KR20170081589A - Typhoon Disaster Discharge Distribution Input Device - Google Patents
Typhoon Disaster Discharge Distribution Input Device Download PDFInfo
- Publication number
- KR20170081589A KR20170081589A KR1020170079110A KR20170079110A KR20170081589A KR 20170081589 A KR20170081589 A KR 20170081589A KR 1020170079110 A KR1020170079110 A KR 1020170079110A KR 20170079110 A KR20170079110 A KR 20170079110A KR 20170081589 A KR20170081589 A KR 20170081589A
- Authority
- KR
- South Korea
- Prior art keywords
- dispensing
- typhoon
- disaster prevention
- water
- control
- Prior art date
Links
Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B3/00—Engineering works in connection with control or use of streams, rivers, coasts, or other marine sites; Sealings or joints for engineering works in general
Abstract
The present invention relates to a dispensing apparatus for preventing a typhoon. More particularly, the present invention relates to an apparatus and a method for installing a tornado tunnel to mitigate a catastrophic typhoon and storm surge, It is equipped with a construction machine crane, a conveyor, and an electronic control device, which is a dispensing device of the above-mentioned typhoon disaster preventing the typhoon by means of a fire disaster prevention device by putting the lifting poison of the power plant into the river mouth and the sea, The present invention relates to a dispensing apparatus for preventing a typhoon from occurring in an unspecified country,
The present invention has been made in view of the above problems, and it is an object of the present invention to provide a disaster prevention system for a small, medium and large sized marine nuclear power plant connected to an island tunnel constituting a dispensing device for a hurricane, To the dispensing and dispensing apparatus for a storm disaster prevention.
Description
The present invention relates to a dispensing apparatus for preventing a typhoon. More particularly, the present invention relates to a dispenser for dispensing a typhoon, and more particularly, The construction equipment crane and conveyor constructed on the top of the floating deck deck, which is a dispensing device of the above-mentioned typhoon disaster prevention device, which is configured to input the floating toxic poison of the marine nuclear hydroelectric power plant to the river estuary and the ocean, And an electronic control unit, and a distributor and dispenser for the storm-storm-type storm-storm dis- tribution in the form of a ladder, which are connected to the electronic control unit, to distribute the storm disaster prevention control to control the tornado near the storm To a charging device.
In general, the safety of natural disasters in the inland riverside coastal areas and coastal areas of coastal areas is weak. Therefore, it is urgently needed to install a dispensing device for storm disaster prevention suitable for the dispenser for typhoon disaster. As a result of research and development, we have made a lot of efforts to find the designing process of dispensing device for typhoon disaster.
The multi-purpose dam annual water supply capacity of the typhoon disaster prevention dispensing and dispensing apparatus is about 10.9 billion
The lowest capacity of Soyanggang Dam is 2.9 billion ㎥, but the annual water capacity is 1.2 billion ㎥, less than 3.4 billion ㎥ of Chungju Dam. Capacity scale of power generation facilities is largest at Chungju Dam with 410 thousand kw.
On the other hand, in the case of the sea, there is a typhoon disaster prevention device equipped with a dispensing device for disaster prevention of a marine nuclear hydroelectric power plant having a double structure block tank dust collector. Therefore, Is produced.
Hereinafter, the tornado and erosion included in the typhoon will be described in detail with reference to the drawings.
Referring to FIG. 1, a description will be given of a typhoon classification for explaining a general outline of a typhoon constituting a main body of a dispensing and dispensing apparatus according to the present invention, and a typhoon dispatching dispensing apparatus A monthly average steady state of the typhoon showing the characteristics exemplifying one embodiment of the road,
Referring to FIG. 2, a typhoon dispatching and dispensing apparatus for dispensing a typhoon according to an embodiment of the present invention is shown. Cross-sectional configuration of semicircular and hazardous semi-
As shown in Figs. 1 and 2, typhoons classified into the main body of the dispensing /
First, the weak tropical cyclone has a center maximum wind speed of less than 17m / s.
Second, tropical storms have a central maximum wind speed of less than 17m / s to 32m / s, from which the typhoon numbers and typhoons are named.
Third, the typhoon has a center wind speed of more than 32m / s. In Korea, the intensity of the typhoon is divided into four classes based on the central air pressure and the central maximum wind speed.
Typhoons will be given their numbers and names when the maximum wind speed near the center reaches more than 17m / s (33knots) due to the development of tropical cyclone.
The name of the typhoon will be used in alphabetical order from the US Joint Typhoon Alert Center located on Guam Island in accordance with the order of occurrence of the year, and the name of the typhoon will be used sequentially from the end of the last typhoon name .
Until April 1979, she used only the name of a woman, but since then she has been putting the names of men and women in turn.
As shown in Fig. 1, the movement of the typhoon in the dispensing and dispensing apparatus main body of the typhoon disaster prevention apparatus is such that the typhoon occurred in the tropical sea gradually develops, And it is often the normal course of the typhoon or sometimes the abnormal course such as the congestion or the movement in the form of the loop.
As shown in Fig. 2, strong winds are gathered in the right semicircle with respect to the direction of the hurricane, so that a dangerous semicircle is called a dangerous circle, while a weak wind in the left semicircle is called a semicircle.
In general characteristics of typhoon,
First, the isosceles are circles and symmetrical.
Second, the attempt of the center pressure is very low, so that the pressure hardness is high and the wind speed is stronger toward the center.
Third, it does not accompany the wire.
Fourth, the temperature distribution is symmetrical about the center.
Fifth, typhoons have eyes in the center and their diameter is about 30km.
Sixth, the precipitation phenomenon is widely distributed in the front of the center, symmetrical with respect to the center, and stronger toward the center (except for the eye of the typhoon).
Seventh, there is a strong storm outside the eye of the typhoon, its diameter is about 200km and it is relatively narrow.
Eighth, it occurs a lot in late summer and it is north to mid latitude.
Ninth, the paradise along the edge of the North Pacific high pressure is shifted to high latitudes and is converted into a low pressure.
Referring to FIG. 3, a typhoon showing a tornado and erosion included in a typhoon constituting the inside of a dispensing and dispensing apparatus main body according to an embodiment of the present invention is illustrated. Sectional configuration of tornado and erosion road,
As shown in Fig. 3, the tornado and the erosion included in the typhoon constituting the inside of the dispensing and inputting apparatus main body for the storm-
The tornado is a powerful whirlwind in the middle of the United States due to a very powerful whirlwind in the form of a funnel that occurs predominantly on a large plain or in the sea, especially during spring to summer,
The seawater that generates the spawning is a rapidly developing cumulonal cloud. The air must be very unstable due to the unstable atmosphere and the convection must be active. The temperature of the ground or sea surface is much higher than the atmospheric temperature, This is likely to occur when it is cold and dry.
However, there must be a vortex seed that is difficult to develop due to the existence of a giant cumulonimbus, and it should have a vortex that can trigger eruption. In the case of the East Sea coast or Ulleungdo, it is beyond the Taebaek mountain range or island. The reason why the erosion does not develop well in the middle of wide ocean and the eruption does not develop well and the erosion does not occur relatively frequently in Korea is not because the atmosphere over the Korean peninsula is not so unstable on the average to be.
Referring to FIG. 4, a diesel engine and a generator are manufactured according to the operation of a hydroelectric power plant, which is shown in a hurricane annihilation
5, there is shown a configuration of a marine hydroelectric power
Referring to FIG. 6, there is shown a configuration of a hydro-hydroelectric power
7, there is shown a diagram illustrating a configuration of a disaster prevention prevention and regulating
8, there is shown a diagram illustrating a configuration of a disaster prevention prevention and
9, there is shown a block diagram showing a configuration of a hydrological
Referring to FIG. 10, there is shown a schematic diagram of a disaster prevention /
11, there is shown a schematic diagram of a structure of a
Referring to FIG. 12, the configuration of the disaster prevention
Referring to FIG. 13, a disaster prevention preventing and regulating
Referring to FIG. 14, a reciprocating
Referring to FIG. 15, there is shown an integrated disaster prevention apparatus for a typhoon according to an embodiment of the present invention, including an integrated
Referring to FIG. 16, there is shown a main problem during pump driving showing a configuration of a disaster prevention
17, a fire pump showing a configuration of a disaster prevention
Referring to FIG. 18, there is shown a diagram illustrating an operation method of each of the valves, showing the configuration of the disaster prevention prevention and
Referring to FIG. 19, there is shown a schematic diagram of the structure of a hydrological
20, a
21, an operation of an automatic collecting tank showing the construction of a hydrological
22, there is shown an operation of an automatic collecting tank showing the construction of a hydrological
23, an operation of an automatic collecting tank showing the configuration of a hydrological
24, a conventional
Referring to FIG. 25, there is shown a diagram illustrating a structure of a
Referring to FIG. 26, an operation method of an adventure and an airship showing the construction of a disaster prevention
1 to 26 each schematically illustrate an embodiment of the internal structure of the dispensing and dispensing apparatus main body according to the present invention.
Referring to FIG. 27, a construction machine
Referring to FIG. 28, a construction machine
Referring to FIG. 29, a construction machine
Referring to FIG. 30, a construction machine
1 to 30 are schematic diagrams illustrating a conventional dispensing and dispensing apparatus for typhoon prevention according to the present invention.
31, the flood control system of the stair-step dam rotation path located at the ridge line of the mountain showing the entire structure of the typhoon dissipation
Referring to FIG. 32, the hull displacement
Referring to FIG. 33, the hull position moving
Referring to FIG. 34, the hull locating movement
Referring to FIG. 35, the hull displacement
Referring to FIG. 36, the hull position moving
Referring to FIG. 37, the hull displacement
Referring to FIG. 38, the hull displacement
Referring to FIG. 39, a hull position shifting
Referring to FIG. 40, the hull displacement
Referring to FIG. 41, the hull displacement
Referring to FIG. 42, a hull position shifting
Referring to FIG. 43, the hull displacement
Referring to FIG. 44, a marine hydroelectric power
Referring to FIG. 45, the hull displacement
Referring to FIG. 46, a marine hydroelectric power
Referring to FIG. 47, the hull displacement
Referring to FIG. 48, a marine hydroelectric power
Referring to FIG. 49, a marine hydroelectric power
Referring to FIG. 50, a marine hydroelectric power
Referring to FIG. 51, a marine hydroelectric power
Referring to FIG. 52, in a storm surge
Referring to FIG. 53, a marine hydroelectric power
54, a marine hydroelectric power
Referring to FIG. 55, a marine hydroelectric power
Referring to FIG. 56, a marine hydroelectric power
Referring to FIG. 57, the flood control system of the stair-step dam rotation path located at the ridge line of the mountain showing the entire structure of the typhoon dissipation
Referring to FIG. 58, the hull displacement
Referring to FIG. 59, a hull displacement
Referring to FIG. 60, the hull locating movement
61, a marine hydroelectric power
Referring to FIG. 62, a marine hydroelectric power
Referring to FIG. 63, a marine hydroelectric power
Referring to FIG. 64, a marine hydroelectric power
24 to 64, the construction equipment excavating machine is divided into a
As shown in Figs. 24 to 64, the hull position moving construction
As shown in Figs. 24 to 64, the typhoon disruption prevention dispensing apparatus of the construction machine constituting the typhoon
As shown in Figs. 24 to 64, a soil-borne construction such as a soil board (straight type, angle type, etc.) is attached to the front portion of the tractor and a ripper and a lute- It is the most basic earthworking machine of construction machinery. It is a compound term of fire (bull) + dozer (resting machine). It is a powerful term to release bull from labor. ) In the hull moving position pumping moving
The application will be described as follows.
As a general rule, the standard size of the doser is expressed by its own weight (ton or kg), ie its own weight. The economical working distance of the doser is 10100m. The distance between two dozers is less than 100m. As shown in the table below,
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 Figs. 24 to 64, the typhoon disaster prevention dispensing and dispensing apparatus comprises a typhoon
The crawler
The crawler type has a large ground area, low ground pressure and strong excavation ability even on bad terrain, and has good backing ability. The use of traverse for wetlands makes it very suitable for wetland work due to its low ground pressure, and it is easy to work underwater to the depth where the track can be locked.
The tire type (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 maneuverability and mobility than infinite tracked type, and is effective for working on flat ground or pavement.
In the sorting by the working device, the
The
As shown in Figs. 24 to 64, the constructional storm-preventing dis- tribution input device constituting the storm-storm dis- tribution dispensing and inputting device of the hull-position moving pumping
As shown in Figs. 24 to 64, in the classification by the subsidiary apparatus,
The
The
The push-rod is used to push the scraper from the back to provide traction when the scraper is working, while the low-pressure rubber tire esophagus is faster than the infinite track and can increase the cargo volume. Also, it is easy to move and does not harm packaging.
Since the U-shaped blade is U-shaped, it does not flood sideways. Therefore, the U Dozer is connected to the upper part (SDU) of the dock hull deck of the marine power plant body included in the
24 to 64, a hull position shifting
The
The
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.
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.
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.
24 to 64, the
24 to 64, the hull position moving pumping
In the outline of the name of each part of the
The motor scraper is a combination of a vehicle type tractor and a scraper. It is different from the fact that the motor scraper is equipped with power by itself. Therefore, it can transport a lot of soil to excavation and excavation in application and specifications. Cutting the ground surface of a flat terrain consisting of aggregates. 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).
In the specification, the flat (load) capacity of the ball is expressed in m 3 , and the order of power transmission is as shown in the table below.
Details of the classification of the
[Comparison between pull-type scraper 859a and power-
The construction machine of the hull moving
(811a) of the hurricane annihilation device (811) constituting the dispensing and dispensing apparatus main body (1) of the typhoon disaster, the moving body (811a) of the offshore hydroelectric power plant constituting the hull deck upper part (SDU) 593,595,595), a crawler-
(SDU) position of the hull dock hull deck upper part (SDU) of the floating docking station (593, 594, 595) by the construction machines of the moving
The apron (859c) is provided 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 landing, the hull position of the marine hydroelectric power plant floating ship (593,594,595) The
In the ejector (859d), the so-called tailgate is located at 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.
In the yoke, it is a member that combines the
The workload of the scraper (braking scraper)
Here, Q : the ball carrying capacity
f : Conversion factor
E : Working efficiency of the scaler
C m : Classify by cycle time.
Grader (862l) is used for civil engineering and mainly works as a stopper. It is a device to pick up ground by scraping the ground with a blade (blade), and it is called a planter of earthwork machine. As for the equipment to be used when it is used, the indication of use and performance is indicated by the length of blade (blade) and it is explained as the following table.
The power transmission procedure will be described in the following table.
The parking brake of the
The power transmission procedure will be described in the following table.
As for the pushing angle and cutting angle of the blade, as shown in the table below, the pushing angle is set to be small in the hard land due to the angle formed by the center line of the grinder and the blade, and 70 ° to 90 ° in the stopping operation. The angle at which the cutting edge of the blade is tilted with respect to the ground. The angle between the grader and the clayboard is adjusted to 45 ° and 60 ° when the soil is pushed to the side and 90 ° when the clay finish is finished.
The following table describes the blade capacity.
only. Q : Blade capacity (m 3 )
B : Blade width (m)
H : Blade height (m)
Minimum turning radius of the steering system
Why there is no differential mechanism
The
The
(811a) of the hurricane annihilation device (811) constituting the dispensing and dispensing apparatus main body (1) of the typhoon disaster, the moving body (811a) of the offshore hydroelectric power plant constituting the hull deck upper part (SDU) 593,594,595) Constructed by connecting the extender cable (861b) to the ripper and the router (856g) constituting the construction machine position control of the hull locomotion control, and the construction equipment connection structure of all six devices (861p) and drag cranes (887) of the crane (593,594,595) of the marine hydroelectric power plant (SDU) at the upper part of the ship's body dock, the dock of the marine power plant, is adjusted to overcome the disaster prevention of the typhoon.
Shovel excavator is the oldest used loading machine and it is a multipurpose machine that can be used as a digging machine and also can do many works by installing front attachment.
It is a machine that carries out various excavation work and crane work by replacing various accessories with the basic type of shovel or crane, and the upper rotating body is capable of turning 360 °. Next, the structure of excavator (856) .
The outer structure of the
The classification by operating method is divided into manual type and hydraulic type by pneumatic and electric type. In the classification by size, it is divided into a small and medium type and a large type, while a small type is a limit of one side which can be rounded in transportation of a railway and a trailer, A shovel with a bucket capacity of 0.6 m 3 or less means a bucket capacity of 3 m 3 and a crane anchorage capacity of up to 10 t.
The performance indication method of the
*
(1) of the dispensing apparatus for the disaster prevention dispatching apparatus for controlling the movement and disassembling and assembling the hull position of the marine hydroelectric power plant floodplain (593,594,595) showing the construction position adjustment constituting the upper part of the body of the marine power plant, The
According to the characteristics of the hydraulic excavator (as compared with the mechanical rope type), the first structure is simple, the second is easy to change the front, and the third is easy to repair and operate. .
The first thing to notice is that the scraper of the drag line (856c) has a large working radius and is easy to dig underwater. Next, it is used to excavate the lower part of the ground broadly, then it is used for harvesting the river, It was not suitable for souring soil or gravel.
The
The maximum working depth of the excavator 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.
The structure and function of the skimmer (856f) is a construction machine that slides the surface of the bucket along the boom of the swinging platform while the bucket is being moved by the force of the chain. It is suitable for thin excavation in a narrow space, (811a) of the hurricane annihilation / disaster prevention unit (811) constituting the inside of the dispensing and dispensing apparatus main body (1) for typhoon disaster prevention because it is used for thin excavation in a narrow place where it is difficult to work. 593,594,595) to control the position of the construction machinery of the hull. The control of the position of the hull of the offshore hydroelectric power plant (593,594,595), which is composed on the upper part of the ship's deck (SDU) To overcome the above problem.
The structure and function of the Ripper and Rooter (856g) are used when the ground is rigid and rigid, making it difficult to excavate. It is attached to the back of a large bulldozer and scraped hard ground using 23 foot saw blades It is suitable for digging, and it was used for the purpose of removing the tree roots, the asphalt and concrete pavement, the rock or the pavement, and the hard soil.
According to the outline of the crane (Cranes, 861), it is called a crane. It is used for lifting and lowering of heavy objects, crushing work by using other working devices, heavy use for collecting waste and building construction, soil, A hook, a clam shell, and a drag line device are installed on the front of the vehicle for the purpose of moving and transporting the vehicle. The structure and basic three-part names are described as follows.
The structure of the
The name of each part of the crane or crane structure is the name of the crane or hoist structure in which the
The cable crane 861o is equipped with a
The standard method of performance is to display the maximum hoisting load in tonnes. The basic operation of the crane is shown in the table below.
As shown in Figs. 24 to 64, the crane (hook) is used for the general lifting work, the loading and unloading of the cargo, and the clam shell (Shell: clamshell) is suitable for earth loading, vertical excavation, dirt removal, underwater excavation, hopper operation and deep hole digging. Shovel is suitable for soil excavation, slope excavation, , Suitable for road construction and drag line (drag line) is suitable for embankment construction work, drainage construction work, loading of soil to flat bottom and underwater work vehicle, and trench hoe It is suitable for work, burial work, excavation work, mining work, and oil pipeline installation work. Pile driver is used for pillar work and bridging of bridges during foundation work. Crane is the main equipment to assemble a hydroelectric plant body.
As shown in Figs. 24 to 64, the operating angle of the boom 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. 24 to FIG. 64, the drag crane is divided into the following types according to the purpose of use, and the function of the drag crane is that it has a large grounding pressure and can not be operated in soft ground but has good maneuverability. The structure and function of the tower crane is a crane equipped with a short jib or hammerhead type truss on a high tower. The crane is used for the purpose It has been widely used in high-rise buildings and construction sites. The structure and function of hydraulic crane,
The boom can be extended up to 510m and the hoisting load is usually 310 tons. It is used for harbor loading and unloading work, civil works, electric pole work, The structure and function of the cable crane,
The trolley is hung up by a thick cable on both ends of the tower. It is used for concrete and material transportation in the dam construction, while the Derrick crane,
The structure and function of the derrick crane as a main constituent part of the present invention is a machine that lifts a boom at a lower part of a steel mast and winds up a block and passes a block through a block and winds up a rope, It is used for assembling, foundation work, and bridge construction work. As a kind, Giederik has the capability of hanging luggage against the material beam, easy to disassemble and unload work with large working radius. 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 hurricane annihilation / disaster prevention unit (811) for controlling the flow rate of the flow of the water into the main body (1) of the distribution control unit for the flood control, which is constituted for controlling and disassembling the hull position of the marine hydroelectric power plant flood control station (593,594,595) Moving pumping moving part (811a) is connected to the construction machinery of hull position movement control of marine hydroelectric power plant floating levitator (593,594,595) constituting on the upper part of SDU of the body of the marine power plant deck.
Tractor crane is a wheel and crawler type crane mounted on the upper body of shovel excavator. The following outriggers maintain safety and prevent the tire from being loaded, which causes wear and tear due to tire and spring load (= Door type crane) is a crane that moves by installing a running rail on the ceiling. It is usually used for the production and processing of concrete beams. Fixed type is used in factory, warehouse It is used for loading but it is not used for construction work, and driving type is used for construction work.
Chain block (648) can be lifted up to a maximum of 15 tons for loading and unloading, and the safeguard for lifting and unloading of the crane is a braking and limiting switch.
Maritime crane transport and construction of large steel structures of bridges. And a
As shown in Figs. 24 to 64, the
The classification according to the loading method is shown in the following table.
The loading method of the loader 857 is shown in the following table.
As shown in Figs. 24 to 64, a loader 857 is often used as a Muk loader in tunnel construction, and is used to load a tombstone demolished during excavation work on a vehicle. The pay loader is used to load the dirt into the dump truck (860), it should be operated as slowly as possible, the bucket should not be raised during no-load operation, and the rail type slack loader should be demolished It is used for various tunnels, residential composition and limestone mining with continuous rock loader. The screw excavator is used for underground excavation work in city area, soil loading work in factory or ship , The use of a bucket wheel x-car, the use of a belt loader, and the loading of a skid loader as a loading machine suitable for working in tunnels or tunnels Up quantity calculation equation shown in the table below.
(811a) of the hurricane annihilation device (811) constituting the dispensing and dispensing apparatus main body (1) of the typhoon disaster, the moving body (811a) of the offshore hydroelectric power plant constituting the hull deck upper part (SDU) 593, 595, and 595) are connected to a dispensing device for hurricane disaster prevention equipped with hull position shifting pumping operations of a hurricane disaster prevention device unit (811) constituting the construction machine position control of hull position shifting control.
In the kind of the
Calculating the required number of trucks:
Calculate truck workload:
here,
In the running resistance of the
The Dumptor is a special off-road truck for short-haul trucks that can be used in narrow workshops. The locomotives are used to transport over 1 km of the locomotive and are used for the construction of tunnel constructions. And the tractor and
The Rope way is a machine that carries the cargo by placing a steel tower on both sides of the mountains and arranging the car every 60m after connecting the cable. It is not restricted by the topography and road conditions and has few faults and is relatively 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 for transporting aggregate and cement material to a tractor. . front. It is also called a full trailer (860a) with an axle and wheels attached to the rear end.
This is an overview of a forklift (Forklift; 858). It is a device for raising or lowering cargo. It is widely used in warehouses and docks 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 Can be tilted forward 56 ° (referred to as the front wrist), backward 10 ° 12 ° (referred to as the posterior wrist), up to a maximum of 4500 mm, and a minimum of 3000 mm (called the maximum amount).
The minimum radius is very small. (Angle of steering of 65 ° 75 ° inside wheel)
The pressure of the hydraulic piston is 110130 kgf / cm 2 .
All-wheel drive is rear-wheel-drive.
Steering device of fork lift truck 858:
A master batch that operates hydraulically is installed. (Hydraulic pressure 70130 kgf / cm 2 )
In operation, the fork is raised from the ground by 150200mm.
It is efficient within 250m.
The front wheel is installed directly on the frame, while the rear wheel does not have a suspension spring in the small size, but a large suspension spring is used.
For the control method, the efficient transportation distance is suitable for the operation within 250m. The height of the fork during transportation is 150200mm for the fork when the cargo is carried. When the slope is transported, the fork part (front part) (593,594,595) of the hydro-electric power station of the hydro-electric power station is constructed by a construction machine to control the movement and disassembly of the hull. And a typhoon destruction and
The
Screw conveyors are used for sand, cement and concrete conveying. Belt conveyors are the most widely used for soil, crushing and aggregate conveying. Size: tonm Portable conveyors are used for conveying sand gravel It was used for harvesting.
This feature car is described in the following as a non-stop driving car and a hoisting on a unimog.
Unnecessary driving car is a car wheel-type all-wheel drive vehicle capable of carrying work in difficult conditions such as mud, sand, and unevenness,
Uni mog is a vehicle that can be widely used in various fields of agriculture, civil engineering, snow removal, and road maintenance. Hoisting is a main body (1) of a typhoon disaster prevention device composed of a construction machine that carries heavy materials, And a typhoon dissipation /
As shown in Figures 24-64,
In the kind of the
As shown in the table above, the additional load (ballast weight) of the urine site is called the 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. It can be added more than twice its own weight. The additional load is iron, water and sand. The tire roller is injected as much as necessary in the water tank, and the machine, tandem, and tamping roller increase the voltage capability by injecting additional load on the wheel.
In the sorting by the pressurizing method, 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 into a rammer and a tamper, and the vibrating compaction machine is composed of a
As shown in FIGS. 24 to 64, the static pressure roller according to the kind and characteristics of the rollers is used to polish the road surface by the static self weight of the rollers, and the use of the
Tandem rollers (863d) are suitable for compaction of clay and clay soil and are used for finishing thick asphalt or finish of asphalt pavement. Power transmission order is engine main clutch transmission front and rear differential gear type decelerator The characteristics are not available for compaction of the crushing stone. The cylindrical shaft of the steel drum is a two-axis tandem and a three-axis tandem. In addition, it is possible to expand the compaction width separately from the operation of the front and rear wheels.
The use of tamping rollers (863e) is used to prepare areas where the soil is fragile. It is a pluck roller, a turn-feed roller, a tape foot roller, and the characteristic is the plucking by turning a plurality of projections in a cylindrical shape of a forcing cylinder
The outline of the tire roller (863f) is to attach the tire instead of the iron wheel of the tandem roller, and it is used for the pulling type and the self-driven type. The application is used to uniformly apply the pressure to the road surface during the airfield runway and highway asphalt pavement. The air pressure was 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.
The Impact Compaction Machine is used for free-fall impact. The Rammer is used for compacting the two-stroke cycle engine body of a small internal combustion engine. Tamper changes the explosive power of the gasoline engine to torque, It is suitable for tightening narrow spaces and roads. The Soil Compactor (863b) is a compact gasoline engine that uses a combination of a device that generates vibration and a plate oscillator As a compaction machine, there is a movable type by self-propelled force. This means that it has a large compaction effect compared to the weight and is suitable for sandy soil and is inappropriate for viscous soil.
The reason for this is the line pressure due to the width (maximum width) of the rollers compaction width (maximum width) which is set in one pass, and the grounding weight of the wheel divided by the width of the wheel is the value (kg / cm).
The
The concrete mixer is a machine that mixes sand, gravel, cement and water to work effectively on the construction site. The dryness type is a method in which the cement and aggregate are metered into the mixer, The transportation is carried out at the construction site and the mixing is performed by 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 ).
The hull position shifting pumping
The outline of the concrete pump (869) is convenient when transporting concrete in a limited space such as a bridge in a tunnel or a building. The pump has a mechanical and hydraulic pressure type. It is a combination of hydraulic or hydraulic type, which means less shock or vibration, easy handling, easy maintenance, and economical. It is used to transport high-rise buildings and long-distance concrete.
Type, the component of the fluid pressure with expression truck loading expression inde diaphragm expression tall buildings used to (more than 100m), and standard displays are displayed in hourly delivery capacity (m 3 / hr) piston concrete pump on a removable and mechanical concrete injection hopper, A suction and discharge valve, a piston, and a cylinder.
Concrete piling machine is a concrete finisher (866). The outline of the concrete piling machine is concrete worker. After finishing concrete work, it is used as a finishing machine. Finish the slab side.
The concrete finisher is designed to finish the surface of the pavement while vibrating the front and back of the surface. Standard marking is a standard that can be applied. And is connected to the upper end portion (SDU) of the marine power plant body dock hull deck
As shown in FIGS. 24 to 64, the outline of the concrete spreader 867 is a packing machine for uniformly laying the raw concrete sprayed on the packed bedrock. The use of the concrete spreader 867 is similar to that of a truck mixer or a dump truck It is classified as a screw type and a box type in a bladed type and at the same time a kind of an asphalt pavement machine is classified as an asphalt mixing plant The
In this type, weighing and mixing method is formed by batch type and continuous type, and the installation method is fixed type and transfer type. The operating method is manual type in electromagnetic type and semi-automatic type. Usage is asphalt heating in combination with asphalt drying and aggregate drying. The hopper and aggregate dryer are equipped with an exhaust dust collector and a hot elevator, a vibrating screen, a mixer and a weighing device on the asphalt cake.
The asphalt finisher (871) is equipped with a sorting and sizing device. It is a device that boils over 150 ° of gravel sand in an asphalt mixing plant and laid the mixed aggregate on the road with a certain standard thickness. It is used as an asphalt finisher In the paving work, it is used in asphalt spraying, picking, chopping, etc. Dimension marking is indicated by the maximum packing width (m) and packing capacity (ton / hr) and in the mechanism of the asphalt finisher (871), the screed is the mixture A living hopper is a container for storing mixed material (asphalt) carried by a dump truck with a hopper of more than 5 tons installed on the front of the equipment. The feeder is installed on the bottom of the hopper, The bumper is installed on the front of the screed and is thick enough to require the mixture sprayed on the road surface. The work to lay the scene.
Asphalt distributor (872) is an equipment that first boils asphalt and sprays it on the road surface. 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 ).
The asphalt cover is a construction equipment that continuously keeps the asphalt mixture for the highway and the asphalt spray is the equipment to heat and dissolve the asphalt, asphalt emulsion and tar by the oil burner and pressurize and spray it on the road surface. Is a machine that performs various work while proceeding on the hearth, and mixes and mixes the surface by adding and mixing the surface. The standard display is indicated by the capacity (m 3 ) of the fluid tank. It is characterized by good workability and excellent maneuverability The efficiency of the sprayer was good and it is easy to adjust the depth of digging the ground.
The diesel pile hammers (883), which are classified as construction machine hovering and anti-erecting machine (877), use the explosive power of a two-cycle diesel engine as a hovering machine, which is twice as fast as a vibration hammer and steam hammer of the same size In this method, the injection device when the ram is raised and dropped by the starter operates. When the ram is injected into the concave surface of the anvil and the ram hits the anvil, the explosive force and the impact force of the ram are applied to the pile And the ram rises up again by the repulsive force. At this time, the exhausting and sucking action is performed, and the falling, the blowing and the explosion are repeated again, so that the continuous hammering operation is possible. And an anvil inserted in the lower part of the cylinder, a fuel pump and a starter in the fuel injector, There are large devices configuration.
A
Its standard specification is to indicate the weight (in tonnes) of the ram, which is used to stamp wood, concrete and steel pipe files. Its characteristics are shown in the table below
The outline of the column hammer (= column file hammer) is a machine that continuously sends up steam or compressed air into the cylinder and repeats the upward and downward movement of the piston to put the pile into the ram at the bottom of the piston rod, In general, steam hammer is used as the outline of the machine. The piston is operated by using the expansion energy of steam. The specification mark is expressed by the weight of piston (ton). Due to this feature, the structure is complicated, maintenance and maintenance are difficult, And it is used to put the pile in the hard and denser soil. It is guided to the lead and has single acting type and double acting type. The outline of the vibration hammer is hammered or pulled by the vibration power, and the frequency is more than 500 times per minute. The standard 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.
The first advantage was that the operation of the hammer was simple, and the equipment was small in size, so that the cost was low, and the adjustment of the drop height made it possible to increase the striking energy.
As shown in Figs. 24 to 64, the second problem was that the piling of the pile was slow, and there was a risk of damaging the pile. Thus, it was easy to damage the surrounding buildings due to vibration at the time of work, It was impossible to work.
The upper portion of the
The diesel hammer is a steam hammer and the vibration hammer is a drop hammer. It is a device to drop a hammer or diesel hammer when putting a file and to install the work device on a crane boom.
The
Construction machine air compressor (Air compressor, 875) is a machine that sucks air in the air to make compressed air and makes it into a high pressure state and is used for various purposes in various construction works. It is used for driving devices, compressing devices 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.
Painting in concrete vibration and logging operations, tire inflation and equipment cleaning, and construction air compressors are large.
Compressors in this category are classified into reciprocating piston type rotary compressors and rotor type compressors by screw type compressors and centrifugal type turbo type compressors. And the portable system can be used while simply moving the compressor.
Air cleaner Low-pressure cylinder Intermediate cooler High-pressure cylinder Air tank The standard indication of this is the amount of air discharged per minute (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.
The function (role) of the main part of it is explained as the following table.
A detailed description of boring equipment (876) equivalent to a jackhammer is given as follows.
The
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).
In its kind, the sinker is the latest type of rock drill with soundproofing, suitable for hole drilling in rock, various swell cuts, and semi-downward work on the 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.
In addition, in the rag drill, the boring machine and the crawler drill are used to move the hull position moving
Conventional dredgers are equipment that digs dirt in water, and it is a route in 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 ).
For the classification by ability, electric and diesel type are classified as steam turbine type and gas turbine type. For the structure and use of dredger, pump dredger (879a) is not suitable for the structure and use of the dredger, In case of long distance, it is used for dredging or landfill construction of harbor by transporting the soil to a toe line or by sucking soil and water by using a low-head pump line. The angle of movement of the hull is 90 ° to 70 °, Is expressed as the rated output (PS) of the drive engine.
The construction and use of bucket dredger (879b) is such that the soil is continuously pumped up by using a bucket conveyor and the dredged soil is transported by a toe line and used for dredging of large-scale routes and anchorage. There is a formula and intermittent type, and a continuous type is often used. The standard indication is indicated by the continuous rated output (PS) of the main engine. The characteristics of the dredger (879b) are as follows.
The structure and use of the Dipper dredger (879c) is used for dredging strong ground and broken rocks or broken rocks. The specification mark is indicated by the bucket capacity (m 3 ) and its characteristics are described in the table below.
As described above, the seabed mineral manganese nodule 909 is collected,
A plurality of construction machine connecting structures are provided inside the dispensing and dispensing apparatus
As shown in Figs. 24 to 64, the structure and use of the
Grab dredger (879d) the structure and purpose is to device a clamshell above vessel as equipment for dredging by a special crane was used in dredging of a small passage or anchorage-marking is grab bucket pyeongjeok capacity (m 3) And its characteristics are described as the following table.
As described above, the seabed mineral manganese nodule 909 is collected,
A plurality of construction machine connecting structures are provided inside the dispensing and dispensing apparatus
It is used to produce crushed stones and crushed stones. It is used mainly for the production of aggregate. In the future, it will be used for the first stage of underground 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.
Jaw Crusher is a machine that is crushed by compressive force. When rocks are inserted between jaws on both sides, they are fixed on one side and the other side is operated and crushed by the price pressure at that time, And is discharged in the discharging direction by the discharging force. Such a jaw is made of a structure capable of crushing any hard rock pomegranate with powerful force.
A gyratory crusher is made of cast iron or steel and consists of a frame lower eccentric shaft and a 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.
The con crusher of the second crusher has an umbrella-shaped cone-mantle head on a short vertical spindle, strikes between the cone-curve balls mounted on the frame by its eccentric motion and crushes the descending stone do. 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 Zyeterotorizer, the cone is short, the dimension of the supply port is small, and the size of the outlet gap is the largest, so that it is possible to produce the standard product with the crushed stone. It is suitable for mass production of certain aggregates. Double crusher of Hammer crusher has two hard steel rolls fixed on a separate horizontal axis and freely adjustable spacing. . 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.
The rod mill of the
The ball mill differs from the rod mill in that a steel ball is rotated in a cylinder instead of a rod to obtain a 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
Hereinafter, the water source and the water quality of the fire water (7) of the dispensing and dispensing apparatus for preventing the typhoon 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 water supply was river water and well water.
Therefore, the well water has 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.
Since river water is abundant in quantity, it is purified and used widely 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 except for the photo phenomenon because of the seasonal changes in water temperature.
The quality of water depends on the pests and germs contained in the water, and turbidity, color, taste, odor, etc. are different. Therefore, if it exceeds the allowable content, it is prohibited to use it. 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). Drinking water should be between 90 and 110 (p.p.m) and should not exceed 300 (p.p.m.).
In addition, water was divided into soft water and soft water according to hardness, and it was said that water less than 90 p.p.m was hard water more than soft water (110 p.p.m).
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).
As shown in Figs. 24 to 64, with respect to the definition of the hydraulic pressure, the hydraulic pressure is a hydraulic pressure pump that uses mechanical power to change the mechanical energy into the pressure energy of the fluid and stores the pressure energy in the hydraulic fluid. Means a device or a method for converting the three basic control elements of control (flow control), flow rate (control of speed) and direction change (control of direction) according to the purpose into mechanical energy again through actuators of hydraulic cylinders or hydraulic motors First of all, the advantage of the hydraulic system is that it generates a large force compared to the size of the system and can precisely control the position and start at a large load, Power, direction, speed) and controllability and excellent heat release.
The disadvantage of this hydraulic pressure is that it is sensitive to foreign substances due to the pollution 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,
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 .
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 a hydraulic system output device for the case of a hydraulic motor (rotary actuator) that generates the hydraulic pressure.
The control unit 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 Figs. 24 to 64, the constitution of the pressure source portion includes a tank for collecting a required amount of oil, a hydraulic pump for pumping oil from the tank into the circuit, and safety valves for protecting the power source, Parts are also equipped with various types of equipment to meet the specific needs of the equipment. Gears and vanes. Piston pumps. Motors and tanks. Relief valves. Shut-off valves. Pressure gauges. (Heat-exchange) And the pressure line and the return line in the suction line, and the control unit will be described as the following table.
A pressure control valve for regulating the pressure of the oil, a directional switching valve for switching the direction of flow of the oil and switching the operating direction of the actuator, and a flow control valve for controlling the operating speed. The pressure control valve is composed of a relief valve The valve is a counterbalance valve for sequence valves and no-load valves. Directional control valves are 2/2 and 3/2 to 4/2 and 4/3 to 5/2-way valves. Flow control valves include orifice And operating speed adjustment, and Table 1-1 shows the configuration of the hydraulic device as shown in the following table.
The actuating part is a rocking motion in the linear motion and the rotation motion and is described as the following table.
First, the cylinder of linear motion is linearly pressed or pulled.
Secondly, the motor of the rotary motion profits the heavy object 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 called Newton [N] 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 hull position shifting pumping
The value of the pressure is generally compared to atmospheric pressure.
Atmospheric pressure (atomospheric pressure), the air surrounding the earth is called the atmospheric pressure, which is called the atmospheric pressure, the standard atmospheric pressure is as follows.
1atm = 760mmHg (can height Ontario) = 10332kg f / m 2 = 1.0332kg f /
= 10.332 mAq (height of water) = 101325 N / m 2 = 1.0 1325 bar
The gauge pressure is the pressure measured by the gauge and the pressure measured relative to the local atmospheric pressure.
Absolute pressure is the pressure measured relative to the full vacuum.
In the fifth power, work is defined as the amount of energy consumed and is calculated as the product of the distance traveled due to the applied force and 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 FIGS. 24 to 64, since the change relation between the units is applied to the equation, the force is N and the velocity is m / s in the above equation. These equations, made in advance of the relationship, are often used in the industrial field because of their convenience. In the international system of units, the power uses Watt (W) as a coordination unit. Since W is a small unit, it is usually expressed in kilowatts (1kW = 1000W) into equation (1.2), the following equation used in the international system of units is obtained.
The kW symbol 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.
In the continuum equation of simple hydrodynamics used in a hydraulic machine, Bernoulli's equation and the principle of Pascal on the statics of fluid and the flow of fluid flow and friction on the principle of pressure transfer 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.
Steady flow in the conduit I la (steady state flow) and the fluid when not in consideration of the compressibility, the tube perpendicular any
And here,
( 1) Since masses passing through a point in unit time are ρ 1 , A 1 , and υ 1 , the above equation becomes
When the fluid is uncompressed, ρ = Const .
And is expressed in units of m / s.
In the Bernoulli equation, the Bernoulli equation describes the relationship between the total energy of the noncompressible fluid and the hydraulic fluid is nearly noncompressible, so the Bernoulli equation can be used for hydraulic systems and the fluid energy in three forms.
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
The above three energy units are 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.
The hydrostatics of the fluid is proportional to the hydrostatic 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)
The principle of Pascal is that when a fluid is pressurized by a force (man's force, mechanical force, or force by a person) in a closed container, the pressure applied to that fluid is transmitted to the other object at the same magnitude in all directions This principle is called "Pascal's principle" because Pascal is the first person to uncover this principle. The principle of this principle is applied to the pneumo-hydraulic device, and the pressure on the surface where the stopped liquid is in contact with each other is perpendicular to the contact surface The magnitude of the pressure acting at one point of the stationary liquid is the same for all directions, so that the pressure applied to a portion of the liquid that is stationary in the closed vessel is simultaneously delivered to all parts at the same intensity, It is called the principle.
As shown in FIGS. 24 to 64, when a liquid is placed in a closed container and a force F is applied thereon, the liquid has a property of not decreasing the volume even when compressed, so that the liquid has a force against the force pressing it 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.
The principle of pressure transfer is that there is no friction between the piston and the cylinder due to these forces due to the filling of the liquid in the cylinder and the application of forces F 1 and F 2 to the piston cross-sectional areas A 1 and A 2 If 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.
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 FIGS. 24 to 64, the flow of fluid is generally referred to as an 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 Laminar flow is a flow that dominates viscous force over inertial force, that is, it has a small Reynolds number, that is, it is a flow with a small velocity and a viscous flow. It satisfies Newton's law of viscosity. Turbulent flow, on the contrary, Because the Reynolds number is large, the velocity is large and the flow in the hydraulic system is usually a laminar flow.
As shown in the table above, friction and flow are lossy when hydraulic energy is transferred through piping. 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.
In the hydraulic pump, the mechanical energy supplied from the prime mover is converted into the hydraulic energy, and the hydraulic energy of the hydraulic oil is converted into the hydraulic energy A pump that converts energy to a hydraulic system by raising the level is called a hydraulic pump. The pump is classified as a cost reduction pump and a volume type pump. A cost reduction pump is a pump in which energy is switched without being clogged, There are constant flow pumps, axial flow pumps, injection pumps, and there is a constant relationship between discharge volume and pressure. As the discharge volume increases, the discharge pressure decreases. The positive displacement pump is a pump that discharges a constant amount every time the axis of the pump rotates Since the discharge amount is constant regardless of the load pressure and the discharge pressure is determined according to the load pressure, When the hydraulic pressure is excessive, there is a risk that the pump will be destroyed. In the hydraulic system, the hydraulic pump sucks the low-energy hydraulic oil in the tank by applying the energy to the inside of the tank, The work or energy that is applied to the hydraulic oil by the pump operation is composed of the work (energy) and the energy (energy) generated by the pump operation, while the hydraulic oil is sent to the outside through the operation part (cylinder, motor) (Displacement) = (Pressure) ㅧ (Width) ㅧ (Displacement) = (Pressure) ㅧ (Exclusion volume).
The work done in unit time, ie, power or power,
As shown in Figs. 24 to 64, Table 2-1 explains the relation between the amount of discharge and the pressure according to the classification of the hydraulic pump, as shown in the following table.
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 power and efficiency of the pump, the suction pressure of the hydraulic pump p s [kg f / cm 2 ], the discharge pressure p d [kg f / cm 2 ], And the discharge flow rate is R [m 3 / s], the pump power (the horsepower that is effectively transmitted to the fluid) L p generated by the pump 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
Assuming there is no leakage loss in the pump, the pump feeds the theoretical power (liquid power) L th ,
( L th = pQ th [kg f m / s]) (2.4)
Here, p kg f / cm 2 is the pump output pressure and sat 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.
In the outline and classification, the hydraulic actuator is a generic name of a hydraulic device that performs mechanical work by generating a reciprocating motion or a rotary motion of an output shaft by pressure oil, and is a hydraulic actuator which is composed of a hydraulic motor (rotary motion of a shaft), a hydraulic cylinder (linear motion of a shaft) (Limited rotational motion of the shaft). Table 4-1 shows the types of hydraulic actuators.
In a hydraulic motor, a hydraulic motor is a device that converts pressure energy into rotary 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, since the efficiency is not good, However, since the hydraulic motor can rotate in either direction, the characteristics of the hydraulic motor are compared with the 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.
The structure of the gear motor is almost the same as that of the gear pump. The supplied hydraulic oil acts on 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.
The vane motor is the same as the vane pump in the structure. It has the advantages of constant output torque, reversible, continuously variable transmission, harsh operation and lighting when the supply pressure is constant. And the speed limit of 200 rpm is small in fluctuation of the output torque and generally has a disadvantage in that fluctuation of the torque is increased because the efficiency is not good at low pressure or low speed in general.
In a piston motor, a piston motor is often referred to as a plunger motor or a rotary piston motor. The piston motor has almost the same structure as the piston pump. The piston motor has an axial type and a radial type. Piston motors have boss and swash plate type.
As shown in FIGS. 24 to 64, 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 The piston motor is classified into a multi-stroke type that generates torque by several piston reciprocating movements per revolution by using an eccentric type and a multi-leaf cam to convert the force due to the pressure applied to the piston to torque. (fixed displacement type) and variable displacement type (each type).
For the output and efficiency of the hydraulic motor, the pressure of the hydraulic oil flowing into the motor is p 1 [kg When called f / cm 2], the pressure oil to the pressure flowing out of p 2 [kg f / cm 2 ] d, and the supply pressure Q the significant flow rate [cm 3 / min] the power flowing into 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,
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.
Advantages of the hydraulic motor in terms of advantages and disadvantages are that it can be quickly stopped 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, , Stop, reverse, and shifting can be controlled simply by a variable displacement pump or metering (a throttle valve, a valve that improves the flow rate), a safety device for overloading or braking is easy, As described above, the hull position shifting pumping
As shown in FIGS. 24 to 64, the construction machinery connecting structure in the form of a spinneret (838) constituting the upper portion (SDU) of the ship's dock hull deck of the marine power plant of the marine hydroelectric power plant lifting plant (593,594, 595) The power
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
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 that the inventor's generator is installed in the sea to solve the problem of mankind by endless production of environment-friendly energy. FIG. 1c is a diagram showing a conventional method of dispensing a typhoon for disaster prevention And the hurricane annihilation / disaster
Generally, in the domestic water resources facilities, the total low capacity of the multi-purpose national dams is about 12.6 billion ㎥, the capacity of the power generation facilities is about 1.05 million kw, and the flood control capacity is about 2.2 billion ㎥. , The annual water supply capacity of these multi-purpose 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. The background technology of the above-mentioned power plant (land hydroelectric power generation) is divided into hydroelectric facilities and hydroelectric generators, so that those skilled in the art can easily understand the present invention by a more detailed explanation. The following is a summary of the overview of the hydropower plant, while explaining the method as shown in the following table, which combines the conventional technology and the power plant with considerable power.
Since the hydropower plant is a facility that utilizes flow and dropping, it should always be built so that the flow necessary 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 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 the facilities properly. Therefore, there are various structures in the works to be used in each facility. Depending on how these are combined, (679s) of the hydroelectric power plant will be briefly examined for the hydroelectric power plant.
In order to take the water of the charge as the previous hydroelectric power generation, the facility which blocks the water in the direction almost perpendicular to the flow of the river - this is called the water intake dam (680b) and the facility for taking water in the lower right- The water taken from the
In the case of conventional power generation dams, if the power generation dam is classified according to its application, a simple intake dam used for a hydroelectric power plant, a slightly larger dam used for increasing the water level on the upstream side in a dam- Not only is there a huge low-water dam (dam-type power plant) that makes reservoirs or reservoirs (680a) by interrupting the valleys or rivers to save water for a period of time, and if you list the main things you should be careful of when building the dam Flood and other external forces, and that the following types of dam should be selected as the most economical considering the topography and geology. After the selection, This is called draining - that the damage to be done should be minimized, and It is necessary to ensure that the maximum flow is safely discharged even at the time of water supply 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, It is a dam for the purpose of taking water from a hydroelectric power plant. Generally, the height and width of the dam are not so large. Next, in the low water dam, it is possible to increase the water level by increasing the water level at the upstream side by the dam and to control the water quantity by season or year Since large quantities of water are used, it has been explained above that it is divided into the adjustment area and the reservoir depending on the magnitude of the adjustment ability.
According to the classification of the existing power generation dam by the material used, the concrete dam and the dirt dam form a rock dam. Firstly, in the concrete dam, the dam is made of the concrete made of the mixed and processed cement, sand and gravel. Secondly, in the case of dirt dams, sand, gravel, and clay are mixed properly and constructed, which is economical when the material is procured locally. This type of dam should be designed to maintain stability by gently sloping both upstream and downstream sides of a concrete dam.
As described above, the typhoon destruction and disaster
The butterfly valve 622 for adjusting the buoyancy of the
If the hydroelectric power plants in the hydroelectric power plants are classified according to their function while the typhoon disaster prevention facilities are constituted by the construction machinery connection structure and the disassembly coupling, water intake facilities (680o), power generation facilities (680p) and waterproof facilities ) Is a facility equipped with flow and head, while the hydraulic power plant (233), which shows the arrangement of the position control of the construction machine of the marine hydroelectric power plant's floating relays (593, 594, 595) In the hydraulic system, the theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated. The water intake system 680o and the power generation system (680p) and waterproofing (680q) hydroelectric power plants (233) and multi-tiered hydroelectric generators (213) devices. The hydroelectric power plant is composed of a seismic type of hydraulics and a marine tidal power plant in the form of a water hammer.
In the old rock dam 680z, it is economical when such a rock material is procured locally as in the case of the
As described above, the marine hydroelectric power generation and production unit 811b for producing the power of the typhoon destruction and disaster prevention device unit 811 constituted inside the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention body, (678c) and a conceptual drawing (678d) of a reservoir power plant showing a construction machine position control arrangement of a hull locomotion control of a marine hydroelectric power plant flood control station (SDU) of a hydroelectric power plant (593,594,595) 678e) Hydroelectric power generation equipment of the construction machine The marine hydroelectric power production and production department (power generating production department) which produces the power to generate the power of the typhoon annihilation device 811 inside the main body (1) 811b are installed in the hydraulic rotary cylinder 620 of the rack and pinion type NRP which is a rotary cylinder and the butterfly valve for controlling the buoyancy of the band guide 621 The vertical partition wall 605 constituted by the dispensing and dispensing apparatuses for stormwave disaster provided with the hydraulic cylinder 622 and the hydraulic cylinder door 624 in the hydraulic cylinder 623 and the pin coupling shaft 606 for the portable lug coupling, A large flange connection connector joint area machining hole 615 in the portable lug 607 and a portable lug pin 608 is connected to the construction machine link structure and the bridge pier 928 and the pipe bridge 937 in the interior of the marine tunnel transport device 941 To the internal tunnel 771 of the marine tunnel communication apparatus constituting the inside of the marine tunnel traffic apparatus 941 in the piercing bridge 928 and the pipe bridge 937 in the crude oil drilling machine 908,
(680o), power generation facilities (680p), and waterproof facilities (680q) are installed in the water intake facilities (680n) while the water power facilities in the hydroelectric power plants are classified according to their functions while the water- ), While the hydro-equipments which are divided into four types are the facilities using the flow rate and the free fall, while the hydraulic power of the
The theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated, and the water intake facility 680o, the power generation facility 680p and the
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, and the stability of the dam is maintained by the own weight of the dam. Since the pressure is applied to the foundation, the installation site should be a place with a solid rock. The gravity dam is mainly made of concrete, but the clay dam (680y) using the soil and the rock dam (680z) using the rock are also used as a kind of gravity dam .
As described above, the marine hydroelectric power generation and production unit 811b for producing the power of the typhoon destruction and disaster prevention device unit 811 constituted inside the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention body, (678c) and a conceptual drawing (678d) of a reservoir power plant showing a construction machine position control arrangement of a hull locomotion control of a marine hydroelectric power plant flood control station (SDU) of a hydroelectric power plant (593,594,595) 678e) of the hydro-electric power generating facility construction machine connection structure, the hydro-electric power generating and producing unit 811b for producing the power of the typhoon destruction preventing apparatus unit 811 constituting the inside of the main body 1 of the typhoon prevention apparatus The marine hydroelectric power station floating readers 593 and 594 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 hydraulic ladder 607 is provided as a dispensing device of the typhoon annihilation machine provided with the hydraulic cylinder 623 for the hydraulic cylinder and the portable lug 607 ) And a portable lug pin (608) with a large flange connection connection joint hole machining hole (615) The construction machine connection structure, the bridge (928) and the pipe bridge (937) are provided inside the marine tunnel transport device (941) The marine tunnel communication apparatus internal train 771 constituting the inside of the marine tunnel communication apparatus 941 in the piercing hole 928 and the pipe bridge 937 in the conventional drilling machine 908,
(680o), power generation facilities (680p), and waterproof facilities (680q) are installed in the water intake facilities (680n) while the water power facilities in the hydroelectric power plants are classified according to their functions while the water- ), While the hydro-equipments which are divided into four types are the facilities using the flow rate and the free fall, while the hydraulic power of the
The airstream and the generator are rotated as the input to the aberration with the theoretical hydraulic power for manipulating the flow rate of the seaweeds and the water intake facility 680o and the power generation facility 680p are installed in the water intake facility 680n which is equivalent to the arrangement of the multi- ) And waterproofing equipment (680q), and hydroelectric power plant (233) multi-tiered hydroelectric generators (213). The hydroelectric power plant is composed of a seesaw type of hydraulics and a marine tidal power plant.
The previous
As described above, the marine hydroelectric power
The butterfly valve 622 for adjusting the buoyancy of the
In the hydraulic plant of the hydro-
The type of the
The
As described above, the marine power plant body dock hull 810b of the marine hydroelectric power generation and
The butterfly valve 622 for adjusting the buoyancy of the
(680o), power generation facilities (680p), and waterproof facilities (680q) are installed in the water intake facilities (680n) while the water power facilities in the hydroelectric power plants are classified according to their functions while the water- ), Which are divided into four types, are facilities that use flow rate and free fall,
The hydroelectric plant of the
Hull position shift of a marine hydroelectric power station floating structure (593,594,595) constituting on the upper part (SDU) of a dock hull deck of a marine power plant body included in a disaster prevention device unit (811) constituting a dispensing apparatus main body (1) It is based on the theoretical physics method of the Bernoulli theorem of the connection structure showing the construction of the position control structure of the tugboat winch (137) and the sluice gate (293) for the sluice opening and closing control with a rope or a chain wound on the control fuselage. The hydrodynamic properties of water and hydrodynamics are included in hydrodynamics to simplify the installation conditions of the marine power plant of the present invention.
In the physical properties of water, the density of water is maximum at 4 [℃] under atmospheric pressure and varies somewhat with temperature, but since the change is very small, it can be treated as having a constant weight in normal hydrological calculations. 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.
If there is a difference in flow velocity within the working fluid, a force is generated that resists its relative motion. This property is called the viscosity or internal friction and was to that the extent indicated by viscosity, determine the order of the depth H [m] a high cross-sectional area A [㎡] from the surface of the water, which stop, as primer in the hydraulic 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.
That is, since W = ωAH [kg], the average force p [kg / T m2]
As shown in Figs. 24 to 64, the p is called the pressure intensity or the 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, And this time
In hydrodynamics, the law of motion of a fluid (water) is treated, and the motion of a fluid is largely divided into a flow, a vortex, and a wave. When a flow is divided again, a stream becomes a square geometric line without being disturbed. It becomes turbulent and becomes a flowing turbulence. 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 [㎥])
Speaking of the stage area, each A 1 [㎡], A 2 [㎡] The average flow velocity on the two points on the leading and surrounded by a solid of the channel, such as a, b υ 1 [m / s], υ 2 [m / s] , The quantity of water flowing from point a in unit time is A 1 B 2 [
By water flowing at a rate υ is thought to have the head that corresponds to the height of the yisangron H bottom in a water bath with the H (= υ 2/2 g ) as the velocity head and the cross-sectional area relative to Torricelli's Law to the end ① A very small hole on the side of the body, this relation 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 expressed by Bernoulli's theorem
As described above, the marine hydroelectric power generation and production unit 811b for producing the power of the typhoon destruction and disaster prevention device unit 811 constituted inside the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention body, (678c) and conceptual diagram of reservoir plant (678d) showing the construction machine position control arrangement of hull locomotion control of marine hydroelectric power station flood control station (SDU) Hydroelectric power plant of conceptual diagram (678e) Marine power of hydroelectric power production producing power for generating power of typhoon destruction device part (811) constituting main body (1) The marine hydroelectric power station flotation readers 593 and 594 and 595 provided as the unit 811b are connected to the hydraulic rotary cylinder 620 of the rack and pinion type NRP which is a rotary cylinder and the buoyancy control butterfly The vertical partition wall 605 constituted by the dispensing and dispensing apparatuses for stormwave disaster provided with the hydraulic cylinder 622 and the hydraulic cylinder door 624 in the hydraulic cylinder 623 and the pin coupling shaft 606 for the portable lug coupling, A large flange connection connector joint area machining hole 615 in the portable lug 607 and a portable lug pin 608 is connected to the construction machine link structure and the bridge pier 928 and the pipe bridge 937 in the interior of the marine tunnel transport device 941 The marine tunnel transit device internal train 771 to the inside of the marine tunnel traffic device 941 at the bridge piercing drilling machine 908 and the bridge bridge 937 to the crude oil-
(680o), power generation facilities (680p), and waterproof facilities (680q) are installed in the water intake facilities (680n) while the water power facilities in the hydroelectric power plants are classified according to their functions while the water- ) Is a facility that uses flow rate and drift, and the hydraulic system of the
The theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated, and the water intake facility 680o, the power generation facility 680p and the
The
(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 ~ 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. When the downstream part of the river is used, the amount of water to be used can be increased, but the drop amount becomes smaller. On the other hand, the water amount in the upstream part of the river is generally decreased.
[Table 1] Approximate values of aberration and generator efficiency
In the types and facilities of hydroelectric power plants, hydroelectric power plants are classified into various categories according to the methods of water intake and operation. 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 considerably high and it is not an economical method because it has a large area of burial. However, in addition to the aptitude terrain, it is often used for irrigation or flood control reservoirs, This dam is the most useful in Korea and it is very important to construct this dam in future.
A dam constructed for the purposes of power generation, irrigation, and flood control is called a multipurpose dam. In addition, when the dam type is used, it is often impossible to avoid a considerable fluctuation due to the imbalance between the amount of rainfall and the quantity of water used. Such a power plant may be called a parachute power plant in particular.
This is because the more abundant the water stored in the dam is, the economically advantageous and also the desirable from the viewpoint of operation, so many kinds of power plants are built in the lower part of Han river system which is relatively sloping and abundant in Korea (Chuncheon, Cheongpyeong, Paldang, Soyang River Power Plant, etc.)
As described above, the marine hydroelectric power production and production unit (811b) for producing the power constituted inside the dispensing and dispensing apparatus main body (1) of the typhoon disaster prevention body, the dock of the marine power plant, (678c) and a conceptual diagram of a reservoir plant (678d) showing the construction machine position control arrangement of the hood locomotion control of the plant (593,594,595) Hydraulic power plant of the concept map of the power plant (678e) The marine hydroelectric power generation and
The butterfly valve 622 for adjusting the buoyancy of the
(680o), power generation facilities (680p), and waterproofing facilities (680p) are installed in the water intake facilities (680n) according to the functions of the hydraulic power plants in the hydroelectric power plants, (680q) are hydraulic facilities of hydroelectric power plant (233) which shows the construction arrangement of the construction machinery to control the displacement of the hull of the marine hydroelectric power plant floating guard (593,594,595) .
On the other hand, the theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated, and the water intake facility 680o and the power generation facility 680p are installed in the water intake facility 680n, ) And waterproofing equipment (680q), hydro-power plant (233), multi-tiered hydroelectric power generators (213), and the hydro-electric power plant is composed of the seisio form of the hydraulic system and the marine tidal power plant
As shown in Figs. 24 to 64, the conventional hydraulic
According to the function, the hydraulic equipment which is divided into 4 kinds of water intake facilities (680n), power generation facilities (680p) and waterproof facilities (680q) is a facility using flow rate and dropping water, The hydropower plant of the
The theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated, and the water intake facility 680o, the power generation facility 680p and the
As shown in Figs. 24 to 64, the hydroelectric power plant of the conventional concept of the dam
As described above, the marine hydroelectric power generation and
The butterfly valve 622 for adjusting the buoyancy of the
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 hydropower plant of the
The water turbine 680o and the power generation equipment 680p are connected to the water intake equipment 680n which is equivalent to the arrangement of the multi-stage
24 to 64, 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 a conceptual diagram 678e of an adjusted- The flow rate exceeding the maximum use amount is not used for power generation but is discharged in an invalid manner because there is no
In this way, the construction cost does not need to be large, but the generated power changes depending on the natural flow rate. Also, since the natural flow rate also fluctuates according to the season, the water supply can be smoothly supplied In Korea, there is no power plant of this type. However, in the rich stream such as Russia (Siberia) or Brazil, an inflow type power plant which uses natural flow as it is for power generation is constructed and operated, and the following reservoir type power plant is used for seasonal river It is a power plant with a large reservoir capable of adjusting the flow rate. It is a power plant that stores the water remaining in the feng shui and discharges it to the dry season to effectively use the river flow over a long period of time (usually one year).
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 water system with low flow rate, , 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
As shown in Figs. 24 to 64, in the hull position moving pumping
Marine power plant body dock Ship bridge (937) with bridge pier (928) and ship bridge (937) showing the arrangement of construction machine position control of hull position control of marine hydroelectric power station levitation stand (593,594,595) 941 constitute a construction machine connection structure included in the
As shown in Figs. 24 to 64, the hull position shifting
As shown in Figs. 24 to 64, a hydraulic power plant of a conventional hydroelectric power plant or an offshore
The existing power plants are Cheongpyeong (400,000 kW), Samrangjin (600,000 kW), Muju (600,000 kW), Sancheong (700,000 kW) and Yangyang (1 million kW) These are all the latter's power plant,
As shown in the drawing, the hull position moving pumping
As shown in Figs. 24 to 64, in the conventional tidal power plant, the above tidal power generation is a power plant for converting the potential energy due to the tidal difference of seawater into electric power. . 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 power of 10,000 [kW] and 24 of 240 km [kW] using a maximum of 13 [m] and an average of 8.5 [m]. The biggest problem of this power generation is location condition, 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.
In the past, a tidal power development plan has been planned in several places around Chungcheongnam-do 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
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 drawing, the hull position moving pumping
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) And is a hydroelectric facility of the
The theoretical hydraulic power for controlling the flow rate of the seaweed is provided as an input to the aberration to rotate the aberrator and the generator. The water intake facility 680o and the power generation facility 680p are connected to the water intake facility 680n, And waterproofing equipment (680q), hydroelectric power plants (233), and multi-tiered hydroelectric generators (213). The hydroelectric power plant is composed of a seesaw type of hydraulic system and a marine tidal power plant.
As shown in FIG. 24 to FIG. 64, the positional relationship and the cross-sectional view of each power plant in the Han River system where the majority of hydroelectric power plants in the country are concentrated in the connection structure of the conventional Toricelli's construction machinery are shown.
As shown in Figs. 24 to 64, the hydro-electric power generation and
This relation is called Torricelli's theorem. Actual is the actual speed of ejection υ 2 'is slightly smaller than the so υ 2 are shown because of the frictional losses in the water viscosity, and vents.
The
As shown in Figs. 24 to 64, in order to install a conventional hydraulic pressure pipe, a
The pressure in the hydraulic pipe (191) should be determined so that the pressure due to the water hammer action acts as the internal pressure, so that the thickness t [cm] of the pipe can sufficiently withstand the maximum water pressure applied to the pipe. diameter of D [cm], the maximum pressure P [kg / ㎠], the steel material allows stress (Yes tension) to σ [kg / ㎠], the joint efficiency of tube η [%], free thickness for corrosion of ε [cm], the tube thickness t [cm] is calculated by the following formula.
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).
The structure of the waterproofing basin is almost the same as that of the above-mentioned waterway, but it was 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.
Similarly, the principle of hydropower generation is explained 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.
In Korea, recently, large dams have been constructed and artificial reservoirs have been made to regulate, develop, and irrigate floods. In addition, water has pressure, position energy, and is often held as a form of potential energy in nature . 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.
Speaking of water generated power P kg o m / sec are free fall to H m, the flow rate Q ㎥ / sec, ratio by weight of the r kg / ㎥ water (P = rHQ kg o m / sec) hydraulic power, so is the free fall and flow And the flow is related to the watershed and the rainfall. The output generated here is proportional to the product of the drop and the yield, so it depends on the packaged hydraulic power at the top of the power plant. In order to increase the output at this time, it is necessary to artificially change the water flow to concentrate the water in one place and to select a power generation point where a large head can be obtained, and water of the present quantity Q [
( P o = 9.8 QH [kW]), which is usually called hydrodynamic.
Theory hydro is to become the input to the aberration rotating the aberration, the generator, and when said aberration output P t and the generator output P g is the aberration efficiency η t, η g the generator efficiency, respectively, (P t = 9.8 QH η t [kW]) ( P g = 9.8 QH η t η g [kW]).
As shown in the figure, as shown in the drawing, the inside of the dispensing and dispensing apparatus
Since the hydropower plant is a facility that utilizes flow and dropping, it should always be built so that the flow necessary 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 divided into 4 types of water supply facilities (680n), water supply facilities (680o), power generation facilities (680p) and waterproof facilities (680q) In addition,
The hydropower plant of the
The theoretical hydraulic power for controlling the flow rate of the seaweed is input to the aberration, and the aberration and the generator are rotated, and the water intake facility 680o, the power generation facility 680p and the
Therefore, Inventor Registration No. 0546221 by the inventor of the present invention registered the registered multipurpose stair maneuvering manhole in three steps to prevent the danger of losing the life of the worker and obstructing the road traffic flow according to the passage of the vehicle. It is the same as the ground surface at the moment when it goes away from the installation position. It is another equipments to the lower end of the manhole cover after the level is uniformly set. The entrance hole of the manhole of the patent 10-0650936 is the manhole of the manhole. In order to solve this problem, the paraffin liquid was injected into the key inserting port for 3 minutes, and then the paraffin liquid was injected for 3 minutes from the paraffin liquid for 3 minutes Later, as the paraffin becomes solid, In addition to not being sad, it is a device that makes it impossible to insert a key in the solid state. Therefore, if the principle is not known, the key expert can not approach the inside of the manhole. At the same time, It is not possible to identify the location where the gas is fumigated, and if the evacuation personnel can not evolve, the expansion nozzle of the present invention is used to prevent carbon dioxide and halon gas from flowing into the front and rear of the manhole gas exposure site by the underground line And it is possible to precisely control the installation position of the pipe nozzle by the clearance space of the manhole cover in the multi-purpose stepped manhole form and the manhole cover which are formed in the double pipe structure without approaching the ignition field without the person hurt. To the domestic No. 10-1167145, the pipe nozzle moving type fire sensor pump is a device for the fire department, and the low temperature detection efficiency with the sensor of the existing fire detection equipment is very fast and the detection speed of the candle is very fast. In the early stage of evacuation, the water evacuation control system was constructed so that the initial evolution of the evacuation can be accomplished in less than 1 second. It is possible to disclose a technology for sequentially removing a plurality of natural disasters at the same time, so that it is very helpful to understand the technique of the present invention.
The inventors of the present invention have made clear that the contents of the application No. 10-2014-0064709 and 10-2014-0064788 filed in the domestic application clearly state that the harmful tidal flats and large forest fires are not affected by the flood drought in the dust storms and typhoons, In order to prevent the above disasters, equipment for preventing disasters caused by disasters is provided as a distance crossing the South Pole and the North Pole at the latitude of the equatorial line, and at the same time, In order to ensure the happiness of a peaceful global village without war and an artificial disaster by eliminating the natural disasters of the uninjured global village constituted by the tube nozzle body, the tube nozzle hole is made porous and the electronic sensor valves It is configured to be guaranteed to function automatically so that it can be expanded and closed automatically.
The multi-purpose dams prevent water-related disasters through flood control in the flood season and provide water for living, agricultural water, and river maintenance by dripping water in a stable manner. In the marine tunnel transportation device (941) In order to prevent the sailing vessel from sinking the ship into the strong wind wave by injecting the distribution input device of the dam construction machine, the evacuation facility of the guided mooring device which forms the shelter at the certain distance is exposed to the upper part of the sea surface, The hydropower generator utilizes the flow velocity of the Kyushu-shi algae to generate hydroelectric power, and the clean power source is supplied to the circular
In this way, despite the fact that it is a major infrastructure for social overhead capital, the multi-purpose dam has recently faced a situation where the social conditions surrounding the construction of the dam are very difficult due to various reasons such as decrease in dam land, increase of interest in environment, Therefore, it is necessary to seriously review the efficient water management process in addition to the diagnosis of the necessity of multi-purpose dam construction at the present time.
The circular
Each of the
The electric power is generated by the
In order to overcome the above-mentioned plurality of flood disasters, the storm disaster
Before construction of the
In order to overcome the above-mentioned plurality of floods, it is possible to supply the cooling water provided in the
And a typhoon disaster prevention facility for controlling the flow rate and the flow of the gas to the facility safety control and management
The level of skill of the present invention is such that the word 'control activity' is a level that is removed or excluded altogether. It eliminates disaster damage that blows like snowballs. It is a disaster prevention system of a disaster prevention system The present invention has been made for the purpose of the present invention, and it is possible to form the construction equipment and the heavy construction equipment of the present invention in the present invention, so that the future-oriented marine power plant body including the future blueprint of the global political, economic, cultural, The inside of the building is a technical feature. According to the invention, the typhoon disaster prevention device of the present invention allows the residents residing in the Seoul area to drink water from Mt. Sorak or Jirisan when the faucet is full, and residents living in Pusan area can drink water from Mt. And on the day when peaceful reunification takes place The hurricane annihilation
In addition, the damage of typhoon is human, physical, and astronomical, and 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 Meteorological Agency. When the weather forecast is announced so that the damage does not occur, the fruit of the orchard is harvested by the whole country as a volunteer service before the typhoon arrives and stored in the freezing warehouse. As a method for coping with floods is desperately required, a hurricane annihilation / disaster
In order to solve the above-described problems, the present invention is not limited to the conventional dispensing apparatus for dispensing the hurricane. Therefore, the damage is an astronomical value,
The present invention relates to a dispensing apparatus for preventing a typhoon. More particularly, the present invention relates to an apparatus and a method for installing a tornado tunnel to mitigate a catastrophic typhoon and storm surge, A construction machine crane that is a distribution input device of the above-mentioned typhoon disaster which is formed so as to exclude the influence of a natural disaster by a disaster prevention device by inputting a floating plant of a power plant into a river mouth and the sea, a reeducer form and a cap connected to a conveyor and an electronic control device The present invention relates to a dispensing and dispensing apparatus for a typhoon disaster prevention system for controlling a tornado approaching a typhoon and a storm occurring in a large plains of an unspecified country in the world,
The technical problem to be solved by the present invention is to provide a small, medium and large marine nuclear hydroelectric power station with a lifelong learning device. In the northern part of the equatorial psoriasis, typhoons, tornadoes and erosion are caused by the rotation and rotation of the earth, In this case, the downward flow of the typhoon is controlled by a vacuum pump, so that it can be repelled by the counter-clockwise echo. Alternatively, the descending air stream, which is the seed of the typhoon, Which is installed in the intake port of the upper deck of the deck so as to open the door to the counterclockwise echo in the air reservoir of the deck so that the flow of the air is counteracted by the counterclockwise echo, .
According to the present invention, according to the long-term weather forecast provided by a satellite, the landed tundra on land has water, a vacuum pump, and a large number of fire trucks for controlling the air flow, so that the flow rate and the air flow The other purpose is to provide a global dispatching and dispensing device for airflow-controllable typhoon disaster, which is installed in a counterclockwise echo so as to reduce the wind.
In order to achieve the above object, the present invention as a technical idea is a dispensing device for a typhoon disaster prevention,
The double tunnel structure penetrating through one side of the intake dam of the distribution shaft 357 constituting the inside of the dispensing and inputting apparatus
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an
According to the long-term weather forecast provided by the satellites, there are many fire trucks that control the water, vacuum pump and air flow in the way that the tornadoes travel on land, so that the flow and gas flow in the center of Dolphong, This system consists of a power generation dam construction machine and a borehole (936) storm disruption dispenser that constitutes the distribution input device of the airflow-variable typhoon disaster preventing the wind to sink into the inside of the marine hydroelectric power plant flood control station (593,594,595) A
The typhoon dis- tribution dispensing apparatus is connected to one side of a marine hydroelectric power
And is disposed inside the dispensing and dispensing apparatus
The hydraulic
A
Below the
A low speed rotation bearing 225 is disposed in the
The
The distribution shaft 357 connected to the distribution shaft 357 of the storm disaster prevention distribution dispensing apparatus is provided with an electric power generating unit for generating hydroelectric power by rotating a number of aberrations by adjusting the diameter of the
When the dangerous tidal redism warning is issued in a drought period, the
The water stored in the peak acid
The flood control apparatus is connected to the
The hydraulic power generator connected to the
A plurality of power pumps 304 connected to the
The portable lug connecting
Alternatively, each of the
Each of the
And a plurality of disaster
The
Water is inserted into each
In the
And is connected to one side of a marine
The
And is connected to one side of a marine
In the
Connected to one side of a marine hydroelectric power plant
An
The emergency valve 84 of the disaster prevention
The
.
According to an aspect of the present invention, there is no conventional dispensing apparatus for dispensing a typhoon, so the damage is an astronomical value,
In order to solve the above-described problems, the present invention is not limited to the conventional dispensing apparatus for dispensing the hurricane. Therefore, the damage is an astronomical value,
The present invention relates to a dispensing apparatus for preventing a typhoon. More particularly, the present invention relates to an apparatus and a method for installing a tornado tunnel to mitigate a catastrophic typhoon and storm surge, A construction machine crane that is a distribution input device of the above-mentioned typhoon disaster which is formed so as to exclude the influence of a natural disaster by a disaster prevention device by inputting a floating plant of a power plant into a river mouth and the sea, a reeducer form and a cap connected to a conveyor and an electronic control device The present invention relates to a dispensing and dispensing apparatus for a typhoon disaster prevention system for controlling a tornado approaching a typhoon and a storm occurring in a large plains of an unspecified country in the world,
The technical problem to be solved by the present invention is to provide a small-sized, medium-sized and large-sized marine nuclear hydroelectric power station with a lifting-type poison, and at the northern part of the equatorial line, typhoons, tornadoes, And the lower air stream is repelled by a counter-clockwise echo by a vacuum pump. In addition, the air conditioner is provided with a redistribution type and a distributor / dispenser for airflow- Type air intake unit to open the door from the upper deck deck air reservoir to the counterclockwise echo to eliminate the flow of air by counter-clockwise echo, and to provide the distribution input unit of the variable air- Will be,
According to the present invention, according to the long-term weather forecast provided by a satellite, the landed tundra on land has water, a vacuum pump, and a large number of fire trucks for controlling the air flow, so that the flow rate and the air flow It will be possible to construct the distribution input device of the airflow-variable typhoon disaster preventing the wind from being put into the counter-clockwise echo.
FIG. 1 is a schematic diagram showing the classification of a typhoon for explaining a general outline of a typhoon constituting the inside of the dispensing and dispensing apparatus main body according to the present invention, and the name of a typhoon. FIG. 1 is a cross-sectional view of a monthly average steep slope of a typhoon showing characteristics that illustrate an embodiment.
FIG. 2 is a sectional view of a typhoon dispatching and dispensing apparatus according to an embodiment of the present invention. FIG. 2 is a perspective view of a typhoon dispatching and dispensing apparatus according to an embodiment of the present invention. Sectional view of hazardous semicircle.
FIG. 3 is a diagram illustrating a tornado and a spill included in a typhoon constituting the inside of a dispensing and dispensing apparatus main body according to an embodiment of the present invention. Sectional view of tornado and erosion.
4 is a view showing the construction of a
5 is a schematic view showing a structure of a hydroelectric power
6 is an external view of a diesel engine showing a configuration of an offshore hydroelectric power
7 is a front sectional view and a front view of a multi-stage multi-stage pump showing the structure of the facility safety
8 is a microcomputer of a multi-stage multi-stage pump showing the configuration of the facility safety
9 is a schematic view showing a structure of an electronic control device
10 is a schematic view showing a structure of a typhoon destruction and
FIG. 11 is a schematic view illustrating a structure of a hurricane annihilation /
[Fig. 12] Fig. 12 is an exploded perspective view showing the structure of the facility safety
[Figure 13] is a schematic diagram of an apparatus for safety control and control of an entire system (811e) included in a typhoon dissipation / disaster prevention device unit (811) constituting a main body of the dispensing and dispensing apparatus according to the present invention, and a sprinkler system piping system sprinkler system And a tilt configuration of the sprinkler head (111) of the trench head and the vibration alarm device (300).
FIG. 14 is a schematic view showing a reciprocating
15 is a perspective view showing the entirety of the equipment safety
16 is a diagram showing a main problem in driving the pump showing the configuration of the facility safety
17 is a view showing a fire pump showing the structure of the facility safety
18 is a diagram showing an operation method of each valve showing the configuration of the facility safety
19 is a perspective view showing a configuration of a dam control unit
20 is a diagram showing a turbine pump 140 (FIG. 20) showing a configuration of an electronic control adjusting device
[Figure 21] is a view showing an operation of an automatic collecting tank showing an arrangement of an electronic control adjusting device
22 is a view showing an operation of an automatic collecting tank showing the configuration of an electronic control adjusting device
23 is a view showing an operation of an automatic collecting tank showing the configuration of an electronic control adjusting device
24 is a sectional view of a conventional
25 is a schematic view showing a structure of an electronic control adjusting device
FIG. 26 is a view showing an operation method of an adve- lune and an airship showing the configuration of the facility safety control management
[FIG. 27] FIG. 27 is a schematic view showing a construction of a plurality of constructions (construction) showing a construction machine position adjustment structure constituting a hull displacement
[Fig. 3] to [Fig. 27] are diagrams for illustrating an embodiment in which the inside of the main body of the dispensing and dispensing apparatus according to the present invention is constituted.
FIG. 28 is a view showing a construction of a
29 is a view showing a configuration of a crane of a construction machine constituting a hull
[Figure 30] is a schematic view showing a structure of a crusher, which shows a configuration of a construction machine position control constituting a hull
[Fig. 31] is a graph showing the overall configuration of a typhoon destruction and
FIG. 32 is a schematic view showing the structure of a storm surge
FIG. 33 is a schematic view showing the structure of a storm surge
FIG. 34 is a schematic view showing the structure of a storm surge
FIG. 35 is a schematic view showing the structure of a hull dislocation
FIG. 36 is a schematic view showing the structure of a storm surge
[Figure 37] is a schematic view showing the structure of a storm surge disruption prevention unit (811) constituting a main body of the storm disaster prevention dispensing apparatus according to the present invention, (853) and the trailer (860a) of the dump truck (860) to the loader (857) showing the construction machine position adjustment arrangement of the hull locomotion control of the constituent marine hydroelectric power plant floodplain (593,594,595) Degree.
FIG. 38 is a schematic view showing the structure of the hull disaster prevention and dismantling
[Figure 39] Figure 39 is a schematic view showing the structure of a storm surge
FIG. 40 is a schematic view showing the structure of a hull disaster prevention and dismantling
FIG. 41 is a schematic view showing the structure of a storm surge
[FIG. 42] is a schematic diagram showing the structure of a hull disaster
[Figure 43] is a schematic view showing the structure of the hull disaster prevention and
FIG. 44 is a schematic view illustrating a marine hydroelectric power
[Figure 45] Figure 45 is a schematic view showing the structure of a storm surge
46 is a view showing a marine hydroelectric power
[Figure 47] Figure 47 is a schematic view illustrating a hull position shifting
[48] FIG. 48 is a schematic diagram illustrating an example of a structure of a storm surge
[Figure 49] Figure 29 is a schematic view showing an example of the structure of a storm surge suppression device according to the present invention, in which a marine hydroelectric power production control section (811b) A schematic view of a hydroelectric power plant construction machine connection structure showing a construction machine position control arrangement of a hull locomotion control of a marine hydroelectric power plant floating structure (593,594,595) at the upper deck (SDU).
FIG. 50 is a schematic view showing an example of a marine hydroelectric power
[Figure 51] is a diagram illustrating a marine hydroelectric power
FIG. 52 is a diagram showing the structure of a storm surge
FIG. 53 is a schematic view illustrating a marine hydroelectric power
FIG. 54 is a schematic view showing a marine hydroelectric power
[55] FIG. 55 is a schematic diagram of a marine hydroelectric power
FIG. 56 is a schematic diagram of a marine hydroelectric power
[Fig. 57] Fig. 57 is a view showing the entire construction of the typhoon dissipation /
FIG. 58 is a schematic view showing the structure of the hull disaster prevention and dismantling
[Figure 59] Figure 59 is a schematic view illustrating a hull displacement moving
[0064] FIG. 60 is a schematic view illustrating a hull displacement
FIG. 61 is a schematic view illustrating a marine hydroelectric power
62 is a diagram showing an example of a marine hydroelectric power
FIG. 63 is a block diagram showing a marine hydroelectric power
FIG. 64 is a block diagram showing a configuration of a marine hydroelectric power
[65] FIG. 65 is a block diagram showing a marine hydroelectric power
FIG. 66 is a schematic view showing a marine hydroelectric power
FIG. 67 is a schematic view showing an example of a marine hydroelectric power
68 is a diagram showing a marine hydroelectric power
[69] FIG. 69 is a schematic view showing an example of a marine hydroelectric power
FIG. 70 is a schematic view illustrating a marine hydroelectric power
[FIG. 71] is a graph showing the overall construction of the typhoon dissipation /
72 is an enlarged perspective view showing a main part of a
FIG. 73 is an enlarged perspective view showing a main part of a
Each of which is disposed inside the
74 is a view showing the structure of the double storey block tank of the marine hydroelectric power
[Figure 75] Figure 75 is an exploded perspective view of a typhoon disaster
[Figure 76] is a diagram illustrating a structure of a double structure block tank (811a) of a marine hydroelectric power plant flood control station (811a) included in a storm disaster prevention device unit (811) constituting the inside of a dispensing and inputting apparatus main body according to the present invention 598) Double structure block tank showing the preparation process of cutting and underwater welding with a marine safety
Each of which is disposed inside the
[FIG. 77] FIG. 77 is a schematic diagram illustrating a disaster prevention
FIG. 78 is a schematic diagram showing an apparatus for safety control and control (811e) included in a typhoon destruction and
[79] FIG. 79 is a schematic view showing an apparatus for safety control and control of a typhoon destruction and
FIG. 80 is a diagram showing an example of a disaster prevention prevention and
FIG. 81 is a schematic view showing an apparatus safety
FIG. 82 is a diagram illustrating a configuration diagram of a multi-pipe fire hose and spray nozzle assembly model included in the typhoon destruction and disaster
FIG. 83 is a schematic diagram showing an example of a configuration of the apparatus for safety management of the equipment included in the typhoon destruction and
84 is a schematic diagram showing an example of a storm surge suppression device according to the present invention, in which the storm
[Fig. 73] to [Fig. 84], respectively, show the apparatus safety
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.
The water tank comprising the air conditioner mechanism of the cooling device, the heating fan for maintaining the air and the cooling fans, and the tanks for controlling the flow of the water and the storage of the water,
In the manufacturing method according to the portable coupling device which can be separated and separated from the crest, the steel plate with the high tension at the lower part of the bottom of the tank excluding the welding process and the lid steel plates at the upper part of the tank are not attached. A large number of stainless steel plates set in accordance with the specifications of the inner block tank (width × length × thickness; 1.5 m × 1 m × 3 mm) equivalent to that of the square mold while being equipped with 60 cm are molded into a circular tank with bolts and nuts, The inner block tank and the outer block tank, in which each steel plate is joined to the machining hole of the press machine by a gasket before the joining by means of a hand tool, are fixed to the base of the bottom steel bar, and then sand and gravel The cement is mixed with the concrete finisher and the concrete spreader in the construction machine, the concrete batching plant, It is suitable for hydroelectric power generation combined with flood control facilities to overcome flood damage by using water potential energy by making foundation floor of water tank with concrete pump after conveying by RIT MIXER truck and using concrete pump. Water storage and flow flow A power generation control unit connected to a distribution shaft constituted by the tanks for controlling the flow of the typhoon and the typhoon disaster prevention unit for controlling the flow rate and the flow of the gas into the main body of the dispensing and inputting apparatus for the typhoon disaster, It is necessary to provide the capacity of the internal groundwater and the deep sea water to the inside of the main body of the dispensing and dispensing apparatus for typhoon disaster with a plurality of power pumps installed at the water intake station, and to control the flow of the gas and the typhoon. Control management front and electronic control control equipment construction machine control unit for typhoon disaster prevention dispensing equipment Flood control of the quick flooding and drought overcome constituting into the body and relates to a hurricane emergency adjustment distribution chute that is configured to fulfill the storm destroyed.
The distribution input device for the emergency typhoon disaster prevention system for a marine hydroelectric power plant in a marine tunnel traffic device having a control shaft for controlling the flow rate and gas flow of the typhoon disaster prevention equipment constituting the dispensing and inputting apparatus main body of the typhoon,
External tank tanks in holding tanks and inner block tanks The length of connecting shafts for connecting the lugs to the inner and outer walls of each tank is 800mm, the diameter is ∮300mm, the length of the iron lugs of the portable lugs is 150mm, (Diameter ∮ 30 mm) of the connection pin connecting shaft is connected to a portable lug pin (length x
The distribution input device of the marine hydroelectric power plant flood control device in the marine tunnel traffic device of the control shaft for controlling the flow rate and gas flow of the typhoon disaster prevention equipment constituting the main body of the storm disaster prevention distribution dispensing apparatus is composed of a holding tank and an inner block tank, The length of the pin connection shaft for the inner lug and the outer wall of each tank is 800 mm, the diameter is 300 mm, and the iron lug of the portable lug is 150 mm, the pin is connected to the lug through a pin connection shaft, The processing hole (diameter ∮30mm) is equipped with a portable lug pin (length x
In a typhoon disaster dispensing device,
The double tunnel structure penetrating through one side of the intake dam of the distribution shaft 357 constituting the inside of the dispensing and inputting apparatus
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an
According to the long-term weather forecast provided by the satellites, there are many fire trucks that control the water, vacuum pump and air flow in the way that the tornadoes travel on land, so that the flow and gas flow in the center of Dolphong, This system consists of a power generation dam construction machine and a borehole (936) storm disruption dispenser that constitutes the distribution input device of the airflow-variable typhoon disaster preventing the wind to sink into the inside of the marine hydroelectric power plant flood control station (593,594,595) A
The typhoon dis- tribution dispensing apparatus is connected to one side of a marine hydroelectric power
And is disposed inside the dispensing and dispensing apparatus
The hydraulic
A
Below the
A low speed rotation bearing 225 is disposed in the
The
The distribution shaft 357 connected to the distribution shaft 357 of the storm disaster prevention distribution dispensing apparatus is provided with an electric power generating unit for generating hydroelectric power by rotating a number of aberrations by adjusting the diameter of the
When the dangerous tidal redism warning is issued in a drought period, the
The water stored in the peak acid
The flood control apparatus is connected to the
The hydraulic power generator connected to the
A plurality of power pumps 304 connected to the
The portable lug connecting
Preferably, the pumping
Each of the
And a plurality of disaster
The
Water is inserted into each
In the
And is connected to one side of a marine
The
And is connected to one side of a marine
In the
Connected to one side of a marine hydroelectric power plant
An
The emergency valve 84 of the disaster prevention
The
.
The following description will be made with reference to Figs. 65 to 84. Fig.
Referring to FIG. 65, a marine hydroelectric power generation and
Referring to FIG. 66, a marine hydroelectric power generation and
Referring to FIG. 67, a marine hydroelectric power generation and
68, a marine hydroelectric power generation and
69, a marine hydroelectric power generation and
Referring to FIG. 70, a marine hydroelectric power
Referring to FIG. 71, the flood control system of the stair-step dam rotation path located at the ridge line of the mountain showing the entire structure of the typhoon dissipation
Referring to FIG. 72, a
Referring to FIG. 73, a
69 to 73 show the hull position moving
Referring to FIG. 74, the double
Referring to FIG. 75, a hull position shifting
Referring to FIG. 76, there is shown a double structure block tank of a marine hydroelectric power plant flood
69, 70, 71, 72, ... are respectively disposed in the
Referring to FIG. 77, the facility safety
Referring to FIG. 78, the facility safety
Referring to FIG. 79, the equipment safety control and
Referring to FIG. 80, it is assumed that a fire in an indoor facility safety
Referring to FIG. 81, the facility safety
Referring to FIG. 82, the multi-pipe fire hose and injection nozzle assembly model diagram included in the typhoon destruction and disaster
Referring to FIG. 83, it can be seen that the initial safety of the facility safety
Referring to FIG. 84, the equipment safety
Figures 73 to 84 illustrate an embodiment of the facility safety
As shown in Figs. 65 to 84, the
The floating pump and the
The disaster prevention water of the water pressure inside the pump piping line hose is discharged from the nozzle gap into the discharge jetting water and the radial curtain water film and is equipped with a water mountain range so as to adjust the flow of the
As shown in FIG. 65 to FIG. 84, the
In order to resolve the disputes over land territorial waters of the world, all military materials and bomb manufacturing experiments should be kept at designated places in the sea, while being preserved as a management form of international peacekeeping force, According to the results, the user can obtain a victory for a country or an individual having a high score through the
It is equipped with a maritime anti-piracy eliminator that can be seen in unspecified areas of the sea, while changing one of the engine propeller (146) and the skewer (147) wing to allow pirates to dive into the water together with the pirate ship In order to maintain the close relationship between the ignition material and the disaster prevention material of the fire source, the communication equipment of the Internet control system before and after the fire occurred, a plurality of pumps and the pump electronic control device, the high performance submersible pump (36) (80) and a plurality of frames in an air storage tank and a wire rope, and a portable transporting equipment. A connecting structure including a helicopter and an airship in an adventure balloon, A typhoon disaster prevention process comprising a facility
As shown in Figs. 65 to 84, a hurricane-type hull locomotive pumping
65 to 84, the dispensing and inputting apparatus of the dive-ready-proceeding-operation-control-device located inside the dispensing and dispensing apparatus
In the block tank hull disassembly-type
A plurality of lug processing holes 615 and an elongated hole 616 for a block tank block unit hull breaking-disassembling position shifting device to form a horizontal block tank hull disassembly-coupling portable lug
The double
A distribution shaft of the adjustment shaft constituted by the inside of the dispensing and dispensing apparatus
65 to 84, the
Since the table-top legs are equivalent to the table-top and the table-top legs are equivalent to the holding tank (590) of the barge hull, the table-top table can be freely moved up and down by manpower, 590 are provided in the hydraulic cylinder 620 and the hydraulic cylinder 623 as hydraulic cylinder doors 624 so that the buoyancy adjusting butterfly valve (not shown) provided in a connection structure with the buoyancy adjusting tank of the barge hull 622 and the buoyancy control butterfly valve 622 having a connection structure to the solenoid valve 76 is provided by operating the on-time main switch button 66 of the solenoid valve start switch button main switch button 66 (591) at the top of the holding tank and the bottom of the holding tank The barge hull 592 is coupled to the holding tank 590 so that the barge hull can be freely lowered and unfolded from the holding tank 590 of the barge hull, A buoyancy control butterfly valve 622 and a solenoid valve 762 provided on a sea surface upper end portion SLU provided on one side of both sides of the holding tank 590 equipped with the buoyancy adjusting tank 609 and connected to the buoyancy adjusting tank of the barge hull, , The buoyancy control butterfly valve (622) having a connection structure to the solenoid valve (76) is provided to provide an operation of the on-time main switch button (66) of the main switch button for the start switch button,
The doors 624 for the hydraulic cylinders are opened by the operation of the
(593,594,595) distributing input device of marine hydroelectric power plant by putting the position shifting device and the throttle control device of the distribution input device of the marine tunnel traffic equipment with the construction machine, (590) connected to one side of a holding tank with a portable lug (607) connected to one side of a barge ship hull attached to one side of the hull, the buoyancy control device of the hull of the barge hull (593,594,595) provided as a holding block tank capable of adjusting the position of the hull at a constant angle from 0 ° to 350 ° vertically and horizontally in the holding tank (590) It is equipped with the main body of the injection device to overcome natural disasters in order to relieve the anxiety of the people peacefully. The power transmission control unit 811d for transferring hydraulic power to both the forward and aft ends of the central portion of the plurality of
In order to renovate the hydraulic equipment, a double structure or a triple structure of a double structure large sliding
A double structure block
The hull attachment separation
The barge hull gradually sinks into the water while losing its buoyancy and is moved to a single vertical processing lug (607) on one side of a holding tank (590) on both sides of the barrel ship hull with a block tank coupling portable lug (607) The lug connecting
65 to 84, the double structure block tank 598 of the marine tunnel transportation device 941 of the marine hydroelectric power station floating navigation device constituting the inside of the dispensing and dispensing apparatus main body 1 of the storm- The marine safety tooling device band guide 621 on the upper half of the sea submerging operation line for performing the assembly of the floating structure block 591 and the double structure block tank 598, The joint separation portable lug 607 and the portable lug pin connection shaft 606 are connected to each other by a pin connection shaft 606 at the sea level while welded wires are welded symmetrically with each other to form a double structure block tank 598 In the marine operation, the tool bar band guide 621 is provided at the upper end of the semi-submerging operation line 637 to connect the large flange 614 at the connection position in units of the double structure block tank 598 to the large flange 614 connection connector The partial coupling of the dual structure block tank 598 is connected to the lever block 123 and the chain block 648 and the band guide 621 and the semi diving operation line 637 are connected to the dual structure block tank 598, Welded joints and flange joints are welded and bolted together with nut assembling tools to construct a double structure block tank (598) of the marine tunnel transport device (941) of a marine hydroelectric power plant floating attachment. And a dispensing device.
The double
At the top of the floodplaintop at the top of the sea surface (SUL), at the top of the floodplain, a tackle winch (137) for controlling the opening and closing of the gate with a rope or a chain wrapped around the fuselage in the block pylon (116) And a lug rotating
The dispensing and inputting device for operating the construction machine as a connection structure of the main body of the dispensing and dispensing apparatus for the storm-
A connection structure of a maritime
(SLU) Floating Standing System Marine power generation facilities located at the upper end of the upper deck of the deck (SDU) The crane boom connecting structure of each crane is provided with a crane boom and a level maintenance weight (107) A hydroelectric power
65 to 84, the distribution input device of the seabed mineral manganese nodule 909 as a connecting structure constituting the inside of the dispensing and dispensing apparatus
As shown in Figs. 65 to 84, the facility safety control management
The water stored in the peak
65 to 84, the storm annihilation
The
The
The heat is dispersed in the oil cooler 151 without the inner cooler 170 and the aft cooler 182 in the
In the facility safety control management
The
65 to 84, the facility safety control management
When the electronic control hydraulic cylinder 620 is pressed by hand on the on-time
65 to 84, in the facility safety control management
A
A disaster prevention piping 89 is provided at the lower end of the high-pressure three-stage multi-stage pump inside the machine room and is attached to the junction connection emergency valve 84 of the
The facility safety control and
And a dispensing device for dispensing a storm to control the flow rate and gas flow,
A fuel piping line having a disaster prevention process and a piping line made of liquid to a gas disposal material piping line are integrally joined together and then a firefighter called a nozzle composed of a pipe nozzle body hose and a piping body in an orderly double- A spray nozzle body B in which a
The burner 173 is adhered to the lower portion of the vinyl tent 77 formed in an advertising balloon (length × width × length: 10 M × 10 M × 10 M, The 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 apparatus is mounted so as to observe the diurnal state of the farther farther from a higher position and the radiosonde 134 is mounted on the lower portion of the spray nozzle body A stacked multi-stage pump 8 as an integral unit, a stacking pipe line 89, a disaster prevention water passage 17, a collecting tank 34 having a double pipe structure, a stack opening 45 in the fire fighting chamber 40, Inside the piping of the communication equipment of the device microcomputer system The engine 144 and the cylinders 138 configured in doctor ventilation and the tumbler winch 137 are connected to the air compressor 80 and the generator 124 by a plurality of valves interrupting the flow of the fuel The head tank 189 and the high-pressure hose 190 are connected to the ground wheel 185 and the tube 188 in the hydrant 179 and the iron structure and the pump inner impeller 143 are connected to the other ignitable materials and the stoichiometric gas 163 The whole area where the fire, flame and pillar are generated is referred to as a fire sensor pump body, and the whole unit (811e) of the safety control and control system constituted by the main body (1) of the typhoon disaster prevention dispenser is connected to the flow (1) All of the fire fighting and disaster prevention industrial equipments necessary for the whole life structure and the early evolution are installed in the disaster prevention earthquake disaster prevention system built in the disaster prevention earthquake disaster prevention system .
In the facility safety control management
The fire-fighting sensor pump, which is composed of the typhoon disaster prevention process which consists of the flow and the typhoon disaster to control the flow of gas, was firstly packed with vinyl coating on the rolled steel for KSD 3507 general pipe, and the connecting coupler connected to the nozzle body was KSD 2331 die- And KSD 3699 hot rolled stainless steel coils. The temperature sensor is replaced by a bimetal or bourdon tube to a paraffin sensor. It is used in diesel engines and fire pumps The solenoid solenoid valve and other standardized general purpose hose pipes are designed to supply both liquid and gas simultaneously in the form of double pipe structure according to their sizes. The sizes of the pipe nozzles are classified into 7 types, Is in the order of a diameter of 200 mm, 180 mm, 150 mm, 130 mm, 100 mm, 80 mm, 50 mm (200 × 180) mm, (180 × 150) mm, (150 × 130) mm, (130 × 100) mm, (100 × 80) mm, and (80 × 50) mm, (50 × 25) mm It consists of 14 types of standard, tube nozzle connected to hose part and tube nozzle of many linear straight-hole processing hole. The working area for the demilitarized zone in the opening area is composed of various types and sizes of pneumatic variable, so that the fire and fire of general combustibles of wood, forest, paper, and futon, which are the ordinary fire of building belonging to each fire class, And the life of the person was saved as fire-fighting and disaster prevention countermeasures by a large number of adverbons and airships, and the destruction of a number of disaster disasters was constituted. In succession, the installation position was set to the inside of a 1200 km radius from the center of the Korean Peninsula, Input device Dispatching device of facility constituting internal part of main body (1) Disaster prevention fire prevention system that constitutes typhoon disaster prevention process composed of facility safety control management whole section (811e) to control flow and gas flow Disaster prevention fire prevention It is made up of disaster prevention countermeasures.
The facility safety control and
A firefighter nozzle (10) used as a plurality of pipe nozzles inside a marine power plant constituting a disaster prevention process equipped with a typhoon disaster to control the flow rate and gas flow has a thickness of 2 mm or more, , The tube joint nozzle has a name of "100" (234), "Nominal 90" (235), "the name of the tube nozzle is" 75
The pipe line (diameter: φ350 mm, vinyl coated flow pipe, 60 mm in diameter) was attached to a plurality of fire-fighting disaster prevention piping lines 168 installed along the mountainous area of the crest, and the tube nozzle 10 was attached to the elbow and the T- Quot; 50 x 40 "(245 ") " to the " nominal 100 x 90" 241, "nominal 90 x 75" 242, "nominal 75 x 65" 243, ) And "nominal 40 × 25" (246), in the same manner as the above-mentioned basic type 1, the fire-tube nozzle is constituted by a reducer 35 having the above- A plurality of 8-segment gaps 15 in the normal position of the injection nozzle 15 and a machining hole 20 constitute an 8-segment nozzle gap at 7 segments of the flange 28 and at a distance of 50 m for safety, The tie elbow 44 connected to the disaster prevention pipe is connected so that the shackle 23 and the bolt 24 are not temporarily released from the flange machining hole 20 to the nut 25 The rope 131 is roped up to the upper end of the body of the nozzle 10 and pulled up from both sides in the opposite direction of the binding position by the shackle 23 to finish fixing with the bolt and disassembled the rope 137, The worker finishes the safety work while dismantling the rope 137 without setting up the worker and the tug winch 37 is provided so that the fire nozzle 10 ) Is equipped with a 15m fire hose nozzle (10) connected to a number of 1km, 2km to 3km length, and each set is equipped with a distribution control device for flood control. Which is a device for controlling the flow of the typhoon.
The facility safety control and
A high pressure piston type
This is connected to a marine
On the other hand, in the facility safety control management
A pressure suction pipe (3) and a discharge pipe (4) are connected to the left and right sides around the suction port around the impeller (143) inside the protective cover of the multi-stage multi-stage disaster prevention pump (8) composed of a storm- Is connected to the
The facility safety control and management
The water supply piping (14) is composed of disaster prevention piping (14), which is composed of a disaster prevention material to control the flow rate and gas flow. Next, the disruption prevention piping (14) (50 × 50 (244)) to 50 × 50 (244) for the name "100 × 90 (241), 90 × 75 (242) for the name and 75 × 65 (243) for the name" 40 × 24 "(246) × 40 (246), the injection nozzle body is connected in the form of an antenna so that the installation is allowed to be mounted, so that the injection nozzle is connected to the pipe line of the injection nozzle body, The
65 to 84, in the facility safety control management
The
It is applied to the versatile multi-purpose range to prevent the spread of large-scale fire and to prevent disasters. It is equipped with a large number of
The power transmitting portion 811d of the adjusting shaft constituting the inside of the distributing and dispensing apparatus
Construct a supply of electricity (685) to the junctions of the cable car (256) of the high and low mountains (395) and the marine pipe bridge (937) and the marine tunnel traffic system (941) And the building of the high and low buildings near the beach of the beach. The
A
65 to 84, the power is supplied from the power transmission portion 811d of the adjustment shaft constituted inside the dispensing and dosing device
The adjustment shaft constituting the inside of the dispensing and inputting apparatus
(811e), which is included in the dispensing and dispensing apparatus for a typhoon disaster prevention system constituted by the inside of the dispensing and dispensing apparatus main body (1) of the typhoon prevention dispensing apparatus, comprises a jet nozzle 10) The
Thus, small and large pipes are used as the small pipes, and disposal water conveying devices are provided for the small pipes. The piping slightly larger than the small pipe is divided into half by the bolt and the natto, and the nozzle gap (15) 4 m, and connected to the high-pressure multi-stage
In the event of a drought (1) with a 1 degree angle of inclination (91) at the ridge line, water is appropriately stored and disposed around the disaster prevention pipe and the disaster prevention pipe around 1 degree angle of inclination (91) To prevent hail damage and cool the heat on a hot day with a holiday resort shoreline on the resort's sandy beach. In areas where visibility is high around the highway due to high fog, a partitioned water film that emits from multiple straight- The fog is removed by means of the means to facilitate the traffic flow and prevent the proximity of the grasshoppers in the fall harvest season, preventing the loss of grain,
Reduction of damage caused by spring dust In order to preserve large-scale bridge management, which is the first steel structure for the preservation of large buildings, it is connected to the distribution shaft (357) in such a wide area. The
65 to 84, the water stored in the mountain-top
Power pump (304) Provide power to machine room and hurricane disaster prevention facility Typhoon destruction and disaster prevention unit (811) installs facilities to prevent natural disasters such as forest fires, yellow snow, snowfall, extreme heat, typhoon, flood and drought and landslide The
When the pressure in the front of the
As shown in Figs. 65 to 84, the equipment safety control management
The
After the
On the other hand, the disaster prevention nozzle, which is provided with a typhoon disaster prevention facility for controlling the flow rate of the flow of the typhoon disaster,
The jet nozzle claw 13 and the
65 to 84, the water stored in the mountain-top
A typhoon disaster prevention dispenser and a typhoon disaster prevention dispenser, and a typhoon disaster prevention and
Power Pump (304) A hurricane annihilation / disaster prevention unit (811) equipped with electric power in a machine room is equipped with a typhoon that provides facilities to prevent natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoon, flood, A flood control process comprising a typhoon disaster prevention facility for controlling the flow rate and the flow of gas is provided in the plant safety control
As described above, a flood control process comprising a typhoon disaster prevention facility that controls the flow of the flow to the facility safety control control center (811e) constituting the inside of the distribution dispensing apparatus
A fire-prevention sensor pump of a pipe-nozzle-type fire-fighting sensor constructed of a typhoon disaster prevention process comprising a facility for controlling the flow rate and a flow of gas to the plant safety control
As shown in FIGS. 65 to 84, a disaster prevention
Hose and piping body of double pipe structure on transportation equipment adver- tune and unmanned airship are adjusted to height and dis- tribution so as to extinguish many disaster disasters. Air and carbon dioxide, which are disaster prevention materials, After the installation of fire water, solid ocher powder and fire sand, the fire pump and air compressor were operated immediately after the detection of heat by the sensor, and a lot of discharge water was discharged to the outside of the pipe nozzle and the fire, flame and pillar were reliably eliminated To be displayed on the monitor through the calculation of the control server of the multi-stage pump control system received from the unmanned camera or mobile service or the mobile phone terminal. The apparatus of the fire prevention sensor pump The sensor pump is installed at each point of the mountain peaks and The disaster prevention material which is fixed to the roof of the building by fixing the eyelid and solidly mixed with the liquid and the gas by the mountain valley or the beach road is firstly surrounded with the combustible gas (non-combustible gas) It prevents the combustion by cutting off the supply and the cooling action to lower the temperature of the combustible to the temperature below the ignition point while cooling the water by the hose while it is evolving in the early stage to save lives, (1) of the above-described typhoon disaster prevention apparatus which ensures the structure and early evolution of the typhoon, and a typhoon disaster prevention facility that controls the flow and the flow of the gas by means of the safety control control section (811e) It is possible to install the fire-prevention sensor pump of the pipe-nozzle type movable accident prevention countermeasure goods which is constituted in the cable car Disruption prevention device for dispatching dispenser 1 is connected to a dispensing shaft 357 constituting the inside of dispensing and dispensing apparatus main body 1 of the disaster-prevention unit, Power is supplied to the fire-fighting sensor pump by the production power of the marine hydroelectric power plant of the typhoon disaster prevention facility composed of the power transmission control unit 811d for transmitting the power constituted to be formed.
The control shaft of the typhoon control dispensing and dispensing apparatus
The
As shown in FIG. 65 to FIG. 84, there is provided a double storm prevention system for controlling the flow rate and the flow of gas to the facility safety control
The
As described above, fire extinguishment in this way was the same as that in the fire-fighting house, because fire-fighting vehicles were usually dispatched after the previous fire, , And a typhoon disaster prevention process comprising a typhoon disaster prevention facility that controls the flow rate and the flow of the gas by providing the facility safety control
In the past, the initial ignition sources that formed the flood control process comprised of the inside of the dispensing and dispensing apparatus
A fire-fighting building comprising a typhoon disaster prevention process comprising a facility for controlling the flow rate and a flow of gas by having the facility safety control management front part (811e) constituted inside the main body (1) of the typhoon disaster prevention distribution dispenser Usually fire is a case of fire spreading on wood, forest and paper, the general fire of the fiber is high and low in mountains, thorny bushes of grassy fields, lawns, grasses and fallen leaves. And the prevention of fire is the best way to prevent carbon dioxide gas and ocher powder from mixing with the fire water in the engine room and the top of the mountain on the rooftop of the large building. Within 2 seconds, combustible gas is surrounded by incombustible gas to block the air supply. The fire fighting fire prevention measures were prepared just before the fire helicopter fire helicopter was dispatched, and a natural swamp composition was formed on the disaster prevention waterway of each ridge line, and the life saving structure of the typhoon
As shown in FIGS. 65 to 84, the disaster prevention
The typhoon disaster prevention process that regulates the flow of the flow that constitutes the inside of the dispensing and dispensing apparatus
As shown in FIG. 65 to FIG. 84, in the case of a non-emergency fire fighting anti-disaster fire fighting equipment for a marine power plant, in which a typhoon disaster prevention process for regulating the flow of the flow constituted inside the dispensing and inputting apparatus main body 1 is formed, The sensor pump includes an electric motor body inside the fire sensor pump, a center circumferential surface portion of a shaft that is a motor center shaft formed on the horizontal center line MBCL of the motor body, a rotating impeller, and a guide vane pump And the pump body is provided with an isolation valve and a check valve for controlling the pressure and flow rate of the fluid and the direction of the flow rate to be controlled by an electronic control device and a flow rate control sensor and pressure Sensor sensor that controls gas, liquid, and solid in the pipe inside the pipe, and power sensor A high pressure tanks for storing incombustible gases such as fire water, loess, firebug, carbon dioxide, carbon dioxide, carbon dioxide and halon gas which are suitable disaster prevention materials suitable for A fire, and water tank tanks in collecting tanks, Pack and a typhoon annihilation / disaster prevention device unit (811) constituted by the inside of the main body (1) of the typhoon disaster prevention dispenser main body (1) so as to be movable by a tent tent, And a typhoon disaster prevention system that includes a typhoon disaster prevention system that controls the flow rate and gas flow in order to prevent the natural disaster of the typhoon.
65 to 84, the storm annihilation
65 to 84, the storm annihilation
The adve- lon and the airship disperse the load of the body of the fire sensor pump body to ensure the safety of the pump body, and the life structure and the initial evolution from large-scale forest fires and large fires are sequentially transferred to a plurality of non- An electronic sensor valve and an unmanned camera are equipped with an anti-firefighting fire-fighting countermeasure product constituting the fire-fighting nozzle and the fire-fighting piping line of an automatic turn-off type, and the typhoon annihilation / disaster prevention unit 811) is a maritime hydroelectric power station equipped with flood control facilities, which consist of a storm disaster prevention facility that controls flow and gas flow to prevent natural disasters such as forest fires, snowstorms, snow storms, typhoons, floods, droughts and landslides (593, 594, 595), and the double-pipe structure of the ridge line of each corner also has a penetration path through which the tunnel (672) is inserted, Is configured in the body (1).
65 to 84, the storm annihilation
The plurality of flanges 28 attached to the body of the pipe 14 are provided with eight machining holes at an angle of inclination of 45 degrees at an angle of inclination 16 and a stopper plate 165 is attached to the upper end of the pipe body upper portion A, (174) and halon gas (175) are supplied to the upper part (A) flange (28) by oxygen and air in the upper part (A) flange and the lower part (A) flange of the injection nozzle The body of the coupling 29 is connected to the center of the cap 165 of the plug cover so that the flushing water 7 is passed through the helium 176 and the fuel 131, A total length of 2100 m, which is combined with a 7-part single pipe which is detachably assembled into a through-hole 20 formed with a pumping water pipe 89 of a small fire hose and a wire rope 19, m < / RTI > and is supplied with the above-mentioned disaster prevention material connected to the nozzle The wire rope 19 formed by the water pipe 89 is connected to the fire hose 9 by a typhoon annihilation disaster prevention unit 811 which is connected to the fire hose 9 such as fire, To prevent the natural disaster of the typhoon, a typhoon dis- tribution dispenser for controlling the flow rate and the flow of gas constituting the main body (1) of the dispenser for preventing the typhoon.
65 to 84, the storm annihilation disaster prevention unit 811 for controlling the flow rate and the flow of the gas constituting the inside of the dispensing and dosing device main body 1 of the typhoon disaster prevention apparatus is provided with a fire suppression device, In order to prevent natural disasters such as typhoons, floods, droughts and landslides, a number of fire-fighting and disaster prevention equipment hoses (9) and pipelines (14) are installed inside a disaster-free global marine hydroelectric power plant, A paraffin tape 177 for a fire detection sensor and a nozzle cap 100 for connecting a paraffin pipe joint nozzle are provided with a high and low acid 395 and a high- (333) Buildings of high and low buildings near the beach on the ridge below the mountain top Wire rope (19) with rooftop opening (192) Fire pipe cable (256) Ha , A A building belonging to a kind of fire, a general building of fire (332) and a forest (266) A common fire of paper and duvets When a fire occurs In the past, helicopters and fire trucks of fire trucks sounded siren The fire helicopter of the roadside car that obstructs the traffic flow and the fire helicopter of the mountain which is obstructing the traffic flow starts to fire when the fire is turned on and off to carry fire water. In order to alleviate the risk of losing life in an urgent and imminent situation as a result of a delay of one second due to a delay in fighting for a moment, the fire prevention disaster prevention measures that will be initially evolved in the early stage of fire fighting vehicle or helicopter (1) In the main body (1) of the dispenser for preventing the typhoon, A
65 to 84, the
65 to 84, the storm annihilation
65 to 84, the storm annihilation disaster prevention unit 811 for controlling the flow rate and the flow of the gas constituting the inside of the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention system, In order to prevent natural disasters such as typhoons, floods, droughts, and landslides, a firefighting sensor pump, which is composed of a typhoon disaster prevention system that controls flow and gas flow, The impeller 143 installed in the impeller 143 for introducing a predetermined amount of the disaster prevention material formed by the impeller 143 into the suction port is connected to the rotation shaft 198 which is the rotation center of the motor and is rotated to increase the water pressure of the inflow water A head tank 189 on the left and right sides of the industrial machine room internal combustion engine and a plurality of fire fighting and disaster prevention piping lines 168 of a predetermined amount of fire fighting water 7 transferring device and a disaster prevention water line A flocculation tank 34 having a double structure in which the flood control tank 17 and the disaster prevention waterway 17 are disposed at predetermined intervals in a predetermined distance from each other at a predetermined inclination angle 16, A flange stopper wire net 28 for a plug filter, a detection sensor ball tab 499 for detecting the flow of the foreign matter in the water collecting tank 34, a fire inlet port 269 for blocking the inflow of foreign substances into the collecting tank 34, And configures switch-off-off time;
A plurality of
A first
Therefore, as shown in FIGS. 65 to 81, the storm annihilation
65 to 84, the typhoon annihilation / disaster
65 to 84, the storm annihilation
65 to 84, the typhoon annihilation
The
65 to 84, the storm annihilation disaster prevention unit 811 for controlling the flow rate and the flow of the gas constituting the inside of the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention system, In order to prevent natural disasters such as typhoons, floods, droughts and landslides, a pressure tank 189 of a multi-stage multi-stage pump and a control system having a typhoon disaster prevention process comprising a typhoon disaster prevention facility, a collecting tank 34, And the associated line relationship between the control unit inverter 47 and the collecting tank 34 is connected to the air inlet 47 and the suction line 269 at the time of suctioning the fire water, 47), the installation position is clearly defined in front of the isolation valve 5, which is the valve (5) in front of each pump (8) which is integrally formed with the tip end of the check valve (6) After the pressure tank 189 is set, The butter 47 controls the amount of fire water pressure by the first pressure check sensor 86 which is a discharge pressure check sensor and the overpressure prevention switch 108 which is integral with the second pressure check sensor 87 on the line of the discharge confluent pipe 4 The mortar 158 is injected into the mixer 73 so as to cool and fire the various fire A within a time of 1 second or less with a plurality of fire-fighting nozzles 10 serving as a discharge nozzle 270, Firefighting cable car which is equipped with typhoon disaster prevention device which prevails fire prevention in neighboring living area including large fire forest included in general fire and typhoon disaster prevention process constituting inside of distribution dispenser main body (1) for typhoon disaster prevention 256 ) Is composed of a plurality of high and low mountain peaks and a plurality of buildings each having a difference in height and height, and each wire rope is connected to a plurality of fire hoses (9) through a safety net (a mesh hose including a wire rope of a cross- ,4 01) -type hurricane 9 is provided as a typhoon disaster prevention device unit 811 that is configured to provide a typhoon disaster, and the typhoon annihilation / disaster prevention device unit 811, which is formed inside the main body 1 of the typhoon disaster prevention device, A technical feature is the dispensing device for the disaster prevention of typhoon, which is equipped with a typhoon disaster prevention system consisting of a typhoon disaster prevention system in order to prevent natural disasters such as forest fire, drought, heavy snow, typhoon, flood, drought and landslide.
The configuration of the three-stage multi-stage pump (8) in which the typhoon disaster prevention process is formed inside the main body (1) of the typhoon disaster prevention dispenser is as follows.
The details of the multi-stage multi-stage pump specification in which the typhoon disaster prevention process comprising the main body (1) of the dispensing device for typhoon disaster is formed are as follows.
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 Po n of all the pumps to the operation stop
· 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 P on and the pressure of the individual maximum operation pump becomes the pump stop point Po ff immediately before stopping.
Therefore, the frequency modulation method can maintain the narrow width of ΔP and control the rotation speed of the main pump by using the frequency modulator, so that the system compensates the sudden pressure change that occurs 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 multi-stage multi-stage pump in which the typhoon disaster prevention process is formed inside the dispensing apparatus
65 to 84, the storm annihilation
65 to 84, the storm annihilation disaster prevention unit 811 for controlling the flow rate and the flow of the gas constituting the inside of the dispensing and dosing device main body 1 of the typhoon disaster prevention apparatus is provided with a fire suppression device, In order to prevent natural disasters such as typhoons, floods, droughts and landslides, an isolation valve (5) that is open when the switch is turned on and closed when the typhoon disaster prevention process consisting of a typhoon disaster prevention facility is formed, A regeneration valve 136 for reducing the pressure to a predetermined pressure and a backflow prevention check valve 61 for shutting off the supply of the water if the disaster prevention water is guided to a predetermined pressure or lower, A multistage pump 8 as a mixer and a power motor control module is operated so that the disaster prevention water is passed through the cutoff valve opening and is connected to the nozzle hose 9 by a gap machining hole around the circumference of a plurality of pipes 14, Plan The fire water whose internal water pressure is formed by the clearance of the joint portion is discharged from the discharge port of the storm disaster prevention dispenser main body 1 in the form of a straight discharging water jet 38 or a plurality of curtain water film 39 Prevention of a number of natural disasters before and after a disaster, such as forest fire, yellow dust, harmful red tide and heavy snow damage, is prevented in the global village where the typhoon disaster prevention process is provided with the book 811e.
65 to 84, the storm annihilation
As shown in FIGS. 65 to 84, the upper end surface of the upper stage surface of the upper stage ground surface with the typhoon disaster prevention process, which is provided in the facility safety control
The air generated by the operation of the
65 to 84, the storm annihilation disaster prevention unit 811 for controlling the flow rate and the flow of the gas constituting the inside of the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention system, In order to prevent natural disasters such as typhoons, floods, droughts and landslides, the piping hose at the valve rear of the valve of the electronic control unit opened with a closed spraying nozzle composed of the flood control equipment and the piping body (B) A straight gap 15 and a circular shaped gap 15 are machined holes 20 of which 490 nozzles and flange joints whose nozzle diameters are adjusted to 5 millimeters or 10 millimeters The nozzle connected to the fire hose portion and the nozzle connected to the hose portion formed inside the fire hose 9 are separated by bolts and nuts and the gap nozzle of the flange joint portion is adjusted by the washer The discharge jetting water 38 and the curtain water film 39 are discharged into the gap 15 of the jetting nozzle 10 discharged by the disaster prevention material holding the water pressure of the fire hose 9 inside the jetting nozzle body B It suppresses the algal blooms by causing the harmful tidal microorganisms (921) gathered to collapse and collapses a number of pylons, and the vertically descending air current, which is a chunk of air over the sea, is vertically descending to the jet stream above sea level 10 km Pressure air compressor (80) and a multi-stage multi-stage pump (184) which is equipped with scenes for removing fire and harmful tidal breezes and typhoons at the moment when the typhoon is returned to the land, A control microcomputer for controlling the injector nozzle and a hose 109 and a nozzle 923 which are configured to display a score on a monitor through the operation of the control server 150 of the control system 150 And is connected to an air compressor (80) and a distribution shaft (357) mounted together with the cooling device. When a notice of a dangerous red tide is issued in a drought period, a mixture of the groundwater and the yellow soil stored in the storage tank and the control dam is supplied to the
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
The paraffin tape 177 constituted inside the dispensing and dispensing apparatus main body 1 of the typhoon disaster prevention device and the paraffin tape 177 formed by the ignition non-substance wire 176 are ignited, A sensing bimetal 102 which is cut at the same time as the sensing wire 41 is cut and connected to the fire water supply controller valve, a thermocouple thermometer switch 103 and a solenoid operation on / off switch button 66 provided in the solenoid valve 76, The emergency siren 93 sounds and the solenoid valve switch operating weight 107 together with the alarm device is operated so that the solenoid valve 76 of the electronic control device is opened and at the same time the stepping- The flame 292 and the pyramid 294 of the fire point are rapidly diffused into the radial clearance 292 and the pyramid 294 by the wall-mounted spray nozzle 10 and the ceiling mount- ing spray nozzle 10, (15) and a straight line The flushing water is injected into the gap 15 by a single linear discharge jet 38 and a radial discharge jetting water curtain 39 to slowly and quickly initialize the flames, flames and pits smoothly, ) Dispatch As a constitution of the global disaster prevention device system for preventing the occurrence of land marine disasters in which the fire, flame, and pillar are removed before the arrival time in the local area, the weather dispatching system (38) The present invention can detect the temperature of the water in the tank and directly or indirectly detect the heat of the fire by the temperature sensor as well. .
65 to 84, the
In the connection configuration of the
A micro switch is a type of limit switch that is very small among the limit switches. Since the micro switch is widely used as a main component in the operation and control, and is a large power switching element in a small shape, It has a high repetition accuracy to repeat the switching operation irrespective of the operation speed and to faithfully repeat the specific operation characteristic while the falling speed of the contact point is directly operated by the force. Since the switch operates even with a small force or movement, ≪ / RTI >
65 to 81, the storm annihilation
In this study, the groundwater in the aquifer bed and the aquifer on the riverbed were supplied with a power pump (304) to distribute the groundwater eruption and to distribute it in the water storage tank and each intake dam. A plurality of double
65 to 84, the
The
65 to 84, the typhoon annihilation / disaster
As the global warming is prevented, harmful breezes are controlled in advance, and the power produced by the Francis
65 to 84, the typhoon annihilation / disaster
65 to 84, the typhoon annihilation / disaster
Oxygen and air are introduced into the sea by the air compressor (80) and net type hose which block the harmful red tide breeding and are installed at the upper part of the inside of the block tower at the center of the upper end of the deck deck The crude oil drill rod connecting
A
65 to 84, the typhoon annihilation / disaster
65 to 81, the storm annihilation
65 to 81, the storm annihilation
65 to 81, the storm annihilation
On the other hand, in order to prevent natural disasters such as forest fires, yellow dust, heavy snow, extreme weather, typhoons, floods, droughts and landslides, the typhoon dissipation / The upper surface of the sea surface and the harmful tidal microorganism 921 are controlled so that the rising
(924) of the pneumatic conveying equipment, a submarine mineral collecting robot (912), a mining basket (842) and a mining collecting tank (924) and a submarine surveying lens A
As shown in FIGS. 65 to 81, the typhoon destruction and disaster
The low pressure shut-off valve 83 is configured such that the fuel supply is interrupted when the pressure is lowered and at the same time the
Barge hull at the top of holding tank (591) No deck at top of deck A certain amount of power is supplied to supply economic energy to the global village Typhoon disaster prevention dispenser Inside the main body (1) Destroy typhoon Disaster prevention unit (811) To prevent natural disasters such as heavy snow, extreme storms, typhoons, floods, droughts and landslides, a power transforming transformer (96) of a substation in which a typhoon disaster prevention process consisting of a typhoon disaster prevention facility is installed .
As shown in FIGS. 65 to 81, the typhoon destruction and disaster
As described above, the hurricane annihilation / disaster
65 to 81, the typhoon
As shown in FIGS. 65 to 81, the typhoon destruction and disaster
A water hammer system of a
The monthly average route of the typhoon, the abnormal path of the typhoon, and the countermeasures to change the typhoon 's course that returns the downward current of the vertical structure of the typhoon to the atmosphere are explained as follows.
The hurricane annihilation / disaster
The internal description of the operation of the engine installed inside the fire-fighting ship as the equipment of the air-conditioning system is omitted below, and the inventor of the present invention has been drawn up as a testing agent of the marine vessel safety system which determines the ship class made up of the crude oil drilling rig We confirmed the safety of the equipment by checking the safety of the equipment at the top and bottom of the crude oil drilling rig, pointing out the defect to the person in charge of each production department, and strengthened the bond between foreign engineers and domestic engineers. According to the weather forecast of the earth in which the seed of the typhoon is removed in advance by the air pressure and the spray water ejected from the spray nozzle installed in the middle of the connection part between the
As described above, the cause of the harmful red tide occurring in the typhoon disaster prevention process in the
The hurricane annihilation / disaster
As shown in Figs. 65 to 84, the present invention provides a dispensing and inputting apparatus for a typhoon disaster, which includes a water storage tank, to the rest of the world.
According to the preferred embodiment of the present invention, according to the preferred embodiment, in order to prevent casualties due to a fire, to prevent casualties due to landslides, to protect casualties from a plurality of disasters, It is noted that the above embodiments are described for the purpose of illustration and not for the purpose of limiting the present invention, and it is to be understood that within the technical scope of the present invention, It will be appreciated that the scope of the claims is dependent upon the other applications described below in accordance with the various embodiments.
(1) Dispensing injector for typhoon disaster 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) (9) double structure nozzle hose and double structure fire hose, (10) double structure firefighting nozzle,
(10a) Nominal name "50", (10f) Nominal "40", (10c) Nominal name " (10k) " 65x50 ", (10l), " 100x90 " 50 x 40 "(10 m)," 40 x 25 "
(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 ("
(103a) thermocouple thermometer switch for the sensor, (103a) thermocouple thermometer configuration, (103b) temperature limit, (103c)
(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
(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)
(443)
(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)
(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
(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) Subsidies of small-scale marine nuclear power plants,
(594) Supporting dock of medium sized marine nuclear hydroelectric power plant,
(595) the support of large-scale marine nuclear hydroelectric 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
(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) flagpole rubber balloon, (629) rope for rope, (630) rope knot hook, (631) emergency stairs, (632) (633) Conveyor, (634) Docking line for sinking ship, (635) Vacuum pump, (636) Tugboat, (637) Semi diving operation line, (638) Bollard, (639) (641) an electric magnet magnet, (646) a space rocket launcher, (646) a rocket launcher, (642) (647) Helicopter, (648) Chain Block, (649) Loess Cement Mixing Equipment Mixer Machine, (650) Aerator, (651) Crane Boom Stand, (652)
(653)
(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) Cloudy rain,
(676) Funnel clouds,
(677) Dust,
(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,
(811) Typhoon destruction and disaster prevention unit (811a) Pumping moving unit (811b) Power production unit (811c) Traffic transportation unit of construction machine (811d) Power transmission unit for transmitting power (811f) Electronically Controlled Equipment Construction Machine Control Unit, (811g) Electronically Controlled Equipment Screw Control Unit,
(812) enriched uranium or
(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
(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
(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)
(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 weapons of more powerful weapons than nuclear bombs,
(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) Nuclear Fuel, (984) Glass, (985) Agate, (986) Amber, (987) Pearl, (988) Statue of Liberty, (989) United Nations, (90) United Nations Organization, Hydrogen bombs, (993), (994) Switches for operation and weight sensors for sensing sensors, Diver sources for control of diving buoyancy, (995) Submarines, (996) Sink ships,
(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 (2)
The double tunnel structure penetrating through one side of the intake dam of the distribution shaft 357 constituting the inside of the dispensing and inputting apparatus main body 1 constituting the typhoon disaster prevention dispensing and dispensing apparatus also has a tunnel 672, Forming an insert into the dam,
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an adjustment shaft 231 constituting each valve, and a water tunnel connection device 231 connected to the marine tunnel transportation device 941 included in the adjustment shaft 231 (593, 594, 595), and a typhoon dis- tribution dispatching device of a borehole (936) are installed in the main body of the dispensing and dispensing apparatus for dispensing the typhoon disaster A borehole 936 is formed with a construction machine inside,
In the water storage tank and the intake dam, there are provided a power pump for regulating the storage of water for stormwave disaster prevention, an adjustment shaft 231 constituting each valve, and a water tunnel connection device 231 connected to the marine tunnel transportation device 941 included in the adjustment shaft 231 In the northern part of the equatorial line, the typhoon, tornado, and erosion move in the direction of clockwise rotation to the north of the equator due to earth's rotation and revolutions. The downward air current is formed to be counteracted by counterclockwise echo, and a downward air stream, which is a seed of a typhoon, is supplied to a suction inlet of a relief type with a dispenser and a dispenser for dispensing a storm- An air-flow type variable-typhoon disaster prevention device that opens a door in a counter-clockwise echo in a deck air-storage compartment to form an air- Configuring the input device;
According to the long-term weather forecast provided by the satellites, there are many fire trucks that control the water, vacuum pump and air flow in the way that the tornadoes travel on land, so that the flow and gas flow in the center of Dolphong, This system consists of a power generation dam construction machine and a borehole (936) storm disruption dispenser that constitutes the distribution input device of the airflow-variable typhoon disaster preventing the wind to sink into the inside of the marine hydroelectric power plant flood control station (593,594,595) A borehole 936 is formed with a construction machine inside the dispensing and dispensing apparatus main body 1 for disaster prevention of each construction machine of the distribution dispensing apparatus,
The typhoon dis- tribution dispensing apparatus is connected to one side of a marine hydroelectric power station floating ship 593, 594, 595 connected to a marine tunnel communication device 941 of each control shaft 231 to control the hull position movement of a marine hydro- The seals 156 formed inside the cylinder 126 used as a sinking preventing retention line for the tanks and the cylinder 126 used as a carrier for disassembling and assembling are assembled so that the high pressure pump and the high pressure hose A hydraulic cylinder 623 assembled with a coupling rod 249 used as a coupling device to the crank 248 and coupled to the coupling device 29, And a hurricane annihilation / disaster prevention device unit (811) for controlling the flow of a rising air stream and a descending air stream, which are gases constituting the inside of the dispensing and dispensing apparatus main body (1) Typhoon room A distribution dispensing device;
And is disposed inside the dispensing and dispensing apparatus main body 1 constituting the respective dispensing shafts 357 connected to the dispensing shaft 357 of the floating operation pumping movable part 811a constituting the dispensing and dispensing apparatus for the storm- The marine hydroelectric power generation and production unit 811b constituting the electric power production including the hurricane annihilation / disaster prevention units 811 constituting the gas flow regulation,
The hydraulic power generating unit 811b constituting the hydro-hydroelectric power generating and manufacturing unit 811b generates a hydraulic pressure difference in the generator 213 to generate mechanical energy, and rotates several turbines and a turbine 267, The aberration turbine 267,
A generator 213 for switching the electric power generated from the turbines 267 and a plurality of turbines 267 and a turbine 267 and a turbine 267 are connected to the rotational speed detector 214, an exciter 215 for supplying a current to the field coil of the alternating-current electric motor is located,
Below the exciter 215, an upper rotation bearing 217 is located below the device 216 for pushing the ring-shaped vane into the device 216 for pushing the ring vane, A device 218 for pushing the rotary bearing is located and a central stator 221 is disposed in the lower portion of the rotating bearing pushing device 218 and a stator 221 is disposed in the stator frame 220, A fan 195 is positioned below the central stator 221,
A low speed rotation bearing 225 is disposed in the braking device ring 223 and the braking device 224 below the fan 195. A low speed cooler 222 is positioned below the low speed rotation bearing 225, 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 turbines located at a lower end of the rotating shaft 198 The turbine rotation bearing 227 and the impeller 228 are disposed inside the casing 141 of the hydroelectric power generator 213 to constitute a hydraulic power connection structure power generation control unit 811b,
The turbine 267 of the Francis aberration 229 and the turbine 267 of the Pelton aberration 230 are different in shape so that the suction port 269 and the discharge port 270 are connected to each other in the casing 141 and the pressure- The pump aber 264 is configured to regulate the power distribution to each industry by controlling the voltage in the substation where the transformer of the substation is provided and the power transmission unit, The pump water turbine 264 is operated by regulating the opening and closing of the main valve 265 with the electric power supplied from the nuclear power plant and the hydroelectric power is produced and the water is moved to the water storage dam 680 located at the upper part of the power plant The storm annihilation disaster prevention unit 811 is provided with the dispensing and inputting devices for storm storm disaster prevention and the harmful red tide is provided to the pumping moving part 811a and the marine hydroelectric power generation control part 811b included in the hurricane annihilation disaster prevention unit 811 The electronic control regulating device control section 811f is connected to the transportation transport section 811c, the power transmission regulating section 811d, the facility safety control management former section 811e and the electronic control regulating apparatus construction machine regulating section 811f of the short- (811g), and is constituted by dispensing apparatuses for typhoon disaster prevention;
The distribution shaft 357 connected to the distribution shaft 357 of the storm disaster prevention distribution dispensing apparatus is provided with an electric power generating unit for generating hydroelectric power by rotating a number of aberrations by adjusting the diameter of the suction port 269 and the discharge port 270, And a seaweed power generation device for production control to control the distribution of power to the respective industries by controlling the voltage in a substation equipped with a transformer of a substation for controlling the flow of the flow constituted by the inside of the dispensing and dispensing apparatus main body 1 for preventing the typhoon And a power transmission control unit 811d for transmitting the power contained in the disaster prevention device 811 so as to constitute a typhoon disaster prevention dispensing apparatus.
When the dangerous tidal redism warning is issued in a drought period, the control dam 304 is connected to the distribution shaft 357 of the typhoon disaster prevention dispensing and dispensing apparatus, The backflow valve 409 is opened and the tumbler winch 137 for the opening and closing control device for the opening and closing of the water is controlled to control the flow of the flow rate. The water contained in the hurricane annihilation disaster prevention unit 811 that regulates the flow of the water constituting the interior of the main body 1 of the hurricane disaster prevention dispensing apparatus while discharging a large amount of water for control into the ocean, A red tide blocking prevention control device, a safety control management front tide 811e, and a typhoon prevention dispensing device;
The water stored in the peak acid intake water dam 680 is connected to the distribution shaft 357 of the typhoon disaster prevention distribution dispensing device and the water pump 409 is opened while the power pump 304 and the piping and the fire hose 9 are opened, A plurality of nozzles 10 connected to the hydroelectric power generation control unit 811b for generating hydroelectric power to the marine hydroelectric power generator 811b The power supplied from the power transmission control unit 811c is supplied to the mechanical pump of the power pump 304 that includes the typhoon destruction and disaster prevention units 811. The typhoon destruction / A dispensing device for dispensing a dispensing device for dispensing a typhoon, which provides a flood control device for preventing natural disasters such as dust, drought, typhoon, flood, drought and landslide, Pumps and k The disaster prevention preventive and regulating facility safety control management sections 811e included in the emergency storm disaster prevention apparatus section 811 for controlling the flow rate and the flow of gas to the connection structure of the car 256, ≪ / RTI >
The flood control apparatus is connected to the control shaft 231 of the dispensing and dispensing apparatus for typhoon disaster and includes an artificial tunnel 672 inserted through the respective control dams and installed in the flood control apparatuses of the dispensing and dispensing apparatus main body 1 And an electronic control regulating device construction machine control unit 811f included in a hurricide annihilation / disaster prevention control unit 811 for controlling the flow of the flow of the hurricane.
The hydraulic power generator connected to the adjustment shaft 231 of the typhoon dis- tribution dispensing and inputting apparatus and located at the marine tunnel traffic device 941 and the hydro-hydroelectric power plant is a flow rate control distributing / inputting device for the inlet port 269 for controlling the flow rate of the algae And a tidal-type disaster prevention dispenser for regulating the flow rate and the flow of gas constituting the inside of the dispensing and dispensing apparatus main body 1 with the electric power production and connected to the distribution shaft 357, (811b); and
A plurality of power pumps 304 connected to the adjustment shaft 231 of the typhoon dis- tribution dispensing and dispensing apparatus to supply the groundwater and the deep seawater in the river to the intake port are provided in the main body 1 of the typhoon- And a typhoon winch 137 for regulating the flow of the flow of the inside of the dam, which is connected to the distribution shaft 357, The dispensing and dispensing apparatus for controlling the flow rate and the flow of gas constituting the inside of the dispensing and dispensing apparatus main body 1 provided with the hydrometalline electronic control adjusting screw adjusting portions 811g, 593, and 595, which are connected to a marine tunnel communication device 941 constituting the control shaft 231, which are provided with a control shaft 231 and a tympanum disaster prevention dispensing and inputting devices.
The portable lug connecting shaft coupling bolt 603 and the portable lug connecting shaft coupling and dismounting nut 603 are installed in the marine hydroelectric power station floating portable reader 593, 594, 595 of the marine tunnel communication device 941 of the adjustment shaft 231 of the typhoon prevention dispensing and dispensing apparatus, A portable lug 607 and a portable lug pin 608. The water intake dam 680 is connected to the vertical partition wall 605, A plurality of pipes 409 and a plurality of pipes 14 are connected to the water storage tank 292 and each water intake dam 680 and a plurality of pipes 14 and fire hoses 9 are connected to the pipe 14 and the fire hose A fire pump 45 connected to a fire nozzle located in a part of the main body 1 of the storm disaster prevention dispensing apparatus main body 1 is provided with a water gate 293 and a water passage 294 of each water intake dam 680, And a hurricane annihilation / disaster prevention device unit 811 for controlling the flow rate and the flow of the gas constituted in the double pipe structure type 811a, The control shaft 231 of the tongue-shaped tunnel 672 is constituted by an air conditioner of the cooling device, a heating fan for cooling the air, and a dispensing device for preventing the typhoon of the cooling fan so as to rapidly extinguish the flood and the typhoon overcoming the drought. Wherein the tornado is provided with a tornado.
The tornado disaster prevention device 811 of the typhoon disaster prevention dispensing device is provided with a pumping movable part 811a and is provided with an idler tunnel 610 of the intake water dam 680, (672)
Each of the tongues 672 constituting the tongue tunnel 672 passes through the wall of the intake dam 680 and adjusts the movement of the fish and shellfish located inside the tongue tunnel 672 located at the center of the dam to the scattering site A plurality of reflectors 804 are provided for providing sunlight,
And a plurality of disaster prevention water passages 17 connected to the water intake dams 680 while being rotated at a predetermined inclination angle along the outer circumferential surface of each of the water intake dams 680, And an air compressor (80) for controlling the opening and closing of the hatch opening (293) and a tangential winch (137) for a hydrant opening / closing control device having a connection structure. And a tornado winch 137 for a hydrant opening and closing control device having a connection structure with an air compressor 80 for opening and closing the hydronephrase 293 for controlling the flow rate and the gas flow of the typhoon destruction and disaster prevention unit 811, And electronic control equipment construction machine control units 811f included in the electronic control equipment construction unit to constitute dispensing and dispensing apparatuses for hurricane disaster prevention.
The tundish 672 of each water intake dam 680 of the typhoon disaster prevention distribution dispensing device is also inserted into the passage and is located in the ridge valley of the crest of the mountain bottom portion provided with the distribution shaft 357 A plurality of water storage tanks 292 and the water intake tanks 292 are connected to the water intake 293 and the water discharge passages 294 and the water storage tanks 290, A control shaft 231 of a construction machine included in a plurality of typhoon dis- tribution dispensing apparatuses for controlling the flow rate of a typhoon disaster prevention facility accommodated in each water intake dam 680 and the flow of gas; And
Water is inserted into each water intake dam 680 constituted by the typhoon preventing distribution dispensing device and is connected to the outer peripheral surface of the control shaft 231 and connected to a plurality of disaster prevention water passages 17, And controls the flow rate and the gas of the typhoon disaster prevention facilities accommodated in the control shaft (231) and the distribution shaft (357) for dispersing and storing the rainwater and the yellow soil mixture of the natural water in the control water storage tank and the control dam of each coastal beach And a storm waterproofing system for controlling the flow rate and the flow of gas constituting the inside of the dispensing and dispensing apparatus main body 1 having the connection structure with each intake water dam 680, A marine hydroelectric power generation control unit 811b for generating electric power to achieve disaster prevention, and a power transmission control unit 811d for transmitting power, and is constituted by dispensing input devices for typhoon disaster prevention;
In the pumping moving part 811a included in the typhoon destruction preventing device 811 constituting the typhoon preventing and distributing apparatus,
And is connected to one side of a marine tunnel communication device 941 of each control shaft 231 constituting the inside of the main body 1 of the dispensing and inputting apparatus for typhoon disaster and the one side of a marine hydroelectric power plant floating posture 593,594,595, The pumping moving part 811a included in the typhoon destruction preventing device 811 is installed in the main body 1 of the typhoon preventing and dispensing apparatus main body 1 provided for movement control and disassembling and assembling of the hull position of the hydroelectric power station floating reader 593, Which is used as a transportation machine constituted by dispensing and dispensing devices for storm disaster prevention of a construction machine for controlling the flow of a flow, is assembled to the shaft 126 of the cylinder 126, A high pressure pump in front, a high pressure hose 190, a coupling 29, a crank 248 as a valve device, and a linkage 249 used as a connecting device to the crank 248, The hydraulic cylinder (623) body Configuring, and;
The cylinder 126 and the piston 127 are provided with a rod seal 822 and a bush seal 824 on the piston seal 823 and a slide ring 826 on the wear ring 825 and an O- 828 and the load seals 829 on the backup seal 830 and the load seals and backup seals 831 on the downstream seal 832 and on the pin seal 833, And a piston ring 836 and a multistring 837 made of a rubber material so as to surround the piston 127 and the inside of the cylinder 126 to classify the high pressure valve and the low pressure valve of the hydraulic pump, Hydraulic hoses provide a connection structure,
And is connected to one side of a marine tunnel communication device 941 of each control shaft 231 constituting the inside of the dispensing and inputting apparatus main body 1 of the typhoon disaster prevention apparatus and the marine hydroelectric power plant flood control console 593, The pumping moving part 811a included in the typhoon destruction preventing device 811 constituted inside the main body 1 of the typhoon preventing device for disaster prevention provided for the movement control and disassembling and assembling of the hull position of the power plant floating guide 593, Is the hull position of the flood control station which is composed of the dispensing devices of the construction machine for the disaster prevention of the typhoon that regulates the flow and the flow of the gas. Standard atmospheric pressure is the pressure of the force applied to the unit area of the object. Devices;
In the pumping moving part 811a included in the typhoon destruction preventing device 811 constituted inside the main body 1 of the dispensing and inputting apparatus for typhoon disaster,
Connected to one side of a marine hydroelectric power plant flood control console 593, 594, 595 of a marine tunnel communication device 941 of each control shaft 231 constituting the inside of the dispensing and inputting apparatus main body 1 of the typhoon prevention disaster, The pumping moving part 811a included in the typhoon destruction preventing device 811 constituted inside the main body 1 of the typhoon preventing device for disaster prevention provided for the movement control and disassembling and assembling of the hull position of the power plant floating guide 593, (8), which is composed of a dispenser and a dispenser for preventing the typhoon of a construction machine that controls the flow rate and the flow of gas, and a solenoid valve (8) at the connecting junction of the flange (28) And the fire extinguishing water installed in the collecting tank 34 at the upper portion of the pump machine room includes detecting the disaster prevention quantity by the ball tap 499, which is a fire water level sensor,
An air hose 109 installed inside the nozzle hose 9; an air nipple 110 for socket-type socket which is detachably coupled to the connection portion of the air hose 109; The diesel engine generator 226 located at the upper end of the engine compartment is operated and the power source 46 is supplied to the motor control module 106 of the prime mover 80 Pressure storage tank 145 so that the air generated by the operation of the electric motor 192 of the prime mover 80 is stored in the receiver high-pressure storage tank 145 at a constant pressure, ;
The emergency valve 84 of the disaster prevention air piping line 181 is expanded and air is blown into the inside of the building and attached to the piping frame outside the building and at the same time the pressure gauge 101 and the pressure switch 104 are connected to the motor control module 106 The crank handle 249 and the crank handle 249 are provided in the overpressure prevention switch box 108 and the compressor main body 263. The crank handle 249 and the crank handle handle 249 are connected to each other by a drive motor 80 having a piston 127 and a cylinder 126, And the electric motor 192 are connected to the baler 252 corresponding to the speed reducer 251 and the belt cover 261 is mounted on the periphery of the baler 252 and the baler 252 And a suction filter 262 installed at an upper end of the compressor main body 263 to adjust the rotational speed of the prime mover 80 and to admit foreign substances to the air suction port 269;
The piston 127 of the compressor 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, The air valve 257 and the automatic valve 259 are provided with drain valves 60 in the high pressure storage tank 145 and the air hose 109 and the air hose connection device nipple 110 And a multi-stage screw cooler 147 in which heat is dispersed to the oil cooler 157 without the internal cooler 170 and the after cooler 182, And is connected to the suction port (269) and the discharge port (270) A dispensing and dispensing apparatus for dispensing a hurricane with a basket 42 and a bed nozzle 172 serving as a lifesaving structure in a base tube 730 and having a connecting structure of a construction machine inside the pumping moving part 811a;
And a tidal-type disruption-introducing-and-dispensing device.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| KR1020170079110A KR20170081589A (en) | 2017-06-22 | 2017-06-22 | Typhoon Disaster Discharge Distribution Input Device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| KR1020170079110A KR20170081589A (en) | 2017-06-22 | 2017-06-22 | Typhoon Disaster Discharge Distribution Input Device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| KR20170081589A true KR20170081589A (en) | 2017-07-12 |
Family
ID=59353139
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| KR1020170079110A KR20170081589A (en) | 2017-06-22 | 2017-06-22 | Typhoon Disaster Discharge Distribution Input Device |
Country Status (1)
| Country | Link |
|---|---|
| KR (1) | KR20170081589A (en) |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109819919A (en) * | 2019-03-27 | 2019-05-31 | 天津海太科技有限公司 | Anti-Typhoon, red tide of hiding semi-submersible type change off land deep water abalone culture platform |
| US11180263B2 (en) | 2020-04-06 | 2021-11-23 | Workhorse Group Inc. | Flying vehicle systems and methods |
-
2017
- 2017-06-22 KR KR1020170079110A patent/KR20170081589A/en not_active Application Discontinuation
Cited By (14)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109819919A (en) * | 2019-03-27 | 2019-05-31 | 天津海太科技有限公司 | Anti-Typhoon, red tide of hiding semi-submersible type change off land deep water abalone culture platform |
| US11180263B2 (en) | 2020-04-06 | 2021-11-23 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11254446B2 (en) | 2020-04-06 | 2022-02-22 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11332264B2 (en) | 2020-04-06 | 2022-05-17 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11370561B2 (en) | 2020-04-06 | 2022-06-28 | Workhouse Group Inc. | Flying vehicle systems and methods |
| US11383859B1 (en) | 2020-04-06 | 2022-07-12 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11407527B2 (en) | 2020-04-06 | 2022-08-09 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11472572B2 (en) | 2020-04-06 | 2022-10-18 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11485518B2 (en) * | 2020-04-06 | 2022-11-01 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11498701B2 (en) | 2020-04-06 | 2022-11-15 | Workhorse Group Inc. | Flying vehicle systems and methods |
| US11603219B2 (en) | 2020-04-06 | 2023-03-14 | Workhorse Group Inc | Flying vehicle systems and methods |
| US11787564B2 (en) | 2020-04-06 | 2023-10-17 | Workhorse Group Inc. | Carriage lock mechanism for an unmanned aerial vehicle |
| US11787563B2 (en) | 2020-04-06 | 2023-10-17 | Workhorse Group Inc. | Unmanned aerial vehicle including equipment mounted in recessed seat of apex support structure |
| US11820533B2 (en) | 2020-04-06 | 2023-11-21 | Workhorse Group Inc. | Flying vehicle systems and methods |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| KR101799861B1 (en) | Flood damage adjustment distribution input device | |
| KR101570665B1 (en) | Flood disaster control system | |
| KR20100027087A (en) | For the ocean a generating plant in global village zero calmity tidal power generator used with in it's a level pipes seesow type | |
| KR20120066690A (en) | Ocean tunnel traffic equipment system using buoyancying of duplication structure of block pipes | |
| KR20070106596A (en) | There is exterminate equipment of cochlodinium and the prevention of a calamity system used for development industry environment of the sea and prevention of a calamity, there of it's exterminate prevention of a clamity after "nothing"and "no problem?? | |
| KR20120095337A (en) | An atomic reactor equipment and nuclea waste management using there with of a nuclear explosion prevention rule of duplication structure tank block | |
| KR20180017061A (en) | Distribution input device for marine products | |
| KR20140094482A (en) | Global nuclear power reactors of different types of body hydroelectric plants operating nuclear power plant reactor shield alternative nuclear waste disposal facility for nuclear reactor radiation leak precipitator control dual structure of the main body of the block distribution feeder tank | |
| KR20180083280A (en) | Dispensing device of aquaculture farm with construction machinery | |
| KR20200099259A (en) | Tsunami disaster prevention dispensing device | |
| KR20150138126A (en) | Nuclear Waste double block structure, the dust collector tank boiling water reactor nuclear power plant equipment for nuclear power plants | |
| KR20160132349A (en) | Manufacturing of the ship corresponding to the ship and the par Bull jet capital of lifesaving entanglement preventing | |
| KR20180019134A (en) | Dual-structure fast reactor breeder reactor facility for ocean won private nuclear waste treatment | |
| KR20150138127A (en) | Nuclear waste disposal in the nuclear power plant facilities dual structure for pressurized water reactor nuclear power plant | |
| KR20170043487A (en) | Marine steel works with metal smelting furnaces and construction machinery | |
| KR20170081589A (en) | Typhoon Disaster Discharge Distribution Input Device | |
| KR20160093580A (en) | Public water landfill of fisheries development apparatus even the ocean with a tunnel of traffic equipment | |
| KR102452262B1 (en) | Dependent Poisoning System for Earthquake Tsunami Prevention | |
| CN110331991A (en) | Ultra-shallow earth-covered lower big section tube coupling crosses the river the riverbed preprocess method of jacking construction | |
| KR20140005836A (en) | Peace retained reclamation construction machinery processing unit which is equipped with | |
| CN104743072A (en) | Combined buoyancy marine reclaimed land | |
| KR20150138129A (en) | Nuclear Waste Nuclear Power Plant reactors equipped with dual structure for high-speed growth of nuclear power plants | |
| KR20150138130A (en) | The dual structure of a nuclear waste disposal facility for nuclear power plants switch to the new nuclear power plant reactors | |
| KR20200100268A (en) | Dispatching device for landslide disaster prevention | |
| KR20160101884A (en) | Marine products cultivation marine products and public water landfill construction machinery of seafood processing equipment |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| A201 | Request for examination | ||
| E902 | Notification of reason for refusal | ||
| E601 | Decision to refuse application |