KR20100062277A - Business modul of ocean city construction and self-product energy system is attened with marine reservoir - Google Patents

Abstract

PURPOSE: A marine city construction business module utilizing a sea reservoir and a self-generation energy supply system are provided to activate marine electric power production by converting the electric power energy into hydrogen energy in the sea and supplying the hydrogen energy. CONSTITUTION: A marine city construction business module utilizing a sea reservoir and a self-generation energy supply system comprise a sea fixed standing complex tidal power plant system and a system module. The sea fixed standing complex tidal power plant system comprises a fixed lower water tank, a floating water power plant, a platform, and an upper water tank, and a floating air power plant. The water power generator and a pneumatic power generator successively operate and generate the electricity by the tidal energy. In the system module, ballast is equipped with the bottom of the floating lower water tank, the sea floating standing complex tidal power floating power plant is built and installed in the sea. A hydrogen gas manufacturing chamber, a hydrogen fuel cell manufacturing chamber, and a liquid hydrogen gas manufacturing chamber produce the hydrogen fuel using the electricity produced by the floating power plant.

Description

BUSINESS MODUL OF OCEAN CITY CONSTRUCTION AND SELF-PRODUCT ENERGY SYSTEM IS ATTENED WITH MARINE RESERVOIR}

A fixed upright composite tidal power plant or floating upright composite tidal power line is installed on the sea, and it utilizes tidal power to create a hybrid system and a floating floating upright composite tidal power line at the same time. The system is fixed to the height, and the system module for producing hydrogen fuel using the generated electric power, the sea stationary upright hybrid tidal power generation facility, the sea floating upright hybrid tidal power generation line, and the casing are combined to create an offshore reservoir and produce electricity. Business model for supplying power to facilities installed in offshore reservoirs and managing facilities housed in offshore reservoirs

The hydrodynamic generator is operated by controlling the nozzle and the electric valve for the first tidal tide and the low tide of the tidal power, and the aerodynamic generator is operated with the air pressure generated by controlling the air obtained from the second upright structure with the nozzle and the electric valve. Combined with the reciprocating motion of the nano-magnet pole attached to the platform inside the coil core, power energy is produced in a complex manner. The ballast is mounted at the bottom of the lower tank to install the power line in the specific structure. A business model that connects and assembles a system module that manufactures hydrogen fuel, an offshore stationary upright power generation facility, an offshore floating upright power generation line, and a casing to create an offshore reservoir and install, manage, and operate facilities on the offshore reservoir.

Until now, the tidal power generation technology has been mainly used to produce electric power by rotating a turbine of a generator by installing a dam in the coastal waters by tidal wave over a certain height, or by using wave power or tidal current. This enormous demand, huge installation area, and ecological flows are blocked by underwater dams, causing continuous damage in terms of environment, and the latter method is ineffective and falls short of the required power generation capacity. In the case of power generation, there are difficulties in installing the power cable on the sea floor to the land, so it is friendly to the marine environment and provides the facilities to convert power energy into secondary energy and supply power generation structure to produce maximum power generation capacity.

Accordingly, the present invention is a fixed offshore tank, a hydroelectric generator, a platform, an upper tank, and an aerodynamic generator. It is a system that builds and installs an offshore floating upright composite tidal power line equipped with a ballast at the bottom of the hybrid system and a floating sub-tank. Solve the problem with the synergy effect of triple generation of electricity without affecting the flow of seawater by creating a marine reservoir by connecting and assembling the system module to produce and supply, and the manufactured and dried power generation facilities, power lines and casing.

First of all, the effect of the present invention is an environmentally friendly power plant that protects marine resources without disturbing the flow of tides.

Second, maximize energy generation efficiency with upright structured complex energy production system

Third, the activation of marine power production by converting and supplying power energy to hydrogen energy at sea

Fourth, clean ocean energy production without fear of exhaustion by infinite energy of daily celestial movement

Fifth, KNOW-HOW for the construction of offshore floating structures, various marine data accumulated due to the installation of power lines, and ancillary cage operations

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a view of the marine fixed upright composite tidal power generation facility according to the present invention, the fixed ground water tank 10 is settled from the basement of the seabed ground line 230 and the hydroelectric generator 90 is built into the upper end of the fixed ground water tank 10. The hydroelectric generator 20 is mounted and the fixed platform 30 is mounted on the top of the fixed bottom water tank 10, and the aerobic power generation top tank 40 is mounted on the top of the fixed platform 30, and the aerospace power upper tank 40 ) The hydrogen gas production chamber 50, the hydrogen fuel cell production chamber 60, and the liquefied hydrogen gas production chamber 60 'are mounted on the top, and the control chamber 70 is mounted on the hydrogen gas production chamber 50. It is a fixed offshore integrated tidal power plant (260).

Figure 2 is a marine floating upright composite tidal power generation line according to the present invention, the ballast 240 is fixed at the bottom and the floating bottom water tank (10 ') is mounted on the top of the bellows 240 and floating underground water tank (10) ') Is equipped with a hydroelectric generator 20, the hydroelectric generator 90 is built in the upper end of the floating platform 30' is mounted on the top of the fixed lower water tank 10 and the floating platform 30 'top The aerospace power plant water tank (40) is mounted on the aerospace power plant water tank (40), the aerobic generator box (80), the hydrogen fuel cell manufacturing room (60) and the liquefied hydrogen gas manufacturing room ( 60 ') is a marine floating type upright composite tidal power line 300 of the structure is equipped with a control chamber 70 is mounted on top of the hydrogen gas production chamber (50).

Figure 3 is a marine fixed bottom water tank according to the present invention, the fixed bottom water tank 10, the coupling grooves 410 in the upper surface of the plurality of sluices 400 around the lower end and the coupling groove 420 from the upper end to the middle ) Is formed, the upper coupling coupling 410 is coupled to the stationary platform 30, the coupling groove 420 is coupled to the coupling plate 430 of the hydroelectric generator 20 and the sluice 400 is the channel of the seawater Play a role.

4 is a hydroelectric generator according to the present invention, the coupling plate 430 on the outer side of the hydroelectric generator 20 and the inner center is composed of a turbine chamber 440 on both sides of the power generating chamber 450 and the power generating chamber 450. The inner wall central portion of the hydro-powered rotating football 480 and the turbine chamber 440 at the lower end of the nozzle port 460 and the electric valve tube 470 and the coupling recess 410 is formed on the top of the hydro turbine (20) As an auxiliary material, there is a turbine chamber lower auxiliary plate 250 and a turbine chamber upper auxiliary plate 250 'so that the hydroelectric generator 20 is mounted inside the stationary lower tank 10 by the coupling plate 430. Hydroelectric generator 90 is mounted and the turbine blade 440 is equipped with a turbine blade 540 with a turbine blade 540 and a hydro-sealed seal bearing 130, and the turbine chamber lower auxiliary plate 250, which is an auxiliary material, and the turbine chamber image. The subsidiary plate 250 ′ increases the rotational force of the turbine chamber 440 by smoothly passing water, and the coupling recess 410 is coupled to the fixed platform 30. It serves to seal the open turbine chamber 400 and the developing chamber 450 and a nozzle mounted Province 460 and the electric valve Province 470. Each nozzle pipe 110 and the electric valve tube 120 to.

Figure 5 is a marine fixed platform in accordance with the present invention, the nozzle platform 460, the electric valve tube 470 and the coupling concave-convex 410 is formed in the lower center of the fixed platform 30, the pipe port 490 and the outside Coupling unevenness 410 is formed, the nozzle tube 460 and the electric valve tube 470 is formed in the upper central portion and the pipe hole 490 and the coupling unevenness 410 is formed on the outside of the lower central coupling unevenness (410) ) Is combined with the hydro box 20 to seal the hydro box and the outer coupling concave and convex 410 is combined with the fixed bottom water tank 10 is integrated and the pump of the hydrogen gas production chamber 50 in the piping port 490 Water supply pipe 170 associated with the 150 is piped and the nozzle tube 460 and the electric valve tube 470 is mounted to the nozzle tube 110 and the electric valve tube 120, respectively.

6 is a top view of the aerodynamic power generation tank according to the present invention, the pipe port 490 in the center of the lower end of the aerodynamic power upper water tank 40, the nozzle tube 460 and the electric valve tube 470 and the coupling concave and convex 410 Is formed and the coupling concave-convex 410 is formed in the upper center and the outer side so that the water pipe 170 is mounted in connection with the pump 150 of the hydrogen gas production chamber 50 in the piping port 490 and the central coupling concave ( 410, the hydrogen gas production chamber 50, the hydrogen fuel cell production chamber 60 and the liquefied hydrogen gas production chamber (60 ') is coupled, the aerodynamic generator (80) is coupled to the outer coupling concave-convex (410) and nozzle tube 460 and the electric valve tube 470 is mounted to the nozzle tube 110 and the electric valve tube 120, respectively.

7 is a hydrogen gas production chamber, a hydrogen fuel cell production chamber, a liquefied hydrogen gas production chamber, a control room according to the present invention, the coupling irregularities 410 are formed at the upper and lower ends of the hydrogen gas production chamber 50 and the lower side of the side surface. Piping port 490 is formed on the bottom of the hydrogen fuel cell manufacturing chamber 60 and the liquefied hydrogen gas manufacturing chamber 60 'coupling concave and convex 410 is formed in the lower side of the pipe port 490 is formed Coupling irregularities 410 are formed at the lower end of the control chamber 70, and the coupling irregularities 410 formed in the hydrogen gas production chamber 50, the hydrogen fuel cell production chamber 60, and the liquefied hydrogen gas production chamber 60 '. ) Is combined with the aerobic power plant water tank (40) and the combined concave-convex (410) of the manufacturing room (70) is combined with the hydrogen gas production room (50), hydrogen gas production room (50) and hydrogen fuel cell production room (60) The water supply pipe 170 is disposed at the bottom in connection with the pump 150 installed in the hydrogen gas production chamber 50 at the piping port 490 of the liquefied hydrogen gas production chamber 60 '. Hydrogen gas 650 piped and produced in the hydrogen gas production chamber 50 is supplied to the hydrogen fuel cell production chamber 60 and the liquefied hydrogen gas production chamber 60 'through the upper gas pipe 660.

8 is a combination of aeroelectric power generation diagram according to the present invention, the coupling unevenness 410 is formed at the lower end of the aerodynamic power generation box 80 and the turbine chamber 440 on both sides of the power generation chamber 450 and the power generation chamber 450 in the center; The nozzle tube 460 and the electric valve tube 470 are formed at the bottom of the turbine chamber of the aeroelectric power generating rotary football 500 and the aerobic power box 80 at the center of the inner wall. Coupling irregularities 410 and the nozzle tube 460 and the electric valve tube 470 is formed on the outside coupled to the coupling concave and convex 410 formed on the lower end of the aeroelectric power generating box 80 and the aerodynamic power supply tank 40 and aerodynamic Turbine rotary shaft 530 of the aerospace generator 80 is equipped with an aeroelectric generator 100 in the power generating chamber 450 of the power generating box 40 and the turbine blade 540 and the aerodynamic power seal bearing 140 are attached. Coupling unevenness 410 and aerodynamic generator box 80 formed on the aerospace power box cover 80 'are attached to the seal 440, respectively, and are connected to the nozzle tube 460 and the electric valve tube 470, respectively. Fit the jeulgwan 110 and the electric valve tube 120.

9 is a ballster diagram according to the present invention, the lower end of the ballast 240 to form an unevenness to increase the buoyancy area, the upper end of the pipe port 490 is formed in the floating platform 30 'pump 150 Coupling unevenness 410 is formed in conjunction with the hydrophobic pipe 170 and the drain pipe 170 'in conjunction with the floating bottom water tank (10') is integrated.

10 is a seafloor bottom tank according to the present invention, the coupling bottom unevenness 410 is formed at the top and bottom of the floating bottom water tank (10 '), the lower portion of the floating bottom water tank (10') ballast ( It is coupled to the 240 and the floating platform 30 'is coupled to the upper body is integrated into the water gate 400 formed around the lower end.

Figure 11 is a sea floating platform in accordance with the present invention in the lower center of the floating platform 30 'nozzle nozzle 460 and the electric valve tube 470 and the pipe port 490 and the anchor line 510 in sequence on the outside ) Is formed, and the coupling irregularities are formed at the center and the outer side, and the coupling irregularities 410 are formed at the upper outer side, so that the lower center and outer coupling irregularities 410 of the floating platform 30 'are hydro-electrically generated, respectively. (20) combined with the floating lower water tank (10 '), the hydroelectric power box 20 is sealed and the floating lower water tank (10') and the floating platform (30 ') are integrated and the nozzle tube (460) and electric Each valve pipe 470 is equipped with a nozzle pipe 110 and an electric valve pipe 120, and each pipe hole 490 includes a pump 150 installed in a hydrogen gas production chamber 50 and a floating platform 30 ′. ) In connection with the water supply pipe 170 and the drain pipe (170 ') is installed in the anchor rope (510) in conjunction with the winch 160 to install the anchor rope (180).

12, 13, 14, and 15 are attached to the power plant according to the present invention, the nozzle tube 110 of FIG. 12 generates water pressure or air pressure, and the electric valve tube 120 opens and closes the electric valve to open and close the water and the stage or the aeration. And short-term control and the hydro-generating seal bearing 130 and the aero-generating seal bearing 140 are attached to the turbine rotation shaft 530, the inner power generation chamber 450 of the hydro-powered bin (20) and aerospace (80). And the inner wall of the turbine chamber 440 is mounted on the hydro-power rotary football 480 and the aerodynamic power rotary football 500 serves to seal the power generation chamber 450 and the turbine chamber 440.

The pump 150 of FIG. 13 is installed in the hydrogen gas production chamber 50 and the floating platform 30 'so that the pump 150 of the hydrogen gas production chamber 50 is the hydrogen gas production chamber 50 and the fixed lower water tank. Supplying fresh water and water to the (10) and the floating bottom water tank (10 '), the pump 150 of the floating platform (10') is fresh water or drainage in the ballast 240, the winch 160 is floating When anchored and settled in the offshore floating type upright composite tidal power line 300, the anchor platform 180 and the anchor 190 are adjusted and the water supply pipe 170 and the drain pipe 170 'are installed on the food platform 30'. Fresh water or drainage in the ballast 240 in conjunction with the 150 and supplies fresh water and water to the fixed bottom water tank 10 and the floating bottom water tank (10 ') and the anchor line 180 is a winch (160) And anchors in conjunction with the 190 helps the anchoring and settlement of offshore floating vertical tidal power generation line (300).

Anchor 190 of Figure 14 in conjunction with the winch 160 and the anchor line 180 to assist in anchoring and settling of the offshore floating vertical tidal power generation line 300, the lowest water level 200 and the average water level 210 And the ultra-high water level 220 is the main tidal energy that is the core of the present invention is a driving force for producing electric power by operating the hydro generator 90 and the aero generator 100.

The ground line 230 of FIG. 15 is a main element for fixing the fixed lower water tank 10 to the seabed, and the turbine chamber lower subplate 250 and the turbine chamber upper subplate 250 'are each turbine chamber of the hydropower 20. It is built in the 440 serves to double the rotational force of the turbine chamber 440 due to the water and the work tool 560 (not shown in the figure) and the work tool cover 560 '(not shown in the drawing) are ballast (240) and the fixed sub-bath (10), the floating sub-bath (10 ') and the hydroelectric chamber (20) of the power generation chamber 450, the turbine chamber 440 and the fixed platform (30) and the floating platform (30) ') And the aerospace upper tank (40), the piston upper upper tank cover (40' ') and the aerospace generator cover (80') are formed and installed in the proper position to be used in the installation and repair of each structure and power plant components do.

16 is a structural diagram of a hydroelectric generator according to the present invention, the hydroelectric generator 90 has a protruding generator rotating shaft 520 and a generator support 550 attached thereto, and the turbine blade shaft 530 has a turbine blade 540 and a hydroelectric seal bearing ( 130 is attached to the turbine rotation shaft 530 is attached to both sides of the generator rotation shaft 520 protruding to the hydro generator 90, the hydro-generating seal bearing 130 seals the turbine chamber 400 and the power generation chamber 450 The turbine blade 540 smoothly rotates.

17 is a structural diagram of an aeroelectric generator according to the present invention, a protruding generator rotary shaft 520 and a generator support 550 is attached to the aerodynamic generator 100, and the turbine blade 540 and the turbine blade 540 and aerodynamic seal bearing ( 140 is attached to the turbine rotating shaft 530 is attached to both sides of the generator rotating shaft 520 protruding to the aeroelectric generator 100 and the aerodynamic power seal bearing 140 seals the turbine chamber 400 and the power generating chamber 450 and The turbine blade 540 smoothly rotates.

18, 19, 20, 21, 22, 23, 24, 25, 26, 27 is an assembly diagram of the marine fixed upright composite tidal power generation equipment according to the present invention, the fixed lower tank (10), the hydroelectric generator (20), fixed type Platform (30), aerospace power plant water tank (40), hydrogen gas production room (50), hydrogen fuel cell production room (60), liquefied hydrogen gas production room (60,), aerobic power generation box (80), control room (70) In the integrated fixed offshore integrated tidal power plant (260)

A fixed lower water tank 10 formed with a plurality of sluices 400 at the bottom and a coupling recess 410 at the top and a coupling groove 420 formed at the inner upper end is buried in the ground line 230.

A plurality of coupling plate 430 and the power generation chamber 450 and the turbine chamber 44 on both sides of the power generation chamber 450 and the hydroelectric rotating shaft 480 on the inner wall and the nozzle tube at the bottom of the turbine chamber 440 ( 460 and the electric valve fitting 470 and the coupling groove 420 and the hydro turbine 20 of the fixed lower water tank 10 is fixed to the hydro turbine 20, the coupling recess 410 is formed on the upper coupling The plate 430 coincides with the hydro turbine 20 in the fixed upper water tank 10 inside the upper end and the stop coupling groove 420, the turbine chamber inside the turbine chamber 440 on both sides of the hydro turbine 20 The lower auxiliary plate 250 is installed, the nozzle tube 460 to the nozzle tube 110 and the electric valve tube 470 is equipped with the electric valve tube 120, the valve hydroelectric generator 20, the generator chamber 450 Hydroelectric generator 90 is provided with a rotating shaft 520 protruding from the hydro turbine 20. The turbine blade 530 and the turbine blade 540 and the hydroelectric seal bearing 130 are attached to the turbine shaft 530 in the turbine chamber 440. Turbine Rotating Shaft (530) Inserted into the hydro-power rotary shaft 480 is installed in the turbine chamber 440 on both sides to match the generator rotary shaft 520, and the turbine chamber lower auxiliary plate 250 'is mounted on both sides to complete the assembly of the hydro generator 90. .

Coupling unevenness 410 of the fixed bottom water tank 10 and the hydropower box 20 and the nozzle chamber 460 and the electric valve pipe 470 and the fixed platform in the turbine chamber 44 of the hydropower box 20 at the bottom A fixed lower water tank (10) and hydraulic power formed at the lower end of the fixed platform (30) where the pipe (490) is formed and the nozzle pipe (460) and the electric valve pipe (470) of the upper water tank (30) are formed at the top. Coupling irregularities 410 of the power generation box 20 and the fixed bottom structure 10 and the fixed platform 30 to match the coupling irregularities 410 formed on the upper end of the hydropower box 20 and the fixed bottom water tank 10 and The nozzle tube 110 and the electric valve tube 120 are installed on the nozzle tube 460 and the electric valve tube 470 formed on the fixed platform 30 and mounted on the upper end of the hydroelectric generator 20.

Piping port 490 is in the center and the coupling irregularities 410 and nozzle tube 460 and the electric valve tube 470 is coupled to the fixed platform 30 is formed at the bottom of the hydrogen gas production chamber (50) Hydrogen fuel cell manufacturing chamber (60) and liquefied hydrogen gas manufacturing chamber (60 ') and aerodynamic power generation box (80) coupling irregularities 410 and fixed platform of the upper coupling of the aerobic power generation upper tank (40) formed Coupling unevenness (410) formed on the top of the 30 is fitted in accordance with the water pipe (490) in the pipe port 490 formed in the center of the aerobic power generation upper tank (40) and install the pump 150 and pump ( 150) the water supply pipe 170 is connected to both sides to be installed below the minimum water level 200 through the piping port 490 of the fixed platform 30, and the hydrogen gas production chamber 50 and the hydrogen fuel production chamber 60 and Combined concave-convex 410 formed in the liquefied hydrogen gas production chamber 60 'and the combined concave-convex 410 formed on the upper end of the upper tank 40, the hydrogen gas production chamber 50 Fit the fuel cell 60 and the liquid hydrogen gas production chamber (60 ') at the top of the aerodynamic power upper tank (40).

The power generation chamber of the aeroelectric power generating box 80 is installed in the nozzle tube 460 and the electric valve tube 470 formed at the upper end of the aerodynamic power generating tank 40 and the electric valve tube 120, respectively. Equipped with an aeroelectric generator 100 having a power generation rotary shaft 520 on the 450, and aerodynamic power generation of the turbine rotary shaft 530 with the turbine blade 540 and the aerodynamic power seal bearing 140 attached to the turbine rotary shaft 530. Inserted into the aeroelectric power generating rotary shaft 500 formed on the inner wall of the (80) to be installed in the aeroelectric power generation box (80) on both sides of the turbine chamber 440 to match the generator rotation shaft (520) and to the bottom of the aerodynamic power generation cover (80 ') The aerodynamic power generation upper tank 40 is mounted on the top of the aerospace generator box 80 so that the coupling recess 410 and the coupling recess 410 formed at the top of the aerospace generator box 80 are matched. On both sides of the aeroelectric generator 100 is installed.

The control chamber 70 is mounted on the top of the hydrogen gas production chamber 50 so that the combined concavities and convexities 410 formed at the top of the hydrogen gas production chamber 50 and the control concavities and concave 410 formed at the control chamber 70 are fixed to each other. The composite tidal power generation facility 260 is integrated.

28, 29, 30, 31, 32 is an assembly diagram of the marine floating upright composite tidal power line according to the present invention, ballast 240, floating sub-tank (10 '), hydropower box (20), floating Platform (30 '), aerospace power plant water tank (40), hydrogen gas production room (50), hydrogen fuel cell production room (60), liquefied hydrogen gas production room (60,), aerospace power generation box (80), control room ( 70) In the integrated offshore floating vertical tidal power generation line 300

Between the upper coupling concave and convex 410 of the ballast 240 is formed with a pipe port 490 and the concave and convex 410 at the upper end of the plurality of water gates 400 and the coupling concave and convex 410 at the top In the middle of the coupling groove 420 is formed in the lower end of the floating bottom tank (10 ') is coupled to the coupling concave-convex 410 is matched and the hydroelectric generator 90 is built-in as in claim 1 20 is mounted on the inner top of the floating bottom water tank 10 'and the floating platform 30' is mounted on the top of the floating bottom water tank 10 'and the pump 150 on the top of the floating platform 30'. ) To install the water supply pipe 170 and the drain pipe 170 'in conjunction with the pump 150 at the bottom of the plumbing port 490 formed in the lowest water level 200 and the ballast 240 and floating platform (30') ) Install the winch 160 on the top to lower the anchor line 180 in conjunction with the winch in the anchor rope (510) formed on the floating platform (30 ') and install the anchor 190 The high power floating water tank (40) is mounted on the top of the high floating platform (30 '), and the hydrogen gas manufacturing room (50), the hydrogen fuel cell manufacturing room (60) and the liquefied hydrogen gas are mounted on the top of the air power generating water tank (40). The manufacturing chamber 60 'and the aeroelectric generator box 80 equipped with the aeroelectric generator 100 are installed, and the control chamber 70 is mounted on the hydrogen gas production chamber 50 so that the offshore floating type upright composite tidal power line ( 30) is integrated.

33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44 is a sea floating floating power generation line according to the present invention is a specific offshore anchorage installation diagram dried offshore floating type upright composite tidal power line Using the pump 150 mounted on the floating platform 30 'to the ballast 240 of 300, the fresh water to the ballast 240 while the offshore floating type upright composite tidal power line 300 to the sea When the fresh water is moved to the specific resolution and the ballast 240 is finished, the pump 150 is stopped.

The floating floating vertical tidal power generation line 300, which arrived at a specific sea, anchors the anchor 190 using the winch 160 mounted on the floating platform 30 'at the highest water level 220 for anchoring. It is settled below (230) and hydropower using the pump 150 installed in the hydrogen gas production chamber 50 from the top water level 210 to the lowest water level 200 to the lower part of the upper water tank (40) ( Fill the space of the turbine chamber 440 and the floating sub-tank 10 'of 30) to eliminate the void, stop the pump 150 and wait, and then become the highest water level 220 to the ballast 240 and floating Turbine chamber 440 of the lower tank (10 ') and the hydropower box (20) is filled with water, and the upper aerosol cutlery (40) is properly filled with the highest water level (220). ) Is full

Floating platform (30) by operating the pump 150 installed in the floating platform (30 ') by draining the fresh water inside the ballast 240, the floating floating vertical power generation line (300) by the floating platform (30) ') By adjusting the anchor line 180 using the winch 160 installed at the bottom of the water level 220 and the bottom of the hydroelectric power box 20, the operation of the pump 150 and the winch 160 is stopped. Thus, the floating floating vertical tidal power generation line 300 is settled at the height required for the best power generation in a particular sea.

45, 46, 47, 48, 49, 50, 51, 52 is a hydro-static stand-up combined tidal power generation equipment 260 produced as a high water power generation system according to the present invention is hydro-powered at the highest water level 220 (20) Open the electric valve pipe 120 of the hydrogen gas production chamber 50 to operate the pump 150, and through the water supply pipe 170 to the turbine chamber 440 and the fixed lower tank 10 of the hydroelectric generator 20 After fresh water, the fresh water from the sea level to the bottom of the aerobic power upper water tank (40) at the lowest water level (200) stops the operation of the pump 150 of the hydrogen gas production room (50), and when the tide comes to the bottom of the hydro power plant (20) The electric valve tube 120 and the lower electric valve tube 120 of the aerospace generator box 80 is closed to prepare for power generation.

As the lowest water level 200 rises to the average water level 210 and the highest water level 220 when the tide is high, the water is hydro-powered by the increased water pressure through the nozzle pipe 110 mounted at the bottom of the hydro power generator 20. The turbine blade 540 of the turbine chamber 440 is turned and moved to the aerobic power plant water tank 40 through the electric valve pipe 120 mounted on the fixed platform 30 to fill the aerospace power plant water tank 40. When the air inside the aerodynamic generator upper tank 40 is aerodynamic power generation (80) through the nozzle pipe 110 mounted on the lower portion of the aerodynamic generator (100) turbine blade (540) of the turbine chamber 44 with the increased air pressure Turned and exhausted to the outside through the open electric valve tube 120 mounted on the top, the power is produced in combination in the hydro-power generator (90) and aero-power generator (100)

When the ebb tide is prepared to close the upper electric valve tube 120 and the upper electric valve tube 120 of the hydro-electric power box (20) of the hydropower box (20) to prepare for power generation.

At low tide, the high water level (220) is lowered to the average water level (210) and the lowest water level (200), the water is hydro-powered by the increased water pressure through the nozzle pipe (110) mounted on the fixed platform (30) turbine room When the turbine blade 540 of the (440) is turned and moved to the fixed lower water tank (10) through the electric valve tube (120) mounted on the bottom of the hydroelectric generator (20), when the water is lowered in the aerodynamic power upper water tank (40). The outside of the aerobic power plant upper water tank 40 rotates the turbine blade 540 of the aeroelectric generator 100 and the turbine chamber 44 with the increased air pressure through the nozzle tube 110 mounted on the top of the aerodynamic power generation 80. It is a power production system diagram that is drawn into the aerospace power upper water tank 40 through the open electric valve tube 120 mounted on the lower side to produce a combination of power in the hydro generator 90 and the aeroelectric generator 100.

53, 54, and 55 are schematic diagrams of a hydrogen fuel production system according to the present invention, in which a hydrogen gas production chamber 50 is used as a general method of converting power energy into hydrogen fuel energy in order to transport power produced on a distant high sea to land. The pump 150 is operated to fill the hydrogen gas production chamber 50 with water, and the hydrogen gas 650 produced by electrolyzing water with the generated power is converted into a hydrogen fuel cell production chamber 60 and a liquefied hydrogen gas production chamber ( 60 ') is a hydrogen fuel production system diagram for producing a hydrogen fuel cell 570 and a liquefied hydrogen gas 580.

56 is a sea stationary upright type bundle multiple tidal power generation facility according to the present invention, the hydropower generator (20) with a built-in hydropower station (20) is installed in a bundle on the inner top of the fixed bottom water tank (10) Complex tidal power plant (270)

Figure 57 is a marine stationary upright multi-stage combined tidal power generation facility according to the present invention is a hydro-mounted upright multi-stage installed multi-stage mounted on the inner top of the fixed lower water tank (10) with a hydro generator (90) built-in Complex tidal power plant (280)

Figure 58 is a marine fixed upright multi-stage combined tidal power generation facility according to the present invention, the hydro-powered generator 20 is built in a hydrostation 20 is installed in a multi-stage installation on the inner top of the fixed lower water tank (10) Upright Multi-stage Combined Tide Power Plant (290)

FIG. 59 is a marine floating upright bundle multiple tidal power generation lead according to the present invention, wherein a hydroelectric generator 20 having a hydroelectric generator 90 is installed in a bundle type on an inner upper end of a floating lower tank 20 '. Floating Upright Bundle Combined Tidal Power Line (310)

Figure 60 is a marine floating upright multi-stage combined tidal power generation lead according to the present invention, the hydro-powered generator 20 is built in a multi-stage mounted on the inner top of the floating sub-sea basin 20 ' Equipped vertical multistage tidal power line (320)

61 is a marine floating upright multi-stage combined tidal power generation line according to the present invention, a hydroelectric generator 20 having a hydroelectric generator 90 installed therein is installed in a multi-stage installation on an inner upper end of a floating lower water tank 20 '. Offshore Floating Upright Multi-stage Combined Tidal Power Line (330)

62, 63, and 64 are attached to the piston-type power plant according to the present invention. The nanocoil core 620 of FIG. 62 is a core in which a micrometer or nanometer-sized coil is properly combined with a power plant. Piston for generating electric power by generating an electromotive force on the nano-coil core 610 by advancing the speed of the nano-magnet pole 620 attached to the lifting platform 610 to move relatively as fast as 1 / micrometer or 1 / nanometer Generator parts

The piston power generation chamber 590 of FIG. 63 has a coupling recess 410 formed at an upper end and a lower end thereof so that the lower coupling recess 410 of the piston power generation chamber 590 is coupled to the floating upper water tank 30 ', and Coupled with the piston power generation chamber cover 590 'and the coupling recess 410 and the lifting cod 640 is formed at the bottom of the piston power generation chamber cover 590' and the lower coupling recess 410 is the piston power generation chamber 590. And coupled to the lifting cod 640, the lifting platform 610 is elevated.

64, the floating elevating body 600 is attached to the lifting platform 610 at the top and the nano-magnet bar 630 is attached to the upper platform 610, the lowest water level 200 and the average water level 210 and the highest water level 220 At the time of raising the inside of the nano-coil core 620, the electromotive force is induced.

65 is a piston generating upper water tank according to the present invention, the lower end and the upper end of the piston generating upper water tank 40 'is formed with a coupling unevenness 410 so that the lower portion of the piston generating upper water tank 40' is a floating platform 30. ') And the upper part is integrated with the piston generating upper tank cover (40 ") and integrated, and the lower end of the piston generating upper tank cover (40") has a lifting cod 640 and coupling concave and convex 410 is formed and Coupling unevenness 410 is formed at the center and the outer side, so that the lower portion of the piston generating upper water tank cover 40 "is coupled with the piston generating upper water tank 40 'and the coupling unevenness 410 at the upper center of the hydrogen gas production chamber. (50) and the hydrogen fuel cell manufacturing chamber 60 and the liquefied hydrogen gas production chamber 60 'is coupled and the coupling unevenness 410 on the outside of the top and the piston power generation chamber 590 is combined and integrated and the lifting cod 640 The lifting platform 610 of the floating lifting body 600 is mounted.

66, 67, 68 is a piston generating upper tank assembly according to the present invention, the fixed lower water tank 10 is buried in the ground of the ground line 230 and the hydroelectric generator 20 with a built-in hydro generator (90) It is mounted on the inner top of the fixed bottom water tank (10) and the fixed platform (30) is mounted on the top of the fixed bottom water tank (10)

Piping port 490 is in the center and the coupling unevenness 410 and the lifting cod 640 is coupled to the fixed platform 30 is formed at the bottom of the hydrogen gas production room 50 and hydrogen fuel cell manufacturing room ( 60) and the liquefied hydrogen gas production chamber (60 ') and the piston generator chamber 590, the coupling grooves (410) formed on the upper end of the piston coupling upper tank (40') formed on the upper end of the fixed platform (30) The coupling unevenness 410 is formed to be matched, and the lifting elevating body 600 having the lifting platform 610 is mounted inside the piston power generating tank 40 'and formed at the bottom of the piston power generating tank cover 40' '. The lifting platform 610 of the floating lifting body 600 is aligned with the coupling recess 410 formed at the upper end of the coupling recess 410 and the piston power upper tank 40 ', and is formed on the piston power upper tank cover 40' '. The piston generating upper tank cover 40 ″ is mounted on the piston generating upper tank 40 ′ so as to protrude into the cod 640.

Mounting the water supply pipe 170 in the pipe port 490 formed in the center of the piston power upper water tank (40 '), install the pump 150, and connected to the water supply pipe 170 on both sides of the pump 150 fixed platform (30) It is installed to be below the minimum water level 200 through the pipe port 490 of the coupling unevenness 410 formed in the hydrogen gas production chamber 50, the hydrogen fuel production chamber 60 and the liquefied hydrogen gas production chamber 60 ' And the upper and upper tanks 40, the coupling recesses 410 formed in the upper portion of the piston power generation tank 40 'to the hydrogen gas production chamber 50, the hydrogen fuel cell 60 and the liquefied hydrogen gas production chamber 60'. Should be mounted on top.

The nano magnetic bar 630 is attached to the lifting platform 610 of the floating lifting body 600 protruding to the upper portion of the piston power generating tank 40 ', and the nano coil core 620 is attached to the outside of the nano magnetic bar 630. In addition, the coupling recess 410 formed at the lower end of the piston power generating chamber 590 and the coupling recess 410 formed at the upper portion of the piston power generating tank 40 'coincide with the piston power generating chamber 590 outside the nanocoil core 620. Piston upper part tank (cover) is fitted to the coupling concave and convex 410 formed on the upper end of the piston generating upper tank (40 ') and the coupling concave and convex (410) formed on the upper end of the piston (40') 40 '') is mounted on the upper end of the piston generating upper tank 40 'to install the piston generator 100 on both sides of the piston generating upper tank 40', respectively.

The control chamber 70 is mounted on the top of the hydrogen gas production chamber 50 so that the combined concavities and convexities 410 formed at the top of the hydrogen gas production chamber 50 and the control concavities and concave 410 formed at the control chamber 70 are fixed to each other. Combined tidal power plant 1 (260 ') is integrated.

Figures 69, 70, and 71 are electric valve pipes 120 of the marine fixed upright combined type tidal power plant 1 (260 '), which is manufactured as a piston-type power generation system according to the present invention, is hydro-generated at the highest water level (220). Open the pump 150 of the hydrogen gas production chamber (50) to operate the fresh water in the turbine chamber 440 and the fixed lower water tank (10) of the hydroelectric power 20 through the water pipe (170) to the lowest water level (200) When fresh water from the sea surface to the bottom of the aerobic power plant upper water tank (40) at the end of the operation stops the pump 150 of the hydrogen gas production chamber 50, when the high water closes the bottom electric valve pipe 120 of the hydropower box (20) Prepare for development.

As the lowest water level 200 rises to the average water level 210 and the highest water level 220 when the tide is high, the water is hydro-powered by the increased water pressure through the nozzle pipe 110 mounted at the bottom of the hydro power generator 20. By turning the turbine blade 540 of the turbine chamber 440 and moving to the aerodynamic power generation tank 40 through the electric valve pipe 120 mounted on the fixed platform 30, water in the piston power generation tank 40 '. As it rises, the floating platform 600 and the lifting platform 610 in the upper portion of the piston power generation tank 40 'are raised, and the nano-magnet rod 630 attached to the lifting platform 610 in the piston power generation chamber 590 is nano. The electric power is produced in the hydroelectric generator 90 and the piston generator chamber 590 while climbing the inside of the coil core 620.

When the ebb tide is prepared to close the upper electric valve tube 120 and the upper electric valve tube 120 of the hydro-electric power box (20) of the hydropower box (20) to prepare for power generation.

At low tide, the high water level (220) is lowered to the average water level (210) and the lowest water level (200), the water is hydro-powered by the increased water pressure through the nozzle pipe (110) mounted on the fixed platform (30) turbine room By turning the turbine blade 540 of 440 and moving to the fixed lower water tank 10 through the electric valve tube 120 mounted on the bottom of the hydroelectric power 20, the water in the piston upper water tank 40 'is low. Floating platform 600 and the lifting platform 610 in the upper piston generator upper water tank 40 'is lowered and the nano-magnetic rod 630 attached to the lifting platform 610 in the piston power generation chamber 590 is nanocoil While going down inside the core 620 is a system diagram of a combination of power is produced in the hydroelectric generator 90 and the piston generator chamber (590).

Fig. 72 is a fixed bottom water tank diagram of a marine dam according to the present invention. The upper surface of the fixed water tank of the marine dam fixed bottom 680 is combined with a plurality of sluices 400 around the lower end and coupled to the middle from the upper end to the middle. The groove 420 and the coupling concave-convex 410 is formed from the upper end to the outer wall of the upper end coupling concave-convex 410 is coupled to the fixed platform 30 and the coupling groove 420 is the coupling plate 430 of the hydroelectric generator 20 Combined with) the sluice gate 400 is the channel of the sea water and the outer wall coupling concave-convex 410 serves to combine with the fixed lower water tank inter-wall 720.

Figure 73 is a floating dam floating bottom water tank according to the present invention, the coupling and concave and convex 410 is formed at the top and bottom of the offshore dam floating oil sub-bath (680 ') and the top to the bottom of the outer wall is formed In the lower portion of the floating lower tank (10 ') is coupled to the ballast 240 and the upper portion of the floating platform (30') is combined and integrated into the water gate 400 formed around the lower end and the outer wall coupling irregularities ( 410 is a fixed upper water tank inter-wall 710 is coupled.

74 is an upper water tank diagram of an offshore dam aerodynamic power generation according to the present invention, a pipe port 490 is coupled to a nozzle port 460 and an electric valve pipe 470 on an outer side of a lower center of the offshore dam aerospace power upper tank 690. Concave-convex 410 and the combined concave-convex 410 is formed from the upper end of the outer wall to the lower end and the concave-convex 410 is formed in the center and the top of the upper end of the pipe 490 in the hydrogen gas production chamber 50 ( The water supply pipe 170 is mounted in connection with the 150 and the hydrogen gas production chamber 50, the hydrogen fuel cell production chamber 60, and the liquefied hydrogen gas production chamber 60 'are coupled to the central coupling concave-convex 410 and coupled to the outside. The aerodynamic generator box 80 is coupled to the unevenness 410 and the nozzle tube 460 and the electric valve tube 470 are respectively mounted to the nozzle tube 110 and the electric valve tube 120. A water tank trunk 710 or a floating upper tank trunk 710 'is coupled.

75 is an offshore dam ballast diagram according to the present invention. The lower end of the ballast 240 forms an unevenness to increase the buoyancy area, and a pipe hole 490 is formed on the upper end thereof to install the floating platform 30 '. Coupling convexity 410 is mounted on the top and the hydrophobic pipe 170 and the drain pipe 170 'in conjunction with the 150 is integrated with the floating lower water tank (10') is integrated and formed from the top to the bottom of the outer wall Concave-convex 410 is a floating lower tank trunk wall 720 'is coupled.

FIG. 76 is a view of the fixed dam platform of the present invention according to the present invention, wherein the nozzle dam 460, the electric valve pipe 470, and the coupling recess 410 are formed at the lower center of the offshore dam fixed platform 780. 490 and the coupling concave and convex 410 is formed, the nozzle tube 460 and the electric valve tube 470 is formed in the upper center and the pipe port 490 and the coupling concave and convex 410 and the upper to the lower coupling Concave-convex 410 is formed, the bottom central coupling concave-convex 410 is combined with the hydro-sea (20) to seal the hydro-sea (20) and the outer coupling concave-convex 410 is combined with the fixed lower water tank (10) to integrate The water pipe 170 connected with the pump 150 of the hydrogen gas production chamber 50 is piped to the pipe port 490, and the nozzle pipe 110 and the electric valve pipe 470 are respectively connected to the nozzle pipe 110. The electric valve tube 120 is mounted and the outer coupling recesses 410 are fixed to the lower tank trunk wall 720 is mounted.

Figure 77 is a floating dam floating platform in accordance with the present invention in the lower center of the offshore dam floating platform (780 ') nozzle nozzle 460 and the electric valve tube 470 and the outside the pipe port 490 and the anchor in order Sphere 510 is formed and the coupling irregularities are formed in the center and the outside, the coupling irregularities 410 and the coupling upper and lower coupling 410 is formed from the top to the bottom of the upper and lower center of the floating platform 30 ' The outer coupling concave-convex 410 is combined with the hydropower box 20 and the floating sub-tank 10 ', respectively, so that the hydro-electric box 20 is sealed and the floating sub-bath 10' and the floating platform 30 ') Are integrated, and the nozzle tube 460 and the electric valve tube 470 are equipped with the nozzle tube 110 and the electric valve tube 120, respectively. In conjunction with the pump 150 installed on the floating platform (30 ') is equipped with a water pipe (170) and the drain pipe (170') and the anchor rope (510) winch ( The anchor wire 180 is installed in association with the 160 and the outer coupling recess 410 is mounted with a floating lower tank intertidal wall 720 '.

FIG. 78 is a casing diagram according to the present invention, wherein a coupling recess 410 is formed from an upper end of an outer wall of the fixed casing 730 to a lower end thereof so as to be combined with the fixed casing 740 and an upper end of the outer wall of the floating casing 730 ″. The coupling recesses 410 formed to the lower end of the floating casing interwall 740 'are coupled to each other, and the lower wall support 750 formed at the lower end serves to support the floating casing interwall 740'.

FIG. 79 is an interior wall diagram according to the present invention. The bottom of the floating casing 730 'and the floating casing 740' prevents the leakage of the marine reservoir 670 and the floating lower partition wall 720 'is fixed to the sea at a fixed interval. Offshore dam fixed bottom water tank (680) of tidal power plant 1 (300 ') and offshore dam belster (700) and offshore dam fixed bottom water tank (680) and offshore dam belster (700) are filled in the offshore reservoir (670). The fresh water is prevented from leaking to the sea, and the fixed casing partition wall 740 and the floating casing partition wall 740 'fill the gap between the fixed casing 730 and the floating casing 730' of the water reservoir tank 670. Prevent leakage between each block to the offshore reservoir 670 where repair or accident occurred Maintain the water level in the reservoir Maritime (670).

80 is a plurality of offshore fixed upright hybrid tidal power generation facilities 2 (260 ") assembled and manufactured as a low-resist composition composition using the offshore fixed upright composite tidal power generation facilities according to the present invention. In the space of the upper and lower ends of the coupling recess 410 and the coupling recess 410 formed on the outer wall of the composite tidal power plant 2 (260 "), respectively, the fixed upper tank trough wall 710 and the fixed lower tank trough wall 720 are installed. The fixed casing 730 is fixed at the bottom of the sea bed 230 at a predetermined interval in the center of the sea reservoir 670 formed by the fixed seam and the fixed casing interlayer 740 is installed on the coupling irregularities 410 formed on the outer wall Formation of the offshore reservoir 670 using the offshore stationary stand-alone hybrid tidal power plant 2 (260 ") with the fixed hydropower plant 760 installed at the proper location of the offshore reservoir 670 formed by blocking the reservoir 670. Power generation system.

81 is a seawater reservoir composition chart utilizing the marine floating upright composite tidal power generation line according to the present invention, which is formed on the outer wall of a plurality of marine floating upright composite tidal power generation lines 1 (300 ') which are dried and settled at a predetermined interval on a specific sea. Float bottom of the floating upper tank trough 710 'and floating lower tank trough 720' and the water reservoir 670 in the space of the top and bottom of the concave-convex concave and convex concave 410, respectively The floating casing 730 'is fixed to the sea at a predetermined interval in the center of the marine reservoir 670 formed by installing the mat 710, and the floating casing partition wall 740' is attached to the coupling irregularities 410 formed on the outer wall. The offshore reservoir utilizing the offshore floating type upright hybrid tidal power plant 1 (300 ') with the floating hydrological power generation line (760') installed at the proper position of the offshore reservoir (670) formed by blocking the offshore reservoir (670) by installing it. 670 composition and power generation system.

82 and 83 are views for generating electricity in an offshore reservoir 670 using an offshore fixed upright hybrid tidal power plant 2 (260 ") constructed as an offshore reservoir power generation system utilizing a fixed offshore fixed tidal power line according to the present invention. As a preliminary measure, the pump 150 installed in the hydrogen gas production room 50 of the offshore fixed type integrated tidal power plant 2 (260 ") installed at the lowest water level (200) was operated to operate the water supply pipe 170 and the drain pipe connected to the pump. The difference between the tide of the sea tide is when the sea water in the sea reservoir 670 is desalted through the sea reservoir 670 to a predetermined level higher than the sea level until the sea level becomes the highest water level 220 through 170 '. The water level of the water reservoir 670 and the water level of the water reservoir 670 are repeatedly raised and lowered with the potential energy of each, so that the fixed hydrological power generation equipment 760 and the fixed fixed upright combined tidal power generation equipment 2 (260 ") of the water reservoir 670 Hydro generator (90) and ball The generator is a power generation system 100 is at the same time produce power in triplicate.

84, 85, and 86 show a marine reservoir 670 utilizing an offshore floating type upright hybrid tidal power plant 1 (300 ') constructed as a marine reservoir power generation system utilizing an offshore floating upright composite tidal power line according to the present invention. Water level (200) as preliminary measure for power generation

The seawater is operated through the water supply pipe 170 and the drain pipe 170 'associated with the pump by operating the pump 150 installed in the hydrogen gas manufacturing room 50 of the installed offshore floating type upright hybrid tidal power generation facility 1 (300'). When the water level of the sea reservoir 670 is desalted to a predetermined level higher than the sea level until the sea becomes the highest water level 220 in the sea reservoir 670, the water level of the sea reservoir 670 is caused by the difference between the tides of the sea. And the sea level are repeatedly elevated with the potential energy of each other, and the aerodynamic power of the floating hydrological power generation line (760 ') of the offshore reservoir (670) and the hydroelectric generator (90) of the offshore floating vertical tidal power plant (300') The generator 100 is a power generation system that generates power in triple at the same time.

1 is a sea stationary upright composite tidal power plant according to the present invention

Figure 2 is a marine floating upright composite tidal power generation line according to the present invention

Figure 3 is a marine fixed bottom water tank according to the present invention

Figure 4 is also hydroelectric power generation according to the present invention

Figure 5 is a marine fixed platform in accordance with the present invention

Figure 6 is a top water tank of aerodynamic power generation in accordance with the present invention

7 is a hydrogen gas production room, a hydrogen fuel cell production room, a liquefied hydrogen gas production room, a control room according to the present invention

8 is aerodynamic development according to the present invention

9 is a ballster diagram according to the present invention

Figure 10 is a marine floating bottom tank according to the present invention

Figure 11 is a marine floating platform in accordance with the present invention

12, 13, 14, 15 is an accompanying view of the power plant according to the present invention

16 is a structural diagram of a hydroelectric generator according to the present invention;

17 is a structural diagram of aeroelectric generator according to the present invention

18, 19, 20, 21, 22, 23, 24, 25, 26, 27 is an assembly diagram of the marine stationary upright hybrid tidal power plant according to the present invention

28, 29, 30, 31, 32 is an assembly diagram of the marine floating upright composite tidal power line according to the present invention

33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44 is a sea floating floating power line specific marine settlement installation diagram according to the present invention

45, 46, 47, 48, 49, 50, 51, 52 is a power generation system according to the present invention

53, 54, 55 is a hydrogen fuel production system diagram according to the present invention

56 is a sea stationary upright bundle multiple tidal power generation facility according to the present invention

Figure 57 is a sea stationary upright multi-stage combined tidal power generation facility according to the present invention

58 is a sea stationary upright multi-stage combined tidal power generation system according to the present invention

59 is a marine floating upright bundle composite tidal power generation power line according to the present invention.

60 is a marine floating upright multi-stage combined tidal power generation line according to the present invention.

61 is a marine floating upright multi-stage composite tidal power generation power line according to the present invention.

62, 63, 64 is a view of the piston-type power plant according to the present invention

65 is a piston generating upper water tank according to the present invention.

66, 67, 68 is a piston generating upper tank assembly according to the present invention

69, 70, 71 is a piston type power generation system diagram according to the present invention

72 is a fixed bottom water tank diagram of the offshore dam according to the present invention

73 is a view of floating dam floating bottom water tank according to the present invention

74 is an upper water tank diagram of the offshore dam aeroelectric power generation system according to the present invention.

75 is a marine dam ballast diagram according to the present invention

76 is a casing diagram according to the present invention;

77 is a partition wall view according to the present invention.

78 is a view showing the composition of the offshore reservoir using the offshore fixed type upright combined tidal power plant according to the present invention.

79 is a view of the composition of the marine reservoir using the marine floating upright composite tidal power line according to the present invention

80, 81 is a marine reservoir power generation system utilizing the fixed fixed upright composite tidal power line according to the present invention

82, 83, and 84 is a marine reservoir power generation system utilizing the floating floating upright composite tidal power line according to the present invention

<Brief description of the main parts of the drawing>

10: fixed bottom water tank 10 ': floating bottom water tank

20: hydropower ship

30: fixed platform 30 ': floating platform

40: aerospace power tank 40 ': piston power upper tank

40 '': Piston Generation Upper Water Tank Cover

50: hydrogen gas production room

60: hydrogen fuel cell production room 60 ': liquefied hydrogen production room

70: control room

80: Aerogen generator 80 ': Aeronautical generator cover

90: hydroelectric generator 100: hydroelectric generator

110: nozzle tube 120: electric valve tube

130: hydroelectric seal bearing 140: aerodynamic seal bearing

150: pump 160: winch

180: anchor line 190: anchor

200: lowest water level 210: average water level

220: highest water level 230: ground line

240: ballast

250: turbine chamber lower auxiliary plate 250 ': turbine chamber upper auxiliary plate

260: Fixed offshore integrated tidal power plant

260 ': Offshore Fixed Standalone Combined Cycle Power Plant 1

260 ": offshore fixed type stand-alone hybrid tidal power plant2

270: Marine fixed upright multiple bundled tidal power plant

280: Fixed offshore multi-stage combined tidal power plant

290: Offshore fixed upright multi-stage combined tidal power plant

300: Offshore Floating Vertical Tidal Power Line

300 ': Offshore Floating Vertical Tidal Power Line 1

300: Offshore Floating Vertical Bundle Tidal Power Line

310: offshore floating vertical multistage tidal power line

320: Offshore floating vertical multistage tidal power line

400: sluice 410: coupling irregularities

420: coupling groove 430: coupling plate

440: turbine room 450: power generation room

460: nozzle port 470: electric valve port

480: hydro power rotating football 490: piping

500: aerodynamic rotation shaft 510: anchor rope

520: generator shaft 530: turbine shaft

540: turbine blade 550: generator support

570: hydrogen fuel cell 580: liquefied hydrogen gas

590: Piston Generation Chamber 590 ': Piston Generation Chamber Cover

600: floating platform 610: platform

620: nano coil core 630: nano magnetic rod

640: lift Daegu 650: hydrogen gas

660: gas pipe 670: offshore reservoir

680: fixed offshore fixed basin 680 ': offshore fixed offset basin

690: offshore dam aerospace power plant water tank 700: offshore dam ballast

710: floating bottom mat

720: Fixed subbath basin 720 ': Floating subbath basin

730: fixed casing 730 ': floating casing

740: fixed casing partition 740 ': floating casing partition

750: wall support

760: fixed hydro power plant 760 ': floating hydro power plant

770: offshore facilities

Claims (12)

Fixed bottom water tank (10), hydro power box (20), fixed platform (30), aerospace power upper water tank (40), hydrogen gas production room (50), hydrogen fuel cell production room (60), liquefied hydrogen gas production room (60,), aerodynamic generator box (80), control chamber 70 is composed of a fixed offshore fixed type integrated tidal power generation equipment (260) A fixed lower water tank 10 formed with a plurality of sluices 400 at the bottom and a coupling recess 410 at the top and a coupling groove 420 formed at the inner upper end is buried in the ground line 230. A plurality of coupling plate 430 and the power generation chamber 450 and the turbine chamber 44 on both sides of the power generation chamber 450 and the hydroelectric rotating shaft 480 on the inner wall and the nozzle tube at the bottom of the turbine chamber 440 ( 460 and the electric valve fitting 470 and the coupling groove 420 and the hydro turbine 20 of the fixed lower water tank 10 is fixed to the hydro turbine 20, the coupling recess 410 is formed on the upper coupling The plate 430 coincides with the hydro turbine 20 in the fixed upper water tank 10 inside the upper end and the stop coupling groove 420, the turbine chamber inside the turbine chamber 440 on both sides of the hydro turbine 20 The lower auxiliary plate 250 is installed, the nozzle tube 460 to the nozzle tube 110 and the electric valve tube 470 is equipped with the electric valve tube 120, the valve hydroelectric generator 20, the generator chamber 450 Hydroelectric generator 90 with a rotating shaft 520 protrudes and the hydro turbine 20, the turbine blade 540 and the hydroelectric seal bearing 130 is attached to the turbine shaft 530 in the turbine chamber 440 Rotary shaft (530) Inserted into the hydro-power rotary shaft 480 is installed in the turbine chamber 440 on both sides to match the generator rotary shaft 520, and the turbine chamber lower auxiliary plate 250 'is mounted on both sides to complete the assembly of the hydro generator 90. . Coupling unevenness 410 of the fixed bottom water tank 10 and the hydropower box 20 and the nozzle chamber 460 and the electric valve pipe 470 and the fixed platform in the turbine chamber 44 of the hydropower box 20 at the bottom A fixed lower water tank (10) and hydraulic power formed at the lower end of the fixed platform (30) where the pipe (490) is formed and the nozzle pipe (460) and the electric valve pipe (470) of the upper water tank (30) are formed at the top. Coupling irregularities 410 of the power generation box 20 and the fixed bottom structure 10 and the fixed platform 30 to match the coupling irregularities 410 formed on the upper end of the hydropower box 20 and the fixed bottom water tank 10 and The nozzle tube 110 and the electric valve tube 120 are installed on the nozzle tube 460 and the electric valve tube 470 formed on the fixed platform 30 and mounted on the upper end of the hydroelectric generator 20. Piping port 490 is in the center and the coupling irregularities 410 and nozzle tube 460 and the electric valve tube 470 is coupled to the fixed platform 30 is formed at the bottom of the hydrogen gas production chamber (50) Hydrogen fuel cell manufacturing chamber (60) and liquefied hydrogen gas manufacturing chamber (60 ') and aerodynamic power generation box (80) coupling irregularities 410 and fixed platform of the upper coupling of the aerobic power generation upper tank (40) formed Coupling unevenness (410) formed on the top of the 30 is fitted in accordance with the water pipe (490) in the pipe port 490 formed in the center of the aerobic power generation upper tank (40) and install the pump 150 and pump ( 150) by connecting the water supply pipe 170 to both sides and installed below the minimum water level 200 through the piping port 490 of the fixed platform 30 and the hydrogen gas production room 50 and the hydrogen fuel production room 60 and Combined concave-convex 410 formed in the liquefied hydrogen gas production chamber (60 ') and the combined concave-convex 410 formed on the upper tank 40, the hydrogen gas production chamber 50 and The hydrogen fuel cell 60 and the liquefied hydrogen gas production chamber 60 'are mounted on the upper end of the aerobic power plant upper tank 40. The power generation chamber of the aeroelectric power generating box 80 is installed in the nozzle tube 460 and the electric valve tube 470 formed at the upper end of the aerodynamic power generating tank 40 and the electric valve tube 120, respectively. Equipped with an aeroelectric generator 100 having a power generation rotary shaft 520 on the 450, and aerodynamic power generation of the turbine rotary shaft 530 with the turbine blade 540 and the aerodynamic power seal bearing 140 attached to the turbine rotary shaft 530. Inserted into the aeroelectric power generating rotary shaft 500 formed on the inner wall of the (80) to be installed in the aeroelectric power generation box (80) on both sides of the turbine chamber 440 to match the generator rotation shaft (520) and to the bottom of the aerodynamic power generation cover (80 ') The aerodynamic power generation upper tank 40 is mounted on the top of the aerospace generator box 80 so that the coupling recess 410 and the coupling recess 410 formed at the top of the aerospace generator box 80 are matched. On both sides of the aeroelectric generator 100 is installed. The control chamber 70 is mounted on the top of the hydrogen gas production chamber 50 to be integrated so that the coupling concave and convex 410 formed at the upper end of the hydrogen gas manufacturing chamber 50 and the control concave and convex 410 formed at the control chamber 70 are integrated. Marine fixed upright combined cycle tidal power generation equipment (260) Fixed bottom water tank (10), hydro power box (20), fixed platform (30), piston power generation top water tank (40 '), hydrogen gas production room (50), hydrogen fuel cell production room (60), liquefied hydrogen gas production In the offshore fixed type upright combined cycle power generation facility 1 (260 '), which is composed of a chamber (60), a piston power generation chamber (590), and a control chamber (70). As set forth in claim 1, the fixed lower water tank 10 is buried and grounded in the ground of the ground line 230, and the hydroelectric generator 20 in which the hydro generator 90 is mounted is mounted on the inner upper end of the fixed lower water tank 10. Mount the fixed platform (30) on the top of the fixed bottom tank (10) Piping port 490 is in the center and the coupling unevenness 410 and the lifting cod 640 is coupled to the fixed platform 30 is formed at the bottom of the hydrogen gas production room 50 and hydrogen fuel cell manufacturing room ( 60) and the liquefied hydrogen gas production chamber (60 ') and the piston generator chamber 590, the coupling grooves (410) formed on the upper end of the piston coupling upper tank (40') formed on the upper end of the fixed platform (30) The coupling unevenness 410 is formed to be matched, and the lifting elevating body 600 with the lifting platform 610 is mounted inside the piston power generating tank 40 'and formed at the bottom of the piston power generating tank cover 40' '. The lifting platform 610 of the floating lifting body 600 is aligned with the coupling recess 410 formed at the upper end of the coupling recess 410 and the piston power upper tank 40 ', and is formed on the piston power upper tank cover 40' '. The piston generating upper tank cover 40 ″ is mounted on the piston generating upper tank 40 ′ so as to protrude into the cod 640. Mounting the water supply pipe 170 in the pipe port 490 formed in the center of the piston power upper water tank (40 '), install the pump 150, and connected to the water supply pipe 170 on both sides of the pump 150 fixed platform (30) It is installed to be below the minimum water level 200 through the pipe port 490 of the coupling unevenness 410 formed in the hydrogen gas production chamber 50, the hydrogen fuel production chamber 60 and the liquefied hydrogen gas production chamber 60 ' And the upper and upper tanks 40, the coupling recesses 410 formed in the upper portion of the piston power generation tank 40 'to the hydrogen gas production chamber 50, the hydrogen fuel cell 60 and the liquefied hydrogen gas production chamber 60'. Should be mounted on top. The nano magnetic bar 630 is attached to the lifting platform 610 of the floating lifting body 600 protruding to the upper portion of the piston power generating tank 40 ', and the nano coil core 620 is attached to the outside of the nano magnetic bar 630. The nano-coil core 620 is installed in the piston power generating chamber 590 so that the coupling unevenness 410 formed at the lower end of the piston power generating chamber 590 and the coupling unevenness 410 formed on the upper portion of the piston power generating tank 40 'are matched. Piston generator upper tank (cover) mounted on the outside and the coupling recess 410 formed on the lower end of the piston generator upper tank cover 40 '' and the coupling recess 410 formed on the upper end of the piston generator upper tank 40 ' (40 '') is mounted on the upper end of the piston generating upper tank (40 '), and the piston generator (100) is installed on both sides of the piston generating upper tank (40'), respectively. The control chamber 70 is mounted on the top of the hydrogen gas production chamber 50 to be integrated so that the coupling concave and convex 410 formed at the upper end of the hydrogen gas manufacturing chamber 50 and the control concave and convex 410 formed at the control chamber 70 are integrated. Marine fixed upright combined cycle tidal power plant 1 (260 ') Ballaster 240, Floating Sub Tank (10 '), Hydro Power Plant (20), Floating Platform (30'), Aerospace Upper Tank (40), Hydrogen Gas Production Room (50), Hydrogen Fuel Cell Manufacturing In the offshore floating type upright integrated tidal power generation line 300, which is composed of a chamber 60, a liquefied hydrogen gas production chamber 60, an aeroelectric power generating box 80, and a control room 70. Between the upper coupling concave and convex 410 of the ballast 240 is formed with a pipe port 490 and the concave and convex 410 at the upper end of the plurality of water gates 400 and the coupling concave and convex 410 at the top In the middle of the coupling groove 420 is formed in the lower end of the floating bottom tank (10 ') is coupled to the coupling concave-convex 410 is matched and the hydroelectric generator 90 is built-in as in claim 1 20 is mounted on the inner top of the floating lower water tank 10 ', and the floating platform 30' is mounted on the upper portion of the floating lower water tank 10 ', and the pump on the top of the floating platform 30' ( 150 to install the water supply pipe (170) and the drain pipe (170 ') in conjunction with the pump 150 at the bottom of the water pipe (490) formed in the lowest water level 200 and the ballast 240 and floating platform (30) ') Install the winch 160 on the top of the anchor platform (510) formed on the floating platform (30') in conjunction with the winch to lower the anchor line 180 and install the anchor 190 and The aerodynamic power generation tank 40 is mounted on the floating platform 30 ', and the hydrogen gas production chamber 50, the hydrogen fuel cell manufacturing chamber 60, and the liquefied hydrogen gas production are mounted on the top of the aerobic power generation tank 40. Marine 60 ', and the aerodynamic generator box 80 is equipped with an aeroelectric generator 100 is installed, and the control room 70 is mounted on the hydrogen gas production chamber 50 is integrated, characterized in that the offshore floating type upright type Combined Tidal Power Lines (300) The marine fixed upright combined cycle power generation equipment 260 manufactured in claim 1 opens the electric valve tube 120 of the hydroelectric generator 20 at the highest water level 220, and then pumps 150 of the hydrogen gas production chamber 50. ) And fresh water into the turbine chamber 440 and the fixed lower water tank 10 of the hydropower plant 20 through the water pipe 170 to fresh water from the sea level from the sea level to the lower portion of the aerodynamic upper water tank 40. When the pump 150 of the hydrogen gas production chamber 50 is terminated when the end of the high tide, the bottom electric valve tube 120 and the bottom electric valve tube 120 of the hydroelectric power box (20) Close to prepare for power generation. As the lowest water level 200 rises to the average water level 210 and the highest water level 220 when the tide is high, the water is hydro-powered by the increased water pressure through the nozzle pipe 110 mounted at the bottom of the hydro power generator 20. The turbine blade 540 of the turbine chamber 440 is turned and moved to the aerobic power plant water tank 40 through the electric valve pipe 120 mounted on the fixed platform 30 to fill the aerospace power plant water tank 40. When the air inside the aerodynamic generator upper tank 40 is aerodynamic power generation (80) through the nozzle pipe 110 mounted on the lower portion of the aerodynamic generator (100) turbine blade (540) of the turbine chamber 44 with the increased air pressure Turned and exhausted to the outside through the open electric valve tube 120 mounted on the top, the power is produced in combination in the hydro-power generator (90) and aero-power generator (100) When the ebb tide is prepared to close the upper electric valve tube 120 and the upper electric valve tube 120 of the hydro-electric power box (20) of the hydropower box (20) to prepare for power generation. At low tide, the high water level (220) is lowered to the average water level (210) and the lowest water level (200), the water is hydro-powered by the increased water pressure through the nozzle pipe (110) mounted on the fixed platform (30) turbine room When the turbine blade 540 of the (440) is turned and moved to the fixed lower water tank (10) through the electric valve tube (120) mounted on the bottom of the hydroelectric generator (20), when the water is lowered in the aerodynamic power upper water tank (40). The outside of the aerospace power plant water tank 40 turns the turbine blades 540 of the aerospace generator 100 and the turbine chamber 44 with the increased air pressure through the nozzle pipe 110 mounted on the top of the aerodynamic generator 80. It is sucked into the aerobic power generation upper tank (40) through the open electric valve tube 120 mounted on the hydroelectric generator (90) and the aerodynamic generator (100) is produced in combination The pump 150 of the hydrogen gas production chamber 50 is operated to fill the hydrogen gas production chamber 50 with water, and the hydrogen gas 650 produced by electrolyzing water with the generated power is used to produce a hydrogen fuel cell manufacturing chamber 60. ) And a hydrogen fuel cell manufacturing system module, characterized in that the hydrogen fuel cell 570 and the liquefied hydrogen gas 580 is supplied to the liquefied hydrogen gas manufacturing chamber (60 '). The marine stationary upright combined cycle tidal power plant 1 (260 ') manufactured in claim 2 opens the electric valve tube 120 of the hydroelectric generator 20 at the highest water level 220 to pump the hydrogen gas production chamber 50. Operation 150 and desalination in the turbine chamber 440 and the fixed lower water tank 10 of the hydroelectric power 20 through the water pipe 170 to lower the aerodynamic power upper tank 40 at sea level at the lowest water level 200 When fresh water is finished, the pump 150 of the hydrogen gas production chamber 50 is stopped, and when the tide becomes high, the electric valve tube 120 of the hydroelectric generator 20 is closed to prepare for power generation. As the lowest water level 200 rises to the average water level 210 and the highest water level 220 when the tide is high, the water is hydro-powered by the increased water pressure through the nozzle pipe 110 mounted at the bottom of the hydro power generator 20. By turning the turbine blade 540 of the turbine chamber 440 and moving to the aerodynamic power generation tank 40 through the electric valve pipe 120 mounted on the fixed platform 30, water in the piston power generation tank 40 '. As it rises, the floating platform 600 and the lifting platform 610 in the upper portion of the piston power generation tank 40 'are raised, and the nano-magnet rod 630 attached to the lifting platform 610 in the piston power generation chamber 590 is nano. The electric power is produced in the hydroelectric generator 90 and the piston generator chamber 590 while climbing the inside of the coil core 620. When the ebb tide is prepared to close the upper electric valve tube 120 and the upper electric valve tube 120 of the hydro-electric power box (20) of the hydropower box (20) to prepare for power generation. At low tide, the high water level (220) is lowered to the average water level (210) and the lowest water level (200), the water is hydro-powered by the increased water pressure through the nozzle pipe (110) mounted on the fixed platform (30) turbine room By turning the turbine blade 540 of 440 and moving to the fixed lower water tank 10 through the electric valve tube 120 mounted on the bottom of the hydroelectric power 20, the water in the piston upper water tank 40 'is low. Floating platform 600 and the lifting platform 610 in the upper piston generator upper water tank 40 'is lowered and the nano-magnetic rod 630 attached to the lifting platform 610 in the piston power generation chamber 590 is nanocoil The power is produced in the hydro generator 90 and the piston generator chamber 590 while descending the core 620. The pump 150 of the hydrogen gas production chamber 50 is operated to fill the hydrogen gas production chamber 50 with water, and the hydrogen gas 650 produced by electrolyzing water with the generated power is used to produce the hydrogen fuel cell production chamber 60. ) And a hydrogen fuel cell manufacturing system module, characterized in that the hydrogen fuel cell 570 and the liquefied hydrogen gas 580 is supplied to the liquefied hydrogen gas manufacturing chamber (60 '). Fresh water to the ballaster 240 using the pump 150 mounted on the floating platform 30 'to the ballast 240 of the offshore floating type upright composite tidal power line 300 of claim 3 While launching the offshore floating type upright composite tidal power line 30 to the sea and moving to a specific sea, the fresh water in the ballast 240 stops the operation of the pump 150. The offshore floating type upright tidal power generation line 300, which arrived at a specific sea, is anchored using an anchor 190 using a winch 160 mounted on a floating platform 30 'at the highest water level 220 for anchoring. Settles below the line 230 and uses the pump 150 installed in the hydrogen gas production chamber 50 to hydroelectrically the lower portion of the upper water tank 40 from the highest water level 210 to the lowest water level 200. Filling the space of the turbine chamber 440 and the floating sub-tank (10 ') of 30 to eliminate the empty space, stop the pump 150 and stand by the highest water level 220, the ballast 240 and floating Turbine chamber 440 of the edible water tank 10 'and the hydropower vessel 20 is filled with water, and the aerodynamic power upper cutlery 40 is properly filled with the highest water level 220, so that the offshore floating vertical tidal power line ( 300) When it is full Floating platform (30) by operating the pump 150 installed in the floating platform (30 ') by draining the fresh water inside the ballast 240, the floating floating vertical power generation line (300) by the floating platform (30) ') By adjusting the anchor line 180 using the winch 160 installed at the bottom of the water level 220 and the bottom of the hydroelectric power box 20, the operation of the pump 150 and the winch 160 is stopped. Specific marine settlement system module of the marine floating vertical tidal power generation line 300, characterized in that to set up the marine floating vertical tidal power generation line 300 In claim 1, the hydro-powered generator 20, the built-in hydroelectric generator 20 is installed on the inner top of the fixed lower water tank 10, characterized in that the marine fixed upright bundle multiple tidal power generation equipment 270 and The water stationary upright multi-stage hybrid tidal power generation facility, characterized in that the hydroelectric generator 20 is built in claim 1 is installed in multiple stages on the inner top of the fixed lower water tank (10). )and The water stationary upright multi-stage hybrid tidal power generation facility, characterized in that the hydroelectric generator (20) having a built-in hydroelectric generator (90) is installed in multiple stages on the inner top of the fixed lower water tank (10). 280) In claim 3, the hydro-powered generator 20 with a built-in hydro-electric generator (20) is a multi-floating upright type multiple bundle tidal power line 310 is installed in a bundle mounted on the inner top of the floating lower tank (20 ') and  The marine floating vertical multistage tidal power generation line is characterized in that the hydroelectric generator 20, the hydroelectric generator 90 is built in the multi-stage mounted on the inner top of the floating lower tank (20 '). 320 and The offshore floating type upright multi-stage composite tidal tidal power plant, characterized in that the hydroelectric generator (20) having a built-in hydropower generator (90) is installed in multiple stages on the inner upper end of the floating lower tank (20 '). Power Generation Lines (330) Offshore Dam Fixed Water Tank (680), Hydroelectric Power Plant (20), Offshore Dam Fixed Power Platform (780), Offshore Dam High Power Station (690), Hydrogen Gas Production Room (50), Hydrogen Fuel Cell Manufacturing Room (60) Liquefied hydrogen gas manufacturing chamber (60), aeroelectric power generating box (80), control room (70) in an integrated marine stationary upright hybrid tidal power plant (2,260 ") A plurality of sluices 400 at the bottom and the coupling irregularities 410 at the top of the offshore dam fixed bottom water tank 680 formed with coupling grooves 420 and the coupling irregularities 410 from the top to the bottom of the outer wall to the middle. The ground line 230 is buried in the basement and assembled and fabricated as in claim 1, but the fixed lower tank 10 and the fixed platform 30 are fixed to the offshore dam fixed subwater tank 680 and offshore dam fixed platform 780. A plurality of offshore fixed type upright hybrid tidal power generation facilities 2 (260 "), which are assembled and manufactured by replacement, are fixed at sea at regular intervals, and combined irregularities 410 and coupling irregularities formed on the outer wall of the offshore fixed type upright hybrid tidal power generation facilities 2 (260") Fixed casing 730 in the center of the marine reservoir 670 formed by installing the fixed upper water tank inter-wall 710 and the fixed lower water tank inter-wall 720 in the space of the top and bottom of the 410, respectively Settled on the ground line 230 and formed on the outer wall It is characterized in that by installing the fixed casing interlocking wall 740 in the concave-and-convex 410 block the offshore reservoir 670 was formed and install the fixed hydrological power generation equipment 760 in the proper position of the formed offshore reservoir 670 Offshore Reservoir (670) Formation and Power Generation System Using the Fixed Offshore Integrated Tidal Power Plant 2 (260 ") Offshore Dam Ballast (700), Offshore Dam Floating Submersible (680 '), Hydroelectric Power Plant (20), Offshore Dam Floating Float Platform (780'), Aerodynamic Power Floating Upper Tank (40), Hydrogen Gas Production Room (50) Hydrogen fuel cell manufacturing chamber (60), liquefied hydrogen gas production chamber (60), aerodynamic generator box (80), control chamber 70 is composed of an integrated offshore floating type upright composite tidal power generation line 1 (300 ') Claim 3 and 6, but dry as the ballast 240, the floating sub-bath (10 ') and the fixed platform (30) is the offshore dam pallet (700) and offshore dam submerged subwater tank (680) ') And the combined irregularities (410) formed on the outer wall of a plurality of offshore type upright composite tidal power generation line 1 (300') assembled and manufactured by replacing it with the offshore dam floating platform (780 ') and settled at a certain interval on a specific sea. Floating casing (670) in the center of the offshore reservoir 670 formed by installing the floating upper tank basin 710 'and the floating lower tank basin 720' in the space of the top and bottom of the combined unevenness (410), respectively ( 730 ′) is fixed to the sea at regular intervals and the floating casing interwall 740 ′ is installed on the coupling irregularities 410 formed on the outer wall to prevent the lower portion of the marine reservoir 670 formed by the impermeable floating sub mat 710. Floating sluice at the proper location of the offshore reservoir 670 formed by blocking the offshore reservoir 670 Wires (760 ') marine floating, characterized in that to install the upright composite tidal power plant 1 300', a marine reservoir 670 and the power generation system utilizing the composition In the marine reservoir 670 using the offshore fixed type stand-alone hybrid tidal power generation facility 2 (260 ") of claim 8 as a preliminary measure for electric power production, By operating the pump 150 installed in the hydrogen gas manufacturing room 50 of the installed offshore fixed type combined-purpose tidal power generation facility 2 (260 "), the seawater is discharged through the water supply pipe 170 and the drain pipe 170 'associated with the pump. When the water level of the sea reservoir 670 is desalted to a predetermined level higher than the sea level until the sea reaches the highest water level 220 in the sea reservoir 670, the water level of the sea reservoir 670 is increased by the difference between the tides of the sea. The water level is repeatedly raised and lowered with the potential energy of each, so that the hydro-generator (760) of the marine reservoir (670) and the hydro-generator (90) and the hydro-power generator of the fixed offshore hybrid tidal power plant (260 ") Power generation system, characterized in that 100 simultaneously generates power in triple In the offshore reservoir 670 using the offshore floating type upright hybrid tidal power generation facility 1 (300 ') as set forth in claim 9, The seawater is operated through the water supply pipe 170 and the drain pipe 170 'associated with the pump by operating the pump 150 installed in the hydrogen gas manufacturing room 50 of the installed offshore floating type upright hybrid tidal power generation facility 1 (300'). When the water level of the sea reservoir 670 is desalted to a predetermined level higher than the sea level until the sea becomes the highest water level 220 in the sea reservoir 670, the water level of the sea reservoir 670 is caused by the difference between the tides of the sea. And the sea level are repeatedly elevated with the potential energy of each other, and the aerodynamic power of the floating hydrological power generation line (760 ') of the offshore reservoir (670) and the hydroelectric generator (90) of the offshore floating vertical tidal power plant (300') Power generation system, characterized in that the generator 100 simultaneously generates power in triple Claims 9 and 9, power generation business, hydrogen fuel remanufacturing, agriculture, fisheries, housing and industry derived from a marine city constructed by installing various offshore facilities 770 accommodated in the marine reservoir 670 The marine city construction project module and marine facilities (770) installed in the marine reservoir (670), characterized in that the operation and management of the maritime floating industry, tourism leisure industry and submarine minerals mining for the complex complex Supplying autogenous energy produced by power generation facilities such as Combined Power Plant 2 (260 "), Offshore Floating Vertical Power Plant (300 '), Fixed Hydro Power Plant (760) or Floating Hydro Power Plant (760'). Power generation system characterized by stirring

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