KR20100108487A - Ocean energy-mix generation-area for marine energy-mix generation equipment - Google Patents

Abstract

PURPOSE: A marine energy-mix generation method using marine energy-mix generation equipment is provided to prevent interference on the tidal flow because the marine energy-mix generation equipment is installed vertically on the sea. CONSTITUTION: A marine energy-mix generation method using marine energy-mix generation equipment is as follows. A pile, a ballaster, lower and upper casings, a platform, a vertical dynamo-room, a hydrogen producing room, and a control room are vertically installed. A tidal power generator and a seawater temperature difference plant are installed inside the platform. An energy-mix power transmitter is installed in the control room. Energy-mix power equipment or energy-mix power generation vessels are connected to each other to construct a marine energy-mix power generation plant.

Description

OCEAN ENERGY-MIX GENERATION-AREA FOR MARINE ENERGY-MIX GENERATION EQUIPMENT}

A fixed upright tidal power plant is installed on the sea, and a floating upright tidal power line is built and installed at an appropriate position and height on a specific sea. The tidal force is used vertically to produce electricity using tidal, aerodynamic and vertical generators. The field of producing electricity by producing large-scale marine energy mix power plant in the center formed by combining and producing hydrogen by using seawater

Inside a fixed offshore upright tidal power plant or offshore floating upright power line that converts tidal tidal energy between high and low tide into electrical energy. It is equipped with wave power, tidal current, sea temperature difference, wind power and solar generator on the outside of the sea and the sea, and the stationary energy mix or floating energy mix power generation line is set up at the proper position and height of the sea to maximize the generation capacity per area. Technology for producing hydrogen at sea with the generated power

Until now, marine energy development technology has installed tidal power in coastal waters and rotates turbines of generators by tidal wave over a certain height to generate electric power, power generation using wave or tidal current, and offshore wind power generation using offshore wind power. The development of seawater temperature differential power generation technology using the temperature difference of seawater was developed arbitrarily or sporadically, and thus the development was delayed or stalled due to problems such as economic efficiency, safety, and environmental environment around the site.

Accordingly, the present invention uses tidal power vertically to smooth the flow of algae to reduce environmental problems and to generate power at the proper location and height of a particular ocean in the five oceans. The installation cost was reduced by installing power generation facilities such as light and combined with the installed and dried power generation facilities to create a mammoth energy mix power generation complex in the center to enable large-scale power generation.

The effect of the present invention is an environmentally friendly offshore power plant that protects marine resources because it is not obstructed by the tidal flow of the ocean upright, and can be installed anywhere in the five oceans in the case of offshore floating, which is beneficial for the development of marine resources and marine energy, and the mammoth marine It is easy to construct an energy mix power plant, which enables large-scale infinite clean power generation, and as a stable offshore structure, it can be equipped with various generators such as wind power, wave power, etc., thus reducing the overlapping investment of installation cost.

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

1 is a pile diagram according to the present invention is attached to the algae generator coupling recess 11 and the algae generator coupling groove 11 'is attached to the outer surface of the concrete or steel pipe pile (10) attached The algae generator combined convex portion 261 of the algae generator 260 is coupled to the algae generator coupler (11 ') and the algae generator combined convex portion (261') by the bolt nut 100 to the algae generator (260) To the pile (10).

Figure 2 is a lower casing diagram according to the present invention, the bottom of the lower casing 20, a plurality of seawater holes 21 and the pile coupling groove 22 on the bottom of the bottom plate and the lower platform coupling groove 23 on the top Is formed and the seawater flows into the seawater port 21, the upper end of the pile 10 is attached to the pile coupling groove 22, and the lower (30) of the lower platform coupling groove 23 of the lower platform coupling grooves uneven ( 31) is mounted and coupled.

3 is an upper and lower platform diagram according to the present invention, the lower view of the lower platform 30 and the imaginary view of the upper platform 120, the lower platform 30, the lower (long) lower casing coupling irregularities 31 The lower platform tidal generator chamber coupling groove 34, the nozzle opening 50 'and the electric valve opening 60' at the upper end thereof, and the lower platform casing coupling groove 32 and the seawater temperature generator pump opening 33 at the upper end thereof. The tidal generator chamber coupling unevenness 71 of the tidal generator box 70 in the lower platform tidal generator chamber coupling groove 34 is formed in the nozzle hole 50 'and the electric valve hole 60', respectively. ) And the electric valve 60 are mounted on the lower platform casing coupling groove 32 to the lower platform coupling unevenness 41 of the platform casing 40 and the seawater temperature generator pump 111 to the seawater temperature generator pump hole 33. do.

The upper platform casing coupling groove 122 is on the lower side of the floating upper platform 400, and the upper platform tidal generator chamber coupling groove 121 is on the inner side, and the upper casing coupling groove 123 and the nozzle hole 50 'are on the upper side. The valve port 60 'and the work tool 470 are formed so that the upper platform casing coupling groove 122 of the platform casing 40 is connected to the upper platform casing coupling groove 122 in the upper platform tidal generator chamber coupling groove 121. Vertical generator chamber upper platform coupling irregularities 76 of the tidal power generation box 180 is the upper casing coupling groove 123, the upper casing coupling irregularities 131 of the upper casing 130 are nozzle holes 50 'and electric valve mechanism The nozzle 50, the electric valve 60, and the work tool door 471 are coupled to the work tool 470 at 60 ′.

4 is a platform casing diagram according to the present invention, the lower platform coupling unevenness 41 at the bottom of the platform casing 40 and the upper platform coupling unevenness 44 are formed at the top of the hexagonal outer center top, middle and bottom of the platform. The wave generator coupling convex and convex portions 43, in which the wave generator coupler 43 'is formed between the connecting concave-convex 42 and the platform concave concave-convex 42, are respectively mounted to the wave generator coupling convex portion 271 of the wave generator 270. And wave generator coupling concave-convex (43) are coupled to the wave generator coupler (43 ') and the wave generator coupling convex (271') with the bolt nut (100) mounted on the outside of the platform casing (40). And the platform connecting member 290 is attached to the platform connecting member concave and convex 42 to form a pile fixed energy mix power generation facility 480, a casing fixed energy mix power generation facility 490, and an offshore floating type. Negative Mix Power Line 500 It is responsible for the.

5 is a tidal generator box according to the present invention, the tidal generator box 70 is composed of a tidal power generator chamber 73 in the center and a tidal generator turbine chamber 74 on both sides, tidal generator room 73 and tidal generator At the center of the wall between the turbine chamber (74), the tidal generator turbine shaft (75) is formed so that the tidal generator turbine shaft (93) is fixed, and the sealing seal material (80) is attached to both sides of the tidal generator shaft (75) and tidal generator The chamber 73 and the tidal turbine turbine 74 are blocked, and the tidal generator room coupling unevenness 71 and the upper platform coupling unevenness 76 are formed at the bottom of the tidal generator room 70 so that the tidal generator coupling unevenness ( 71 is the lower platform tidal generator chamber coupling groove 34 of the lower platform 30 and the upper platform coupling unevenness 76 is mounted to the upper platform tidal generator chamber coupling groove 121, respectively, and tidal generator turbine chamber 74 Auxiliary turbine chamber subsidiary material (72) is mounted at the bottom and at the top The power turbine chamber upper auxiliary material (72 ') is installed to smooth the flow of seawater. The tidal turbine chamber lower auxiliary material (72) and the tidal turbine chamber upper auxiliary material (72') are equipped with a nozzle port (50 ') and an electric valve (60'). ) Is formed so that the nozzle 50 and the electric valve 60 is mounted to control the inflow and outflow of sea water due to the difference between the tidal tide by the electric valve 60.

6 is an aerodynamic generator diagram according to the present invention, the aerodynamic generator box 190 is composed of an aerodynamic generator room 193 in the center and an aeroelectric generator turbine chamber 194 on both sides, and an aerodynamic generator room 193 and aerodynamic generator. At the center of the wall between the turbine chamber 194, an aeroelectric generator turbine shaft hole 195 is formed, the aeroelectric generator turbine shaft 201 is settled and the sealing seal material 80 is attached to both sides of the aerodynamic generator shaft hole 195 The chamber 73 and the aeroelectric generator turbine chamber 194 are blocked, and the aeroelectric generator chamber coupling unevenness 191 and the hydrogen production chamber coupling unevenness 196 are formed at the lower end of the aeroelectric generator chamber 70 so that the aerodynamic generator coupling unevenness is formed. 191 is the upper casing cover of the upper casing cover aeroelectric generator chamber coupling groove 164 and the hydrogen production chamber coupling unevenness 196 is coupled to each of the hydrogen production chamber aeroelectric generator chamber coupling groove 213 and aerodynamic generator An aerodynamic turbine chamber subsidiary material 192 is installed at the bottom of the turbine chamber 194. At the top, aerodynamic turbine chamber upper auxiliary material (192 ') is installed to smooth the flow of air.Aerodynamic turbine chamber upper auxiliary material (192) and aerodynamic turbine chamber upper auxiliary (192') are equipped with nozzle holes (50 ') and electric valve holes ( 60 ') is formed so that the nozzle 50 and the electric valve 60 are mounted, respectively, by the electric valve 60 to control the inflow and outflow of air in accordance with the change of sea water due to the difference between tides.

7 is an upper casing buoyancy body according to the present invention, the upper casing buoyancy body 140, the outer side of the upper side of the nano magnetic rod coupling groove 141 is formed, the nano magnetic rod 150 is mounted and the upper casing buoyancy body 140 ) Is operated up and down inside the upper casing 130 in accordance with the inflow and outflow of sea water due to the difference between the tidal flow introduced from the tidal generator chamber 90, the nano-magnet rod 150 is vertical generator chamber 180 The piston moves inside the nanocoil core 170 mounted therein.

8 is a nozzle 50 as a fitting 1 according to the present invention, a sealing seal member 80 having a nozzle 50, an electric valve 60, and a seal coupling hole 80 ', and a bolt nut 100, which are generally used. ) And the electric valve 60 are mounted to the nozzle port 50 'and the electric valve port 60' of the tidal power generator turbine room 74 and the aeroelectric generator turbine room 194 and controlled by the electric valve 60. Induces the inflow and outflow of seawater and air according to the tidal difference between the tidal generator and the seal coupling member 80 is formed of the tidal generator turbine shaft (75) formed in the center of the wall between the tidal generator chamber 73 and the tidal generator turbine chamber 74 and The tidal generator of the tidal generator 90 in the aeroelectric generator turbine shaft sphere 195 formed in the center of the wall between the aerobic generator chamber 193 and the aerobic generator turbine chamber 194 and the nano magnetic rod 162 of the upper casing cover 160. Mounted on the shaft 91 and the aeroelectric turbine shaft 201 of the aerodynamic generator 200 and the upper casing buoyancy body 140 When the nano magnetic rods 150 are settled, the seal coupling material 80 is mounted on the wall or slab with the bolt nut 100 so that the tidal generator chamber 73, the tidal generator turbine chamber 74, and the aeroelectric generator chamber 193 are installed. And the aeroelectric generator turbine room 194 and the vertical generator room 180 and the upper casing 130 is the main parts that serve to deliver the pressure of sea water and air to each turbine.

9 is a nano magnetic rod according to the present invention, the nano magnet rod 155 is attached to the upper end of the nano magnetic rod 150, the nano magnetic rod 150 is formed on the upper casing buoyancy body 140 nano magnetic rod groove 141 The upper casing buoyancy body 140 moves up and down inside the upper casing 130 by the inflow and outflow of sea water due to the difference between the tidal tides, and is mounted inside the vertical generator chamber 180. In the core 170, the nano-magnet rod 150 is a piston movement to generate an electromotive force in the nano coil core 170, the vertical generator 184 is to produce power.

10 is a vertical generator box according to the present invention is a vertical generator chamber coupling recess 181 is formed at the bottom of the vertical generator box 180, the vertical generator chamber entrance (183) is mounted on the outside and the nano coil core 170 ) Is a core composed of nanocoils 171, the nanocoil core 170 is mounted inside the vertical generator chamber 180 by the nanocoil core fixing material 182, the top of the inflow and outflow of sea water due to the difference between tides The casing buoyancy body 140 moves up and down inside the upper casing 130, and the nanomagnetic rod 150 mounted on the upper casing buoyancy body 140 performs the piston movement inside the nanocoil core 170. The nanomagnet 155 and the nanocoil 171, which are composed of nano-sizes rather than the speed of the change in time, are increased at the speed of nano units to generate high electromotive force in the nanocoil core 170 to produce power. .

11 is an energy mix transmitter diagram according to the present invention, the energy mix transmitter 450 includes the tidal power generator 451, the aerodynamic power generator 452, the vertical power generator 453, and the tidal power generator 454. ), Wave power generator (455), wind power generator (456), solar power generator (457), and seawater temperature differential generator (458). Tidal generator (90), aerodynamic generator (200), vertical generator (184), wind generator (250), tidal current generator (260) mounted on the stationary energy mix generator (490) and offshore floating energy mix generator (500). ), The wave generator 270, and the photovoltaic generator 280 and the seawater temperature differential generator plant 110 is modulated into a certain amount of electricity so as to receive and integrate the power of the energy mix transmitter ( 450) transmits power to the electric power demand source at once.

12 is a tidal generator diagram according to the present invention, the tidal generator shaft 91 outside the tidal generator 90, the tidal generator turbine shaft 93 protrudes outside the tidal generator turbine 92, and the tidal generator 90 and The tidal generator turbine 92 is mounted in the tidal generator chamber 70 and the tidal generator turbine chamber 74, respectively, so that the tidal generator shaft 91 and the tidal generator turbine shaft 93 are mutually coupled to the tidal generator turbine chamber 74. When the tidal generator turbine 92 is rotated according to the control of the electric valve 60, the tidal generator turbine shaft 93 and the tidal generator shaft 91 are simultaneously operated. By rotating the tidal generator 90 generates electric power and is transmitted to the tidal power generator 451 of the energy mix transmitter 450 mounted in the control room 240 so as to be modulated into a certain amount of electricity so that the integrated power can be transmitted. Working as a demand source at mix transmitter (450) Transmission is.

FIG. 13 is an aerodynamic generator diagram according to the present invention, in which an aeroelectric generator shaft 201 outside the aeroelectric generator 200 protrudes an aeroelectric generator turbine shaft 203 outside the aeroelectric generator turbine 202, and a. The aeroelectric generator turbine 202 is mounted in the aeroelectric generator chamber 193 and the aeroelectric generator turbine chamber 194, respectively, and the aeroelectric generator shaft 201 and the aeroelectric generator turbine shaft 203 are coupled to each other so that the aerobic generator turbine room 194 The air pressure generated by the upper casing buoyancy body 140 moving up and down inside the upper casing 130 due to the inflow and outflow of sea water due to the difference between the tidal tide is controlled by the control of the electric valve 60. When the generator turbine 202 is rotated, the aeroelectric generator turbine shaft 203 and the aeroelectric generator shaft 201 rotates at the same time, the aerodynamic generator 200 produces power to the energy mix transmitter 450 mounted in the control room 240 Is transmitted to aerospace generators (452) It is modulated by the stored electricity quantity of constant quality to be integrated transmission powers the demand by transmitting electrical energy mix 450.

14 is a seawater temperature difference plant according to the present invention, the seawater temperature difference plant 110 is mounted inside the platform casing (40) by the seawater temperature generator pump 111 to pull up the seawater with shallow depth and deep seawater As a power generation plant that produces electric power using a temperature difference, the generated power is transmitted to the seawater temperature difference generator 458 of the energy mix transmitter 450 mounted in the control room 240 so as to be integrally transmitted. It is modulated by the amount of electricity and supplied to the customer by the energy mix transmitter 450.

15 is a hydrogen production plant according to the present invention, the hydrogen production plant 220 is supplied with the seawater to the pump 440 mounted to the outside of the hydrogen production chamber 210 fixed energy-mixed power plant 480 and casing fixed type Tidal generator 90, aerodynamic generator 200, vertical generator 184, wind generator 250, tidal current generator 260, wave generator of the energy mix power plant 490 and offshore floating energy mix line 500 270, and the hydrogen produced as a plant for producing hydrogen by purifying the seawater using the power produced in the photovoltaic generator 280 and the seawater temperature differential generator plant 110 is a demand source by the hydrogen carrier ship in liquefied or gaseous state Supplied to.

16 is an upper casing diagram according to the present invention, the lower view is an upper casing 130 and the upper view is an upper casing cover 160, the upper casing 130, the bottom of the upper platform coupling irregularities 131, the upper upper casing cover The coupling groove 132 is formed so that the upper platform coupling recess 131 is the upper casing coupling groove 123 and the upper casing cover coupling groove 132 of the upper platform 120 is the upper casing of the upper casing cover 160. It is coupled to the coupling unevenness 131 inflow of the seawater introduced at the low water level 420 to the high water level 420 "in the tidal power generator turbine chamber 74 of the tidal power generation box 70 and the low water level 420 at the high water level 420". The aerodynamic generator turbine room of the pneumatic generator box 190 acts to drain freshwater seawater and has a built-in upper casing buoyancy body 140 equipped with a nano-magnet rod 150 to generate air pressure in the upper casing 130. 194 and the nano-magnetic rod 150 is a piston movement inside the nanocoil core (170) And by the aerodynamic generator 200 and a vertical generator (184) to produce electric power

An upper casing coupling concave-convex 161 at the lower end of the upper casing cover 160 has a vertical generator chamber coupling groove 163 at the top and an upper casing cover aeroelectric generator chamber coupling groove 164 and a hydrogen production chamber coupling groove 165 at the inner side. Is formed in the upper casing coupling recess 161, the upper casing cover coupling groove 132 of the upper platform 120, the vertical generator chamber coupling groove 163 is the vertical generator chamber coupling recess 181 of the vertical generator box 180 And the upper casing cover aeroelectric generator chamber coupling groove 164 is equipped with aeroelectric generator chamber coupling unevenness 191 of the aeroelectric generator box 190, respectively, and the nano-magnets 162 on the outer side of the upper casing cover 160; The inner side of the work tool 470 and the upper casing cover of the aeroelectric generator compartment 190, the nozzle hole 50 'and the electric valve hole 60' is formed inside the aeroelectric generator chamber coupling groove 164, the nano-magnet 162, the nano-magnetic rod 150 is a working tool gate 471 to the work tool 470 and The nozzle 50 and the electric valve 60 are mounted to the nozzle port 50 'and the electric valve port 60', respectively, and the pump 440, the pump valve 440 ", and the pipe 440 'are upper casing. Pump connector 133 is installed on the upper casing cover 160 as needed to operate the pump 440 and to control the necessary pump valve 440 "to supply seawater inside the upper casing 130 to the tidal generator 90 ) And the aerodynamic generator 200 and the vertical generator 184 to the initialization mode state.

17 is a wind turbine according to the present invention, the wind turbine 250 is composed of a tower 251 supporting the upper portion, a blade 252 for rotating the generator and a rotor hub 253 equipped with a generator and gears, etc. When the tower 251 is mounted in the wind turbine coupling groove 243 at the top of the control room 240 and the blade 252 rotates due to the sea wind, the power is generated by the rotation of the gear and the generator built in the rotor hub 253 to produce power. It is transmitted to the wind power generator 456 of the energy mix transmitter 450 mounted in the 240 to be modulated to a certain amount of electricity so that the integrated transmission can be supplied to the demand source from the energy mix transmitter 450.

18 is a legend diagram according to the present invention, the seabed ground line 410, the low water level 420 and the medium water level 420 'and the high water level 420 "as a pile 10 or the lower part of the bottom of the sea battery line 410 Fix the casing 20 'and fix the anchor fixed energy mix power generation facility 480, the casing fixed energy mix power generation facility 490, and the anchor 430 "of the offshore floating energy mix power generation line 500. By repeating the low water level 420, the medium water level 420 'and the high water level 420 "of the tide to produce power in the tidal generator 90, aerodynamic generator 200 and the vertical generator 184.

FIG. 19 is a view of the winch in accordance with the present invention. The winch 430 and chain 430 ′ and anchor 430 allow the offshore floating energy mix power line 500 to settle at a particular offshore location and height for best power generation. ") To fill the water in all tanks using pumps installed in the offshore floating energy mix power line 500 at low water level 420, and operate the winch to coincide with the rise of the tide to release the chain 430". The offshore floating energy mix power line 500 is carried out until it reaches a high water level (420 ") and anchored at the bottom of the undersea ground line 410 to fix the offshore floating energy mix power line 500 at an optimal height. To optimize power generation.

20 is a pump attached view according to the present invention, the pump 440 is composed of a pipe 440 ′ and a pump valve 440 ″ installed on the upper flat pong 120 and the upper casing cover 160, respectively. And the end of each pipe 440 'is connected to a hydrogen production plant 220 mounted in the bottom of the low water level 420, the upper casing 130, and the hydrogen production chamber 210 in the sea, and the pile fixed energy mix power generation facility. 480 and the tidal generator turbine chamber 74 of the upper casing 130 and the tidal generator box 180 and the lower casing 20 as preparations for initializing power generation of the casing fixed energy mix power generation equipment 490. Alternatively, the pump 440 is operated to fill the lower casing 20 'with water, and the pump valve 440 " When land drying of 500) is completed, fill the ballast 370 with water Used for launching the injected energy mix line 500, and the preparation of the hydrogen produced in each generator power plant and power generation of the line and serves to supply the water to the hydrogen production plant 220.

21 is a tidal current generator diagram according to the present invention, a tidal current generator 260 is mounted on the front of the tidal current generator turbine 263 and protects the turbine protection net 262 and the tidal current generator 260 on the side of the tidal current generator 260 The algae generator combined convex portion 261 formed with the 461 'is attached, so that the algae generator 260 is combined with the algae generator combined convex and concave convex portion 11 of the pile 10 or the lower casing 20'. The algae, which is the flow of tidal current, is transmitted to the algae generator 260 by the algae generator 260 by assembling and mounting the bolt nut 100 into the ore 461 'and the algae generator combining port 11'. The produced and produced power is transmitted to the tidal current power generator 454 of the energy mix transmitter 450 mounted in the control room 240 and modulated into an electric quantity of a certain quality so that the integrated power can be transmitted to the energy mix transmitter 450. Is supplied to the demand source.

22 is a photovoltaic generator diagram according to the present invention, the photovoltaic generator 280 is a photovoltaic coupling combination of the photovoltaic plate 282 having a photovoltaic plate 283 at the front and a photovoltaic coupler 281 'mounted at the rear thereof. It is composed of (281) to fix the solar coupling concave and convex (281) to the slab (284) of the structure and the solar tube generator coupling hole (281 ') of the solar coupling concave-convex (281) and the slab bolt nut (100) Assemble and produce electric power from the solar energy absorbed by the solar collector plate 283, and transmits to the photovoltaic power generator 457 of the energy mix transmitter 450 mounted in the control room 240 to be uniformly transmitted It is modulated by the amount of electricity of and supplied from the energy mix transmitter 450 to the demand source.

23 is a wave generator diagram according to the present invention, the wave generator 270 is composed of a wave generator casing 272 and a wave power generating chamber 273, the wave generator coupling iron portion 271 formed with a wave generator coupling iron fittings (271 '). ) Is mounted on the wave generator casing 272, and the wave generator coupling convex portion 271 and the wave generator coupling concave-convex 43 of the platform casing 40 are coupled to the wave generator coupling convex portion 271 of the wave generator coupling convex portion 271. ') And the wave generator coupler (43 ") is assembled by mounting the bolt nut 100 to the platform casing 40, the wave force of the waves derived from the sea wave generator in the wave generator casing 272 (273) The power is transmitted to the wave power generator 455 of the energy mix transmitter 450 mounted in the control room 240 to produce power, and is modulated into an electric quantity of a certain quality so that the integrated power can be transmitted. Is supplied to the demand source

24 is a hydrogen production chamber diagram according to the present invention, the lower view of the hydrogen production chamber 210 and the upper portion of the hydrogen production chamber cover 230 to the hydrogen production chamber 210 at the bottom of the hydrogen production chamber combined unevenness 211 top The hydrogen production chamber cover coupling groove 212 is formed in the door 460 and the window 461 is formed on the outside of the wall, the hydrogen production chamber coupling irregularities 211 hydrogen production chamber coupling of the upper casing cover 160 The groove 165 and the hydrogen production chamber coupling groove 212 is coupled to the hydrogen production chamber cover coupling irregularities 231 and

Hydrogen production chamber cover 230 The lower outer side of the hydrogen production chamber cover coupling irregularities 231, the hydrogen production chamber aeroelectric generator chamber coupling groove 213 is the upper control room coupling groove 232 and the hydrogen production chamber aeroelectric generator chamber coupling The nozzle hole 50 'and the electric valve hole 60' are formed in the groove 213, and the hydrogen production chamber coupling groove 121 is connected to the hydrogen production chamber aerogen generator chamber in the hydrogen production chamber cover coupling recess 231. The groove 213 is equipped with a hydrogen production chamber coupling unevenness 196 of the aeroelectric generator box 190, and a nozzle 50 and an electric valve 60 are respectively installed in the nozzle port 50 'and the electric valve port 60'. The aerosol generator box 190 and the aerosol generator 200 are mounted in the center of the hydrogen production chamber 210, and the hydrogen production plant 220 is mounted outside the aerosol generator box 190, and the upper casing (the aerodynamic generator 200) is mounted on the aerosol generator 200. 130) produces electricity by the air pressure generated inside the pump 440, the pump valve 440 'and the top of the upper casing 130 Is (440 ") is connected to the hydrogen-producing chamber pump connector (214) to purify the water to produce hydrogen in a hydrogen production plant 220.

25 is a diagram illustrating a control room according to the present invention. A door 460 and a window 461 are attached to the outside, so that the wind turbine 250 is connected to the control chamber coupling recess 241 to the control chamber coupling groove 232 of the hydrogen production chamber cover 230 and the wind turbine coupling groove 243. Tower 251 is mounted and the energy mix transmitter 450 is installed in the control room 240, tidal generator 90, aerodynamic generator 200, vertical generator 184, wind generator 250, tidal current generator 260, wave generator 270, and photovoltaic generator 280 and the seawater temperature generator plant 110 to integrate the power and modulate the amount of electricity of constant quality supplied from the energy mix transmitter 450 to the demand source Manage the role.

FIG. 26 is a schematic view of a part of an energy mix complex according to the present invention. ) Is the platform of the pile fixed energy mix power generation facility (480), the casing fixed energy mix power generation facility and the floating energy mix power generation line (500) in order to obtain synergy effect of the marine energy when it is settled at its position according to the sea condition. Each platform casing 40 or the floating platform casing 390 by attaching the platform connecting member 290 to the platform connecting member uneven 42 attached to the casing 40 and the floating platform casing 390 on the upper, middle, and lower ends of the casing 40 and the floating platform casing 390. By blocking the liver to block the inflow and digging of the seawater to protect the marine energy mix complex 510 and the lower end between the platform of each platform casing 40 and floating platform casing 390 Attach the platform connection bottom plate 300 to block the flow of tides, the chain 430 'and the anchor 430 "is combined in the center of the marine energy mix complex 510 and the energy mix complex buoyancy body 310 energy mix The energy mix bottom lower plate 1 320 mounted on the buoyancy body coupling groove 321 is settled, and a chain and an anchor are coupled around the energy mix complex buoyancy body 310 to the energy mix complex buoyancy coupling groove 321. Attached to the installed energy mix bottom second plate 320 'and the energy mix bottom third plate 320 " in turn, the platform casing 40 and floating platform casing attached to the edge of the marine energy mix just 510 Attached to the platform connection lower plate 300 of 390 to cut off the lower end of the marine energy mix complex 510 from the sea water to the energy mix bottom 1 plate 320 and the energy mix bottom 2 plates 320 'and energy Nozzle port 50 'formed on the mix base lower plate 3 " The lower end of the marine energy mix complex 510 is controlled through the sphere 60 'and the inflow and outflow of sea water is controlled. The valve opening 60 'blocks the flow of seawater completely.

Energy mix complex inner pillar 360 at the bottom of the energy mix complex bottom plate 1 320, the energy mix complex bottom 2nd plate 320 'and the energy mix complex bottom 3 plate 320 " Attached to the energy mix complex upper plate 1 330 from the center of the marine energy mix development complex 510, and the energy mix complex upper plate 2 (330 ') and energy Attach the upper part of the mixing stage 3 plates 330 "and energize the upper casing connection upper 2 plates 350 'on top of the energy mix stage 2 plates 330' and the platform casing 40 or the floating platform casing 390. Attach the upper casing upper plate 1 350 to the top of the mix stage upper plate 3 (330 ") and the platform casing (40) or floating platform casing (390) to connect the platform casing (40) or floating platform casing (390). Attaching the upper casing connecting member 340 between the upper end of the mammoth offshore energy mix The complex 510 can be formed to form a wide area of grassland to produce enormous power.

27 is a lower casing diagram according to the present invention, a plurality of seawater holes 21 and lower platform coupling grooves 23 are formed at the lower end of the lower body casing 20 'to form seawater holes 21. The inflow and outflow is caused by the difference between the tide and the lower platform coupling groove 23, the end (long) bottom casing coupling concave (31) of the lower platform 30 is coupled.

28 is a ballast diagram according to the present invention, a tidal current generator coupling recess 11 having a tidal current generator coupling hole 11 'is attached to the bottom of the ballast 370, and a floating lower casing groove 371 and an outer side of the upper portion are provided. The ballast concave-convex 372 is formed in the work tool 470 and the ballast pump port 373 is formed in the center side, so that the pipe 440 "of the pump 440 is provided in the ballast pump port 373 by the work tool 470. (4) is mounted on the work tool gate (471) and the lower casing groove (371) is coupled to the ballast coupling recess (24) to operate the pump 440 installed on the floating platform casing (390). Fill the ballast 370 from the outside through the outside and repair or repair through the work tool 470 if necessary, floating energy according to the filling state of the ballast 370 and the fixed state of the anchor 430 " It plays an important role in influencing power generation efficiency at the proper position of the mix line. When the 500 is settled at sea, the algae generator coupling convex 11 is coupled to the algae generator convex portion 261 of the algae generator 260 to the algae generator coupling hole 11 'and the algae generator convex hole 261'. Assemble and install with bolt nut (100).

Figure 29 is a top, bottom floating platform in accordance with the present invention, the bottom is a floating lower platform 380 and the top is a floating upper platform 400, the floating bottom platform 380 is a floating bottom platform at the bottom. Floating lower platform tidal generator chamber coupling groove 383, nozzle opening 50 'and electric valve opening 60' are formed at the upper center of the lower casing coupling groove 381, and the floating lower platform is provided at the upper end. The casing coupling groove 382 and the ballast pump hole 373 are formed so that the auxiliary generator chamber coupling unevenness 71 of the tidal generator box 70 is located in the floating lower platform tidal generator chamber coupling groove 383. (50 ') and the electric valve (60'), the nozzle 50 and the electric valve (60), respectively, the lower platform coupling unevenness of the floating platform casing 390 in the floating lower platform casing coupling groove (382) 41 and the ballast pump port 373 is equipped with a pump 440 and a pipe 440 ".

Floating upper platform 400 Bottom outer floating upper platform casing coupling groove 401 inside the floating upper platform tidal generator chamber coupling groove 402 on the upper upper casing coupling groove 123 and the nozzle port 50 ') And the electric valve port 60' and the working tool 470 are formed, the upper platform coupling unevenness 44 of the floating platform casing 390 is floating floating upper platform casing coupling groove 401 The platform tidal generator chamber coupling groove 401 has a tidal generator chamber upper platform coupling recessed and uneven 76 of the tidal generator box 180, and the upper casing coupling groove 123 has an upper casing coupling recess 131 of the upper casing 130. The nozzle opening 50 'and the electric valve opening 60' are equipped with a nozzle 50, an electric valve 60, and a work opening waterproof door 471 at the work opening 470, and a winch 430 at each upper corner. Install.

30 is a floating platform casing diagram according to the present invention, the lower platform coupling unevenness 41 at the bottom of the floating platform casing 390 and the upper platform coupling unevenness 44 are formed at the top and the floating platform casing 390. ) Wave power generator coupling recesses (43) having wave generator coupling holes (43 ') formed between the platform connection recesses (42) and the platform connector recesses (42) at the top, the middle, and the bottom of the wave generator (270), respectively. Floating platform casing by assembling the wave generator coupling convex portion 271 and the wave generator coupling concave-convex (42) into the wave generator coupling sphere (43 ') and the wave generator coupling iron buckle (271') by bolt nut (100). The wave generator 270 is mounted on the 390 and the platform connecting member 290 is attached to the platform connecting member concave and convex 42 to form the pile fixed energy mix generating equipment 480 or the casing stationary energy when the offshore energy mix generating complex 510 is formed. Coupling with the mix power generation equipment (490) It is to play a role.

FIG. 31 is a pile assembly diagram of a pile fixed energy-mix power generation assembly according to the present invention, in which a pile 10 having a tidal current generator coupling unevenness 11 is attached to the bottom of a subsea ground line 410.

32 is a pile fixed energy-mix power generation assembly 2 according to the present invention, the pile coupling groove 22 formed at the upper end of the pile 10 fixed to the bottom of the seabed ground line 410 and the lower end casing 20. The assembly of the pile 10 and the lower casing 20 is fitted to match.

Figure 33 is a pile fixed energy-mix power generation assembly 3 according to the present invention, the lower platform coupling groove 23 formed on the upper end of the lower casing 20 and the lower (long) lower casing coupling unevenness formed on the lower side of the lower platform 30. The lower casing 20 and the lower platform 30 is assembled to be combined so that 31 is consistent.

FIG. 34 is a view illustrating the assembly of a pile fixed energy mix power generation system according to the present invention, in which the nozzle 50 and the electric valve 60 are provided at the central nozzle port 50 'and the electric valve port 60' of the lower platform 30. As shown in FIG. The lower platform 30 and the platform casing 40 are mounted so that the lower platform casing coupling groove 32 formed on the upper surface of the lower platform 30 and the lower platform coupling recess 41 formed on the bottom of the platform casing 40 coincide with each other. In the platform casing 40 so that the lower platform tidal generator chamber coupling groove 34 formed in the center of the lower platform 30 and the tidal generator chamber coupling unevenness 71 formed at the bottom of the tidal generator box 70 coincide with each other. Tidal generator box 70 is coupled to the tidal generator chamber 70 inside the tidal generator chamber 73 and the tidal generator turbine chamber 73 on both sides of the assembly diagram is formed.

35 is a pile fixed energy mix power plant assembly 5 in accordance with the present invention, the tidal turbine chamber lower auxiliary material 72 is mounted on both bottoms of the tidal generator turbine chamber 74 of the tidal power generator 70 and the tidal generator 90 It is an assembly diagram in which the tidal generator 90 is mounted in the tidal generator chamber 73 by attaching a sealing seal material 80 to the tidal generator shaft 91.

Fig. 36 shows the assembly of the pile fixed energy mix power generation system according to the present invention with the sealing seal material 80 mounted on the tidal generator turbine shaft 93 and the tidal generator turbine chamber 74 mounted on the tidal generator turbine shaft. The tidal generator turbine shaft (93) is coupled to the tidal generator shaft (91) via the tidal generator turbine shaft (75) of the tidal generator box (70) and mounted on the tidal generator shaft (91) and the tidal generator turbine shaft (93). The assembled seal material 80 is attached to the tidal generator turbine shaft sphere (75) is assembled by coupling with a bolt nut (100).

Figure 37 is a pile fixed energy-mix power generation equipment assembly according to the present invention as shown in Figure 7 is installed on the outside of the platform casing seawater temperature differential power generation plant 110, the seawater temperature difference generator pump hole 33 formed on the lower platform (30) Seawater temperature difference generator pump 111 is installed on the upper side of the tidal generator turbine chamber 74 is an assembly diagram of the upper auxiliary material 72 'in the tidal turbine chamber.

38 is an 8-pile fixed energy-mix power generation assembly according to the present invention, the upper platform casing coupling groove 44 formed on the upper surface of the platform casing 40 and the upper platform casing coupling groove 122 formed on the lower surface of the upper platform 120. In addition, the upper platform tidal generator chamber coupling groove 121 formed at the bottom of the tidal generator chamber upper platform coupling irregularities 76 and the upper platform 120 formed at the top of the tidal power generation box 70 and the upper platform 120 The nozzle 50 and the electric valve 60 are attached to the nozzle port 50 'and the electric valve port 60' formed at the top.

Figure 39 is a pile fixed energy-mix power generation assembly 9 according to the present invention, the upper casing coupling groove 123 formed on the upper platform 120 and the upper platform coupling recess 131 formed on the lower end of the upper casing 130 coincide. The upper platform 120 and the upper casing 130 so as to combine and install the upper casing buoyancy body 140 in the upper casing 130 as possible.

40 is a pile fixed energy-mix power generation assembly 10 according to the present invention, the nano-magnetic rod 150 in the nano-magnetic rod coupling groove 141 formed on the upper casing buoyancy body 140 mounted inside the upper casing 130 The upper casing 130 and the upper casing cover 160 so that the upper casing cover coupling groove 132 formed on the upper casing 130 and the upper casing coupling concave-convex 161 formed on the lower end of the upper casing cover coincide with each other. By attaching and attaching a sealing seal material 80 to the upper casing cover 160, the nano magnetic rod 162 bottom bolt to the nano magnetic rod 150 protruding from the nano magnetic rod 162 formed on the upper casing cover 160 bolts The nozzle 100 is mounted to the nut 100 and the nozzle 50 is formed on the upper casing cover 160 and the electric valve 60 (60), respectively.

FIG. 41 is an assembly diagram of a pile fixed energy mix power generation system according to the present invention. The upper casing aeroelectric generator chamber coupling groove 164 formed in the upper center of the upper casing cover 160 and the aeroelectric generator formed at the bottom of the aeroelectric generator box 190 are shown in FIG. Both sides of the aeroelectric generator chamber 193 and the aerobic generator chamber 193 are mounted on the upper casing cover 160 and the aeroelectric generator box 190 so as to match the actual coupling unevenness 191. An aeroelectric generator turbine chamber 194 is formed in the upper casing cover 160, nano coil rods protruding to the outer side of the nano magnetic rods 162 formed on the outer sides of the upper, middle, and bottom of the nano coil core fixing material ( 182) is an assembly diagram installed nanocoil core 170 is installed.

42 is a view illustrating the assembly of a pile fixed energy mix power generation system according to the present invention, in which the vertical generator chamber coupling grooves 163 and the vertical generator chamber coupling recesses of the vertical generator box 180 are formed at upper and outer sides of the upper casing cover 160. 181, the upper casing 160 and the vertical generator box 180 is combined and mounted, and the aerodynamic turbine chamber lower auxiliary material 192 is mounted on the lower portion of the aerobic generator turbine chamber 194 of the aerodynamic generator box 190 and the aeroelectric generator It is an assembly diagram which attached the aeroelectric generator 200 which attached the sealing seal material 80 to the shaft 201 to the aeroelectric generator chamber 193. As shown in FIG.

FIG. 43 is an assembly diagram of a pile fixed energy mix power generation system according to the present invention. FIG. 43 is a sealing seal material 80 mounted on an aeroelectric generator turbine shaft 203 to be mounted in an aeroelectric generator turbine chamber 194. The aero generator turbine shaft 203 is coupled to the aero generator shaft 201 through the aero generator turbine shaft opening 195 of the aero generator generator 190 and mounted on the aero generator shaft 201 and the aero generator turbine shaft 203. Attaching the sealed sealing material 80 to the aero generator turbine shaft hole 195 and coupling and mounting it with the bolt nut 100, and installs the upper auxiliary material 192 'on the aero turbine generator chamber 194 and the upper casing The upper casing cover 160 and the hydrogen production chamber 210 so that the hydrogen production chamber coupling groove 165 formed at the top of the cover 160 and the hydrogen production chamber coupling recess 211 formed at the bottom of the hydrogen production chamber 210 coincide with each other. It is an assembly diagram fitted with a combination.

44 is a 14-pile fixed energy mix power plant assembly according to the present invention, the hydrogen production plant 220 is installed on the outside of the hydrogen production chamber 210 and the hydrogen production chamber coupling irregularities formed on the top of the aeroelectric generator box 190 ( 196 and the hydrogen generator chamber coupling groove 233 formed at the bottom of the hydrogen production chamber cover 230 and the hydrogen production chamber cover cover coupling groove 212 and the hydrogen production chamber cover (2) formed at the top of the hydrogen production chamber 210 ( 230, the aeroelectric generator box 190 and the hydrogen production chamber 210 and the hydrogen production chamber 210 and the hydrogen production chamber cover 230 to match the hydrogen production chamber cover coupling concave-convex (231) formed at the bottom is mounted It is an assembly road.

FIG. 45 is a fifteen-figure fixed energy mix power plant assembly 15 according to the present invention, wherein the nozzle 50 and the electric valve 60 'formed in the hydrogen production chamber cover 230 are connected to the nozzle 50 and the electric valve 60. FIG. ), Respectively, and install the energy mix transmitter 450 on the upper outer side of the hydrogen production chamber cover 230 and the control chamber coupling groove 232 and the control chamber 240 formed at the upper end of the hydrogen production chamber cover 230. The hydrogen production chamber cover 230 and the control chamber 240 are assembled to be mounted so that the control chamber coupling concavities and convexities 241 are formed.

FIG. 46 is an assembly diagram in which the tower 251 of the wind turbine 250 is coupled to the wind turbine coupling groove 243 formed at the top of the control room 240 as an assembly of the pile fixed energy mix generator according to the present invention.

FIG. 47 illustrates the assembly of a fixed energy-mixed power generation facility according to the present invention as shown in FIG. 17. The algae generator coupling recess 11 attached to the pile 10 and the algae generator coupling section 261 attached to the algae generator 260 are combined. And assembled with a bolt nut (100) in the tide generator coupler (11 ") formed in the tide generator coupler (11) and the tide generator coupler (261 ') formed in the tide generator coupler (261). On the algae generator 260 is mounted.

FIG. 48 is a diagram illustrating the assembly of a pile-type energy-mixing power generation facility according to the present invention, wherein the wave generator coupling concave-convex 43 attached to the side of the platform casing 40 and the wave generator coupling convex portion 271 attached to the wave generator 270 are provided. Coupled to the wave generator coupler (43 ') and wave generator coupler 271 formed in the wave generator coupling concave-convex (43) and assembled with a bolt nut (100) to the casing platform ( 40 is an assembly diagram in which the wave generator 270 is mounted.

FIG. 49 is an assembly diagram of a pile fixed energy mix power generation system according to the present invention, in which a pump 440, a pump valve 440 ′, and a pipe 440 ″ are formed at an upper end of an upper casing 130. The pump valve 440 is connected to the upper casing 130 through the upper casing pump connector 133 and connected to the pipe 440 ″ to the pump 440 installed on the upper platform 120. ') Is installed and the pipe 440' is assembled to the hydrogen production plant 220 through the hydrogen production chamber pump connector 214 formed in the hydrogen production chamber 210.

FIG. 50 is a view illustrating the assembly of a fixed-type energy-mix power generation unit 20 according to the present invention. Assembling the photovoltaic generator 280 in the vertical power box 180 and the control room 240 by assembling the bolt nut 100 to the photovoltaic coupler 281 ′, and the upper platform 120 and the upper casing. The work tool 470 is formed on the outside of the cover 160 so that the work tool door 471 is mounted and the door 460 is mounted on the vertical power generation box 180 and the door to the hydrogen production room 210 and the control room 240. 460 and window 461 are assembled.

51 is a pile upright tidal tidal power generation system according to the present invention as shown in Fig. 1 from the bottom of the pile 10, the lower casing 20, the platform casing 40, the tidal generator 90 is installed, the upper casing buoyancy body 140 Also shown is a pile upright type tidal power generation facility (481) consisting of an upper casing (130), a vertical generator (184), and a hydrogen production chamber (210) in which aerodynamic generator (200) is installed.

Figure 52 is a pile upright tidal tidal power generation system 2 according to the present invention when the low water level 420 tidal power generation box 180 mounted on the top and bottom of the electric valve 60 and the pump 440 installed on the upper platform 120 And the pump valve 440 'and open the seawater to the low water level 420 line of the lower casing 20 through the pipe 440 "and the tidal generator turbine chamber 74 of the tidal generator box 70. Complete generation of power generation facilities.

Figure 53 is a pile fixed upright tidal power generation system according to the present invention, the left tidal power generation of the pump 440 and pump valve 440 'and tidal power generation box 70 installed on the upper platform 120 at low water level 420 The preparation of tidal power generation for power generation is completed by closing the electric valve 60 mounted at the bottom of the turbine chamber 74 and the electric valve 60 mounted at the bottom of the left aeroelectric turbine room 194 of the aerospace generator 190. do.

54 is a pile upright tidal tidal power generation system according to the present invention. FIG. 54 shows the right tidal turbine room 74 of the tidal power generation tank 70 with the flow of seawater rising as the water level is changed from the low water level 420 to the medium water level 420 '. The upper casing buoyancy is rotated through the nozzle 50 mounted on the lower side and passed through the upper casing 130 through the electric valve 60 mounted on the upper side. When the sieve 140 rises, the nano magnetic rod 150 attached with the nano magnet 151 mounted on the upper casing buoyancy body 140 rises inside the nanocoil coil 170 and moves inside the upper casing 130. The trapped air rotates the aeroelectric generator turbine 202 through the nozzle 50 mounted on the lower side of the aeroelectric generator turbine chamber 194 of the aerodynamic generator box 190, and the upper side of the control chamber 240 through the electric valve 60. While exhausted to the outside through the formed aerodynamic generator ring mechanism (242) Power generator 90 and a vertical generator (184) and is producing power in the aerodynamic generators (200).

55 is a pile upright tidal tidal power generation system in accordance with the present invention, and the seawater is mounted at the bottom of the right tidal turbine chamber 74 of the tidal power generator 70 until the high water level 420 "is reached. Rotating the tidal generator turbine 92 through the upper casing 130 through the electric valve 60 mounted on the upper casing, the upper casing buoyancy body 140 is built in the upper casing 130, the upper casing The nano magnetic rod 150 attached to the upper side of the buoyancy body 140 is attached to the nano magnetic coil 150 rises inside the nano-coil 170 and the air trapped inside the upper casing 130 is aerodynamic power generation (190) The aeroelectric generator turbine 202 is rotated through the nozzle 50 mounted to the lower side of the aeroelectric generator turbine chamber 194 and the aerodynamic generator return mechanism 242 formed at the top of the control chamber 240 through the electric valve 60. The tidal generator 90 and the vertical generator 184 while being exhausted to the outside And it will continue to produce power in the aerodynamic generators (200).

56 is a pile upright tidal tidal power generation system in accordance with the present invention. When the high water level 420 "peaks, the aerodynamic valve 60 and the aerodynamic valve 60 installed on the upper side of the right tidal turbine turbine 74 of the tidal power generator 70 are aerodynamic. Close the electric valve 60 installed on the upper side of the right aeroelectric generator turbine chamber 194 of the generator box 190 and the electric valve 60 and aeroelectric generator installed on the upper side of the left tidal generator turbine chamber 74 of the tidal generator box 70. Opening the electric valve 60 installed on the upper side of the left aerospace generator turbine chamber 194 of the box 190, the flow of sea water is lowered, the upper casing buoyancy body 140 built in the upper casing 130 is lowered and the nano-magnet ( 151 is attached and the nano-magnet rod 150 mounted on the upper casing buoyancy body 140 is lowered inside the nanocoil coil 170 to generate an electromotive force on the nanocoacoil 170 of the vertical generator 184 to vertical The generator 184 produces power and the outside air is supplied to the aerodynamic generator ring mechanism of the control room 240. Suction into the nozzle 50 installed on the top of the aeroelectric generator box 190 through the 242 to rotate the aeroelectric generator turbine 202 installed in the aerobic generator turbine room 194 of the aerobic generator box 190 and the upper casing 130 Air flows into the aeroelectric generator 200 to produce power) and the seawater is generated through the nozzle 50 installed on the upper right side of the tidal power generator 70, the right tidal turbine turbine 194 The tidal generator turbine 92 is rotated and passed through the electric valve 60 to the lower casing 20 to produce power from the tidal generator 90.

57 is a pile upright tidal tidal power generation system in accordance with the present invention. When the water level is changed from the high water level 420 "to the medium water level 420 ', the flow of seawater is continuously lowered, and the upper casing buoyancy body embedded in the upper casing 130 is shown. As the 140 descends, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nano core coil 170 so that the nano core coil of the vertical generator 184 is lowered. The electromotive force is generated in the 170 so that the vertical generator 184 continuously produces electric power and the outside air is installed on the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240. As the aerodynamic generator turbine 202 is rotated and installed in the aerobic generator turbine room 194 of the aerodynamic generator box 190 and air is introduced into the upper casing 130, the aeroelectric generator 200 continues to produce power. The seawater is in the upper right corner of the tidal power generator (70). The tidal power generator (70) rotates the tidal generator turbine (92) of the right tidal turbine (194) through the installed nozzle (50) and passes through the electric valve (60) to the lower casing (20). 90 continue to produce power.

58 is a pile upright tidal tidal power generation system in accordance with the present invention. As the 140 descends, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nano core coil 170 so that the nano core coil of the vertical generator 184 ( The electromotive force is generated in 170 so that the vertical generator 184 continuously generates power, and the outside air is supplied to the nozzle 50 installed on the top of the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240. Suction rotates the aeroelectric turbine 202 installed in the aerobic generator turbine room 194 of the aerobic generator box 190 and air flows into the upper casing 130, the aerodynamic generator 200 continues to produce power and sea water Is on the upper right of the tidal generator 70 Tidal power generator (70) rotates the tidal generator turbine 92 of the right tidal turbine chamber 194 through the nozzle (50) and passes through the electric valve 60 to the lower casing 20, the tidal generator The power is continuously produced at 90 and the process of FIGS. 51 to 58 is changed four times a day due to the difference between tides and tidal generators 90, vertical generators 184, and aerodynamic generators 200. This is a pile upright tidal power generation system that produces electricity.

59 is a pile fixed seawater temperature differential power generation system according to the present invention, the right seawater temperature generator pump 111 installed inside the platform casing 40 is provided with a pipe 440 ″ in the deep sea and the left seawater temperature generator pump 111 is disposed. Is a power generation system diagram for an offshore temperature generator plant 110 that produces power by using a temperature difference between a deep sea and an offshore portion where a pipe 440 ″ is installed.

60 is a pile fixed hydrogen production system according to the present invention, a pump 440 installed on an upper platform 120 and a pipe 440 ″ installed on an ocean floor in a hydrogen production plant 220 installed inside a hydrogen production chamber 220. Is connected to the hydrogen production plant 220 through the pump valve 440 'installed on the upper casing cover 160 and the hydrogen production chamber pump connector 214 formed in the hydrogen control chamber 220, and the upper casing cover 160 is upper part. Opening the pump valve 440 ′ installed in the hydrogen production plant 220 to supply seawater is a system diagram for producing hydrogen by purifying the seawater in the hydrogen production plant 220.

61 is an assembly diagram of the casing fixed energy mix power generation assembly according to the present invention, in which the lower casing 20 'is mounted on the bottom surface of the subsea ground line 410.

62 is a casing-fixed energy-mix power generation assembly 2 according to the present invention, the lower platform coupling formed on the upper part of the lower casing 20 'and the lower casing 20' fixed to the bottom of the submarine ground line 410. It is an assembly diagram in which the lower casing 20 'and the lower platform 30 are coupled to each other so as to coincide with the end (long) lower coupling recesses 31 formed at the lower end of the groove 23 and the lower platform 30.

FIG. 63 shows the casing fixed energy mix power generation assembly 3 according to the present invention. The nozzle 50 and the electric valve 60 are respectively formed at the center nozzle port 50 'and the electric valve port 60' of the lower platform 30. FIG. Each of the lower platform 30 and the platform casing 40 so that the lower platform casing coupling grooves 32 formed on the upper platform 30 and the lower platform coupling recesses 41 formed on the bottom of the platform casing 40 coincide with each other. In the platform casing 40 so that the coupling and the lower platform tidal generator chamber coupling groove 34 formed in the center of the lower platform 30 and the tidal generator chamber coupling unevenness 71 formed at the bottom of the tidal generator box 70 coincide with each other. The tidal generator box (70) is coupled to the tidal generator chamber (73) and the tidal generator turbine chamber (73) on both sides of the tidal generator chamber (70) is assembled.

64 is a casing stationary energy mix power generation assembly 4 according to the present invention, the tidal turbine chamber lower auxiliary material 72 is mounted on both bottoms of the tidal generator turbine chamber 74 of the tidal power generator 70 and the tidal generator 90 is shown in FIG. It is an assembly diagram in which the tidal generator 90 is mounted in the tidal generator chamber 73 by attaching a sealing seal material 80 to the tidal generator shaft 91.

Fig. 65 is a casing fixed energy mix power plant assembly 5 according to the present invention, with the sealing seal material 80 mounted on the tidal generator turbine shaft 93, mounted on the tidal generator turbine chamber 74, and of the tidal generator turbine 92; The tidal generator turbine shaft 93 is coupled to the tidal generator shaft 91 through the tidal generator turbine shaft 75 of the tidal generator box 70 to the tidal generator shaft 91 and the tidal generator turbine shaft 93. Attached to the tidal generator turbine shaft hole 75 is attached to the sealing seal material (80) is assembled to install the auxiliary turbine chamber upper auxiliary material (72 ') in the coupling mounting with the bolt nut (100).

FIG. 66 is a casing fixed energy mix power generation assembly 6 according to the present invention, wherein the seawater temperature difference generator plant 110 is installed on the inside and outside of the platform casing 40, and the seawater temperature difference generator pump hole 33 formed on the lower platform 30 is shown. Seawater temperature difference generator pump 111 is installed on the upper side of the tidal generator turbine chamber 74 is an assembly diagram of the upper auxiliary material 72 'in the tidal turbine chamber.

Figure 67 is a casing fixed energy mix power generation assembly 7 in accordance with the present invention, the upper platform coupling grooves 44 and upper platform casing coupling grooves 122 formed on the upper platform 120 formed on the top of the platform casing 40 and Tidal generator chamber formed on the top of the tidal generator chamber upper platform coupling unevenness 76 and the upper platform tidal generator chamber coupling groove 121 formed at the bottom of the upper platform 120 is coupled to match the upper platform 120 It is an assembly drawing which attached the nozzle 50 and the electric valve 60 to the nozzle opening 50 'and the electric valve opening 60' formed in the upper end, respectively.

Figure 68 is a casing fixed energy mix power generation assembly 8 according to the present invention, the upper casing coupling groove 123 formed on the upper platform 120, the upper platform coupling recess 131 formed on the lower end of the upper casing 130 coincides. The upper platform 120 and the upper casing 130 so as to combine and install the upper casing buoyancy body 140 in the upper casing 130 as possible.

FIG. 69 shows the assembly of a casing fixed energy mix power generation system according to the present invention. FIG. 69 shows a nano magnetic rod 150 in a nano magnetic rod coupling groove 141 formed on an upper casing buoyancy body 140 mounted inside an upper casing 130. The upper casing 130 and the upper casing cover 160 so that the upper casing cover coupling groove 132 formed on the upper casing 130 and the upper casing coupling concave-convex 161 formed on the lower end of the upper casing cover coincide with each other. By attaching and attaching a sealing seal material 80 to the upper casing cover 160, the nano magnetic rod 162 bottom bolt to the nano magnetic rod 150 protruding from the nano magnetic rod 162 formed on the upper casing cover 160 bolts The nozzle 100 is mounted to the nut 100 and the nozzle 50 is formed on the upper casing cover 160 and the electric valve 60 (60), respectively.

70 is a casing fixed energy mix power generation assembly 10 according to the present invention, the upper casing aerodynamic generator chamber coupling groove 164 formed in the upper center of the upper casing cover 160 and the aeroelectric generator chamber formed at the bottom of the aerodynamic generator box 190 The upper casing cover 160 and the aeroelectric generator box 190 are coupled to each other so as to match the unevenness of the coupling 191 to both sides of the aerodynamic generator room 193 and the aerobic generator room 193 in the center of the aerodynamic generator box 190. An aeroelectric generator turbine room 194 is formed and the upper, middle, and bottom of the nano-coil fixing material 182 on the outside of the nano-magnetic rod 150 protruding to the nano-magnetic rod 162 formed on the outer side of the upper casing cover 160. ) Is an assembly diagram installed nano coil core 170 is installed.

FIG. 71 illustrates the assembly of a casing fixed energy mix power generation system according to the present invention, wherein the vertical generator chamber coupling grooves 163 and the vertical generator chamber coupling recesses of the vertical generator box 180 are formed at upper and outer sides of the upper casing cover 160. 181, the upper casing 160 and the vertical generator box 180 is coupled and mounted, and the aerodynamic turbine chamber lower auxiliary material 192 is mounted on the lower portion of the aerobic generator turbine chamber 194 of the aerobic generator box 190 and aeroelectric generator It is an assembly diagram which attached the aeroelectric generator 200 which attached the sealing seal material 80 to the shaft 201 to the aeroelectric generator chamber 193. As shown in FIG.

FIG. 72 is a view illustrating the assembly of a casing fixed energy mix power generation system according to the present invention. FIG. 72 is a sealing seal material 80 mounted on an aeroelectric generator turbine shaft 203 to be mounted in an aeroelectric generator turbine chamber 194. The aero generator turbine shaft 203 is coupled to the aero generator shaft 201 through the aero generator turbine shaft opening 195 of the aero generator generator 190 and mounted on the aero generator shaft 201 and the aero generator turbine shaft 203. Assembled seal material 80 is attached to the aero generator turbine shaft sphere (195) by coupling with the bolt nut (100) and the assembly of the aerodynamic turbine chamber upper auxiliary material (192 ') on top of the aerospace generator turbine chamber (194) to be.

FIG. 73 illustrates the assembly of a casing fixed energy mix power generation system according to the present invention, in which a hydrogen production plant 220 is installed outside the hydrogen production chamber 210 and the hydrogen production chamber coupling unevenness formed on the top of the aeroelectric generator box 190 ( 196 and the hydrogen generator chamber coupling groove 233 formed at the bottom of the hydrogen production chamber cover 230 and the hydrogen production chamber cover cover coupling groove 212 and the hydrogen production chamber cover (2) formed at the top of the hydrogen production chamber 210 ( 230, the aeroelectric generator box 190 and the hydrogen production chamber 210 and the hydrogen production chamber 210 and the hydrogen production chamber cover 230 to match the hydrogen production chamber cover coupling concave-convex (231) formed at the bottom is mounted It is an assembly road.

FIG. 74 is a view illustrating the assembly of a casing fixed energy mix power generation system according to the present invention, wherein the nozzle 50 and the electric valve 60 are formed in the nozzle port 50 'and the electric valve port 60' formed in the hydrogen production chamber cover 230. ), Respectively, and install the energy mix transmission electricity 450 at the top outside of the hydrogen production chamber cover 230, and at the bottom of the control room coupling groove 232 and the control room 240 formed at the top of the hydrogen production chamber cover 230. The hydrogen production chamber cover 230 and the control chamber 240 are assembled to be mounted so that the control chamber coupling concavities and convexities 241 are formed.

FIG. 75 is an assembly diagram of a casing fixed energy mix power generation assembly 15 according to the present invention, in which a tower 251 of a wind turbine 250 is coupled to a wind turbine coupling groove 243 formed at an upper end of a control room 240.

Figure 76 is a casing fixed energy mix power generation assembly 16 according to the present invention, the algae generator coupling irregularities 11 attached to the pile 10 and the algae generator coupling section 261 attached to the algae generator 260 is coupled to The algae generator coupling hole 11 "formed in the algae generator coupling concave-convex 11 and the algae generator coupling convex portion 261 ′ formed in the algae generator coupling convex portion 261 are assembled with bolt nuts 100 to the pile 10. The tidal current generator 260 is mounted.

Figure 77 is a casing fixed energy mix power generation assembly 17 according to the present invention, the wave generator coupling unevenness 43 attached to the side of the platform casing 40 and the wave generator coupling convex portion 271 attached to the wave generator 270 is Coupled to the wave generator coupler (43 ') and wave generator coupler 271 formed in the wave generator coupling concave-convex (43) and assembled with a bolt nut (100) to the casing platform ( 40 is an assembly diagram in which the wave generator 270 is mounted.

FIG. 78 is an assembly diagram illustrating a casing fixed energy mix power generation system according to the present invention, in which a pump 440, a pump valve 440 ′, and a pipe 440 ″ are formed on an upper side of an upper casing 130. The pump valve 440 is connected to the upper casing 130 through the upper casing pump connector 133 and connected to the pipe 440 ″ to the pump 440 installed on the upper platform 120. ') Is installed and the pipe 440' is assembled to the hydrogen production plant 220 through the hydrogen production chamber pump connector 214 formed in the hydrogen production chamber 210.

FIG. 79 illustrates a casing fixed energy mix power plant assembly 19 according to the present invention, which is formed in a photovoltaic coupling unevenness 281 attached to a photovoltaic generator 280 in an upper slab of a vertical power generating box 180 and a control room 240. Assembling the photovoltaic generator 280 in the vertical power box 180 and the control room 240 by assembling the bolt nut 100 to the photovoltaic coupler 281 ′, and the upper platform 120 and the upper casing cover. (160) The work tool 470 is formed outside the work tool door 471 is mounted, the door 460 is mounted to the vertical power generation box 180, the door to the hydrogen manufacturing room 210 and the control room 240 ( 460 and a window 461 is assembled.

80 is a casing fixed upright tidal power generation system 1 according to the present invention from the bottom of the lower casing (20 '), the platform casing 40, the tidal generator 90 is installed, the upper casing buoyancy body 140 is embedded It is also a pile upright type tidal power generation facility (481) consisting of a hydrogen production chamber 210, the upper casing 130, the vertical generator 184, the aerodynamic generator 200 is installed.

Figure 81 is a casing fixed upright tidal power generation system 2 in accordance with the present invention when the low water level 420 tidal power generation box 70 mounted on the upper and lower electric valve 60 and the pump 440 installed on the upper platform 120 And the pump valve 440 'and open the seawater to the low water level 420 line of the lower casing 20 through the pipe 440 "and the tidal generator turbine chamber 74 of the tidal generator box 70. Complete generation of power generation facilities.

82 is a casing fixed upright tidal power generation system 3 according to the present invention, the left tidal power generation of the pump 440, the pump valve 440 'and the tidal generator 70 installed on the upper platform 120 at the low water level 420 The preparation of tidal power generation for power generation is completed by closing the electric valve 60 mounted at the bottom of the turbine chamber 74 and the electric valve 60 mounted at the bottom of the left aeroelectric turbine room 194 of the aerospace generator 190. do.

83 is a pile upright tidal tidal power generation system in accordance with the present invention, the right tidal turbine room 74 of the tidal power generation vessel 70, as the flow of sea water rises from the low water level 420 to the medium water level 420 '. The upper casing buoyancy is rotated through the nozzle 50 mounted on the lower side and passed through the upper casing 130 through the electric valve 60 mounted on the upper side. When the sieve 140 rises, the nano magnetic rod 150 attached with the nano magnet 151 mounted on the upper casing buoyancy body 140 rises inside the nanocoil coil 170 and moves inside the upper casing 130. The trapped air rotates the aeroelectric generator turbine 202 through the nozzle 50 mounted on the lower side of the aeroelectric generator turbine chamber 194 of the aerodynamic generator box 190, and the upper side of the control chamber 240 through the electric valve 60. While exhausted to the outside through the formed aerodynamic generator ring mechanism (242) Power generator 90 and a vertical generator (184) and is producing power in the aerodynamic generators (200).

FIG. 84 is a casing fixed upright tidal power generation system 5 according to the present invention until the seawater reaches a high water level 420 " and the nozzle 50 mounted below the right tidal turbine turbine 74 of the tidal power generator 70. FIG. Rotating the tidal generator turbine 92 through the upper casing 130 through the electric valve 60 mounted on the upper casing, the upper casing buoyancy body 140 is built in the upper casing 130, the upper casing The nano magnetic rod 150 attached to the upper side of the buoyancy body 140 is attached to the nano magnetic coil 150 rises inside the nano-coil 170 and the air trapped inside the upper casing 130 is aerodynamic power generation (190) The aeroelectric generator turbine 202 is rotated through the nozzle 50 mounted to the lower side of the aeroelectric generator turbine chamber 194 and the aerodynamic generator return mechanism 242 formed at the top of the control chamber 240 through the electric valve 60. The tidal generator 90 and the vertical generator (1) are exhausted to the outside. 84) and the aerodynamic generator 200 will continue to produce power.

FIG. 85 is a casing fixed upright tidal power generation system 6 according to the present invention. Close the electric valve 60 installed on the upper side of the right aeroelectric generator turbine chamber 194 of the generator box 190 and the electric valve 60 and aeroelectric generator installed on the upper side of the left tidal generator turbine chamber 74 of the tidal generator box 70. Opening the electric valve 60 installed on the upper side of the left aerospace generator turbine chamber 194 of the box 190, the flow of sea water is lowered, the upper casing buoyancy body 140 built in the upper casing 130 is lowered and the nano-magnet ( 151 is attached and the nano-magnet rod 150 mounted on the upper casing buoyancy body 140 is lowered inside the nanocoil coil 170 to generate an electromotive force on the nanocoacoil 170 of the vertical generator 184 to vertical Generator 184 produces power and outside air is the aerodynamic generator of control room 240. It is sucked into the nozzle 50 installed on the top of the aero generator generator 190 through the mechanism 242 to rotate the aero generator turbine 202 installed in the aero generator generator chamber 194 of the aero generator generator 190 and the upper casing ( As air enters 130, the aeroelectric generator 200 produces electric power, and the seawater is provided through the nozzle 50 installed on the upper right side of the tidal power generator 70. The tidal generator turbine 92 is rotated and passed to the lower casing 20 through the electric valve 60 to produce power in the tidal generator 90.

Figure 86 is a casing fixed upright tidal power generation system according to the present invention Figure 7 is the upper casing buoyancy body embedded in the upper casing 130 by the flow of sea water is continuously lowered when the water level is changed from the high water level (420 ") to the medium water level (420 ') As the 140 descends, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nano core coil 170 so that the nano core coil of the vertical generator 184 is lowered. The electromotive force is generated in the 170 so that the vertical generator 184 continuously produces electric power and the outside air is installed on the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240. As the aerodynamic generator turbine 202 is rotated and installed in the aerobic generator turbine room 194 of the aerodynamic generator box 190 and air is introduced into the upper casing 130, the aeroelectric generator 200 continues to produce power. Seawater is the upper right corner of the tidal power generator (70). The tidal power generator (70) rotates the tidal generator turbine (92) of the right tidal turbine (194) through the installed nozzle (50) and passes through the electric valve (60) to the lower casing (20). 90 continue to produce power.

87 is a casing fixed upright tidal power generation system 8 in accordance with the present invention, when the water level is changed from the low water level 420 to the low water level 420, the flow of sea water is continuously lowered to the upper casing buoyancy body embedded in the upper casing 130 ( As the 140 descends, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nano core coil 170 so that the nano core coil of the vertical generator 184 ( The electromotive force is generated in 170 so that the vertical generator 184 continuously generates power, and the outside air is supplied to the nozzle 50 installed on the top of the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240. Suction rotates the aeroelectric turbine 202 installed in the aerobic generator turbine room 194 of the aerobic generator box 190 and air flows into the upper casing 130, the aerodynamic generator 200 continues to produce power and sea water Top right of tidal generator 70 The tidal power generator (70) rotates the tidal generator turbine (92) of the right tidal turbine (194) through the installed nozzle (50) and passes through the electric valve (60) to the lower casing (20). 90) to continuously produce power, and the process of Figs. 51 to 58 is changed four times a day due to the difference between tides, and continuously in the tidal generator 90, the vertical generator 184 and the aerodynamic generator 200. It is a casing fixed upright tidal power generation system that produces electricity.

Figure 88 is an assembly of the offshore floating energy mix power line according to the present invention as a ballast 370 to be dried on the land ground line 411, the ballast pump port 373 at the top center stage (out) The lower casing coupling groove 371 and the ballast concave-convex 371 is formed.

FIG. 89 is an assembly diagram of an offshore floating energy mix power generation line according to the present invention. FIG. 89 is a top floating bottom casing coupling groove 371 and a floating bottom casing 201 of a ballast 370 constructed on a land ground line 411. &Quot;) The assembly diagram in which the ballast 370 and the floating lower casing 20 "

FIG. 90 is a diagram illustrating the assembly of a floating offshore energy mix power generation line according to the present invention. FIG. 90 is a floating lower platform coupling recess 25 and a floating lower platform 380 formed on the upper side of a floating lower casing 20 ″. The floating lower casing 20 " and the floating lower platform 380 are combined and mounted so that the lower platform lower casing coupling groove 381 is matched with the central nozzle hole 50 'of the floating lower platform 380. A floating lower platform casing coupling groove 382 and a floating platform casing 390 are mounted to the valve port 60 'and the nozzle 50 and the electric valve 60 are respectively mounted on the floating lower platform 380. Floating bottom platform coupling unevenness formed in the lower portion (391) to match the floating bottom platform 380 and the floating platform casing 390 is assembled.

91 is an assembly of the offshore floating energy mix power line according to the present invention as shown in the bottom of the floating lower platform tidal generator chamber coupling groove 383 and tidal generator box 70 formed in the center of the floating lower platform 380. Tidal generator chamber (73) and tidal generator chamber (71) inside the tidal generator box (70) by coupling and mounting the tidal generator box (70) inside the floating platform casing (390) to match the formed tidal generator chamber coupling unevenness (71). 73) The tidal generator turbine chamber 74 is formed on both sides, and the tidal turbine chamber lower auxiliary material 72 is mounted on both bottoms of the tidal generator turbine chamber 74 of the tidal power generator 70, and the tidal generator of the tidal generator 90 is provided. It is the assembly figure which attached the sealing seal material 80 to the shaft 91, and installed the tidal power generator 90 in the tidal power generator room 73. As shown in FIG.

FIG. 92 is an assembly diagram of an offshore floating energy mix power generation line 5 according to the present invention, in which a sealing seal material 80 is mounted on an tidal generator turbine shaft 93, mounted on an tidal generator turbine chamber 74, and an tidal generator turbine 92. ) Tidal generator turbine shaft 93 of the tidal generator turbine shaft through the tidal generator turbine shaft (75) of the tidal generator shaft (91) and the tidal generator shaft (91) and tidal generator turbine shaft (93) Attached to the sealing seal material 80 mounted on the tidal power turbine shaft shaft 75 is an assembly diagram coupled to the bolt nut 100 mounted.

93 is a seawater floating energy mix power line assembly 6 in accordance with the present invention, the seawater temperature differential generator 110 is installed on the floating platform casing 390 outside the floating bottom platform (380) The seawater temperature difference generator pump 111 is installed on the upper portion of the pump port 33, and the tidal power generator turbine chamber 74 has an auxiliary auxiliary material 72 'mounted on the tidal turbine chamber.

94 is an assembly of the offshore floating energy mix power line according to the present invention as shown in Figure 7 floating upper platform coupling irregularities (392) and floating floating platform formed on the bottom of the floating platform casing (390) The upper platform casing coupling groove 401 and the tidal generator chamber formed on the top of the tidal power generation box 70, the upper platform coupling unevenness 76 and the floating upper platform tidal generator room coupling groove formed at the bottom of the floating upper platform 400 ( 402 is assembled and fitted to match the assembly of the nozzle 50 and the electric valve 60 (60) in the nozzle port (50 ') and the electric valve port (60') formed on the upper floating platform (400), respectively to be

FIG. 95 is an assembly diagram of an offshore floating energy mix power generation line according to the present invention as shown in FIG. 8, a floating upper casing coupling groove 403 formed on an upper portion of the floating upper platform 400 and an upper platform coupling recess formed on a lower end of the upper casing 130. Floating upper platform 400 and the upper casing 130 is coupled and mounted so that the 131 is matched, and the upper casing buoyancy body 140 is installed in the upper casing 130 is assembled.

FIG. 96 is an assembly diagram of an offshore floating energy mix power line according to the present invention as shown in FIG. 96, in which a nano magnetic rod (141) is formed in a nano magnetic rod coupling groove 141 formed on an upper casing buoyancy body 140 mounted inside the upper casing 130. 150 and the upper casing cover 130 and the upper casing cover 160 so that the upper casing cover coupling groove 132 formed on the upper casing 130 and the upper casing coupling concave-convex 161 formed on the lower end of the upper casing cover coincide with each other. Attaching the sealing seal material 80 to the upper casing cover 160, the bottom of the nano magnetic rod 162 to the nano magnetic rod 150 protruding from the nano magnetic rod 162 formed on the upper casing cover 160 It is assembled with the bolt nut 100 and the nozzles 50 'and the electric valves 60' formed in the upper casing cover 160 and the nozzles 50 and the electric valves 60, respectively.

97 is an assembly of the offshore floating energy mix power line 10 according to the present invention, the upper casing aerodynamic generator chamber coupling groove 164 formed in the upper center of the upper casing cover 160 and the aerodynamic generator formed at the bottom of the aerodynamic generator box 190 Both sides of the aeroelectric generator chamber 193 and the aerobic generator chamber 193 are mounted on the upper casing cover 160 and the aeroelectric generator box 190 so as to match the actual coupling unevenness 191. An aeroelectric generator turbine chamber 194 is formed in the upper casing cover 160, nano coil rods protruding to the outer side of the nano magnetic rods 162 formed on the outer sides of the upper, middle, and bottom of the nano coil core fixing material ( 182) is an assembly diagram installed nanocoil core 170 is installed.

FIG. 98 is an assembly diagram of an offshore floating energy mix power line 11 according to the present invention, wherein the vertical generator chamber coupling grooves 163 and the vertical generator chamber coupling recesses of the vertical generator box 180 are formed at upper and outer sides of the upper casing cover 160. The upper casing 160 and the vertical generator box 180 are combined and mounted so that the 181 is matched, and the aerodynamic turbine chamber lower auxiliary material 192 is mounted on the lower portion of the aeroelectric generator turbine room 194 of the aerodynamic generator box 190 and aerodynamically. It is an assembly diagram in which the sealing seal material 80 is mounted on the generator shaft 201.

99 is a 12-degree assembly of an offshore floating energy mix power generation line according to the present invention. The aeroelectric generator turbine shaft 203 is coupled to the aeroelectric generator shaft 201 through the aerobic generator turbine shaft sphere 195 of the aerobic generator box 190 and to the aerodynamic generator shaft 201 and the aeroelectric generator turbine shaft 203. Attach the mounted sealing seal material 80 to the aeroelectric generator turbine shaft hole 195 and attach and mount it with the bolt nut 100, and install the auxiliary material (192 ') on the aerodynamic turbine chamber upper part of the aerodynamic generator turbine chamber 194, Hydrogen production chamber coupling grooves 211 formed at the lower end of the hydrogen production chamber 210 and the hydrogen production chamber coupling groove 165 formed on the upper casing cover 160 having the generator 200 mounted on the aerodynamic generator chamber 193. The upper casing cover 160 and the hydrogen production chamber 210 to be matched Good is also assembled.

100 is an assembly of the offshore floating energy mix power line according to the present invention as shown in Figure 13 is installed hydrogen production plant 220 on the outside of the hydrogen production chamber 210 and the hydrogen production chamber coupling irregularities formed on the top of the aeroelectric generator box 190 Hydrogen production chamber cover cover coupling groove 212 and the hydrogen production chamber cover is formed so that the aeroelectric generator chamber coupling groove 233 formed at the lower end of the hydrogen production chamber cover 230 and the hydrogen production chamber cover 230 (230) The aeroelectric generator box 190 and the hydrogen production chamber 210 and the hydrogen production chamber 210 and the hydrogen production chamber cover 230 to match the hydrogen production chamber cover coupling irregularities 231 formed at the bottom coupled It is also assembled.

101 is a 14-degree assembly of an offshore floating energy mix power line according to the present invention, the nozzle 50 and the electric valve (60 ') formed in the hydrogen production chamber cover 230, the nozzle 50 and the electric valve ( 60, respectively, and install the energy mix transmitter 450 on the upper outer side of the hydrogen production chamber cover 230, the control chamber coupling groove 232 and the lower control room 240 formed on the hydrogen production chamber cover 230 Hydrogen production chamber cover 230 and the control chamber 240 is assembled to be mounted so that the control chamber coupling concave-convex 241 formed in the.

FIG. 102 is an assembly diagram in which the tower 251 of the wind turbine 250 is coupled to the wind turbine coupling groove 243 formed at the top of the control room 240 as an assembly of the offshore floating energy mix power generation line 15 according to the present invention. .

FIG. 103 is a 16-degree assembly of an offshore floating energy mix power line according to the present invention, and the algae generator coupling recess 11 attached to the floating lower casing 22 "and the algae generator coupling section attached to the algae generator 260 (FIG. 261) is assembled with a bolt nut (100) to the algae generator coupling sphere (11 ") formed in the algae generator coupling concave-convex (11) and the algae generator coupling convex portion (261 '). The assembly of the algae generator 260 is mounted on the floating lower casing (20 ").

104 is an assembly of the offshore floating energy mix power line according to the present invention as shown in Figure 17, the wave generator coupling unevenness 43 attached to the side of the floating platform casing 390 and the wave generator coupling convex portion attached to the wave generator 270 ( 271 are assembled and assembled with the bolt nut 100 to the wave generator coupler 43 'and the wave generator coupler 271 formed in the wave generator coupler 271, respectively. Floating casing platform 390, the wave generator 270 is assembled.

105 is an assembly of the offshore floating energy mix power generation line 18 according to the present invention, in which the pump 440, the pump valve 440 'and the pipe 440 "are placed on the upper side of the upper platform 120. A pump valve connected to the upper casing 130 through the upper casing pump connector 133 and connected to the pipe 440 ″ to the pump 440 installed on the upper platform 120. 440 'is installed and the pipe 440' is connected to the hydrogen production plant 220 through the hydrogen production chamber pump connector 214 formed in the hydrogen production chamber 210.

106 is a 19-degree assembly of an offshore floating energy mix power line according to the present invention, in the solar power generator coupling unevenness 281 attached to the solar generator 280 in the upper slab of the vertical power generation box 180 and the control room 240. Assembling the photovoltaic generator 280 in the vertical power generation box 180 and the control room 240 by assembling the bolt nut 100 to the formed photovoltaic coupler 281 ′, and the upper platform 120 and the upper casing. The work tool 470 is formed on the outside of the cover 160 so that the work tool door 471 is mounted and the door 460 is mounted on the vertical power generation box 180 and the door to the hydrogen production room 210 and the control room 240. 460 and window 461 are assembled.

Figure 107 is a floating offshore energy mix power generation system according to the present invention 1 is a floating platform casing 390, the upper casing buoyancy body 140 is installed from the bottom of the ballast 370, tidal generator 90 is built Floating upright tidal power generation equipment 501 consisting of the upper casing 130, the vertical generator 184, the hydrogen production chamber 210, the winch 430 and the anchor 430 "with the aerodynamic generator 200 installed. It is a power generation system diagram connecting water and pipes 440 ″ on land and operating a seawater temperature generator 111 to replenish water to the ballast 370.

108 is a power generation system diagram of the offshore floating energy mix power generation system according to the present invention, which is partially flooded with the ballast 370, and launches the offshore floating energy mix power generation line 500 at sea.

109 is a three-phase offshore floating energy mix power generation system according to the present invention, when the offshore floating energy mix power generation line is launched at sea, all pumps 440 are operated and the pump valve 440 'and the electric valve 60 are operated. Open and fill all the water tanks such as hydrogen production plant 220, upper casing 130, tidal power generator turbine chamber 74, seawater temperature difference generator plant 110, floating bottom casing (20 "), etc. The winch 430 operates to lower the anchor 430 ″.

110 is an off-shore floating energy mix power generation system according to the present invention. FIG. 440) and the pump valve 440 'is a power generation system diagram.

111 is a 5 degree off-shore floating energy mix power generation system according to the present invention when the difference between the tidal flow from the low water level 420 to the medium water level 420 'changes the seawater temperature difference generator pump 111 and the winch 430 The power generation system diagram controls the chain 430 'as much as the power generation line rises while draining the water in the lester 370 to the outside.

FIG. 112 is a schematic view of the off-shore floating energy mix power generation system according to the present invention. FIG. It is a power generation system diagram of fixing the chain 430 'and fixing the offshore floating energy mix line 500 to a certain height.

FIG. 113 is a diagram of a marine floating energy mix power generation system 7 according to the present invention, when the marine floating energy mix power generation line 500 is set at a constant height, the upper side of the right aeroelectric generator box 190 and the tidal generator box 70. Closed the electric valve 60 is installed, open the electric valve 60 installed on the bottom of the left aeroelectric generator box 190 and the tidal generator box 70 to complete the preparation of the generation of offshore floating type upright tidal power generation line 501 Schematic.

114 is an 8-minute offshore floating energy mix power generation system according to the present invention, when the difference between the tidal flow from the high water level 420 "to the medium water level 420 'is changed, the water in the upper casing 130 is the tidal generator box 70. Tide through the nozzle 50 installed on the top of the tidal generator turbine room 74 of the tide generator turbine chamber 74 and through the electric valve 60 installed at the bottom of the tidal generator turbine chamber 74 to assist the floating lower casing (20 ") The tidal generator turbine 92 installed in the generator turbine chamber 74 rotates to produce electricity in the tidal generator 90, while the upper casing buoyancy body 140 in the upper casing 130 descends, and the aerodynamic generator ring mechanism of the control room 240 is lowered. Intake air 205 is introduced into the upper casing 130 through the electric valve 60 via the aeroelectric generator turbine room 194 through the nozzle 50 installed on the top of the aerobic power generation box 190 to the inlet (242). As the aerodynamic generator turbine 202 rotates and the aeroelectric generator 200 supplies electricity. The nano magnetic rods 150 mounted on top of the upper casing 130 are lowered in the nanocoil core 170 so that electromotive force is generated in the nanocoil coil 170 so that the vertical generator 184 generates power. Schematic.

115 is a 9-degree floating-type energy mix power generation system according to the present invention, the water in the upper casing (130) of the tidal generator box 70 when the difference between tidal flow is changed from the medium water level (420 ') to the low water level (420) The tidal generator is passed through the nozzle 50 installed at the top of the tidal generator turbine chamber 74 and through the electric valve 60 installed at the bottom via the tidal generator turbine chamber 74 to the floating lower casing 20 ". The tidal generator turbine 92 installed in the turbine chamber 74 rotates to continuously generate electricity from the tidal generator 90. As the upper casing buoyancy body 140 in the upper casing 130 descends, the aerodynamic generator of the control chamber 240 is lowered. The suction air 205 flows into the ventilation port 242 and the upper casing 130 through the electric valve 60 via the aeroelectric generator turbine chamber 194 through the nozzle 50 installed on the top of the aerodynamic generator 190. Aerodynamic generator turbine 202 rotates as it enters the aerodynamic generator The 200 continuously generates electricity and the nanomagnetic rod 150 mounted on the upper casing 130 is lowered in the nanocoil core 170 to generate an electromotive force on the nanocoil coil 170 to generate a vertical generator ( 184) is a power generation schematic that continues to produce electricity.

FIG. 116 is a 10 degree off-shore floating energy mix power generation system according to the present invention when the low water level 420 is reached and closes the electric valve 60 installed at the bottom of the left aeroelectric generator box 190 and the tidal generator box 70, and the right side. A power generation system diagram that is prepared for continuous generation of offshore floating type upright tidal power generation line 501 by opening the electric valve 60 installed on the top of the aeroelectric generator box 190 and the tidal generator box 70.

FIG. 117 is an off-shore floating energy mix power generation system 11 according to the present invention. When the difference between tidal tide is changed from the low water level 420 to the middle water level 420 ', the water in the floating lower casing 20 "is the tidal generator box 70 through the nozzle 50 installed at the bottom of the tidal generator turbine chamber 74 and through the electric valve 60 installed at the top via the tidal generator turbine chamber 74 to assist the upper casing 130. The tidal generator turbine 92 installed in the generator turbine chamber 74 rotates to produce electricity in the tidal generator 90, and the exhaust air 204 in the upper casing 130 moves up as the upper casing buoyancy body 140 rises. The aeroelectric generator 200 exhausts the aerodynamic generator return mechanism 242 of the control room 240 through the electric valve 60 via the aeroelectric generator turbine chamber 194 through the nozzle 50 installed at the bottom of the power generation box 190. The aeroelectric generator turbine 202 is rotated to produce electricity and the upper casing 130 The nano-magnet rod 150 mounted on the top is lowered in the nanocoil core 170 to generate an electromotive force on the nanocoil coil 170 so that the vertical generator 184 produces power.

FIG. 118 is a 12-degree off-shore floating energy mix power generation system according to the present invention. The tank passes through the nozzle 50 installed at the bottom of the tidal generator turbine chamber 74 of 70 and passes through the electric valve 60 installed at the upper end of the tidal generator turbine chamber 74 to the upper casing 130. The tidal generator turbine 92 installed in the generator turbine chamber 74 rotates to continuously generate electricity in the tidal generator 90, and the exhaust air 204 in the upper casing 130 rises in the upper casing buoyancy body 140. While the aeroelectric generator 200 of the control room 240 through the electric valve 60 via the aeroelectric generator turbine chamber 194 through the nozzle 50 installed on the lower side of the aerodynamic generator box 190 aerodynamic generator ring mechanism 242 Exhausted to the aerodynamic generator turbine 202 rotates to generate electricity continuously And the nano-magnet rod 150 mounted on the upper casing 130 is lowered in the nanocoil core 170 to generate an electromotive force on the nanocoil coil 170 so that the vertical generator 184 continuously generates power. It is a power generation system.

Figure 119 is a floating lower casing diagram according to the present invention, the bottom of the floating lower casing (20 ") a plurality of seawater holes 21 and the bottom of the bottom plate of the ballast coupling irregularities 24 and the bottom floating platform Coupling unevenness (25) is formed and the seawater flows into the sewer (21), floating lower casing coupling groove (371) and floating lower platform coupling unevenness (25) of the ballast 370 to the ballast coupling unevenness (25) ) Is coupled to the floating lower casing coupling groove 371 of the floating lower platform (380).

FIG. 120 is a view illustrating the construction of a marine energy mix power plant 1 according to the present invention, and the lower portion of the pile stationary energy mix generator 480, the casing stationary energy mix generator 490, and the offshore floating energy mix generator line 500 This is a composition map arranged for the development of the power plant.

FIG. 121 is a diagram illustrating the construction of a marine energy mix power generation complex according to the present invention. FIG. 2 shows a pile stationary energy mix generator 480, a casing stationary energy mix generator 490, and an offshore floating energy mix generator 500. It is a composition diagram arranged only for composition.

FIG. 122 shows the construction of the offshore energy mix power plant 3 according to the present invention. The pile fixed energy mix generator 480, the casing stationary energy mix generator 490, and the offshore floating energy mix generator 500 are generated at sea. The platform coupling member 290 is coupled to the upper platform coupling concave-convex 44 attached to the lower platform 30 and the floating lower platform 380, which is disposed just for the composition, and the energy-mixed complex lower plate 1 320 from the center portion. The energy mix complex buoyancy body 310 is mounted on the energy mix complex buoyancy coupling groove 321 formed at the lower end of the energy mix complex lower plate 2 '320' and the energy mix complex lower plate 3 '320' and the energy mix complex lower portion 1st plate 320, energy mix bottom 2nd plate (320 '), energy mix bottom 3rd plate (320 "), platform bottom connection plate 300, pile fixed energy mix generation equipment (480) and casing fixed energy mix Power generation equipment (490) and An upper power line also injected energy mix the lower platform 30 and the lower floating platform 380, the mutual coupling is mounted and energy mix only installed inside the pillar 360 on the lower plate, each upper power complex composition of 500.

Figure 123 is a 4th composition of the marine energy mix development complex according to the present invention, the energy mix bottom 1st plate 320 and the energy mix bottom 2nd plate 320 'and the energy mix bottom 3rd plate 320 "is assisted on top The development of the power generation complex 70 and the tidal generator 90 is installed.

FIG. 124 is a schematic view of the composition of the marine energy mix power plant 5 according to the present invention, the energy mix top plate 1 330 and the energy mix top 2 plate 330 ', and the energy mix top 3 plate 330 "and the pile fixing type. The upper platform 120 and the floating upper platform 400 of the energy mix generator 480, the casing stationary energy mix generator 490, and the offshore floating energy mix generator line 500 are mounted to each other, The energy mix complex inner pillar 360 is installed at the top and the development of the complex is also.

125 is a view showing the composition of the marine energy mix power plant 6 according to the present invention, and the upper portion of the energy mix top 1 plate 330 and the energy mix top 2 plate 330 'and the energy mix top 3 plate 330 ″. The upper casing buoyancy body 140 on which the magnet rod 150 is mounted is installed, and the upper portion of the energy mix stage 1 plate 330, the upper portion of the energy mix stage 2 plate 330 ′, and the upper portion of the energy mix stage 3 plate 330 ″ The upper casing connecting upper plate 1 (330) and the upper casing connecting upper plate 2 (330 ') are the fixed stationary energy mix generator (480), the casing stationary energy mix generator (490), and the offshore floating energy mix power line ( The upper casing cover 160 of the 500 and is coupled to each other, the nanocoil core 170 is installed on each upper plate, and the aerodynamic generator box 190 and the aerodynamic generator 200 is also a composition of the power generation complex is installed.

FIG. 126 is a view of the composition of the marine energy mix power generation complex according to the present invention, which is perpendicular to the upper portion of the energy mix top plate 1 330, the upper portion of the energy mix top plate 330 ′ and the upper portion of the energy mix top 3 plate 330 ″. The generator box 180, the hydrogen production chamber 210, and the control room 240 are installed, and the wind power generator 250 is mounted on the control room 240, and the solar power generator is mounted on the control room 240 and the vertical generator box 180. The construction of a power plant with 280 is also shown.

FIG. 127 shows the construction of an offshore energy mix power generation complex according to the present invention as shown in FIG. 8 using a pile stationary energy mix generator 480, a casing stationary energy mix generator 490, and an offshore floating energy mix power line 500. It is a power generation complex composition with the mixed power generation complex 510.

1 is a file diagram according to the present invention

Figure 2 is an end casing diagram according to the present invention

Figure 3 is an upper, lower platform in accordance with the present invention

Figure 4 is a platform casing diagram according to the present invention

Figure 5 is a tidal generator box according to the present invention

6 is an aerodynamic generator box according to the present invention

Figure 7 is an upper casing buoyancy body in accordance with the present invention

8 is an accessory according to the present invention.

Figure 9 is a nano magnetic rod according to the present invention

10 is a vertical generator box according to the present invention

11 is an energy mix transmitter according to the present invention.

Figure 12 is a tidal generator according to the present invention

Figure 13 is an aerodynamic generator according to the present invention

14 is a seawater temperature difference plant according to the present invention

15 is a hydrogen production plant according to the present invention

Figure 16 is a top casing diagram according to the present invention

Figure 17 is also a wind power generator according to the present invention

18 is a legend according to the present invention

19 is a winch accessory view in accordance with the present invention.

20 is an accessory view of the pump according to the present invention.

Figure 21 is a tidal current generator according to the present invention

Figure 22 is a solar generator according to the present invention

Figure 23 is a wave generator in accordance with the present invention

24 is hydrogen production according to the present invention

25 is a control room diagram according to the present invention

Figure 26 is a schematic view of the energy mix according to the present invention

Figure 27 is a lower casing diagram according to the present invention

Figure 28 is a ballster diagram according to the present invention

Figure 29 is a top, bottom floating platform in accordance with the present invention

Figure 30 is a floating platform casing diagram according to the present invention

Figure 31 is a pile fixed energy mix power plant assembly 1 according to the present invention

32 is a pile fixed energy-mix power generation assembly assembly 2 according to the present invention

Figure 33 is a pile fixed energy mix power plant assembly according to the invention 3

Figure 34 is a pile fixed energy mix power generation assembly according to the invention 4

35 is a pile fixed energy-mix power generation equipment assembly 5 according to the present invention

36 is an assembly of the stationary energy-mixing power generation equipment 6 according to the present invention

Figure 37 is a pile fixed energy mix power plant assembly according to the present invention 7

38 is an assembly of the stationary energy-mixing power generation equipment 8 according to the present invention

Figure 39 is a pile fixed energy mix power generation assembly according to the invention 9 degrees

40 is a pile fixed energy-mix power generation assembly according to the invention 10 degrees

41 is an assembly of the stationary energy-mixing power generation equipment 11 according to the present invention

42 is an assembly of the stationary energy-mixing power generation plant according to the present invention 12 degrees

43 is an assembly of the stationary energy-mixing power generation plant according to the present invention 13 degrees

Figure 44 is a pile fixed energy mix power plant assembly 14 according to the present invention

45 is a pile fixed energy-mix power generation assembly according to the invention 15 degrees

46 is an assembly of the stationary energy-mixing power generation equipment according to the present invention 16 degrees

Fig. 47 is an assembly of the stationary energy-mixing power generation equipment according to the present invention.

48 is an assembly of the stationary energy-mixing power generation equipment according to the present invention 18 degrees

49 is an assembly of a stationary energy-mixing power generation plant according to the present invention.

50 is an assembly of the stationary energy-mixing power generation equipment 20 according to the present invention

51 is a pile stationary upright tidal power generation system 1 according to the present invention.

Figure 52 is a pile fixed upright tidal power generation system according to the present invention 2

Figure 53 is a pile fixed upright tidal power generation system according to the present invention 3

54 is a pile upright tidal tidal power generation system in accordance with the present invention.

55 is a pile upright tidal tidal power generation system in accordance with the present invention.

56 is a pile fixed upright tidal power generation system according to the present invention 6

Figure 57 is a pile fixed upright tidal power generation system according to the present invention 7

58 is a pile upright tidal tidal power generation system in accordance with the present invention.

59 is a pile fixed seawater temperature differential power generation system according to the present invention

60 is a pile fixed hydrogen production system according to the present invention

61 is a casing stationary energy mix power generation assembly assembly 1 according to the present invention

Figure 62 is a casing stationary energy mix power generation assembly assembly 2 according to the present invention

Figure 63 is a casing fixed energy mix power generation assembly 3 according to the present invention

64 is an assembly of the casing stationary energy-mix power generation equipment according to the invention 4 degrees

Figure 65 is a casing stationary energy mix power plant assembly 5 degrees according to the present invention

Figure 66 is a casing fixed energy mix power generation assembly 6 according to the present invention

Figure 67 is a casing fixed energy mix power plant assembly according to the present invention 7

68 is an assembly of the casing fixed energy mix power generation equipment 8 according to the present invention

Figure 69 is a casing stationary energy mix power generation assembly 9 according to the present invention

70 is a casing stationary energy mix power generation assembly 10 according to the present invention

71 is an assembly of the casing stationary energy mix power plant 11 according to the present invention

72 is assembled 12th casing stationary energy mix power plant according to the present invention

Figure 73 is a casing stationary energy mix power plant assembly 13 according to the present invention

74 is an assembly of the casing stationary energy mix power plant 14 according to the present invention

75 is assembled 15 degrees casing stationary energy mix power plant according to the present invention

76 is assembled 16 degrees casing stationary energy mix power generation equipment according to the present invention

Figure 77 is a casing stationary energy mix power generation assembly 17 according to the present invention

78 is an assembly of the casing stationary energy mix power generation equipment according to the present invention 18 degrees

79 is an assembly of the casing stationary energy mix power generation equipment according to the present invention 19 degrees

80 is a casing fixed upright tidal power generation system according to the present invention 1

Figure 81 is a casing stationary upright tidal power generation system 2 in accordance with the present invention

82 is a casing stationary upright tidal power generation system 3 according to the present invention

83 is a casing stationary upright tidal power generation system in accordance with the present invention.

84 is a casing stationary upright tidal power generation system 5 according to the present invention

85 is a casing stationary upright tidal power generation system according to the present invention 6

86 is a casing fixed upright tidal power generation system according to the present invention 7

87 is a casing fixed upright tidal power generation system 8 in accordance with the present invention

Figure 88 is an assembly of the offshore floating energy mix power line according to the present invention

89 is an assembly of the offshore floating energy mix power generation line 2 according to the present invention

90 is an assembly of the offshore floating energy mix power line 3 according to the present invention

91 is an assembly of the offshore floating energy mix power line 4 according to the present invention

92 is an assembly of the offshore floating energy mix power line 5 according to the present invention

93 is an assembly of the offshore floating energy mix power line according to the present invention 6

94 is an assembly of the offshore floating energy mix power line according to the present invention.

95 is an assembly of the offshore floating energy mix power line according to the present invention

96 is an assembly of an offshore floating energy mix power line according to the present invention.

97 is an assembly of the offshore floating energy mix power line 10 according to the present invention

FIG. 98 is an assembly diagram of an offshore floating energy mix power line according to the present invention.

99 is an assembly of the offshore floating energy mix power line 12 according to the present invention

100 is an assembly of the offshore floating energy mix power line according to the present invention 13 degrees

101 is an assembly of the offshore floating energy mix power generation line 14 according to the present invention

102 is an assembly of the offshore floating energy mix power line according to the present invention 15 degrees

Figure 103 is an assembly of the offshore floating energy mix power line 16 according to the present invention

104 is an assembly of the offshore floating energy mix power line according to the present invention 17 degrees

105 is an assembly of the offshore floating energy mix power line 18 according to the present invention

106 is an assembly of the offshore floating energy mix power line according to the present invention 19 degrees

Figure 107 is a marine floating energy mix generation system according to the present invention 1

108 is a marine floating energy mix generation system according to the present invention 2

109 is a marine floating energy mix generation system according to the present invention 3

110 is an offshore floating energy mix power generation system according to the present invention.

111 is a 5 degree offshore floating energy mix power generation system according to the present invention

112 is a marine floating energy mix generation system according to the present invention 6

113 is a marine floating energy mix generation system according to the present invention 7

114 is an 8-minute offshore floating energy mix generation system according to the present invention

115 is a marine floating energy mix generation system according to the present invention 9

116 is a seafloor floating energy mix power generation system 10 according to the present invention

Figure 117 is a seafloor floating energy mix power generation system according to the present invention

118 is a seafloor floating energy mix generation system according to the present invention 12

Figure 119 is a marine floating energy mix power generation system 13 according to the present invention

120 is a view of the marine energy mix development complex composition 1 according to the present invention

121 is a composition of the marine energy mix development complex according to the present invention 2 degrees

122 is a view of the marine energy mix development complex composition 3 according to the present invention

Figure 123 is a composition of the offshore energy mix power plant 4 according to the present invention

124 is a composition of the marine energy mix development complex 5 according to the present invention

125 is a view of the composition of the marine energy mix development complex 6 according to the present invention

126 is a view of the composition of the marine energy mix development complex according to the present invention

127 is a view of the marine energy mix development complex composition 8 according to the present invention

128 is a floating bottom casing view according to the present invention.

<Brief description of the main parts of the drawing>

10: file 11: algae generator coupling irregularities

11 ': algae generator

20: lower lower casing 20 ': lower lower casing

20 ": Floating bottom casing 21: Sewer

22: pile coupling groove 23: lower flat groove coupling groove

24: ballast coupling irregularities 25: floating lower platform coupling irregularities

30: lower flat groove 31: end (long) lower casing coupling irregularities

32: lower platform casing coupling groove 33: seawater temperature difference generator pump

34: Lower platform tidal generator room coupling groove

40: platform casing 41: lower platform coupling irregularities

42: platform connection unevenness 43: wave generator coupling unevenness

43 ': wave generator coupling 44: upper platform coupling uneven

50: nozzle 50 ': nozzle

60: electric valve 60 ': electric valve ball

70: tidal generator box 71: tidal generator room coupling irregularities

72: auxiliary auxiliary material for tidal turbine chamber lower 72 ': auxiliary auxiliary material for tidal turbine chamber upper part

73: tidal generator room 74: tidal generator turbine room

75: tidal turbine turbine shaft 76: upper platform coupling unevenness

80: sealing seal material

90: tidal generator 91: tidal generator shaft

92: tidal generator turbine 93: tidal generator shaft

100: Bolt nut

110: seawater temperature difference generator plant 111: seawater temperature difference generator pump

120: upper platform 121: upper platform tidal power generation coupling groove

122: upper platform casing coupling groove 123: upper casing coupling groove

130: upper casing 131: upper platform coupling irregularities

132: upper casing cover coupling groove 133: upper casing pump connector

140: upper casing buoyancy material 141: nano magnetic rod coupling groove

150: nano magnetic rod 151: nano magnet

160: upper casing cover 161: upper casing coupling irregularities

162: nano magnetic rod 163: vertical generator chamber coupling coupling groove

164: upper casing cover

165: hydrogen production chamber coupling groove

170: nano coil core 171: nano coil

180: vertical generator box 181: vertical generator coupling irregularities

182: nano coil core fixing material 183: vertical generator compartment entrance

184: vertical generator

190: Aerogen generator box 191: Aerogen generator room coupling irregularities

192: Auxiliary material for aerospace turbine room 192 ': Auxiliary material for aerospace turbine room

193: aeroelectric generator room 194: aeroelectric generator turbine room

195: aeroelectric turbine turbine shaft 196: hydrogen production chamber combined irregularities

200: aero generator 201: aero generator shaft

202: aero generator turbine 203: aero generator turbine shaft

204: exhaust air 205: intake air

210: hydrogen production room 211: hydrogen production room bonding irregularities

212: hydrogen production chamber cover cover coupling groove 213: hydrogen production chamber pneumatic generator chamber coupling groove

214: hydrogen production chamber pump connection

220: hydrogen production plant

230: hydrogen production chamber cover 231: hydrogen production chamber cover coupling irregularities

232: control room coupling groove

240: control room 241: control room coupling irregularities

242: aerodynamic generator ring mechanism 243: wind generator coupling groove

250: wind power generator 251: tower

252: blade 253: rotor hub

260: tidal current generator 261: tidal current generator combined parts

261 ': tidal current generator coupling 262: turbine protection net

263: Algae turbine

270: wave generator 271: wave generator coupled iron

271 ': wave generator combined steel ball 272: wave generator casing

273: wave power generation room

280: photovoltaic generator 281: photovoltaic generator combined irregularities

281 ': PV generator coupler 282: heat collecting plate

290: Platform connector

300: platform connection bottom plate

310: energy mix complex buoyancy body 310 ': energy mix complex bottom coupling uneven

320: Energy Mix Complex Underground 1st Edition 320 ': Energy Mix Complex Underground 2nd Edition

320 ": Energy mix bottom 3rd edition 321: Energy mix complex buoyancy body coupling groove

330: Upper part of the energy mix park 1st edition 330 ': Upper part of the energy mix park 2nd edition

330 ": Energy Mix Complex Upper 3rd Edition

340: upper casing connecting member

350: Upper casing connecting plate 1 350 ': Upper casing connecting plate 2

360: Energy Mix Complex Inner Column

370: Ballaster 371: floating lower casing coupling groove

372: uneven ballast 373: ballast pump ball

380: Floating lower platform

381: floating lower platform stage lower casing coupling groove

382: floating lower platform casing coupling groove

383: Floating bottom platform tidal generator room coupling groove

390: floating platform casing 391: floating bottom platform coupling irregularities

392: floating upper platform coupling unevenness

400: floating upper platform

401: floating upper platform casing coupling groove

402: floating upper platform tidal generator room coupling groove

410: submarine ground 411: land submarine

420: Low water level 420 ': Medium water level

420 ": high water level

430: Winch 430 ': Chain

430 ": anchor

440: Pump 440 ': Pump valve

440 ": pipe

450: energy mix transmitter 451: tidal power generator

452: aeroelectric generator 453: vertical generator

454: tidal power generator 455: wave power generator

456: wind power generator 457: solar power generator

458: seawater temperature difference generator

460: Door 461: Window

470: work tool 471: work tool gate

480: Pile Fixed Energy Mix Generator

481: pile fixed upright tidal power plant

490: Casing Fixed Energy Mix Generator

491 casing fixed upright tidal power plant

500: Offshore floating energy mix reverse line 501: Offshore floating type tidal power generation line

510: Marine Energy Mix Development Complex

Claims (7)

The pile stationary energy mix generator 480 includes the pile 10, the lower casing 20, the lower platform 30, the platform casing 40, the tidal generator 50, the tidal generator 90 and the seawater temperature differential generator. Plant 110, the upper platform 120, the upper casing 130, the upper casing buoyancy body 140, the nano magnetic rod 150, the upper casing cover 160, nano coil core 170 and the vertical generator box ( 180), aeroelectric generator box 190, aerodynamic generator 200, hydrogen production chamber 210, hydrogen production plant 220, hydrogen production chamber cover 230, control room 240, wind power generator 250 and tidal current It is composed of a generator 260, wave generator 270, solar generator 280 and the energy mix transmitter 450 To secure the pile 10 attached to the algae generator coupling irregularities 11 on the bottom of the seabed ground line 410 and the pile coupling groove 22 formed at the upper end of the pile 10 and the lower casing 20. Pile (10) and the lower casing (20) is combined and mounted on the lower platform coupling groove 23 formed on the upper end of the lower casing (20) and the lower (long) lower casing coupling irregularities (31) formed on the lower platform (31). The lower casing 20 and the lower platform 30 are combined and fitted to each other, and the nozzle 50 and the electric valve (50 ') and the electric valve opening 60' of the lower platform 30 are connected to each other. 60, respectively, and the lower platform 30 and the platform casing so that the lower platform casing coupling groove 32 formed on the upper side of the lower platform 30 and the lower platform coupling unevenness 41 formed on the bottom of the platform casing 40 coincide with each other. The lower platform tidal generator chamber coupling groove 34 and the tidal generator formed at the center of the lower platform 30 are combined and mounted 40. The tidal generator chamber formed at the bottom of the 70 is coupled to the tidal generator box 70 inside the platform casing 40 so that the tidal concave-convex recesses 71 coincide with the tidal generator chamber 73 in the tidal generator box 70. The tidal generator turbine chamber 74 is formed on both sides of the tidal generator chamber 73 so that the tidal turbine chamber lower auxiliary material 72 is mounted on both bottoms of the tidal generator turbine chamber 74 of the tidal power generator 70, and the tidal generator 90 The sealing seal material 80 is mounted on the tidal generator shaft 91 of the trough), and the tidal generator 90 is mounted on the tidal generator chamber 73, and the tidal generator turbine is equipped with the sealing seal material 80 on the tidal generator turbine shaft 93. Mounted in the turbine chamber 74 and coupled to the tidal generator shaft 91 through the tidal generator turbine shaft (75) of the tidal generator box 70 to the tidal generator turbine shaft 93 of the tidal generator turbine 92 and tidal The tidal generator motor is provided with a sealing seal material 80 mounted on the generator shaft 91 and the tidal generator turbine shaft 93. Attached to the shaft sphere (75) is coupled to the bolt nut 100, the seawater temperature difference generator pump (33) formed on the lower platform (30) is installed on the outside of the platform casing (40) Install the seawater temperature differential generator pump 111 in the upper part, and install the tidal turbine chamber upper auxiliary material 72 'in the tidal generator turbine room 74, and the upper platform coupling unevenness 44 formed on the platform casing 40 and the upper platform. (120) the upper platform casing coupling groove 122 formed at the bottom and the tidal generator chamber formed at the top of the tidal generator box 70, the upper platform tidal generator chamber coupling at the bottom of the upper platform coupling unevenness 76 and the upper platform 120 Coupling and mounting so that the groove 121 is matched, and the nozzle 50 and the electric valve 60 (60 ') formed on the upper platform 120, respectively, and the nozzle 50 and the electric valve 60, respectively, the upper platform 120 and the upper casing coupling groove 123 formed on the top The upper platform 120 and the upper casing 130 are combined and mounted so that the upper platform coupling recesses and projections 131 formed at the bottom of the bouquet casing 130 are installed, and the upper casing buoyancy body 140 is installed inside the upper casing 130. And attaching the nano magnetic rod 150 to the nano magnetic rod coupling groove 141 formed on the upper casing buoyancy body 140 mounted inside the upper casing 130 and the upper casing cover coupling formed on the upper casing 130 The upper casing 130 and the upper casing cover 160 are combined and mounted so that the groove 132 and the upper casing coupling recess 161 formed at the bottom of the upper casing cover coincide with each other, and the nano magnetic rods 162 formed on the upper casing cover 160. A sealing seal material 80 is attached to the upper casing cover 160, the lower end of the nano magnetic rod 162 to the nano magnetic rod 150 protruding into the mounting) as a bolt nut 100, and a nozzle formed on the upper casing cover 160. The nozzle 50 and the nozzle 50 Equipped with a copper valve 60 and the upper casing cover 160, the upper casing pneumatic generator chamber coupling groove 164 formed in the upper center and the aerodynamic generator chamber coupling irregularities 191 formed at the bottom of the aerodynamic generator box 190, the upper The aeroelectric generator turbine chamber 194 is formed on both sides of the aerodynamic generator chamber 193 and the aeroelectric generator chamber 193 by combining the casing cover 160 and the aeroelectric generator box 190 to be mounted. And nanocoil cores 170 having upper, middle and lower nanocoil core fixing materials 182 mounted on the outer side of the nano magnetic rod 150 protruding from the nano magnetic rods 162 formed on the outer sides of the upper casing cover 160. The upper casing 160 and the vertical generator so that the vertical generator chamber coupling groove 163 and the vertical generator chamber coupling recess 181 of the vertical generator box 180 coincide with each other. Combined mounting box 180 and aeroelectric generator turbine room of the aeroelectric generator box 190 (194) The aeroelectric turbine chamber bottom auxiliary material 192 is mounted on the lower side of the aeroelectric generator shaft 201 equipped with a sealing seal material (80) in the aeroelectric generator chamber (193) and aeroelectric generator turbine shaft An airtight turbine turbine shaft of the aeroelectric generator box 190 is fitted with a sealing seal material 80 to the aeroelectric generator turbine chamber 194, and the aerobic generator turbine shaft 203 of the aeroelectric generator turbine 202 is mounted on the sealant seal material 80. Coupled with the aeroelectric generator shaft 201 through the (195) and attaching a sealing seal material (80) mounted on the aerodynamic generator shaft (201) and the aeroelectric generator turbine shaft (203) to the aerodynamic generator turbine shaft opening (195) bolt nut Combined and mounted to the (100) and the aerodynamic turbine chamber upper auxiliary material (192 ') is installed on the top of the aeroelectric generator turbine room 194 and the hydrogen production chamber coupling groove 165 and the hydrogen production chamber (top) formed on the upper casing cover (160) Hydrogen production chamber coupling irregularities 211 formed at the bottom of the 210 to match the upper Combining and mounting the Yixing cover 160 and the hydrogen production chamber 210, the hydrogen production plant 220 is installed on the outside of the hydrogen production chamber 210 and the hydrogen production chamber coupling irregularities formed on the top of the aeroelectric generator box 190 (196) ) And the hydrogen generator chamber coupling groove 233 formed at the bottom of the hydrogen production chamber cover 230 and the hydrogen production chamber cover cover coupling groove 212 and the hydrogen production chamber cover 230 formed at the top of the hydrogen production chamber 210. A) combined with the aeroelectric generator box 190 and the hydrogen production chamber 210 and the hydrogen production chamber 210 and the hydrogen production chamber cover 230 to match the hydrogen production chamber cover coupling irregularities 231 formed at the bottom; The nozzle 50 and the electric valve 60 are mounted to the nozzle hole 50 'and the electric valve hole 60' formed in the hydrogen production chamber cover 230, respectively, and are disposed on the upper outer side of the hydrogen production chamber cover 230. Control room coupling groove 232 is installed on the top of the hydrogen production chamber cover 230 to install the energy mix transmitter 450 The hydrogen production chamber cover 230 and the control chamber 240 are coupled and mounted so that the control chamber coupling concavities and convexities 241 formed at the bottom of the control chamber 240 are combined with each other. The algae generator coupling unevenness 11 attached to the pile 10 and attached to the pile 10 and the algae generator coupling recess 261 attached to the algae generator 260 are coupled to the algae generator coupling unevenness 11. ) Into the algae generator coupling sphere (11 ") and the algae generator coupling convex portion (261) formed by the bolt nut (100) to the algae generator 260 in the pile (10) The wave generator coupler (43) attached to the side of the platform casing (40) and the wave generator coupler (271) attached to the wave generator (270) are combined and formed in the wave generator coupler (43). Wave generator coupling convex portion formed at 43 'and wave generator coupling convex portion 271. (271 ') is assembled with a bolt nut 100, the wave generator 270 is mounted on the casing platform 40, the pump 440, the pump valve 440' and the pipe 440 "on the upper platform 120 ) Is connected to the inside of the upper casing 130 through the upper casing pump connector 133 formed at the bottom of the upper casing 130, and the upper casing connected to the pipe 440 ″ to the pump 440 installed on the upper platform 120. The pump valve 440 'is installed on the cover 160 and the pipe 440' is connected to the hydrogen production plant 220 through the hydrogen production chamber pump connector 214 formed in the hydrogen production chamber 210, and the vertical power generation. Assembled with a bolt nut 100 in the solar cell coupling port 281 ′ formed in the solar cell coupling recess 281 attached to the solar generator 280 in the upper slab of the box 180 and the control room 240 The photovoltaic generator 280 is mounted on the vertical power generation box 180 and the control room 240, and the upper platform 120 and the upper part. The work tool 470 is formed outside the yingsing cover 160 so that the work tool door 471 is mounted, and the door 460 is mounted in the vertical power box 180, and the hydrogen production chamber 210 and the control room 240 are mounted. Pile-mounted energy-mixed power generation equipment 480, characterized in that the door 460 and the window 461 is mounted The pile fixed upright tidal power generation facility 481 of the pile stationary energy mix power generation facility 480 manufactured in claim 1 has an electric valve 60 and an upper platform mounted on the upper and lower tidal power generation boxes 180 at the low water level 420. Open the pump 440 and the pump valve 440 'installed in the 120, and the seawater is stored in the low water level of the lower casing 20 through the pipe 440 "and the tidal generator turbine chamber 74 of the tidal generator box 70 Initialization of the power generation facility by passing through the line 420 and at the low water level 420, the left side tidal power generation turbine room 74 of the pump 440, the pump valve 440 'and the tidal power generation box 70 installed on the upper platform 120 Close the electric valve 60 mounted on the lower side and the electric valve 60 mounted on the lower side of the left aeroelectric power turbine room 194 of the aerospace generator box 190 to complete the preparation of tidal power generation for power generation and low water level (420). At the bottom of the tidal generator turbine chamber 74 of the tidal power generator 70, the flow of sea water rises as the water level rises to 420 '. The upper casing buoyancy body which rotates the tidal generator turbine 92 through the mounted nozzle 50 and passes through the upper casing 130 through the electric valve 60 mounted on the upper portion and is embedded in the upper casing 130 ( When the 140 rises, the nano-magnet rod 150 to which the nano-magnet 151 mounted on the upper casing buoyancy body 140 is attached rises inside the nanocoil coil 170 and the air trapped inside the upper casing 130. The aerodynamic generator turbine 202 is rotated through the nozzle 50 mounted to the bottom of the right aeroelectric generator turbine chamber 194 of the aerospace generator box 190 and aerodynamically formed on the control chamber 240 through the electric valve 60. The sea water is exhausted to the outside through the generator ventilation mechanism 242 to produce power in the tidal generator 90, the vertical generator 184 and the aerodynamic generator 200 and until the high water level (420 "), the seawater of the tidal power generator (70) Nozzle 50 mounted to the bottom of the right tidal generator turbine chamber 74 When the tidal power generator turbine 92 is rotated through and the upper casing buoyancy body 140, which is passed through the upper casing 130 through the electric valve 60 mounted on the upper portion and is built in the upper casing 130, is raised, The nano-magnet rod 150 to which the nano magnet 151 mounted on the casing buoyancy body 140 is attached rises inside the nanocoil coil 170 and the air trapped inside the upper casing 130 is aerodynamically generated (190). Rotating the aeroelectric generator turbine 202 through the nozzle (50) mounted to the lower side of the aeroelectric generator turbine chamber 194 of the () and the aerodynamic generator ring mechanism 242 formed on the control chamber 240 through the electric valve 60 It is exhausted to the outside through the tidal generator 90, the vertical generator 184 and the aerodynamic generator 200 to continue to produce power and when the high water level (420 ") peaked tidal generator turbine room on the right side of the tidal generator 70 (74) Electric valve 60 and aeroelectric generator box installed on the top Closing the electric valve 60 installed on the top of the right aeroelectric generator turbine room 194 of (190) and the electric valve 60 and aerodynamic generator box installed on the top of the left tidal generator turbine room 74 of the tidal power generator 70 ( Opening the electric valve 60 installed on the upper side of the left aeroelectric turbine turbine room 194 of the 190, the flow of sea water is lowered, the upper casing buoyancy body 140 embedded in the upper casing 130 is lowered, the nano-magnet 151 And the nano magnet rod 150 mounted on the upper casing buoyancy body 140 descends inside the nanocoil coil 170 to generate an electromotive force on the nanocoil coil 170 of the vertical generator 184 to generate a vertical generator ( 184 generates electricity and outside air is sucked into the nozzle 50 installed on the top of the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240, the aeroelectric generator turbine of the aerobic generator box 190 Rotating the aeroelectric turbine 202 installed in the chamber 194 and air in the upper casing 130 As the aerodynamic generator 200 is introduced, electric power is generated, and the seawater is generated through the nozzle 50 installed on the upper right side of the tidal power generator 70. The tidal generator of the right tidal generator turbine chamber 194. When the turbine 92 is rotated and passed through the electric valve 60 to the lower casing 20, electric power is produced by the tidal generator 90, and when the high water level 420 ″ is changed from the high water level 420 ″ to the middle water level 420 ′, the seawater flows. As the lower casing continuously descends the upper casing buoyancy body 140 embedded in the upper casing 130, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 is nanocored. The electromotive force is generated in the nanocoil 170 of the vertical generator 184 by descending from the coil 170 so that the vertical generator 184 continuously produces electric power, and the outside air is the aerodynamic generator ring mechanism of the control room 240 ( Furnace installed on top of the aeroelectric generator box 190 through 242) Aspirated by the 50, the aeroelectric generator turbine 202 installed in the aerobic generator turbine room 194 of the aerodynamic generator box 190 is rotated and the air flows into the upper casing 130, the aerodynamic generator 200 continues to power The sea water rotates the tidal generator turbine 92 of the tidal power generator 70, the right tidal generator turbine chamber 194 through the nozzle 50 installed on the upper right of the tidal power generator 70, and the electric valve 60 Passing to the lower casing (20) through the) continuously produces power in the tidal power generator (90) and when the water level is changed from the low water level (420 ') to the low water level (420') the flow of sea water is continuously lowered to the upper casing (130) As the upper casing buoyancy body 140 embedded therein descends the nano magnet 151 and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nanocoil coil 170 to generate a vertical generator. Electromotive force is generated in the nanocoil coil 170 of 184 The vertical generator 184 continuously produces electric power, and the outside air is sucked into the nozzle 50 installed on the top of the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240. Rotation of the aeroelectric generator turbine 202 installed in the aerobic generator turbine room (194) of the) and as the air flows into the upper casing 130, the aerodynamic generator 200 continues to produce power and the seawater is tidal power generation (70) The tidal power generation box 70 is rotated through the nozzle 50 installed at the upper right side of the right side of the tidal power generator turbine chamber 194. The tidal power generator turbine 92 is rotated and passed through the electric valve 60 to the lower casing 20. While the tidal generator 90 continuously produces power, the tidal power generators 90, the vertical generators 184, and the aerodynamic generators 200 are changed four times a day due to the difference between tides. Continuously electric) The right seawater temperature generator pump 111 installed inside the platform casing 40 has a pipe 440 "installed in the deep sea, and the left seawater temperature generator pump 111 has a low pipe 440" installed therein. And an offshore temperature generator plant 110 that produces power by using a temperature difference between the offshore and the pump 440 installed on the upper platform 120 on the hydrogen production plant 220 installed inside the hydrogen production chamber 220 and on the sea floor. An installed pipe 440 "is connected to the hydrogen production plant 220 through a pump valve 440 'installed on the upper casing cover 160 and a hydrogen production chamber pump connector 214 formed in the hydrogen control chamber 220. Opening the pump valve 440 ′ installed on the casing cover 160 to supply seawater to the hydrogen production plant 220 to purify the seawater in the hydrogen production plant 220 to produce a pile upright, characterized in that to produce hydrogen. Tidal generator (90), vertical generator (184), aerodynamic generator (200), wind generator (250), tidal current generator (260), and wave power installed in the power generation facility (481) and offshore floating energy mix power line (500). The electric power produced by the generator 270 and the solar tube generator 280 is supplied to the tidal power generator 451, the aerodynamic power generator 452, the vertical power generator 453, and the tidal power generator of the control room 240. 454), wave power generator 455, wind power generator 456, solar power generator 457, and seawater temperature differential generator 458, and the power of the energy mix transmitter 450 to a certain quality of power. Converted and supplied to the demand source or pile-type fixed energy mix generator 480, characterized in that for producing hydrogen in the hydrogen production plant 220 using sea water Casing stationary energy mix generator 490 is a pile (10), the lower casing (20 '), the lower platform (30), platform casing (40), tidal generator (50), tidal generator (90) and seawater temperature difference Generator plant 110, upper platform 120, upper casing 130, upper casing buoyancy body 140, nano magnetic rod 150, upper casing cover 160, nano coil core 170 and vertical generator box 180 and the aeroelectric generator box 190, the aerodynamic generator 200, the hydrogen production chamber 210, the hydrogen production plant 220, the hydrogen production chamber cover 230, the control room 240 and the wind generator 250 and It consists of a tidal current generator 260, wave power generator 270, photovoltaic generator 280 and energy mix transmitter 450 The lower platform coupling groove 23 and the lower platform (20 ') formed at the top of the lower casing (20') are fixed to the lower casing (20 ') to which the tide generator coupling unevenness (11) is attached to the bottom of the sea bed (410). 30) The lower lower casing 20 and the lower platform 30 are combined and mounted so that the lower (long) lower casing coupling concavities and convexities 31 formed at the lower end thereof are aligned with the central nozzle hole 50 'of the lower platform 30. The lower platform formed at the bottom of the lower platform casing coupling groove 32 and the lower platform casing 40 are mounted to the valve port 60 'and the nozzle 50 and the electric valve 60, respectively. The lower platform 30 and the platform casing 40 are coupled to each other so that the coupling recesses 41 match, and the lower platform tidal generator chamber coupling groove 34 and the lower end of the tidal generator box 70 formed at the center of the lower platform 30. The tidal power generation box 70 is formed inside the platform casing 40 so that the tidal generator room coupling recesses and protrusions 71 formed thereon are matched. A tidal generator turbine chamber 74 is formed on both sides of the tidal generator chamber 73 and the tidal generator chamber 73 inside the tidal generator box 70 so that the tidal generator turbine chamber 74 of both sides of the tidal generator 70 is installed. The tidal turbine chamber lower auxiliary material 72 is mounted at the bottom, and the sealing seal material 80 is mounted on the tidal generator shaft 91 of the tidal generator 90 to mount the tidal generator 90 in the tidal generator room 73, and tidal The sealing seal material 80 is mounted on the generator turbine shaft 93 to be mounted in the tidal generator turbine chamber 74 and the tidal generator turbine shaft 93 of the tidal generator turbine 92 is tidal generator turbine of the tidal generator box 70. It is coupled to the tidal generator shaft 91 through the shaft hole 75 and the sealing seal material 80 mounted on the tidal generator shaft 91 and the tidal generator turbine shaft 93 is attached to the tidal generator turbine shaft hole 75. Coupling and mounting with bolt nut 100, seawater temperature differential power generation plan inside the platform casing 40 (110) and the seawater temperature generator pump 111 formed on the lower platform 30, the seawater temperature difference generator pump 111 is installed in the tidal power generator turbine chamber 74, the auxiliary auxiliary material upper chamber 72 ' And the upper platform coupling recesses 44 formed on the top of the platform casing 40 and the upper platform casing coupling grooves 122 formed on the bottom of the upper platform 120 and the tidal generator chamber upper platform formed on the upper side of the tidal generator box 70. Coupling unevenness 76 and the upper platform tidal generator chamber coupling groove 121 formed at the bottom of the upper platform 120 is coupled to match the nozzle hole 50 'and the electric valve mechanism formed on the upper platform 120 top Each of the nozzles 50 and the electric valves 60 are mounted at 60 'and the upper casing coupling grooves 123 formed on the upper platform 120 and the upper platform engaging recesses formed on the lower ends of the upper casing 130 are formed. ) To combine the upper platform 120 and the upper casing 130 to match Mounting and installing the upper casing buoyancy body 140 in the upper casing 130, and the nano magnetic rod in the nano-magnetic rod coupling groove 141 formed on the upper casing buoyancy body 140 mounted inside the upper casing 130 The upper casing 130 and the upper casing cover 160 are attached to the upper casing 130 so that the upper casing cover coupling groove 132 formed on the upper casing 130 and the upper casing coupling recess 161 formed on the lower end of the upper casing cover coincide with each other. ) And attach the sealing seal material 80 to the upper casing cover 160, the nano magnetic rod 162 bottom to the nano magnetic rod 150 protruding from the nano magnetic rod 162 formed on the upper casing cover 160 And the nozzle 50 and the electric valve 60 are mounted on the nozzle hole 50 'and the electric valve hole 60' formed on the upper casing cover 160, respectively. (160) Upper casing aerodynamic generator room coupling grooves formed in the upper center and aerodynamic foot The aeroelectric generator room 193 is installed at the center of the aeroelectric generator box 190 by combining and mounting the upper casing cover 160 and the aeroelectric generator box 190 so as to match the aerodynamic generator room coupling irregularities 191 formed at the bottom of the flagship 190. The aerodynamic generator turbine chamber 194 is formed on both sides of the aerodynamic generator chamber 193 and the upper end of the nano magnetic rod 150 protruding to the nano magnetic rod 162 formed on the outer side of the upper casing cover 160, Interruption, the bottom of the vertical generator chamber coupling groove 163 and the vertical generator box 180 is installed in the bottom of the upper casing cover 160, the nano coil core 170 is equipped with a nano coil core fixing material 182 at the bottom. The upper casing 160 and the vertical generator box 180 are combined and mounted so that the vertical generator chamber coupling recesses and projections 181 coincide with each other, and the aerodynamic turbine chamber lower auxiliary material 192 is disposed below the aerodynamic generator turbine chamber 194. ) And aeroelectric power generation with a sealing seal material 80 on the aeroelectric generator shaft 201 (200) is mounted on the aeroelectric generator chamber (193) and the suture seal material (80) is mounted on the aeroelectric generator turbine shaft (203) mounted on the aerobic generator turbine chamber (194) and aeroelectric generator turbine shaft of the aerobic generator turbine (202) 203 is coupled to the aeroelectric generator shaft 201 through the aerodynamic generator turbine shaft sphere 195 of the aerodynamic generator box 190, and the sealing seal material mounted to the aeroelectric generator shaft 201 and the aeroelectric generator turbine shaft 203 ( 80 is attached to the aero generator turbine shaft hole (195) by coupling and mounting with the bolt nut (100) and the upper casing cover (160 ') to install the upper auxiliary material (192') aerodynamic turbine chamber upper portion of the aerospace generator turbine room (194) The upper casing cover 160 and the hydrogen production chamber 210 are combined and mounted so that the hydrogen production chamber coupling groove 165 formed at the top and the hydrogen production chamber coupling recess 211 formed at the bottom of the hydrogen production chamber 210 coincide with each other. Hydrogen production plant 220 is installed outside the hydrogen production chamber 210 Hydrogen generator chamber coupling grooves 196 formed on the top of the aeroelectric generator box 190 and aerosol generator chamber coupling grooves 233 formed on the bottom of the hydrogen production chamber cover 230 coincide with each other and hydrogen formed on the top of the hydrogen production chamber 210. Aerospace generator box 190 and the hydrogen production chamber 210 and the hydrogen production chamber to match the production chamber cover coupling groove 212 and the hydrogen production chamber cover coupling irregularities 231 formed at the bottom of the hydrogen production chamber cover 230 210 and the hydrogen production chamber cover 230 to be coupled to match the nozzle 50 and the electric valve (60 ') formed in the nozzle opening 50' and the hydrogen valve cover 230 and the electric valve (60) And install the energy mix transmitter 450 on the upper outer side of the hydrogen production chamber cover 230 and the control chamber coupling groove 232 and the control chamber 240 formed at the top of the hydrogen production chamber cover 230, respectively. The hydrogen production chamber cover 230 and the control chamber 240 are coupled to each other so that the control chamber coupling recess 241 is matched. The tower 251 of the wind turbine 250 is coupled to the wind turbine coupling groove 243 formed at the top of the control room 240 and coupled to the tidal current generator 11 and the tidal current generator 260 attached to the pile 10. The algae generator coupling section 261 attached to the algae generator coupling hole 11 &quot; and the algae generator coupling convex portion 261 formed in the algae generator coupling concave-convex 11 are formed in the algae generator coupling convex section 261 '. The algae generator 260 is mounted on the pile 10 by assembling the bolt nut 100, and the wave generator coupling convex portion 43 attached to the side surface of the platform casing 40 and the wave generator coupling convex portion attached to the wave generator 270. 271 are assembled and assembled with the bolt nut 100 to the wave generator coupler 43 'and the wave generator coupler 271 formed on the wave generator coupler 271, respectively. The wave generator 270 is mounted on the casing platform 40 and pumped onto the upper platform 120. 440, the pump valve 440 ′ and the pipe 440 ″ are connected to the inside of the upper casing 130 through the upper casing pump connector 133 formed at the bottom of the upper casing 130, and to the upper platform 120. The pump valve 440 ′ is installed on the upper casing cover 160 connected to the pipe 440 ″ and the pipe 440 ′ is formed in the hydrogen production chamber 210. 214 is connected to the hydrogen production plant 220 and the photovoltaic generator coupling formed in the photovoltaic coupling concave and convex (281) attached to the photovoltaic generator 280 in the vertical slab 180 and the upper slab of the control room 240. Assembling the sphere 281 ′ with the bolt nut 100 to mount the photovoltaic generator 280 on the vertical power generation box 180 and the control room 240, and the upper platform 120 and the upper casing cover 160 outside. The work tool 470 is formed in the work tool door 471 is mounted and the door 460 in the vertical power generation box 180 Complex and hydrogen production chamber 210 and the control room 240 to the door 460 and the window casing fixed energy power generation mix characterized in that (461) is mounted equipment 490 The casing stationary upright tidal power generation facility 481 of the casing stationary energy mix power generation unit 490 manufactured in claim 3 has an electric valve 60 and an upper platform mounted on the upper and lower tidal power generation boxes 180 at the low water level 420. Open the pump 440 and the pump valve 440 'installed in the 120, and the seawater is stored in the low water level of the lower casing 20 through the pipe 440 "and the tidal generator turbine chamber 74 of the tidal generator box 70 Initialization of the power generation facility by passing through the line 420 and at the low water level 420, the left side tidal power generation turbine room 74 of the pump 440, the pump valve 440 'and the tidal power generation box 70 installed on the upper platform 120 Close the electric valve 60 mounted on the lower side and the electric valve 60 mounted on the lower side of the left aeroelectric power turbine room 194 of the aerospace generator box 190 to complete the preparation of tidal power generation for power generation and low water level (420). ) To the middle water level (420 ') as the flow of sea water rises to the right tidal generator turbine room 74 of the tidal power generator (70) The upper casing buoyancy is rotated through the nozzle 50 mounted to the upper portion and passed through the upper casing 130 to the upper casing 130 through the electric valve 60 mounted on the upper portion. When the sieve 140 rises, the nano-magnet rod 150 to which the nano-magnet 151 mounted on the upper casing buoyancy body 140 is attached rises inside the nanocoil coil 170 and inside the upper casing 130. The trapped air rotates the aeroelectric generator turbine 202 through the nozzle 50 mounted on the lower side of the aeroelectric generator turbine chamber 194 of the aerodynamic generator box 190, and the upper side of the control chamber 240 through the electric valve 60. The seawater is tidal-powered until it is exhausted to the outside through the formed aerodynamic generator ring mechanism 242 to produce power in the tidal generator 90, the vertical generator 184 and the aerodynamic generator 200, and reaches a high water level 420 "(70). Furnace installed under the tidal generator turbine room (74) on the right side of The upper casing buoyancy body 140 rotates the tidal generator turbine 92 through the bladder 50 and is passed through the upper casing 130 to the upper casing 130 through an electric valve 60 mounted on the upper casing 130. If this rises, the nano-magnet rod 150 attached to the upper casing buoyancy body 140 attached to the nano-magnet 151 is raised in the nanocoil coil 170 and the air trapped inside the upper casing 130 aerodynamic The aeroelectric generator return mechanism formed on the control chamber 240 by rotating the aeroelectric generator turbine 202 through the nozzle 50 mounted on the lower side of the aeroelectric generator turbine chamber 194 of the power generation box 190 and the electric valve 60 When the exhaust gas is exhausted to the outside through the generator 242, the vertical generator 184 and the aerodynamic generator 200 continuously generates power and the high water level 420 "peaks, the right side of the tidal generator 70 Electric valve (60) installed on the top of the tidal generator turbine chamber (74) and aerodynamic power generation Close the electric valve 60 installed on the upper side of the right aeroelectric generator turbine room 194 of the flagship 190 and the electric valve 60 and aeroelectric generator box installed on the top of the left tidal generator turbine room 74 of the tidal generator box 70 Opening the electric valve 60 installed on the upper side of the left aeroelectric turbine turbine room 194 of the 190, the flow of sea water is lowered, the upper casing buoyancy body 140 built in the upper casing 130 is lowered, the nano-magnet 151 ) And the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 is lowered inside the nanocoil coil 170 to generate an electromotive force on the nanocoil coil 170 of the vertical generator 184 to generate a vertical generator. 184 generates electric power and the outside air is sucked into the nozzle 50 installed on the top of the aero generator box 190 through the aero generator generator mechanism 242 of the control room 240, the aero generator of the aero generator box 190 Rotating aeroelectric turbine 202 installed in the turbine chamber 194 and the upper casing 130 As the air is introduced, the aeroelectric generator 200 produces electric power, and the seawater is tidal power through the nozzle 50 installed on the upper right side of the tidal power generator 70. Rotating the turbine turbine 92 and passing through the electric valve 60 to the lower casing 20 to produce power in the tidal generator 90 and to change from the high water level (420 ") to the medium water level (420 ') of the seawater As the flow is continuously lowered, the upper casing buoyancy body 140 embedded in the upper casing 130 descends while attaching the nanomagnet 151 and the nanomagnetic rod 150 mounted on the upper casing buoyancy body 140 is nano. The electromotive force is generated in the nanocoil 170 of the vertical generator 184 by descending from the inside of the core coil 170 so that the vertical generator 184 continuously produces power and the outside air is the aerodynamic generator ring mechanism of the control room 240. Installed on top of the aerodynamic generator box 190 through 242 The aerosol generator 200 is sucked into the nozzle 50 and rotates the aerosol generator turbine 202 installed in the aerosol generator turbine chamber 194 of the aerosol generator box 190 and air flows into the upper casing 130. And the sea water rotates the tidal generator turbine 92 of the tidal power generator 70, the right tidal generator turbine chamber 194 through the nozzle 50 installed on the upper right side of the tidal power generator 70, and the electric valve. Passing to the lower casing 20 through the 60, the tidal power generator 90 continuously generates power, and when the water level is changed from the heavy water level 420 'to the low water level 420, the flow of seawater is continuously lowered to the upper casing. As the upper casing buoyancy body 140 embedded in the 130 descends, the nano magnet 151 is attached and the nano magnetic rod 150 mounted on the upper casing buoyancy body 140 descends inside the nanocoil coil 170. Electromotive force is generated on the nanocoil coil 170 of the vertical generator 184 The vertical generator 184 continuously produces power, and the outside air is sucked into the nozzle 50 installed on the top of the aeroelectric generator box 190 through the aerodynamic generator ring mechanism 242 of the control room 240 and the aeroelectric generator box ( As the aeroelectric generator turbine 202 installed in the aeroelectric generator turbine room 194 of 190 is rotated and air flows into the upper casing 130, the aeroelectric generator 200 continues to produce electric power, and the seawater generates tidal power (70). Rotate the tidal generator turbine 92 of the tidal generator box 70 of the right tidal generator turbine chamber 194 through the nozzle 50 installed on the upper right of the) and through the electric valve 60 to the lower casing 20 As the water is passed, the tidal generator 90 continuously generates power, and the tidal flow generator 90, the vertical generator 184, and the aerodynamic generator (steps 51 to 58 are changed four times a day by tidal wave difference). Continuously from 200) The right seawater temperature generator pump 111, which produces electricity and is installed inside the platform casing 40, has a pipe 440 "installed in the deep sea, and the low seawater temperature generator pump 111 has a low pipe 440" installed therein. And a pump 440 installed above the upper platform 120 in the hydrogen production plant 220 installed in the hydrogen production chamber 220 and producing an electric power using the temperature difference between the deep sea and the sea. A pipe 440 ″ installed on the seabed is connected to the hydrogen production plant 220 through a pump valve 440 ′ installed on the upper casing cover 160 and a hydrogen production chamber pump connector 214 formed in the hydrogen control chamber 220. When the pump valve 440 ′ is installed on the upper casing cover 160 to supply seawater to the hydrogen production plant 220, the hydrogen production plant 220 purifies the seawater to produce hydrogen. Tidal generator (90), vertical generator (184), aerodynamic generator (200), wind generator (250), and tidal current generator (260) installed on the upright tidal power generation facility (491) and offshore floating energy mix power line (500). The electric power generated by the over-wave generator 270 and the solar tube generator 280 is generated from the tidal power generator 451, the aerodynamic generator 452, the vertical generator 452, and the tidal stream of the control room 240. Electricity (454), wave power generator (455), wind power generator (456), solar generator (457) and sea water temperature difference generator (458) are transmitted to the energy mix transmitter 450 of a certain quality The casing fixed energy mix power generation line 490, which is converted into electric power and supplied to a demand source, or hydrogen is produced in the hydrogen production plant 220 using seawater. The offshore floating energy mix power line 500 includes a ballast 370, a floating lower casing (20 "), a floating lower platform (380), a floating platform casing (390), an tidal power generator (50), and tidal power. Generator 90, seawater temperature difference generator plant 110, floating upper platform 400, upper casing 130, upper casing buoyancy body 140, nano magnetic rod 150, upper casing cover 160 and nano Coil core 170, vertical generator box 180, aeroelectric generator box 190, aeroelectric generator 200, hydrogen production chamber 210, hydrogen production plant 220, hydrogen production chamber cover 230 and control room ( 240, wind power generator 250, tidal current generator 260, wave power generator 270, photovoltaic generator 280 and the energy mix transmitter 450 In order to match the ballast coupling recesses 24 formed at the bottom of the floating bottom casing coupling groove 371 and the bottom floating casing 20 " 370) and the floating lower platform (20 ") is coupled to the floating lower platform formed on the bottom of the floating lower platform coupling irregularities (25) and the floating lower platform (380) formed on the bottom of the floating lower casing (20") The floating lower casing 20 " and the floating lower platform 380 are coupled to each other so that the lower casing coupling groove 381 is matched, and the central nozzle hole 50 'and the electric valve hole of the floating lower platform 380 are mounted. 60 ') and the nozzle 50 and the electric valve 60 are mounted on the floating lower platform casing coupling grooves 382 and floating platform casing 390 formed on the upper side of the floating lower platform 380, respectively. Floating lower platform 380 and floating platform casing so that the floating lower platform coupling unevenness 391 coincides 390 is coupled to the floating lower platform tidal generator chamber coupling groove 383 formed in the center of the floating lower platform 380 and the tidal generator chamber coupling irregularities 71 formed at the bottom of the tidal generator box 70 coincide with each other. Tidal generator chamber (74) on both sides of the tidal generator chamber (73) and tidal generator chamber (73) inside the tidal generator box (70) by coupling and mounting the tidal power generator (70) inside the floating platform casing (390). Is formed and the tidal turbine chamber lower auxiliary material 72 is mounted on both sides of the tidal generator turbine chamber 74 at the bottom of the tidal generator box 70, and the sealing seal material 80 is attached to the tidal generator shaft 91 of the tidal generator 90. To mount the tidal generator 90 to the tidal generator chamber 73, to mount the sealing seal material 80 to the tidal generator turbine shaft 93, to the tidal generator turbine chamber 74, and to the tidal generator turbine 92. The tidal generator turbine shaft 93 is passed through the tidal generator turbine shaft hole 75 of the tidal generator box 70. Coupled with the power generator shaft (91) and the sealing seal material (80) mounted on the tidal generator shaft (91) and the tidal generator turbine shaft (93) is attached to the tidal generator turbine shaft hole (75) to combine with the bolt nut (100) And install the seawater temperature differential power generation plant 110 on the outside of the floating platform casing 390 and install the seawater temperature difference generator pump 111 on the seawater temperature difference generator pump hole 33 formed on the floating lower platform 380. And the tidal turbine chamber upper auxiliary material 72 'is mounted in the tidal generator turbine chamber 74, and the floating upper platform coupling unevenness 392 formed on the upper side of the floating platform casing 390 and the floating upper platform 400 are located below. The floating upper platform casing coupling groove 401 and the tidal generator chamber formed at the top of the tidal power generation box 70 The upper platform coupling unevenness 76 and the floating upper platform tidal generator chamber formed at the bottom of the floating upper platform 400 Coupling groove 402 And the nozzle 50 and the electric valve 60 are mounted on the nozzle hole 50 'and the electric valve hole 60' formed on the floating upper platform 400, respectively. ) The floating upper platform 400 and the upper casing 130 are combined and mounted so that the upper platform coupling recesses 131 formed at the lower portion of the upper upper casing coupling groove 403 and the upper casing 130 coincide with each other. The upper casing buoyancy body 140 is installed in the casing 130, and the nano magnetic rod 150 in the nano magnetic rod coupling groove 141 formed on the upper casing buoyancy body 140 mounted inside the upper casing 130. Attach the upper casing 130 and the upper casing cover 160 and the upper casing cover coupling groove 132 formed on the upper casing 130 and the upper casing coupling concave-convex 161 formed on the bottom of the upper casing cover to match. Mounted and formed on the upper casing cover 160 Attach the sealing seal material 80 to the upper casing cover 160, the lower end of the nano magnetic rod 162 to the nano-magnetic rod 150 protruding from the magnetic rod 162, mounted with a bolt nut 100 and the upper casing cover 160 The upper casing aerodynamic generator chamber coupling groove is mounted on the upper casing cover 160 and the nozzle 50 and the electric valve 60 are mounted on the nozzle hole 50 'and the electric valve hole 60' formed at the upper side. The upper casing cover 160 and the aeroelectric generator box 190 are combined and mounted to match the aeroelectric generator room coupling irregularities 191 formed at the bottom of the asynchronous generator box 190 and the aerodynamic generator box 190. The aeroelectric generator turbine chamber 194 is formed at both sides of the aerodynamic generator chamber 193 and the aerodynamic generator chamber 193 and protrudes to the nano magnetic rod 162 formed on the outer side of the upper casing cover 160. On the outside of the top), the nanocoil core 170 with the nanocoil core fixing material 182 is installed on the top, middle, and bottom. The upper casing 160 and the vertical generator box 180 such that the vertical generator chamber coupling groove 163 and the vertical generator chamber coupling recesses 181 of the vertical generator box 180 coincide with the bouquet casing cover 160 on the outer sides of the upper side. And the auxiliary turbine turbine lower auxiliary material 192 is installed in the aerodynamic generator turbine chamber 194 of the aeroelectric generator box 190, and the sealing seal material 80 is mounted on the aeroelectric generator shaft 201, and the aeroelectric generator turbine shaft. An airtight turbine turbine shaft of the aeroelectric generator box 190 is mounted on the sealing seal material 80 to the aeroelectric generator turbine chamber 194 and the aeroelectric generator turbine shaft 203 of the aerobic generator turbine 202 195) is coupled to the aeroelectric generator shaft 201 and the sealing seal material 80 mounted on the aeroelectric generator shaft 201 and the aeroelectric generator turbine shaft 203 is attached to the aeroelectric generator turbine shaft opening (195) bolt nut ( 100) coupled to the top of the aeroelectric generator turbine room (194) A hydrogen production chamber coupling groove 165 and a hydrogen production chamber formed on an upper casing 160 having the aero turbine generator 200 mounted on the aero generator generator 193 with an upper auxiliary power material 192 ′ installed therein. The upper casing cover 160 and the hydrogen production chamber 210 are combined and mounted so that the hydrogen production chamber coupling concavities and convexities 211 formed at the lower end of the 210 are coincident with the hydrogen production plant 220. Hydrogen generator chamber coupling unevenness (196) formed on the top of the aeroelectric generator box 190 and the aerosol generator chamber coupling groove (233) formed at the bottom of the hydrogen production chamber cover 230 and the hydrogen production chamber 210 on the top Hydrogen generator compartment cover and hydrogen production chamber 210 and hydrogen production so as to match the hydrogen production chamber cover coupling groove 212 and the hydrogen production chamber cover coupling irregularities 231 formed at the bottom of the hydrogen production chamber cover 230 are formed. The chamber 210 and the hydrogen production chamber cover 230 are fitted to match the hydrogen production chamber cover (230) The nozzle 50 and the electric valve 60 are respectively mounted in the nozzle hole 50 'and the electric valve hole 60' formed in the upper side of the hydrogen production chamber cover 230. The hydrogen production chamber cover 230 and the control chamber 240 are installed so that the control chamber coupling groove 232 formed at the top of the hydrogen production chamber cover 230 and the control chamber coupling recess 241 formed at the bottom of the control chamber 240 are aligned with each other. Combined mounted and coupled to the tower 251 of the wind turbine 250 to the wind turbine coupling groove (243) formed on the top of the control room 240 and attached to the tide generator coupling uneven (11) attached to the floating lower casing (22 ") And the algae generator coupling section 261 attached to the algae generator 260 and the algae generator coupling hole 11 "formed in the algae generator coupling unevenness 11 and the algae generator coupling convex portion 261 are formed. The algae generator 260 is mounted on the floating lower casing 20 " by assembling the bolt nut 100 to the sphere 261 '. The wave generator coupling concave and convexity 43 attached to the side surface of the platform casing 390 and the wave generator coupling convex portion 271 attached to the wave generator 270 are combined to form the wave generator coupling concave and convexity 43. ') And the wave generator coupling iron part 271 formed in the wave generator coupling iron part 271' by the bolt nut 100, the wave generator 270 is mounted on the floating casing platform 390 and the upper platform ( 120, a pump 440, a pump valve 440 'and a pipe 440 "are connected to the inside of the upper casing 130 through the upper casing pump connector 133 formed at the bottom of the upper casing 130 and the upper platform. The pump valve 440 ′ is installed on the upper casing cover 160 connected to the pipe 440 ″ and the pipe 440 ′ is formed in the hydrogen production chamber 210. It is connected to the hydrogen production plant 220 through the laboratory pump connector 214 and vertical power generation (180) And assembling the bolt generator 100 into the photovoltaic coupler 281 ′ formed in the photovoltaic coupler unevenness 281 attached to the photovoltaic generator 280 in the upper slab of the control room 240. ) Coupled to the vertical power generation box 180 and the upper control room 240 and the work tool 470 is formed outside the upper platform 120 and the upper casing cover 160, the work tool door 471 is mounted and vertical The offshore oil-type energy mix power line 500, characterized in that the door 460 is mounted on the power generation box 180 and the door 460 and the window 461 are mounted on the hydrogen production room 210 and the control room 240. ) The offshore floating type upright tidal power generation line 501 of the offshore floating energy mix power generation line 500 produced in claim 5 is filled with the ballast 370 to some extent and operates all the pumps 440 when the water is launched. Opening the valve 440 'and the electric valve 60, the hydrogen production plant 220, the upper casing 130, the tidal generator turbine chamber 74, the seawater temperature difference generator plant 110, the floating bottom casing 20 ") and all the water tanks, such as water to the winch (430) to move the anchor (430") to lower the water filled in all the water tank and the low water level (420) when the bottom of the submarine ground line (410) After anchoring 430 ″ and locking the pump 440 and pump valve 440 ′ and the difference between tidal water is changed from low water level 420 to medium water level 420 ′, seawater temperature generator pump 111 and winch 430. The water level 420 'by adjusting the chain 430' as much as the power generation line rises while draining the water in the ballast 370 to the outside. When the water in the ballast 370 is drained until the difference between the tidal flow is changed to the high water level 4420 ", the winch 430 is stopped and the chain 430 'is fixed to the offshore oil-type energy mix power line 500 When settled at a constant height close the electric valve 60 installed on the upper side of the right aero generator box 190 and the tidal generator box 70 and the electric power installed at the bottom of the left aero generator box 190 and the tidal generator box 70 The valve 60 is opened to prepare for generation of the offshore floating type upright tidal power generation line 501. When the difference between the tidal flow is changed from the high water level 420 "to the medium water level 420 ', the water in the upper casing 130 becomes the tidal power generator. Floating lower casing (20 ") through an electric valve (60) installed at the bottom via the nozzle (50) installed on the top of the tidal generator turbine chamber 74 of the box 70 and via the tidal generator turbine chamber (74). The tidal power generator turbine 92 installed in the tidal power generator turbine chamber 74 rotates while passing through the tidal power generator. The upper casing buoyancy body 140 in the upper casing 130 to produce electricity in the machine 90 descends while the suction air 205 flows into the aerodynamic generator ring mechanism 242 of the control room 240 to generate aerodynamic power (190). As the aerodynamic generator turbine 202 rotates while the aeroelectric generator turbine 202 is rotated as it enters the upper casing 130 through the electric valve 60 through the aerodynamic generator turbine chamber 194 through the nozzle 50 installed at the top. And the nano-magnet rod 150 mounted on top of the upper casing 130 descends in the nanocoil core 170 to generate electromotive force on the nanocoil coil 170 so that the vertical generator 184 produces power. When the difference between the tidal flow is changed from the middle water level 420 'to the low water level 420, the water in the upper casing 130 passes through the nozzle 50 installed on the tidal generator turbine chamber 74 of the tidal generator box 70. Floating through the electric valve 60 installed at the bottom via the tidal generator turbine chamber 74 The tidal generator turbine 92 installed in the tidal generator turbine chamber 74 rotates while passing through the lower casing 20 "to continuously generate electricity from the tidal generator 90. The upper casing buoyancy body 140 in the upper casing 130 is rotated. ) Is lowered and suction air 205 flows into the aerodynamic generator ring mechanism 242 of the control room 240 and is driven via the aeroelectric generator turbine room 194 through the nozzle 50 installed on the top of the aerodynamic generator box 190. As the aerodynamic generator turbine 202 rotates while the aerodynamic generator turbine 202 is rotated through the valve 60, the aeroelectric generator 200 continuously generates electricity and the nano magnetic rod 150 mounted on the upper casing 130. The nanocoil core 170 descends to generate electromotive force in the nanocoil coil 170 so that the vertical generator 184 continues to produce power and reaches the low aerodynamic generator box 190 when the low water level 420 is reached. Electric valve 60 installed at the bottom of the generator box (70) Close and open the electric valve 60 installed on the upper side of the right aeroelectric generator box 190 and the tidal generator box 70 to prepare for continuous power generation of the offshore oil type upright tidal power generation line 501, the low water level at 420 When the difference between the tidal flow is changed to 420 ', the water in the floating lower casing 20 "passes through the nozzle 50 installed at the bottom of the tidal generator turbine room 74 of the tidal generator box 70 and the tidal generator turbine room. The tidal power generator turbine 92 installed in the tidal power generator turbine chamber 74 rotates while passing through the electric valve 60 installed at the upper end via the 74 to the upper casing 130, thereby rotating the electric power in the tidal power generator 90. And the exhaust air 204 in the upper casing 130 as the upper casing buoyancy body 140 rises through the aerodynamic generator turbine chamber 194 through the nozzle 50 installed at the bottom of the aerodynamic generator 190. The aerodynamic generator ring mechanism 2 of the control room 240 is driven by the aeroelectric generator 200 through the electric valve 60. 42, the aerodynamic generator turbine 202 is rotated to produce electricity and the nano-magnet rod 150 mounted on the upper casing 130 is lowered in the nanocoil core 170 to the nanocoil coil 170 When the electromotive force is generated, the vertical generator 184 produces electric power, and when the difference between tidal tide is changed from the medium water level 420 'to the high water level 420 ", the water in the floating lower casing 20" is the tidal generator box (70). Tidal power generator turbine while passing through the nozzle (50) installed on the bottom of the tidal generator turbine chamber 74 and through the electric valve 60 installed on the top via the tidal generator turbine chamber 74 to the upper casing (130) The tidal generator turbine 92 installed in the chamber 74 rotates to continuously generate electricity in the tidal generator 90, and the exhaust air 204 in the upper casing 130 rises as the upper casing buoyancy body 140 rises. Aeroelectric generator turbine room 194 through a nozzle 50 installed at the bottom of the power generation box 190 Through the electric valve 60, the aeroelectric generator 200 is exhausted to the aeroelectric generator ring mechanism 242 of the control room 240, the aeroelectric generator turbine 202 is rotated to continuously produce electricity and the upper casing 130 top The offshore floating type, characterized in that the vertical magnetic generator 184 continuously generates power by the electromagnet generated in the nanocoil coil 170 is lowered in the nanocoil core 170 mounted on the The tidal generator 90, the vertical generator 184, the aerodynamic generator 200, the wind generator 250, the tidal current generator 260, installed in the upright tidal power generation line 501 and the offshore floating energy mix power line 500, The power generated from the wave generator 270 and the solar tube generator 280 is generated from the tidal power generator 451, the aerodynamic generator 452, the vertical generator 452, and the tidal stream of the control room 240. Electricity (454), wave power generator (455), wind power generator (456) and solar power generation (457) And it is transmitted to the seawater temperature difference generator 458 to be converted to a certain quality of power in the energy mix transmitter 450 to supply to the demand or to produce hydrogen in the hydrogen production plant 220 using seawater Offshore floating energy mix power line (500) The offshore energy mix power generation complex 510 includes a pile stationary energy mix power generation facility 480, a casing stationary energy mix power generation facility 490, an offshore floating energy mix power generation line 500, a platform connector 290, and a platform connecting bottom plate ( 300) and the energy mix complex buoyancy body 310, the energy mix lower plate 1 320, the energy mix lower plate 2 320 ', the energy mix lower plate 3 320 "and the energy mix upper plate 1 330, Energy mix upper plate 2 (330 ') and energy mix upper plate 3 (330 "), upper casing connection upper plate 1 350 and the upper casing connection upper plate 2 (350') and the energy mix in the inner column (360) Composed Pile fixed energy mix power generation equipment (480), casing fixed energy mix power generation equipment (490) and offshore floating energy mix power generation line (500) are arranged on the lower platform 30 and floating lower platform ( 380 is coupled to the upper platform coupling concave-convex 44 attached to the platform connecting member 290, and the energy mix bottom lower plate 1 320 and the energy mix bottom 2 plates (320 ') from the center and the energy mix bottom 3 The energy mix complex buoyancy body 310 is mounted on the energy mix complex buoyancy body coupling groove 321 formed at the bottom of the plate 320 ″, and the energy mix complex lower plate 1 and the energy mix complex lower plate 2 '320' And the energy mix bottom 3rd plate (320 "), the platform bottom connecting plate (300) and the pile fixed energy mix power plant (480) and the casing fixed energy mix power plant (490) and offshore floating energy mix power line (500) Lower platform (30) and floating lower platform 380 is coupled to each other and installed on the top of each lower plate of the energy mix stage inner pillar 360, the energy mix bottom lower plate 1 320 and the energy mix bottom 2 plates (320 ') and the energy mix bottom 3 plates (320 ") Install the tidal power generator box 70 and the tidal generator 90 on the top, and the top 1 energy plate 330 and the top 2 energy mix plate 330 'and the top 3 energy mix plate (330) ") And the upper station 120 and the floating upper platform 400 of the pile stationary energy mix power plant 480, the casing stationary energy mix power plant 490, and the offshore floating energy mix power line 500 are mutually coupled. The top of each upper plate is installed inside the energy mix stage pillars 360, and the upper portion of the energy mix stage 1 plate 330 and the energy mix stage upper plate 2 (330 ') and the top of the energy mix stage 3 plate (330 ") The upper casing buoyancy body 140 is equipped with a nano magnetic rod 150 is installed in the energy mix complex The first plate 330, the upper portion of the energy mix top plate 330 ', the upper portion of the energy mix plate 3 plate 330 ", the upper casing connection upper plate 1 330 and the upper casing connection upper plate 2 330' The pile fixed energy mix generator 480, the casing stationary energy mix generator 490, and the upper casing cover 160 of the offshore floating energy mix generator line 500 are mounted to each other and nanocoil cores are placed on top of each top plate. 170 is installed, the aerodynamic generator box 190 and the aerodynamic generator 200 is installed, the top of the energy mix complex 1 plate 330 and the top of the energy mix complex 2 plate (330 ') and the top of the energy mix complex 3 plate (330) ") Vertical generator box 180, hydrogen production chamber 210 and the control room 240 is installed on the top, the wind turbine 250 is mounted on the control room 240, the control room 240 and the vertical generator box 180 The offshore energy mix development complex 510 and the offshore energy mix development complex, characterized in that the solar generator 280 is mounted on the top (5 10) power generated by the tidal generator 90, the vertical generator 184, the aerodynamic generator 200, the wind power generator 250, the tidal current generator 260, the wave power generator 270 and the solar tube generator 280 installed in the 10) The tidal power generator 451, the aerodynamic power generator 452, the vertical power generator 453, the tidal power generator 454, the wave power generator 455, and the wind power generator of the control room 240. 456 and the solar power generator 457 and the sea water temperature difference generator 458 is converted into a certain quality of power from the energy mix transmitter 450 is supplied to the demand source or hydrogen production plant using sea water 220 Coastal energy mix development complex, characterized in that to produce hydrogen in

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