multi-stage multi-stage pump, The equipment including air compressor, air storage tank, wire rope and fire cable car body, fire fighting disaster prevention equipments and facilities including airship are mixed with gas, liquid and solid disaster prevention material, Previously, a solid nozzle nozzle was used to keep the liquid in the event of a fire, It is a crevice nozzle composed of a gap and a straight gap in the form of a partition, and the fire water is separated into a plurality of radial curtain water films and a plurality of linear straight curtain water films. In addition, It evolved within one second from large-scale forest fires and large fires caused by a number of disasters that made the body and life free from matter, and set up a rescue system in order to prevent floods and droughts. It is composed of flood control facilities to thoroughly prevent the disasters and to prevent the disasters of many disasters. In addition to the measures to stabilize the crisis, Equipment for manufacturing, installation and lifesaving equipment It is installed in mountains and buildings with firepipe nozzle nozzle stopper installed in fire-prevention disaster nozzle. It is equipped with fire-prevention nozzle to prevent disasters in case of other disasters. The nuclear waste treatment dual structure block tank marine tunnel transport device 941 of the train 771 and the nuclear reactor facility of the nuclear power plant are connected to the inside of the double structure block tank 598 constructed under the barge hull 591 while the device is installed in the ocean. A fire extinguisher (not shown) is installed in the top and bottom of the mountain while a fire type fire extinguishing equipment is provided in the inside of the main body 1, and at the same time, a vinyl pack 43, a water tank tank 295, Nuclear power plants' nuclear reactor facilities (1), which provide advance protection against natural disasters, such as forest fires, dust storms, snow storms, typhoons, floods, droughts and landslides, And a power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility unit 811 to the inside thereof.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a pipe-nozzle type fire-fighting sensor pump of a non-emergency fire prevention disaster prevention product for a marine power plant in which a flood control process for controlling the flow of the flow is formed in the main body (1) A motor having a rotating impeller, a guide vane pump and a piston attached to both outer sides of the impeller, and a prime mover separably assembled with the turbine, at a central portion circumferential surface portion of a rotating shaft which is a motor center axis formed on the horizontal center line MBCL of the motor body. The pump and the pump body are equipped with an isolation valve, check valve, fluid pressure and flow control and flow direction control with electronic controls A flow control sensor and a pressure sensor, a gas switch, a sensor switch for establishing flow interrupts in the piping, a power line for supplying power energy, and a fire suppression material, fire retardant, Gas, and carbon dioxide High-pressure tanks for storage of non-flammable gases in HALON gas, clean-up tanks and tank tanks, sealed and open-to-flow type vinyl packs, And a fire tank (295) and a fire hose (9), which are located at the top of the mountain, and which are easy to move, and at the same time, a dictionary of natural disasters such as fire, drought, snow, heavy snow, typhoon, flood and drought, (811d) that transfers the power of the flood control facility of the nuclear power generation facility unit (811) to the inside of the reactor facility main body (1) of the nuclear power plant It is preferable that the disinfection-controlled disaster prevention device is connected.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility unit 811 to the inside of the nuclear reactor facility main body 1 of the nuclear power plant is provided with fire fighting, Drought and landslide The movable pipe nozzle which formed the flood control process to prevent many natural disasters is divided into the basic 1 type and the basic 2 type according to the standard type fire hose standard and the flange connection is made by the fire pipe nozzle and the coupling joint The fire pipe nozzles are connected to the fire-fighting cable car, and the movable pipe nozzle has a constant inclination angle of the ridge line at the lower end of the ground surface (GLL) It is fixed at a distance of 50m in the same distance as the new one. It has a high and low mountain and a crest of the crest of the ground at the bottom of the ground and a high and low building near the beach. The steel tower is assembled by assembling the steel tower, then fixing the steel tower with an anchor bolt by a hand tool, and simultaneously installing a wire rope and a plurality of driving wheel rollers and a furnace on the steel tower of the flood control disaster prevention apparatus, While simultaneously installing the fire extinguishing material conveying device mounted on the top of the mountain and the rooftop of the building while providing a connection to the fire hose connecting portion of the fire extinguishing material conveying device mounted on the fire fighting cable car, At the same time as installing the mobile firefighter nozzle, the power plant generator and the engine The motor power generated from the generator is passed through a power supply line of a transformer connected to a plurality of electric wires and a power supply line of a main pole, and then the pump motors are connected to the impellers and the pistons A flue gas mixture which has plunger pumps to provide countercurrent flow of the flushing water to the top of the high acid, a generator of the power plant, and a loess mixture which provides countercurrent flow of the flushing water to the top of the acid without power supply from the engine generator In the early days of the fire, the fire and flame in the wood, forest, and paper, which are ordinary fires of buildings belonging to a large number of fire types, can be evacuated in less than one second. At the same time as providing installation in the lower part, Prevention of a large number of natural disasters by the water tank 295 and the fire hose 9 which provide a position in the reactor main body 1 of the nuclear power plant can be prevented by using the fire prevention hose 9, And a power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 to the flood control disaster prevention device formed with the flood control process.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, the power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility 811 is provided with a fire prevention function for prevention of natural disasters such as forest fires, dust storms, heavy snow, extreme storms, floods, droughts and landslides Fire sensor pump composed of flood control facility Double pipe hose formed by collecting tank and pressure tank in a lot of fire fighting and fire hydrant and electromagnetic heat sensor and flow control equipped with air compressor in piping nozzle installed in fire fighting piping line Valve and manmade level hose, fire-fighting nozzle and fire detection sensor, paraffin nozzle stopper, discharge flushing water, And the combustion action is prevented by providing a cutoff of the air supply to surround the combustible material and the cooling action to lower the temperature of the combustible material to a temperature below the ignition point to prepare a jet to the gap between the processing hose of the fire hose pipe and the muddy water In the above-mentioned cooling action fire-fighting apparatus, a rescue refuge is provided to the fire-fighting cable car security area in the early stage of the fire and the relief is carried to the basket below the airship, and the adve- lon and the airship disperse the object load of the fire- To provide a safety guarantee of the pump body and to provide the life structure and early evolution from large-sized forest fires and large-scale fires in sequence. However, at the same time, a plurality of non-powered pumps, a tank tank, a collecting tank, an electronic sensor valve, Establishment of a fire-fighting nozzle and a fire-fighting piping line in the top of the mountain Firewood, snow, heavy snow, heavy snow, typhoon, flood, drought, landslide Prevention of a number of natural disasters with a simple plastic bag 43, a water tank 295 and a fire hose 9, To the nuclear reactor facility main body 1 of the nuclear power plant by the power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility unit 811 to the flood control disaster prevention apparatus formed with the flood control process.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, the power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility 811 is provided with a fire prevention function for prevention of natural disasters such as forest fires, dust storms, heavy snow, extreme storms, floods, droughts and landslides Fire-fighting sensor pump provided by flood control facility Fire-fighting and fire-fighting measures equipment of marine power plant provided with many fire-fighting and fire hydrants, collecting tank and pressure tanks The hose (9 And the body of the pipe 14 is provided with a distance of 300 mm between the injection nozzle gap 15 and the hole 10 of the processing hole 20 of the nozzle 10 so that the bolt 24 and the nut 25 and the washer 26), a plurality of 8 nozzle clearance At the same time, the piping body of the piping body is provided with a plurality of processing holes 20 each having a diameter of 5 mm or less along the circumference of the cylindrical pipe, and the total machining hole clearance is 498 positions in the spray nozzle body The upper end portion A of the injection nozzle body is provided with a plurality of flanges 28 attached to the body of the pipe 14 with eight machining holes at a constant inclination angle of 45 degrees A flange 28 is provided with a plug reinforcement steel plate 165 on the upper end of the piping body upper part A and a flange and an injection nozzle 10 are formed on the upper end part A of the flange 28 with a plug- The reinforcing steel plate 165 in the center position of the stopper cap 165 through which oxygen, carbon dioxide 164, halon gas 175, helium 176, fuel 131 and fire water 7 pass under the flange of the lower end of the body A The body of the coupling 29 has a small (i. E. &Lt; RTI ID = 0.0 &gt; A through hole 20 in which a water pipe 89 of a fire hose and a wire rope 19 are formed is provided with a 7-piece single pipe which is disassembled and assembled by a hand tool monkey spanner, The device was standardized with a total length of 2100 mm in the apparatus, and provided with the above-mentioned disaster prevention material connected to the nozzle, while being installed in the top and bottom of the mountain and simultaneously moving the plastic pack 43 and the water tank tank Prevention of a number of natural disasters by the firefighting (295) and firefighting (9) of the nuclear power plant into the nuclear reactor facility main body (1) of the nuclear power plant, And a power transmission unit 811d that transmits the flood control facility power of the flood control facility to the flood control disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, the power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility 811 is provided with a fire prevention function for prevention of natural disasters such as forest fires, dust storms, heavy snow, extreme storms, floods, droughts and landslides In the non-disaster marine hydroelectric power plant constructed by the flood control facility, a number of fire-fighting and disaster prevention measure hoses 9 and fire pipe nozzles 10 provided in the body of the pipe 14, The high and low mountains (395) of the paraffin tape for the sensor (177) and the nozzle stopper (100) for connecting the paraffin pipe joint nozzle are connected to the ridge line of the high and low building near the bathing beach (333) (19) to (256) of fire-fighting cable cars (256) equipped with fire-fighting equipment and fire-prevention sensor pump of nozzle-type movable fire-fighting countermeasure goods are installed. At the same time, ) In the past, when a fire occurred in the general combustible materials of paper and futon, the helicopter and the fire truck of the fire truck started to fire with the siren sounding. At this time, the obstacle of the road car and the fire helicopter The fire that was turned off at the moment of going to carry the fire water is revived again, and the digestion activity of the fire scene for the reason and the reason is delayed by one second as for the fire scene, the risk of losing life to the urgent and urgent situation In order to solve the problem, A fire extinguishing countermeasure product non-hazardous fire fighting countermeasure product, a fire extinguishing sensor pump installed at the top and bottom of the mountain while simultaneously providing a plastic bag 43 for easy movement, a water tank 295 for providing a position on the mountain top, The prevention of natural disasters such as forest fires, yellow dust, heavy snow, hurricanes, typhoons, floods, droughts and landslides is prevented by the hose (9) inside the nuclear reactor main body (1) of the nuclear power plant, And a power transmission unit 811d that transmits the power to the flood control and disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention system includes a hose 9 of a sensor pump in which a flood control process is provided to prevent floods, drought, heavy snow, heavy rain, typhoon, flood, drought, A plurality of the non-hazardous paraffin nozzle plugs 100 formed in the drum 10, and a fire heat detection sensor paraffin having the double pipe nozzle gap holes sealed by the paraffin tape 177 are melted, And burning fire and flame on the ignition object are not easily diffused to large fire due to the detection of low temperature of the candle, and the human life is saved, but at the same time, The fire sensor pump of the fire extinguisher 124e is a fire extinguishing material of the fire extinguisher 124b and the foam fire extinguisher 124e which are adapted to the fire A fire which does not burn easily within 1 second The incombustible gas surrounds the combustible material and provides the air (oxygen) interception to prevent the combustion, and the cooling effect to lower the temperature of the combustible material to the temperature below the ignition point. The fire extinguisher (7) and the fire extinguisher (7) were installed in the pipe-type fire extinguishers (124) of the non-disaster fire prevention and disinfection countermeasure goods by assuring the lifesaving and the early evolution from the large- The yellow mortar 158 and the arsonist 159 are introduced into the collection tank 34 by the mixer 73 while the membrane pump 144 and the compressor 80 and the internal cooler 170 are simultaneously introduced into the collection tank 34. [ A fire tank, a water tanks tank 295 and a fire hose 9, which are located at the top of the mountain and at the bottom of the mountain, Floods, droughts and landslides. In order to prevent the natural disasters from occurring, a power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility 811 to the nuclear reactor main body 1 of the nuclear power plant It is preferable to be connected to the disaster control disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention apparatus includes a flood control disaster prevention apparatus in which a flood control process is performed by a power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, , Dust storms, storms, typhoons, floods, droughts, landslides. In order to prevent the natural disasters from happening many times, Prevention and rotation disaster prevention waterway, reservoir water reservoir installed in the valley, prevention of forest fires, forest fires and eco-environment restoration in the dam, and measures to be provided in the shelter and the route to prepare the disaster preparedness of the sailing vessel The water supply tank 295 and the fire hose 9 are installed at the top and bottom of the mountain while providing the flow control of the water supply facilities according to the evacuation facility of the water supply system, (1) of the nuclear power plant to prevent the natural disasters of a number of natural disasters from being transmitted to the power plant (1) of the nuclear power plant (811) The present invention can be applied to a flood control and disaster prevention system in which a flood control process is formed by a transfer unit 811d, Is a remarkable difference.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention device, there are provided a plurality of pump shuttle spiral casing (310) inside the fire sensor pump for preventing a plurality of natural disasters such as forest fires, sandstorms, heavy snow, extreme storms, floods, droughts, landslides, The impeller 143 provided with a predetermined amount of disaster prevention material to be introduced into the intake port is connected to a rotary shaft 198 that is a rotation center of the electric motor and is rotated to compress the water pressure of the incoming fire water 7 A plurality of fire-fighting disaster prevention piping lines 168 of a predetermined quantity of fire fighting water 7 transfer device, a head tank 189 on the left and right side of the field machine room internal pump, disaster prevention waterways 17 A double-structure collecting tank 34 for providing a forward arrangement at constant intervals with a constant inclination angle 16 of the disaster prevention water passage 17 and a double-structure collecting tank 34 for collecting the fire water from the collecting tank 34 The detection sensor ball tab 499 and the flushing water inlet port 269 for blocking foreign matter from entering the collecting tank 34 are opened at the time of the switch button turn-on and the flange stop wire mesh 28 for the plug filter. A tee elbow 44 and a coupling ring 29 of the binding apparatus in which the disaster prevention material carbon dioxide 164 and halon gas 175 are introduced at the rear of the head tank 189, A low pressure shut-off valve 83 for shutting off the supply of water to the rear end of the disaster prevention pipe 14, a mixer 73 for mixing the disaster prevention material carbon dioxide 164 and the natural loess soil 158, (106) is a high-pressure inlet The multistage pump 8 is operated and at the same time the flushing water is connected to the piping continuous tee elbow 44, the radyer 35 and the flange 28 and simultaneously passes through the disaster prevention pipe 14 and is connected to the nozzle hose 9 A plurality of gaps 15 around a pipe circumference and a gap 15 between the processing hole 20 and a plurality of flange 28 junctions constitute the connection structure of the flushing control device control section, A first pressure check sensor 86 installed in front of the isolation valve 5 and a second pressure check sensor 87 installed integrally with the decompression valve are provided in front of the isolation valve 5, And an emergency valve (84) provided in the bypass disruption pipe line (168) so as to open and close the isolation valve (5) opposite to the isolation valve (5) The pressure value from the sensor 86 and the second pressure check sensor 87 And an electronic control unit (88) for controlling the operation of the emergency valve (84) is provided. A vinyl bag (43), which is installed at the top of the mountain and the lower part of the mountain, ) And firefighting hose (9) to prevent natural disasters such as forest fires, sandstorms, heavy snow, extreme weather, typhoons, floods, droughts and landslides into the reactor main body (1) It is preferable that the power transmission unit 811d is connected to a flood control disaster prevention device in which a flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a flood control disaster prevention apparatus, in which a flood control process is formed by a power transmission unit 811d for transmitting disaster control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant, The airbag 77 of the upper part of the outdoor building is lifted up to the upper end of the surface of the ground so that air is stored in the air tube 130 of a plurality of container sizes and at the same time, After confirming the boarding structure with disaster relief workers and refugees, it is possible to overcome the crisis situation calmly, It is installed in mountains and buildings with a paraffin sensor nozzle stopper (100) installed in the firefighter nozzle by the facilities manufacturing and installation method and lifesaving equipment. It is used for fire prevention purpose. In case of other disasters, And an air piping line 181 having a longer water piping line and an extension in the hydrant 179 are provided with a fire cable car 256 and a pump fire extinguisher 124 integrally with the respective pumps and the respective valves integrally with the detection sensor switches A fire tank (295) and a fire hose (9), which are located at the top of the mountain and at the same time as the firepipe (43) , Dust storms, storms, typhoons, floods, droughts and landslides. Prevention of a number of natural disasters can be prevented by controlling the flood control of the nuclear power plant (811) inside the nuclear reactor main body (1) Connected to the power transmission unit (811d) for transmitting power to non-emergency flood control device is formed flood control process configured are preferred.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention apparatus includes a flood control disaster prevention apparatus in which a flood control process is performed by a power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, , Dust storms, hurricanes, typhoons, floods, droughts and landslides. In order to prevent various natural disasters, the pump which is composed of flood control system is installed in the roof of a large building. A reduction gear 251 to various motors and a wire 192 to a wire rope 19 of a trolley winch 137 are operated when the upper and lower ends of the building are pressed by a switch button, The diaphragm pump 144 is connected to the loess soil 158 and the arsonist 159 which enable the disaster prevention water line 7 in the line of the disaster prevention piping line 168 to be extinguished all the day and night with the equipment inside the pump extinguisher body, At the same time, it is installed in the summit and subordinate areas while providing input to the fire-fighting activities in the roads and roads of the Rhodos Mountains and the roads. At the same time, the plastic packs 43 that are easy to move, the tank tanks 295 and the fire hoses 9, Dust, landslide, flood, drought, landslide, etc. The prevention of natural disasters can be prevented by installing a power transmission unit (not shown) for transmitting the flood control equipment power of the nuclear power generation facility 811 to the reactor main body 1 of the nuclear power plant 811d) is connected to a flood control disaster prevention device in which a flood control process is formed.

 As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention apparatus includes a flood control disaster prevention apparatus in which a flood control process is performed by a power transmission unit 811d that transmits disaster control facility power of the nuclear power generation facility unit 811 to the nuclear reactor facility main body 1 of the nuclear power plant And a power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the nuclear reactor facility main body 1 of the nuclear power plant includes a flood control and disaster prevention apparatus including a forest fire, , The desert, typhoon, flood, drought, landslide The diehlum pump (144) facility which constitutes the flood control process composed of the flood control facility which prevents the prevention of the natural disaster in large numbers, At the same time, it is equipped with suction and discharge with the rubber membrane and the Teflon membrane (538) provided to the diaphragm pump (144) facility by the up and down operation, and at the same time, the diaphragm pump A crank 248 and a link belt 249 are formed on the rubber film 538 at the upper end thereof so as not to be easily worn or closed with a fluid containing sludge particles, And the fire tank (295) and the fire hose (9), which are located at the top of the mountain and at the top of the mountain, Landslide A plurality of natural disasters are prevented from being transmitted to a power transmission unit 811d for transmitting the power of the flood control facility of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant, It is preferable that the connection is made by a disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a Centurion Pouillage pump 308, in which a flood control process for preventing natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoon, flood, A guide vane 142 is provided on the impeller 143 in the body of the Century Puyugel pump 308 for providing the rotary shaft 198 and the impeller 143 inside the casing 141, The chiller 391 facility of the mechanical seal provided with the mechanical seal seal 156 of the shaft seal device, the partition wall 372 and the balance holes 376 is provided on the circumference of the rotating shaft 198, The axial rod portion 390 is provided, and at the same time, The control box of the board 53 is provided with the function of the three-stage multi-stage pump control board 53 while the flow rate check flow meter 105 and the overpressure prevention switch 108 are connected to the stop valve 114 A pipeline line sensor formed by a tee elbow 44 is provided in the line pipe 168 of the water tank tank 168 and the water tank tank 295 which is located at the top of the mountain and in the lower part of the mountain, Firefighting (9) prevents the prevention of natural disasters such as forest fires, sandstorms, heavy snow, extreme weather, typhoons, floods, droughts and landslides into the reactor main body (1) of the nuclear power plant. It is preferable that the power transmission unit 811d is connected to the flood control disaster prevention device in which a flood control process is formed.

As shown in FIG. 6q, preferably, the power transmission unit 811d for providing power transmission of the flood control equipment of the nuclear power generation facility 811 to the inside of the reactor facility main body 1 of the nuclear power plant, The flood control disaster prevention system includes a multi-stage multi-stage pump and a pressure tank 189 of a control system, in which a flood control process is provided to prevent a large number of natural disasters such as forest fires, sandstorms, heavy snow, extreme storms, floods, droughts, The line equipments connected to the control unit inverter 47 and the collecting tank 34 are connected to the collecting tank 34 and the control unit inverter 47 while at the same time, 271 and the check valves of the respective pumps are provided so as to be able to control the closing and opening of the valves in the inverter 47 and then the respective multi-stage pumps 8 at the front end of the check valve 6 and the valves 5 Installed in front of valve (5) The pressure tank 189 and the control unit inverter 47 are connected to the line equipment connected to the line of the discharge confluent line 4 by a first pressure check sensor 86 and a second pressure check sensor 87, And the overpressure prevention switch 108 while controlling a certain amount of fire pressure of the fire while a plurality of fire nozzles 10 serving as the ejection nozzles 270 are controlled by a mixer 73 to provide a cooling action and a choking effect within a second within one second, And the flood control devices for providing fire prevention in the neighborhood living area of the residential area and the fire fighting control devices for the nuclear power plant, The installation of the fire fight cable car 256, in which the flushing control process is formed inside the facility body 1, includes a plurality of fire hoses (9), each of which is connected to each of a plurality of buildings having high and low mountain peaks and difference in height ) (9), which is a safety net (401), which is a mesh hose, which is a mesh hose that includes a crisscross type wire and a sperm wire rope, is installed in the mountain top and under the mountain, (295) and fire hose (9), which are located at the top of the mountain, are used for preventing natural disasters such as forest fires, snow, snow, heavy rain, typhoons, floods, droughts and landslides. It is preferable that the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 is connected to the flood control disaster prevention apparatus having the flood control process formed therein.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention system includes the flood drought warning and weather warning in accordance with the long-term weather forecast of the meteorological agency, the large-scale wildfire occurring in other seasons, and the loess that can be prepared to overcome natural disasters such as yellow dust, Mixing the mixture, the existing multifunctional dams and newly installed multi-purpose dams are equipped with a number of collecting tanks and double pipe structure block tanks on the circumference of the body in accordance with the seasonal temperature change, and the heating and insulation devices for freezing the water in the cage farm In addition to the dredging and stormwater rivers, the tidal flats have been installed in the vicinity of the shoreline, Preventive action before and after the harmful red tide of the ocean by spraying the loess mixture before the occurrence of the algae. It is possible to maximize the prevention of the disaster by spraying the loess mixture continuously on the beach without the ship. Lifting of the offshore and offshore ocean power plants. Nuclear reactor facilities of nuclear power plant Nuclear radiation leakage control of reactor facility of alternative nuclear waste treatment shielding system Installed in top and bottom of mountain and with provision of distributing device of dual structure block tank dust collector Difficulty of wildfires, yellow dust, snow, heavy snow, typhoons, floods, droughts, and landslides are prevented by the simple plastic packing 43, the tank tank 295 and the fire hose 9, A power transmission unit 811d for transmitting the power of the flood control equipment of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the power plant, The adapted connection control flood disaster prevention device is formed adjusting step is preferred.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant (593,594,595) of the offshore and offshore marine power plants that continuously develop the forest greening project in parallel with the flood control disaster prevention system. Nuclear reactors of the nuclear power plant (1) (2) Controlling the nuclear radiation leakage of the reactor facility of the shielding device The dual structure block tank dust collector is provided with a distributing and inputting device, and at the same time, the vinyl bag (43) which is easy to move, the water tank 295, , Dust storms, intense typhoons, floods, droughts, landslides Prevention of a number of natural disasters can be prevented by installing nuclear power plants The connection to the emergency flood control device is provided consisting of a flood control process flood conditioner power transmission unit (811d) for transmitting power of 811 is preferred.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention device is a spray nozzle piping connected to the upper part of the sea level of the typhoon occurrence area and the unspecified area of the expected occurrence area by the arrangement of the poles, and is formed by the falling spray shape of the triangular shape of the doctor ventilation and the radial discharge spraying Like the Rocky Mountains in the Andes Mountains on the land, the pipeline doctor lines, such as the spray nozzles for the prevention of high and low mountain fires, were created to provide a water mountain range equal to that of the Rocky Mountains and the Andes, The disaster prevention system is equipped with a simple plastic bag (43) and a water tank The prevention of natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods, droughts and landslides can be prevented by using the tank 295 and the fire hose 9 in the nuclear reactor main body 1 of the nuclear power plant, And a power transmission unit 811d that transmits the flood control facility power of the flood control facility to the flood control disaster prevention apparatus.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant Disaster Controlled Disaster Prevention Systems are equipped with spray nozzles, buoyant flag rubber balloons and air supply devices in the water of the sea floor to disrupt the typhoon, and at the same time, There is an artificial waterfall that alternates between the cave, the gong, the bell and the bamboo in every corner of the globe where the earth and the disaster area of the sea are located, while the dormant and the wind power and the non - The dispersion type is to replace the emission of water over the sea and over land by thunderstorm, With the passage of the intestines, the trumpet canals are routed over the sea surface in the piping crevices, so that they will roar with the wind and block the occurrence of a severe typhoon in advance. In the sky where cumulonimbus and stormy clouds stay, lightning rods are installed in the adver- At the same time, the radar control tower on the rooftop of the control tower of the mooring tower is provided with storage of the hull from the lightning strike and lightning, and at the same time, the easy plastic bag 43, the water tank 295, Dust, landslide, flood, drought, landslide, etc. The prevention of natural disasters can be prevented by installing a power transmission unit (not shown) for transmitting the flood control equipment power of the nuclear power generation facility 811 to the reactor main body 1 of the nuclear power plant 811d) is connected to a flood control disaster prevention device in which a flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention device, the number of discharge type of discharge line of the disaster prevention line that hides the typhoon inside the marine nuclear hydroelectric power plant and the vertical structure of the typhoon are dropped in the troposphere about 10 km above the sea level and dropped on the sea surface at the upper part of the SLD At the same time, the disaster prevention water is transferred from the top of the Arctic through the pipe line of the tube level type at the equatorial point, and at the same time, natural disaster prevention like the artificial waterfall The typhoon is the annual heat of the atomic bomb dropped in Hiroshima in the past, At the same time, the humanity of the global village is prepared to clean up the sadness and suffering from the disaster disaster. At the same time, the better environment of the global environment is improved and at the same time, the double structure high pressure hose High pressure hose connection The number of couplings with the number of couplings is less than 10km, and at the same time, the pipe level pipeline is constructed on the side of the flood control pedestrian side of the crane. The seismic crane boom of the crane is used to change the course of the typhoon in a 10- At the same time, it is also possible to provide a reduction in the damage of land typhoons, and at the same time, it is also possible to prepare the ejected yellow loess mixture from several nozzles which provide the position on the pipe level line at the same time, It consists of a safety connection structure inside the main body of the nuclear power plant. Is equipped with a construction machine and a flood control device to prevent natural disasters from occurring and to provide flood control and disaster prevention equipment while providing installation at the top of the mountain and at the same time as moving a simple plastic bag (43) The prevention of natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods, droughts and landslides can be prevented by using the tank 295 and the fire hose 9 in the nuclear reactor main body 1 of the nuclear power plant, And a power transmission unit 811d that transmits the flood control facility power of the flood control facility to the flood control disaster prevention apparatus.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention system, the number of injections that provide the jet into the gap of the injection nozzle into the nuclear hydroelectric power plant body is provided with a method of preventing natural disaster according to the nozzle type, And at the same time, the power of the wind is latched, the air compressor being operated by the electronic control unit and the first pressure check sensor by the pressure reducing valve and the safety valve without the electronic control unit A motor belt, a motor feeder, a belt cover, an air suction filter, and an after-cooler, which are provided together with the second pressure check sensor, The hose of the aft cooler is provided with a cooling water inlet and attached to the upper end of the chanel base of the bed frame. Air is produced by the injection nozzles to provide a rubber tube and a high pressure hose to supply a coupling with a high pressure hose connection. And the downward current is controlled with dust and fine dust, the upper and lower sides of the sea surface are provided with a substitute for 꽹, 징, 징, 과, and 종 for disaster prevention and control. At the same time, the roar of the artificial waterfall falls on the drop point It is possible to change the jetting water gap continuously to provide a different type. At the same time, it is possible to provide a fall without resting due to the same artificial waterfall rumble in the continuous type, but at the same time, At the same time, we set up a measure and, as a result, At the same time, at the radar weather observation center, there is installed an unmanned camera and weather observation equipment radiosonde and a weather observation radar inside the basket for the boarding of the bottom of the advertisement balloon, and at the same time, The water tank 295 and the fire hose 9, which are located at the top of the mountain and at the same time and which are easy to move, , Typhoon, flood, drought and landslide. The prevention of natural disasters is controlled by the power transmission unit (811d) which transfers the power of the flood control facility of the nuclear power generation facility (811) to the nuclear reactor main body (1) of the nuclear power plant. It is preferable that the process is connected to the disaster-controlled disaster prevention apparatus formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a power transmission unit (811d) facility for transmitting the flood control facility power of the nuclear power generation facility unit (811) to the inside of the reactor facility body (1) of the nuclear power plant includes a forest fire, a yellow storm, And droughts and landslides. A multi-stage pump with a flood control process consisting of a flood control facility that provides preventive measures against a number of natural disasters is described in the city code. Anyone can easily make a pumping without fire or close to the pump machine in case of a fire, and at the same time, According to the room, a fire-fighting helicopter is installed in the mountain top and under the mountain, while simultaneously preparing a flood control process to set up the initial evolution within one second before the arrival of the fire scene. At the same time, Prevention of a number of natural disasters by the firefighting (295) and firefighting (9) of the nuclear power plant into the nuclear reactor facility main body (1) of the nuclear power plant, And a power transmission unit 811d that transmits the flood control facility power of the flood control facility to the flood control disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The disinfection-controlled disaster prevention apparatus includes an isolation valve 5 which is opened and closed at the time of switch-on when a flood control process is formed, a regulator 136 which decompresses disaster prevention water to a constant pressure, The operation of the high pressure multi-stage pump 8 in which the disruption prevention carbon dioxide 164, the natural loess 158, the mixer mixer 73, and the power motor control module are connected is operated At the same time, the disaster prevention water is passed through the opening of the shutoff valve, and a water pressure is formed by a gap between a plurality of pipe holes 14 around the circumference of a plurality of pipes 14 connected to the nozzle hose 9 and a plurality of flange- The fire water is installed in the top and bottom portions of the mountain while providing a plurality of discharging water 38 in the form of a straight discharge spray 38 and a plurality of curtain water films 39 in the shape of a curtain water film 39. At the same time, Prevention of a number of natural disasters by the firefighting (295) and firefighting (9) of the nuclear power plant into the nuclear reactor facility main body (1) of the nuclear power plant, And a power transmission unit 811d that transmits the flood control facility power of the flood control facility to the flood control disaster prevention device.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The disaster control disaster prevention system includes a disaster prevention control process, a disaster prevention light beam 149 provided in the form of a damage reduction method in response to a typhoon and the occurrence of a landslide before the occurrence of an earthquake, The tugboat 130 and the lifeboat 188 provided with a lifting net (safety netting 401) and a lifting structure provided for the onshore vessel which is provided for preventing the sinking of the marine vessel from the storm waves generated at sea at the same time, A gas damper provided with a rescue basket 42, a combined life bed nozzle 172, an arsonist 159 and an air storage vinyl tube, (909) for collecting iron ore manganese nodule (909), which is provided as disaster control device that provides disaster prevention and improves future machine civilization, as well as a sand bag barrier which is equipped as a firefighter and a submarine pipeline line connecting the land and sea. (911) of the nets (910) and the pneumatic transportation equipment (916), the submarine mineral reac- tion robot (912), the yard basket and the search sensor for search equipment and underwater lights, 1), the upper and lower ends of the barge hull 591 of the marine hydroelectric power plant in which the flood control process is formed by the power transmission unit 811d for transmitting the flood control facility power of the nuclear power generation facility unit 811, A first pressure check sensor 86 provided in front of the isolation valve 5 and a second pressure check sensor 87 provided as a check valve 6 and the valve 5 on the basis of the isolation valve 5, Before and after The emergency valve 84 and the first pressure check sensor 86 which are provided to be opened and closed as opposed to the isolation valve 5 in the bypass line 168 and the bypass line 168, And an electronic control unit (88) for controlling the operation of the emergency valve (84) by checking the pressure value from the first pressure check sensor (86) and the pressure value from the second pressure check sensor (86) The prevention of natural disasters such as forest fires, sandstorms, heavy snow, heavy snow, typhoons, floods, droughts, and landslides in a large number of natural disasters with the plastic pack 43, the water tank 295 and the fire hose 9, It is preferable that the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the reactor facility body 1 is connected to the flood control disaster prevention apparatus in which the flood control process is formed.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The flood control disaster prevention apparatus includes a pipe hose at the rear end of a valve of an electronic control unit having a closed injection nozzle opened and a straight gap 15 and a round type gap 15 along the periphery of the pipe body B of the pipe line. (20) having a nozzle diameter of 5 mm to 10 mm, and a flange joint (8) with a clearance nozzle provided with a supply of disaster prevention material provided with liquid and gas, a spray nozzle and a fire hose (B) in which a nozzle connected to a hose provided inside the nozzle body (9) is provided with a bolt and nut separating coupling and the gap nozzle of the washer flange joint is adjusted, The jetting water 38 and the curtain water film 39 are provided in the gap 15 of the jetting nozzle 10 emitted by the disaster prevention material so that a plurality of pellets collapse at the same time (38) and the curtain water film (39), which simultaneously provide the water pressure for reserving the harmful tidal microorganism (921) distributed at the same time while providing the water repellency to the harmful tidal microorganisms (921) gathered at the same time, The unmanned camera (184), in which a vertical descending air current, which is a mass of air, is returned to the jet stream above the sea level 10 km, and the vertical descending air current is returned to the tidal wind so that the typhoon can not approach the land. ), And simultaneously displays the score on the monitor through the operation of the control server (51) of the control system (150) of the high-pressure air compressor (80) A hose 109 and an air nozzle 923 are provided together with the air compressor 80 and the cooling device and at the same time are connected to the distribution shaft to the flood control disaster prevention device, When the occurrence warning is issued, the ample water pump 304 provided in the reservoir dam and the ground water and the loess mixture stored in the reservoir tank controls the opening of the water gate valve 409, and at the same time, The water tank 295 and the fire hose 9 (9), which are located at the top of the mountain and in the lower part of the mountain while simultaneously discharging the control water to the ocean to prevent the harmful tidal generation, ) Prevention of a number of natural disasters can be prevented by installing fire prevention facilities (811) inside the reactor main body (1) of the nuclear power plant, Is a power transmission unit (811d) adapted to connect the flood control device disaster-flood control process provided for transmitting are preferred.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention device, there are provided a faucet water supply valve 495, a handle handle 533, and an intermediate portion (not shown) in the indoor water supply pipe 14 in the outside of the neighborhood living alone in the firefighting and disaster prevention system, At the same time, it is provided with a bracket 44 attached to an elbow-socket bushing thread, and at the same time, a fire-water control valve is provided at the part of the flow meter 105 for checking the fire- When a fire is generated indoors or outdoors, the installation is divided into indoor and outdoor areas, and the water pipe (14) is connected to the hose (9) for detecting the fire sensor by a nozzle hose 0) stopper is formed to provide a water pressure inside the hose, and at the same time, a fire prevention is provided even under the water pressure of the water supply. At the same time, the air for supplying gas and the noncombustible gas 164 pass, The first ignition sensing wire 41 for detecting the initial ignition point at the same time is provided with the injection hose nozzle for the paraffin stopper to arrange for the advancement arrangement and at the same time to suppress the ignition of the flame 235 and the flame 236 (B) It is installed at the top of the mountain and under the mountain, while attaching to many areas with the interior corner and the bottom of the ceiling, The prevention of natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods, droughts and landslides in the water tank (295) and fire hose (9) A is preferably configured to connect the power transmission unit (811d) for transmitting the power of the nuclear power plant flood control seolbibu 811 to flood disaster prevention control device is formed flood control process.

As shown in FIG. 6q, it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant The parasitic disaster prevention apparatus is provided with a paraffin tape 177 connected to the paraffin tape 177 and the ignition non-material wire 176 to generate ignition. At the same time, the detection strip 41 is cut, The thermistor thermometer switch 103 and the solenoid operation on / off switch button 66 provided on the solenoid valve 76 and the emergency siren 93 after the switch operation, At the same time, the solenoid valve switch actuating solenoid 107 together with the alarm device is operated to open the solenoid valve 76 of the electronic control device, and at the same time, the stair-step injection nozzle 10 and the wall- The fire water is rapidly supplied to the ceiling fixing spray nozzle 10 and the fire spout 235 of the fire point and the fire spout 2236 and the fire pillar 237 are inserted into the gap of the radiation type 15 and the straight line type The flushing water is discharged into the gap 15 by a single linear discharge jet 38 and a radial discharge jetting water curtain water film 39 so as to smoothly discharge the flames, Fire truck dispatch It is necessary to prevent the occurrence of land marine disaster that provides for the elimination of fire, flame and pillar before the arrival time in the local area. At the same time, The present invention, which directly or indirectly senses the water level in the tank tank and the fire heat by a temperature sensor, which can be identified by the Internet network of the forecasting control system and the naked eye, The firepipe (29) and the fire hose (9), which are located at the top of the mountain and at the bottom of the mountain, Flood, drought, and landslide. In order to prevent the natural disaster from occurring, the power transmission unit 811d for transmitting the flood control facility power of the nuclear power plant 811 to the nuclear reactor main body 1 of the nuclear power plant, It is preferable to be connected to the formed flood control disaster prevention device.

Referring to FIG. 6R, within the reactor main body 1 of the nuclear power plant having the dual structural block tank dust collector for treating nuclear waste according to the present invention, A three-stage stepped pump fire extinguisher which is configured to achieve the initial evolution, a flushing-type flushing-type flushing tank, and an alternative manometer turn-type level balance pipe nozzle disaster prevention flushing control unit. (811) Nuclear Power Plant (811) Power Generation Facility to Include in Power Generation Facilities of the Nuclear Power Plant Three-Stage Stepped Pump Fire Extinguisher Fire Prevention Collecting Tank and Alternate Manometer Turn Level Balancing Tube Nozzle Dispensing Dispensing Dispensing Device The side construction of the road,

As shown in FIG. 6 (r), it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, the separation service of fire brigade nozzles installed at the high and low mountains, valleys, roads, and neighborhood buildings is provided with a total of 7 segments at a distance of 300 mm It is standardized with a total length of 2100mm, and the distance between the nozzle of the fire hose connection part is 600mm, so that the hole of the nozzle gap which is twice as large as the diameter of the fire hose provided by the standardization has a plurality of 7 segments and a diameter There are 70 machining holes of 5 mm, totaling 498 total machining holes, and at the same time, the mounting positions are the same as the pole arrangement At the same time, the height of the fire fighting equipment was adjusted according to the shape of the building and the forest, and the height of the hose and the pipe body of the double-pipe structure, Which is used as a disaster prevention and control agent for disasters and air pollutants, which is lighter than air and halon gas in air and carbon dioxide, helium is installed in a liquid fire-fighting water, solid ocher powder and fire- It was found out that a large number of discharging jets were discharged to the outside of the pipe nozzle while providing operation immediately after the detection, and a scene in which fire and flame and pillar were removed at the same time was provided from an unmanned camera, a mobile service, To display the score on the monitor through operation of the control server of the multi-stage pump control system In the pipe-nozzle-type fire-extinguishing sensor pump facility constructed by the fire-prevention sensor pump of the non-disaster fire prevention disaster prevention countermeasure goods, it is necessary to arrange the winch fixation on the roof of each corner and the roof of each building, It is an incombustible gas that does not burn easily within 1 second due to the initial fire when the disaster prevention material mixed with the liquid, gas, and solid is surrounded by the combustible material. And at the same time, the cooling effect of putting the water in the hose at the same time, the early evolution is provided, and the lifesaving is provided, and the life structure and the early evolution are surely guaranteed from the fire and the seasonal fire The nuclear reactor main body 1 of the nuclear power plant is supplied with water from the nuclear power plant 811, (811d), which is equipped with a disaster-control disaster prevention device, which is equipped with a disaster-control disaster prevention device, which is equipped with a power transmission unit (811d) And a power transmission control unit 811 connected to the distribution shaft to the inside of the reactor facility body 1 to transmit the power constituted by flood control to the interior of the reactor facility body 1 of the nuclear power plant of each distribution axis. The production power of the marine hydroelectric power plant of the regulating facility supplies power to the fire sensor pump.

As shown in FIG. 6 (r), it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, a plurality of fixed type watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight watertight, A bolt 24 for disassembling and assembling several flanges 28 formed by a body of a pipe 14 provided with several nozzle machining holes and a plurality of gap machining holes 20 is mounted on a flange bolt 24 of a flange bolt And the nut 25 is connected to a bolt screw tap to form a connection with a hand-held monkey pen, and the water hammer pump 393, which is composed of a paraffin nozzle cap 100, Facilities include air The non-powered pump bubble pump, which is provided to raise the water surface by ejecting the compressed air supplied from the condenser 80 to the lower hole of the pumping pipe 89, is also connected to a flexible high-pressure hose made of wire, rubber, The jetting water 38 and the water jetting water film 39 ejected to the outside of the body of the firefighting nozzle 10 constituted by the fire fighting and disinfection piping line 168 are dropped while the water jetting water piping line 168 is provided, (593,594,595) of the control shaft of the control shaft to the inside of the reactor installation main body (1) of the nuclear power plant composed of the unmotor pump and the unmanned camera (184) of the water tank, the electronic sensor valve and the control system. The fire-fighting nozzle nozzle 10 is provided with the soil-to-be-cleaned fire-fighting device for preventing fire damage by mixing the loess soil 158 with the mixer of the pipe- Ghana is used as a water gun and water cannon in the discharge of water from the river to provide disaster prevention effect. At the same time, it is equipped with Nuclear Waste Treatment (NLL) near the armistice line and dual structural block tank marine tunnel transportation equipment (941) 1) It is desirable that the nuclear power plant (811) on the control shaft is connected to a flood control facility that provides preventive measures against natural disasters such as forest fires, dust storms, heavy snow, extreme winds, typhoons, floods, droughts and landslides.

As shown in FIG. 6 (r), it is preferable that a flood control process is formed by the power transmission unit 811d that transmits the flood control facility power of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant In the flood control disaster prevention apparatus, in the connection facility structure of the multi-stage multi-stage pump 8 of the high pressure, the sensing strap 41 provided with the detection sensor is distributed in an extensive area, (43) and disaster prevention materials in basket plastic bags of a certain size, and then connect them with sensing wires at the top of the area containing the disaster prevention material. Flood Control Flange Bonding Site after installation with disaster prevention device installed, and classified by region Fuel Control Detection Sensor installed in the area of the connection point of the disconnection pipe And a sensing wire connected to an electronic control sensor provided at an upper end of a regulating valve of a hammering type to provide flood control and disaster prevention, and the sensing wire (41) is connected to each corner of the plurality of tent tents (43) 4 and 8 places, and at the same time, the mounting position of the twine knot is fixed to the tent fastening frame so as to be fixed to the water tank tank 295 (8) of a reactor main body (1) of a nuclear power plant having a dual structure block tank dust collector for treating nuclear waste, and a high pressure stage multi-stage pump (8) installed inside a machine room formed in an internal nuclear power generation facility Provide a connection structure.

As shown in FIG. 6q, preferably, the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the reactor facility main body 1 of the nuclear power plant, In the disaster-controlled disaster prevention apparatus, the disaster prevention apparatus includes a solenoid valve 76 connected to a suction joint pipe 3 at the upper end of the road surface on the lower side of the ground surface and the flange 28, The fire extinguishing water provided in the quartz tank 34 is provided with a fire water level sensor for detecting the disaster water quantity and at the same time a socket type nipple 110 for connecting the hose 109 provided inside the nozzle hose 9, (77) and the airship (78) are provided at the upper end of the sea surface before the occurrence of the disaster, while at the same time the emergency power generator (226) at the upper deck of the ship is operated and the power source Discharging Controlled Discharging Apparatus Providing Air to the Recipient High Pressure Storage Tank 145 While Air is Provided to the Power Motor Control Module 106 While the Air Compressor 80 is Provided In the event of a disaster, the emergency valve (181) emergency valve (84) is opened and air is blown into the hull when a disaster occurs, while the air pressure in the high pressure storage tank (145) Air is stored in a plurality of container size lifting tubes 130 attached to an external piping frame and at the same time the advent of the advertisement balloon 77 at the upper end of the lifeline hull deck is raised to the upper end of the sea level, After confirming the structure of the crew of the disaster ship on the structural basket (42), it is necessary to prepare for overcoming the crisis situation, and at the same time, to prevent disasters on the land and sea of the global village. Safety control system The paraffin (100) provided in the injection nozzle by the manufacturing method of installation and lifesaving device is installed on the marine vessel and it is installed in the mountain top and under the mountain with the flood control facility for fire prevention purpose and other disasters. At the same time, forest fire, yellow dust, heavy snow, extreme weather, typhoon, flood and drought, landslide prevention of many natural disasters by the easy plastic bag 43, the tank tank 295 and the fire hose 9, It is preferable that the power transmission unit 811d that transmits the power of the flood control facility of the nuclear power generation facility unit 811 to the inside of the reactor facility body 1 of the nuclear power plant is connected to the flood control disaster prevention apparatus formed with the flood control process.

Referring to FIG. 6, the nuclear reactor plant main body 1 of the nuclear power plant having the dual structural block tank dust collector for nuclear waste treatment according to the present invention is installed in the nuclear power plant 811 with the disaster prevention / A disaster-preventing and disaster prevention apparatus for disaster prevention and control section constituting a ship 1078 having a conventional sinking vessel and rescue force for rescue force capable of overcoming a severe storm wave 1101 from sinking, (811) Nuclear Power Plant's Power Plant Nuclear Power Plant's (1078) vessel with rescue force for nuclear waste disposal is placed inside nuclear reactor plant main body (1) The side configuration of the distribution and input device of the reactor installation disinfection control disaster prevention device of the nuclear power plant to be included in the part,

Referring to FIG. 6 (t), the nuclear reactor plant main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste treatment according to the present invention is installed inside a nuclear power plant 811, Which is an example of an elemental example showing a disaster-prevention and disaster prevention device for preventing a disaster, constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101 A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided on a ship 1078 having rescue rescue force for nuclear waste disposal for generating facilities nuclear power plant of a nuclear power generation facility unit 811, 626, elevator alibite 632, conveyor 633, bollard 638, anchor 639, anchor chain 640, and helicopter 647, as well as the rope knot claw 630, the emergency stairs 631, Circles Nuclear power plant nuclear reactor power plant disaster control disaster prevention apparatus which is included in preventive disaster prevention control section of nuclear power generation facility section (811) inside nuclear reactor facility main body (1) of magnetic power plant Rubber balloon of vessel (1078) (914) side configuration,

Referring to FIG. 6 (b), within the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste treatment according to the present invention, the disaster prevention and disaster prevention units of the nuclear power generation facility 811, Which is an example of an elemental example showing a disaster-prevention and disaster prevention device for preventing a disaster, constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101 A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided in a nuclear waste disposal apparatus of a nuclear power plant of a nuclear power generation facility unit 811 showing a configuration and a ship 1078 having a life- An elevator 636 and an elevator ally 660 and a conveyor 633 and a bollard 638 and an anchor 639 and an anchor chain 640 and a helicopter 647, ) Nuclear power plant nuclear reactor power plant disaster control disaster prevention apparatus that provides to be included in prevention control section of nuclear power generation facility section (811) inside nuclear reactor facility main body (1) of nuclear power plant Rubber balloon of vessel (1078) (914) lateral strabismus configuration,

Referring to FIG. 6w, in the nuclear reactor main body 1 of the nuclear power plant having the double structure block tank dust collector for nuclear waste treatment according to the present invention, the disaster prevention and disaster prevention units of the nuclear power generation facility 811, Which is an example of an elemental example showing a disaster-prevention and disaster prevention device for preventing a disaster, constituting a ship 1078 having a conventional sinking vessel and rescue force rescue force incapable of sinking and preventing a strong wind wave 1101 A hatch cover 153, a life-size combination bed nozzle 172, and a rope rope (not shown) provided in a nuclear waste disposal apparatus of a nuclear power plant of a nuclear power generation facility unit 811 showing a configuration and a ship 1078 having a life- An elevator 636 and an elevator ally 660 and a conveyor 633 and a bollard 638 and an anchor 639 and an anchor chain 640 and a helicopter 647, ) Nuclear power plant nuclear reactor power plant disaster control disaster prevention apparatus that provides to be included in prevention control section of nuclear power generation facility section (811) inside nuclear reactor facility main body (1) of nuclear power plant Rubber balloon of vessel (1078) (914) Lateral strap configuration Road,

As shown in FIGS. 6 S, 6 T, 6 V, and 6 W, it is preferable that the reactor structure main body 1 of a nuclear power plant having a dual structural block tank dust collector for nuclear waste treatment according to the present invention is provided with nuclear power generation Disaster prevention preventive and controllable disaster control disaster prevention devices provided in the nuclear power plant safety control management production former 811e of the facility unit 811, the electronic control adjusting apparatus construction machine control unit 811f and the screw control units 811g Disaster Prevention and Control Disaster Prevention and Disaster Prevention System which provides a ship 1078 having a conventional sinking vessel and rescue force for rescue force that can not overcome a severe storm wave 1101 can not be overcome. A hatch cover 153, a lifting structure bed nozzle 172, a rope rope 629, a rope knot claw 630, and an emergency staircase 631 provided on a ship 1078 having a nuclear waste disposal apparatus and rescue force rescue force, ) And lift The reactor facility body 1 of the nuclear power plant having the ally bait 632, the conveyor 633, the bollard 638, the anchor 639, the anchor chain 640, the helicopter 647 and the rubber balloon 914 A power transmission unit 811d for transmitting power to the nuclear waste nuclear waste disposal unit 811a and the electric power production unit 811b of the nuclear power generation facility unit 811 and the traffic transportation unit 811c of the construction machine, Equipment safety control management Production control unit 811e, electronic control unit construction machine control unit 811f and screw control units 811g The flood control disaster prevention unit The rising air current 925 and the down air current 926 of the typhoon The air current The control device nuclear waste disposal apparatus and the ventilating basket 951 for the harmful rust-breathed ventilation dust collector, the flexible high-pressure hose 190, the introduction pipe 191, the blower 641, the heater fan 642 for keeping the air, Equipment mixer machine (649) and crane boom (651) and crane boom hook (652) and rubber balloon (914) and ball A nozzle 923, a loess mixture 927 for soap bubble, a crude oil drill 934, a cooling air bubble 939, an underground line disaster prevention nozzle 945, a submarine line wiring 946, (947), which is equipped with a structure for installation of anti-sinking footrests, and a construction equipment and a dispenser for marine vessel replacement traffic equipment. It is preferable that the nuclear reactor is installed in the reactor main body of a nuclear power plant having a dual structure block tank scrubber for nuclear power plant,

Referring to FIG. 6U, within the nuclear reactor main body 1 of a nuclear power plant having a double structure block tank dust collector for nuclear waste disposal according to the present invention, a disaster prevention preventive control section of a nuclear power generation facility 811, Which is an example of a constitutional example showing a flood control and disaster prevention device of a disaster prevention preventive control part constituting an air flow regulating device of a typhoon rising air flow 925 and a descending air flow 926 among the flood control disaster prevention devices provided in the disaster- A nuclear waste disposal apparatus of a nuclear power plant of a nuclear power generation plant 811 showing a nuclear power generation plant 811 and a garden hatch basket 951 for a harmful rusty sucking and dust collector, a flexible high pressure hose 190, an introduction pipe 191, a blower 641, The heater fan 642 for warming and the yellow loess cement mixer mixer machine 649 and the crane boom 651 and the crane boom hook 652 and the rubber balloon 914 and the air nozzle 923 and the loess mixture 927) and crude oil And a double structure air injection rubber tubing 947 inside the container for the submergible regulating device and a disassembly nozzle 945 and a submarine line wiring 946 are connected to each other by a wire 934 and cooling air bubbles 939, Nuclear power plants' nuclear reactor facilities to prevent disasters from being installed in the nuclear reactor facility (811) inside the nuclear reactor main body (1) Flushing control disaster prevention device Upwind airflow (925) and downward airflow (926) The apparatus includes a nuclear waste disposal apparatus and a horticultural basket 951 for a harmful rust-absorbing and collecting dust collector, a flexible high-pressure hose 190, an introduction pipe 191, a blower 641, a heater fan 642 for maintaining the air, The mixer machine 649 and the crane boom 651 and the crane boom hook 652 and the rubber balloon 914 and the air nozzle 923 and the yellow loam mixture 927 for the soap bubble and the crude oil drill 934 and the cooling air bubbles 939), a disaster prevention nozzle 945, a submarine line wiring 946, (947) side-by-side configuration of the dual structure air-inflated rubber tube inside the container for the device,

As shown in FIG. 6U, the nuclear waste treatment dual structure block tank marine tunnel traffic devices 941 are installed in the vicinity of the demilitarized zone and the NLL line, 811) is preferably connected to a flood control facility that provides for the prevention of a number of natural disasters such as forest fires, sandstorms, heavy snow, extreme weather, typhoons, floods, droughts and landslides. Inside the reactor plant main body of a nuclear power plant, a distributing and inputting apparatus generally includes a supply section for storing a mixture of cooling water and yellow soil, which is a fuel explosion-proof control article, and supplying a predetermined amount of fuel explosion- Nuclear Fuel Explosion Prevention Control Products to Be Sealed in Nuclear Reactor Alternative Nuclear Waste Shielding Nuclear Reactor Facilities And an injection section for injecting the nuclear fuel explosion-proof control article distributed by the distribution section into the nuclear reactor facility of the alternative nuclear reactor alternative nuclear waste processing shielding apparatus, while at the same time, Belt Stabilization tank for diving control and holding tank, inner block tank and outer block tank, which are connected to each other, are located at the outer part of the Bellevest Stalling Tank. The tabletop table is equiped with the barge hull and the tabletop table leg is equivalent to the holding block tank of the barge hull. Therefore, the tabletop table can be easily manned by the manpower and the tabletop table leg Just as you put it up and down. At the position of the surface, the holding block tanks of the barge hull can be easily pinched and spread by the sea. At the same time, the nuclear power plant equipment is equipped with a barge hull at the top of the sea surface, a holding block tank for the barge hull, It is installed in the sea, or on the upper part of the sea surface (SLU) which is connected to one side of the both sides of the holding block tank with the block tanks of the hull of the barge hull, and at the same time, A solenoid valve having a connection structure to a Bellevast butterfly valve and a solenoid valve provided in a connection structure with a single tank and simultaneously providing an opening of a ballast control valve, a main switch button operation of a main switch button for a start switch button is provided Diving control on barge hull At the same time as the seawater was being filled, the barge ship hull was slowly submerged into the water while it lost its buoyancy to the nuclear power plant facilities and, at the same time, a single block on both sides of the holding block tank with a portable tank- Vertical State Lug One horizontal vertical machining hole with lug coupling pin and linkage structure at the same time Horizontal holding block tank pipe pier is made of barge hull and lug without losing buoyancy, Horizontal state of the connecting shaft with the connecting structure at one side Horizontal stowage block at the position of the supporting block tank At the same time as the hull of the barge is slowly submerged in the water at the position of the connecting axis of the tank, the bottom tanker hull of the holding tank is seated on the seabed, Connecting individual holding block tanks not connected to barge hull The stern section is vertically positioned to control the vertical movement of the sea level, while at the same time, it is attached to the nuclear power plant equipment. The top of the holding tank is connected to the barge hull. Positioning of each ship in the vertical position on the top of the sea level control is completed. Each ship's block tanks are connected to the ship's stern section and the top of the holding tank. The barge hull is connected to the distribution shaft. Equipment, submersible and semi-working submersible vessels, barges, tugboats and towing lines Construction of offshore cranes, anti-erosion and anti-aircraft construction equipment, Connect the automatic manufacturing process of fixing and termination of the mooring device by putting the control device In the nuclear power plant facilities, which are equipped with the anti-submergence lifting plant, it is necessary to establish the foundation for the installation of anti-submergence lifting plant in the nuclear power plant facilities. It is preferable to constitute reactor facilities of the nuclear waste disposal screening device of the nuclear power plant with the distributing and inputting devices into the reactor main body of the nuclear power plant having the double structure block tank dust collector,

Referring to FIG. 6x, it can be seen that in the nuclear reactor main body 1 of a nuclear power plant having a dual structure block tank dust collector for nuclear waste disposal according to the present invention, A peace-preserving message that restores peace-preserved message photo-shoots (958), more powerful than nuclear bombs, to each region within a radius of 1200 km from the center of the Korean peninsula, A nuclear waste disposal apparatus for a nuclear power plant of a nuclear power generation facility 811 showing a constitutional example illustrating a photo shoot 958 and a peace preserved message photo shoot 958 are installed in a radius Peacekeeping, which will re-establish in each region within 1200km and prepare to carry out the tasks according to the rights and obligations of the establishment of a new federal state in Northeast Asia Lt; RTI ID = 0.0 &gt; 958 &lt; / RTI &gt;

As shown in FIG. 6x, in order to prevent the disaster prevention preventive control unit of the nuclear power plant 811 inside the nuclear reactor main body 1 of the nuclear power plant, (958) nuclear power plant nuclear waste disposal system and a peace-preserving message photo-sho (958) from the center of the peninsula within a radius of 1200km to re-install each region in accordance with the rights and obligations of the establishment of a new federal nation in the facility of peace stateful message Photo shovel (958) to raise the mission, provided the local governments of the stylist and Northeast Asia peace and coexistence have to mobilize to the door to depositions gathered the holy meaning of peace, Magna Carta provided Magna Carta draft editorial and At the same time, in the above-mentioned large- scale peace coexistence in Northeast Asia , All sailors and passengers who provide for the unity of the dignity of life that has made life not to lose its life in the fire which has been made to lose its life in the ship, By constructing a hitch carver, a double structure rubber balloon (914) and an emergency exit door on the left and right sides of the ship, we are able to live a safe life, I hope my descendants will be rescued from the deadline, and I will make shipbuilding the first equivalent in the world that has never caused the sinking of the Cheonan and sinking of the passenger ship, but at the same time, We believe that the will of the inventor who made the name safe and the nuclear bombs A more powerful weapon, a peace-keeping message photo shovel (958), was installed at nuclear power plant facilities, a submersible and semi-submersible submarine, barge, tugboat, In the nuclear power plant facilities in which the connection and disconnection control device and the automatic control device for automatic disconnection of the mooring device are installed to provide the connection structure for the dispensing and inputting device of the marine vessel alternative transportation equipment, Construction of infrastructure for distribution of equipment for construction machinery and marine vessel alternatives to traffic facilities Operation of nuclear reactors with position control and throttle control devices Double structure block for nuclear waste processing Tank of nuclear power plant with dust collector Nuclear waste disposal screening equipment for nuclear power plants with distribution devices Is composed of a picture not shovel 958 is preferred.

On the other hand, in the vicinity of the launching platform of the satellite and the space rocket to the nuclear power plant facilities, a 1 meter thick natural loam and disaster prevention construction equipment are installed on the deck deck floor and the package is arranged on the deck deck. At the same time, Around the launch pad, a 100 meter diameter circular ocher block disaster prevention wall was installed at a height of 3 meters and a height of 15 meters. At the same time, satellites and space rockets were launched from the satellite launch pad and space rocket launch pad formed at the top of the deck deck When a huge amount of fuel is burned in order to obtain propulsion, high temperature is generated. At this time, high temperature high pressure combustion heat generated by satellite, space rocket, etc. is 100 m in diameter circular ocher block. At the same time, deck decks are equipped with nuclear plant facilities, In addition, at the same time, in the nuclear power plant facilities, the movement of the hull is dependent on the length of the quay so that the crane boom can be used in the deep sea. At the same time, in the nuclear power plant facilities, two batches are prepared at the front of the hull, while at the same time, the hull of the nuclear power plant is retracted and the batch is prepared at the same time At the same time, nuclear power plant facilities are equipped with anchors and anchor chains that can be used as ship shelters in coastal marine shelters, and are capable of safely carrying out hull travel Build a dual structure block tank dust collector for nuclear waste disposal with one set of equipment It is a desperate need for configuring a nuclear reactor facility into the body of a nuclear power plant.

(Second Embodiment)

A second embodiment of the present invention will be described.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, as shown in FIGS. 1 to 6. FIG.

FIGS. 1 to 6 are cross-sectional views for explaining a method for manufacturing and installing a reactor facility of a nuclear power plant having a double structure block tank dust collector for treating nuclear waste according to an embodiment of the present invention, and an apparatus for manufacturing a reactor facility of a nuclear power plant to be.

The first stage is able to select the hydraulic element by reading the hydraulic symbol indicated in the circuit diagram.

The order of the following exercises is

First, prepare for work.

First, the hydraulic circuit diagram is read.

Next, select the hydraulic element shown in the circuit diagram.

Next, check whether there is any abnormality in the hydraulic test equipment.

Second, the hydraulic element is assembled.

First, the hydraulic element is fixed on the hydraulic work plate.

Next, connect each hydraulic element using connecting hose.

Check the connection.

Check and check the connection of each hydraulic element and the connection hose for abnormality.

Third, the test works.

First, count the start switch.

And align the pressure relief valve using the input to 40kg _f / cm ^2.

On the other hand, the forward and backward movements of the single acting cylinder are made by switching the position of the 3/2-way valve. Also, check the pressure of p1 and p2 during forward movement and record in the record chart of Table 6-4.

Next, in order to arrange the exercise device

Power off the hydraulic power unit after cleaning.

Confirm that the pressure of the pressure gauge after shutoff is 0 kg _f / cm ² .

Next, connect the hydraulic element using connecting hose.

Also check the connection elements,

Check the connection of each hydraulic element and the connection hose for abnormality.

After the inspection, the test operation is performed.

Turn on the ignition switch after operation.

And align the pressure using a pressure relief valve to 40kg _f / cm ^2.

Use the 4/2-way valve to complete Table 6-5.

Arrange each hydraulic element after completion.

Power off the hydraulic power unit after cleaning.

Confirm that the pressure of the pressure gauge after shutoff is 0 kg _f / cm ² .

After confirming, remove the hydraulic piping and trim the parts.

<Table 1-1>

[Embodiment 1] In countermeasures against the intermediate stop of the hydraulic cylinder

First of all,

First, the function of the pilot operated check valve can be explained.

Second, the intermediate stop system of the cylinder can be constructed.

According to the training sequence,

Prepare for practical training.

First, select the parts required for the exercise in Figure 6-8, and place it on the fixing plate and fix it.

Use the hydraulic hose to pipe the parts placed after fixing, as shown in the circuit diagram.

Test operation after piping.

Supply power to the hydraulic power unit after the test.

After the supply, the valve <2> is actuated to advance the cylinder.

After the movement, the valve <3> is operated to move the cylinder backward.

Next, put a weight of 20kg _f on the cylinder.

Next, the valve <2> is operated to advance the cylinder to the intermediate position of the stroke.

And arrange exercise equipment.

After the trim cylinder is fully backward movement, and the pressure of the pressure gauges such that the 0kg _f / cm ² operates the valve <3>.

Power off the hydraulic power unit after operation.

After shutting off, remove the hydraulic piping and trim the parts.

[Embodiment 2] According to the speed control of the hydraulic cylinder

Practice goals include

First, a meter-in speed control circuit of the hydraulic cylinder can be constructed.

The following can configure the meter-out speed control circuit of the hydraulic cylinder.

Prepare a meter-in speed control exercise by practice sequence.

Then select the parts necessary for the practice of Figure 6-12 meter-in speed control and place it on the fixing plate and fix it.

Use the hydraulic hose to pipe the parts placed after fixing, as shown in the circuit diagram.

Next, test the operation.

Supply power to the hydraulic power unit after the test.

It adjusts the set pressure of the pressure relief valve determining the maximum pressure of the feed system after a 50kg _f / cm ^2.

Then, adjust the adjustment screw of the throttle relief valve so that the completion time of advancement of the cylinder in the no-load state is 10 seconds.

Check the pressure and time of p1, p2, p3 during the forward movement after adjustment and record in the record table of Table 6-6.

After recording, apply a compressive load of appropriate strength by using the brake lever of the cylinder.

On the other hand, the procedure of (4) is repeated.

Repeatedly release the brake lever of the cylinder and then applies a tensile load by the weight (20kg _f).

(4) is repeated.

After repeating, arrange exercise equipment.

Power off the hydraulic power unit after cleaning.

Confirm that the pressure of the pressure gauges after blocking is 0 kg _f / cm ² .

* After confirming, remove the hydraulic piping and trim the parts.

Next, prepare the meter-out speed control exercise.

After preparation, Fig. 6-13 Meter-out speed control Select the parts necessary for the exercise and fix it on the fixed plate.

Arrange the arranged components after deployment by using a hydraulic hose as shown in the circuit diagram.

Then, the operation test is performed in the same manner as in Section 2.

In the same way as in Section 3, the training apparatus is arranged.

Also prepare the counter balance valve exercise.

After preparation, select the parts necessary for the counterbalance valve exercise shown in Fig. 6-14, and fix it on the fixing plate.

After fixing, use the hydraulic hose to connect the parts placed.

Then, test the operation.

Meanwhile, in a no-load condition the pressure p3 during forward movement so that 20kg _f / cm ² to adjust the adjusting screw of the pressure relief valve.

Also, arrange the exercise equipment in the same way as in 3..

<Table 6-6>

관계지식

Relationship knowledge

■ Meter-In Speed Control

■ Meter-out speed control

As described above, a space rocket launcher (643), which is an equipment for space science development, which is a device for the development of the marine environment industry, is installed inside a reactor main body (1) of a nuclear power plant having a double structural block tank dust collector for nuclear waste treatment (611) and space rockets (612) are mounted on the upper deck deck (SDL) at the top of deck deck (595) deck of a large marine power plant built in the ocean according to the international community hierarchy. At the same time, Dual Nuclear Waste Treatment Nuclear Power Plant Facilities Dual purpose high temperature nuclear reactor installations can be selected by members of the United Nations UN Peace Keeping Force and the UN Scientific Committee.

It is not easy to raise the treasure to the inside of the main body. However, according to the present invention, there is provided a dual-purpose multi-purpose high-temperature gas reactor facility for a nuclear waste treatment nuclear power plant for nuclear power plant, and a distribution input device for a floating- Nuclear waste disposal structure consisting of double structure block tank bridge for marine disaster prevention and marine environment industry development Development of nuclear waste disposal facility for nuclear power plant in the world as a connection structure of marine tunnel traffic equipment Dual structure of multi-purpose high temperature facility Nuclear reactors Nuclear reactors Nuclear reactors Nuclear reactors Nuclear reactors Shielding reactors Nuclear reactors Leakage control Dual structure block Tanks Nuclear power plants with dust collectors Nuclear reactors with main distribution devices Nuclear waste disposal screening reactors To construct the facility The.

It is to be understood that the present invention is not limited to the above-described embodiments, but may be modified in various ways by those skilled in the art without departing from the scope of the technical idea of the present invention. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present invention as set forth in the appended claims.

""

""

"자형태의 지그),(23)샤 클,(24)볼트,(25)너트,(26)와샤,(27)외부블록탱크 외부 위치로 결합 분리 해지용 힌지,(27a)힌지용 ㄱ형의 러그 핀 연결축,(27b)힌지용 장축의 연결축,(28)플랜지 또는 선체의 벨러스터 바라싱 탱크 흡입구 이물질 접근 차단용 플랜지마개철망,(29)카플링,(30)카플링 암나사산 몸체,(31)카플링 수나사산 몸체,(32)가스켓트 또는 고무패킹,(33)노즐호스장비거치대,(34)집수정탱크 또는 안전탱크,(35)레듀사,(36)고성능수중펌프,(37)펌프수차,(38)토출분사수,(39)물막 또는 커텐물막,(40)소방정,(41)감지노끈,(42)바스켓,(43)이중비닐텐트 또는 봉지,(44)엘보 또는 티이엘보,(45)소방용 펌프,(46)동력 전원 공급장치인 전원,(47)인버터,(48)인버터 브이오,(49)억세스포인터,(50) 인터넷망,(51)입형다단펌프의 관제서버,(52)모니터,(53)펌프제어보드 또는 타구어윈치 조정박스,(54)근거리무선통신안테나,(55)근거리무선통신장치의무선통신제어모듈,(56)디스플레이,(57)전자제어장치 에이 디이 씨,(58)스위치 입력회로, (59)전자제어장치 엠씨유,(60)전자제어장치 디이 에이 씨,(61)과전류차단기용 브레이크, (62) 전원부,(63)디스플레이 화면,(64)아날로그입력,(65)디지털입력,(66)각 펌프의 온 오프 제어용 메인스위치버턴,(67) 보조스위치 버턴,(68)입형다단펌프 디스플레이 입력 또는 컴퓨터 전산망 입력,(69)현재 압력값 또는 설정 압력값 압력설정수치 인식명판,(70)메모리,(71)동력전선,(73)방재물질 혼합기믹서,(74)이중관 구조 블록배관라인,(74a)내부블록배관,(74b)외부블록배관,(75)헝겊꺼즈,(76)솔레노이드밸브,(77)애드벌룬,(78)비행선,(79)가스통,(80)공기압축기,(81)모바일서비스,(82)휴대용단말기,(83)저압차단 밸브,(84)비상 밸브,(85)감압 밸브,(86)제1압력체크센서,(87)제2압력 체크센서,(88)전자제어유닛,(89)방재배관라인 또는 양수관,(89a)수직 양수관,(89b)수직 하향관,(90)볼밸브 핸들,(91)드렌처헤드,(92)밸브몸체 내부 디스크,(93)비상싸이렌,(94)최초발화원인물질인 스파크 또는 낙뢰,(95)전신주,(96)변압기,(97)레듀사붓싱소켓,(99)점멸경고등,(100)파라핀노즐마개,(101)압력계,(102)감지센서 바이메탈,(102a)열전대의 구성 방식,(102b)열전류 발생,(102c)열기전력 발생, (102d)측정점,(102e)기준점,
(103)감지센서용 열전대 온도계 스위치,(103a)열전대 온도계의 구성방식,(103b)측온한계,(103c)온도 1,(103d)전류계 온도의 눈금,(103e)금속A,(103f)금속B,(103g)전위차가 발생,(103h)열전대와 보상도선,(103i)측온 접점,(103j)열전쌍,(103k)보상 접점,(103l)보상 도선,(103m)기준 접점,(103n)열전대의 종류, (103o)보호관이 없음,(103p)보호관,(103q)고온물체,(103r)보호관이 있음,(103s)시스형,(103t)측온단자,(103u)측온접점,(103v)스텐 금속시스,(103w)보호관 부착 백금 측온 저항체,(103x)마이카,(103y)백금선,(103z)자기,
(104)레벨 또는 압력스위치,(104a)다이어프램식 압력스위치, (104b)공압-센서 압력스위치, (105)방유량 체크용 유량계,(106)전동기제어모듈,(107)밸브스위치작동용 추 또는 크레인 붐대 레벨 유지 웨이트,또는 납덩이 추,(108)과대압력 방지스위치 또는 스위치박스,(109)공기호스,(110)공기호스 연결장치 닛플,(111)스프링 쿨러헤드,(112)반사관,(113)가용금속용 퓨우즈,(114)정지밸브 또는 수도밸브,(115)지하매설관,(116)철탑 또는 블록철탑,(117)부자,(118)부자회로개폐기,(119)벨,
(120)경보밸브,(121)시험밸브,(122)고압수도펌프,(123)레버 블럭,(124)소화기(소화기a, 소화기b, 소화기c, 소화기D, 소화기e, 소화기f) (125) 체인,(126)실린더,(127)피스톤 또는 피스톤펌프,(128)소화기 고정용 핀,(129)빗장 장금장치,(130)인명구조용튜우브,(131)로프,(132)컨테이너,(133)앙카볼트,(134) 라디오존데,(135)구동바퀴 로라 용 도루레,(136)레귤레이트,(137)동체에 감긴 밧줄이나 쇠사슬로 수문개폐 조절장치용 타구어윈치,(138)시린더,(139)철개망태,(140) 터어빈펌프,(141)케싱,(142)베인펌프 또는 가이드베인,(143)임펠러,(144)다이어후렘펌프,(145)고압저장탱크,(146)프로펠러펌프 또는 프로펠러,(147)다단식나사 공기 압축기 그리고 나사펌프,(148)플런저펌프,(148b)사축식 플런저펌프,(148c)레이디얼 플런저펌프,(149)철재빔,(150)방재펌프 제어시스템 또는 관제시스템,(151)오일 냉각기,(152)맨홀덥게,(153)해치카버,(154)방화문,(155)글랜드패킹,(156)매커니컬 시일 또는 각개의 시일,(157)제트펌프,(158)황토,(159)방화사,(160)옥내소화전상자 (161)자동소화전,(162)호스걸이,(163)질식가스,(164)불연성 가스의 이산화탄소, (165)보강철판,(166)성냥불(a) 또는 발화물체(화재유형별의 A급, B급과 C급으로 분류함),(167)나사탭, (168)송수구 또는 소방방재 배관 라인,(169)방수구,(170)내부냉각기,(171)배기가스,(172)인명구조겸용 침대노즐,(173)가스랜지 또는 버너,(174)탄산가스,(175)하론가스,(176)핼륨가스,(177)발화물질 파라핀테이프,(178)비발화물질 철사,(179)소화전(단구형a,쌍구형b),(180)비닐포대,(181)방재공기배관라인,(182)후미냉각기,(183)리밋스위치 또는 리미트스위치,(184)무인카메라,(185)끝이 뾰족한 틈새 결합공구 지그대 쇄기,(186)스프링,(187)무인점화기 스파크라이터,(188)구명정,(189)압력탱크용 헤드탱크,(190)플렉시블고압호스 또는 유압호스,(191)도입관 또는 수압관,
(192)동력모터 전동기 몸체,(193)후드,(194)스냅링,(195)팬,(196)몸체프레임,(197)몸체 전방 보강철판,(198)회전축,(199)회전자조립,(200)전방 회전축받이, (201)고정자조립,(202)모터보호용 주물프레임,(203)단자박스,(204)인양볼트,(205) 단자박스 카버,(206)후방 회전축받이,(207)후방 보강철판,(208)공극,(209)팬 카버 또는 보호 카버,(210)회전자 철심,(211)고정자 철심,(212)고정자 권선,
(213) 활성막식 가스 홀드업장치,
(214) 필터,
(215) 배기탑,
(216)방사능 저장탱크,
(217)여과기,
(218)방사능 측정기,
(219)모니터링 포스트,
(220) 드럼통,
(221) 등변산 형강,
(222) 우라늄 광산,
(223) 옐로 케인크,
(224)핵폐기물[＜＜＜,＞＞＞],(224a)고체핵폐기물,(224b)액체핵폐기물,(224c)기체핵폐기물,
(225)철근 콘크리트 매트,
(226)엔진발전기, (277)터빈 회전 축받이,
(228)재처리공장,
(229)전환공장,
(230)농축공장,
(231)전환·가공공장,
(232)탐조등,
(233)제련공장,
(234)에어 드라이어,(235)불씨,(236)불꽃,(237)불기둥,
(238)원자력발전소의 핵 폐기물처리의 이중관 구조 블록배관라인 조절축,
(239)재순환펌프,
(240)압력 제어풀,
(241)급수펌프,
(242)순환수펌프 또는 1차주 냉각계통 순환펌프,
(243)냉각재펌프 또는 2차주 냉각계통 순환펌프,
(248)크랭크,(249)링크대,(250)푸레,(251)감속기,(252)브이밸트,(253)플런저,(254)고정핀,(255)타임머,(256)케이블카아,(257)공기밸브,(258)안전밸브,(259)자동밸브, (260)드레인밸브,(261)벨트카버,(262)흡입필터,(263)압축기본체,(264)수차 또는 펌프수차,(265)메인밸브,(266)산림,(267)터빈 또는 회전날개,(268)엔진발전기 또는 플라이휠,(269)취수구 또는 흡입구,(270)방수로 또는 토출구,(271)공운전 방지장치,(272)펌프전원,(273)제어전원,(274)비상운전회로,(275)직류파워공급회로,(276)마이크로 콘트롤 유니트,(277)디 아이피 스위치설정회로,(278)디스플레이회로,(279) M/C 구동신호 접점출력회로,(280)모터 과부하 신호입력회로,(281)인버터운전 데이트 입출력회로,(282)압력감지회로,(283)외부상태 입력회로,(284)토출 압력 트랜스미터어,(285) 흡입/토출 스위치,(286)베드 프레임,
(287)냉각수 또는 냉각수 입구,(288)유분리탱크,(289)흡입밸브,(290)기어드라이븐,(291)건조기,(292)물탱크,
(293)수문,(293a)데인터 게이트,(293b)롤링 게이트,(293c)설계수위,(293d)수면,(293e)앵커부문 고정부,(293f)고정부,(294)수로 또는 회전수로,(295)수조탱크,(296)게이트밸브,(297)리턴밸브,(298)부시 또는 트로틀부시,(299)드렌처 헤드(a,b,c,d)의 종류,(300)진동경보장치,(301)드레인,(302)역정지밸브,(303)고압 보울탱크,(304)양수펌프,(305)유량제어용 버터플라이밸브,(306)중탄산소다,(307)재유입구,(308)센튜리 퓨우걸 펌프,(309) 오수펌프,(310)스파이럴 케이싱,(311)블류우트 펌프,(312)후드밸브,(313)양수구, (314)펌프 본체,(315)플로우트,(316)볼 밀어넣기 기기,(317)플랙스블카프링,(318) 플로우트 스위치,(319)뒷날개,(320)퍼올림 밸브,(321)빨아올림 밸브,(322)분출 수면계,(323)실제 양정,(324)분출 양정,(325)제트펌프,(326)기어펌프,(327)윙 펌프, (330)분리 실,(331)마그넷 스위치,(332)핵폐기물건물,(333)빌딩 또는 대형건물,(334) 밸런스,(335) 언밸런스,(336)옥내 소화용 펌프,(337)로터리펌프,(338)로터리 회전자,(339)프라이 밍,(340)자흡식 펌프,(341)축류펌프,(342)혼류펌프,(343)점성펌프,
(344)원자력발전소의 이중구조 블록탱크 제조설치 공정의 연결축,
(344a) 가(A B )변의 블록탱크, (344b) 나(B C) 변의 블록탱크, (344c) 다(A C)변의 블록탱크, (344d) 라(A R) 변의 블록탱크, (344e) 마(A Q) 변의 블록탱크, (344f) 바(A P) 변의 블록 탱크, (344g)사(A O) 변의 블록탱크, (344h) 자(A M) 변의 블록탱크, (344i) 아(A N) 변의 블록탱크, (344j)갑(A B C), 삼각형 블록탱크, (344k) 을(A B "C),삼각형 블록탱크, (344l) 병(A R S),삼각형 블록탱크, (344m) 무(A Q T),삼각형 블록탱크, (344n) 갑 자(A O B),삼각형 블록탱크, (344o) 을축(A N W),삼각형 블록탱크, (344p) 병인(A M X),삼각형 블록탱크, (344q)차(D E)변의 블록탱크,(344r)카(B D)변의 블록탱크,(344s)타(C E)변의 블록탱크,
(345)표준형 글랜드패킹 또는 글랜드, (346) 주액랜턴링부착패킹, (347)랜턴패킹, (348) 2중 글랜드형 패킹, (349) 드로틀부시부착패킹, (350) 냉각수출구, (351) 봉수, (352) 냉각수 입구, (353) 슬리이브내면 냉각병용 워터재킷부착패킹, (354) 슬리이브의 내부 냉각실, (355) 보조글 랜드, (356) 누설액의 냉각실, (357) 글랜드 패킹짜는 방법, (358) 여덟가닥짜기, (359) 봉지짜기, (360) 격 자짜기, (361) 플래싱구멍, (362) O링, (363) 스톱더, (364) 중동링, (365) 밀봉단면, (366) 시이트링, (36 7) 피동링, (368) 퀀칭, (369) 쿠울링, (370) 되돌림관, (371) 핸들(Handle), (372) 격벽, (373) 축방향의 드러스트 하중, (374) 임펠러 전면에 작용하는 압력, (375) 임펠러 뒷면에 작용하는 압력, (376) 밸런스호울 ,
(377) 흡입압력, (378) 배면압력, (378) 밸런스구멍, (380) 전면웨어링, (381) 토출압력,(382)배면 베어링 링,(384)뒷날개, (385)뒷날개 설치로 인한 압력분포와 임펠러,(386)다단펌프의 임펠러 배치,(387)수주분리,(388)수주결합,(389)수격작용,(390)축봉부,(391)냉각방식의 매커니컬시일,(392)스트레이너,(393)수격펌프,(394)옥상소방운전실 또는 크레인운전실,(395)높고 낮은 산,(396)폴저엔코 드(Pulse Encoder),(397) 스피드콤멘드(Speed Command),(398) 모터스피드 그리고 변속기,(399) 디스크 브레이크(DISC Brakes),(400) 방파제 겸용 방제탱크,(401) 안전로프그물망, (402)공기 압축실(Air Chamber),
(403) 슬루우브 밸브,(404)밸브몸통,(405)밸브덥개,(406)슬루우스밸브,(407)패킹누르게,(408)패킹누르게 너트,(409)밸브,(410)핸들,(411)핸들너트,(412)패킹, (413)웨지게이트밸브,(414)단체밸브,(415)플렉시블밸브,(416)패럴렐 슬라이드밸브, (417)더블 디스크 게이트밸브,(418)스톱밸브,(419)플랜지형 글로우브밸브,(420)플랜지형 앵글밸브,(421)몸통,(422)본네트 덥개,(423)디스크,(424)덥개붙임밸브 시이트,(425)밸브대,(426)밸브 누르개,(427)핸들,(428)덥개 끼움링,(429)패킹누르개링, (430)패킹 누르개,(431)나사 끼움형,(432)덥개 보울트,(433)패킹 누르개 보울트, (434)핀,(435)덥개 보울트용 너트,(436)패킹 누르개 보울트용너트,(437)핸들 너트, (438)멈춤나사,(439)와셔,(440)패킹,(441)가스킷,(442)밸브누르게,(442a)평면누르게,(442b)원뿔누르게,(442c)구면누르게,(442d))스터트누르게,
(443) 콕1형 (444) 콕2형,(445) 청동나사넣기 메인콕,(446)주철플랜지형 글랜드형,(447)청동나사넣기 글랜드콕,(448) 삼방콕,(449) 사방콕,(450) 핸들콕,
(451)첵 밸브,(452)스윙형 첵밸브,(453)리프트형 첵밸브,(454)첵밸브몸통, (455)덥게,(456)디스크,(457)디스크 핀,(458)플러그,(459)조정밸브,(460)감압밸브, (461)파이로트 작동 자력식감압밸브,(462)2 차측 감지구멍,(463)다이어프램,(464) 파이로트밸브,(465)배기연돌,(466)메인밸브,(467)메인밸브스프링,(468)조정스프링,(469)오 토압력조절밸브,(470)나사형 오토 압력조절밸브(a),(471)플랜지형 압력조절밸브(b)
(472) 안전밸브, (473)스프링식 안전밸브,(474)리리이프식 안전밸브,(475) 증기용 포프 스프링식 안전밸브, (476)포프식 안전밸브,(477)온도조절밸브,(478) 오토 급수기,(479)오토 급수기(a),(480)오토수준 조정기,(481)공기빼기밸브,(482) 오토 열동형증기용 공기 배기밸브,(483)바켓트 온수형 오토공기 배기밸브,(484) 냉매배관용 밸브,(485)냉매스톱 밸브,(486)팩드밸브,(487)팩레스밸브,(488)팩레스 밸브,(489)팽창밸브,(490)다이어후렘형 팽창밸브,(491)벨로우스형 팽창밸브,(492)부자 밸브,(493)냉매용 압력조정밸브,(494)전자밸브,(495)오토 급수밸브,(496)일반형 수전용 수도꼭지,(497)지수선,(498)분수전,(499)볼탭,
(500)해양원자력발전소의 선체안전 보존용 피뢰침,
(501)나사 이음형 Y형 스트레이너 외형도(a) 단면도(b), (502) U형 스트레이너,(503)V형 스트레이너,(504)관 고정금속,(505)터언 버클부 지지밴드,(506)지지밴드,(507)로울러부 지지밴드,(508)수직관 매몰용 밴드,(509)철재 안경밴드,(510)바닥밴드,(511)트랩,(522)앵글형 열동식 트랩,(523)스트레이트 열동식 트랩,(524)버 키트 트랩,(525)상향식 버키트 트랩,(526)하향식 버키트 트랩,(527)플로우트 트랩, (528)임펄스 증기트랩,(529)수도꼭지몸통,(530)패킹상자,(531)패킹누르게,(532)꼭지대,(533)핸들,(534)디스크,(535)디스크패킹,(536)내수패킹,(537)내노화성물건 패킹,(538)테프론막,
(539)열팽창이 큰 금속,(540)열팽창이 작은 금속,(541)타임머 또는 레벨스위치,(542)하이레벨 알람,(543)베이컴 페일루어 알람,(544)스멀 릴레이 알람,(545) 알람 리셋트 버턴,(546)로워 레벨스위치,(547)플랩(flap;밸브의 혀),(548)사운 드 캡,(549)첵 노즐,(550)루우버 카버,(551)플로이트 인셔어트 스위치,(552)지시눈금스케일,(553)오우버 플로워 콘넥션,(554)벤트 파이프 콘넥션,(555)플랜지 콘넥션, (556)이중비닐 개방형 침바늘,(557)솔레노이드밸브 몸체,(558)카버,(559)스폴, (560)스플 패킹,(561)파이로트,(562)코일,(563)콘넥터,(564)메니 폴드(L;PTY8"대유량형),(565)매니 폴드(S;M5소유량형),(566)나사볼트,(567)공기호스 결속구 유니온 카플링,(568)유니온 몸체결속 카플링,(569)2위치 싱글,(570)2위치 더블,(571)LL; 중앙 수직형,(572)L; 수직형,(573)수평형; M,(574)F; 피팅 포함,(575)도시기호 싱글,(576)더블,(577)에이 취,(578)아이,(579)제이,(580) 마이크로 스위치,(581) 직접 배관형,(582)베이스 배관형,(583)파이어 댐퍼,(584)댐퍼 스핀들,(585)닥터 벤츄레이션,(585a)닥터 벤츄레이션 흡입구,(585b)닥터 벤츄레이션 배출구,(586) 몽골 피에의 열기구,(587) 블량샤르의 열기구, (588) 켈리의 열기구,(589) 증기비행선,
(590) 교각겸용 이중구조 지주블록탱크,
(591) 지주탱크 상단의 바지선선체,
(592) 지주탱크 하단의 바지선선체,
(593) 소형의 해양원자력발전소의 부양식독,
(594) 중형의 해양원자력발전소의 부양식독,
(595) 대형의 해양원자력발전소의 부양식독,
(596) 이중구조내부블록탱크,
(597) 고장력 스테인레스강의 철판,
(598) 이중구조블록탱크,
(599) 이중구조 외부블록탱크,(600) 블록탱크용 제 1보조형강,(601) 블록탱크용 제 2보조철판 ,(602)제 1보조형강과 제 2 보조철판의 모서리부위 용접 결함을 해소 시키기 위해 절단된 부위 스냅홀,(603)블록탱크 선체 분해결합 휴대용 러그 연결축 볼트,(603a)볼트의 나사산,(604)블록탱크 선체 분해결합 휴대용 러그 연결축 분해결합 너트,(603b)너트의 나사산,
(605)블록탱크 선체 분해결합용 제 2 보조 철판 수직격벽,(606)블록탱크 선체 분해결합 휴대용 러그 핀 연결축,(607)블록탱크 선체 분해결합 휴대용 러그,(608)블록탱크 선체 분해결합 휴대용 러그 핀,(609)블록탱크용 선체 분해결합용 제 2 보조철판 수평격벽,(610)블록탱크 선체 교통장치용 격벽맨홀, (611) 인공위성,(612) 우주로켓,(613)블록탱크 블록단위 선체 분해결합용 러그힌지소켓,(614)블록탱크 블록단위 선체 분해결합용 대형플랜지,(615)대형플랜지 접속연결구 접합부위 가공홀 또는 러그 가공홀작키베드 가공홀,(616)계류장치 부양식독 바지선선체 균형 조절장치용 작키베드,(616a)블록탱크 블록단위 선체 분해결합 위치이동 조절장치용 러그 장공홀,(617)블록탱크 선체 분해결합 이중관 구조 탱크교각 건설용 부교식 새들 형틀,(618)블록탱크 선체 교통장치용 가이드레일, (619) 헬리콥터 정류장,(619)블록탱크 블록단위 선체 분해결합조절장치용 유압회전실린더기계 또는 블록단위 선체의 드릴 선반 로터리 실린더기계의 랙＆ 피니언형(NRP) 실린더기계,
(620)유압회전실린더(로터리 실린더[랙＆피니 언 형-NRP]),
(621)블록탱크 블록단위 선체 분해결합조절장치용 밴드 지그대,
(622)블록탱크 블록단위 선체 부침조절장치용 벨러스터 버터플라이밸브,
(623)블록탱크 블록단위 선체 분해결합조절장치용 유압실린더 유압작키,
(624)블록탱크 선체 교통조절장치용 유압 실린더 도어 또는 블록탱크 블록단위 선체 분해결합조절장치용 유압실린더기계.(625)마개철판,
(626)화력발전소,
(627) 엔진제어시스템용 엔진제어모듈,(628)부이깃대 고무풍선,(629)밧줄용 로프,(630) 로프 매듭갈고리,(631)비상계단,(632)승강기용 앨리베이트,(633)콘베이어,(634)침몰선박 인양선의 침몰방지 체류선,(635)진공펌프,(636)예인선,(637)반잠수작업선,(638)볼라드,(639)앙카,(640)앙카용 체인,(641)송풍기 또는 쿨링팬,(642)공기 보온용의 히터팬,(643)인공위성발사대,(644)계류탑,(645)전기자석마그넷,(646)우주로켓발사대, (647)헬리콥터,(648)체인블럭,(649)황토세멘트혼합장비 믹서기계,(650)애자,(651)크레인 붐대, (652)크레인 붐걸고리,
(653)우라늄 239,(653a)우라늄 238,
(654)물,(654a)경수,(654b)중수 또는 가압중수,
(655) 항상 같은 방향으로만 흐르는 전류인 직류, (656) 시소가 오르내릴 때마다 흐름의 방향이 바뀌는 전류인 교류,
(657) 중간 열교환기 또는 1차주냉각계통 중간 열교환기,(657a)2차냉각 계통출구,(657b)저온 헤드,(657c)2차냉각재입구,(657d)지지판,(657e)중앙배관,(657f)외측환상부,(657g)압력용기,(657h)단열재,(657i)고온 헤드,(657j)혼합기,(657k)1차계통가스 입구,(657l)1차계통가스출구,(657m)단관,(657n)내압관,(657o)단열층,(657p)고온가스통로,(657q)라이나,(657r)2중관,(657s)내압관,(657t)저온가스통로,(657u)내관,(657v)고온가스통로,(657w)라이나,(657x)단열층,,
(658)열교환기,
(659)전류가 잘 흐르지 않는 니크롬선,(660)전구몸체,(661)베이스,
(662)넵투늄,
(663)필라멘트,(664)유리,(665)형광 방전관,(666)점등관,(667)방전,(668)탄소막대,(669)양극(플러스;(+)로 표시함),(670) 음극(마이너스; (-)로 표시함),
(671) 연료집합체,
(672) 원자력발전소,(672a) 어도터널,
(673)시이소 중심축 프레임,
(674)양성자,
(675)중성자,
(676)감속재 또는 감속재용기,
(677)추코트 반도,
(678)하천,(678a)총낙차,(678b)방수로,(678c)유입식 발전소의 개념도,(678d)저수지식 발전소의 개념도,(678e)조정지식 발전소의 개념도,(678f)조력발전의개념도,(678g)취수구,(678h)상부조정지,(678i)하부조정지,(678j)가역식펌프수차,(678k)발전력,(678l)양수전력,(678m)양수,(678n)발전,(678o)조력조정지,(678p)한강수계에서의 각발전소위치구성도,(678q)화천 수력발전소,(678r)소양강 수력발전소,(678s)충주 수력발전소,(678t)춘천 수력발전소,(678u)의암 수력발전소,(678v)청평 수력발전소,(678w)팔당 수력발전소,(678x)소양강,(678y)남한강,(678z)괴산 수력발전소,
(679)제방,(679a)토질차수벽,(679b)상류측 록필,(679c)필터,(679d)본체 록필,(679e)부벽댐,(679f)표면차수판,(679g)부벽,(679h)이용수심,(679i)중공부,(679j)주변전실,(679k)표층콘크리트,(679l)물의위치에너지,(679m)물의운동에너지,(679n)기계에너지,(679o)전기에너지,(679p)이론수력,(679q)수차출력,(679r)발전기출력,(679s)수력발전의 개요도,(679t)댐식 발전소의 개념도,(679u)스크린,(679v)취수탑,(679w)볼탭밸브,(679x)입구밸브,(679y)주요기기,(679z)주요변압기,
(680)댐,(680a)저수지 또는 조정지,(680b)취수댐,(680c)양수댐,(680d)양수식,(680e)양수발전,(680f)댐수로식,(680g)댐식,(680h)수로식,(680i)압력수조,(680j)조압수조,(680k)침사지,(680l)무압수조,(680m)상수조,(680n)취수설비,(680o)도수설비,(680p)발전설비(양수),(680q)방수설비,(680r)고수위,(680s)저수위,(680t)암벽,(680u)상류면보호층,(680v)배수층,(680w)토질재료,(680x)기초암반,(680y)흙댐, (680z)암석댐,
(681)연료피복재,(682) 피복관 또는 지르칼르이관,
(683)핵연료펠릿,
(684) 전압, (685) 전력, (686)전원의 출구, (687)전원의 입구,
(688)원자로건물 또는 격납건물 또는 콘크리트 방호벽, (688A)원자로건물,(688B)터어빈건물,(688C)제어건물,(688D)보조건물,(688E)디젤발전기건물,(688F)핵연료건물,(688G)폐기물건물,
(689)연료봉,(689a)연료다발조절,(689b)상단노즐,(689c)연료막대조절,(689d)연료막대,(689e)스프링클립조립,(689f)하단노즐,(689g)연료봉후단 캡,(689h)플루늄,(689i)홀드다운스프링,(689j)우라늄 다이옥시드 연료 펠렛,(689k)가스캡,(689l)지르칼로이 크라우딩,
(690)초고압 변전소,(691)1차 변전소,(692)송전소 내부 중심에 7가닥의 강철선,(693)54가닥의 알루미늄선,(694) 연료호스,(695)송전선,(696)해양터널 횡단철도 변전소,(697)중간 변전소,(698)대단위 공장,(699)중단위 공장,(700)2차 변전소, (701)소단위 공장,(702)가정(태양열 주택이 포함됨),(703)스탭발판 걸고리,(704) 전선 균형용 케인크의 초고압 전선 균형애자,
(705)핵폐기물처리 관제조공정의 분배축,(706)소구경 전기저항 용접관,(707)원재료,(708)언코일링,(709)레벨링,(710)사이드트리밍,(711)절단과 대강연결,(712)성형,(713)용접과 내외면 비드제거,(714)초음파와 와류탐상시험,(715)용접부열처리,(716)공냉,(717)수냉,(718)진원성형,(719)절단,(720)평평도시험,(721)구조관,(722)교정,(723)중간적재,(724)유도가열로,(725)에스 알엠(SRM),(726)열간절단,(727)면취,(728)수압시험,(729)초음파와 와류탐상시험,(730)무게와 길이측정기,(731)육안 및 치수검사,(732)나사,(733)도유,(734)일반 배관용,(735)아연도금,(736)아연도 강관,(737)보일러 튜브,(738)냉각대,
(739)중구경 케이지 성형 전기저항 용접관,(740)코일마게 철판원재료,(741) 사이드 트라밍,(742)케이지 성형,(743)송유관,(744)초음파 탐상시험,(745)진원성형,(746)송유관(석유산업용 강관),(747) 대구경 강관,(748)엣지 밀링기계,(749)3롤 밴딩기계,(750)포스트 밴딩기계,
(751)가용접,(752)내면용접,(753)백가후징,(754)외면용접,(755)관단 싸이징, (756)관단면취,(757)X-선시험,(758)냉간 익스팬딩,(759)마킹.포장.출하,(760)스파이랄 용접강관,(761)언 코일링,(762)구조관과 강관말뚝,(763)비도복 배관용,(764) 외면 브라스트 크리닝,(765)내면 브라스트 크리닝,(766)내면도장,(767)1차 도장, (768)도장과 도복,(769)도복장 강관,(770)초음파와 X-선검사,
(771)해양터널장치용 내부 전동차,
(772)원자력발전기 또는 터빈발전기,
(773)원자력발전기용 회전하지 않는 전기자코일,
(774)원자력발전기용 회전하는 회전자전자석코일,
(775)송전선,(776)송전철탑,(777)개폐시설,(778)보일러 또는 주전자,
(779) 증기파이프,(780) 증기 또는 강력한 기체의 고온고압 증기 출입구,
(781)생산전력 중앙제어실 ,
(782)송전측정실 트랜스 포머룸, (783) 보일러 작동 노심,
(784) 원자, (785) 전자,
(786) 증기건조기,
(787) 자석,
(789) 탈기기,
(790) 수증기를 냉각시켜 물이 되게 하는 장치의 쿨링기기인 복수기,(790a)복수기 리리이프식 안전밸브,(790b)복수기안전밸브,(790c)복수기몸체,
(791) 노심 또는 핵 연료실,(791a)노심지지방벽,(791b)핵분열,
(792) 드럼,
(793) 재열기,
(794) 이중구조 블록탱크 집진기 또는 화력발전소의 집진기,
(795) 중유탱크, (796) 중유,
(797) 유조선 또는 화물선,
(798) 제어봉,(798b)제어봉 구동축,(798c)제어봉 압지강판,(798d)제어봉 심출봉강,(798e)제어봉 안내관,(798f)제어봉 구동축,(798g)제어봉 인장용 봉강,
(799) 방사성 폐기물,
(800) 플루오르화 우라늄,
(801) 플루토늄,
(802) 비등수형 원자로설비,
(803)가압수형 원자로설비,
(804)기체냉각로 원자로설비,
(805)다목적 고온가스로 원자로설비,(805a)1차 냉각계통이 수납된 페블-베드형 고온가스로의 내부구조,(805b)열차폐체,(805c)관통구 마개,(805d)보조 순환장치),(805e)제어봉 저장통,(805f)홀드다운 플레이트,(805g)제어봉 구동장치,(805h)보조 순환장치,(805i)보조 열교환기,(805j)노심지지 구조물,(805k)프리스트 레스트 콘크리트 원자로용기,(805l)PCRV 안전밸브,(805m)연료 투입구,(805n)He 순환장치, (805o)PCRV 지지 구조물,(805p)페블-베드형HTR-모듈원자로의단면구조,(805q)구형연료배출관,(805r)붕소구정지계,(805s)반사체영역제어봉,(805t)구형연료투입관,(805u)급수관,(805v)주증기관,(805w)가스순환기,(805x)고온가스배관,(805y)표면냉각기,(805z)단열재,
(806)신형전환로 원자로설비,
(807)증기탑,
(808)격납용기,
(809)정화장치,
(810)증기발생기,(810a)터빈발전기로가는스팀출구,(810b)급수노즐,(810c)2차냉각수,(810d)진동억제봉,(810e)세관지지강관,(810f)세관덮개,(810g)세관다발, (810h)세관강판,(810i)분리강판,(810j)1차측 출구,(810k)1차측 입구,(810l)열교환세관,(810m)냉각수유로,(810n)증기발생기 세관,(810o)증기발생기 내부동체,
(811)원자력발전설비부,(811a)원자력 발전 핵폐기물 처리부,(811b)전력 생산제조부,(811c)건설기계의 교통운송부,(811d)동력을 전달하는 동력 전달부,(811e)원전가동 설비안전 통제 관리생산 전장부,(811f)전자제어조절장치 건설기계조절부,(811g)나사조절부,
(812) 농축우라늄 또는 우라늄 235,
(813)원자로압력용기,(813a)압력용기덥개,(813b)압력용기상단덮개하부,(813c)압력용기원통덥개,(813d)압력용기원통덥개상단,(813e)압력용기원통덥개상단부,(813f)입구노즐,(813h)디플렉토철판,(813i)공기쳄버실,(813j)버플철판,(813k)물,(813l)스프레이션 풀,(813m)밴트파이브,(813n)연료조립,(813p)압력용기원통덥개상단,하단조립부,(813q)드라이벽,(813s)압력용기원통덥개하단조립부,(813t)압력용기원통덥개상단조립부,(813v)연료봉철판,(813w)출구노즐,(813y)노심지지조립,(813z)제어봉 안내관 조립대,
(814) 가압기,(814a)스프레이노즐,(814b)가압보호용기,(814c)가압조절밸브,
(814d)스팀경계,(814e)가압용기몸체,(814f)냉각수입구,(814g)가열기히터,
(815) 원자핵,(815a)핵자, (815b)핵력,
(816) 냉각재 또는 1차계나트륨 또는 2차계나트륨,(816a)냉각재입구 노즐, (816b)냉각재출구 노즐,
(817) 소음기,
(818) 기수분리기,
(819)유압탱크,(819a)열판,(819b)유면계(오일 포트장),(819c)드레인(배유구),(819d)탱크밑판,(819e)격판(버플 플레이어),(819f)석션 스트레이너,(819g)위판 패킹(내유고무),(819h)흡입구패킹,(819i)흡입구뚜껑,(819j)탱크위판,(819k)에어 블리저 겸 주유구(콤비네이션 에어 블리저),(819l)탱크각판,(819m)청소창 패킹(내유고무),(820)유압모터,(821)유압펌프,(822)로드앤드피스톤시일,(823)피스톤시일,(824)부프시일,(825)웨어링,(826)스라이드링,(827)디유부시,(828)오링,(829)로드시일,(830)백업시일,(831)로드시일 ＆ 백업시일,(832)다스트시일,(833)핀다스트시일,(834)다스트위프시일,(835)부프링(836)피스톤링,(837)다스트링,
(838)고속증식로 원자로설비,
(839)등변산형강 또는 부등변산형강,(840)기상관측장비레이다,(841)원유(기름),(842)해저광물뜰채바스켓,(843)심해저탐색 수중조명,(844)버킷 또는 빠레트,(845)스큐르 드릴의 심해저 굴착장비용 굴착기,(846)앙카 대체용 쇄기 크랭크,(847)착암기 또는 네트,(848)엑츄레이트,(849)해저광물 뜰채용 공기주머니,(850)턴박클,(851)교각용 레벨기초 밑받침대,(852)고정용 쇄기 받침목,(853)아아크용접기 또는 아르곤용접기,(853a)용접연결선,(853b)용접각장,(854)파이프 랙,
(855)불도저,(855a)크롤러형 도저,(855b)휠형 도저,(855c)스트레이트 도저,(855d)딜터 도저,(855e)앵글 도저,(855f)힌지 도저,(855g)트리 도저,(855h)레이크도저,(855i)하이드릭리퍼,(855j)도저의동력전달장치,(855k)캠기타장치용 흡입펌프,(855l)기관,(855m)냉각계통,(855n)최종기어장치,(855o)기동륜의스프로킷, (855p)유동륜의아이들러,(855q)조항클러치,(856)굴삭기,(856a)백호,(856b)파워셔블,(856c)드래그라인,(856d)어스드릴,(856e)크램셸,(856f)스키머,(856g)리퍼와 루터, (857) 로더, (858) 지게차,(859)스크레이퍼,(859a)견인식 스크레이퍼,(859b)동력식 스크레이퍼,(859c)에어프런,(859d)이젝트,(859e)볼,(859f)커팅테지,(860)덤프트럭,(860a)트레일러,
(861)크레인 또는 기중기,(861a)기중기 구조의 각부명칭,(861b)익스턴트케이블,(861c)하중계,(861d)브리들,(861e)붐벡스들,(861f)메이로프,(861g)붐호이스트로프,(861h)상부프레임,(861i)하부프레임,(861j)호이스트로프,(861k)전방드럼,(861l)중간드럼,(861m)후방드럼,(861n)균형추,(861o)케이블크레인,(861p)기중기의 6개 전부장치,(861q)갈쿠리(Hook)장치,(861r)조개(Clamshell)장치,(861s)삽(Shovel)장치,(861t)긁어파기(Dragline)장치,(861u)도량파기(Trenchhoe)장치,(861v)기둥박기(Pile driver)장치
(862)모터그레이더,(862a)머플러,(862b)기관플라이휠,(862c)냉각팬,(862d)전후전달러치,(862e)트랜스러치,(862f)고정기어식변속기,(862g)주차브레이크,(862h)차등기어,(862i)트랜스퍼카아중성기어감속기,(862j)디스크 브레이크,(862k)그레이더의 외부구조,
(863)롤러,(863a)진동 롤러,(863b)소일콤팩터,(864)노상 안전기,
(865)콘크리트배칭플랜트,(865a)콘크리트호퍼,(865b)운반장치차징차트,(865c)조정판,(865d)물멧처,(865e)대칭호퍼,(865f)스케일 프레임,(865g)저장 빈,(865h)종합벨트콘베이어,(865i)턴헤드,(865j)버킷엘리베이트,(865k)운반시멘트차드,(865l)조정판,(865m)기록장치,(865n)원형믹서,(865o)시멘트 사일로,(865p)스쿠르 콘베이어,
(866)콘크리트 피니셔,(866a)스쿠르 스프레이,(866b)제1 스크리드,(866c)진동기,(866d)피니싱 스크리드,(866e)가이드롤러,(866f)가이드레일,(866g)마무리면,
(867)콘크리트스프레더,(868)콘크리트믹서트럭,(869)콘크리트펌프,(870)아스팔트 믹싱 플랜트,(871)아스팔트 피니셔,
(872)아스팔트살포기,(872a)동력피동펌프,(872b)밸브제어,(872c)분무바,(872d)버니,(872e)버림관,(873)골재 살포기,
(874)쇄석기,(874a)자이레토리크러셔,(874b)새시프레임,(874c)피더호퍼, (874d)진동그리스리피터,(874e)파쇄헤드부의 1차 조크러셔, (874f)파쇄실 후미의 2차 조크러셔, (874g)진동스크린,(874h)드럼엘리베이터,
(875)공기압축기,(876)천공기,(877)항타와 항발기,(878)사리 채취기,
(879)준설선,(879a)펌프준설선,(879b)버킷준설선,(879c)스팟드시어,(879d)운전실 또는 조정실,(879e)레드시어,(879f)스팟드,(879g)블러스트탱크,(879h)블러스 트펌프,(879i)레드,(879j)기관실,(879k)디퍼 준설선,(879l)그래브 준설선,(879m)버킷구동장치,(879n)후부스팟드,(879o)스팟드윈치,(879p)버킷,(879q)좌우의전부스 팟 드,(879r)디퍼,(879s)윈치,(879t)닻줄창고,(879u)벨트 컨베이어,(879v)그래브,
(880)별도의 지정 건설기계,(882)파일드라이버,(882a)붐, (883) 디젤파일 해머, (884)증기해머, (885)유압크레인,(885a)피스톤 모터,
(886)타워크레인,(886a)가이 데릭 구조의 각부명칭, (886b)가이 데릭,(886c)주측,(886d)붐,(886e)붐호일,(886f)턴버클,(886g)공망,(886h)3각데릭,(886i)주측,(886j)붐,(886k)붐호일,(886l)레크,
(887)드레그 크레인,(887a)드레그 크레인의 구조,(887b)호이스트케이블,(887c)덤프케이블,(887d)버킷,(887e)하부붐,(887f)레터렉트케이블,(887g)케이블롤러,(887h)붐케이블,(887i)케이블롤러,(887j)붐 호이스트 케이블,(887k)케이블드럼,(887l)케이블드럼,(887m)평행추,
(888)클램셀 부착물을 가진 크레인,(888a)홀딩 라인,(888b)개폐라인, (888c)클램셀버킷,(888d)상부프레임,(888e)하부프레임,(888f)랙라인,(888g)로프가이드,(888h)붐탠던트,(888i)브리들,(888j)붐 호이스트 로프,(888k)전방드럼,(888l)후방드럼,(888m)평행 추,
(889)머캐덤롤러,(890)탠덤롤러,(891)탬핑롤러,(892)타이어롤러,(893)트랙터,(894)트레일러,(895)램,(896)리드,(897)냉각수냉크,(898)파일,(899)헬밋,(900) 연료펌프,(901)캠,(902)연료탱크,(903)기동장치,(904)붐전핀,(905)캐드워크,(906) 어댑터,
(907)어군탐지기 소나,
(908) 원유시추용 드릴링머신의 로터리 테이블선반기계,
(909)망간 단괴,
(910)뜰채그물,(911)흡입채집기계,(912)해저광물채취로봇,
(913) 잠망경,(914)고무풍선,(915)와이어로프 체인,
(916)이중구조 배관라인 자동공압식 밸브운송장치,
(917)코아드릴,
(918)비이오 피이 스키드,(919)고무타이어,(920)버너 붐,
(921)유해적조 미생물,(922)무공해의 천연가스,
(923)공기노즐,
(924)광물채집 뚜레박,(925)상승기류,(926)하강기류,(927)황사먼지 또는 비누거품용 황토혼합물,
(928)이중구조블록탱크 관교각,
(929)핵폐기물처리이중구조블록탱크 관교량,
(930)화학물질,(931)시멘트,(932)어족자원 확보용 그물,
(933)방재선 또는 방제선,(934)원유시추선,(935)시이소 핸들용 지렛대,
(936)시추공,
(937)이중구조블록탱크 관교량,(938)전극판 아노드,(939)냉각공기방울,(940)비트,
(941)핵폐기물처리 이중구조블록탱크 해양터널 교통장치,
(942)타워크레인 시이소 크레인 붐대.
(943)해양 시이소수력발전소,(943a)수력발전 장치용 펌프 수차,(943b)대형수력발전 장치용 펠톤 수차,(943c)대형수력발전 장치용 프란시스 수차,
(944)대형수력발전기 시이소 수력발전설비,(944a)수력발전장치용 회전속도 검출기,(944b)교류발전기의 전동기 계자 코일에 전류를 공급하는 직류발전기용 여자기,(944c)고리관 깃을 밀어 넣는 기기,(944d)상부 회전축받이,(944e)회전축받이를 밀어넣는 기기,(944f)고정자 코일,(944g)고정자 프레임,(944h)중심부 고정자,(944i)저속냉각기,(944j)제동장치 링,(944k)제동장치 또는 잭,(944l)저속 회전축받이,(944m)엔진발전기,(944n)터빈회전축받이,(944o),(944p)회전축받이,(944q)날개바퀴,
(945)지중선로 방재노즐 또는 공유매립지,
(946)해저선로배선 또는 공유수면매립지,
(947)부침조절장치용 콘 테 이 너 내부용의 공기투입용 고무 튜우브,
(948)용광로,(948a)용광로의 노재 벽돌,
(949)선체의 잠수 위치조절 이동장치와 잠수 부력 조절용의 납덩이 추,
(950)온도 자동감지센서용 열전 대 온도계 스위치,
(951)유해적조 흡입 집진기용의 뜰채 바스켓 또는 파 레 토,
(952)물의 위치에너지조절장치용 무동력펌프의 수격펌프,
(953)군사장비 잠수함,
(954)레이저 컴퓨터 절단기,
(955)핵 폭탄보다 더 강력한 무기의 평화 보존형 메시지 포 토 삽,
(957)해양 풍력발전소,(957a)풍력발전기용 풍차,
(958)기상예보관측,
(959)삿대 대체 사용품돛,
(960)인공위성 일기 예보 정보 수집기계,
(961)우주로켓,
(962)인공위성
(963)평화주권선,(964)석유,(965)다이아몬드,(966)철,(967)주석,(968)석탄,(969)농기구,(970),(971)군수물자,(972)국경지역,(974)함선,(975)잠수함,(976)전투기,(977)함정,(978)핵항공모함,(979)유류송유관,(980)가스배관,(981)금과은,(982)핵연료,(984)유리,(985)마노,(986)호박,(987)진주,(988)위령탑,(989)국제연합국가,(990)국제연합기구,(991)원폭,(992)수소폭탄,(993),(994)스위치 작동용 추와 감지센서용의 무게감량용 납덩이추에 잠수원 잠수부력 조절용의 납덩이추,(995)잠수정,(996)침몰선박,
(1005)증기발생기의 증발기구조,(1006)증기출구관,(1007)증기출구실 동체 외관,(1008)습도계 관,(1009)증기출구관,(1010)액면계 관,(1011)나트륨 냉각계 입구 관,(1012)상부 평판,(1013)연결봉,(1014)냉각수 누설 검출관,(1015)2차 아르곤가스관,(1016)스커트,(1017)나선형 열교환 세관,(1018)나트륨 냉각재 출구관,(1019)반구형하부동체,(1020)익수관,(1021)덥개,(1022)동체외관,(1023)나트륨 통로,(1024)나트륨-물 반응 생성물 방출관,(1025)내관,(1026)모니터 링 입구관,(1027)급수 입구관 판,(1028)급수 입구관,(1028a)급수 입구실 외관,
(1029)핵기지,(1030)해체시설,(1031)피트의잠정저장,(1032)MOX가공,(1033)MOX연소로,(1034)폐기물의혼합유리고화체,(1035)고준위폐기물,(1036)최종처분장,(1037)장기저장,(1038)깊은지하동굴,(1039)플루토늄처분을선택할수있는경로,(1040)핵무기해체에서플루토늄처분과정,(1059)핵분열,(1069)원자로 노재벽돌,(1070)이산화 우라늄,(1071)연구로,(1072)동력로,(1073)원자로증기취출계통,(1074)드레인펌프,(1075)가열장치,(1077)핵연료공업주기,(1078)인명구조용 복원력을 구비한 선박,(1101)거센풍랑파도,
도크선체갑판 상단부(SDU),도크선체갑판 중심부(SDM),도크선체갑판 상단부(S DL),기계실바닥표면 상단부(MFGU),기계실바닥표면(MFG), 기계실바닥표면 하단부(M FGL),지표면 상단부(GLU),지표면(GLL),지표면 하단부(GLD), 적도전선(EL), 북극(N P), 남극(SP),
경도(longitude;ld로 칭함),위도(latitude; lt로 약칭),
분사노즐 상단부(A), 분사노즐 몸체(B), 분사노즐 하단부(C),
도로지표면 상단부(GLU), 도로지표면(GLL), 도로지표면 하단부(GLD),
펌프 몸체(PB), 펌프 몸체 수직 라인(PPVL), 펌프몸체 수평중심라인(PBCL)
밸브 몸체 중심선(VBCL or PBCL),방화수수면 하단(WLD),방화수수면(WLL), 분출 수면(WLU), 해수면 상단부(SLU),해수면(SLL),해수면 하단부(SLD),
기계실 외부(Out of Merchinery Room;OMR),기계실(Merchinery Room ; MR),
기계실 내부(In of Merchinery Room ; IMR),(1) Nuclear waste treatment for nuclear power plants Dual structure of nuclear power plant facilities High-speed propagation furnace Reactor main body or nuclear power plant reactor main body,
(2) a control box of a multi-stage pump control panel, (3) a suction merging pipe, (4) a discharge joining pipe, (5) a pump isolation valve, (6) a pump backflow prevention check valve, (7) (10) Double-structured fire-fighting nozzle, (10a) Nozzle body by name "Nominal 100", (10b) "10", "10", "10", "10", "10", "10", and "10" 90 ", (10i) Title" 90 × 75 "(10j) Title" 75 × 65 "
(11) Fire nozzle frame, (12) Sensing sensor, (13) Cogs, (14) Piping or nozzle piping, (15) Clearance, (16) Tilt angle, (16a) Blade propelling angle, (19) a wire rope; (20) a machining hole; (21) a hooking lug or a portable lug;
(22) Jig or various types of jigs ("

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(23) Shackles (24) Bolts (25) Nuts (26) Washers (27) Outer blocks (28) Flange or hull bellows barring tank inlet inlet flange stop wire mesh (29) Couplings, (30) Coupling ring threaded body, (27) (36) High performance submersible pump, (37) High-performance submersible pump, (37) High-performance submersible pump, (37) Coupling water threaded body, (32) Gasket or rubber packing, (42) basket, (43) double vinyl tent or bag, (44) elbow or tee elbow, (38) discharge jet, (39) water film or curtain water film, (47) an inverter, (48) an inverter V, (49) an access pointer, (50) an internet network, (51) a control server of a multi-stage pump , (52) Monitor, (53) Pump control board or tug boat winch adjustment panel (55) a wireless communication control module of a short-range wireless communication device, (56) a display, (57) an electronic control device Aidey, (58) a switch input circuit, (59) (62) Power supply, (63) Display screen, (64) Analog input, (65) Digital input, (66) Each pump (67) Main switch button for on / off control, (67) Auxiliary switch button, (68) Multistage multi-stage pump display input or computer network input, (69) Current pressure value or set pressure value Pressure setting numeric nameplate, 71) Power line, (73) Disaster material mixer mixer, (74) Double pipe structure piping line, (74a) Inner block piping, (74b) External block piping, (75) Cloth gate, (76) Solenoid valve, (77) (78) Airship, (79) Gasbox, (80) Air Compressor, (81) Mobile Service, (82) Portable Terminal, (83) Low Pressure Shutoff Valve, (84) Emergency Valve, (8 6) a first pressure check sensor, 87 a second pressure check sensor, 88 an electronic control unit, 89 a disaster prevention piping line or pumping water line, 89 a vertical pumping water pipe, 89 b vertical downpipe pipe, ) Ball valve handle, (91) Drencher head, (92) Valve body inner disc, (93) Emergency siren, (94) Spark or lightning, the first source of ignition, (95) (100) paraffin nozzle stopper, (101) pressure gauge, (102) sensor bimetal, (102a) thermocouple configuration method, (102b) thermoelectric current generation, (102c) thermoelectric power Occurrence, (102d) measurement point, (102e) reference point,
(103a) thermocouple thermometer switch for the sensor, (103a) thermocouple thermometer configuration, (103b) temperature limit, (103c) temperature 1, (103d) scale of the ammeter temperature, (103m) potential difference occurs, (103h) the thermocouple and the compensating wire, (103i) the thermocouple contact, (103j) the thermocouple, (103k) the compensating contact, (103p) Protection pipe, (103p) High temperature object, (103r) Protection pipe, (103s) CISS, (103t) Temperature measurement terminal, (103u) Temperature measurement contact, (103v) Sheath, (103w) platinum resistance thermometer with protective tube, (103x) mica, (103y) platinum wire, (103z)
(104) level or pressure switch, (104a) diaphragm type pressure switch, (104b) pneumatic-sensor pressure switch, (105) flow meter for flow rate check, (106) motor control module, (108) Overpressure protection switch or switch box, (109) Air hose, (110) Air hose connection nipple, (111) Sprinkler head, (112) Reflector, 113) Fuses for fusible metal, (114) stop valves or water valves, (115) underground pipes, (116) steel towers or block steel towers, (117)
(120) Alarm valve, (121) Test valve, (122) High pressure water pump, (123) Lever block, (124) Fire extinguishers (fire extinguishers a, fire extinguishers b, fire extinguishers c, fire extinguishers D, fire extinguishers e, fire extinguishers f) ) Chain, (126) cylinder, (127) piston or piston pump, (128) fire extinguisher fixing pin, (129) bolt lock device, (130) life casting tube, (131) rope, 133) Anchor bolts, (134) Radio sonde, (135) Driving wheel rollers Dorure, (136) Regulate, (137) Tucker winches for control of water gate opening and closing with ropes or chains wrapped around the fuselage, (143) impeller, (144) diaphragm pump, (145) high pressure storage tank, (146) high pressure storage tank, (139) Propeller pump or propeller, (147) multistage screw air compressor and screw pump, (148) plunger pump, (148b) small shaft plunger pump, (148c) radial plunger pump, (149) steel beam, System or control system, (151) oil cooler, (153) hatch cover, (154) fire door, (155) gland packing, (156) mechanical seal or individual seal, (157) jet pump, (158) loess, (159) (160) Indoor fire hydrant box (161) Automatic fire hydrant, (162) Hose hanger, (163) Fume gas, (164) Carbon dioxide of incombustible gas, (165) Reinforced steel plate, (166) Match fire (167) screw tabs, (168) transit lines or fire fighting piping lines, (169) watertight ports, (170) internal coolers, (171) exhaust gases (174) gas land or burner, (174) carbon dioxide gas, (175) halon gas, (176) helium gas, (177) pyrophoric material, paraffin tape, (178) non-pyrophoric material (180) vinyl bag, (181) disaster air piping line, (182) rear cooler, (183) limit switch or limit switch, (184) unmanned camera (186) springs, (187) unmanned igniter spark lighters, ( 188) lifeboats, (189) head tanks for pressure tanks, (190) flexible high-pressure hoses or hydraulic hoses, (191) introduction or hydraulic pipes,
(193) a retaining ring, (195) a fan, (196) a body frame, (197) a front reinforcing steel plate, (198) a rotating shaft, (199) a rotor assembly 200 forward rotation bearing 201 stator assembly 202 motor protection casting frame 203 terminal box 204 lifting bolt 205 terminal box cover 206 rear drive bearing 207 rear (209) a fan cover or a protective cover, (210) a rotor iron core, (211) a stator iron core, (212) a stator winding,
(213) an active film gas hold-up device,
(214) filter,
(215) an exhaust tower,
(216) a radioactive storage tank,
(217) a filter,
(218) a radioactivity meter,
(219) Monitoring posts,
(220) drums,
(221) Isotropic steel beams,
(222) uranium mines,
(223) Yellow Cain,
(224) nuclear waste, (224a) solid nuclear waste, (224b) liquid nuclear waste, (224c) gas nuclear waste,
(225) Reinforced concrete mats,
(226) engine generator, (277) turbine rotary bearing,
(228) reprocessing plant,
(229) Conversion plant,
(230) Concentration plant,
(231) Conversion · Processing plant,
(232) Searchlight,
(233) Refineries,
(234) the air dryer, (235) the embers, (236) the flames, (237) the pillar,
(238) Double pipe structure of nuclear waste treatment of nuclear power plant Block Piping line Control shaft,
(239) Recirculation pumps,
(240) Pressure Control Pool,
(241) feed pump,
(242) circulating water pump or primary cooling system circulation pump,
(243) coolant pump or secondary cooling system circulation pump,
(258) V-belt, (253) plunger, (254) pin, (255) timer, (256) cable car, (257) an air valve, (258) a safety valve, (259) an automatic valve, (260) a drain valve, (261) a belt cover, (262) a suction filter, (263) (265) a main valve, (266) a forest, (267) a turbine or rotary vane, (268) an engine generator or flywheel, (269) a water intake or intake, (270) a watertight or discharge opening, 272) a pump power source, 273 a control power source, 274 an emergency operation circuit, 275 a DC power supply circuit, 276 a microcontrol unit, 277 a DIP switch setting circuit, 278 a display circuit, 279 (281) M / C drive signal contact output circuit, (280) Motor overload signal input circuit, (281) Inverter operation data input / output circuit, (282) Pressure sensing circuit, (283) External state input circuit, (285) a suction / discharge switch, (286) a bed frame,
(287) a cooling water or cooling water inlet, (288) an oil separation tank, (289) an intake valve, (290) a gear drive, (291) a dryer, (292)
(293), (293a), (293b), (293b), (293c) and (293c) the design water level, (293d) the water surface, (293e) the anchor section fixing section, B) a kind of a drencher head (a, b, c, d), (300) a vibration tank, (295) a tank tank, (296) a gate valve, (297) (301) drain, (302) reverse stop valve, (303) high pressure bowl tank, (304) amniotic pump, (305) butterfly valve for flow control, (306) sodium bicarbonate, (307) 308) Century fugu pump 309 Sewage pump 310 Spiral casing 311 Blowout pump 312 Hood valve 313 Pump 314 Pump 315 Float, (316) a ball pushing device, (317) a flexible carding, (318) a float switch, (319) a rear wing, (320) a scoop valve, (321) a sweep valve, (324) jet pump, (326) gear pump, (327) wing pump, (330) separation chamber, (331) magnet switch, (332) nuclear waste building, (333) building Or large building 334 Balance 335 Unbalance 336 Indoor fire pump 337 Rotary pump 338 Rotary rotator 339 Priming 340 Suction pump 341 ) Axial flow pump, (342) mixed flow pump, (343) viscous pump,
(344) Double structure block of nuclear power plant Connecting tank of manufacturing and installation process,
344b and 344c and 342b and 344c and 342b and 344c and 342c and 342c and 342c and 342c and 342c and 342c respectively correspond to the block tank 344b and the BC tank 344b, (344f) block tanks of side (A), (344h) and (AM) sides, (344i) block tanks of (A) (ABC), triangular block tanks, (344l) bottles (ARS), triangular block tanks, (344m) AQT, triangular block tanks, (A), a triangular block tank 344a, an ANW, a triangular block tank 344p, an AMX triangle block tank 344q, a DE tank block 344r, A block tank on the side of the car BD, a block tank on the side of the (CE)
(345) a standard gland packing or gland; (346) a liquid with a liquor lantern ring; (347) a lantern packing; (348) a double gland packing; (349) a packing with a throttle bush; (351), (352) cooling water inlet, (353) sleeve inner cooling water bottle jacket packing, (354) inner cooling chamber of sleeve, (355) auxiliary gland, (356) (367) O-ring, (363) stop, (364) how to weave gland packing, (358) eight strand weaving, (359) bagging weave, (360) (365) sealing ring, (366) sealing ring, (367) passive ring, (368) quenching, (369) cushioning, (370) returning tube, (371) Handle, (372) (373) the pressure acting on the front of the impeller, (375) the pressure acting on the back of the impeller, (376) the balance ball,
(387) the suction pressure, (378) the back pressure, (378) the balance hole, (380) the front wear ring, (381) the discharge pressure, (382) the rear bearing ring, (386) Impeller arrangement of multi-stage pump, (387) Order separation, (388) Order coupling, (389) Water hammer action, (390) Axial rod, (391) (395) Speed Command, (398) Speed Command, (398) High Speed Low Mount, (396) High Speed Low Mount, (396) Pulse Encoder, (399) DISC Brakes, (400) Combined Breakwater Control Tank, (401) Safety Rope Net, (402) Air Compressor, Air Compressor,
(403) a squeeze valve, (404) a valve body, (405) a valve cover, (406) a sluice valve, (407) a packing press, (408) a packing press nut, (409) (411) a handle nut (412) packing, (413) a wedge gate valve, (414) a single valve, (415) a flexible valve, (416) a parallel slide valve, A flange type glow valve, (420) a flange type angle valve, (421) a body, (422) a bonnet cover, (423) a disk, (424) a cover valve seat, (427) Handle, (428) Covering ring, (429) Packing pusher ring, (430) Packing pushbutton, (431) Screw-in type, (432) Cover bolt, (433) Packing pushbutton bolt 434 pin, 435 packing bolt nut, 436 packing nut bolt nut, 437 handle nut, 438 detent screw, 439 washer, 440 packing, 441 gasket, 442 (442a) plane press, (442b) conical press, (442c) spherical press, (442d)
(443) Cock 1 type (444) Cock 2 type, (445) Bronze threading main cock, (446) Cast iron flange type gland type, (447) Bronze threading gland cock, (448) ) Bangkok, (450) Handle Cock,
(451) check valve body, (455) hotplate, (456) disk, (457) disk pin, (458) plug, (451) check valve, (452) swing type check valve, (463) a pilot valve, (465) an exhaust stove, (465) a control valve, (459) a pressure reducing valve, (461) a pilot operated magnetic pressure reducing valve, 466) Main valve, (467) Main valve spring, (468) Adjusting spring, (469) Otto pressure regulating valve, (470) Screw type auto pressure regulating valve (a) )
(472) Safety valve, (473) Spring type safety valve, (474) Relief type safety valve, (475) Pope spring safety valve for steam, (476) Pope type safety valve, (477) 478) Auto water dispenser (479) Auto water dispenser (a), (480) Auto level regulator, (481) Air vent valve, (482) Air exhaust valve for auto heat steam, (483) Valve 488 refrigerant piping valve 485 refrigerant stop valve 486 feed valve 487 charge valve 488 charge valve 489 expansion valve 490 diaphragm expansion Valve 491 bellows type expansion valve 492 rich valve 493 refrigerant pressure adjusting valve 494 solenoid valve 495 auto water valve 496 water type faucet 497, An exponent line, (498) before the fraction, (499)
(500) Lightning rod for hull safety preservation of marine nuclear power plant,
(501) V-type strainer, (504) tube fixing metal, (505) turnbuckle support band, 506) Supporting band 507 Roller support band 508 Vertical tube for burying 509 Steel spectacle band 510 Bottom band 511 Trap 522 Angle thermal trap 523 (524) a bottom-up bucket kit, (526) a bottom-up bucket kit, (527) a float trap, (528) an impulse steam trap, (529) a faucet body, (530) (533) a packing, (531) a packing press, (532) a stick, (533) a handle, (534) a disk, (535) a disk packing, (536) a domestic water packing, (537) membrane,
(541) a high-level alarm, (543) a bay compile alarm, (544) a smooth relay alarm, (545) a high thermal expansion metal, (540) (546) low level switch, (547) flap, (548) sound cap, (549) check nozzle, (550) louver carver, (551) float (552) an indicator scale, (553) an overflow contact, (554) vent pipe connection, (555) flange connection, (556) double vinyl open needle, (557) solenoid valve body (568), (563) a connector, (564) a manifold L (PTY8 "large flow type), (565) a spool, ) Manifold (S, M5 ownership type), (566) Screw bolt, (567) Air hose coupling Union coupling, (568) Union body coupling Coupling, (569) 2 position single, (570) 571) LL; central vertical type, (572) L; vertical type, (573) horizontal type, M, (574) (581) direct piping type, (582) base piping type, (583) fire damper, (584) damper spindle, (587) ) Doctor Ventilation, (585a) Doctor Ventilation Inlet, (585b) Doctor Ventilation Exit, (586) Mongolia Phee Hot Air Balloon, (587) Bachelor Hot Air Balloon, (588) Kelly Hot Air Balloon, (589) Steam Airship ,
(590) Dual structure holding block tanks,
(591) Barge hull at the top of holding tank,
(592) Barge hull at bottom of holding tank,
(593) Lifelines of small-scale marine nuclear power plants,
(594) Lifelines of medium-sized marine nuclear power plants,
(595) Lifelines of large-scale marine nuclear power plants,
(596) Double structure inner block tank,
(597) High-strength stainless steel plate,
(598) Double structure block tank,
(599) Double structure external block tank, (600) First auxiliary steel for block tank, (601) Second auxiliary steel plate for block tank, (602) Corner welded part of first auxiliary steel and second auxiliary steel plate (603) Block Tank Hull Disassembly Portable Lug Connecting Axle Bolt, (603a) Bolt Thread, (604) Block Tank Hull Disassembly Portable Lug Connecting Axle Disassembly Coupling Nut, (603b) Nut Threaded,
(605) Block tank Secondary steel plate vertical partition for hull disassembly coupling (606) Block tank Hull disassembly portable lug pin connecting shaft, (607) Block tank Hull disassembly portable lug, (608) Block tank Hull disassembly portable (609) Secondary steel plate for disassembly of hulls for block tanks (610) Block tank Tank bulkhead manhole for hull transport equipment (611) Satellite, (612) Space rocket, (613) Block tank block unit (614) block tank block unit large hull flange for hull disassembly coupling, (615) large flange connection connection joint hole machining hole or lug machining hole machining hole, (616) mooring device levitation hook barge (616) Blocks Tank blocks Unit hulls Dismantling equipment Lugs for position control equipment Elongation hole, (617) Block tank Hull Split Coupler Double tubular structure Pipes, For tank hull transportation equipment Id rail 619 helicopter station, 619 block tank hull block decomposition coupling adjuster for hydraulic rotational machine cylinder or block hull drill shelf rotary cylinder machine rack and pinion type of (NRP), a cylinder machine,
(620) Hydraulic rotating cylinder (rotary cylinder [rack & pinion type -NRP]),
(621) Blocks Tank blocks Units for dismantling and dismounting of bands Fixtures,
(622) Block -house Block-block Belt unit for shipbuilding unit Butterfly valve,
(623) Blocks Tank blocks Unit parts for hydrauli ... Hydraulic cylinders for c ...
(624) Block-hatches Hydraulic cylinders for railway transport equipment Doors or blocks Tank blocks Hydraulic cylinders for c ... (625)
(626) Thermal Power Plant,
(627) engine control module for engine control system, (628) buoyant flag rubber balloon, (629) rope for rope, (630) rope knot hook, (631) emergency staircase, (632) Conveyor, (634) Sink prevention line, (635) Vacuum pump, (636) Tugboat, (637) Semi diving work line, (638) Bollard, (639) Anchor, (640) (641) a blower or a cooling fan, (642) a heater fan for inserting air, (643) a satellite launch pad, (644) a mooring tower, (645) an electric magnet magnet, (646) a space rocket launch pad, (647) ) Chain block, (649) Yellow clay cement mixing equipment Mixer machine, (650) Insulator, (651) Crane boom frame, (652)
(653) uranium 239, (653a) uranium 238,
(654) water, (654a) hard water, (654b) heavy water or pressurized heavy water,
(655) a direct current that always flows only in the same direction, (656) an alternating current that is a current that changes the direction of flow each time the seesaw changes,
(657) intermediate heat exchanger or primary cooling system intermediate heat exchanger, (657a) secondary cooling system outlet, (657b) low temperature head, (657c) secondary coolant inlet, (657d) support plate, (657e) (657 g) pressure vessel, (657 h) insulation, (657i) high temperature head, (657 j) mixer, (657 k) primary system gas inlet, (657 l) primary system gas outlet, (657 m) (657n) pressure vessel, (657o) insulated layer, (657p) hot gas cylinder, (657q) liner, (657r) double pipe, (657s) pressure vessel, (657t) low temperature gas passage, (657u) ) Hot gas cylinders, (657w) liners, (657x) insulating layers,
(658) heat exchanger,
(659) a nichrome wire which does not flow well, (660) a bulb body, (661) a base,
(662) neptunium,
(663) filament, (664) glass, (665) fluorescent discharge tube, (666) starter, (667) discharge, (668) carbon rod, (669) Cathode (indicated by minus (-)),
(671) a fuel assembly,
(672) nuclear power plant, (672a) Ado Tunnel,
(673) the center axis frame of the chassis,
(674) a proton,
(675) Neutron,
(676) Moderator or moderator containers,
(677) Chuukot Peninsula,
(678a), (678a), (678b), (678c), (678c), (678d), (678e), (678e) and (678f) concept of tidal power generation, respectively. (678h), 678h, 678i, 678i, 678i, 678k, 678k, 678l, 678m, 678n, (678p) Hwacheon Hydroelectric Power Plant, (678r) Soyanggang Hydroelectric Power Plant, (678s) Chungju Hydroelectric Power Plant, (678t) Chuncheon Hydroelectric Power Plant, (678p) , (678v) Cheongpyeong Hydroelectric Power Plant, (678w) Paldang Hydroelectric Power Plant, (678x) Soyanggang River, (678y) Namhan River, (678z)
(679a), (679a), (679b), (679b), (679c), (679d) (679i) hollow space, (679j) surrounding whole room, (679k) surface layer concrete, (679l) water potential energy, (679m) water kinetic energy, (679n) mechanical energy, (679o) electrical energy, (679p) (679q) aberration power, (679q) aberration output, (679r) generator output, (679s) hydroelectric power generation outline, (679t) concept of dam type power plant, (679u) screen, (679v) intake tower, (679w) ) Inlet valve, (679y) main equipment, (679z) main transformer,
(680a) Reservoir, (680b) Reservoir, (680b) Reservoir, (680c) Reservoir, (680d) Biomass, (680e) Pumped storage, (680f) (680i) pressure water tank, (680j) seawater seawater, (680k) geyser seepage, (680l) no seawater tank, (680m) water tank, (680n) ), (680q) waterproofing facilities, (680r) high water level, (680s) low water level, (680t) rock wall, (680u) upstream surface protection layer, (680v) drainage layer, (680w) soil material, ) Dirt dam, (680z) rock dam,
(681) fuel cladding material, (682) cladding or zircalite,
(683) Nuclear fuel pellets,
(684) voltage, (685) power, (686) power outlet, (687) power source inlet,
(688) reactor building or containment building or concrete barrier, (688A) reactor building, (688B) turbine building, (688C) control building, (688D) auxiliary building, (688E) diesel generator building, (688F) nuclear fuel building 688G) Waste building,
(689a) fuel bundle adjustment, (689b) upper nozzle, (689c) fuel rod adjustment, (689d) fuel rod, (689e) spring clip assembly, (689f) lower nozzle, , 689h plundum, 689i hold down spring, 689j uranium dioxide fuel pellet, 689k gas cap, 689l zircaloy crowding,
(692), (691) primary substations, (692) seven strands of steel wire in the center of the transmission line, (693) 54 strands of aluminum wire, (694) fuel hoses, (695) (697) Substation, (699) Substation, (700) Secondary substation, (701) Substation factory, (702) Home (including solar house), (703) Substation substation, ) Stepped foot hook, (704) High voltage wire balancer,
(705) the distribution axis of the nuclear waste treatment line manufacturing process, (706) the small diameter electric resistance welded pipe, (707) the raw material, (708) uncoiling, (709) leveling, (710) side trimming, (712) molding, (713) welding and internal and external bead removal, (714) ultrasonic and vortex test, (715) welding heat treatment, (716) air cooling, (717) water cooling, (721) flattening test, (721) structural tube, (722) calibration, (723) intermediate loading, (724) induction heating furnace, (725) SRM, (726) (727) chamfering, (728) hydraulic test, (729) ultrasonic and vortex test, (730) weight and length measuring instrument, (731) visual and dimensional inspection, (732) screw, (733) For general piping, (735) galvanized, (736) galvanized steel pipe, (737) boiler tube, (738) cooling base,
(749) Cage molding, (743) Oil pipeline, (744) Ultrasonic flaw test, (745) Ultrasonic flaw welding, (745) (746) Oil pipeline (Steel pipe for petroleum industry), (747) Large diameter steel pipe, (748) Edge milling machine, (749) Three roll banding machine, (750) Post banding machine,
(751), (757) X-ray test, (758) cold weld, (752) inner weld, (753) backgauge, (754) outer weld, (763) Uncoiling, (762) Structural and steel pipe piles, (763) For non-coated pipes, (764) Outside Brushed Cleaning, (765) inner blast cleaning, (766) inner painting, (767) primary painting, (768) painting and dressing, (769)
(771) Internal transportations for marine tunnels,
(772) Nuclear or turbine generators,
(773) Non-rotating armature for atomic power generators Coils,
(774) Rotors for nuclear power generators Electromagnets Coils,
(775) Transmission line, (776) Transmission tower, (777) Opening and closing facility, (778) Boiler or kettle,
(779) steam pipe, (780) steam or strong gas high temperature high pressure steam outlet,
(781) Production power Central control room,
(782) transmission measuring room transformer room, (783) boiler operating core,
(784) atom, (785) electron,
(786) Steam dryer,
(787) Magnets,
(789) Deaerator,
(790a) a condenser relief type safety valve, (790b) a condenser safety valve, (790c) a condenser body,
(791) core or nuclear fuel chamber, (791a) core support barrier, (791b) fission,
(792) Drums,
(793) Reheating,
(794) Dual structure block Dust collector of tank or thermal power plant,
(795) heavy oil tank, (796) heavy oil,
(797) Oil tankers or cargo ships,
(798b) control rod drive shaft, (798c) control rod clamping plate, (798d) control rod extension bar, (798e) control rod guide pipe, (798f) control rod drive shaft, (798g) control rod tension rod,
(799) Radioactive waste,
(800) uranium fluoride,
(801) Plutonium,
(802) Boiling water reactor installations,
(803) Pressurized water reactor installation,
(804) Gas cooling furnace nuclear plant,
(805) an internal structure of a multi-purpose high-temperature gas reactor installation, (805a) an internal structure of a Pebble-Bed type high-temperature gas furnace in which a primary cooling system is housed, (805b) a heat shield, (805c) through- 805e control shaft 805f hold down plate 805g control rod drive unit 805h auxiliary circulation unit 805i auxiliary heat exchanger 805j core support structure 805k prestressed concrete reactor vessel , (805l) PCRV safety valve, (805m) fuel inlet, (805n) He circulation unit, (805o) PCRV support structure, (805p) cross sectional structure of pebble-bed type HTR module reactor, (805q) (805s) reflector zone control rod, (805s) reflector zone control rod, (805t) spherical fuel inlet pipe, (805u) water pipe, (805v) collars, (805w) gas circulator, (805x) hot gas piping, Cooler, (805z) insulation,
(806) New conversion reactor facilities,
(807) Steam towers,
(808)
(809) purifier,
(810a) steam generator, (810a) steam outlet to the turbine generator, (810b) water nozzle, (810c) secondary cooling water, (810d) vibration suppression rods, (810e) tubing supported steel pipes, (810f) (810i), (810i), (810i), (810i), (810i), and (810i) the primary outlet, (810o) Steam generator inner body,
(811a) Nuclear power generation nuclear waste treatment unit (811b) Power generation manufacturing unit (811c) Traffic transportation unit of construction machine (811d) Power transmission unit for transmitting power (811e) Nuclear power plant operation (811f) Electronic Control Control Equipment Construction Control Equipment, (811g) Screw Control Equipment,
(812) enriched uranium or uranium 235,
(813) Reactor pressure vessel (813a) Pressure vessel cover (813b) Pressure vessel Top cover bottom (813c) Pressure vessel Cylinder cover (813d) Pressure vessel Cylinder cover top, (813e) Pressure vessel Cylinder cover top 813f) inlet nozzle 813h deflector steel plate 813i air chamber chamber 813j baffle plate 813k water 813l spray pool 813m vant five fuel assemblies 813p) Pressure vessel Cylinder top and bottom assembly, (813q) Dry wall, (813s) Pressure vessel Cylinder shell bottom assembly, (813t) Pressure vessel Cylinder shell top assembly, (813v) Fuel rod iron plate, (813w) Nozzle, (813y) core support assembly, (813z) control rod guide tube assembly stand,
(814) pressurizer, (814a) spray nozzle, (814b) pressure protection container, (814c) pressure regulating valve,
(814d) steam boundary, (814e) pressure vessel body, (814f) cooling water inlet, (814g) heater heater,
(815) nucleus, (815a) nucleon, (815b) nuclear force,
(816) a coolant or primary sodium or secondary sodium, (816a) a coolant inlet nozzle, (816b) a coolant outlet nozzle,
(817) Silencers,
(818) Separator,
(819) a hydraulic tank, (819a) a hot plate, (819b) an oil level meter (oil port), (819c) drain, (819d) tank bottom plate, (819e) diaphragm Strainers (819g) Teflon packing (819h) Inlet packing, (819i) Inlet lid, (819j) Tank top plate, (819k) Air blender and combination air purifier (819l) (821) hydraulic pump, (822) rod-and-piston seal, (823) piston seal, (824) booster seal, (825) (823) a slide seal, (827) a die bush, (828) an oing, (829) a load seal, (830) a backup seal, (831) a load seal and backup seal, (834) multistage seals, (835) baffling (836) piston rings, (837) multistrings,
(838) Fast breeder reactor facilities,
(849) Underwater submarine mineral water baskets, (843) Underwater exploration underwater lights, (844) Bucket or pallet, (834) (845) Deck excavator for submersible drilling rigs, (846) Wreck crank for anchor replacement, (847) Rock drill or net, (848) Actuate, (849) (851) Pylon level foundation base, (852) Fixing wrist stand, (853) Arc welder or argon welder, (853a) Welding wire, (853b) Welded bracket, (854)
855b bulldozer 855a crawler type dozer 855b wheel dozer 855c straight dozer 855d deleter dozer 855e angle dozer 855f hinge dozer 855g tree dozer 855h (855i) HYDRICAL RIPPER, (855J) DOZER POWER TRANSMISSION, (855k) CAM OTHER EQUIPMENT DRIVE PUMP, (855L) ENGINE, (855m) COOLING SYSTEM, (855N) (855p), a clutch (856) an excavator, (856a) a backhoe, (856b) a power shovel, (856c) a drag line, (856d) an earth drill, (856e) (856) Skimmer, (856g) Ripper and Luther, (857) Loader, (858) Forklift, (859) Scraper, (859a) Traction Scraper, (859b) Power Scraper, (859c) Air Front 859d) Eject, 859e Ball, 859f Cutting Tee, 860 Dump Truck, 860a Trailer,
(861) Cranes or cranes, (861a) Name of each part of the crane structure, (861b) Extension cable, (861c) Loadmeter, (861d) Breeze, (861e) Boomboxes, (861f) Boom hoist rope, 861h upper frame, 861i lower frame, 861j hoist rope, 861k front drum, 861l middle drum, 861m rear drum, 861n balancer, 861o cable crane (861p) All six units of the crane, (861q) Gook, (861r) Clamshell, (861s) Shovel, (861t) Dragline, (861u) ) Trenchhoe unit, (861v) Pile driver unit
A motor gear grinder 862a a muffler 862b an engine flywheel 862c a cooling fan 862d front and rear front and rear values 862e translators 862f fixed gear transmission 862g parking brake , (862h) differential gear, (862i) transfer car neutral gear reducer, (862j) disc brake, (862k)
(863) rollers, (863a) vibrating rollers, (863b) soil compactors, (864)
(865) Concrete Batch Plant, (865a) Concrete Hopper, (865b) Conveyor Charging Chart, (865c) Adjustment Plate, (865d) Water Meter, (865e) Symmetric Hopper, (865f) Scale Frame, (865i) Conveyor belt, (865i) Turnhead, (865j) Bucket elevator, (865k) Transportation cement Chad, (865l) Adjusting plate, (865m) Recording device, (865n) Circular mixer, (865o) Cement silo 865p) scour conveyor,
(866) a concrete finisher, (866a) a scour spray, (866b) a first screed, (866c) a vibrator, (866d) a finishing screed, (866e) a guide roller, (866f) a guide rail, (866g)
(867) Concrete spreaders, (868) concrete mixer trucks, (869) concrete pumps, (870) asphalt mixing plants, (871) asphalt pavers,
(872) Asphalt Sparger, (872a) Power Driven Pump, (872b) Valve Control, (872c) Spray Bar, (872d) Bunny, (872e) Discard Pipe, (873) Aggregate Duster,
(874) a crusher, (874a) a gyration crusher, (874b) a chassis frame, (874c) a feeder hopper, (874d) a vibration grease repeater, (874e) a primary jaw crusher of a crushing head, (874f) Tea jar crusher, (874g) vibration screen, (874h) drum elevator,
(875) air compressors, (876) perforators, (877) horses and anti-erectors, (878)
(879) Dredger, (879a) Pump dredger, (879b) Bucket dredger, (879c) Spotdish, (879d) Cab or control room, (879e) Red Shear, (879f) Spotted, (879g) Blast tank, (879h) Blast pump, (879i) Red, (879j) Engine room, (879k) Dipper dredger, (879l) Grab dredger, (879m) Bucket drive, (879n) Backspot, (879o) Spot Winch, (879p) bucket, (879q) All right and left spots, (879r) Dipper, (879s) Winch, (879t) Anchor warehouse, (879u) Belt conveyor, (879v) Grab,
(882) boom, (883) diesel file hammer, (884) steam hammer, (885) hydraulic crane, (885a) piston motor,
(886) tower crane, (886a) the name of each part of the girder structure, (886b) Gide derrick, (886c) main side, (886d) boom, (886e) boom foil, 886f turnbuckle, (886g) ) 3 Derek, 886i, 886j Boom, 886k Boom Foil, 886l Leak,
(887) Drake cranes (887a) Structure of drag cranes, (887b) Hoist cables, (887c) Dump cables, (887d) Buckets, (887e) Lower boom, (887f) Letter cable, (887h) cable drum, (887i) cable roller, (887j) boom hoist cable, (887k) cable drum, (887l) cable drum, (887m)
(888) Clamp cell attachment, 888a Holding line, 888b Closing line, 888c Clamshell bucket, 888d Upper frame, 888e Lower frame, 888f Rack line, Rope guide, 888h crowbar, 888i bridle, 888j boom hoist rope, 888k front drum, 888l rear drum, 888m parallel weight,
(899) Tandem Roller (891) Tamping Roller, (892) Tire Roller, (893) Tractor, (894) Trailer, (895) Ramp, (896) Lead, (897) Cooling Water Cooler (898) file, (899) helmets, (900) fuel pump, (901) cam, (902) fuel tank, (903) starter, (904) boom front pin, (905) ,
(907) Fish Finder Sonar,
(908) Rotary table of drilling machine for crude oil Lathe Machine,
(909) manganese nodule,
(910) Nets, (911) Suction collecting machines, (912) Undersea mining robots,
(913) periscope, (914) rubber balloon, (915) wire rope chain,
(916) Double structure pipeline Automatic pneumatic valves Transportation equipment,
(917) Core Drill,
(918) non-inflatable, (919) rubber tires, (920) burner boom,
(921) harmful tidal microorganisms, (922) pollution-free natural gas,
(923) an air nozzle,
(924) mineral collecting troughs, (925) ascending air streams, (926) descending air streams, (927) yellow clay mixtures for dusty dust or soap bubbles,
(928) Double structure block tank pipe Pier,
(929) Nuclear waste treatment dual structure block tank pipe bridge,
(930) chemicals, (931) cement, (932) fishing nets,
(933) Disaster or Pollution Control, (934) Crude Oil Drill, (935) Levers for Shiseo Handle,
(936) Borehole,
(937) double structure block tank pipe bridge, (938) electrode plate anode, (939) cooling air bubble, (940)
(941) Nuclear waste treatment Double structure block tank Marine tunnel transport equipment,
(942) Tower crane Seisio Crane Boom Tower.
(943) Marine aquatic power plant, (943a) Pump aberration for hydroelectric power plant, (943b) Pelton aberration for large hydroelectric power plant, (943c) Francis aberration for large hydroelectric power plant,
(944) Large-scale hydroelectric generator Shiseido hydroelectric power plant (944a) Rotational speed detector for hydroelectric power plant (944b) Exciter for dc generator (944c) that supplies current to the motor field coil of alternator (944d) an upper rotation bearing, (944e) a device for pushing a rotary bearing, (944f) stator coil, (944g) stator frame, (944h) center stator, (944i) low speed cooler, (944j) (944k) Braking device or jack, (944l) Low speed bearing, (944m) Engine generator, (944n) Turbine rotary bearing, (944p), (944p) Rotary bearing, (944q)
(945) Underground disaster prevention nozzles or shared landfills,
(946) Subsea line wiring or shared reclamation land,
(947) Container for inflation control device Rubber tube for air supply for internal use,
(948) furnace, (948a) furnace brick,
(949) Ship's diving position control device and diving buoyancy control weight,
(950) thermocouple thermometer switch for temperature auto sensing sensor,
(951) Hatchback basket or pareto for harmful redeye suction dust collector,
(952) Locomotives, non-power, for water,
(953) Military equipment Submarine,
(954) Laser cutting machine,
(955) Peacekeeping message of a weapon more powerful than a nuclear bomb,
(957) Offshore Wind Power Plant, (957a) Wind Turbine Windmill,
(958) Weather Forecast Observation,
(959) Alternative goods goods Sail,
(960) Satellite weather forecast information collection machine,
(961) Space rocket,
(962) Satellite
(963) Peace Sovereign, (964) Petroleum, (965) Diamond, (966) Iron, (967) Tin, (968) Coal, (969) Agricultural Equipment, (970), (971) (977), (977), (978) nuclear aircraft carrier, (979) oil pipeline, (980) gas piping, (981) gold and silver, (982) (984) glass, (985) agate, (986) amber, (987) pearl, (988) munitions, (989) United Nations, (990) United Nations Organization, (991) Bombs, (993), (994), and (995) submersibles, (996) sinking vessels,
(1006) steam outlet pipe, (1007) steam outlet body fuselage appearance, (1008) hygrometer tube, (1009) steam outlet tube, (1010) level surface tube, (1011) sodium cooling system (1018) a spiral heat exchange tubule, (1018) a sodium coolant outlet pipe, (1012) a bottom plate, (1013) a connecting rod, (1014) a cooling water leak detection pipe, (1015) a secondary argon gas pipe, (1023) Sodium-water reaction product discharge pipe, (1025) Inner pipe, (1026) Monitor, (1023) Ring inlet pipe, (1027) water inlet pipe plate, (1028) water inlet pipe, (1028a) water inlet chamber,
(1033) Waste mixed glass solid, (1035) High-level waste, (1039) Nuclear facility, (1030) Demolition facility, (1031) (1040) Plutonium disposal process from nuclear dismantlement, (1059) fission, (1069) nuclear reactor bricks, (1010) nuclear disruption, (1039) long term repository, (1038) deep underground cave, 1070) Uranium dioxide, (1071) Study, (1072) Power train, (1073) Reactor steam extraction system, (1074) Drain pump, (1075) Heating device, (1077) Nuclear fuel industry cycle, (1101) a strong wind wave,
(SDU), dock hull deck center (SDM), dock hull deck top (S DL), machine room bottom surface top part (MFGU), machine room floor surface (MFG), machine room floor surface bottom part (M FGL) The upper part GLU, the surface GLL, the lower part GLD, the equatorial line EL, the north pole NP, the south pole SP,
Longitude (ld), latitude (lt)
The injection nozzle upper end A, the injection nozzle body B, the injection nozzle lower end portion C,
The road surface top surface GLU, the road surface GLL, the road surface GLD,
Pump body (PB), pump body vertical line (PPVL), pump body horizontal center line (PBCL)
(SLL), SLL (SLL), SLD (SLB), and SLB (SLD), respectively, of the valve body center line (VBCL or PBCL), fire retardant water surface (WLD), fire water surface (WLL)
Out of Merchinery Room (OMR), Merchinery Room (MR)
In the Merchinery Room (IMR),

Claims (37)

Nuclear waste disposal for nuclear power plants Dual structure of nuclear power plant facilities In the reactor plant for fast breeder reactors,
Nuclear power plant facilities include nuclear reactor plants (593,594,595) of marine power plants (673) and nuclear reactors (1) of nuclear power plants Nuclear reactors of nuclear reactors A nuclear power plant and reactor facilities including a double structure block tank 598 for controlling the nuclear power plant and a double structure block tank precipitator 794 of the nuclear nuclear waste disposal shield of the nuclear power plant, ;
The nuclear waste disposal facility of the reactor plant of the nuclear power plant includes the mixture of the yellow waste mixed with the cooling water into the reactor core 681 inside the reactor and the reactor core 681 to the nuclear waste disposal treatment control product cooling water, The nuclear waste in the nuclear reactor main body 1 of the nuclear power plant is treated while the nuclear reactor is operated while the nuclear fuel in the nuclear fuel chamber is controlled while the inside of the reactor core 681 and the reactor core 681 are filled with the devices (593,594,595) Nuclear waste disposal of marine nuclear power plant (593,594,595) Nuclear waste disposal of dual structure block tank dust collector (794) constituting marine nuclear power plant Nuclear waste treatment Dual structure block tank pipe bridge Marine tunnel transport device (941) Constituting a reactor plant combination of a nuclear power plant having a dual structure block tank precipitator 794;
The double structure block tank arrangement of the nuclear waste disposal dual structure block tank scrubber 794 includes a disassemblyable inner block tank 596 and an outer block tank 599 having a double structure cylindrical connection structure, The dual structure block tank (794) facility of the nuclear power plant, while providing the dual structure block tank (598) as the processes, is coupled to the disaster prevention devices that control the nuclear radiation leak coupled to the reactor facility connection shafts, The nuclear waste treatment of the nuclear reactor facility is performed by the block tank dust collector 794;
The double structure block tank dust collector 794 includes a reactor structure of a nuclear power plant that provides the production control of a dual structure block tank dust collector 794 with connection structure construction machine cranes 861 that can be disassembled and coupled at a marine vessel manufacturing factory. A nuclear power plant 811 configured as an interior of the main body;
The nuclear reactor facility 811 includes a boiling water reactor 802, a pressurized water reactor 803, a gas cooling furnace reactor 804, and a multi-purpose high temperature gas reactor (810) consisting of the inside of the nuclear reactor facility main body of the nuclear power plant provided with the nuclear reactor power plant (805), the new conversion furnace reactor facility (806) and the fast propagating reactor reactor facility (838) 811a);
In the reactor facility in which the bed for regulating the nuclear waste capacity into the storage tanks of the nuclear power generation nuclear waste processing unit 811a is provided inside the reactor facility body 1 of the nuclear power plant, Nuclear reactors to prevent nuclear fuel explosion Nuclear reactors before and after breakdown Nuclear power plant replacement Alternative power generation Nuclear power plants including hydroelectric power generators including wind power generators and thermal power generators for wind power generators A power generation and production section 811b of the nuclear power generation facility unit 811 constituted;
The double structure block tank reactor 794 of the power production and production section 811b is provided with a plurality of inner block tanks 596 and a central structure block tank 589 at the center portion and aft end portions of the outer block tank 599, The crane boom 651 and the crane boom hook 652 and the conveyor 633 of the position movement control device construction machine crane 861 are opened to open and close the crane boom hook 792 and the conveyor 633, While at the same time the dual structure block tank 598 is used to construct a nuclear power plant 811 constructed inside the nuclear reactor main body of a nuclear power plant which provides transportation by means of a marine installation connection structure capable of disassembly and disassembly in the manufacture of industrial field launch dock sites. A transportation section 811c of the machine;
The transportation transport unit (811c) of the construction machine includes an adjustment shaft provided in the reactor main body (1) of the nuclear power plant to provide capacity adjustment to the storage tanks of the nuclear reactor nuclear waste disposal shield apparatus;
The control shaft is connected to the power transmission unit 811d for disassembly coupling the reactor main body 1 of the nuclear power plant to the strut block tank 590 of the reactor main body nuclear power generation facility 811 of the individual nuclear power plant, Nuclear waste treatment of tank 598 Double structure block tank pipe bridge 928 and double structure block tank pipe bridge 941 connection structure of the connection shaft of the nuclear tunnel plant A distribution shaft having a discharge shaft for distributing to storage tanks of a reactor facility manufacturing apparatus and a nuclear waste processing shielding apparatus;
The distribution shaft includes a power transmission portion 811d provided with transformers for transmitting the power of the nuclear power plant 811 constituted inside the reactor facility main body of the nuclear power plant providing capacity to the storage tanks of the nuclear waste treatment shielding apparatus )Wow;
The power transmission unit 811d is provided with the same exhaust gas outlet as the dust collector of the exhaust gas facility which can withstand the natural disasters of the nuclear reactor main body 1 of the nuclear power plant before and after operation of the nuclear reactor safety facility (811e) of the nuclear power plant (811) consisting of the interior of the reactor facility of the nuclear power plant having the entrance,
The control facility 688C, the auxiliary building 688D and the diesel generator building 688E are connected to the reactor building 688A and the turbine building 688B of the nuclear power plant, Nuclear power plant buildings (688F), waste buildings (688G), and power plant buildings (688Z) with connection structures. Prevention of nuclear explosion Prevention of nuclear explosion Nuclear waste treatment Before and after nuclear power plants Nuclear power plants The electronically regulated control apparatus construction machine control unit 811f controls the crane boom 651 and the conveyor 633 of the locomotion control apparatus construction machine crane 861 while simultaneously providing an enormous amount of radiation- The operation of the carrier is separated into the electronic control devices and the operation of the carrier is controlled by the electric control device of the nuclear power plant 811 A self-regulating regulating device construction machine regulating section 811f;
The electronic control regulating device construction machine control unit 811f includes a control shaft for controlling the nuclear waste capacity to the storage tanks of the nuclear reactor nuclear waste disposal shield apparatus constituted inside the nuclear reactor facility main body 1 of the nuclear power plant (1) of the nuclear reactor plant main body (1) of the nuclear power plant to prevent the nuclear fuel explosion of the nuclear reactor main body (1) of the nuclear power plant in a safe and continuous manner. The barge hull (591) is equipped with a nuclear power plant production facility (811b) for nuclear power plant, while at the same time the barge hull (592) at the bottom of the dual structure holding tank is equipped with reactor facilities for a nuclear waste treatment nuclear power plant The screw adjusting portion 811g of the nuclear power generation facility unit 811 is connected to the holding tank 590 by the disassembly- The position adjustment of the lug connecting shaft splitting and disassembling nuts 604 and the adjusting shafts in the lug 607 and the lug connecting shaft connecting bolts 603 is performed on the common lug pin connecting shaft 606 to the reactor installation main body 1 of the nuclear power plant, Further comprises a screw adjusting portion 811g of the nuclear power plant 811 provided inside;
The reactor installation for providing inserting on both sides of the forward and aft ends of the central portion of the double structure block tank dust collector 794 of the screw adjusting portion 811g includes a plurality of internal block tanks 596 of the dual structure block tank reactor dust collector 794 ) Nuclear power plant equipped with position shifting control by a carrier equipped with a crane boom hook 652 and a conveyor 633 on the crane boom 651 of the construction machine crane 861, Performing a nuclear power plant operation consisting of a nuclear waste disposal apparatus in a double structure block tank dust collector 794 provided with a safe and continuous nuclear radiation leakage control of a nuclear power generation facility 811 provided inside a reactor facility main body of a power plant;
The operation of the nuclear power plant is provided inside the nuclear reactor main body 1 of the nuclear power plant. However, it is also possible to freely control the amount of production power and to operate the nuclear power plant in preparation for natural disaster, The nuclear plant waste treatment tank tank 295 disposed at the upper end of the double structure block tank dust collector 794 is provided in order to supply the yellow loess mixtures to the water supply pump 241, The nuclear waste disposal reactor that provides the transfer to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 contains the yellow waste mixture mixed with the cooling water inside the reactor core 681 and inside the reactor core 681, Processing control products When the yellow waste mixture mixed with the cooling water is filled into the core (681) and the core (681) inside the reactor by the nuclear waste disposal apparatus, the nuclear fuel collision At the same time, the reactor facility maximizes the nuclear power generation production capacity of nuclear reactor facility (1) of land and ocean nuclear power plants, while preventing the explosion of nuclear reactors immediately, while preventing nuclear explosion by double structure block tank collector, The facility is equipped with nuclear waste treatment double structured block tank bridge bridge to prevent sinking of marine nuclear power plant and prevention of nuclear fuel explosion to be installed inside reactor main body (1) of marine nuclear power plant marine tunnel transportation device (941) The construction of the disaster prevention system and the construction machinery of the flood control system to withstand the natural disasters of the nuclear power plant.
(941), a disaster prevention device for flood control that can withstand the natural disasters of the ocean, and a construction machine equipped with a position control system to control the movement of the nuclear power plant Wherein the reactor is equipped with a double-structure high-speed reactor for nuclear power generation. The method according to claim 1,
(593, 594, 595) of a marine power plant constituting the nuclear power plant 672 and a nuclear waste treatment dual structure holding block tank 590 of an individual reactor facility composed of the interior of the nuclear reactor facility main body 1 of the nuclear power plant, Double structure block tank pipe bridge 928 and double structure block tank pipe bridge 937 constituting block tank 598 Nuclear radiation leakage control of connection shaft Double structure block tank dust collector 794 and double structure block tank pipe bridge 937) Nuclear Power Plant Reactor Facility Provided with Reactor Facility of Nuclear Power Plant 672 for Disassembly of Connection Shaft The distribution shaft 705 of the nuclear waste processing tube manufacturing process of the nuclear power plant unit 811 of the nuclear plant,
The double structure block tank 598 of the distribution shaft 705 includes an inner block tank 596 which provides a position to the center of the double structure block tank 598 and an inner block tank 596 which is located outside the inner block tank 596 (597) as a double structure with an outer block tank (599) Connected to cutting and welding processes at the industrial site by steel plate (597) The first auxiliary steel pipe 600 and the second auxiliary steel plates 601 for the block tank are connected to the distributing and loading device of the structural block tank pipe bridge 937 and are connected to the double structure block The large flange 614, which provides the connection structure for the connection shaft to the bow and stern connection position of the tank 598, is positioned as a connection structure at the connection location of the large flange connection joint connection area processing hole 615 of the large flange doing (625) of the distribution shaft (705) of the nuclear waste treatment pipe manufacturing process of the nuclear reactor plant main body of the nuclear power plant while providing the drill lathe and the cutter of the cutting tool to the flange (614) The double structure block tank 598 of the distribution shaft 705 of the pipe manufacturing process is made of the high-strength stainless steel steel plate 597 according to the manufacturing process according to the safe design, The nuclear waste treatment pipe manufacturing process of the nuclear reactor facility including the overhead crane 861 and the conveyor 633 which are fed into the transportation process with the double structure block tank 598 in accordance with the process order of the transportation, (597) of the high-strength stainless steel by the foroming and roll forming bending machine according to the thickness of the disc by a forom bending machine (a) and V-shaped bending (b) At the same time as the bending process is being performed, the stopper plate (625) of the distribution shaft (705) of the pipe manufacturing process is formed by a press braking type press braking type bending machine, a bending type roller bending machine, The overhead crane 861 and the conveyor 633 conveyor which are fed into the conveying process while performing the bending and cutting process with the bending and cutting machine of the high-strength stainless steel steel plate 597 by the bending roller bending machine, The welder, the cutting tool, the drill lathe, and the cutter can perform the welding process to the banding joint portion of the steel plate 597 of the high-tensile strength stainless steel, The tank 598 has a large flange 614 that provides a location for the connection of a large flange 614 that provides a location for the bow and stern connection, A stopper plate 625 is provided as a connection structure of the distribution shaft 705 of the pipe manufacturing process of the manufacturing and processing shelf process and is provided with an inner block tank 596 and an outer block tank 599 for providing a position outside the inner block tank 596 The inner block tank 596 completes the welding process while adjusting the positional movement to the overhead crane 861 and the conveyor 633 into the outer block tank 599 to form the double structure cylindrical shape The nuclear power plant is constructed such that the nuclear power plant is operated into a double structure block tank 598 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process of the nuclear power generation facility unit 811 into the reactor facility body of the nuclear power plant having the connection structure of the nuclear power plant;
The double structure block tank 598 constituting the operation of the nuclear power plant includes a plurality of outer block tanks 599, a first auxiliary shape steel for a block tank 600, A second auxiliary steel plate 600 for a block tank and a second auxiliary steel plate 601 for a block tank are provided with a second auxiliary steel plate 601, a vertical partition wall 605, a horizontal partition wall 609 and a steel beam 149, The vertical barriers 605, the horizontal barriers 609, the steel beams 149, the snap holes 602 and the barrier manholes 610 are cut by a computer laser cutter while simultaneously being welded to the welders of the welding process A nuclear power plant 811 having a double structure block tank dust collector 794 inside the reactor facility main body 1 of the fifth protection wall nuclear power plant constructed along the outer wall circumferential surface of the fourth protective wall containment vessel 808 The nuclear reactor is operated with the double structure block tank 598 of the distribution shaft 705 of the nuclear waste processing tube manufacturing process, ;
The double structure block tank 598 constituting the nuclear power plant is provided with a communication device hydraulic cylinder door 624 and an emergency stairway and a step 631 in the vertical partition wall 605 and the horizontal partition wall 609 constituted by the partition wall manhole 610, ) Consists of a welding process and is equipped as a traffic device of a double structure block tank dust collector (794) to prevent explosion of a reactor, and a double structure block tank dust collector (794) A dual structure block tank (598) of a distribution shaft (705) of a nuclear waste processing pipe manufacturing process consisting of a nuclear power generation facility (811) inside the reactor facility body (1);
The plurality of stopper steel plates 625 constituting the operation of the nuclear power plant are composed of a bending type bending machine, a press braking type bending machine, a bending type roller bending machine and a three bending type roller bending machine, The bunging steel plate 625 is provided with a double structure block tank 598 having a cylinder type coupling structure egg type and constituted by a cap tight coupling assembly of the double structure block tank 598 while bending the steel plate 597 by bending and bending the bending plate, (598) The plurality of inner block tanks (596) and the plurality of outer block tanks (599) are individually welded to the upper and lower ends of the block tanks and the large flanges are assembled into a double structure block The tank 598 bolting assembly and the welding process assembly of the closure plate 625 may be assembled into a cap-tight fitting welding process assembly of a closure plate 625 without a large flange (811) inside the nuclear reactor main body (1) of the nuclear power plant and a core assembly provided with a bolting assembly, which is provided in the explosion-proof double structure block tank collector (794) of the nuclear reactor facility The nuclear waste disposal control apparatus is divided into a waste disposal dispensing apparatus and a nuclear fuel explosion control apparatus, and a nuclear waste disposal unit 794 of the distribution shaft 705 of the nuclear waste disposal pipe manufacturing process is operated to operate the nuclear power plant;
The reactor facilities constituting the nuclear power plant operate in such a way that nuclear waste is stored in one place in a plurality of inner block tanks and a plurality of outer block tanks at the lower end of a vacant space of the outer block tanks, The reactor installation is comprised of a third wall of the reactor consisting of the interior of the inner block tank 596, which is fixed with reinforcing concrete mats 225 of thickness m and steel beams 149, The nuclear fuel is injected into the nuclear reactor, and the reactor is equipped with a distribution input device for nuclear waste disposal and a fuel injection control device for nuclear fuel explosion control to constitute the nuclear power generation and constitute the nuclear power generation facility 811 in the reactor main body 1 of the nuclear power plant The dual structure block tank precipitator 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process being constructed to operate the nuclear power plant;
In the reactor installation constituting the nuclear power plant, an enormous amount of radiation is generated inside the reactor installation, and the reactor installation includes a cladding tube 682 for safely protecting the first wall pellet 681 and the second wall fuel rod 689 The reactor building 688 portion of the reactor building 688 including the third wall reactor pressure vessel 813 and the fifth wall reinforcing concrete mat 225 in the fourth wall containment vessel 808 is divided into five A nuclear waste disposal and dispensing apparatus having a double structure block tank separator 794 constructed by replacing the nuclear waste disposal control apparatus with a protective wall, and nuclear fuel explosion control distribution dispensing apparatuses, ) To a dual structure block tank scrubber (794) of a distribution shaft (705) of a nuclear waste treatment line manufacturing process comprising:
The double structure barge ship hull 591 at the lower end of the holding tank of each control shaft is provided with a double structure block tank dust collector 794 for controlling the leakage of nuclear radiation into the SDM of the hull deck At the center of a plurality of inner block tanks 596, there are provided nuclear reactor facilities for nuclear waste disposal at each side of the bow and stern, The structure barge hull 591 is provided with the guide rails 618 installed on the left and right sides of the deck deck and the crane 861 having the capacity of 5000 ton on the guide rail 618 as the upper end portion SDU of the hull deck A nuclear waste disposal dispenser having a double structure block tank dust collector 794 constructed by replacing a 5-fold protective wall inside the barge hull with a nuclear fuel waste disposal unit and a nuclear fuel explosion control At the same time as providing the moving installation of the dispensing and inputting apparatus, the nuclear waste disposal reactor facility is provided with a double hinged and triple hinged double-structure sliding hatch cover 153 at the safety place where the crane 861 for the renovation is installed, A nuclear waste disposal pipe (811) in the reactor main body (1) of the nuclear power plant, which is provided as a construction transportation transportation part for adjusting the position of the respective control shaft provided at one end of each control shaft, The dual structure block tank cleaner 794 of the distribution shaft 705 of the process;
The nuclear reactor facility constituting the operation of the nuclear power plant is composed of an exhaust gas outlet equivalent to a dust collector of an exhaust gas facility which can withstand the natural disasters of the ocean into the nuclear reactor facility main body 1 of the nuclear power plant before and after the operation of the nuclear power plant. The nuclear waste and nuclear radiation pollutants of the reactor facility having the inlet are connected to the double pipe block piping lines 74 for positioning the inside of the double structure block tank dust collector 794 to the nuclear waste locating passage And the nuclear radiation pollutants are detected by a plurality of temperature pressure sensing sensors. When the temperature sensor of the safety valve detects a temperature of 700 to 800 degrees in the inside of a nuclear reactor and a pressure of a high pressure reaches a dangerous level, At the same time that the sensing sensor transmits an alarm message to the computer in the safety control room, At the same time as the pressure sensing sensor and the safety valve are opened, the nuclear reactor waste is passed through the pressure vessel internal block piping line 74a at each location, and the nuclear waste is stored in each location of the block tank, ) At the same time that the temperature pressure sensing sensor safety valve 472 connected to the lower inner block tank is opened and the outer block piping line 74b of the nuclear reactor facility is provided with the fuel explosion prevention control article stored in the inner block tank, A thermocouple thermometer sensor switch 103 having a connection structure with a pressure gauge 101 and a temperature sensing bimetal 102, a flow rate check operation level pressure switch 104 and a flow rate check flow meter 105, And a safety valve 472 of a piping line automatic pneumatic valve conveying device 916 to form a plurality of through holes at an angle of 45 ° at an upper end of the reactor building 688 At the same time that the through-hole processing is provided by the low-cutter, the construction machine and the drill machine, the reactor facility constitutes a double-pipe structure block pipe line 74 in the plurality of through holes, and the plurality of safety valves 472 are connected to the block pipe line 74 and a bolt 24 and a nut 25 with a flange connecting connection by a gasket 32 and a double structure block having a diameter twice the diameter of the reactor building 688 along the outer wall surface of the reactor building 688. [ A tank 598 is provided at one location with an outer block tank 599 for storing nuclear waste treatment and a radiation type connection structure to provide a distribution input device for nuclear waste disposal and a distribution input device for nuclear fuel explosion control. It consists of nuclear reactor core (681) and nuclear reactor core (681), which are equipped with nuclear fuel explosion prevention control goods just before reactor explosion, Waste site The dual structure block tank collector 794 of the distribution shaft 705 of the reboiler manufacturing process is configured to operate as a nuclear power plant;
The reactor facility constituting the nuclear power plant is connected to a steam generator 810 and a steam dryer 786 installed outside the pressure vessel 813 of the double structure block tank dust collector 794, A plurality of inner block tanks 596 and a plurality of outer block tanks 599 are connected to a nuclear fuel assembly (not shown) separately in the nuclear reactor installation of the containment vessel 808 corresponding to the fourth wall and the double structure block tank precipitator 794 corresponding to the fifth wall. Explosion-control control article cooling water 287 and soap which are supplied to a pressure vessel 813 such as a furnace immediately before a reactor large-scale explosion are provided with a loess soil 158 and a cement mixing equipment mixer machine 649, The control device is charged into the pressure vessel 813 at a time by an automatic injection device at a time, and a plurality of fire-fighting nozzle nozzles 10, which are cleaned in the reactor installation after the occurrence of the earthquake, A fuel injection control device for controlling the fuel explosion control device inside the power container 813 and inside the containment container 808 and performing the cleaning process automatically inside the reactor facility without inputting human and robot, (811), which is equipped with nuclear waste disposal and disposal apparatuses for nuclear waste disposal and recycling facilities inside and outside the nuclear reactor facility, and the nuclear power generation facility (811) inside the nuclear reactor facility main body The dual structure block tank collector 794 of the distribution shaft 705 of the tube manufacturing process is configured to operate as a nuclear power plant;
The internal cleaning of the nuclear reactor constituting the nuclear power plant is performed by cleaning the inside of the nuclear waste disposal pipe manufacturing process distribution shaft 705 double structure block tank dust collector 794 through the cooling water inlet of the distribution input unit cooling water pipe line of the fuel explosion control 352 and the cooling water 287 that prevents the yellow loam mixture from solidifying is mixed with the yellow loam mixture by a mixer machine 649 to produce a soap bubble in the pressure vessel 813). After the earthquake has stopped, the internal water pump (242) immediately cleans the inside of the reactor to prepare continuous nuclear power generation without restraint from natural disasters and to maximize safety operation of the reactor facilities To the distribution input device of the nuclear waste disposal with the reactor explosion preventive double structure block tank dust collector 794, The dual structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process consisting of nuclear power generation equipment part 811 inside the nuclear reactor facility main body 1 of the nuclear power plant of the land and marine nuclear power plants, To operate;
The nuclear power generation facility 811 of the reactor nuclear reactor facility includes a plurality of dual nuclear fuel reactors 810 for storing the nuclear nuclear waste 224 connecting the outer walls of the nuclear reactor building wall from the first wall to the fifth wall, The nuclear power plant 811, which is formed at a stage before and after the operation of the nuclear power plant of the nuclear power plant constituted by a plurality of nuclear reactors and a coupling connection structure inside the nuclear power plant including the structural block tank reactor accumulator 794, A steam turbine 267 generating nuclear fission in the reactor and generating steam by the heat to produce power by rotating the steam turbine 267 and a nuclear power generator 772 for converting the power produced from the steam turbine 267, And a rotary rotor for a nuclear power generator installed along the circumference of a rotary shaft 198 connecting the steam turbine 267 and the nuclear power generator 772. [ Rotating armature coil 773 for a nuclear power generator installed along a circumferential surface of a rotating rotor electromagnet coil 774 for the nuclear power generator and a steam turbine 267 connected to the nuclear power generator 772 And a frame 775 that integrally fixes the rotating shaft 198 to the nuclear power generation facility 811 in the reactor main body 1 of the nuclear power plant on land and in the ocean The dual structure block tank cleaner 794 of the distribution shaft 705 of the nuclear waste treatment line manufacturing process being constructed;
The nuclear power generation facility 811 of the reactor facility of the nuclear power plant operates the cooling water inlet 352 of the cooling water piping line having a connection structure with the condenser 790 at the lower part of the body of the steam turbine 267 of the nuclear power generation facility unit 811 And a circulation water pump 242 connected to a cooling water inlet 352 of a cooling water piping line to a piping line 169 at a watertight path in front of the condenser 790 to connect the reactor main body of the nuclear power plant 1) the nuclear power generation facility unit 811 inside the nuclear power plant, and the dual structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process;
The nuclear power generation facility 811 of the reactor facility of the nuclear power plant operates a water supply pump 241 at the rear of the condenser 790 and outside the reactor facility and a purifier 809 is installed outside the reactor at the front of the water supply pump 241 And a plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 storing the enriched uranium fuel 812 in the reactor internal piping line in front of the purifier 809, A safety device control rod 798 is installed in the inside of the reactor control rod 813 to automatically insert the control rod 798 at a time to automatically stop the operation of the nuclear reactor and to operate the nuclear reactor of the nuclear power plant A double structure block tank dust collector 794 of a distribution shaft 705 of a nuclear waste treatment pipe manufacturing process composed of a nuclear power generation facility 811 in the main body 1, And;
The nuclear power generation facility 811 of the nuclear reactor facility of the nuclear power plant operates the first wall pellet 683 of the nuclear reactor reactor facility and the cladding pipes 682 protecting the second wall foul rod 689, A collision of the cladding pipe 682 is generated by the first wall containment vessel 808 and the safety valves 472 in which the plurality of temperature pressure sensing sensors are formed in the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 are opened, Exploded nuclear waste 224 passes through the inner block piping 74a of each block piping line 74 at the upper end of the vessel 813 and the outer block piping 74b passes through the inner block piping 74a The explosion-proof control article cooling water 287 and the yellow loess mixture 927 for soap bubbles are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241 and the double structure block tank 598 ) With respect to the internal lower end positions of the respective portions, the nuclear waste 224 is moved and stored The reactor pressure control valve 472 connected to the internal block tank 596 of the pressure vessel 813 is opened and at the same time the reactor installation of the nuclear power plant is connected to the inner block piping 74b of the block piping line 74, The nuclear fuel explosion-proof control article cooling water and the loess mixture 158 stored in the block tank 596 are transferred to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 857, The cooling water and the loess mixture 927 for the soap bubble are supplied to the cooling water 287 and the cooling water 287 stored in the inner block tank 596 and the outer block tank 599 at the respective positions of the inner block tank 596 and the outer block tank 599, If the inside of the nuclear reactor facility is filled with the sooty loess mixture (927), the explosion of the nuclear reactor facility will be terminated. At the same time, the reactor facilities for the operation of the nuclear power plant will be equipped with nuclear reactor substitute input devices, The nuclear reactor plant is operated with the double structure block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process consisting of the nuclear power generation facility 811 inside the reactor facility body 1 of the power plant ;
The nuclear power generation facility 811 of the reactor facility of the nuclear power plant is provided with a remote control cutting or submarine mineral collection robot 912 for disassembling the reactor facility of the nuclear power plant operating the nuclear power plant, When the internal explosion stops, a plurality of the reactor pressure relief valves 472 are closed and a plurality of the reactor pressure relief valves 472 are normally closed at the time of operation of the reactor facility. (591) of the nuclear power plant. A number of reactor facilities are installed in the anti-sinking type barge of the ocean, and are installed in the reactor main body (1) of the nuclear power plant on land and in the ocean Of the nuclear power plant 811 of the nuclear power plant, the double structure block tank collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process, Configuration be made of copper and;
The nuclear power plant 811 of the reactor facility of the nuclear power plant of the nuclear power plant is provided with a position for installing the nuclear power plant 811 at the top of the sea level of 40 m so as not to be restricted by the weather conditions of the earthquake and tsunami, The equipment and the diving buoyancy control devices are used to regulate the position of the nuclear power plant so that the nuclear power plant can be operated so that a plurality of nuclear reactors of the nuclear power plants not affected by the earthquake and tsunami can not explode. At the same time, The power generation facility unit 811 includes a dual structure block tank dust collector 794 for controlling the nuclear radiation leakage so as to prevent explosion of the nuclear reactor facility in the nuclear fuel chamber that prevents environmental pollution due to nuclear waste, (593,594,595), which is a marine power station that allows safe and continuous operation of nuclear power plants, (1) the nuclear power generation facility (811) inside the main nuclear power plant of the land and ocean nuclear power plants, while ensuring the safety of the power generation facilities and ensuring the renovation of the reactor facilities by continuous operation. A dual structure block tank (794) of a distribution shaft (705) configured to operate the nuclear plant at the nuclear power plant before and after the operation of the nuclear plant
The nuclear power generation facility 811 of the reactor facility of the nuclear power plant of the nuclear power plant includes a mooring device constructed on the barge by nuclear waste disposal, a diving buoyancy control device, a nuclear waste disposal dispensing device, and a nuclear fuel explosion control dispensing device, A dual structure block tank that controls the nuclear radiation leak that prevents the nuclear reactor facility from exploding inside and outside the nuclear fuel chamber to prevent the environment from being contaminated by the waste. The reactor of the nuclear power plant (672) It is equipped with a mooring device, a diving buoyancy control device, a distribution and input device for nuclear waste treatment, and nuclear reactor facilities installed in a nuclear power plant (672) (1) of nuclear power plants of land and sea nuclear power plants of nuclear power plants of nuclear power plants The unit 811 includes a dual structural block tank dust collector 794 of the distribution shaft 705 of the nuclear waste processing pipe manufacturing process so as to operate the nuclear power plant. The nuclear power plant of the nuclear power plant operates. And nuclear waste disposal marine tunnel traffic device (941) Disaster prevention device and carrier, construction machinery with controllable displacement, and wind turbine, thermal power generator and hydroelectric power plant to substitute power generation production;
Wherein the nuclear power plant is a nuclear power plant for nuclear power plants. The method according to claim 1,
The distribution shaft 705 of the dual structure block tank dust collector nuclear waste processing pipe manufacturing process of the nuclear power plant 811 constituting the reactor facility main body 1 of the nuclear power plant on land and on the ocean,
(593,594,595) nuclear power plant 672 of a marine power plant constituting the distribution shaft 705 is connected to the inside of the nuclear reactor facility main body 1 of the nuclear power plant by the marine vessel manufacturing process of the connecting shaft of the nuclear waste treatment pipe manufacturing process 705 The small diameter electrical resistance welded pipe 706 manufactured by the nuclear power generation facility unit 811 is provided with the raw material 707 uncoil 708 at the ring leveling 709 (712) at the cutting and roughing connection (711) to the side trimming (710) and at the same time the equipment of the nuclear power plant (672) performs the welding and the inner and outer bead removal (713) 714 and at the same time the weld heat treatment 715 of the nuclear power plant 672 is equipped with the centrifuge 716 and the centrifugal forming 718 with the water cooling 717 device and at the same time the cutting 719 of the nuclear power plant 672 , And the flatness test (720), and at the same time, the structure pipe 721 of the nuclear power plant 672 The calibrating 722 facility is used to calibrate the process of the facility by hot cutting 726 and chamfer 727 and intermediate hydraulic test 728 in an intermediate load 723 and induction heating furnace 724 to SRM 725 standards. A screw 732 for performing a dimensional inspection 731 visually with an ultrasonic wave and a vortex test 729 and a weight and length measuring instrument 730 and a galvanizing plate 733 for a general pipe 734, (1) of a nuclear power plant that regulates production at a cooling stand (738) equipped with a galvanized steel pipe (735), a galvanized steel pipe (736) and a boiler tube (737) (593,594,595) Nuclear power plant (593,594,595) connected to a joint shaft for the connection of a joint structure capable of disassembling the connection shaft of a double structure block tank (794) and a double structure block tank bridge (937) The power generation plant 672 is connected to the double structure block 810 of the nuclear power generation facility unit 811 of the reactor facility main body 1 of the nuclear power plant, Large precipitators nuclear waste pipe into the distribution shaft 705 in the manufacturing process be configured to achieve a nuclear power plant and nuclear reactor plant, and;
The cage-shaped electrical resistance welded pipe 739 of the marine power plant's 593,594,595 nuclear power plant 672 facility of the distribution shaft 705 is connected to the coil mage steel plate raw material 740 through the side trimming 741 The nuclear power plant 672 facility completes the oil pipeline ultrasonic wave 743 and the flaw test 744 with the cage forming unit 742 connected to the cage forming electric resistance welding pipe (739) Nuclear Power Plant Reactor Facility for Production Distribution Apparatus Dual Structure Block Nuclear Power Plant Unit (811) of Nuclear Power Plant Unit (1) Distribution Shaft (705) of Nuclear Waste Treatment Plant Manufacturing Process
The large diameter steel pipe 747 of the steel pipe 746 for the oil pipeline oil industry of the nuclear power plant 672 of the marine power plant constituting the distribution shaft 705 is connected to the edge milling machine 748 and the three roll banding The production is made in the nuclear power plant 811 of the reactor main body 1 of the nuclear power plant which controls the production by the machine 749 and the post-bending machine 750 distribution dispensers, The outer surface weld 754 of the nuclear power plant 672 facility while concurrently performing the weld 752 and the back firing 753 weld cuts the pipe sagging 755 and the pipe section 756 and the X- The spiral welded steel pipe 760 of the nuclear power plant 672 facility is provided at the same time as providing the nuclear power plant 672 facility execution with the dispensing apparatuses for the process of marking and packing 758 and the cold expanse 758, The uncoiling 761 of the steel pipe pile 762 and the uncoated pipe 763 of the steel pipe pile 762, The first coating 767 of the cleaning 764 and the inner blast cleaning 765 and the inner coating 766 and the coating and coating 768 are performed while the coating of the coated steel pipe 769 of the nuclear power plant 672 ) Constructs the large-diameter steel pipe (747) of the petroleum industry steel pipe (746) of the oil pipeline through the process of the ultrasonic wave and the X-ray inspection (770) At the same time, the reactor facility of the nuclear power plant is installed in the reactor main body (1) of the nuclear power plant by the distribution input devices of the nuclear radiation leakage control device dual structure block tank dust collector (794) (593,594,595) of nuclear power plant (673), docking buoyancy control device for nuclear power plant (672), distribution and input device for nuclear waste disposal, and nuclear reactor facility safety operation of FUSS (811) Equipment as nuclear waste disposal pipe can be connected at the connecting bond decomposition axis marine production factory of a manufacturing process 705 of the structure;
Wherein the nuclear power plant and the nuclear reactor facility are included in the nuclear power plant. The method according to claim 1,
The dual structure block tank dust collector of the nuclear power plant 811 constituting the reactor facility main body 1 of the nuclear power plant and the distribution shaft 705 of the nuclear waste treatment pipe manufacturing process of the nuclear power plant, ), A docking buoyancy regulating device and a nuclear waste disposal nuclear power plant (672)
The distributing and inputting device of the marine power plant (593, 594, 595) nuclear power plant (672) constituting the distribution shaft (705) is connected to the inside of the nuclear reactor facility main body (1) of the nuclear power plant, (598) of the distribution input unit dual structure block tank (598) constituted at the nuclear power generation facility (811) for controlling the production from the marine vessel manufacturing plant to the decompositionally connectable connection structure, The double block structure tank 598 is provided with the double block structure tank 598 and the double block structure tank 598 are provided in the outer block tank 599 that positions the inner block tank 596 and the outer block tank 596, 597) is installed at the end of a double structure block tank 598, which is manufactured by a distribution input device of a cutting process and a welding process connection structure at an industrial site. The double structure block tank pipe bridge type marine tunnel transportation device 941 is connected to a nuclear power plant 672, Of The first auxiliary steel section 600 and the second auxiliary steel plate 601 parts for the block tank are connected to the waste disposal and dispensing apparatus and are produced as a connection and disconnection device of the connection structure of the cutting process and the welding process, A large flange 614 which provides an overlap with the connecting shaft connecting structure of the forward and theft connecting portions 598 of the nuclear reactor 598 is formed by arranging a large flange 614 for providing the position of the nuclear reactor facility connection portion of the nuclear power plant with a stopper plate 625 of a predetermined size The dual structure block tank 598 provided with the nuclear power plant distribution dispensing apparatus of the nuclear power plant equipment process is provided with the steel plate 597 made of high tensile stainless steel, The dual structure block tank 598 dispense and dispense apparatus includes a double structure block tank 598 in the order of bending, cutting, and transporting, and an overhead crane 861 and a conveyor 633, And the nuclear waste disposal dispensing apparatus of the nuclear power plant 672 includes a nuclear power plant facility; and
The double structure block tank 598 of the nuclear reactor facility is provided with a foaming and rolling mortar bending machine according to the thickness of the steel sheet 597 of high strength stainless steel or a high strength stainless steel of the double structure block tank 598 The steel plate 597 is provided with a double structure block tank 598 while a bending process is performed in the form of a right angle bending (a), a V-type bending (b) and a round bending (c) ) The equipment for bending the equipment includes a bending type press braking type bending machine, a bending type roller bending machine, and three bending roller bending machines, ) And a conveyor (633), the position of the banding weld joint of the high-strength stainless steel steel plate 597 is adjusted while the welded joint portion is welded to the welder and the cutting tool The double structure block tank 598 is provided with a large flange 614 (see FIG. 4) for providing a stern connection position with the double structure block tank 598, while simultaneously having a drill lathe and a cutter to perform the welding process to the banding weld joint portion of the steel plate. A large flange 614 for providing a position to the connection position of the nuclear power plant 672 and the nuclear plant 672 of the marine power plant as a connection structure of the manufacturing and processing shelving process, (1);
The inner block tank 596 and the outer block tank 599 that positions the outer block tank 596 outside the inner block tank 596 are connected to the inner block tank 596 at the same time as the pre- The nuclear power plant equipment may be equipped with a dual structure block tank scrubber 794 that controls the nuclear radiation leakage, a dual structure block tank 5988, (593,594,595) in the nuclear power plant main body (1) of the nuclear power plant with the nuclear power plant (673) and the distribution of the diving buoyancy control device and the nuclear waste treatment in the nuclear power plant (672) Pre-operation of the nuclear reactor facility of the reactor and the reactor installation Before the operation of the nuclear reactor of the nuclear power plant (811) of the reactor facility, the nuclear waste treatment pipe manufacturing process (705) Plaiting;
(672) facilities for nuclear power plants, including nuclear power plants (672) for nuclear power plants. The method according to claim 1,
(593,594,595) nuclear power plant (672) of the marine power plant and the reactor structural body (1) of the nuclear power plant (1) and the dual structure block tank dust collector of the nuclear power generation facility section (811) to the nuclear waste treatment pipe manufacturing process The diving ready preparation movable adjustment dispenser screw adjusting portion 811g, which constitutes the connecting axis,
The damping-progress-ready movable-control-distributing-input-device screw adjusting portion 811g includes a double structure block tank hull (not shown) provided in horizontal and vertical coupling structures at respective portions of the holding tank upper barge hull 591 and the holding tank lower barge hull 592 The disassembly and binding portable lug 607 includes a horizontal dual structure block tank hull disassembly and attachment lug 605 having a plurality of lug processing holes 615 and an elongated hole 616 for a double structure block tank hull disassembly and position movement controller in block units. Pin connection shaft (606) Double structure block tank vertical to processing hole (615) Hull disassembly coupling Portable lug pin connection shaft (606) Machining hole (615) and block unit Double structure Block tank Hull breaker Holes 616 are provided to connect the piercing hull 591 and the bottom of the double structure block tank holding tank 590 at the upper portion of the double structure block tank holding tank to the piercing double structure block tank holding tank 590, A double structure block tank hull disassembling and coupling unit 603 bound to several lug processing holes 615 among a plurality of connection shafts 606 bound to a plurality of processing holes 615 provided at respective portions in a vertical form of the branch hull 592. [ The holding tanks 590 are constructed with the connection shaft 606 double structure block tanks 598 provided with the connection lugs 606 for connecting the shafts 606 to the shafts 601 and 602, The ready-for-operation-actuation-control-dispense-input-screw control unit 811g provides a pre-dispense input to the dispensing devices of the immersion rest stop line 634 for lifting the sinking vessel to allow the floating control of the marine power plant (593,594,595) (593,594,595) Nuclear power plant (615) facility of the marine power plant The nuclear waste treatment facility manufacturing process (613) (705) The ready-motion control dispense dispenser screw adjuster 811g includes a double structure block tank 598, a connecting structure at the lower end of the holding tank 590, a connecting structure at each part of the barge hull, 598) The inlet port 585a of the doctor ventilation 585 of the damping control device and the ventilation port 585a of the damping control device of the damping control device and the outlet port of the doctor ventilation 585 (585b) and double structural block tank Hydraulic cylinder door (624) and stopper plate (625) for hull traffic control Double structure piping line Automatic pneumatic valve Transport device (916) and motor control motor control module (106) (593,594,595) At the same time, the diving control device of the nuclear power plant (615) facility of the marine power plant is equipped with a horizontal double structure block tank holding tank (590) Number (593,594,595) nuclear power plant (672) facility of a marine power plant arranged to prepare for the submergence proceeding to the lower sea level SLD by providing a switching to the landing block tank 590 of the submergence retention line 634, The nuclear power plant 672 is provided with the sinking prevention line distribution input to the fly valve 622, the high pressure multi-stage multi-stage disaster prevention pump 8 and the blower 641 of the doctor ventilation 585, (594, 595, 596) are connected to the reactor building (688) with a connection structure inside the reactor main body (1) of the nuclear power plant by providing the protection of the nuclear power plant (672) (1) The double structure block tank dust collector of the nuclear power generation facility (811) is connected to the nuclear waste disposal pipe manufacturing process (705) of the nuclear reactor plant by the diving process preparation Configuration be made to the screw adjustment part (811g) of the same regulation and distribution chute;
The diving operation ready controllable dispensing and inputting apparatus constituting the connecting shaft of the screw adjusting unit 811g includes a double structure block tank hull disassembling and attaching portable lug (not shown) formed at each connecting barge line at the upper and lower ends of the double structure block tank holding tank 590, A screw 603a of the lug connecting shaft coupling bolt 603a and a screw 603b of the lug connecting shaft coupling and disassembling nut 604 and a lug connecting pin shaft 606 are provided with a lug The pins 608 may be disassembled into a hydraulic rotary cylinder machine 619 for position control of the distribution system of the traffic apparatus equipment and a hydraulic cylinder machine 624 for the block unit structural block tank And a plurality of lug processing holes 615 provided in the double structure block tank hull breaking-disassembling portable lug 607 and an elongated hole 616 for the block unit double structure block tank hull breaker position shifting regulator Horizontal The double structure block tank 598 includes a double sash structure paddle saddle form frame 617 for constructing a dual pipe structure tank bridge pier provided with a double structure block tank hull disassembly and traction which is a tugboat 636 provided on a semi diving operation line 637, In the same form Nuclear power plant Reactor unit inside block (1) Block unit Double structure Block tank Docking position adjustment of the hull of the submerged ship (621) and the submerged ship line sinking prevention rescue line (634) (107) for controlling the diving buoyancy and the diverting buoyancy is provided to the bottom barge hull (592) of the double structure block tank holding tank to perform the assembly of the sea surface by a connection structure capable of performing diving coupling. Nuclear power plant reactor main body (1) Nuclear power plant main body (1) Nuclear power plant (811) Double structure block tank Configuration be a rare achieve a nuclear waste disposal tube manufacturing process 705 proceeds dive preparation movable adjustable distribution chute screw adjusting portion (811g) having an axis of connection of the nuclear reactor plant, and;
The power transmission unit 811d, which is provided with transformers for transmitting the power of the nuclear power plant 811 of the reactor facility main body 1 of the nuclear power plant having the screw control unit 811g and the connection shaft,
The dual structure block tank holding tank lower barge hull 592 constituting the connecting shaft of the power transmitting portion 811d is provided with a diving preparation ready protection position at the lower end SLD of the sea surface, And an outlet power source 686 and an inlet power source 687 for the voltage 684 and the power 685 to provide the production power to the production power supply 688. [ The primary transmission substation 691 is provided with seven steel wires 692 and a transmission line diameter 692 at the center of the transmission substation from the extra high voltage substation 690 to the shift control substation 690. [ The double structure block tank holding tank lower barge line hull 592 having the input portion 695 with the 54 strands of aluminum wire 693 and the connecting shaft of the power transmitting portion 811d is provided with the submarine line wiring connection structure The marine tunnels that provide the location as a connected structure The primary transformer 691 is connected to the high voltage substation 690 provided with the production power supply shift control transformer 96 of the transverse railway substation 696 and the intermediate transformer substation 697 and the power 685 A large-scale plant 698 for providing power supply and a substation plant 699 are provided with production power supply to a position having a submarine line wiring connection structure. At the same time, a primary substation constituting a connection shaft of the power transmission unit 811d 691 in the secondary substation 700 is a connection structure having a substation line 701 for connecting the substation 701 and a submarine line wiring connection structure for providing the production power supply distribution discharge to the household 702 including the solar house And a substructure 95 and a transformer 96. The connection structure of the submarine line is connected to the step foot hook 703 and the cable balance ultra high voltage wire balance insulator 704, Production power supply distribution (GLD) on the land, a connection with a connection structure that provides the output of the production power supply distribution provided by the wired lines. (1) a nuclear power plant main body (1), which is equipped with a production electric power supply regulating device and distributes production electric power supply of the nuclear power plant main body (1) The power transmission unit 811d having the connecting shaft of the nuclear waste treatment pipe manufacturing process 705 of the nuclear reactor facility is supplied with the production electric power to the household 702 including the solar house;
The power transmission unit 811d provided as transformers for transmitting the power of the nuclear reactor facility unit 811 of the reactor facility main body 1 of the nuclear power plant is a transformer connection structure having a submarine line wiring connection structure, The nuclear plant facility is provided with a structure for connecting the sink preventive stay line 634 for lifting the sinking vessel to the inside of the reactor installation main body 1 of the nuclear power plant or a double structure block tank 598) for controlling the nuclear radiation leakage is provided in the nuclear reactor main body 1 of the nuclear power plant or in the nuclear power plant 672 of the marine nuclear power plant 593,594,595. Nuclear waste disposal of reactor facilities at the Fuehsien Nuclear Power Plant (811) before the safety operation of the reactor equipment of the mooring device, the diving buoyancy control device and the nuclear waste disposal dispensing device and the reactor facility This decomposition can be connected in a marine vessel coupled manufacturing plants connection axis of the manufacturing process 705, structure;
And a diving progression ready controllable dispensing device screw adjusting part (811g) having a connection shaft of the pipe manufacturing process (705). The double structure of the nuclear waste treatment facility for nuclear power plant Nuclear reactor installations. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The distribution input device of the nuclear power plant for a dive buoyancy preparation ready movable control system constituting the connection axis position of the diesel engine 705,
The distribution input apparatus constituting the nuclear power plant facility is composed of a nuclear power plant (672) of floating power plant (593,594,595) of a marine power plant and a nuclear reactor main body (1) of a nuclear power plant as a nuclear waste processing dual structure Block Tank The marine tunnel traffic device 941 is connected to a double structure block tank pipe bridge 937 at the upper part of a dual structure holding block tank pipe bridge 928 to treat nuclear waste of a nuclear power plant double structure block tank marine tunnel traffic device (941) is comprised of a buoyant buoyancy preparation ready controllable in the ocean and the nuclear waste treatment dual structure block tank bridge 929 is connected to the nuclear waste disposal dual structure block (SLD) 40M position at the sea level (SLD) Tank tube bridge (929) The position of the facility is adjusted by the dive buoyancy preparation ready operation control, and the double structure block tank, the marine tunnel traffic facility (941) The connection shaft of the bridge (929) and the connection shaft of the nuclear waste disposal double structure block tank bridge (929) are provided with the dispersion control of the capacity of the reactor installation body (1) of the nuclear power plant as the preparation for diving buoyancy preparation ready operation, The connection shaft of the pipe bridge (929) is inserted to the upper end of the pipe bridge (937) of the double structure support block tank pipe bridge (928) and inserted into the connection shaft of the nuclear waste treatment double structure block tank bridge bridge (929) The empty space of the control structure for distributing the capacity of the floating nuclear power plant (593, 594, 595) nuclear power plant (672) of the marine power plant to the inner position of the pipe bridge (937) base of the dual structural block tank holding tank pipe bridge (928) An inner block tank 596 for providing a position to the center of the double structure block tank 598 of the tank 598 and an outer block tank 596 for positioning the inner block tank 596 and the outer block tank 596, The block tank 599 (598) Dual structure block tank with connection structure inside the body The marine tunnel transport system (941) has a double structure block tank bridge bridge (929) and a double structure block block tank bridge (593,594,595) nuclear power plant (672) facility of a marine power plant is provided with the construction equipment located inside the distribution input device hull of the sink prevention rescue ship (634) (593,594,595) Nuclear power plant (672) facility and connection structure of marine power plant (1) inside the nuclear reactor plant main body (1) of the nuclear power plant, (672) of a nuclear power plant (672) which provides a sinking ship lifting by a sinking prevention resident line (634) having a submarine line injection nozzle of a submarine line injection nozzle connection port and a submarine line wiring connection structure (1) Nuclear power generation facility (811) Screw control unit (811g) Dual structure block tank dust collector is installed in nuclear waste treatment pipe manufacturing process (705 ) Of the reactor main body (1) of the nuclear power plant, which constitutes the connecting shaft position of the nuclear power plant,
The screw control portion 811g of the nuclear reactor main body 1 of the nuclear power plant is connected to the block tank engaging portable lug 607 constituting the connection shaft position of the nuclear waste processing pipe manufacturing process 705 of the reactor facility. The distribution dispensing apparatus of the present invention is provided with a pipe bridge 937 so as to be connected to the floating structure of the nuclear reactor facility main body 1 of the nuclear power plant and the floating sea which is not formed at the upper part of the double structure block tank pipe bridge 937 of the nuclear power generation facility unit 811 (593,594,595) The nuclear plant facility is provided with a strut tank upper barge hull 591 and a strut tank lower barge hull 592. The strut tank upper barge hull 591 is provided with nuclear power plant facilities And a double structure block tank combined portable lug 607 formed separately from the support block tank 590 and a plurality of double divergent holes provided at each portion are provided in the holding tank lower barge line hull 592, A plurality of hull disassembly portable lug pin connecting shafts 606 bound to the coarse block tank hull disassembly portable lug 607 is connected to the block tank hull disassembly portable lug connecting shaft bolt 603 and the lug connecting shaft bolt thread 603a ) And a lug fin 608. Each of the floating type dishes 593, 594, 595, which are equipped with a nuclear power plant facility and constitute a nuclear reactor main body 1,
(593, 594, 595) nuclear plant installation is provided with a nuclear power plant facility by the depth of the sea surface (SLL) of the landing block tank (590) in accordance with the sea depth, (593, 595) and the respective coupling connection structures are provided in the respective portions of the double structure block tank-combined portable lug (607), while the small-sized floating pillow (593) Block tanks Hull disassembly connection Portion of the portable lug 607 Multiple block tanks bound to the joint hole 615 Hull disassembly Portable lug pin Disconnect the connecting shaft 606 from the block tank hull Disassembling the portable lug Connecting the shaft bolt (603a) of the block 603 and a screw 603b of the block tank hull disassembly coupling portable lug connection shaft disassembly coupling nut 604, The tank marine tunnel traffic facility 941 facility and the dual structure strut block tank pipe bridge 928 are constructed of construction equipment to position the hull deck deck of the distribution control unit 634 with the sinking rescue vessel 634, (593, 594, 595) nuclear power plants (593, 594, 595) are secured to the submarine by fixing the mooring crank (846) for mooring device anchor replacement to the hydraulic cylinder machine (624) The connection structures provided to prevent sinking of the power plant are connected to the submarine line injection nozzle connecting port of submarine line spraying nozzle and submarine line wiring connection structure inside the nuclear reactor facility main body 1 of the nuclear power plant by sinking prevention flood control structures (593,594,595 ) Nuclear power plant facilities (1) Facility (1) Facility facility of nuclear power plant as connecting structure of construction equipment to establish position on hull deck deck of nuclear power plant facility Providing the fixation of a shredder crank (846) for mooring anchor replacing the undersea hydraulic cylinder machine 624 and jakki bed prevent sinking into the connection structure at the 616 stay line 634 and configure be made for a nuclear power plant facilities, and;
(593,594,595) Nuclear power plant's distribution input device for sinking prevention constituting the nuclear power plant facility is located at the upper position of 40 meters above the double structure block tank pipe bridge (937) (1) of the reactor main body (1) of a nuclear power plant which is provided with the bridge bridge bridge bridge and the nuclear power plant main body (1) (593,594,595) nuclear plant facilities of the nuclear reactor plant main body (1) of the individual nuclear power plants that distribute and discharge the readings (593,594,595) to the sinking anti-
A double structure block tank 598 of the nuclear power plant, and an inflow control device of the connection structure of the nuclear power plant facility 598, a distribution barrel and a fixed barge The double structure block tank bridge piers 928 for supporting the nuclear power plant equipments with the vacant space of the connection and disconnection device distribution shaft by the connection structure of the double structure block tank 598 of the plurality of floating type floats 593, (SLL) and a connection structure of pipe bridge pier (928) provided in units of 500 cubic meters of double structure block tanks are provided as connection structures and fixed to the seabed at intervals of 500 meters. Construction equipments are provided and the mooring device anchor replacement worm crank 846 located at the bottom base 851 for the bridge pier level ), While the nuclear power plant equipment is provided as a fixed installation connection structure. At the same time, the nuclear power plant equipment is connected to the nuclear power plant reactor main body (1) An apparatus main body (1) constituting a facility;
The distributing and inputting apparatus constituting the distributing shaft of the floating type sinking restraining (593, 594, 595) connecting structure of the nuclear reactor plant main body (1)
Upper barge deck at the upper end of the barge deck deck of distribution dispenser (593, 594, 595) distribution shafts and barge at the top of the sea surface to provide a position on the sea surface at the bottom of the deck 40 meters above the deck deck. At the top of the deck deck, there is a shelter to protect sailing vessels from natural disasters. At the same time, the nuclear plant's nuclear reactor facility (1) facility provides electricity to the environmentally friendly pollution-free energy industry, and a number of nuclear power plants and wind power plants The hydropower plant is provided with individual power generation facilities and the seabed mineral resource collection site is located at the upper deck of deck deck deck (593,594,595) of submarine mineral resource collection site and floating lifting dock (593,594,595) located in the lower part of the floating deck hull deck deck (SDL) But the normal position of the block pylon 116 is provided with a floating pylon top pants (1) of the reactor main body (1) of the nuclear power plant by providing the distribution shaft of the distribution shaft for providing the position of each of the generator facilities to each of the aircraft emergency landing sites which are located at the upper position of the deck deck (593,594,595) deck deck top, which provides a position to the position with the distribution shaft connection structure of the line injection nozzle and submarine line wiring. At the weather observation site, the aircraft emergency landing area is divided into the distribution shaft The reactor main body 1 of the nuclear power plant is constituted by the electronic control regulator construction machine regulator 811f of the nuclear power generation facility 811;
(1) the distribution control system of the nuclear power plant (1) the control system of the nuclear power plant (811) consisting of the inside of the reactor facility main body of the nuclear power plant providing the electronic control device for the operation of the carrier for the distribution shaft construction machine The connection structure distribution dispensing device,
The electronic control regulating device construction machine control unit 811f is provided with a connection structure having a submarine line wiring connection structure to the submarine line injection nozzle of the submarine line injection nozzle connection port into the reactor installation main body 1 of the nuclear power plant Nuclear Waste Treatment Double Structure Block Tank The Marine Tunnel Transportation Equipment (941) facility is equipped with a double shaft, double structure block tank bridge pipe bridge (929) and a double structure block tank bridge pipe (937) The double structure block tank 598 having the connection shaft of the block tank pipe bridge 937 is provided with the guide rail 618 for the hull transportation device in the inner block tank 596 facility provided at the lower end position inside the inner block tank 596 The inner block tank 596 is provided with an inner block tank 596 and an outer block tank 599. The inner block tank 596 is installed in the inner block tank 596, Of A guide rail pedestal 852 for providing a position to a connection structure at the lower end of the guide rail 618 for providing a position at the lower end of the inside of the inner block tank 596, 596 may be provided with natural gas and crude oil transportation, or may be provided with natural gas and crude oil, for example, The transport facility is provided with a pipeline line automatic pneumatic valve transport device 916. The tug line 636 and the semi-submerged operation line 637 are connected to the inside of the reactor installation main body 1 of the nuclear power plant, (634), nuclear plant facility and nuclear reactor power plant nuclear reactor equipment distribution input device, and
(941) Installed to a position where disassembly and assembly of facilities can be completed. Nuclear power plant reactor main body that completes the process and connects both sides of land and the book. (593, 594, 595) having a distribution axis for exposing the upper surface of the sea surface (1) on a substrate of the nuclear power plant (1) to the inside of the nuclear reactor facility main body (1) of the nuclear power plant by construction machine equipments, The system is equipped with a mechanical control unit (811f), and a mooring device and a diving buoyancy control device installed in a nuclear power plant (673) and a nuclear power plant (673) The connection axis of the nuclear waste processing pipe manufacturing process 705 of the reactor facility at the former Huizhou nuclear power plant 811;
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) (705) Diversification preparation for the operation of the diving power plant that constitutes the nuclear power plant facility Operation of the distribution control unit for the control and control of the nuclear power plant equipment and the barge hull at the top and bottom of the holding tank of the nuclear power plant facility (591,592) Nuclear power plant facilities The distribution and dispensing apparatus for providing the processing unit 811a,
The distribution input device of the nuclear power generation nuclear waste processing unit 811a is connected to the submarine line injection nozzle 593,594,595 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant, (593,594,595) of the submerged marine power plant with the connection structure with the submarine line connection structure. (591) The holding tank tank provided at the connection structure of the nuclear power plant. (591) The holding block tank for positioning the lower part of the central part A column block tank 590 for providing a position as a connecting structure at the center of the lower tank barge 592 of the lower tank barrel 590 and a plurality of column block tanks 590 for providing a position as a connection structure around the center of the barge hulls 591, 590 are connected to the upper and lower ends of the support block tank 590 of the connection shaft of the upper portion of the strut tank upper barge hull 591, A plurality of processing holes 615 and a block unit double structure block tank hull disassembly unit 607 are provided in the body of the double structure block tank combined portable lug 607. However, The lug elongated holes 616a for the position movement control device are connected to the screw shaft 603a and the lug connection shaft coupling 603a of the connection tank shaft 606 and the lug connection shaft coupling bolt 603, The nut screw thread 603b of the splitting nut 603 and the block tank hull disassembly coupling portable lug 607 and the block tank coupling portable lug fins 608 are connected to the float control port 593,594,595 of the anti- (619), a mooring unit and a floating bed (616) connection structure for a hull balancing hull balancer, there is a floating structure of a marine power plant (593,594,595) (593,594,595) Nuclear power plant (672) of submarine power plant and submarine line injection nozzle nozzle connection to submarine line main body (1) of nuclear power plant At the same time, (593,594,595) nuclear power plant (672) of a submerged offshore power plant (673) and a nuclear reactor plant main body of a nuclear power plant 1) Nuclear power plant nuclear waste disposal screening facility with internal protection Two-tiered block tank to provide leakage of nuclear radiation from nuclear reactor facilities. Nuclear power plant equipment (811) Nuclear power generation nuclear waste treatment unit (811a);
A double structure block tank coupling lug 607 for providing a connection structure to a nuclear power generation nuclear waste treatment section 811a of a nuclear power plant 672 of a marine power plant's floating power plant 593,594,595 and a nuclear power plant 811 of a nuclear power plant, ),
(593, 594, 595) nuclear power plants 672 of the nuclear power generation nuclear waste processing unit 811a are installed at the respective portions of the upper barge hull 591 and the holding tank lower barge hull 592 of the holding tank 590 in horizontal and vertical forms A double structure block tank provided with a coupling structure and having a plurality of processing holes 615 and an elongated hole 616a formed in the body and having a horizontal pin connection shaft hole 615 and a vertical pin connection shaft 615, Holes 615 and a long hole 616a are formed in the upper portion of the strut tank 590 so as to be perpendicular to the connecting portion of the strut block tank 590 and the upper end barge hull 591 and the lower end barge hull 592 of the strut tank 590, The connection shafts 606 bound to the plurality of the processing holes 615 among the plurality of connection shafts 606 coupled to the plurality of processing holes 615 provided at the respective portions in the shape of the connecting shafts 606 are removed, The connection structure is provided with the coupling of the nuclear power plant 672, The double structure strut block tank (590) facility is equipped with a connection structure distributing and inputting device capable of disassembling and disassembling the nuclear power plant (672) by pre-distributing the sink prevention rescue line (634) Assembled nuclear power plant (672), and the lower part of the center of each vertical strut block tank (590) is provided with connection structure by excavation equipment and mooring devices, and is provided as a connection structure The vertical holding block tanks 590 are provided in the vertical holding block tanks 590 and the position adjustment switching is provided in the vertical holding block tanks 590 in the auxiliary adjusting block connecting structure resisting lines 634. Alternatively, The throttling control device of the power plant (672) is provided with a pre-sinking prevention line (634) prepared for the submergence proceeding at the lower end of the sea level (SLD) (1) Double structural block for nuclear radiation leakage control of reactor facilities of nuclear waste treatment shielding system with connection structure with protection (1) Excavation equipment and mooring equipment provided on the anti-sinking rescue ship (634) (593,594,595) nuclear power plant (672) of a marine power plant and nuclear reactor facility main body of nuclear power plant (1) nuclear waste treatment section (811a) of nuclear power generation facility section (811) (811a) distribution equipment, drilling rigs and mooring devices to make the reactor plant operate;
(593,594,595) nuclear power plant (672) of the nuclear power plant of the nuclear waste disposal unit (811a) and the nuclear reactor main body (1) of the nuclear power plant. The rotary table lathe machine 908)
The nuclear reactor waste disposal unit of the nuclear waste disposal unit 811a comprises a nuclear reactor facility main body 1 and a distribution input unit of the nuclear reactor nuclear reactor operation unit comprises a floating harvesting plant of a submergence preventing marine power plant which is located at the sea level upper end SLU of the sea level SLL The rotary table lathe machine 908 of the drilling machine for drilling crude oil in the drill machine room of the hull deck upper part (SDU) is located at the upper end of the drill machine room when the crude oil is connected to the plurality of pipe racks 854 The pipe rack 854 in the state ready for excavation preparation is provided with the boom of the crane boom of the overhead crane 651 and the boom hook connection of the crude oil bound to the boom hook 652 and the connection structure of the wire rope 19, And a plurality of pipe racks 854 provided as connection structures of the sea level lower end SLD of the sea level SLL. The core drill 917 is provided with a drilling hole 936 as an excavator rotation body At the same time, the core drill (917) Which is mounted on each of the strut block tank upper barge hulls provided as a connection structure at the position of the hydraulic cylinder machine 624 and the key bed 616 at the position of the excavation hole 936 provided at the connection structure, (593,594,595) of the non-sinking marine power plant, and the crude oil and natural gas discharged from the location of the crude oil borehole (936) in the nuclear power plant facility. (SDU) upper part of the hull deck upper part (SDU) equipped with a submarine line wiring as a subsidiary connecting structure, or a connection structure is provided at the upper end of the lower part of the block pylon 15 of the nuclear power plant facility The ceiling crane 651 is provided with a linking structure inside the machine room of the drilling machine located at the lower end of the overhead crane 651, The table-table lathe machine 908 is provided with several hydraulic cylinder keys 623 for drilling, which are located at positions opposite to the circular table line with the rotating body of the rotary table lathe machine 908 body, The rotary table lathe machine 908 of the drilling machine for crude oil is brought to the position opposite to the center line position in the line, The rotary table lathing machine 908 continues to bind the pipe racks 854 to the central position with the rotor connection structure, A plurality of pipe racks 854 provided at a point of a crude oil borehole 936 located at a connecting structure, A nuclear borehole 936 is provided with a core drill 917 for rotating a drilling hole 935 of a crude oil borehole 936 equipped with a nuclear waste treatment facility 911 and a nuclear waste treatment facility 916 composed of a reactor facility body 1 of a nuclear waste treatment unit 811a The distribution dispenser of the nuclear power plant is provided with a pipe rack 854 for crude oil when crude oil is connected to the wire rope 65 of the ceiling crane 651, Machine tools turning (908) Blocks for the drilling of a bit of body Rotary table of units with hydraulic rotary cylinder machine (619) for dismounting coupling adjusters Hydraulic cylinders for drills A rotary table lathe machine (9) of a crude drilling machine for drilling crude oil with a feed arrangement with a feed arrangement to the top of a rotary table lathe machine (908) of a crude drilling machine 08) operation, the crude oil and natural gas discharged from the position of the crude oil borehole 936 are simultaneously moved to both sides of the boom and boom hook 652 of the crane boom of the tower crane 886 while terminating the excavation of the crude oil bore hole 936 The boom of the crane boom of the tower crane 886 and the boom hook 652 of the tower crane 886 are vertically rotated to provide the deep sea energy resources to the top of the deck deck. At the same time, The distribution dispenser that constitutes the waste disposal system is to transfer crude oil and natural gas discharged from the crude oil borehole (936) inside the nuclear power plant facility to the inside of the nuclear power plant from the crude oil borehole (936) Nuclear power plant is operated as a connection structure between crude oil and natural gas to be discharged. The crude oil and natural gas crude oil borehole distribution system, which is positioned as a connection structure at the location of the crude oil borehole (936) in the interior, is connected to the oil well borehole (936) Nuclear waste landfill is set up at a deep sea basin borehole (936), and nuclear power plant facilities (593,594,595) installed at coastal marine power stations are equipped with safe mooring facilities by means of mooring devices and diving buoyancy control devices At the same time, a crude oil borehole 936 is provided as a nuclear waste incineration treatment core drill 917 into the nuclear reactor facility main body 1 of the nuclear power plant, and at the same time, the nuclear facility operation body 1 of the nuclear waste treatment unit 811a is operated ;
The distribution input apparatus constituting the sinking restraining line 634 as a connection structure of the nuclear power plant facility of the marine power plant of the nuclear waste disposal unit 811a,
The nuclear power plant equipment of the nuclear waste processing unit 811a operates the hydraulic cylinder apparatus 39 by connecting the anchor replacement crankshaft 846 connected to the construction machine to the core drill 917 drilling hole 936 as a connection structure The wrench crank 846 is pushed into the excavation hole 936 and the wrench crank 846 compresses and expands inside the excavation hole 936 to form a crevice tool 185) are fixed to the ground by means of a connection structure, and at the same time, the guide bar (185) fixes the lower end portions of the respective holding tanks so that the barge line is prevented from drifting, Prevention; and
(593,594,595) of the marine power plant (593,594,595) Stacked tank top barge with mooring device of nuclear power plant equipment Construction machine mounted on the hull Barge to locate the connection structure Hull equipped with anti-drift prevention Anchor replacement crank (846) Mooring device (593,594,595) of the nuclear power plant (673) and the distribution of the diving buoyancy control device and nuclear waste disposal in the nuclear power plant (672) of the marine power plant. Before the safe operation of the reactor installation of the reactor and the reactor, the connection shaft of the nuclear waste processing pipe manufacturing process (705) of the reactor facility in Fushih nuclear power plant (811)
And the nuclear waste disposal unit (811a) is constructed as a connection structure capable of disassembling and coupling the nuclear power plant of the nuclear waste disposal unit (811a) at the marine vessel manufacturing plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) And the nuclear waste disposal input device of the nuclear waste disposal unit 811a constituting the connection axis position of the nuclear waste disposal unit 705,
The nuclear waste disposal and dispensing apparatus of the nuclear waste disposal unit 811a is a connection structure of a floating nuclear power plant 593,594,595 nuclear power plant 672 of a submergence preventing marine power plant and a nuclear power plant main body 1 of a nuclear power plant, The large flange 614, which provides the location of the nuclear waste disposal dispenser with a connection structure with submarine line injection nozzles and subsea line interconnection structure of the connection, is connected to the connection distribution dispenser connection structure of the double structure block tank 598 The connecting structure for constructing a double structure block tank 598 and a landing block tank 590 as a link structure for constructing an equator (EL) on the Earth's south pole (SP) and the north pole (NP) The double structure block tanks 598 are provided in the form of a double structure block tank barge line, and at the same time, the distribution input device of the double structure block tank barge line is provided with the pre-sinking retention line 634, (593,594,595) Nuclear power plant facilities to provide the whole connection of nuclear power plant facilities. Nuclear waste treatment at intervals of 500m. Double structure block tank pipe bridge (929) Connected (937) body structure at the same time as constructing a double structure block tank pipe bridge pier (928) in order to construct a connection structure, and at the same time, the distribution input device of the nuclear power plant equipment is submerged in the deep sea The double structure block tank pipe bridge pier 928 is installed at a location where the double structure block tank pipe bridge pier 928 is installed, At the same time as installing the flagpole rubber balloon (628), the distribution and input device of the nuclear power plant equipments are provided with direction indication and depth depth recognition notation A mounting position of the double structure block tank pipe bridge 928 which hangs the wire rope 915, the diving position adjusting movement device of the hull and the diverting buoyancy weight 949 is provided at the lower end of the flagpole rubber balloon 628 And transferring the individual double structure block tank pipe bridge 928 to the same sink prevention resident lines 634 as the floating control pipes 593,594 and 595 of the marine power generation plant while towing the double structure block tank bridge bridge 928 with the tug line 636, Distributed structure inside a reactor plant main body (1) of a nuclear power plant, and a large structure flange (614) for joining a double structure block tank with a connection structure having a submarine line wiring line connection structure (946) to the injection nozzle of a nozzle nozzle connection distribution (593,594,595) Mooring equipment of a nuclear power plant (593,594,595) Nuclear power plant (672) and atomic power plant's atomic power plant Equipment unit (1) configured to be made of nuclear waste processing plant reactor to the distribution chute of a nuclear power seolbibu 811 nuclear waste processing section (811a), and;
A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation unit (811c) of a construction machine for establishing a connection with a nuclear waste disposal unit (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.
The distribution input device of the reactor construction equipment of the nuclear power plant equipment is provided with the transfer of the nuclear power plant equipment to the sink prevention resident line (634), or after the transfer of the nuclear power plant equipment, the water depth of the installation point is 300 meters , The pile column is increased by 50 meters more than the water depth and attached to the seesaw crane boom base 942 of the tower crane for the position-control mobile device, the pile 898 is vertically erected and the excavator for the deep- 845), a rock drill (847), a perforator (876), a hatcher and an anti-erection machine (877) 880 includes a file driver 882, a diesel file hammer 883, a steam hammer 884, a hydraulic crane 885, a tower crane 886, a crawler crane 887, a truck crane 888, 889 and the tandem roller 890, The tamping rollers 891 and the tire rollers 892 and the tractors 893 and the trailers 894 are installed in the distributing and inputting apparatuses of the nuclear power plant construction machinery and the distribution tubes of the respective nuclear power plant construction machinery, The apparatus includes a system for distributing a nuclear power plant construction machine with a ram 895 and a lid 896, a coolant cooler 897, a helmet 899, a fuel pump 900, a cam 901 and a fuel tank 902 908 and the adapter 906 of the starter 903 which is provided as a device and simultaneously provides a base of a plurality of double structure block tank pipe bridge 928 as a connecting structure on the sea floor (929) of nuclear waste treatment double structure block tank bridge (929) and prepare double structure block tanks of 10 double structural blocks to the installation position of double structure block tank pipe pier (928) of each place Or to connect one set of the above double structure block tank The double structure block tank bridge pier (928) exposed at the upper sea level of sea surface is provided with a mooring structure, and a dual structure block tank is connected to the rope to moor and at the same time, an actuator 848 is operated in the construction machine cab (593,594,595) Protection of nuclear power plant facilities by mooring system and nuclear reactor plant main body of nuclear power plant (1) Nuclear power generation facility (811) Nuclear waste treatment section (811) (593,594,595) Nuclear power plant equipment of a marine power plant as a distribution input device of a nuclear reactor construction equipment that consists of a nuclear waste disposal dispensing device as a transportation transportation part (811c) of a construction machine providing connection with a nuclear power plant ;
A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation unit (811c) of a construction machine for establishing a connection with a nuclear waste disposal unit (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.
The distribution and input device of the nuclear plant construction equipment of the nuclear power plant equipment is composed of a nuclear waste processing double structure block tank bridge 929 Is provided by moving the holding block tank 590 to a depth of 500m 3 of the double structure block tank at the depth of the sea level SLL to provide movement and at the same time providing the double structure block tank bridge 929 The connecting structure anchor 639 and the anchor chain 640 provided at the crane boom portion 942 of the crane substituting tower crane are provided on the seabed. At the same time, the crane boom portion 942 is wound around the rotary body tumbler winch 958, 958 to provide a distributing and inputting device for a nuclear reactor construction machine that releases the anchor 639 and the wire rope chain 915, and at the same time, as a connection structure inside the reactor installation body 1 of the nuclear power plant, (593,594,595) of mooring prevention marine power plant with mooring devices are installed in the main body of nuclear power plant (1) Nuclear power generation facilities (811) Nuclear waste disposal and dispensing apparatus composed of a nuclear waste disposal and dispensing apparatus as a transportation transport unit (811c) of a construction machine providing connection with a nuclear waste disposal unit (811a). Constituting nuclear plant facilities;
A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation unit (811c) of a construction machine for establishing a connection with a nuclear waste disposal unit (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.
The distribution input device for connecting the nuclear waste treatment dual structure block tank bridge 929 constituting the nuclear power plant facility to the nuclear power plant facility and the reactor facility construction machine is a device for connecting the nuclear power plant, (959), which is repeated while being wound around a rotary hook-and-loop winch (958) and loosened with a hook-and-loop winch (958) to release the anchor chain (640). At the same time, The supply sail 959 is connected to the double structure block tank 598 at the side of the nuclear waste treatment double structure block tank bridge 929 at the sea surface by a combined operation process (929) of the double-structure block tank bridge (929) connected to the Nuclear Waste Disposal at the same time while providing a provisional passage for the ship as a connection structure. Water Treatment Double Structure Block Tank Tube Bridge (929) Double Tank Block Tank Bridge (929) Double Structure Block Tank (598) Connection Location The double structure block tank connection portion may be provided as a connection structure at a predetermined distance between the even number of connection portions and the odd number of connection portions out of the outer block tank 599 to the double structure block tank, (1) Nuclear waste disposal in-house Double structure block tank bridge (929) Combined connection structure as a mooring device Vessel vessel temporary pathway Reactor facility Providing the dispensing devices of the construction machine, It is a connection structure with an internal connection structure. It is a connection structure having a submarine line wiring connection structure to the injection nozzle of the injection nozzle connection port. (593,594,595) of mooring prevention structures (593,594,595) of mooring preventive offshore power plant by mooring devices to the nuclear reactor plant main body (1) Nuclear power generation facility (811) Nuclear waste treatment section (811a) (811c) is a connection structure of equipment for providing protection of the distribution input device of a nuclear reactor construction equipment comprising nuclear waste disposal dispenser;
A reactor facility construction machine (1) comprising a nuclear waste disposal and dispensing apparatus as a transportation transportation unit (811c) of a construction machine for establishing a connection with a nuclear waste disposal unit (811a) of a nuclear reactor facility main body (1) The distribution dispensing apparatus of FIG.
The distribution input device for connecting the nuclear waste treatment dual structure block tank bridge (929) constituting the nuclear power plant facility and the nuclear reactor plant construction equipment to the nuclear power plant facility and the nuclear reactor plant construction equipment is the same as that of the above-mentioned floating nuclear power plant equipment (593,594,595) The partitioning and injecting apparatus for pipe bridge cracking and dismounting with a connecting structure is provided with a pivoting mechanism for pivoting a pivoting lug 21 at a portion abutting against a peg lug 21 provided as a joint detachment hinge 27 at an outer position of the outer block tank 599 A double structure block tank having a hinge binding for a hinge a-shaped lug pin connecting shaft 27a and a hinge long axis connecting shaft 27b is connected to a double structure block tank connecting portion at a predetermined distance interval position (1) as a connection structure inside the reactor facility of a nuclear power plant with a spray nozzle of a nozzle nozzle connection and a connection structure with a submarine line wiring connection structure. (593,594,595) Nuclear Power Plant Reactor Facility Provided by Mooring Devices of Nuclear Power Plant Facilities (1) Nuclear Power Generation Facilities (811) Establishment of connection with nuclear waste treatment section (811a) (811c) a nuclear waste disposal and dispensing apparatus, a distributing and dispensing apparatus for a nuclear reactor construction machine is provided, and a lock-unlocking device is hung on a horizontal outer wall position;
The distributing and inputting apparatus of the nuclear reactor construction machine is provided with the handle lever 935 welded to each other while vertically rotating to arrange the connection portions of the double structure block tank at the respective positions, ) And the ground (22) are provided with a double structure block tank disassembly coupling structure and at the same time a block unit double structure block tank hinge disassembling lug hinge socket (613) (593,594,595) Internal connection structure of the nuclear power plant Equipment injection nozzle of the nozzle connection and subsea line wiring (946) Double structure block provided with connection structure Double block tank pipe bridge (937) Combined distribution input (593,594,595) Mooring equipment of nuclear power plants Mooring equipment of marine power plants (593,594,595) Combined decomposition of nuclear power plant facilities with double structure block tank connection position Fixed lifting system of marine power plant with provision of disassembly structure of double structure block tank by interlocking device (185) and grounding device (22) Dock (593,594,595) Nuclear power plant facilities were installed with the distribution and input devices of the reactor facilities of the nuclear power plant, and the mooring device, diving buoyancy control device and nuclear waste disposal processing installed in the ocean power plant floating plant (593,594,595) nuclear power plant (672) Before the safe operation of the nuclear reactor facility of the apparatus and the nuclear reactor facility, the connection axis of the nuclear waste processing pipe manufacturing process (705) of the nuclear reactor facility in Fusi Nuclear Power Plant (811)
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
The power generation and production unit 811b of the nuclear power generation facility 811 constituted by the nuclear power plant 672 of the marine power plant of the land and sea and the nuclear power plant main body 1 of the nuclear power plant, The distribution input apparatus of the power production and production unit 811b, which includes a dust collector as a plurality of generators for nuclear waste disposal and power generation of a nuclear reactor facility,
The distribution and input device of the power generation and production section 811b is a connection structure of the nuclear power plant main body 1 and includes a plurality of generator distribution input devices for generating the ocean power station's 593,594,595 power generators including 593,594,595 ) Nuclear power plant (672) and connection structure inside nuclear reactor plant main body (1) of atomic power plant Injection nozzle connection Submarine line wiring (946) Nuclear waste disposal double structure block tank bridge structure providing connection structure (593,594,595) Nuclear power plant (672) facilities are provided with a linkage arrangement control device (593, 594, 595), a connection control device (929) Dependent deck decks constructed as a structure Decks connected to each other in the marine power plant in each location Double structure block tank Decks Decks are double-structured in the form of a nuclear explosion- (593,594,595) Nuclear power plant (672) facilities of marine power plant of nuclear power plant of nuclear reactor power plant (677), marine wind power plant (957) and marine seesaw An atomic power generator 772 provided outside the hydroelectric power plant 943 outside the double structure block tank dust collector 794 for controlling the leakage of the nuclear radiation for the eco-friendly wind power generator 957a and the deck deck interior, and a large hydroelectric generator A connection structure provided with a fixed connection structure and provided with connections to respective line distribution shafts and provided with transformers for transmitting the power of the nuclear power plant 811 to each distribution shaft in the reactor main body 1 of the nuclear power plant, The nuclear waste disposal facility having the transfer unit 811d and the connection structure having the connection structure of the submarine line injection nozzle and the submarine line wiring 946 into the reactor main body 1 of the nuclear power plant (929) Combined distribution input device The connection structure of a marine power plant which is provided as a connection structure of a plurality of marine power generation facilities and a distribution input device of a floating marine mooring device. The power generation and production unit 811b of the nuclear power generation facility 811 including the nuclear power plant 672 of the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant is installed in the reactor facility (811b) which comprises a plurality of generators for nuclear waste disposal and power generation and constitutes a connection shaft reactor facility, and is configured to operate the nuclear power plant with a nuclear power plant;
A plurality of power generating and manufacturing units 811b of the nuclear power generation facility 811 of the nuclear power plant 671 of the offshore and offshore marine power plants and the nuclear power plant main body 1 of the nuclear power plant, (593,594,595) of the marine power plant. The marine seisio hydropower plant (943), which is a substitute for the power generation and power generation, is prepared for the repair of the nuclear power plant equipment. A large hydropower generator (944) as a connection structure, which constitutes a plurality of power plant nuclear power plants,
The distribution input apparatus constituting the operation of the nuclear power plant 944 of the large hydroelectric generator 943 of the marine seesaw hydropower plant 94 provided for the power generation and power generation in preparation for the retrofit of the nuclear power plant facility of the distribution and dispensing apparatus, The large hydrostatic generator body of the marine seesaw hydroelectric power plant 943 is connected to a head tank 189 for a pressure tank located at the upper end of the barge line and an inlet of cooling water for the inlet pipe 191 in front of the head tank 189, 35) An introduction pipe 191 having a water pressure pipe shape is connected to the head tank 189 and has a plurality of introduction pipes 191 at the upper end of the marine sheath hydroelectric power plant 943 and the discharge port at the rear of the head tank 189 The pump aberration 943a of the turbine 267 and the Pelton aberration 943b of the turbine 267 to the lower portion of the body of each large hydrostatic generator Seisoh hydroelectric power plant 944 that provide a position in the interior of the marine seesaw hydroelectric power plant 943, 943c ) And the discharge port (270) at the rear of the water supply port (269), and at the same time, the hydro-electric power generation distribution input device in the ocean is equipped with the flow velocity of the current, The inlet pipe 191 in the form of a hydraulic pipe riser 35, which provides a flow rate conversion with mechanical energy, is vertically rotated by a large hydrostatic generator shear facility 944 having a sheath center shaft frame 673 that provides mechanical energy conversion (593,594,595) nuclear power plant (672) of a marine power plant and a nuclear power plant (672) of a marine power plant having a seesaw crane boom stand (942) of a tower crane that performs an operation, A large hydropower generator distribution and charging device is provided inside the reactor facility body 1 of the nuclear reactor facility 1 to further operate nuclear power plants;
The large hydraulic power generator seesaw facility 944 that constitutes further operation of the nuclear reactor of the nuclear reactor is provided with a rotational speed detector 944a for a hydraulic power generator for providing a position at the top of the center of the rotational shaft 944q, An exciter 944b for DC generator which supplies current to the motor field coil of the alternator providing a position at the lower end of the rotational speed detector 944a for use, a drag ring pipe 944c for pushing the ring pilot feather, A stator frame 944g and a center stator 944h and a rotary bearing 944i and a braking device 944j of a low speed cooler and a braking device 944j for braking The jack 944k of the apparatus and the low-speed rotary shaft 944l are positioned at the upper end of the central portion of the rotary shaft 944q while the large hydrostatic generator seesaw facility 944 is connected to the rotary shaft 944q, turbine( The power generation assembly is provided with the turbine rotation bearing 944n, the casing 944o, the guide vane and the impeller 944q and the flow velocity of the current to the inside of the hydroelectric power generating room, The large hydrostatic generator seesaw facility 944 provides a mechanical energy conversion to the inlet pipe 191 having the shape of the hydraulic pipe of the hydraulic pressure reducer 35 and the center shaft frame 673 of the sheathing equipment 944 A large hydroelectric generator seiside facility 944 having a multi-stage entrainment type manomoon form, and a seesaw crane boom zone 942 of a tower crane for performing a vertical rotation operation, thereby further providing devices for generating electrical energy, (593,594,595) of a marine power plant with a connection structure of the power generation facility to produce a large hydropower distributor / dispenser installed inside the nuclear power plant facility to make the nuclear power plant more operational And;
The power generation and production unit 811b of the nuclear power generation facility 811 constituted by the nuclear power plant 672 of the marine power plant of the land and sea and the nuclear power plant main body 1 of the nuclear power plant, The dust collector is provided with a plurality of generators for nuclear waste disposal and power generation of the nuclear reactor facility and transformers for transmitting the power between the electric power production and manufacture section 811b and the nuclear power generation facility section 811 constituting the nuclear power plant operation of the connection axis reactor facility The distribution input device of the power transmission portion 811d,
The power generation and production section 811b and the power distribution section 811d of the large hydroelectric generator seeside facility 944 constituting the nuclear reactor operation of the nuclear reactor further comprise a reactor installation main body 1 of the nuclear power plant, Deck deck reactor installation of marine nuclear power plant as an internal connection structure When the double structure block tank collector (794) is operated, the power generation capacity is increased to 1,000,000 w / h at intervals of 10 km, and a large hydropower distributor input device is provided The distributing and inputting device of the electric power producing and producing section 811b is a connection structure provided in each of the marine power generating stations with a large hydroelectric generator seesirator 944 and an environmentally friendly wind power generator windmill 957a, The transformer 96 of the power transmission line 775 is connected to the power transmission line 775 and the power transmission tower 776 is provided with a predetermined amount of power generation power, The generators provided in the water are designed to provide a certain amount of water to the connection process of the large flange 614 of the nuclear waste treatment double structure block tank bridge 929, which is located at the lower end of the nuclear power plant facility of the floating plant (593,594,595) It is also possible to equip the generator with the supply of power generation equipment as the connection structure of the distributing and inputting device, to simultaneously perform the bolting work process with the hammer and the wrench of the hand tool, or to control the generator power of the nuclear power plant, (593,594,595) nuclear power plant (672) of a marine power plant, each of which provides coupling of a chain block (648) and a turnbuckle (850) The submarine line injection nozzle to the structure is connected to the injection nozzle of the nozzle connection and the submarine line wiring (946), and the double structure block tank bridge bridge (929) The entrances may further include devices for generating electrical energy by having a seesaw crane boom 942 of a tower crane that provides for a vertical rotation operation to a large hydroelectric generator seesiter 944 having a multi- (593,594,595) of marine power plants with a connection structure of power generation facilities that generate power for the nuclear power plants.
The power generation and production section 811b of the nuclear power generation facility section 811 constituted by the nuclear power plant 672 of the marine power plant of the land and ocean and the nuclear power plant 671 of the nuclear power plant, A connecting shaft provided with a plurality of generators for processing and generating nuclear waste in a nuclear reactor facility;
The distribution input device of the power generation and production section 811b constituting the operation of the nuclear reactor of the nuclear reactor is a connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant, The dispensing device comprises:
A reactor building is provided with a vertical partition wall 605, a horizontal partition wall 609, a partition wall manhole 610, a manhole cover 152 and a hatch cover 153 in the double structure block tank of the nuclear reactor facility, The hydraulic cylinder door 624 is provided as a connecting structure in the double structure block tank 598 and the distribution block connecting structure lever block 123 and the chain block 648 and the turnbuckles 850 are provided in the double structure block tank 598 (593,594,595) of the marine power plant, the height of the nuclear waste treatment double structure block tank bridge (929) is calculated as the height of the pipe bridge (593,594,595) in nuclear power plant (593,594,595) Nuclear power plant (672) inside the reactor main body (1) of the nuclear power plant which provides the double structure block tanks to be combined with each other by 1.5 times the width of the nuclear power plant (929) chapter The connecting shaft of the nuclear waste disposal facilities distributed input device and the reactor nuclear waste disposal tube manufacturing process 705 of the nuclear reactor plant in the nuclear power plant when seolbibu 811 reactor facility after the safety operation of the former;
As a connection structure capable of being disassembled and coupled in a marine vessel manufacturing factory of a power transmitting portion 811d provided with power generating and manufacturing portion 811b of the nuclear power generation facility 811 and power transforming devices for transmitting power, Nuclear power plant nuclear power plant facilities nuclear power plant nuclear power plant facilities nuclear power plant nuclear power plant nuclear power plant nuclear power plant facilities The method according to claim 1,
(593,594,595) Nuclear power plant (672) and nuclear reactor plant main body (1) Nuclear power generation facility (811) Electronic control regulator Construction machine control section (811f) Disaster prevention device and lifting device A distributing and inputting device for a connecting shaft disaster prevention control device constituting a distributing and inputting device for a production facility device in a block steel tower,
(593, 594, 595) of a marine power plant as a connection shaft connection structure of a nuclear power plant, and a dis- tribution input device for a disaster prevention device, a lifting device, and a production facility device, (593,594,595) Nuclear power plant and Nuclear Power Plant Reactor facilities inside the main body (1) Submarine line injection nozzle connection Submarine railway line (946) and upper part of the sea surface (SDU The upper end of the holding tank upper barge hull 591 has a processing hole 615 for providing the connection of the equilateral hexagons 839 to the center upper end SDU of the upper deck deck, 25 and washer 26 provide connection of equilateral inclined ramps 839 with spanner hand tools, but the connecting shaft of the nuclear power plant equipment is connected to a seesaw crane The block unit block steel towers 116 provided with the respective connection structures by inserting the blocks 942 are inserted into the lug processing holes 20 of the block unit block steel towers 116 to be engaged with the shackles 23 of the position adjusting and moving device At the same time, the nuclear power plant equipment is provided with a block unit block steel tower 116 by assembling transportation to a seesaw crane boom block 942 of a tower crane, An emergency staircase 631 is provided in the emergency stairway 116 and an emergency stairway 631 is provided as a traffic device and an emergency stairway 631 provided at the stair of the block pylon 116 is connected to the lower steam airliner 589) to the location of the bollard 638 of the mooring platform and to the center of the lower end of the lower part of the steam jet ship 589 to the position of the ceiling crane 651 and the elevator allybeat 632, And the holding tank top As the positions of four deck decks of the ground hull 591, there are provided a block unit boom with a connection structure of 500m units, and a plurality of seesaw crane boom units 942 of the crane provided at the bottom of the sea, (593,594,595) Nuclear power plants Nuclear power plants Nuclear power plant facilities with connection structure (2) Nuclear waste treatment facilities to provide submarine line wiring (946) Double structure block tank bridge (929 ) Combined Dispenser Input Unit The block unit block of the equipment provided as a connection structure to protect the mooring operation by the connecting structure is equipped with the emergency stairway (631) (593,594,595) Nuclear power plants Nuclear waste treatment facilities (1) Nuclear waste treatment Double structure Block tank pipe bridge (929) Coupling distribution Injection device Connecting shaft connection structure Floating stand (811) Electronic control equipment construction machinery control unit (811f) Dispensing equipment for disaster control equipment, lifting equipment and production facility equipment Dispensing equipment for disaster control equipment consisting of a block tower To constitute the facilities of nuclear power plants;
(593,594,595) of the above-mentioned marine power plant (593,594,595) Nuclear power generation unit constituting a block steel tower as a connecting shaft connection structure of a nuclear power plant facility (811) Electronic control adjusting apparatus construction machine control unit (811f)
The nuclear power plant 811 constituting the connecting shaft connection structure of the nuclear power plant equipment for providing the disaster prevention water supply to the top end upper block block tower 116 at the upper end of the mooring tower 644, The distributing and inputting device for the control device is a high pressure type multi-stage disaster prevention pump (8) for providing a nuclear power plant disaster prevention control device as a connecting structure at the upper end of the deck deck of the holding tank upper barge hull (591) When the main switch button 66 for the start switch button of the main switch button 8 of the main switch button 8 is manually depressed to the on-time main switch button 66, The multistage multi-stage disaster prevention pump 8 is connected to the double structure disaster prevention hose 9 and the disaster prevention water 7 by a connection structure structure Providing the fire emergency disaster prevention can double structure tube nozzle 10 is 7, and release, or connecting shaft of the nuclear power plant equipment; and
Electronic control device The dispensing device for the disaster control device of the construction machine control part (811f) is composed of a fire prevention disposal double structure nozzle (10) for mounting transportation equipment and a fire prevention disaster double structure Connection between pipe nozzle and water pipe connection Fixed fire fighting emergency pipe with double structure pipe Connection line of nozzle (10) Wire rope (19) and connection device Shackle (23) A connection line wire rope 19 for protecting the disaster prevention duplex pipe nozzle 10 from the lower end of the basket 42 on which the pile at the bottom of the lower end of the airship 78 and the radio sonde 134 is mounted, A disaster prevention device is provided with connection structures of connection shafts connected to the inside of the double structure disaster hose (9), and a disassembly device for disaster prevention control devices of the connection axis electronic control adjustment device construction machine control part (811f) of the nuclear power plant equipment The device production facilities are provided with a high performance submersible pump 36 and an air compressor 80 to provide a combination of a disaster control device with a top connection structure of a floating deck deck, Dispensing device for disaster control device of control unit 811f The production facility equipment is a connection structure having a connection structure of submarine line wiring 946 into the reactor main body 1 of a nuclear power plant, Block tank pipe bridge (929) Coupling distribution input device The connection block for the flood control device provided by the flood control device or the plant equipment for protection of floodproofing disaster prevention device. (593,594,595) nuclear power plant of the marine power plant and the nuclear reactor main body (1) of the nuclear power plant as the connection structure of the line distributing and inputting device, (929) Nuclear power plant (811) Electronic control equipment Construction machinery control unit (811f) Disaster prevention equipment and lifting equipment provided with connection structure to be protected by disaster prevention device and production facility equipment A distributing input device for a connection shaft disaster control device constituting a distribution input device for a production facility device in a block tower;
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plants and nuclear reactors of nuclear power plants (1) Nuclear power generation facilities (811) Electronic control devices Construction machinery control parts (811f) Discharging devices and lifting devices and production facilities Distribution of equipment The disaster control distribution dispensing apparatus of the connecting shaft constituting the apparatus in the block steel tower,
The disaster control pump control system and the control system 150 constituted by the connection structure of the nuclear power plant facilities and the electronic control distribution dispatching apparatus of the fire fighting disaster prevention machine room are equipped with the internal control system of the nuclear plant of the marine power plant (593,594,595) Submarine line injection Nozzle connection Submarine line wiring (946) Dependent sounding deck which provides position by connection structure Disaster prevention pump on top of deck High-pressure multi-stage emergency protection pump (8) The multi-stage pump control panel control box (2) has a fire prevention electronic control device for controlling the electronic control facility of the nuclear power plant equipment. The control box (2) (3), discharge joint piping (4), pump internal isolation valve high-pressure shut-off valve (5) and pump internal check-back check valve (6) And a fixing frame 11 for fixing the position of the fire suppression pipe nozzle 10 and the multi-stage multi-stage fire prevention pump 8, (12) for the electronic control device for detecting a fire, and a fire-control emergency electronic control device for the nuclear power plant, the electronic control device connection structure of the nuclear power plant includes a control box A power supply unit 62, an inverter 47 for an electronic control unit, an inverter VCO 48, an access pointer 49 and an internet network 50 A rechargeable battery 37 having a connection structure with a short range wireless communication antenna 54 and a wireless communication control module 55 of a short range wireless communication device is provided inside the monitor 52 and the control board 53 of the internal control server 51, The mobile terminal 81 and the portable terminal 82 are connected to each other by a connection structure, The fire fighting and disinfecting electronic control devices of the nuclear power plant equipment are connected to the display 56 and the electronic control unit ADIC 57 and the electronic control unit MCU 59 of the switch input circuit 58 A main switch button 66 for a start switch button and an auxiliary switch button 66 for providing a position to the electronic circuit connection structure between the DAC 60 and the analog input 64 of the display screen 63 and the digital input 65, 67, a display input computer network input 68 and a recognition name plate 69 of a pressure setting value which is a set pressure value of the current pressure value, a memory 70 and a connection structure of the power supply power supply line 71 The power source 46 of the fire-fighting electronic control unit of the nuclear power plant equipment is provided with the power source 46 to the electronic control units of the fire-fighting disaster machine room, and the flood control unit 593, 594, 595 of the marine power plant, nuclear power Nuclear power plant and nuclear power plant Nuclear power plant Nuclear waste treatment facility to connect inside structure (1) Subsea line wiring (946) Connected structure Nuclear waste treatment Double structural block Tank pipe bridge (929) Coupling distribution input device Equipment to be provided as a connection structure to protect production equipment and electronic control unit of fire fighting and disaster prevention machine room of nuclear power plant equipment. Electronic control device connection structure Maintenance of ocean power plant (593,594,595) Nuclear power plant (1) of a nuclear power plant and an electronic control device line distribution and input devices of a fire fighting and disaster prevention operation room, a nuclear power generation facility (811), an electronic control adjusting device construction machine control device (811f), a disaster prevention device and a lifting device Disassembly and dispensing equipment for production facility equipment is connected to a block tower. Disassembly control Dispensation dispensing equipment Nuclear power station reactor facilities To constitute the operation of nuclear power plants;
The fire fighting and disinfecting control distribution dispensing apparatus composed of the connecting shaft connection structure of the nuclear power generation facility 811 of the reactor facility main body of the nuclear power plant, the electronic control regulating apparatus construction machine control unit 811f,
The fire fighting and disinfection control distribution dispensing apparatus is a connection structure inside the reactor main body 1 of a nuclear power plant of a marine power plant (593,594,595) of a marine power plant, and is connected to a piping 89 having an electronic control device of a fire fighting disaster prevention operation room, The connection structure of the piping 89 is connected to the safety valve 258 of the piping 89 by the safety valve 258, the low pressure shut-off valve 83 for the electronic control unit, the emergency valve 84 and the relief valve 85 of the reducing valve 85 And the rubber packing 32 of the gasket for piping connection and connection is connected to the bolt 24, the nut 25 and the washer 26 at the gap 15, The first pressure check sensor 86, the second pressure check sensor 87, the electronic control unit 88 and the bypass pipe line 89 for piping connection of the collecting tank 34 are connected to each other A connecting structure having a connection structure with a dozer 35 and a tee elbow 44 of an elbow with piping connection is provided inside the piping 89, The main switch button 66 for the start switch button of the connection shaft multi-stage disaster prevention pump 8 of the electronic control regulating apparatus construction machine control section 811f and the disaster prevention water spraying (593,594,595) of a marine power plant, or a connection structure of a nuclear power plant having a submarine line wiring (946) as a connection structure inside the reactor main body (1) of a nuclear power plant. (929) Combined distribution injecting device Flotation control device and production facility Equipment to be equipped with a connection structure to protect devices Electronic control device of fire fighting and dismantling machine room (593, 594, 595) nuclear power plant of the marine power plant and the nuclear reactor facility main body (1) of the nuclear power plant as connection structures of the line distribution input apparatus, (811) Electronically controlled regulator (811f) Discharging device and lifting device for lifting device and production facility device Connection shaft for constructing block steel tower Distribution input device Configured to operate the reactor plant of the nuclear power plant;
(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution input device for the production facility apparatus (593,594,595) Fire fighting and disaster control device The distribution dispatching device of the operation of the nuclear power plant facilities,
The distribution dispenser for operating the nuclear power plant equipment is provided with a detour line 35 for connection of piping connection of the connection structure water collecting tank 34 having a connection structure to the forefront of the multistage disaster prevention pump 8 of the fire- Piping connection There is connection structure with tee elbow (44) of attached elbow, but disaster prevention water (7) of fire prevention disaster prevention control goods is stored in piping (89) of connection structure of nuclear power plant facilities, The on-time main switch button 66 of the main switch button 66 for the start-up switch button of the emergency disaster prevention control article 7 of the multistage disaster prevention pump 8 of the control article and the high pressure multi- The operation of the pump can be provided by pushing it in by hand, or by pushing it manually at the position of the off-time main switch button 66 of the main switch button 66, High-pressure type multi-stage disaster prevention pump (8) (33) is a connection structure helicopter (647) having a connection structure with a high-performance submersible pump (36) for piping connection connection. The hooks for the electronic control device 13) and the connection structure of the nuclear power plant having the connection structure of the coupling is the disaster prevention water (7) having the internal water pressure of the double structure fire hose (9) Is pressed by hand at the position of the on-time main switch button 66 of the main switch button 66 for the start switch button of the high-pressure multi-stage emergency protection pump 8 before and after the operation of the high-pressure multi- (3) and a discharge joint pipe (4) for electronic control and an internal high-pressure shut-off valve (5) of an isolation valve pump are connected to the high-pressure-type multi-stage disaster prevention pump (8) Pump inside The disaster prevention water 7 having the water pressure inside the connection structure of the nuclear power plant equipment is supplied to the fire suppression double structure pipe nozzle 9 through the pipe And a nuclear waste treatment double structure block tank which provides a position having a submarine line wiring 946 as an internal connection structure of a fire fighting and disaster control apparatus facility as a connection shaft connection structure of a nuclear reactor facility main body 1 of a nuclear power plant Pipe bridge (929) Coupling dispenser Input device It is equipped with equipment to provide connection structure to protect the disaster prevention device and production facility equipment. It is equipped with electronic control device line dispensing input device of fire prevention disaster prevention machine room. (593,594,595) nuclear power plant and nuclear reactor plant main body (1) of a marine power plant with connection structure with water pressure, Electronic control equipment of machine room Electronic distribution system of line control equipment (811) Electronic control equipment of line control equipment (811f) Dispatching device for dismantling device and production equipment device Shaft Disaster Control Distribution Discharging Equipment Nuclear power plants are constructed to operate nuclear reactors;
(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution input device for the production facility apparatus (593,594,595) Fire fighting and disaster control device The distribution dispatching device of the operation of the nuclear power plant facilities,
The disaster prevention water supply apparatus 7 having the water pressure is moved through the piping to the position of the fire disaster prevention double structure pipe nozzle 10 so that the fire disaster prevention double structure pipe nozzle 10 The exhaust gas is discharged to the outside of the body of the fire-fighting disaster prevention double-structure pipe nozzle 10 in the processing clearance 15 for a plurality of position-adjusting and moving apparatuses for providing a position with the water- At the same time, the discharge jetting number 38 of the fire-fighting and disinfecting control article and the disaster prevention water 7 of the curtain water film 39 of the fire-fighting disaster control article are arranged at the positions of the plurality of processing holes 20, Discharge jetting is provided in the form of a radiation film discharge jet 38 (water film curtain 39) at the positions of the plurality of processing holes 20 and the clearance 15 of the plurality of processing holes 20. However, And the combustion effect is prevented by preventing the combustion and the combustion (593,594,595) nuclear power plant of the marine power plant and the nuclear reactor main body (1) of the nuclear power plant as the connecting structures having the water pressure of the connection structure of the nuclear power plant facilities, Electronic control equipment of disaster prevention machine room Nuclear power generation equipment with line distribution input devices (811) Electronic control equipment Dispatching device and lifting device of construction machine control part (811f) Dispatch control Dispenser Discharging device Nuclear power plant's nuclear reactor plant is constructed to operate as a nuclear power plant;
(593,594,595) of the connection shaft of the marine power plant constituting the disruption device of the construction machine control section (811f) and the distribution and input device of the production facility apparatus. (593,594,595) Fire fighting and disaster control device The operation and distribution dispatching device of the nuclear power plant facilities,
The distribution dispenser for operation of the nuclear power plant equipment is a fire extinguishing control fire extinguisher control device that allows early evolution to occur within 1 second. The discharge nozzles 38 are provided as connection structure disaster prevention water 7 of the curtain water film 39 of the firefighting and disaster control product. The discharge jetting water 38 is provided at the positions of the plurality of processing holes 20, At the position of the jetting number 38 and the gap 15 of the plurality of processing holes 20, the discharge jetting number 38 of the radiation type provides ejection falling jetting in the form of a water film curtain 39, The disaster prevention is fire prevention by the smokestack action which surrounds the combustible with the incombustible gas and stops the supply of air to prevent the combustion and the cooling action to reduce the combustible to the ignition point temperature. By The fire prevention disaster prevention water of the nuclear power plant equipping the fire hose body with the connection structure is mixed with the fire prevention disaster control water cooling water 287 and the air hose 109 for storing the non-combustible gas 164 having the water pressure, The portable wireless communication terminal 82 of the high pressure multi-stage multi-stage disaster prevention pump control system 150 in the disaster prevention pump operation machine room and the safety control room and the disaster prevention pump control system 150 in the safety control room are provided as a connection structure for providing the mixed disaster prevention water, A main switch button 66 for operation control and a connection structure for providing a disaster-free water spraying reactor;
Dispensing Pump Auxiliary switch button (67) The power supply control box is distributed to the safety control room and the disaster control pump operating machinery room. The coupling connection pipe (29) for piping connection is connected to the coupling body It is equipped with threaded body (31) connection structure, dual fire extinguisher (40) and helicopter (647) are equipped with mixed fire water and loess soil (158) (593,594,595) of a marine power plant by arranging a structural coupling to provide a connection structure having a disconnection nozzle 945 by an underground line into the reactor main body 1 of a nuclear power plant and a submarine line wiring 946 as a connection structure Nuclear waste treatment Double structure Block tank bridge (929) Equipments to provide connection structure to protect production equipment equipment by equipped with joint distribution dispenser and flood control system The emergency stairs 631 of the traffic device of the block unit block steel tower 116 may be provided as a line distribution input device and the line distribution and input device connecting structures may be connected to the inside of the reactor facility main body 1 of the nuclear power plant, (593,594,595) of the marine power station, the mooring device, the diving buoyancy control device, the distribution and input device of the nuclear waste disposal, and the nuclear reactor facility safety operation of the nuclear reactor facility (811 ) Nuclear waste treatment plant manufacturing process at nuclear facility (705) Connection of nuclear reactor plant at nuclear power plant Disconnection device, lifting device and production facility of shaft construction machine control section (811f) Connection shaft constituting distribution dispensing device Flood of marine power plant (593,594,595) Nuclear power plants Nuclear reactors Main unit (1) Connection shaft connection structure Fire fighting and disaster control equipment Nuclear power plant Facilities for operation and distribution of equipment for marine ship (593, 594, 595) nuclear power plant (672) of a marine power plant and a nuclear reactor facility main body (1) of a nuclear power plant as nuclear power generation facilities (811 (FBR) 838 constituting a dual structure block tank precipitator 794 having a nuclear reactor waste disposal unit 811a and a nuclear reactor waste reactor treatment unit 811a,
The FBR 838 of the nuclear power plant 811a is connected to the nuclear reactor waste reactor 811a of the nuclear power plant 811 to construct a dual structural block tank collector 794 for nuclear waste treatment. A nuclear waste disposal and dispensing apparatus having a double structure block tank precipitator 794 in the form of a nuclear radiation leakage control source statistic in a nuclear reactor power plant 672 and a nuclear reactor main body 1 of a nuclear power plant, Explosion control dispensing device In order to install a large number of reactor facilities in the marine anti-sunken double structure block tanks and floodgates, and to prevent the earthquake and tsunami from being affected by weather conditions, ) Of the submerged barge line equipped with the installation position of the dispensing device. The nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility section 811 which prevents the plurality of nuclear power generation reactors from exploding into the nuclear power plant 672 of the apparatus and the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant, (FBR, 838) constituting the nuclear radiation leak control dual structure block tank dust collector (794) provided on the connection axis,
The fast breeder reactor facility (FBR) 838 constituting the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the ocean power plant and the reactor facility body (FBR) 838 constructed in the double structure block tank precipitator 794 of the nuclear power generation facility unit 811 inside the fuel rod 689 at the central portion of the fuel rod 689 to about 20% of the enriched uranium 235 (812) The enriched enriched uranium 812 and the natural uranium 812 and the plutonium 812 are mixed and the fuel rod 689 is surrounded by natural uranium 812 at the same time, The liquid metal sodium is used for the coolant 816 and the plutonium 801 is provided for the purpose of preparing the plutonium 801 for entering or leaving the uranium 238 653a to the plutonium 801, At the same time, It is not necessary to reduce the neutron 675 to the reactor FBR 838 so that the moderator 676 is not contained and the heat generated in the reactor installation in the intermediate heat exchanger 657 is transferred to the intermediate heat exchanger 657 At the same time, the heat exchanger 658 transforms the water 654 into steam 780 as heat of the liquid sodium to form a nuclear power plant while the steam turbine 267 provides rotation, A dual structural block tank dust collector 794 in the form of raw statistics for the treatment of nuclear waste on the connection axis of the nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility 811 inside the nuclear power plant main body 1 of the floating planted nuclear power plant of the power plant (FBR, 838) connecting shaft which constitutes a high-speed reactor,
The double structure block piping line (74) for establishing the position of the fast breeder reactor facility (FBR, 838) inside the double structure block tank dust collector (794) of the connecting shaft of the nuclear power generation nuclear waste processing unit (811a) The temperature sensor of the safety valve of the safety valve detects the temperature of the inside of the nuclear reactor in the range of 700 to 800 degrees Celsius When the dangerous state of the pressure sensor 813 is reached, the temperature and pressure sensors provide an alarm message to the computer in the safety control room, and at the same time, As the block piping line 74a passes through the explosive nuclear waste and nuclear waste is stored in each of the double structure block tank dust collector 794, (813) a temperature pressure sensing sensor safety valve (472) connected to the bottom internal double structure block tank provides an opening, while at the same time an outer block piping line (74b) is provided with a fuel explosion- A thermocouple thermometer sensor switch 103 having a connection structure with an automatic charging device flashing warning lamp 99, a pressure gauge 101 and a temperature sensing sensor bimetal 102 and a level pressure switch 104 for flow rate check operation, And a safety valve 472 of a pipeline automatic pneumatic valve conveying device 916. At the same time, a connection structure is provided at the upper end of the reactor building 688 at a predetermined angle of 45 degrees Holes are formed by a laser cutting machine and a construction machine drilling machine. At the same time, a double pipe structure piping line 74 is formed in a plurality of through holes, while a plurality of block piping lines 74 The front valve 472 is provided with flange connection connections by means of bolts 24 and nuts 25 and gaskets 32 and at the same time providing a connection to the reactor building 688 along the outer wall surface of the reactor building 688 (794) One piece of equipment includes a nuclear waste disposal dispenser and nuclear fuel (683) explosion control unit which is combined with an external block tank (599) for nuclear waste disposal and storage and a radiation type connection structure. The reactor is installed in the reactor core inside the reactor core (681) and outside the reactor core (681). Prevention of nuclear fuel explosion immediately before the reactor explosion. Connected to the nuclear reactor main body (1) (683) explosion-proof control appliances which are provided as a structure and at the same time contain explosion-proof control appliances for nuclear reactor power plant nuclear reactor main body (1) And dual structure block tank dust collector (794) for the control of the nuclear radiation leakage of the nuclear reactor facility, but also to prevent explosion of nuclear fuel in the reactor main body (1) of the floating nuclear power plant of the marine power plant at the same time Block tank Dust collector (794) The nuclear reactor facility is equipped with a fast breeder reactor facility (FBR, 838) to construct the nuclear power plant, and a mooring device and diving buoyancy control Equipment and Nuclear Waste Treatment Dispensers and Reactor Facilities Nuclear Reactor Facilities Safety Operation Fusi Nuclear Power Plant Division (811) Dual Structure Block Tank Collector with Nuclear Radiation Leakage Control of Nuclear Reactor Facilities (794) The nuclear power generation nuclear waste treatment unit 811a of the power generation facility unit 811, the connection shaft for supplying the fast breeder reactor facility (FBR, 838), the marine vessel (593,594,595) nuclear power plant (672) of the marine power plant and nuclear power plant nuclear waste treatment section (811) of the nuclear power plant (811) inside the nuclear power plant main body (1) of the nuclear power plant. 811a) The fast breeder reactor facility (FBR, 838) constituting the double structure block tank collector 794 in the form of a raw statistic for nuclear waste disposal as a connection axis,
The FBR 838 of the nuclear power plant 811a is connected to the nuclear reactor waste reactor 811a of the nuclear power plant 811 to construct a dual structural block tank collector 794 for nuclear waste treatment. A nuclear waste disposal and dispensing apparatus having a double structure block tank precipitator 794 in the form of a nuclear radiation leakage control source statistic in a nuclear reactor power plant 672 and a nuclear reactor main body 1 of a nuclear power plant, Explosion control dispensing device In order to install a large number of reactor facilities in the marine anti-sunken double structure block tanks and floodgates, and to prevent the earthquake and tsunami from being affected by weather conditions, ) Of the submerged barge line equipped with the installation position of the dispensing device. The nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility section 811 which prevents the plurality of nuclear power generation reactors from exploding into the nuclear power plant 672 of the apparatus and the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant, (FBR, 838) constituting the nuclear radiation leak control dual structure block tank dust collector (794) provided on the connection axis,
The fast breeder reactor facility (FBR) 838 constituting the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the ocean power plant and the reactor facility body (FBR) 838 constructed in the double structure block tank precipitator 794 of the nuclear power generation facility unit 811 inside the fuel rod 689 at the central portion of the fuel rod 689 to about 20% of the enriched uranium 235 (812) The enriched enriched uranium 812 and the natural uranium 812 and the plutonium 812 are mixed and the fuel rod 689 is surrounded by natural uranium 812 at the same time, The liquid metal sodium is used for the coolant 816 and the plutonium 801 is provided for the purpose of preparing the plutonium 801 for entering or leaving the uranium 238 653a to the plutonium 801, At the same time, It is not necessary to reduce the neutron 675 to the reactor FBR 838 so that the moderator 676 is not contained and the heat generated in the reactor installation in the intermediate heat exchanger 657 is transferred to the intermediate heat exchanger 657 At the same time, the heat exchanger 658 transforms the water 654 into steam 780 as heat of the liquid sodium to form a nuclear power plant while the steam turbine 267 provides rotation, A dual structural block tank dust collector 794 in the form of raw statistics for the treatment of nuclear waste on the connection axis of the nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility 811 inside the nuclear power plant main body 1 of the floating planted nuclear power plant of the power plant (FBR, 838) connecting shaft which constitutes a high-speed reactor,
The double structure block piping line (74) for establishing the position of the fast breeder reactor facility (FBR, 838) inside the double structure block tank dust collector (794) of the connecting shaft of the nuclear power generation nuclear waste processing unit (811a) The temperature sensor of the safety valve of the safety valve detects the temperature of the inside of the nuclear reactor in the range of 700 to 800 degrees Celsius When the dangerous state of the pressure sensor 813 is reached, the temperature and pressure sensors provide an alarm message to the computer in the safety control room, and at the same time, As the block piping line 74a passes through the explosive nuclear waste and nuclear waste is stored in each of the double structure block tank dust collector 794, (813) a temperature pressure sensing sensor safety valve (472) connected to the bottom internal double structure block tank provides an opening, while at the same time an outer block piping line (74b) is provided with a fuel explosion- A thermocouple thermometer sensor switch 103 having a connection structure with an automatic charging device flashing warning lamp 99, a pressure gauge 101 and a temperature sensing sensor bimetal 102 and a level pressure switch 104 for flow rate check operation, And a safety valve 472 of a pipeline automatic pneumatic valve conveying device 916. At the same time, a connection structure is provided at the upper end of the reactor building 688 at a predetermined angle of 45 degrees Holes are formed by a laser cutting machine and a construction machine drilling machine. At the same time, a double pipe structure piping line 74 is formed in a plurality of through holes, while a plurality of block piping lines 74 The front valve 472 is provided with flange connection connections by means of bolts 24 and nuts 25 and gaskets 32 and at the same time providing a connection to the reactor building 688 along the outer wall surface of the reactor building 688 (794) One piece of equipment includes a nuclear waste disposal dispenser and nuclear fuel (683) explosion control unit which is combined with an external block tank (599) for nuclear waste disposal and storage and a radiation type connection structure. The reactor is installed in the reactor core inside the reactor core (681) and outside the reactor core (681). Prevention of nuclear fuel explosion immediately before the reactor explosion. Connected to the nuclear reactor main body (1) (683) explosion-proof control appliances which are provided as a structure and at the same time contain explosion-proof control appliances for nuclear reactor power plant nuclear reactor main body (1) And dual structure block tank dust collector (794) for the control of the nuclear radiation leakage of the nuclear reactor facility, but also to prevent explosion of nuclear fuel in the reactor main body (1) of the floating nuclear power plant of the marine power plant at the same time Block tank Dust collector (794) The nuclear reactor facility is equipped with a fast breeder reactor facility (FBR, 838) to construct the nuclear power plant, and a mooring device and diving buoyancy control Equipment and Nuclear Waste Treatment Dispensers and Reactor Facilities Nuclear Reactor Facilities Safety Operation Fusi Nuclear Power Plant Division (811) Dual Structure Block Tank Collector with Nuclear Radiation Leakage Control of Nuclear Reactor Facilities (794) A connection shaft for supplying a nuclear reactor nuclear waste treatment unit 811a of a power generation facility unit 811 and a reactor reactor facility (FBR, 838) for a fast breeder reactor;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant unit 811 of the nuclear power plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant of the above- The nuclear waste disposal and dispensing apparatus for operation of the nuclear power plant equipment constituting the connection shaft position of the nuclear waste disposal pipe manufacturing process 705 of the reactor facility,
The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure of a nuclear power plant, and it is provided as a nuclear waste disposal unit (811a) of a nuclear power plant for distribution and installation of facility protection facilities. The reactor installation main body 1 of the floating installation type nuclear power plant, which is located at the sea level upper end portion SLU of the sea surface SLL that provides the position with the connection structure submarine line wiring 946 to the inside of the facility main body 1, , A buoyant deck deck upper central connection structure, and a block-type bulkhead block tower (116) for positioning the inside of the reactor installation main body (1) of the buoyant nuclear power plant at the upper left corner of the upper deck deck center It has a safety control room that provides a position as a connection structure. However, many countries with nuclear weapons have nuclear power generation Nuclear Waste Dispensing and Discharging Device Consisting of Bovine Nuclear Reactor Facility The nuclear waste disposal and dispensing device equipped with the satellite launching platform and the space launch device for the nuclear waste disposal device equipped with the satellite and the space rocket, Preventing flood drought control Preventing the flood Prevention of floods Preventing the damage of volcanic ash before and after tsunami, forest fire, dust and volcanic eruption Preventive weather control to control flood forecasting Observing weather forecasting facility (958) A helicopter stop 619 is provided in the peripheral equipment of the block steel tower 116 of the nuclear waste disposal and dispensing apparatus to provide a position as a connection structure in the vicinity of the upper center of the deck deck, The satellite 962, the satellite launch pad 643, and the space rocket 961 of the space rocket 961, A nuclear power station is installed at the top of the deck deck in the vicinity of the satellite launching platform 643 and the space rocket launching platform 646 as a nuclear launching platform 643 and a space rocket launching platform 646, The connection structure inside the reactor main body (1) of the power plant is provided with a connection structure having a submarine line wiring (946). The upper part of the deck deck is provided with a natural loess (158) A connection structure provided at the top of a deck deck to prevent the harmful tidal microorganism 921 from breeding Natural sooty loess 158 of powdered soot mixed with the water for control of control of fire control is provided at the upper end of the floating deck deck In order to prevent the harmful tidal microorganisms (921) from propagating in the seabed, the undersea position is located in the inside of the yard basket (951) of the harmful rust- And the harmful tidal microorganisms 921 are stored in the harmful tidal sediment collector. The natural loess soil 158 is supplied to the inside of the greenhouse basket 951 and the harmful tidal microorganisms The natural loess soil 158 is supplied to the seabed at the bottom position of the bottom of the floating deck deck body 921. However, A winch 137 and a seesaw crane boom girder 942 and a wire rope 19 and a wire rope chain 915 of a tow crane replacement tower crane are connected to a drive wheel roller 135 for a position- While the natural loess soil 158 is fed to the seabed, the moving device tuna winch 137 and the seesaw crane boom table 942 of the tower crane substitute for crates are moved to perform the position adjustment movement while simultaneously controlling the air compressor 80 and the air In the hose 109, the net-shaped air hose 109 is filled with oxygen (593,594,595) of the marine power plant by providing a fire control control goods arrangement that protects the marine environment and protects the marine environment. The submarine line wiring (596,594,595) Nuclear plants (1) Nuclear plants (1) Nuclear plants (1) Nuclear plants (1) Nuclear plants (2) Nuclear plants The nuclear waste disposal unit 811a of the nuclear power generation facility unit 811 of the nuclear power generation facility unit 811 is connected to the connection shaft position of the nuclear waste disposal pipe manufacturing process 705 of the reactor facility The nuclear waste disposal for operation of the nuclear power plant equipment constituting the nuclear power plant is operated by the distribution and input devices;
The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant unit 811 of the nuclear power plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant of the above- Nuclear waste treatment plant of nuclear reactor waste treatment plant tank dust collector (705) Crude oil and natural gas crude oil drilling equipment crude oil drilling equipment (934) constituting the connection axis position of reactor manufacturing process (705) ,
The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure inside the nuclear reactor main body 1 of a nuclear power plant of a marine power plant (593,594,595) of a marine power plant. The upper end of the marine deck hull deck (SDU The crude oil drilling rig 934 for providing a position as a connection structure to the upper center portion is provided at a lower end of a ceiling crane 651 which is located at the upper end of the lower end inside the block steel tower 116 of the nuclear power plant facility, Drilling machine Rotary table lathe machine (908) Drilling machine for drilling machine of nuclear power plant equipment with a connection structure inside the machinery room, or a nuclear plant. Circular table with rotating body of the body. And the hydraulic cylinder actuating key 623 controls the movement of the plurality of actuating keys 623 in the opposite-to- The nuclear waste disposal and dispensing apparatus of the nuclear power plant equipment may be provided with a rotary table lathe machine 908 and a rotary table lathe machine 908. [ And a plurality of piping racks (853) are connected to the pipeline racks (854) at a central position by a connecting structure connected to the pipeline by a position movement control device. A plurality of pipe racks 854 arranged at the position of the crude oil borehole 936 provided at the location of the crude oil borehole 936. The crude oil borehole 936 equipped with the connection structure for positioning the crude oil at the crude oil pipe connection structure 917 ), The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is provided with a ceiling crane 65 1 and the pipe rope 854 for connecting the drill bar to the wire rope 19 are provided with a hydraulic rotary cylinder (not shown) for drilling the rotary drum of the rotary table lathe machine 908 of the drilling machine for crude oil at the drilling machine room 619) with a plurality of hydraulic cylinders 623 for drilling to provide a position as a connection structure in the opposite direction to the circular table table, or with a transfer arrangement to the top of the rotary table lathe machine 908 of the drilling machine, The operation of the input device is performed to terminate the excavation of the crude oil bore hole 936 and to simultaneously deliver the crude oil and natural gas discharged from the oil borehole 936 to both sides of the seesaw crane boom zone 942 of the tow- The seismic crane boom zone (942) of the tower crane replacing the above-mentioned crane was installed as a connection structure to provide a waste disposal site. (593,594,595) of the marine power plant by providing a lift to the top of deck deck. The distribution of crude oil and natural gas oil borehole that provides the connection structure with the submarine line wiring (964) The nuclear reactor power plant 811a of the nuclear power generation facility unit 811 of the nuclear power generation facility unit 811 may be provided with the double structure block tank collector 811a of the nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811, (705) of nuclear reactor waste treatment plant nuclear waste facility processing of nuclear power plant equipment constituting the connection axis position of nuclear reactor waste disposal apparatus,
The nuclear power generation nuclear waste treatment unit 811a of the nuclear power generation facility unit 811 of the nuclear power plant unit 811 of the nuclear power plant main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant of the above- (934) of crude oil and natural gas crude oil borehole facilities of nuclear power plants constituting the connection axis position of the nuclear waste processing pipe manufacturing process (705) of the reactor facility, and the deep sea water energy resource and mineral collection The nuclear waste disposal dispensing apparatus of the present invention,
The nuclear waste disposal and dispensing apparatus of the nuclear power plant facility is a connection structure inside the nuclear power plant main body 1 of a floating nuclear power plant of a marine power plant, and a subterranean mineral resource gathering place where a submarine line wiring 946 is provided (841) for collecting manganese nodules (909), and automatic pneumatic conveying device (916) for piping line for position-regulating movement device. The suction structure of the suction suction machine (911) and the minerals of the suction- The harvesting robot 912 and the mineral gathering trough 924 are provided with a connection structure for providing a position as a connection structure on both sides of the seesaw crane boom band 942 of the sea level lower end portion SLD replacement tower crane, Replacement tower crane Seisio Crane Boom (942) Deep-sea energy resource connection axis in vertical rotation operation; and
The nuclear waste disposal and dispensing apparatus of the nuclear power plant equipment is provided with a means for transferring the salvaged resources to a transmission structure (254) inside the reactor main body (1) of the floating nuclear power plant of a marine power plant Transport equipment supplying material to the industrial site on the land 500m block unit double structure block tank facility as a connection structure Lifting of a marine power plant having a connection structure for establishing a position as a connection structure Nuclear power plant reactor main body (1) Internal connection structure (946) with a submarine track wiring (946), which is a connection structure in which each of the equipment of the marine power generation facility is located at one side of the deck of the floating deck deck and one side of the deck of the floating deck deck And the collection of energy resources and distribution input device of the deep seabed mineral. The crude oil borehole distribution and dispensing apparatus connecting structures may be provided with a nuclear reactor main body 1 of a floating nuclear power plant or a nuclear power generation nuclear waste treatment unit 811a of a nuclear power generation facility unit 811 of a nuclear power generation facility unit 811 The dual-structure block tank dust collector is used as a nuclear waste disposal facility for the operation of a nuclear power plant that constitutes the connection axis position of the nuclear waste processing pipe manufacturing process (705) of the reactor facility. A distribution input device of a marine power generation facility having a connection axis position of a nuclear reactor main body 1 of a floating feeder nuclear power plant;
The nuclear waste disposal plant of the nuclear power plant, and the nuclear waste disposal plant of the nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The diving preparation ready operation control distribution dispensing apparatus constituting the connection axis position of the diving progress preparation control dispensing apparatus 705,
The distribution input device of the nuclear power generation facility 811 includes a holding tank upper barge hull 591 provided as a connection structure inside the reactor facility main body 1 of the floating power plant of the marine power plant, The hull safety equipment for distribution and input is provided as a connection structure having a connection structure submarine line wiring 946 to the holding tank lower barge hull 593 and the hull safety equipment is provided with a high strength bolt 603 and a high strength nut 604 are connected to the large block 614 through the hole 615 and the outer block tank 599 is connected to the double structure block tank holding tank 590 by a plurality of double structure block tank holding tanks 590, Large flange (615) to provide position for connection with both aft parts and stern parts. Rubber packing of gasket for connection of tank connection structure to gap (15) position. Strength flange 614 and the high strength bolts 603 and the high strength nuts 604 to the large flange 614 joining portion hole 615 of the connecting structure to adjust the position of the distributing and inputting device of the nuclear power generating facility portion 811 Hydraulic cylinder machine for equipment (619) and hydraulic equipment for transportation equipment (624) and hand tool hammer lancet connection structure with floating structure double structure of nuclear reactor plant nuclear reactor block tank pipe pier (928) and double structure block tank pipe Bridge (937) Disassembly coupling Hydraulic rotary cylinder machine (619) Double structure block tank with distribution dispenser (598) Connection structure Provide disassembly connection or horizontal double structure block tank (598) Connection structure Connection part At the same time, the tee elbow 44 is provided with a hydraulic rotary cylinder machine (619) for position adjustment as a connecting structure of disassembly coupling dispensing and feeding device, (SDU) of the hull deck hull deck (SDM) of the hull deck center (SDM) to the inside of the reactor installation main body (1) of the floating nuclear plant of the marine power plant, (SDL) Upper end of upper deck of ship (SDU) Holding tank Upper barge Ship hull (591) and holding tank Lower barge hull (592) Connecting structure Submarine line wiring (946) Facilities Separate towers Replacement towers Crane seesaw crane Boom area (942) Connected structure Mooring device and power generation facility Connection structure of marine power plant (593,594,595) Connected nuclear power plant equipment to distribution facility of nuclear power plant (811) ;
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input device of the nuclear power generation facility unit 811 is a connection structure inside the reactor facility main body 1 of a floating power plant nuclear power plant of a marine power plant and is connected to a holding tank of the upper end portion SDU of the hull deck of the hull deck center portion SDM, A double structure block tank 598 for providing a position to a position having a submarine line wiring 946 as a connecting structure between a top barge hull 591 and a holding tank bottom barge hull 592 of a floating lowered end portion SDL of a floating octopus hull deck Submarine mineral resource exploration equipment located outside the outer block tank (599) It is provided as a connection structure of a power generation facility device for distributing and inputting marine power generation power to a location of a plurality of deepwater exploration underwater lights (843) And the distribution input device of the nuclear power generation equipment section 811 simultaneously arranges the harmful tidal control and barges for mounting the disaster prevention device, A plurality of column block tanks 590 are provided with a plurality of column block tanks 590 for providing a position as an external connection structure for the column block tanks, (614) connecting connection joint part processing hole (615) and the long hole hole (616) and the pin connecting shaft connecting structure are connected by the hydraulic cylinder screw (623), and the double structure block tank hull disassembly The coupling device of the thread 603a of the bolt of the coupling lug connection shaft bolt 603 and the screw 604b of the lug connection shaft decomposition coupling nut 604 is coupled to the hammer lancet hydraulic rotary cylinder machine 619, The distribution of the nut coupled to the pin connection shaft thread 603a can be prevented by providing a pin coupling with the pin coupling shaft 615 or by a hand tool provided at one side of the pin joint, (593,594,595) of the marine power plant, and a connection structure inside the reactor main body (1) of the nuclear power plant, the center of the hull deck (SDM) SDU) and a floating sediment hull deck bottom part (SDL) Floating upholstery hull deck upper part (SDU) Holding tank top barge hull 591 and bottom tank bottom barge hull 592 Each crane boom connection structure Mooring device Connection with power generation facility Connection structure of floating power plant of marine power plant Nuclear power plant of nuclear power plant (1) Consists of facility of nuclear power generation facility (811);
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution and input device of the nuclear power generation facility 811 is connected to the interior of the nuclear reactor main body 1 of the floating nuclear power plant of the marine power plant by connecting the upper part SDU of the hull deck of the hull deck center (SDM) (SDL) Floating Upholstery Sub hull deck upper part (SU) Holding tank upper barge hull (591) and holding tank lower barge hull (592) Connecting structure for providing position to a position with submarine line wiring (946) The double structure block tank combined traveling lug (607) at the upper and lower barge hulls of the upper and lower strut block tanks is combined with the horizontal and vertical forms at the respective portions of the strut tank upper barge hull (591) and the strut tank lower barge hull (592) A double structure block tank provided with a connection structure; a portable lug (607) having a plurality of processing holes (615) and an elongated hole (616) in a body; a horizontal pin connection shaft hole (615) 61 5 and a long hole 616 are formed on the upper portion of the upper block barge hull 592 and a vertical structure of the upper end barge hull 591 and the lower barge hull 592 are provided, Detachment-engaging portable lug pin connecting shaft 606 bound to several processing holes 615 among a plurality of block tank hull disassembly-type portable lug pin connecting shafts 606 bound to the processing holes 615 A block tank hull disassembly portable lug pin connecting shaft 606 having a single block tank hull disassembly portable lug pin connecting shaft 606 and a single row double row hitch disassembling portable lug pin connecting shaft 606;
Nuclear waste treatment Double structural block tank (941) Fixed float line on the upper part of the traffic system (941) Barge hull (592) and diving position control device on the side of a horizontal stowage block tank with level balance on both sides A double structure block tank-attached portable lug (607) provided with a vertically-coupled structure while leveling the barge line hull (592) of the fixed lifting hood while simultaneously performing diving to the bottom of the boat with a buoyancy control weight (949) Block tanks Hull disassembly coupling Portion lug pin connection shaft (606) Block tank with coupling Hull disassembly coupling Portion lug pin The connection block shaft (606) allows the vertical tie-rod block tank to be installed in a vertical coupling structure, (592) of the holding tank upper end of the reactor installation main body (1) of the buoyant reprocessing nuclear power plant, (615) of the lug hinge socket (613) and the nuclear waste disposal dual structure block tank (601) which provide the position of the ridge hinge connection structure with the ridge hinge A socket 613 and a concave-and-convex connection structure are selectively provided on the upper surface of the deck plate 590 and a lug hinge socket 613 is provided on the upper surface of each of the deck decks, (593,594,595) of landing block tanks (593,594,595), which are located at the upper end of the marine tunnel traffic device (941), are connected to each other in a unit of volume to provide a fixed lifting pad (593,594,595) (SLU) Barge hull and SLD Nuclear power plant Nuclear waste treatment Nuclear waste treatment Double structure Block tank Tube bridge (929) (593,594,595), or a combination of several double structure block tanks (607) with a double structure block tank with a barge hull at the top of the holding tank and a bottom tank barge at the bottom of the holding tank. Portable lug pin connection shaft 606 Several column block tanks 590 joined to the processing hole 615 of the body and the lug pin connection shaft 606 are used to prevent flooding of floats and flood prevention of floats from the sea level, The facility is equipped with a protection structure, and at the same time, the harmful tidal control and barge lines for mounting the disaster prevention device are connected to the control unit. The reactor structure of the nuclear power plant is upgraded and the barge lines for disaster prevention equipment are connected to the barge lines. (1) of the reactor plant main body (1) of a floating power plant of a marine power plant, and an upper end portion of the sea surface having a submarine line wiring (946) SLU) Submarine docking hull Deck top (SDU) Offshore power plant with connection structure Separate towers Replacement towers Crane seesaw crane Boom bar (942) Connecting structure Mooring and power generation equipment Distributing input device Connecting structures (1) of the nuclear power plant of the power plant, (1) the nuclear power station of the nuclear power plant, (2) the mooring device and the diving buoyancy control device of the nuclear power station (593,594,595) (811) of the Fusi Nuclear Power Plant Operation Section (705) of the nuclear waste processing pipe manufacturing process of the nuclear reactor;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant. The nuclear power plant of the nuclear power plant at the bottom of the sea level surface (SLL) (938), which prevents the marine biogeochemistry and barnacles, which are located outside the body from connecting structures, to grow in the connection structure of the nuclear power plant, is treated as a nuclear waste treatment double structure block tank bridge at the bottom of the sea level (SLL) The subordinate structure block tank bridge pier 929 and the double structure block tank bridge pier 928 are installed outside the body at regular intervals and the distribution apparatus of the nuclear power generation facility 811 monitors the military equipment submarine (907) of the fish finder, while simultaneously establishing the detection of dynamics in the seabed, and at the same time, connecting the inside of the nuclear reactor main body (1) of the marine power plant to the floating nuclear power plant. (SDU) Marine power generation facility Alternative towers Replacement tower Cranes Seiso Crane Boom area (942) Connection structure Mooring device and power plant facility Connected structures Hull safety distribution Hull safety devices for operation and intercommunication satellites (962) Satellite weather forecast information collection machines (960) with connection structure are used to provide a connection structure inside the reactor main body (1) of a nuclear power plant (593,594,595) Marine power plant (593,594,595) Mooring device and diving buoyancy control device for nuclear power plant (672) and distribution facility of nuclear waste treatment and reactor installation of nuclear reactor facility Safety operation Before the operation of nuclear facility of nuclear power plant (811) The connection axis of the nuclear waste treatment pipe manufacturing process 705;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution dispenser of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the marine power plant and the nuclear reactor facility main body 1 of the nuclear power plant as a connection structure, , The distribution control unit 811 of the nuclear power plant 811 is provided at the top of the control tower radar 840 of the control room upper block pylon 116, which provides a position as a connection structure, And the lightning rod 500 are provided as a hull distributing and charging device for hull safety operation or the upper end of the sea surface (SLU) equipped with a connection structure submarine line wiring 946 is connected to the interior of the reactor installation body 1 of the nuclear power plant. (SDU) Offshore power plant Seagate replacement crane Seisio Crane Boom area (942) Connection structure Mooring device and power generation facility Distribution facility of hull safety operation Connection structure of nuclear power plant The nuclear reactor facility main body (1) is provided inside, and the mooring device and the diving buoyancy control device of the nuclear power plant (672) of the marine power plant floating support (593,594,595) The connection axis of the nuclear waste processing pipe manufacturing process 705 of the reactor facility at the former Huizhou nuclear power plant 811;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input device of the nuclear power generation facility unit 811 is connected to the inside of the nuclear power plant main body 1 of the nuclear power plant of the marine power plant and the floating nuclear power plant 672 of the marine power generation plant. The power generated by the plant is supplied to the distribution and input device of the nuclear power plant (811), and power control is provided by the connection structure of the transformer (96) of the large capacity substation. At the same time, (597) manufacturing plant of raw material high-strength stainless steel, and a manufacturing plant of steel beam (149) and steel section (839) for producing small-diameter piping and large diameter piping and large- (941) of the nuclear waste treatment dual structural block tank marine tunnel traffic equipment, while providing the power line supply performance, The double structure block tank pipe bridge (928) facility of the nuclear waste treatment dual structural block tank bridge bridge (929) has a standard of 5M diameter, Double structural block tank pipe pier (928) is provided as a connection structure with a diameter enlarged to 1M at 5M, or semi-diving operation line (637) with double structure block tank at the top of deck deck. A double structure block tank dust collector of a nuclear power plant (811) of a nuclear power plant of a floating power plant of a marine power plant as a connection structure for providing a connection of a large flange (614) A diving process ready controllable control dispensing device for the hull safety equipment constituting the connection axis position of the nuclear waste disposal pipe manufacturing process (705) of the facility, comprising the processing of the nuclear waste of the reactor facility;
The connection structure of the marine power plant's buoyant pilot nuclear power plant (672) and the inside of the nuclear reactor plant main body (1) of the nuclear power plant is the same as that of the double structure tank bridge bridge saddle formwork (617). (621) Shipbuilding line (634) Dock deck (624) Sinking ship (621) Sinking ship Sink prevention rescue line (634) The disaster prevention nozzle 945 to the inside of the reactor installation main body 1 of the nuclear reactor facility 1 is connected to the upper end of the sea surface (SLU) with the connection structure submarine line wiring 946. The upper part of the deck of the hull deck (SDU) The crane seesaw crane boom zone (942) is connected to the mooring unit and the power generation facility unit. The double structure block tank pipe bridge (928) is installed and installed. The connection to the structure receives power configuration of the reactor of the nuclear waste disposal plant small body (1) of the nuclear reactor plant support sikdok nuclear power of the marine power plant and be made;
The various types of jig 22 body crevice machining holes 20 are connected to the lifting feeder nuclear power plant 672 of the marine power plant and to the inside of the reactor facility main body 1 of the nuclear power plant, A plurality of gimp joint toolpieces 185 having a sharp end and a plurality of pointed ends are connected to the shank linkage. The grinding wheel 185 is provided with a number of jig 22 machining holes 20 and several The anchor replacement crank 846 and the bridge pillar foundation base 851 are provided on the side and lower sides of the saddle form body and are provided with several anchor replacement worm cranks 846 (1) the nuclear waste treatment of nuclear installations of the marine power plant;
The upper part of the sea surface (SLU) equipped with the submarine line wiring (964) as an internal connection structure between the floating power plant (672) of the marine power plant and the reactor main body (1) of the nuclear power plant. (942) connection structure connection axis of the tower crane of the tower crane replacing tower
(928) as a connection structure between the mooring device and the power generation facility device. The power supply provided by the offshore power plant of the floating wind turbine is provided, and the nuclear power of the nuclear reactor installation (593,594,595) Nuclear power plant (672) Mooring system, diving buoyancy control system, nuclear waste disposal dispenser and nuclear reactor facility (1) Before the safe operation of the nuclear reactor facility, the connection axis of the nuclear waste processing pipe manufacturing process (705) of the nuclear reactor facility in Fusi Nuclear Power Plant (811)
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a plurality of anchor replacement crankcocks 846 as a connection structure inside a reactor facility main body 1 of a nuclear power plant, (811) as a connecting structure of the Nuclear Power Plant (811) while providing floating seaweeds to the seabed. Hull safety distribution and hull safety equipment and construction equipment for towing deck decks. (842) and submarine mineral resources (844) for submarine mineral resource reclamation with connection structure to the boom hook hook (18) inside the boom frame body by distributing both sides with the crane boom zone (942) (909) were collected by the connection structure, and the manganese nodule (909) was moved to the upper part of the deck (SDU) (909) of the submarine mineral resource manganese nodule (909) of the reactor facility main body (1) of the floating power plant of the marine power plant is supplied to the marine power plant, Construction of the lifting device to the upper deck (SDU) position Seaweed crane boom barriers (942) of tower crane replacement towers constitute the nuclear waste treatment of the nuclear reactor plant main body (1);
The distribution input device for the operation of the submarine mineral collection and construction machinery as the connecting structure of the nuclear reactor facility main body 1 of the floating power plant of the marine power plant is as follows: Construction machinery equipment Seized crane boom of tower crane (942) And the pallet 844 for reclaiming the seabed mineral resources are disposed at the upper end of the sea surface (SLD) of the sea surface SLL and the upper end of the sea surface (SDL) SLU) to the top of the hull deck (SDU) of the floating crane, to adjust the position of the crane to the connection structure of the crane boom base (942) of the tower crane and to transport the manganese nuclide (909) The loading and unloading device for the operation of the seabed mineral collecting construction machine simultaneously provides the position control to the upper part of the floating deck hull deck (SDU) with the seesaw crane boom part (942) of the tower crane, The subsoil mineral resource collection site in the reactor main body (1) of the buoyant reprocessing nuclear power plant of the cattle is a connection structure for distributing and inputting the suction collecting machine (911) and the mineral extraction robot (912) of the mineral resource collecting equipment. It is a connection structure that receives the power generated by the floating oceanic power plant while arranging the resource collection and simultaneously controlling the position shift to the upper part of the floating deck hull deck (SDU) as a connection structure of the seesaw crane boom zone (942) (911) and minerals collecting robot (912) in the nuclear reactor plant main body (1) of the nuclear power plant. The submersible mineral collecting system is a distribution input apparatus for operating the mining equipment. Mineral collecting robots (912) and seaport crane boom units (942) of tower crane substitute construction equipment for construction of lifting equipment are constructed to collect submarine mineral resources;
The distribution input device for operating the seabed mineral collecting construction machine as a connection structure between the floating nuclear power plant 672 of the marine power plant and the reactor facility main body 1 of the nuclear power plant,
(SLU) with a submarine line wiring 946 as a submarine mineral resource collection connection structure to the inside of the reactor facility main body 1 of the nuclear power plant and the flood control sounding nuclear power plant 672 of the marine power plant, (SDU) Location Offshore power plant with location as a connection structure Lifting of marine power plant powered by individual mooring and power generation facilities Connection structure between nuclear power plant (672) and nuclear reactor plant main body (1) (593, 594, 595) to the seabed by the diving control device, and the seats are installed as the connecting structure. Also, the hull safety device for the safe distribution of the hull to the upper position of the deck deck of the floating deck, the hull safety device for the operation equipment, Nuclear Power Plant (672) and Nuclear Power Plant Nuclear Reactor (1) Lifting device of construction equipment (1) Construction machinery Replacement tower crane Seisio Crane Boom (942) The seismic crane boom zone (942) of the tow crane replacing the towing crane for the lifting device construction equipment while arranging the collection of the seabed mineral resources by the structure is provided with the position control to the upper part of the floating deck hull deck (SDU) As a connection structure that receives the power generated from the marine power plant, it is connected to a floating collection plant (672) of a marine power plant and a suction collection machine (911) and a mining robot (912) (911) and mineral extraction robots (912) and lifting equipment Construction machinery Forklift tower crane Seisio crane Boom bar (942) Submarine minerals Organize to collect resources;
The distribution input device for operating the seabed mineral collecting construction machine as a connection structure between the floating nuclear power plant 672 of the marine power plant and the reactor facility main body 1 of the nuclear power plant,
(672) of the offshore power plant and the nuclear plant main body (1) of the nuclear power plant are connected to each other by a submerged locating structure including a submerged mineral resource harvesting device on a suction collecting machine and a mining robot (909) Standing octopus Hull Deck upper part (SDU) Location Connection structure Movement structure to control conveying Construction machinery equipments Separate towers Replacement tower cranes Seisio crane Tower cranes with connection structure of boom zone (942) (886 ) Connecting structure of the connecting magnet magnet 645 and the suction collecting machine connected to the pneumatic conveying apparatus 916 and the connecting structure for conveying the manganese nodule 909 and the aliquot 632 for the elevator and the upper tank barge (591) Surrounding structure provided at the upper end of the upper part of the hull deck (SDU) (844) is equipped with a conveying system that adjusts the position of the ship's upper deck (SDU) to the floating deck hull deck top (SDU), while at the same time the submarine mineral collection and construction machine dispensing system is equipped with a seesaw crane boom 942) and at the same time the connecting structure of the conveyor 633 is located at the upper position of the floating deck hull deck upper part (SDU) in the submarine mineral resource collecting place of the submarine mineral resource located in the SDL of the floating hull deck hull deck Submarine mineral resource exploration equipment and connection structure for searching submarine mineral resource collecting process state while providing submarine mineral resource movement and submarine track (232) and submarine surveying glass underwater illumination light (843) A lighting device for providing a position with a wiring 946 is provided, and at the same time, a floating-type solar power plant 672 of a marine power plant and an atom Connected structures inside nuclear reactor facility (1) of power plant Inhalation collecting machine and connection structure Mineral collecting robot and submarine mineral resource collecting equipment All above mentioned submarine mineral resource collecting equipment included as a connection structure are collected at the water pressure of the deep sea floor and the flow rate of the deep sea The connection structure of each of the lever blocks 123 and the wire rope chain 915 for preventing loss of collecting equipment at the location of the undersea mineral resource collecting site, The bait (632) and the submarine excavation equipment are connected to each other to prevent loss by collecting equipment. In addition, all of the seabed mineral resource collecting equipment is equipped with a lever block (123 ) Wire rope connection structure Each of the gathering devices bound to the structure is moved to a position where the wound wire rope provided on the lever block (123) Hitting a while providing Let go to the seabed mineral gathering process state search Equipped the shift adjustment by picking equipment gakgae at the same time as the connection structure unmanned camera 184 belonging to the seabed exploration equipment connecting shaft; and
The connection structure includes an undersea camera resource search device, a searchlight 232, and a connection structure to connect the unmanned camera 184 to a position where the underwater illumination lamp 843 for the submarine survey lens glass is discharged to the illumination. While the process state scene transmission is being carried out, the distribution input device for operating the submarine mineral collection and construction machine simultaneously connects the container box latching device 129 of the container box 132 corresponding to the submarine mineral carrier to the unmanned camera 184) Submarine mineral collecting process State transmission of the sea surface (SLU) with the transmission of the scene Up to the hull deck upper part (SDU) position to the hull safety facility control room Location to the location of the control room Submarine cable (946) (672) of the offshore power plant and the reactor structure main body (1) of the nuclear power plant are connected to the intake structure collecting machine and the mining robot (SLU) with submarine track wiring (946) included in the submarine mineral resource collection equipment as a whole connection structure Internet connection network (50) to establish the location of the SDU hull safety facility control room inside the control room The undersea camera 184 receives the undersea mining process state scene transmitted from the monitor 51 of the server 51 and the control board 53 through the unmanned camera 184 while simultaneously receiving the connection structure mooring device and connection structure mineral resource collection (1) Inside of the nuclear reactor plant main body (1), which is equipped with the equipments for distributing the moving equipment of the equipments and the equipments for securing the seabed at the seabed while allowing the mineral resource collecting equipment to withstand the pressure of the deep sea bed and the flow rate of the deep sea bed. And the distribution apparatuses for the operation of the submarine mineral collection and construction machinery are provided, and the mooring device formed at the marine power station floating feeder nuclear power plant (672) And diving buoyancy control device and distribution device of nuclear waste disposal and nuclear reactor facility facility safety operation Before the operation of FUSSO nuclear power plant (811), the connection axis of nuclear waste treatment pipe manufacturing process (705) of reactor facility;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a floating crane 846 as a connection structure of an anchor replacement crank 846 inside a reactor facility main body 1 of a nuclear power plant. The power plant is connected to the seabed. It is a distributing and input device. It is equipped with a marine seat of a floating nuclear power plant. It is located at the upper part of deck deck. It is connected to the hull safety device and connecting structure, A seaweed crane boom base 942 of a tower crane for replacement of a cruise ship crane base is divided and a float base 844 and a connecting structure 844 are connected to the hoist base 184, (942) at the same time as the seesaw crane boom (942) Movement control device Connects the structure to collect seabed mineral resources Upper deck (SDU) above the deck (811) supplied with electric power produced by an offshore power plant that provides a location of a submarine mineral resource with the position of the floating deck hull deck upper part (SDU) The power transmission unit (811d) connects the main body (1) of the nuclear power plant of the marine power plant with the connection structure of the power transmission unit (811d) to the seabed crane boom zone (942)
(593, 594, 595) of the marine power plant is a connection structure of the reactor main body (1) of a nuclear power plant. The distribution input device for operating the seabed mineral collecting construction machine,
Construction Equipment Equipments Seisie Crane Boat (942) for the replacement tower crane Seated on each side of the connecting structure Both the basin (842) and pallet (844) connection structure for reuse of seabed mineral resources are connected to the lower part of the sea surface (SLL) ) Positioning Movement Control Device Connection Structure from the Inside Submarine Mineral Resource Collecting Site to the Upper Sea Level Upper Part (SDU) Position of the Upper Sea Level Upper Part (SLU) in the Underwater Hybrid Substructure SDL of the Hull Deck Below the Seabed Crane Boom Stand (942) At the same time, the seesaw crane boom zone 942 is provided with a seesaw crane boom zone 942 for controlling the movement of the seabed mineral resource manganese nuclide 909 as a connection structure to the position of the upper part of the floating deck hull deck (SDU) At the same time, the inside of the nuclear reactor facility (1) of the nuclear power plant is distributed in the submarine mineral resource collection site, The seismic crane boom zone (942), with its mouth, provides for the collection of seabed mineral resources and at the same time a connection structure to control the movement of the hull deck to the upper deck (SDU) And a power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation facility 811 supplied with the power generated by the offshore power plant of the offshore power plant, (1) The operation is carried out by seismic crane boom zone (942) to regulate submarine mineral resources by the displacement control system;
The seesaw crane boom zone 942 distributing and inputting device for operating the seabed mineral collecting construction machine as a connection structure of the reactor facility main body 1 of the floating power plant nuclear power plant of the marine power plant,
The distribution and input device of the seesaw crane boom 942 is located at a position inside the seabed mineral resource collecting site and is connected to the upper end of the sea surface (SLU) (942) Connection structure Mooring device and connection structure Standing on the seabed with the connection structure for lifting and listening to the power supplied by the power generation facility, Hull safety distribution and connection to the connecting structure Hull safety equipment and construction machinery for operation Seito crane replacement tower crane Separate crane boom area (942) Seaside crane boom area (942) distribution structure with connection structure The system is equipped with an input device, and the position control is carried out to the upper part of the deck (SDU) A power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation equipment unit 811 supplied with electric power is connected to the main body 1 of the nuclear power plant of the marine power plant by the operation of the shuttle crane boom 942) is configured to collect seabed mineral resources with a displacement control device;
A distributing and inputting device for operating a seabed mineral collecting construction machine as a connection structure of a nuclear reactor main body 1 of a floating power plant of a marine power plant,
The distribution dispenser for operation of the construction machine includes a manganese nodule 909 for providing a location on the seafloor including a suction collecting machine, a connection structure minerals collecting robot and a submarine mineral resource harvesting equipment connection structure as a nuclear reactor connection structure of a nuclear power plant, It is provided as a connection structure, and it is installed as a connection structure, and it is moved to the upper part of SDU of the hull deck of the ship. Construction equipment equipment Construction equipment equipment Replacement towers of each tower Seisio crane boom of crane (942) Electric magnetic magnet The mooring nodule 905 is connected to the pipeline line conveying device 916 of the connecting structure suction collecting machine and at the same time the connection structure for the elevator allybeat 632 is connected to the upper part of the strut tank upper barge hull 591 (842) for collecting seabed mineral resources and a pallet (844) provided at the upper end of the upper part (SDU) of the floating deck hull deck top The construction and operation of the above-mentioned construction machinery is carried out by a construction machinery and equipment that adjusts the position of the ship's upper deck (SDU) to the position of the floating deck hull deck (Seaweed crane boom zone (942) And at the same time the conveyor 633 moves the conveyor 633 to the upper end of the floating deck hull deck upper part (SDU) in the undersea mineral resource collecting place, which is located inside the lower end SDL of the floating deck hull deck A submarine mineral resource searching apparatus 232 for searching the seabed mineral collecting process state and a submarine line wiring 946 for connecting a deep sea exploration underwater illumination lamp 843 as a connecting structure are provided At the same time, a suction collection machine, a mining robot and a submarine mineral resource collection device are connected to the inside of the nuclear reactor facility (1) of the floating planting nuclear power plant of the marine power plant And a power transmission unit 811d provided as transformers for transmitting the power of the nuclear power generation facility 811 supplied with the power generated by the marine power plant of the marine power plant, The operation of the main body (1) is constituted so as to collect seabed mineral resources by the movement control device of the seesaw crane boom zone (942);
As the connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593, 594, 595), the distribution input device for operating the seabed mineral collecting construction machine,
The unmanned camera (184), which is provided as a connection structure inside the nuclear reactor main body (1) of the floating nuclear power plant of a marine power plant for operation of the submarine mineral collection construction machine, The undersea mineral resource collecting apparatus searching for the undersea mineral resource searching apparatus 232 and the deep sea exploration underwater illuminating lamps 843 are connected to the unmanned camera 184, The container box latching device 129 of the container box to be transferred to the control room is connected with the unmanned camera 184 to the hull safety equipment control room position located at the upper part of the sea surface (SLU) and the upper part of the hull deck (SDU) A line wiring 946 is provided in the reactor main body 1 of the marine power plant, and a connection structure suction intake machine and a connection structure Water harvesting robot with undersea mineral resources collecting equipment connected to the structure that contains the connection structure connecting shaft; and
(SDU) hull safety equipment control room with a submarine line wiring line 946. The Internet network 50 is connected to a monitor 52 of the internal control server 51 and a control unit The ship's undersea camera 184 receives the undersea mining process state scene transmitted to the inside of the board 53 while receiving the seabed mineral collecting process state scene at the marine power generation facilities, and the seesaw crane boom zone 942 of the tower crane for replacing each marine power generation facility. The distribution structure of the submarine mineral collection and construction equipment is as follows. The distribution structure of the submarine mineral collection and construction equipment is as follows. (1) inside the nuclear reactor plant (1) of the nuclear power plant, and (5) 95) Mooring device and diving buoyancy control device for nuclear power plant (672), nuclear waste disposal system for nuclear waste disposal and reactor facility safety operation Fukushima Nuclear Power Plant (811) The connecting axis of the process 705;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 is an internal connection structure between the floating nuclear power plant 672 of a marine power plant and the nuclear power plant main body 1 of a nuclear power plant. The submarine line harness 946 is provided with a distribution structure to the connection structure. In addition, the connection structure of the mineral resource collecting equipment at the seabed is a diving control device provided with a connecting structure for enduring the water pressure of the deep sea floor and the flow rate of the deep sea floor The connection structure of the connection structure of the Bellows butterfly valve 305 and the connection structure of the diving control device connection structure 585 directly connects the conduit type 581 to the doctor ventilation inlet port 585a and the doctor ventilation outlet port 585b, While the distribution apparatus of the nuclear power plant unit 811 is provided with the compressed air generated in the air compressor 80 of the prime mover A single-force automatic pneumatic instrumentation device provided with a microswitch 580 is set in the timer 541 as an overpressure prevention scale indicator, or automatically set to the fire damper 583 without being manually depressed Pressure air is injected into the air cylinder 138 equipped as a connection structure and at the same time the damper spindle 584 connecting structure provides pressure air in the doctor ventilation 585 while the fire damper 583 performs the full closing and expansion The fire damper 583 may be provided with devices for controlling the interruption and supply of air and may be provided with a connection structure such as a pipeline automatic pneumatic conveying device 916, The connection structure provided with or provided with a connection structure such as the Bell-Butterfly valve 305 of the apparatus can be used for the sleeping of the reactor installation main body 1 of the lifting type docking nuclear power plant of the marine power plant To control the control device be configured to accomplish the reactor equipment body (1) of a nuclear power plant, and;
The double structure block tank dust collector of the nuclear power plant 672 of the offshore and offshore marine power plants and the reactor main body 1 of the nuclear power plant 1 and the nuclear power generation facility 811 of the nuclear power plant is connected to the nuclear waste treatment pipe manufacturing process 705 of the reactor facility, The diving preparatory operation control regulating control dispensing device for the hull safety equipment,
The distribution input device of the nuclear power generation facility unit 811 receives the pressure air generated from the air compressor 80 of the prime mover into the reactor facility main body 1 of the nuclear power plant and the floating nuclear power plant 672 of the marine power plant, When the solenoid valve overpressure prevention switch 108 of each solenoid valve 76 and the on-time main switch button 66 of the main switch button 66 for the solenoid valve start switch button are manually pressed, the butterfly valve 305 And the main switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is fully closed to provide an operation interruption. Alternatively, when the start switch button &lt; RTI ID = 0.0 &gt; When the on-time main switch button 66 of the main switch button 66 is manually depressed, the connection structure of the butterfly valve 305 is expanded so that the pressure air generated in the air compressor 80 passes through the pipeline line connection structure And a connection structure for providing a connection structure to a plurality of fire doors 154 and a plurality of hatch cover 153 bodies at the same time as a solenoid valve (not shown) of the reactor main body 1 of a floating power plant The solenoid valve overpressure prevention switch 108 and the butterfly valve 305 connection structure of the solenoid valve 76 are configured to perform an operation;
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input device of the nuclear power generation facility unit 811 performs an operation in which the electronic control rotary hydraulic cylinder 35 is rotated as a connection structure between the floating nuclear power plant 672 of a marine power plant and the reactor facility main body 1 of a nuclear power plant At the same time, a plurality of fire doors 154 and a plurality of hatch cover 153 connection structures are opened as a connection structure, and the mineral resources provided in the seabed mineral collection site are connected to the inside of the body of the holding tank lower barge hull 592 The vacuum pump 635 for the conveying and lifting device and the power cable 71 are connected to each other in the empty space by the structure, and the distributing and inputting device of the nuclear power generation facility 811 is provided with the main switch button for the start switch button The vacuum pump 635 is rotated by manually depressing the on-time main switch button 66 of the vacuum pump 66, Mineral resources provided at the submarine mineral collection site located outside the body of the barge hull (592) are the connecting structure that provides the position movement to the inside of the body of the barge hull (591) at the top of the holding tank. 1) the internal hydraulic control rotary cylinder (35) hull safety equipment is constructed inside;
The distribution input device for operating the submarine mineral collection and construction machine as a connection structure of the nuclear reactor main body 1 of the floating power plant of the marine power plant includes a hull 206 for controlling the submersible- And the submarine mineral resource connection structure to replace the submarine mineral resource connection structure to provide the hull safety facility, or the submarine submarine mineral resource for controlling the diving position of the hull, (SLU) Floating upholstery Upper part of the upper deck (SDU) of the hull Deck of marine power generation facility which is positioned as a connection structure. Replacement Tower Cranes Seiso Crane Boom Stand (942) Connection Structure Make a power plant with mooring system and connection structure. A connection structure provided at a low mineral collection site, comprising a main body (1) of a nuclear power plant of a marine power plant as a distribution input device for operation of a construction machine;
As the connection structure of the nuclear reactor main body 1 of the nuclear power plant of the marine power plant (593, 594, 595), the distribution input device for operating the seabed mineral collecting construction machine,
The mineral resources of the distributing and inputting apparatus for operation of the submarine mineral collection and construction machine are divided into a hollow space inside the lower tank barge hull (592) of the holding tank, a hull connecting structure diving position adjusting movement device and a diving buoyancy Submarine mineral resources for diving buoyancy control, replacing submarine mineral resources, and a plurality of fire doors and a plurality of hatch covers (153) provided on the outer bulkhead of each part of the body of the holding tank lower barge hull (592) (916) to pass through a pipeline line automatic pneumatic conveying device
The solenoid valve overpressure prevention switch 108 of the connection structure solenoid valve 76 and the main switch for the solenoid valve start switch button of the connection structure solenoid valve 76 are connected to the ballast butterfly valve 305 of the diving control device of the pipeline, The connection structure of the button (66) is provided with a connection structure by a connection structure of the power cable (71), and the connection structure of the boat crane boom bar of the tower crane substituting the inside of the reactor installation main body (1) of the floating power plant of the marine power plant 942) Distribution system for distribution of mineral resources to the connection structure Moving device Construction equipment Consisting of connecting structure with connection to the structure and having a seated place at the seabed, but at the same time, the upper part of the sea surface (SLU) The marine power generation facilities that provide the location of each quay Alternative tower Crane seesaw crane Boom bar (942) Connection structure Mooring device (593,594,595) installed at the nuclear power plant (672) of the marine power plant, or the connection structure provided at the seabed mineral collection site by the power plant equipment having the connection structure, And diving buoyancy control device and distribution device of nuclear waste disposal and nuclear reactor facility facility safety operation Before the operation of FUSSO nuclear power plant (811), the connection axis of nuclear waste treatment pipe manufacturing process (705) of reactor facility;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input device of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of a marine power plant and the reactor main body 1 of a nuclear power plant. In the submarine mineral resource collection equipment distributing and inputting apparatus, Tank (590) Upper barge hull (591) 500 m long to position to upper side position Double structure block tank A manganese nodule (909) with reserves of 5000 million meters of seabed, The connecting structure having a structure in which a plurality of the grounding baskets 183 and the nuclear plant construction unit 811 are connected to the inner position of the container box of the connection and disconnection structure of the nuclear power plant 811 is constituted by a submarine mineral garden air bag 849, The seepage crane boom base 942 of the tower crane is distributed to distribute both sides of the seabed crane boom base 942 to the hook hook 18 of the seesaw crane boom base 942 of the tower crane, The float basket 842 and the pallet 844 connecting structures are connected to the sea level basin 842 and the pallet 844 connection structure for collecting seabed mineral resources on both sides of the seesaw crane boom portion 942 of the tower crane, (SDD) of the upper part of the sea surface (SLU) to the position of the upper part of the hull deck (SDU) of the sea surface from the position of the submarine mineral resource collection place in the lower part of SDL (SDL) (909) of mineral resource manganese nodule (909) to the upper part of the ship's deck (SDU), while at the same time arranging the submarine mineral resource collection site inside the main body The distribution input device of the nuclear power generation facility 811 is provided to the position where the connection structure submarine line wiring 946 is provided, (SLU) levitated at the top of the sea surface (SDU) Located at the top of the deck of the ship (SDU) Separate towers Replacement tower Cranes Seisoka Crane Boom area (942) Mooring device connection structure (593, 594, 595) to the seafloor. Both sides of the seesaw crane boom zone (942) of the tower crane at the bottom of the sea surface provided inside the nuclear reactor facility main body (1) of the floating nuclear power plant of the marine power plant, A connecting structure for providing a distribution input device of the nuclear power generation facility 811, and constituting a nuclear power plant main body 1 of a floating power plant of a marine power plant;
The distribution input device of the nuclear power generation facility 811 of the mineral resource and the lifting device lifted by the floating pickling hull collecting device as a connection structure of the nuclear reactor facility main body 1 of the nuclear power plant of the marine power plant of the marine power plant (593,594,595)
The distribution input apparatus of the nuclear power generation facility unit 811 is a system in which a hydraulic structure of the connecting structure hydraulic hydraulic cylinder 39 is operated as a connecting structure inside the reactor facility main body 1 of the floating planted nuclear power plant of a marine power plant, The nodule 909 is provided inside the reactor installation main body 1 and the seesaw crane boom stand 942 hydraulic cylinder machine 624 of the tower crane substituting for crates positioned at the top of deck deck of the strand tank upper barge hull 591 The hydraulic system of the hydraulic cylinder machine 624 is provided with the load and piston seal 822 and the piston seal 823 and the booster seal 824 and the wear ring 825 and the slide ring 826, 828 and the O-ring 828 and the load seal 829 and the backup seal 830 and the load seal and backup seal 831 and the mist seal 832 and the pin cast seal 833 and the mist seal 834, A bushing ring 835, a piston ring 836 and a multistring 837, System 624 in nuclear power Equipped the distribution chute of seolbibu 811, a hydraulic pump connected to the high-pressure hose structure 190 and the high pressure of the conjugate through to the pipe and the solenoid valve (76) axis; and
The piston moves forward and backward within the hydraulic cylinder machine 624 and at the same time the seesaw crane boom stand 942 of the tow crane replacement tower crane is moved to the upper position of the deck deck of the holding tank upper barge hull 591 to the hydraulic cylinder machine 624, The submarine mineral resources that are recovered to the upper part of the upper deck (SDU) of the floating deck hull deck are provided with the national foreign debt reimbursement (SDU) at the top of the sea deck (SDU) at the top of the sea with the submarine line wiring (946) connected to the distributing and inputting device of the nuclear power plant (811) Crane boom (942) Mooring device of connection structure and connection structure inside reactor main body (1) of nuclear power plant. The distribution and input devices of the nuclear power plant 811 are provided in the reactor main body 1 of the magnetic power plant and the mooring device and the diving buoy control device and the nuclear waste generated in the nuclear power plant 672 of the marine power plant floating support 593,594,595, Dispensing device of treatment and reactor facility of nuclear reactor facility Before the safety operation, the connection axis of the nuclear waste processing pipe manufacturing process (705) of the reactor facility at Hue City Nuclear Power Plant (811);
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 includes a floating nuclear power plant 672 of a marine power plant and a furnace distributing and inputting apparatus for operating a mineral resource heat treatment operation of a floating power plant 672 of a marine power plant and a nuclear power plant Reactor main body (1) Internal connection structure Upper part of sea surface (SLU) with submarine track wiring (946) Upper part of upper deck (SDU) Upper marine power generation facility Replacement towers of different towers Crane seesaw crane Boom bar (942) Structures Mooring system and connection structure Submarine mineral resource lifted by power generation facility Submarine line wiring (946) Replacement towers with connection structure Seisio crane boom stand of crane (942) Body connection structure Internal boom hook hook (842) and a pallet (844) for collecting seabed mineral resources in the seabed crane boom (18), but the seabed crane boom stand (942) The reclaimed grass baskets 842 and 844 are provided with an upper surface SLL at the lower level of the sea surface SLL and a lower level SDL at the inner bottom of the SDL, At the same time, the distribution input device of the nuclear power plant 811 carries out the transportation of the seabed mineral resource manganese nodule 909 to the upper part of the floating deck hull deck (SDU) The distribution and input device of the nuclear power generation facility 811 is connected to the upper end of the sea surface (SLU) with the connection structure submarine line wiring 946, the upper part of the ship deck (SDU) (942) Connecting structure Mooring device and lifting of marine power plant Nuclear power plant nuclear reactor plant (1) Connected to the inside Structure of the nuclear power plant Made be configured reactor equipment unit to dispensing chute furnaces for heat treatment of mineral resources and movable;
(593,594,595) of the above-mentioned marine power plant, the furnace distributing and inputting device for operating the mineral resource heat treatment operation is a connection structure of the reactor main body 1 of the nuclear power plant of the marine power plant (593,594,595) ) Inside the submarine mineral resource collection site, the inhale collection machine and mineral extraction robot of the mineral resource collection equipment are distributed and installed, and the location movement control is carried out by the position movement control device. At the same time, the upper part of the upper part of the deck (SDU) And a blast furnace 948 having a furnace 948a of a blast furnace 948 is provided with a blast furnace 948 provided with a blast furnace and a furnace 948. The bottom of the blast furnace 948 is poured with molten manganese nuclide 909, (948) for the production of the guide rails (597) and the guide rails (618), and at the same time, And a connecting structure for providing the guide rail 618 for the block tank hull transportation device inside the reactor facility main body 1 of the nuclear power plant includes the production and supply of the iron plate 597 and the guide rail 618 as the double structure block tank pipe The guide rails 618 provided in the inner lower tank location connection structure of the inner block tank 596 of the dual structure block tank 598 connected with the nuclear waste treatment dual structure block tank bridge 929 having the connection shaft of the bridge 937 The furnace distributor for the mineral resource heat treatment operation is provided with a train 771 for locating the internal block tank 596 with an internal train 771 for a marine tunnel apparatus of 100 KM / (597) of the high-strength stainless steel and the guide rail (618) are provided inside the nuclear reactor main body (1) of the nuclear power plant. The connecting shaft of the current device and the submerged buoyancy control devices and nuclear waste disposal distribution chute and reactor plant reactor plant safety operation before and after the manufacturing process 705, the nuclear waste disposal pipes of the reactor in a nuclear power plant seolbibu 811 of the;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The submarine energy constituting the position of the connecting shaft of the submarine 705, and the diving preparatory operation regulating control distribution dispensing apparatus for the construction machine dispensing apparatus and the hull safety apparatus for operating the mineral collecting apparatus,
The distribution input device of the nuclear power generation facility unit 811 is connected to the upper end of the sea level upper surface portion SLU with the submarine line wiring 946 as the internal connection structure of the reactor facility main body 1 of the floating planted nuclear power plant of the marine power plant, SDU) Offshore Generation Facility Seito Crane Replacement Tower Cranes Replacement Tower Crane Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom Boom (SLD) of the sea surface (SLL) as a connection structure between the grate basket 842 and the palette 844 for collecting the seabed mineral resources at the same time, as a connecting structure on both sides of the seesaw crane boom band 942, (SDU) at the upper part of the sea surface (SLU) to the upper part of the deck (SDU) The distribution and dispensing apparatus of the facility unit 811 is equipped with a manganese nodule 909 as a connection structure for the seesaw crane boom band 942 by transporting the seabed mineral resource manganese nodule 909 to the upper end SDU of the floating deck hull deck At the same time, in the inside of the reactor facility main body (1) of the nuclear power plant of the marine power plant, the seesaw crane boom zone (942) is connected to the inside of the seabed mineral resource gathering place. And the hatching erectors 877 are provided for injecting the solidified manganese nodule 909 into the furnace as the manganese nodule 909 for crushing the crushed manganese nodules 909. At the same time, the file driver 882 of the plurality of construction machines 880, The position of the hammers 883 and the steam hammers 884, the hydraulic cranes 885 and the tower cranes 886 are adjusted to adjust the position of the hammers 883 and the crane 886. At the same time, the intake collection machine 911 for collecting the seabed mineral resources and the mineral picking robot 912) includes a construction machine excavator It is a connection structure to control the operation position movement as a connection structure. It is a connection structure of the reactor main body (1) of a floating power plant of a marine power plant. It is equipped with a construction machine distributing input device for operating submarine energy and mineral gathering equipment. Collecting resources into a plurality of construction machines 880;
The construction machine distributing and inputting apparatus for operating the submarine energy and mineral collecting equipment composed of the connection structure of the crane boom unit (74) of the reactor facility main body (1) of the nuclear power plant of the marine power plant (593,594,595)
(1) Inside the tower Replace towers Replace towers Crane seesaw crane Boom barge (942) Crane Boom boom Boom Boom girder (652) Multiple heavy oil tanks on both sides of the body Pressure hose 190 connected to the 500 m high-pressure hose 190 connected to the bottom of the heavy oil tank 795 by a plurality of high-pressure hoses 190 as a connection structure, (908) a plurality of drill rod pipe racks (854) connected to a drilling machine; a core drill (917) positioned at the fore end; a crude oil borehole (936) and a natural gas borehole (936) , A predetermined amount of piping files are provided, and at the same time, loess and cement are supplied to the pipe line (854) as a passage of the pipe line to supply the piping file crevice space to the loess and cement While at the same time fill the pipe files 500m high pressure hoses 190 connect fitting couplings (29) to a high pressure hose connection is connected to a plurality of connection structures shaft; and
The crude oil and the natural gas, both of which are provided with crude oil and natural gas reservoirs, are connected to boom hoists and boom hooks 652 of the crane boom area of the seesaw crane boom area 942 of the tower crane, The ingot basket 842 and the pallet 844 for collecting the undersea mineral resources are connected to the in-body boom hook hook 18 so as to form a weep basket 842 for collecting both undersea mineral resources of the seesaw crane boom girder 942, And the Palette 844 are located at the lower end of the sea level SLL of the sea level SLL and the SDU of the floodplain hull deck upper part SDU of the upper part of the sea surface (909) of the submarine mineral resource to the upper part of the floating deck hull deck (SDU), and at the same time, the vertical Crude oil, natural gas and undersea energy harvesting equipment, which provide lifting to the deck top deck at full operation, are located at the upper end of the sea surface (SLU) (SDU) Offshore power plant with location to the upper position Seito crane of different crane tower Crane boom of boom zone (942) Boom boom of boom Boom and boom hook (652) Connection structure Mooring device and connection The structure includes the connection axis of the nuclear waste processing pipe manufacturing process 705 of the reactor facility at the nuclear power generation facility 811;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution apparatus of the nuclear power generation facility unit 811 includes a nuclear power plant 672 of a marine power plant and the reactor facility of the nuclear power plant 1 of the nuclear power plant, A plurality of inner block tanks 596 and a plurality of outer block tanks 599 to the outside of the plurality of inner block tanks 596 and a first auxiliary tank 600 for a block tank, A vertical partition 605, a horizontal partition 609 and a steel beam 149 in the second auxiliary steel plate 601 for the block tank and the second auxiliary steel 600 for the block tank and the second auxiliary steel 600 for the block tank 601, Cutting processing is performed by a computer laser cutter 954 for each of the auxiliary steel plate 601, the vertical partition 605, the horizontal partition 609, the steel beam 149, the snap hole 602 and the partition wall manhole 610 At the same time, welding of the double structure block tank dust collector 794 is provided by a welder of the welding process, 4 Fifth guard wall distributing apparatus and fuel explosion control dispensing apparatus formed along the outer wall surface of the protective wall containment vessel 808 Nuclear reactor nuclear leakage leakage control dual structure block tank dust collector (794) Nuclear Reactor Nuclear Reactor (Nuclear Reactor) Nuclear Reactor (Nuclear Reactor);
The distribution and input device of the nuclear power generation facility unit 811 includes a vertical partition wall 605 in which a partition wall manhole 610 is formed inside a reactor facility body 1 of a floating planted nuclear power plant of a marine power plant and a horizontal partition wall 609, The hydraulic cylinder door 624 and the emergency stairs 631 are provided with a reactor installation main body 1 of a floating type pilot nuclear power plant by a welding process and a double structure block tank dust collector 794, The unit is provided with a hydraulic cylinder door 624 and emergency stairs 631, and is provided as a transportation device in the inside and outside of the double structure block tank dust collector 794 for control of the reactor facility nuclear radiation leakage control reactor. The shielding device is configured to operate the nuclear power plant;
A plurality of stopper plates 625 are connected to a cylindrical double structure block tank 598, a plurality of inner block tanks 596 and a plurality of outer block tanks 599, At the top and bottom of the dual structure block tank, the double structure block tank dust collector 794 is welded to the large structure flange bolt 794 and the large flange bolt connection double structure block tank dust collector 794, (1) of the nuclear plant of the marine power plant, a plurality of nuclear reactor nuclear waste (224) treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus are installed in the main body (1) of the marine nuclear power plant. And the barge hull 592 at the lower part of the holding tank. Alternatively, the nuclear reactor main body 1 of the floating nuclear power plant of the marine power plant may be divided into a plurality of reactor nuclear waste 224 It comprises a nuclear powered by the fuel control device to the explosion of a plurality of steel plate stopper 625 be configured to accomplish the reactor equipment body (1) and;
In the nuclear waste disposal unit dual structure block tank dust collector 794 of the nuclear power generation facility unit 811, a plurality of inner block tanks and a plurality of outer block tank vacancies are stored in the lower ends of the empty space before nuclear explosion, At the same time, the installation of the reactor floor of the double structure block tank precipitator 794 is provided with fixation by the reinforced concrete mat 225 and the steel beam 149 of the number of the road surface lower surface GLD thickness m, The barge hull 591 at the upper end of the holding tank is replaced with the reactor building 688 outside the inner block tank 596 having the nuclear fuel explosion preventive double structure block tank dust collector 794, Nuclear Reactor (Nuclear Reactor) Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Nuclear Reactor Control distribution dispenser Dual structure block Tank dust collector (794) is installed in the marine power plant to supply the nuclear waste to the reactor main body (1) of the floating nuclear power plant of the marine power plant Discharging injection device and nuclear fuel explosion control Dispensing input device Double structure block A tank dust collector 794 is provided to generate electric power and the nuclear radiation leakage control dual structure block tank dust collector 794 operates the nuclear power plant;
The distribution and input device of the nuclear power generation facility 811 has a large amount of radiation generated inside the nuclear power plant main body 1 of the floating power plant of the marine power plant so that the nuclear fuel explosion control distribution input device A first wall pellet and a cladding for providing a second wall fuel rod protection; a third wall reactor pressure vessel, a fourth wall containment vessel and a fifth wall reactor building; and a reinforced concrete mat (225) A double structure block tank dust collector (794) is installed as a dispensing device and a nuclear fuel explosion control dispensing device in place of a five-layered protective wall, or a nuclear power plant is installed in the nuclear reactor main body (1) Of the nuclear reactor facilities are provided as a reactor nuclear waste disposal dispenser with double structure block tank reactor buildings (688) in the barge hull (591) at the upper end of the holding tank At the same time, the barge hull (592) at the bottom of the holding tank is provided with a plurality of nuclear reactor facilities such as a reactor facility of the nuclear power plant in the nuclear fuel explosion control distribution dispensing apparatus dual structure block tank dust collector (794) Control dual structure block tank cleaner 794 to operate the nuclear power plant;
The distribution and dispensing apparatus of the nuclear power generation facility unit 811 has a connection structure with a steam generator 810 and a steam dryer 786 installed outside the reactor pressure vessel 813. The nuclear power generation facility 811 A plurality of through holes are formed in the upper portion of the nuclear reactor building 688 corresponding to the fourth wall and the containment vessel 808 corresponding to the fourth wall of the distribution dispensing apparatus using cutters and construction machines at an angle of 45 degrees A plurality of safety valves 472 are connected to the block piping line 74 by means of bolts 24 and nuts 25 and a gasket The reactor building 688 may be provided with a flange coupling connection with the reactor building 688 or the distribution injector dual structure block tank dust collector 794 of the nuclear power generation facility 811 along the outer wall surface of the reactor building 688, The double structure block tank 598 having a diameter twice the diameter of the double structure block tank 598 Nuclear waste treatment storage External block tank (599) and radiation-type double pipe structure block piping line (74) By providing a connection structure, nuclear waste disposal dispensing equipment and nuclear fuel explosion control dispensing equipment The radiation leakage control dual structure block tank dust collector 794 is configured to operate the nuclear power plant;
The distribution unit of the nuclear power generation facility unit 811 includes a plurality of inner block tanks 596 and a plurality of outer block tanks 599 in the double structure block tank reactor building 688, The cement mixer equipment mixer machine 649 is installed in the pressure vessel 813 such as a furnace immediately before the large explosion of the nuclear reactor and the mixture of the nuclear fuel explosion-proof control article cooling water 287 and the loess mixture 927 ) Is installed in the pressure vessel (813) at the same time by injecting a fuel explosion-proof control article into the automatic injector double structure fire-fighting nozzle (10), and the inside of the reactor facility is cleaned before the earthquake A plurality of double-structured fire-fighting nozzle nozzles 10 are formed inside the pressure vessel 813 and inside the containment vessel 808, but the interior of the reactor facility, Dynamically automatic injection device A double structure fire-fighting nozzle 10 is provided with a plurality of internal cleaning processes, and at the same time, a nuclear fuel explosion-control dispensing device having a reactor facility of a double structure block tank dust collector 794, (1) of the reactor facility main body (1) of the nuclear power plant, and a double structure block tank of the nuclear reactor facility is installed in the reactor main body (1) of the nuclear power plant. It is equipped with a treatment distribution dispenser to prevent the explosion of the nuclear reactor facilities before and after safe operation of the reactor facilities, and to set up the operation of the nuclear reactors;
The distribution and dispensing apparatus of the nuclear power generation facility unit 811 forms a circulation water pump 242 connecting the cooling water 287 and the piping line 352 to the distribution and dispensing apparatus of the nuclear fuel explosion control apparatus. The mixture of the yellow loess mixture and the yellow loam mixture mixer machine (649) is mixed with the cooling water (287) so that the loess mixture is not solidified. At the same time, the cooling water (287) The pressure inside the pressure vessel 813 at the same time to clean the inside of the reactor immediately before and after the occurrence of the earthquake and at the same time to ensure the safe operation of the reactor facility capable of performing continuous power generation without being restricted by natural disasters A nuclear waste disposal and dispensing apparatus having a double structure block tank dust collector 794 for preventing nuclear explosion prevention nuclear radiation leakage control formed by maximizing nuclear fuel explosion Nuclear Fuel Explosion Control of a Multiple Nuclear Reactor Installed in a Nuclear Reactor Facility 1 of a Nuclear Power Plant Equipped with Dispenser Feeding Devices Reactor Facility Safe Operation Before and After Dual Structure Block Tank Dust Collector Reactor Operation ;
The distribution input device of the nuclear power generation facility unit 811 includes a double structure block tank dust collector reactor facility of a nuclear power generation system in which the outer wall surface of the nuclear reactor building of the dual structure block tank dust collector reactor equipment of the fifth wall (224) Radiation nuclear wastes (224) connected to one of the nuclear reactors of a nuclear power plant containing nuclear reactors (1) Nuclear reactors of the nuclear power plant The nuclear power generated at the time before and after operation of the nuclear power plant includes a steam turbine 267 generating nuclear fission in the nuclear reactor facility to generate steam 780 to rotate the steam turbine 267 to generate power, The nuclear power generator 772 for providing the power conversion produced from the nuclear power plant 267 and the steam turbine 267 and the nuclear power generator 772 A rotating rotor electromagnet coil 774 for a nuclear power generator installed along a circumferential surface of a connecting rotating shaft 198 and a rotating electromagnet coil 774 for rotating the rotor electromagnet coil 774 for the nuclear power generator, The nuclear plant generator 811 includes an armature coil 773 and a frame 775 for fixing the rotary shaft 198 to the nuclear power generator 772 and the steam turbine 267. The reactor installation safety Control of nuclear radiation leakage before and after operation Dual structure block tank dust collector (794) Reactor facility to operate nuclear power plant;
The distribution input apparatus of the nuclear power generation facility unit 811 includes a cooling water pipe line 352 having a connection structure with the condenser 790 at a lower portion of the body of the steam turbine 267 of the nuclear power generation facility unit 811, A circulation water pump 242 for providing a connection with the piping line 169 and the cooling water 287 piping line 352 is provided at the front of the condenser 790 in order to prevent the leakage of the radioactive- Tank Dust Collector (794) is used to operate nuclear reactors with reactor facilities;
A feed pump 241 is formed at the rear end of the condenser 790 and outside the nuclear reactor facility and a purifier 809 is installed outside the reactor facility in front of the feed pump 241 A plurality of coolant pumps 243 are installed outside the body of the reactor pressure vessel 813 in which the fuel of the uranium 812 is stored so that the inside of the reactor pressure vessel 813 The control rod 798 is installed in the core at a time so that the reactor can be provided with an emergency stop. However, at the same time, when the double structure block tank dust collector (794) In the nuclear reactor facility, cooling water (287) and a mixture of loess and loess are put into the pressure vessel (813) at the same time, (794) The reactor structure is configured to operate the nuclear power plant;
The distribution input apparatus of the nuclear power generation facility unit 811 has a structure in which a clad pipe 682 for protecting the first wall pellet 683 and the second wall frit rod 689 is installed in a plurality of reactor installations from a seismic occurrence The safety valves 472 in which the plurality of temperature pressure sensors are formed in the third wall reactor pressure vessel 813 and immediately before the explosion in the fourth wall containment vessel 808 are opened and the pressure vessel 813 of the upper block piping line Detonated nuclear waste 224 passes through the inner block piping 74a of the inner block tank 74 and the outer block piping 74b communicates with the fuel explosion-preventing control article cooling water stored in the inner block tank 596 The yellow loess mixtures which generate soap bubbles are transported to the inside of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the water supply pump 241. In the inner bottom of each of the double structure block tanks 598, The wastes 224 may be stored for movement, The temperature block sensor control valve 472 connected to the lock tank 596 is opened and at the same time the outer block pipe 74b of the block piping line 74 is connected to the fuel block control water coolant And the loess mixtures which generate soap bubbles are transferred to the interior of the pressure vessel 813 and the fourth protective wall containment vessel 808 by the feed pump 241. At the same time, The energy of the water is converted into kinetic energy, and the water is transferred to the interior of the nuclear reactor facility. At the same time, the inner block tank 596 and the outer block tank 599 are filled with the stored coolant and yellow soil mixtures, (794), which is an alternative to reactor building, is provided as a substitute injector for nuclear reactor building. Configuration be made to the nuclear power plant operation and can double the building block dust collector tank (794) equipment to provide a soil mixture, and;
The dispensing apparatus of the nuclear power generation facility unit 811 includes a remote control cutter and a robot 700 for disassembling the reactor facility of the nuclear power plant and a plurality of temperature pressures In the distribution input device of the nuclear power plant 811 in which the detection sensor safety valves 472 are closed, a plurality of temperature pressure detection sensor safety valves 472 are normally closed when the reactor is operated, (591) of the nuclear power plant to be installed on the ocean barge line (591);
The distribution and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear reactor radiation leakage control dual structure block tank dust collector 794 installed in the marine anti-submersible floating barge line, so as not to be restricted by the weather conditions of earthquakes and tsunamis The position of the nuclear power installation at 40m above the sea level is controlled by the mooring device and the diving and buoyancy control devices installed on the floodgate of the anti-submerged buoyant type, but also the flood control which is not affected by the earthquake and tsunami Nuclear power plants are constructed to operate nuclear reactors with a dual-structure block tank dust collector (794) to prevent nuclear reactors from exploding at nuclear power plants;
The distribution and input device of the nuclear power generation facility unit 811 may include a reactor structure including a double structure block tank dust collector 794 to prevent explosion of a reactor in a nuclear fuel chamber to prevent environmental pollution due to nuclear waste, Axis; and
The distribution and input device of the nuclear power generation facility unit 811 is a barge that provides safe and continuous operation of the nuclear power plant, guarantees the safety of the nuclear power generation facility, ensures the renovation of the reactor with continuous operation, In addition to providing the mooring device, the diving buoyancy control device, the nuclear waste disposal dispensing device, and the fuel explosion control distribution dispensing device, it is also possible to prevent pollution of the environment due to the nuclear waste, The nuclear waste disposal system of the non-explosion dual structure block tank dust collector is installed in the nuclear reactor main body 1 of the nuclear power plant, and the mooring device, the diving buoy control device, Waste Treatment Dispensing Apparatus and Nuclear Reactor Facilities Before the safety operation, FUSSIA Nuclear Power Plant (811) Water treatment tube manufacturing process of the connecting shaft (705);
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and ocean offshore power plants and the reactor structure main body of the nuclear power plant (1) Nuclear power generation facility of the nuclear power generation facility (811) The dive progression ready operation control distribution dispensing apparatus for the hull safety equipment constituting the connection axis position of the diving operation preparation control apparatus 705,
The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear plant power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) I composed and;
The distribution dispenser of the nuclear power generation facility unit 811 is installed at the top of the sea level 40 m so as not to be restricted by the weather condition, and the distribution power supply unit of the nuclear power generation facility unit 811 is provided with a floating nuclear power plant 672, (638), anchor chain (640), rocker bed (616), rotary table lathe machine (908) of crude drilling machine and buoyancy regulator piping line automatic pneumatic valve transport device (916), a vacuum pump (635), a high pressure multi-stage multi-stage disaster prevention pump (8) for a disaster prevention pump, and a double structural block tank dust collector (794) for controlling the hull barrel torsion tank. A Bell-rotor butterfly valve 305 of a diving control device of a piping line having a connection structure of a plug-through wire net 28 and a jet pump 157, a nuclear waste disposal control valve 305 of a nuclear waste disposal storage tank and a doctor venture 585, A solenoid formed in the hydraulic cylinder device 624 for the block inlet port 585a and the doctor ventilation outlet port 585b and the hydraulic cylinder door 624 for the block tank hull traffic control device and the hydraulic unit for the block- Valve (76) Diverge position control of each connecting valve and hull, Movement control of diving buoyancy control valve (949), Adjustment of throttling control, and operation of large Marine Nuclear Power Station floodgate (595) (595) operating structure at the same time as the ship's weight, sea level gravity and buoyancy are generated, and buoyancy generated by sea level gravity causes the large ocean nuclear power plant floodgate (595) to float slowly to the sea A plurality of bollards 638 for holding a ship mooring rope of a barge and a ship mooring canceller are connected to a strut tank upper barge hull 591 and a holding tank lower barge hull 592, The anchor 639 formed on the anchor chain 640 for connecting the bollard 638 and the mooring device anchor 639 is pierced by the winch 137 to the seabed (595) of a large marine nuclear power plant. (595) When an underwater anchor (595) is anchored to the barge hull by an anchor ring device and the sea floor depth is deeper than the continental shelf depth, crude oil (908) of the drilling machine for drilling, and the anchorage of the marine nuclear power station floating ship (595) of the above-mentioned large-scale marine nuclear power plant is provided with an anchor ring device, And the operation of the feed dog 185 is performed by folding the body of the feed dog 185 with the hydraulic cylinder hydraulic pressure key 623 formed at the hydraulic cylinder 623 of the mooring unit replacing the hydraulic cylinder hydraulic pressure pad 623, (595) of the marine nuclear power plant is lifted, or when the hydraulic cylinder (623) of the hydraulic cylinder is operated by the umbrella pushing operation of the main body (185), a large marine nuclear power plant lifting plant 595) Anchor bolting mooring arrangements with barge hull anchoring arrangements to adjust the height of barge elevation. Nuclear power plant flood control console (595) Double structure block tank Barge hull anchoring Anchor bolting Mooring device Nuclear power plant operation The equipment is configured to operate before and after operation of the nuclear power plant;
The distribution input device of the nuclear power generation facility unit 811 includes an air receiver tank 145 for an air storage tank for providing diving control of the floating pick-up hood into the reactor facility main body 1 of a floating power plant nuclear power plant of a marine power plant, An air liquefying apparatus cooling mechanism cooling fan 645 of the HV system and a heater fan (not shown) for floating the air balloon 78, the rubber balloon 914 and the tube 188 in the air 642), maritime pirates that cause war, and those who are engaged in international diplomatic disputes, are expelled from the global atmosphere by satellite launchers (643), satellites and airships, and at the same time, An air compressor 80 is installed in the reactor launching base 643 and the space rocket launching base 646. The air compressor 80 is installed in the reactor installation main body 1 of the reactor main body 1, At the same time, the tackle winch 137 operated by the compressed air supplied from the air compressor 80 is used as a dual structure block tank dispensing device of the nuclear power plant 811 of the Nuclear Power Plant Lt; / RTI &gt;
The distribution and input device of the nuclear power plant 811 includes a crane 861 installed at the top of the floating deck hull deck (SDU), a wire rope 19 included in the crane 861, a wire rope chain 915 And an air hose 109 connected to the front of the trolley winch 137 in front of and behind the air receiver tank at the rear of the air compressor 80 and an electric magnet magnet 645 A pipeline line automatic pneumatic conveying device 916 for conveying loess and cement by piping and high pressure hose, and a mixing equipment mixer machine 73 for providing a position in front of the pipeline automatic pneumatic conveying device 916 And a lever block 123 is provided for each tonnage capacity so as to be combined in units of a dual structure block tank 598 to provide a combined nuclear reactor facility of a marine nuclear power plant in units of a dual structure block tank 598, The distribution of the equipment 811 The apparatus is provided with a machining hole for male and female engaging in an iron plate bracket 165 which is coupled with a holding tank and a holding tank combining part by a bolt-nut, while securing the fastening object again with the turn- In the tank facility, there is a joint between the flange and the flange on the welded part that can withstand high pressure, and the distribution of the nuclear waste treatment reactor equipment (811) of the nuclear waste disposal reactor facility of the marine nuclear power plant The reactor is operated to operate the nuclear power plant;
The distribution and dispensing apparatus of the nuclear power generation facility unit 811 is configured such that the rubber packing 32 of the gasket packing is connected to the intermediate portion of the gap between the large flange 614 and the large flange 614, The block tank assembly is provided with a large flange machining hole 615 with high strength bolts and nuts for connection to the inside and outside of the dual structure block tank 598 and to the double structure block tank flange 614 and other engaging flanges 614 , While at the same time the dual structure block tank flange 614 is connected to the dual structure block tank connection inside the reactor installation body 1 of the nuclear power plant and the high pressure stage multi stage pump 8 and the doctor ventilation fan 195 are operated The opening of the ballastere butterfly valve 622 is provided by the actuation of the valve disc in the ballastere butterfly valve 622 which causes the float to provide floating humanoid hull diving in response to the opening of the manhole 610 and the hatch cover 153 Me, Dong The ship's floating hull is floated to the sea, and the barge hull at the bottom of the double structure vertical holding tank is formed into a nuclear waste treatment storage tank generated from the reactor, and the barge hull bottom support adjustment mechanism The horizontal axis of the hinged joints of the horizontal and vertical hinges is connected to the long hole 606 of the lug pin 606, Distributor input device flood control The Bellactor Butterfly Valve (622) controls the operation of the nuclear power plant to provide docking docking;
The dispensing apparatus of the nuclear power generation facility unit 811 is provided with a guide rail 618 for deck deck upper end equipment transfer and a helicopter station 619 as the upper end of a floating deck deck deck, (623) for a semi-submerged operation line on which a double-structure block tank frame combination in the form of a folding umbrella is provided for a marine operation, and a hydraulic cylinder operation key (598) Combined tool fixture The band guide (621) is equipped with a hydraulic cylinder mounted on a semi-submerged working line (637), and at the same time The coupling facility of the double structure block tank of the distribution input device of the nuclear power generation facility unit (811) includes the control device balancing control device for flood control for the submarine submerged submarine The motor control unit of the motor of the motor of the coupling motor of the dual structure block tank is provided with the twin butterfly valve 622 and the above- The interior equipment includes a hood 193, a retaining ring 194, a fan 195, a body frame 196, a body front reinforcing steel plate 197, a rotary shaft 198 and a rotor assembly 199, The frame 202 and the terminal box 203, the lifting bolts 204 and the terminal box cover 205, the rear rotation bearing 206 and the rear reinforcing steel plate 207 An assembly of the rotor 208, the protective cover 209, the rotor core 210, the stator core 211 and the stator windings 212 is provided and power is supplied to the motor body 192 of the motor, It is necessary to prevent the sinking in case of damage to the defective part of the ship and to construct the source structure of the extension time An electronic control device for providing a connection structure with the equipment doctor ventilation 585 of the HVAC system for one hour and the mineral resource intake port suction control device by adjusting the water pressure in the floating hood 58 is provided with switch button ON- A stopper plate 625 formed of a hydraulic cylinder door 624 for closing the door when the door is opened and closing the switch button off-state, and a stopper wire netting 28 for blocking access to the inlet of the inlet of the hull, Electronic control devices to ensure continuous operation of nuclear reactors for nuclear waste disposal facilities before and after the operation of nuclear reactors in marine nuclear power plants;
The distribution apparatus of the nuclear power generation facility unit 811 is provided with an air pipeline 181 for preventing sinking of the hull and an emergency engine 226 for extending the prevention of hull sinking prevention. (628) for the identification of the position of the double pipe structure tank, which is designed to prevent access to other ships during the safe marine assembly period, and at the same time, the rope for dismantling rope 629 and rope connecting knot claws 630 and at the same time the emergency step 631 facility into the block pylon 116 is provided with elevator alibault 636 and double structure block tank holding tank upper barge hull 591), a discharge suction vacuum pump (635) for adjusting the balance between the conveyor (633) for mineral and mechanical equipment conveying equipment and the lower tank barge hull (592) of the holding tank, and an air intake The air supply lines 634 of the inlet and outlet units, and at the same time, the distribution input unit parts of the nuclear power generation facility 811 are installed at marine vessel manufacturing plants and industrial sites in the heavy industry, The tugboat 666 is provided with a conveyor 633 for a mechanical equipment conveying device and a boom barge rubber balloon 628 for controlling the elevation of the barge line. Nuclear waste treatment of nuclear power plants at Fushy before the safety operation Nuclear power plants (811) distributing and input devices constitute a continuous nuclear power plant;
The distribution input apparatus of the nuclear power generation facility unit 811 is a nuclear waste management system in which the nuclear power generation facility of the nuclear power plant can be prevented from exploding without being affected by earthquakes and tsunamis. Nuclear waste disposal and dispensing equipment that prevents pollution of the environment is a double structure block tank in which nuclear reactors in a nuclear fuel chamber are prevented from exploding. Nuclear reactor facilities In nuclear power plants, nuclear reactors formed from the first wall to the fifth wall The double structure block tank is formed of a plurality of double structure block tanks in a storage tank, and the double structure block tank is formed of an inner block tank and outer block tanks to prevent the explosion of the reactor. To ensure the safety of a nuclear power plant so that continuous operation can be carried out, and at the same time, And a nuclear explosion-proof double structure block tank dust collector (794) for preparing a repair safety guarantee and for treating the nuclear waste, the nuclear power plant connecting shaft
The nuclear reactor waste 224 that is exploded into the block piping line 74 passes through the double structure block tank reactor nuclear reactor facility to prevent the nuclear reactor room from exploding into the nuclear reactor facility body, And a robot 700 for cutting the nuclear reactor waste by the remote control during the decommissioning of the reactor facility of the nuclear power plant having a shortened life span at the same time. The internal explosion of the reactor pressure vessel 813 The safety valves 472 are closed so that the safety valves 472 are closed. In addition, when the reactor facilities are operated, the remote control device robots 700 In addition, it is necessary to establish the continuous operation of nuclear reactors for the nuclear waste disposal of marine nuclear power plants before the safety operation of reactor facilities, (1) of the nuclear power plant in which the nuclear reactor internal and external nuclear reactors are not detonated, and the nuclear waste And the nuclear power plant (671), the docking buoyancy regulator, the nuclear waste disposal and distribution system, and the nuclear reactor facility. The connection axis of the nuclear waste disposal dispenser equipment of the facility;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and marine marine power plant (672) and nuclear reactor plant main body (1) Nuclear power generation plant (811) dual structure block tank dust collector The nuclear waste disposal and dispensing device of the reactor facility for the hull safety equipment constituting the connection axis position of the facility,
The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean, and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control to Prevent Explosion Dual Structure Block Tank Dust Collector (794) Nuclear Waste Treatment Unit Configuration be made for continuous operation of nuclear power plants operating in the distribution chute and;
The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility 811 includes water leaking from the valve of the nuclear power plant 672 and water in the building inside the nuclear power plant main body 1 of the floating nuclear power plant of the marine power plant The washing water in the case where the regenerated liquid of the ion exchange resin is a liquid is collected in the storage tank 216 and the nuclear waste disposal filtration is provided by the filter 217. At the same time, ) To measure the radioactivity and to confirm that there is no harm, water other than the washing water to be sent to the sea together with the cooling seawater is purified by the filter (217), while the filtered water and the distilled water At the same time as the reactor coolant is provided, the nuclear waste disposal and dispensing facility is equipped with monitoring posts 219 for monitoring the nuclear reactor facility of the floating nuclear power plant of a marine power plant 1) To prevent nuclear radiation contamination both inside and outside. At the same time, nuclear waste disposal and dispensing equipment is installed in the reactor main body (1) of the nuclear power plant, and a mooring device And diving buoyancy control device and nuclear waste disposal unit and nuclear reactor facility safety operation Fusi Nuclear Power Plant Division (811) double-structure block tank Dust Collector Nuclear waste disposal unit of nuclear reactor waste disposal unit
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the land and marine marine power plant (672) and nuclear reactor plant main body (1) Nuclear power generation plant part (811) dual structure block tank dust collector, The nuclear waste disposal and dispensing device of the reactor facility for the hull safety equipment constituting the connection axis position of the facility,
The nuclear waste disposal and dispensing apparatus of the reactor facility of the nuclear power generation facility 811 includes a nuclear power plant 672 of a marine power plant and a reactor structure of nuclear reactor leakage control double structure block tank dust collector 794), and a nuclear fuel explosion control distribution input device. It is also possible to install a plurality of nuclear reactor facilities on the barge of an anti-sunken double structure block tank of the ocean, and to prevent the earthquake and tsunami Nuclear power plant (811) Nuclear waste disposal system installed at 40m above the sea level to prevent the sinking Prevent sinking type barge line reactor facility Safe operation Reactor facility to establish safe operation facility Safety facility operation device Nuclear power Nuclear Power Generation in Nuclear Power Plants Nuclear Radiation Leakage Control to Prevent Explosion of Multiple Nuclear Reactor Facilities Dual Structure Block Tank House Configuration be made up the original operation to the exchanger 794 nuclear waste disposal distribution chute of a nuclear reactor plant, and;
In the nuclear waste disposal and dispensing apparatus of the reactor facility of the nuclear power generation facility 811, when the air contained in the inside of the building and the water contained in the inside of the reactor is gas, an activated film gas which weakens the radioactivity when the pressurized water reactor is operated The ventilation system of the power plant is provided with a plurality of symmetrical filters 214 for discharging the purified air to the outside air by the hold-up device 213 and discharging all of the ventilated air from the exhaust tower 215, (1) Nuclear waste treatment (811) of the nuclear power plant (811), in which nuclear waste disposal (224) treatment system is used to prevent nuclear radiation contamination inside and outside the reactor main body The distribution dispenser is provided with a nuclear power plant (672) inside the nuclear reactor main body (1) of the floating nuclear power plant of the marine nuclear power plant, At the same time, when the ion exchange resin and the filter medium are solid, the filter sludge and the used resin liquid are supplied to the storage tank 216 in the form of nuclear waste The paper and cloth contaminated with nuclear radioactivity are compressed to provide volume compression. At the same time, all of the nuclear waste is solidified into concrete and filled in the drum 220, and the inside of the nuclear waste disposal building site The nuclear waste storage 224 and the nuclear waste storage building 332 and the monitoring monitoring posts 219 are provided for the nuclear waste disposal of the forklift truck, 593,594,595) Nuclear power plant main body (1) Prevention of nuclear radiation contamination both inside and outside of a marine power station Mooring device and diving buoyancy system After the nuclear waste disposal apparatus and a distribution chute and before the reactor equipment safe operation of the reactor equipment at nuclear power seolbibu 811 double structure block dust collector tank of a nuclear reactor plant nuclear waste processing plant distribution chute in connection shaft;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and reactor body of nuclear power plant (1) Nuclear power plant (811) of nuclear power plant Nuclear waste treatment section (811a) Nuclear waste at the connection axis of the nuclear waste disposal facility of the facility Nuclear waste disposal facility of the reactor facility for the hull safety facility constituting the treatment of the nuclear waste (224) into the nuclear fuel cycle of the nuclear fuel industry,
The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear radiation leakage control dual structure block tank collector 794 into the nuclear power plant 672 of the marine power plant and the reactor facility body 1 of the nuclear power plant, ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control that Multiple Nuclear Reactors Can not Explode Dual Structure Block Tank Dust Collector (794) The nuclear power plant (811) 's nuclear waste disposal and dispensing facility is configured to operate the nuclear power plant;
The nuclear fuel cycle of the nuclear waste fuel plant of the nuclear waste treatment facility includes the nuclear fuel plant 593,594,595 of the ocean power plant and the nuclear fuel 683 used in the nuclear reactor main body 1 of the nuclear power plant, Uranium 812 can be processed at uranium fluoride 812 in a conversion plant 229 that allows for the processing of nuclear fuel 683 at the reprocessing plant 228, In the nuclear fuel cycle of the industry, as the enrichment plant 230, the nuclear fuel 683 is transferred to the carrier, while at the same time the uranium fluoride 812 is converted to uranium dioxide at the conversion plant 229, At the same time, the nuclear fuel cycle of the nuclear waste fuel industry is processed in the form of pellets 683 to provide a fuel rod 689. At the same time, the plutonium 801 processed in the reprocessing plant is fed to the conversion / processing plant 231 At the same time, these reprocessed fuel rods 689 again transport the nuclear fuel 683 to the nuclear power plant 672 by means of a carrier forklift, and at the same time, the nuclear power plant 672 , A reprocessing plant 228 and a concentration plant 230 and a conversion plant 229 and a conversion and processing plant 231 are installed at the top of a sea sinking anti-sinking type floating barge deck deck at the top of the sea, Connection axis; and
Nuclear waste (224) disposal unit, the nuclear waste (224) treatment of the nuclear fuel industry of the nuclear fuel industry preventing the contamination of the nuclear radiation from inside and outside into the reactor main body (1) of the nuclear power plant, (794), and a mooring device, a diving buoyancy control device, and a nuclear waste disposal dispenser installed in a nuclear power plant (672) of a marine power plant, Fusi Nuclear Power Generation Facilities (811) to connect nuclear waste disposal dispenser equipment of reactor facilities;
A nuclear waste disposal facility of a marine shipbuilding factory capable of disassembly and disassembly, and a nuclear waste disposal facility of the nuclear waste disposal facility. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and reactor body of nuclear power plant (1) Nuclear power plant (811) of nuclear power plant Nuclear waste treatment section (811a) Nuclear waste at the connection axis of the nuclear waste disposal facility of the facility Nuclear waste disposal facility of the reactor facility for the hull safety facility constituting the treatment of the nuclear waste (224) into the nuclear fuel cycle of the nuclear fuel industry,
The nuclear waste disposal and dispensing apparatus of the nuclear power generation facility unit 811 is provided with a nuclear radiation leakage control dual structure block tank collector 794 into the nuclear power plant 672 of the marine power plant and the reactor facility body 1 of the nuclear power plant, ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Reactor Facility Nuclear waste disposal and dispensing equipment to operate the nuclear power plant;
The nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a comprising the nuclear power plant floating support 593,594,595 nuclear power plant 672 and the nuclear power generation facility unit 811 of the nuclear power plant main body 1 of the nuclear power plant,
The nuclear waste treatment facility of the nuclear power generation nuclear waste treatment unit 811a includes the nuclear waste treatment unit 1 of the nuclear power plant and the nuclear power plant 672 of the marine power station 593,594,595, (224) include permanent heavy nuclear waste disposal facility equipment with a long half-life, including construction machine heavy equipment hoe (877) and excavator (845) to provide nuclear waste (224) And at the same time constituting the nuclear waste disposal system as construction equipment with the nuclear waste disposal facility facility 224 and at the same time the nuclear waste disposal facility facility constituting the conversion from the nuclear reactor 811 to another material , The construction of nuclear waste (224) according to the depth of the strata and the depth of the seabed is carried out by construction machines. At the same time, nuclear waste disposal is carried out by the construction equipment heavy equipment hire (877) and excavator Be configured at the same time while the nuclear waste disposal apparatus, the vessel, made be configured nuclear waste in shipping the double tube structure, drum 220 containing the nuclear waste to the buried region in the nuclear waste 224 apparatus vessels and equipment;
The nuclear waste disposal apparatus transportation facility of the nuclear power generation nuclear waste disposal unit 811a includes a double pipe structure drum 601 containing nuclear waste at the upper end of the barge deck deck 591 provided with the space rocket 612 and the space rocket launching rods 646, (224) processing unit space rocket (612) and a space rocket launching unit (646) transportation facility, which is configured to transmit the nuclear waste (220) to the space rocket (612) (593,594,595) Nuclear power plants (672) and reactor facilities of nuclear power plants (1) Nuclear waste (224) treatment device inside and outside to prevent nuclear radioactive contamination Space rockets (612) and space rocket launchers (646) Transportation facilities;
And the nuclear waste disposal system comprises a nuclear waste disposal facility for nuclear waste disposal. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and reactor body of nuclear power plant (1) Nuclear power plant (811) of nuclear power plant Nuclear waste treatment section (811a) Nuclear waste in the connection shaft of the facility's nuclear waste disposal dispenser equipment Nuclear waste disposal dispatch equipment remodeling facility of the nuclear facility safety facility nuclear waste facility (224) that constitutes the nuclear fuel cycle of the nuclear fuel industry,
The nuclear waste disposal and dispensing device remodeling facility of the reactor facility of the nuclear power generation facility unit 811 is provided with a nuclear radiation leakage control dual structure block 671, A nuclear waste disposal dispensing apparatus having a tank dust collector 794 and a nuclear fuel explosion control dispensing apparatus. The method includes the steps of providing a plurality of nuclear reactor facilities to the barge of an anti-sunken double structure block tank of the ocean, (811) at 40m above sea level to prevent the restriction of the nuclear power plant and the submerged-type barge line reactor facility with the position setting of the distribution input unit. Nuclear power plant nuclear waste disposal unit (811a) nuclear power plant nuclear power generation nuclear power plant can not explode It made be configured to operate nuclear power plants with the nuclear waste disposal facilities of the distribution chute renovation saneung leakage control double tank structure block dust collector 794 and the reactor equipment;
The nuclear reactor waste treatment unit 811a of the nuclear power generation nuclear waste treatment facility 811a is installed in the nuclear power plant main body 1 of the floating nuclear power plant 593,594,595 of the marine nuclear power plant, A connection axis of the nuclear power plant 811 for providing the shutoff of the reactor piping line to the safety valve 472 and the operation of the boiler 783 for the thermal power generation at the same time in preparation for the time period of 3 months or more,
The nuclear power plant nuclear waste disposal unit (811a) has a connection structure to supply emergency power generation by supplying steam of high temperature and high pressure. (1) To ensure the safety of nuclear power plants by safe and continuous operation of nuclear power plants, and to provide for the renovation of reactor facilities with the prevention of radioactive contamination at the time of renovation of reactor facilities, (593,594,595) Installed thermal power generation facilities inside the marine power plant, and the mooring device and diving buoyancy control device of nuclear power plant (672) and the nuclear power plant The connection axis of the nuclear waste processing thermal power generation facility of the reactor facility in the facility unit 811;
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the above-mentioned offshore and offshore marine power plants and reactor body of nuclear power plant (1) Nuclear power plant (811) of nuclear power plant Nuclear waste treatment section (811a) Nuclear waste in the connection shaft of the facility's nuclear waste disposal dispenser equipment Nuclear waste disposal dispatch equipment remodeling facility of the nuclear facility safety facility nuclear waste facility (224) which constitutes the nuclear fuel cycle of the nuclear fuel industry,
The distribution input device of the nuclear power generation facility unit 811 is connected to the floating power plant 672 of the marine power plant and the nuclear power plant 811 of the nuclear power plant in the reactor main body 1,
A nuclear waste disposal unit 811a is connected to the nuclear waste disposal dispensing apparatus having the nuclear radiation leakage control dual structure block tank dust collector 794 and the nuclear fuel explosion control dispensing apparatus. It is necessary to provide the installation position on the barge line of the double structural block tank and the installation position of the distribution and input device of the nuclear power generation facility 811 at the upper 40 m of the sea level so as not to be restricted by the weather condition of the earthquake and tsunami, Nuclear power plant Nuclear power plant Nuclear power generation Nuclear power generation Nuclear radiation leak control to prevent the explosion of a large number of nuclear power plants Double structure block tank dust collector (794) Reactor facility To operate the nuclear power plant;
The reactor facility of the nuclear power generation nuclear waste treatment section 811a constituted by the nuclear power plant floating support 593,594,595 nuclear power plant 672 and the nuclear power generation facility section 811 of the nuclear power plant main body 1 of the nuclear power plant,
In the reactor facility of the nuclear power plant of the nuclear power generation nuclear waste treatment section (811a), a 1-meter-thick natural loess soil and a disaster prevention yarn are placed on the deck deck floor of the floating deck detoxification around the launching platform of the satellite and the space rocket, At the same time, a 60m diameter round ocher block disaster prevention wall was installed at a height of 3m and a height of 15m, and at the same time a satellite and a space rocket were fired at a satellite launch pad and a space rocket launch pad formed at the top of a deck deck When the huge amount of fuel burned to obtain propulsion is generated, the combustion heat of high temperature and high pressure generated by the emission of satellite and space rocket at the same time as the high temperature is generated is set as a 60 m diameter round ocher block fire prevention wall at high temperature and high pressure A deck deck is equipped with a hull safety device to hold it firmly, Replacement Tower Cranes Seiso Crane (942) is 60m in diameter and 15m in height with a height of 15m. The block tank hull is disassembled and coupled to a double pipe structure tank bridge bridge construction saddle formwork (617), and the satellite launch pad and space rocket launch pad The manganese nodule (909) formed at the top of the deck deck is provided on the deck deck with a thickness of 2 m. However, after the satellite and the space rocket are fired, (617), and at the same time, the vessel movement control device is provided at the position of the depth of 10 meters or the depth of the sea, and at the same time, the movement of the hull is dependent on the length of the puncture, The isocrane boom zone 942, the hydraulic rotary cylinder machine 619, and the hydraulic cylinder machine 624, The ship's shelter can be moved to the ship's shelter if the hull is retracted and both front and rear sides are simultaneously provided with a tailwind. At the same time, the ship shelter is moved to the oceanic power plant facility (593,594,595) And anchors and anchor chains are provided inside the nuclear reactor main body 1 of the nuclear power plant, and the mooring device, the diving buoyancy control device, and the nuclear waste disposal processing provided in the nuclear power plant 672 of the marine power station levitating station (593,594,595) Before the safety operation of the nuclear reactor facility of the nuclear reactor and the nuclear reactor facility, the connection axis of the reactor facility of the nuclear reactor nuclear waste treatment section (811a)
Which is composed of two or more nuclear reactors as a disassembly-connectable structure at a marine shipbuilding factory. The dual structure of a nuclear waste treatment nuclear power plant for nuclear power plants, a reactor for high-speed propagation reactor, a nuclear waste disposal nuclear power plant, Structure Fast Reactor Reactor Facility. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the marine power plant and the inside of the nuclear reactor facility main body (1) of the nuclear power plant The inside of the nuclear reactor power plant (811) The fast breeder reactor facility (FBR) 838, which constitutes a dual structure block tank precipitator 794 in the form of statistics,
The FBR 838 of the nuclear power plant 811a is connected to the nuclear reactor waste reactor 811a of the nuclear power plant 811 to construct a dual structural block tank collector 794 for nuclear waste treatment. A nuclear waste disposal and dispensing apparatus having a double structure block tank precipitator 794 in the form of a nuclear radiation leakage control source statistic in a nuclear reactor power plant 672 and a nuclear reactor main body 1 of a nuclear power plant, Explosion control dispensing device In order to install a large number of reactor facilities in the marine anti-sunken double structure block tanks and floodgates, and to prevent the earthquake and tsunami from being affected by weather conditions, ) Of the submerged barge line equipped with the installation position of the dispensing device. The nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility section 811 which prevents the plurality of nuclear power generation reactors from exploding into the nuclear power plant 672 of the apparatus and the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant, (FBR, 838) constituting the nuclear radiation leak control dual structure block tank dust collector (794) provided on the connection axis,
The fast breeder reactor facility (FBR) 838 constituting the connection shaft of the nuclear power generation nuclear waste processing unit 811a of the nuclear power generation facility unit 811 is connected to the floating nuclear power plant 672 of the ocean power plant and the reactor facility body (FBR) 838 constructed in the double structure block tank precipitator 794 of the nuclear power generation facility unit 811 inside the fuel rod 689 at the central portion of the fuel rod 689 to about 20% of the enriched uranium 235 (812) The enriched enriched uranium 812 and the natural uranium 812 and the plutonium 812 are mixed and the fuel rod 689 is surrounded by natural uranium 812 at the same time, The liquid metal sodium is used for the coolant 816 and the plutonium 801 is provided for the purpose of preparing the plutonium 801 for entering or leaving the uranium 238 653a to the plutonium 801, At the same time, It is not necessary to reduce the neutron 675 to the reactor FBR 838 so that the moderator 676 is not contained and the heat generated in the reactor installation in the intermediate heat exchanger 657 is transferred to the intermediate heat exchanger 657 At the same time, the heat exchanger 658 transforms the water 654 into steam 780 as heat of the liquid sodium to form a nuclear power plant while the steam turbine 267 provides rotation, A dual structural block tank dust collector 794 in the form of raw statistics for the treatment of nuclear waste on the connection axis of the nuclear power generation nuclear waste treatment section 811a of the nuclear power generation facility 811 inside the nuclear power plant main body 1 of the floating planted nuclear power plant of the power plant (FBR, 838) connecting shaft which constitutes a high-speed reactor,
The double structure block piping line (74) for establishing the position of the fast breeder reactor facility (FBR, 838) inside the double structure block tank dust collector (794) of the connecting shaft of the nuclear power generation nuclear waste processing unit (811a) The temperature sensor of the safety valve of the safety valve detects the temperature of the inside of the nuclear reactor in the range of 700 to 800 degrees Celsius When the dangerous state of the pressure sensor 813 is reached, the temperature and pressure sensors provide an alarm message to the computer in the safety control room, and at the same time, As the block piping line 74a passes through the explosive nuclear waste and nuclear waste is stored in each of the double structure block tank dust collector 794, (813) a temperature pressure sensing sensor safety valve (472) connected to the bottom internal double structure block tank provides an opening, while at the same time an outer block piping line (74b) is provided with a fuel explosion- A thermocouple thermometer sensor switch 103 having a connection structure with an automatic charging device flashing warning lamp 99, a pressure gauge 101 and a temperature sensing sensor bimetal 102 and a level pressure switch 104 for flow rate check operation, And a safety valve 472 of a pipeline automatic pneumatic valve conveying device 916. At the same time, a connection structure is provided at the upper end of the reactor building 688 at a predetermined angle of 45 degrees Holes are formed by a laser cutting machine and a construction machine drilling machine. At the same time, a double pipe structure piping line 74 is formed in a plurality of through holes, while a plurality of block piping lines 74 The front valve 472 is provided with flange connection connections by means of bolts 24 and nuts 25 and gaskets 32 and at the same time providing a connection to the reactor building 688 along the outer wall surface of the reactor building 688 (794) One piece of equipment includes a nuclear waste disposal dispenser and nuclear fuel (683) explosion control unit which is combined with an external block tank (599) for nuclear waste disposal and storage and a radiation type connection structure. The reactor is installed in the reactor core inside the reactor core (681) and outside the reactor core (681). Prevention of nuclear fuel explosion immediately before the reactor explosion. Connected to the nuclear reactor main body (1) (683) explosion-proof control appliances which are provided as a structure and at the same time contain explosion-proof control appliances for nuclear reactor power plant nuclear reactor main body (1) And dual structure block tank dust collector (794) for the control of the nuclear radiation leakage of the nuclear reactor facility, but also to prevent explosion of nuclear fuel in the reactor main body (1) of the floating nuclear power plant of the marine power plant at the same time Block tank Dust collector (794) The nuclear reactor facility is equipped with a fast breeder reactor facility (FBR, 838) to construct the nuclear power plant, and a mooring device and diving buoyancy control Equipment and Nuclear Waste Treatment Dispensers and Reactor Facilities Nuclear Reactor Facilities Safety Operation Fusi Nuclear Power Plant Division (811) Dual Structure Block Tank Collector with Nuclear Radiation Leakage Control of Nuclear Reactor Facilities (794) A connection shaft for supplying a nuclear reactor nuclear waste treatment unit 811a of a power generation facility unit 811 and a reactor reactor facility (FBR, 838) for a fast breeder reactor;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
The facilities of the disaster prevention apparatus constituted inside the connection shaft include a flood control unit 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 inside a reactor facility main body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) The nuclear power plant is operated by the facilities of the disaster prevention apparatus to be constructed;
Nuclear Waste Treatment of Nuclear Power Plant (811) Dual Structure Block Tank Dust Collector Installations of offshore and offshore marine power plants equipped with nuclear reactors (593,594,595) Nuclear power plants (672) and nuclear reactor plant main body (1) And
In the disaster prevention apparatus equipment constructed inside the connection shaft, a disaster prevention line to which typhoons are latent is provided with an injection nozzle, a diaphragm rubber balloon 628, a rope rope 629, rope knot hooks 630 ), A marine cable car (256), an unmanned camera (184), a high pressure type multi-stage disaster prevention pump (8), a double structure nozzle hose and a double structure fire hose (9) The satellite weather forecast information collecting machine 960 of the weathering air bag 130 and the weather forecasting 958 and the electronic control unit of the disaster control pump control system and the control system 150 and the air supply (942) Connected structure It is constituted by facilities of disaster prevention device and at the same time disaster prevention facilities are equipped with facilities for disaster such as earthlamp and coastal cumulonimbus and cataclysm in which global warming phenomenon is resolved. At the same time, facilities for sound vibration and frequency disaster prevention equipment are provided, and at the same time, facilities for disaster prevention equipment are provided with facility facilities for disaster prevention equipment in accordance with the power of wind equivalent to artificial waterfall falling sound, And a radial type dispersing and disbursing device, a submarine mineral deposit bag 130, a substitute goods sail 959, and a seesaw crane of a tower crane substitute crane (942) to provide the discharge of water over the sea and over the sea. At the same time, the sound emission frequency and sound wave vibration wave that substitute the radiation type dispersing and disrupting device are transmitted. At the same time, the facilities of the disaster prevention device are equipped with the wind along with the wind above the sea surface, and prevent the occurrence of the severe typhoon, (672) of the marine power plant, and a lightning rod (701) which is positioned at the top of the deck deck upper block block tower (116) of the marine power plant. The location of the lightning rod 500 on the rooftop of the control tower of the mooring tower 644 is provided in the lightning rod 500 of the block pylon tower 116, Weather observation equipment Radar (840) A lightning rod (500) that keeps the hull from lightning and lightning on the control tower is provided with peaceful earth environment preservation. In addition, a reactor structure disaster prevention device of a nuclear power plant with double structure block tank reactor At the same time, it is necessary to prepare a disaster prevention structure inside the reactor main body (1) of a nuclear power plant, and to install a disaster prevention structure Mooring device, diving buoyancy control device, nuclear waste disposal dispenser and nuclear reactor facilities installed in the power plant 672 Nuclear waste disposal facility in Fusi Nuclear Power Plant (811) before safety operation The facility connection axis of the disaster prevention device;
A nuclear reactor plant, a nuclear reactor plant, a nuclear reactor plant, and a nuclear reactor plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
The distribution input apparatus of the nuclear power generation facility unit 811 is provided with a floating nuclear plant power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank precipitator 794 inside a reactor facility body 1 of a nuclear power plant Nuclear waste disposal dispenser and nuclear fuel explosion control distribution dispenser A number of nuclear reactor facilities are installed on the barge of an anti-sinking double structural block tank of the ocean and a sea level top surface which is not restricted by earthquake and tsunami weather conditions. Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear power plant Nuclear Radiation Leakage Control to Prevent Explosion Dual Structure Block Tank Dust Collector (794) Consists of Reactor Facility Connecting Shaft It is configured to be made up the original operation of the equipment and emergency devices;
The facilities of the nuclear power plant of the marine power plant (593,594,595) and the nuclear power plant of the nuclear power plant (1) include the nuclear power plant (811) A connection shaft (1) of the facility body
In the installation of the disaster prevention device of the nuclear power plant 811 constituting the inside of the connection shaft of the reactor installation main body 1 of the floating support type nuclear power plant, the number of injections for providing the ejection through the gap between the dual structure injection nozzles is naturally At the same time, the disaster prevention apparatus of the nuclear power generation facility unit 811 is provided with a shuttlecock for reducing the power of the wind, The air compressor 80 forms a piston-type air compressor 80 which is operative by an electronic control unit 88 and which is connected to the pressure reducing valve 85 and the safety valve 259 without an electronic control unit 88 The motor cover 252 and the motor cover 250 together with the belt cover 261 and the air suction filter 262 together with the first pressure check sensor 86 and the second pressure check sensor 87, And an oil cooler 151 are formed, The tank of the oil cooler 151 is provided with a cooling water inlet 287 and attached to the upper end of the channel base of the bed frame 286 to produce air together with the injection nozzle 10, The equipment of the disaster prevention device of the nuclear power plant 811 having the combination of the hose 947 and the high pressure hose 190 with the coupling 29 of the high pressure hose connection and the latent power of the typhoon at the same time, The disaster prevention device is installed at the upper and lower sides of the sea surface where the airflow 925 and the downward airflow 926 are controlled together with the yellow sand fine dust so that the disaster prevention and control are simultaneously performed. There are several manhole covers 152, several hatch covers 153 and several fire doors 154, which prevent the sailing vessel from losing its restoring power freely from a natural disaster of the typhoon, And the safety regulations of the International Maritime Safety Association are faithfully executed. At the same time, the nuclear power generation facilities 811, The discharge jetting number 38 for continuously dropping the jetting water gap is provided at the dropping point of the jetting jetting number 38 for dropping the power of the typhoon, With the number of ejection nozzles 38 forming a continuous falling drop, and at the same time, the same level of artificial waterfall roaring, which allows the power of the typhoon to be subdued, This scene, in which a strong typhoon is transformed into a warm wind, but at the same time, the power of the typhoon is reduced, is replaced by an unmanned camera (184) (593,594,595) of the marine power plant which was sent from the radar meteorological observation center to control the upward airflow (925) and the downward airflow (926) of the typhoon together with the dust dust. The unmanned camera 184 and the weather observation equipment radiosonde weather observation radar 840 are mounted inside the basket 1 inside the main body 1 and the basket 42 on which the lower end fillet is mounted, A rubber tube 947 for introducing air for the inside of the container for the inflow control device provided in a connection structure to the bottom line 945 and the submarine line wiring 946 and a furnace 948 of the furnace 948 for continuous operation of the furnace 948 Nuclear Radiation Leakage Control by the Bricks 948a In the interior of the double structure block tank dust collector 794, provision of the disaster prevention device of the nuclear power generation facility 811 is provided with the input of the raw material bricks 948a of the blast furnace 948, I (949) for diving buoyancy control, a thermocouple thermometer switch (950) for thermo-sensor, and a seesaw crane boom zone (942) for tow-crane replacement tower crane A large hydraulic power generator seesaw facility 944 is connected to the hydraulic aerator 943a of the marine seesaw hydroelectric power plant 943, the Phelpton aberger 943b for a large hydroelectric power plant, and the Francis turbines 943c for a large hydroelectric power plant, (952) of the non-powered pump for the energy control device of the water, which is provided with the hydraulic power supply and the connecting structure, and the hatch basket (951) and the military equipment submarine (953) A laser cutting machine 954 is provided to check the maintenance status of the facility facilities of the disaster prevention apparatus of the nuclear power plant (811) of the main body of the nuclear power plant of the marine power plant (1) (955), which is more powerful than nuclear bombs, is equipped with facilities for disaster prevention at the nuclear power plant (811). At the same time, the World War II, the Korean War and the Cheonan This is the first time that a group of military photographers and imitated statues, who have gathered the characters of the war criminals who made all the military actions and act factors of the act to promote the Yeonpyeong Island bombing and nuclear frenzy experiment, The center of the triangle The 1,200 km radius from the center of the Korean peninsula Coordinates set within the range of 2,400 km in diameter formed inside and outside the United Nations include 38 ° 20 '00 ° north latitude center of the Korean peninsula and 127 ° 17' Kangwon-do, Gangwon-do, Gangwon-eup, Gangsan-ri, 190 In the center of the Korean peninsula in the Imamyeon area, a 200-meter radius inside is called Northeast Asia No. 1, It is planned to set up a new concept of one of the United Nations' national capitals as an area of 1000 ㎢, while at the same time, a radius of 400 meters and a radius of 1 iri from the surface of the peninsula, The distance range is called Northeast Asia 1500 and the range of 1200 km from the center of the peninsula is called Northeast Asia 3000 and it is confirmed that the old ancestors' 811 are equipped with windmill wind turbine 957a for a wind power generator of a offshore wind power plant 957, disaster prevention nozzles 945 by an underground line and submarine line wiring 946, ) And the satellite weather forecast information collection machine (960) to the inside of the nuclear reactor facility main body (1) of the nuclear power plant, (593,594,595) installed at the nuclear power plant (672), the docking buoyancy regulator and the nuclear waste disposal and distribution system, and the nuclear reactor facility safety operation of the nuclear reactor facilities. The connection axis of the disaster prevention device of the reactor facility;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
The facilities of the nuclear disaster prevention apparatus of the nuclear power generation facility 811 constituting the inside of the connection shaft of the nuclear power plant 1 include the floating nuclear power plant 672 of the offshore power plant and the nuclear power plant 671 of the nuclear power plant Nuclear Waste Dispensing and Discharging Apparatus Having Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector 794 and Nuclear Fuel Explosion Control Distribution Dispensing Apparatus A plurality of nuclear reactor facilities are installed on the barge of an anti- And 40m at the top of the sea level so as not to be restricted by the weather conditions of earthquakes and tsunamis. It is equipped with the installation position of the distribution input device of the nuclear power plant (811) to prevent sinking of the barge line reactor facility. Nuclear reactors that form a nuclear reactor safety operation device Nuclear power plant nuclear reactors that prevent multiple nuclear reactors from exploding Double structure block tank dust collector (794) Reactor system consists of disassembly device inside the connecting shaft to constitute the operation of the nuclear power plant;
The facilities of the disaster prevention device of the nuclear power plant 811 constituted by the floating power plant 593, 594, 595 nuclear power plant 672 of the marine power plant and the nuclear power plant main body 1 of the nuclear power plant,
(593,594,595) of the marine power plant; (1) the connecting shaft of the nuclear reactor main body of the nuclear power plant; and
The facilities of the disaster prevention apparatus constituting the inside of the nuclear reactor connection axis include the nuclear reactor main body 1 of the nuclear power plant, the Vladivostok, the Uleungdo, the Dokdo and the Pohang in Russia according to the marine sovereign power line, (941), and at the same time, Yeosu and Jeju Island are connected to the Nuclear Waste Treatment Double Structure Block Tank Marine Tunnel Traffic System (941). At the same time, Pyeongtaek, Baekryeongdo and Shandong Peninsula Nuclear Waste Treatment Double Structure Block Tank Provides a connection to the Marine Tunnel Traffic System (941) and provides connections to Pohang and Japan's downstream areas through the nuclear waste disposal dual structure block tank marine tunnel transport system (941) It is necessary to establish the foundation of the Korean federal government, and at the same time to transform it into a one-day living zone, while at the same time, The rope knot claws 630 formed in the fishing pier rubber balloon and the wire rope net (19) in the fishery area provided by the equipment for military defense, It is like a kelp in the sea, so illegal fishing boats provide a net throw to fishing grounds. At the same time, rope knot hooks (630) can be used to limit the entry of illegal fishing boats (593,594,595) at the ocean power plant (673), the diving buoyancy control device and the nuclear waste at the nuclear power plant (672) of the ocean power plant. Nuclear waste treatment of FUJI Nuclear Power Plant (811) before safety operation of nuclear reactor facility installation and dispensing equipment Block precipitator tank reactor plant the land and support of the marine power plant in the ocean sikdok nuclear power plant and equipment connection of the emergency device which consists of a reactor internal equipment body (1) of a nuclear power plant provided with a connecting shaft axis;
As a connection structure capable of disassembling and coupling in a marine vessel manufacturing factory. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
(593,594,595) of the above-mentioned marine power plant The facilities of the nuclear power generation facility (811) constituting the inside of the main shaft of the nuclear power plant (1) include facilities of the floating power plant of the marine power plant (672) Nuclear waste treatment dispensing apparatus and nuclear fuel explosion control dispensing apparatus having dual structure block tank dust collector (794) for controlling nuclear radiation leakage into the facility body (1) A plurality of nuclear reactor facilities are connected to a barge And the installation position of the distribution and input device of the nuclear power plant (811) at the top of the sea level (40m above sea level) so as not to be restricted by the weather conditions of the earthquake and tsunami. Nuclear reactor safety equipment for safe operation of Fusi Nuclear power plant safety reactors Many nuclear reactors of nuclear power plants can not explode Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Configured to operate nuclear reactors;
The facility of the disaster prevention device of the nuclear power generation facility 811 constituted by the nuclear power plant 672 of the ocean power plant and the nuclear power plant main body 1 of the nuclear power plant includes facilities of the marine power plant (593,594,595) Nuclear reactor plant main body (1) Connecting axis
The connection axis of the reactor main body 1 of the nuclear power plant is limited to the range of up to 29 km from the ground inside the reactor main body 1 of the nuclear power plant of the nuclear power plant 672 of the floating power plant of the marine power plant At the same time, several floodplains formed above the sea level above sea level 5 and 38 ° above the sea of the East Sea were equipped with military sensor sensors to prevent the production of military equipment. It also has a sensor detection device, but at the same time, it has a restriction to make nuclear facilities of Pyongando and Hamgyeongdo helpless. At the same time, when a nuclear missile is fired, it is formed as a defensive missile attached to the net at the firing position, To automatically shoot down enemy territory to launch its own nuclear missile At the same time, the end of the nuclear weapons buildup was immediately followed by the westward sea level in the sea above the sea and the 38th parallel to the sea in the East Sea. (958), which is more powerful than nuclear bombs, and which is more powerful than nuclear bombs, will be re-installed in each region within a radius of 1200km from the center of the Korean peninsula, And at the same time, it is located outside the area of 29 km above the ground. It is equipped with a sensor sensor for military defense and a disaster prevention netting device formed in a large number of flood control stations in the reactor main body 1 of a nuclear power plant in the ocean and airspace, (593,594,595) Mooring devices and diving buoyancy tanks formed at nuclear power plant (672) Equipment and Nuclear Waste Treatment Dispensing Equipment and Nuclear Reactor Facilities for Safe Operation of Nuclear Reactors Nuclear Waste Treatment of Nuclear Reactor Facilities of Reactor Facilities (811) (593,594,595) Nuclear power plant (672) of the offshore and offshore marine power plants and the connection axis of the disaster prevention device consisting of the inside of the reactor facility main body (1) of the nuclear power plant;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
The facilities of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power generation facility include a floating nuclear power plant 672 of a marine power plant and a nuclear radiation leakage control dual structure block tank dust collector 794 ) Nuclear Waste Dispensing and Discharging Apparatus and Nuclear Fuel Explosion Control Distribution Discharging Apparatus A number of nuclear reactors are installed on the barge of an anti-sinking double structure block tank of the ocean and are not restricted by weather conditions of earthquakes and tsunamis. Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Power Plant Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Configuration be made movable in a nuclear plant disaster prevention apparatus consists of internal equipment, and the connecting shaft;
The facilities of the nuclear power plant of the marine power plant 672 and the nuclear power plant 811 of the nuclear power plant 1 include the nuclear power plant 593,594,595 of the above ocean power plant, A connecting shaft (1) of the reactor installation main body
The vertical structure of the typhoon is provided together with the discharge type of jet 38 of the disaster prevention line which is disposed inside the facilities of the nuclear power generation facility unit 811 to prevent typhoons, , 10 km above the top of the sea level. The disaster prevention system, which provided a disruption device to the sea surface at the top of the SLD at the top of the troposphere at the top of the top of the sea, (958), and at the same time, a seismic crane boom stand (942) of a tow crane replacement tower crane is provided so that a rain cloud is provided to the seafloor 10 km below the sea level, Natural disasters such as artificial waterfalls such as unmanned disaster prevention waterways are installed in the facility of the disaster prevention apparatus of the nuclear power generation facility 811 at the same time The Typhoon is a dual structure of a seismic crane boom zone (942), a tow crane replacement tower crane, which was designed to allow the typhoon of latent heat of atomic bombs of thermal energy estimated to be one million in the past year's Hiroshima to fall into the Pacific Ocean and the Atlantic Ocean. Level piping line 958 for the disaster prevention apparatus, and at the same time, the human beings of the global village are provided with the disaster pumping control system and the electronic system of the control system 150 Control device connection structure The double structure high pressure hose (190) at the top of the sea surface of the connecting shaft provided at the upper part of the sea surface of the connection shaft is formed within 10 km of the coupling part of the high pressure hose (190) (958) Several floodplain decks Decks formed on the side of deck Replacement tower crane Seisio Crane Boom (942) At the same time, the seesaw crane boom zone 942 of the tower crane is provided with a downward flow 926 to convert the upwind flow 925 into an upward flow 925, The pipeline line (958), which is made of non-ferrous metal with better heat conduction efficiency than iron, is equipped with an image of the loess mixture, which is discharged from several double-structured fire-fighting nozzle (10) (1) to the inside of the nuclear power plant (1) Preventive conditions to prevent nuclear radiation leakage Double structure block tank dust collector (794) To connect the inside of the reactor connection shaft And the establishment of a disaster prevention device to constitute, and at the same time, in accordance with the establishment of a new federal state in Northeast Asia, At the same time, nuclear plant facilities of land and ocean nuclear power plants. (1) Disaster prevention equipment is equipped with efficient nuclear power plant to maximize the production power while preventing the explosion of reactor facilities. At the same time, (1) of the nuclear power station of the nuclear power plant, the prevention of the sinking of the nuclear power plant, the prevention of the nuclear fuel explosion and the disaster prevention device of the distribution shaft are provided in the nuclear reactor main body 1 of the nuclear power plant, Nuclear reactors (811) for nuclear reactors Leakage control Dual structure block tank (794) Nuclear reactors (794) Reactor facilities A connection axis of the disaster prevention device constituting the connection axis;
The nuclear reactor of nuclear power plant for nuclear power plants is equipped with a double structure high speed propagation furnace reactor facility. The method according to claim 1,
(593,594,595) Nuclear power plant (672) of the offshore and offshore marine nuclear power plants equipped with the nuclear reactor waste processing double structure block tank dust collector facility of the nuclear power generation facility unit (811) and the nuclear plant main body (1) In the facilities of the disaster prevention apparatus constituted inside,
The facility of the disaster prevention apparatus constituting the inside of the connection shaft of the nuclear power generation facility unit 811 is composed of a floating nuclear power plant 672 of a marine power plant and a reactor structural body 1 of a nuclear power plant, A nuclear waste disposal and dispensing apparatus having a dust collector 794 and a nuclear fuel explosion control distribution dispensing apparatus are provided with a plurality of reactor facilities to be installed on a barge of an anti-sinking double structure block tank of the ocean, Nuclear power plant (811) installed at 40m above the sea level to prevent the use of restraint system. Sink prevention type barge line reactor facility equipped with position setting. Nuclear Power Generation Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) To construct nuclear power plants;
The facilities of the nuclear disaster prevention system of the nuclear power generation facility 811 constituting the connection axis of the nuclear power plant 672 of the offshore power plant and the reactor main body 1 of the nuclear power plant are as follows: (593,594,595) Dual structure block tank (794) to control the nuclear radiation leak that constitutes nuclear power plant (672) and nuclear reactor plant main body (1) of nuclear power plant Nuclear waste treatment dual structure block tank pipe bridge 937) The connection shaft protection system provided with a connection structure capable of disassembling the connection shaft is composed of a connection shaft of a floating nuclear power plant (593,594,595) nuclear power plant (672) of a marine power plant and a nuclear power plant main body (1)
The facilities of the above-mentioned disaster prevention apparatus include a nuclear power plant, a nuclear power plant, a nuclear power plant, and a nuclear power plant, In addition to providing facilities for disaster prevention equipment in a livable environment, at the same time, the facilities of disaster prevention equipment should not be able to imitate the stiffness of the stork while strutting the stiffness, imitate the stork stance, In addition, the leaders of the international community will be equipped with disaster prevention equipment for disaster prevention equipment, including military water tanks, bombers, bombs and bullets And satellites, missiles, nuclear bombs and rocket bombs have been used to make room The facilities of the disaster prevention apparatus are provided, and the facilities of the disaster prevention apparatus are established by the international society codes and norms, and the facilities of the disaster prevention apparatus are provided to overcome the punctured global economic crisis. The provision of a disaster prevention device for a connection shaft that enables the world economy to be saved by fostering the environment friendly non-polluting energy industry, and at the same time, the facilities of the disaster prevention device constituting the inside of the connection shaft of the nuclear power generation facility 811, It is necessary to provide equipment for disaster prevention of connecting shafts that can prevent sinking accident of sailing vessel without any further casualties even if the ship sinks accidentally while sailing in the state. As the vessel of the device is being laid, the facilities of the disaster prevention device are arranged in accordance with the rights and duties of the Korean Federation of Northeast Asia The raw material is supplied to the blast furnace 948 located inside the steel mill so that the reprocessing is provided inside the reactor main body 1 of the nuclear power plant while the construction machine heavy equipment is installed in the nuclear power plant main body 1, The connection axis is composed of a mooring device, a diving buoyancy control device, a nuclear waste disposal dispenser, and a nuclear reactor facility installed at a nuclear plant (593,594,595) nuclear power plant (672) Nuclear Radiation Leakage Control Dual Structure Block Tank Dust Collector (794) Equipment of Disaster Prevention Equipment Consisting of Connecting Shaft;
The nuclear power plant of claim 1, wherein the nuclear power plant is a nuclear power plant, and the nuclear power plant is a nuclear power plant.

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