KR20220120747A - Combined Renewable Energy Production System With Offshore Floating Platform For Wave, Wind And Solar Power Generation - Google Patents

Abstract

The present invention relates to a combined renewable energy production system including an offshore floating platform, the combined renewable energy production system which is configured to perform wind power generation and solar power generation on an upper part (upper plate) of the offshore floating platform for wave, wind and solar power generation among new and renewable energy and to perform wave power generation on a lower part (underwater) of the platform. The combined renewable energy production system according to the present invention comprises: an abandoned ship; an abandoned-ship-floated offshore platform installed symmetrically on both right and left sides of the abandoned ship; a plurality of wave power generation devices installed on a lower part of the offshore platform; and a plurality of wind power generators and a plurality of solar power generation panels installed on the offshore platform. The combined renewable energy production system according to the present invention can produce clean energy on a large scale with a high degree of integration in a single place and can move freely in a sea area with good waves and wind to select an appropriate position. Moreover, an abandoned ship can be used to be economical, a hollow cylindrical steel pipe is used as a component of the offshore platform to increase buoyancy, underwater pipes, frame-supporting columns, etc. are cylindrical to be able to reduce an antirust area, and a ballast water chamber for adjusting buoyancy and balance is made to enable the height of the platform to be adjusted stably like general ships.

Description

Combined Renewable Energy Production System With Offshore Floating Platform For Wave, Wind And Solar Power Generation

The present invention is a composite renewable energy production system having an offshore floating platform for power generation of wave power, wind power, and solar power among new renewable energies, specifically, wind power generation and solar power generation in the upper part (top plate) of the offshore floating platform, It relates to a complex renewable energy production system having a floating offshore platform (hereinafter, sometimes referred to as a 'platform') configured to generate wave power in the lower platform (underwater).

As international regulations on greenhouse gases, the main culprit of global warming, are strengthened, countries around the world are turning their eyes to new energy industries. As developed countries including Korea and the United States recently declared a 'carbon neutral policy for 2050', the world is expected to further accelerate the development of various new and renewable energy technologies as an alternative to fossil fuels. There are various types of renewable energy sources. On land, there are solar power, wind power, and geothermal power. At sea, there are tidal power generation and tidal power generation. However, on land solar power and wind power generation, etc. is limited due to noise, location restrictions, and damage to the landscape. As one of the ways to overcome this limitation, the development of technology using the ocean as an energy source is emerging in Korea.

In view of these domestic and foreign trends, in order to actively respond to this, the present invention has devised a method for producing energy using the sea. In other words, solar and wind power generation on land has limitations in terms of securing a place and site suitable for a location more fundamentally than environmental destruction, landscape damage, or noise. On the other hand, in the case of offshore power generation, there is a limit to easily securing additional sites for tidal power and tidal power generation.

In addition to the limitations of additional suitable site conditions for renewable energy generation on land and the medium-to-long-term large-scale investment such as 'offshore wind farms' at sea, commercialized technologies that are easy to apply and have power generation and economic feasibility have yet to be developed. We are at a point where innovative technology development that goes beyond the limitations of existing wave power devices is required.

Korean Patent Registration No. 10-1059065 discloses a closed ship disposed in a floating state in the sea; Position fixing means for fixing the closed ship to a specific position in the sea; and a plurality of wind power generation modules disposed on the deck of the scrapped ship, and is installed in the sea where strong winds are generated, and describes a wind power generator using a waste ship having excellent wind power generation efficiency. However, since the registered patent installs a wind tower for wind power generation on a deck, the utilization of the abandoned ship is low, and thus the amount of power generation is also insignificant.

In addition, in the Republic of Korea Patent No. 10-1851909, a waste vessel such as a tanker or bulk carrier is installed on the shore with a high difference between the tides and the strong water pressure generated during the inflow and discharge of seawater into and out of the tank of the abandoned vessel. Although it describes a tidal power generation device using a ship that rotates a water wheel to generate power, this patent also has a low utilization of an abandoned ship and, accordingly, the amount of power generation is insignificant.

Therefore, an offshore floating platform that can produce large-scale new and renewable energy with high efficiency by greatly increasing the amount of power generation and generating wind power and solar power on the upper part of the offshore platform (top plate), and generating wave power on the lower part of the upper platform (underwater) There is a need for a complex renewable energy production system equipped with this.

Registered Patent 10-1059065 Registered Patent 10-1851909

An object of the present invention is an offshore floating type that can efficiently produce large-scale renewable energy by generating wind power and solar power in the upper part of the offshore platform (top plate) and wave power in the lower part of the platform (underwater) in order to significantly increase the amount of power generation It is to provide a complex renewable energy production system equipped with a platform.

The present invention for achieving the above object is a closed ship; As a floating offshore platform symmetrically installed on both left and right sides of the closed ship, it extends from both left and right sides of the closed ship by a predetermined length perpendicular to it, and a plurality of lattice types coupled in parallel in the horizontal and vertical directions, respectively A main frame, a plurality of sub-submersible pipes connected by extending a certain length in parallel to the main frame from both left and right sides of the closed ship under the main frame, and a main sub-submersible pipe coupled to the outer ends of the plurality of sub sub-submersible pipes A closed ship floating type having a plurality of main frame support columns connecting between the underwater pipe and the underwater pipe. offshore platforms; And a plurality of wave power generation units, a hydraulic oil pressure tank for storing hydraulic oil in a compressed state by compression in the hydraulic cylinder of the wave power unit, a hydraulic motor operated by the compressed hydraulic oil in the hydraulic oil pressure tank, the hydraulic motor It relates to a complex renewable energy production system comprising; a generator that produces electricity by a wave power generator, and a wave power device having an atmospheric hydraulic oil storage tank for storing hydraulic oil that has become atmospheric pressure after power generation.

A preferred embodiment of the present invention is a composite renewable energy production system, characterized in that it is connected with a plurality of fixed wires to the upper end of a plurality of fixed towers installed on the deck of an abandoned ship and the main underwater pipe in order to provide structural stability of the offshore platform provides

Another preferred embodiment of the present invention, instead of the closed ship floating offshore platform, a self-floating offshore platform is used, and the self-floating offshore platform is extended by a certain length in both left and right vertical directions from the central portion and is coupled to a plurality of grid-type main frame; a plurality of sub-frames coupled in parallel to each other in the transverse and longitudinal directions of the grid-type main frame; A plurality of sub-submersible pipes coupled by extending by a predetermined length from both left and right sides of the central part in parallel to the main frame under the main frame, and the outermost sub-submersible pipes in the longitudinal direction of the outer ends and the central part of the plurality of sub sub-submersibles a submersible pipe consisting of a main submersible pipe coupled to; a plurality of main frame support columns connecting between the main frame and the underwater pipe; And it provides a composite renewable energy production system, characterized in that it has an underwater reinforcement column connecting the main frame from the four corners of the main underwater tube and the secondary underwater tube on both sides in the longitudinal direction of the central part.

Another preferred embodiment of the present invention provides a composite renewable energy production system, characterized in that the sub-submersible pipe and the main sub-submersible pipe are cylindrical steel pipes to increase buoyancy.

Another preferred embodiment of the present invention provides a composite renewable energy production system, characterized in that the sub-frame reinforcement channel is diagonally coupled to each other in the coupling part of the main frame and the sub-frame or in the coupling part between the sub-frames. As used herein, the term 'jannel' refers to a frame having a 'C' shape in cross section.

Another preferred embodiment of the present invention is that, except for the central part, from the middle part of the main frame support column or the underwater reinforcement column, the support column fixing wire is diagonally coupled to the lower part of the main frame support column or underwater reinforcement column adjacent thereto. It provides a complex renewable energy production system, characterized in that.

Another preferred embodiment of the present invention is that the closed ship floating offshore platform or self-floating offshore platform is provided with ballast water chambers for a certain length at both ends of the outermost main submersible pipe so as to maintain an appropriate height from the sea level. It provides a complex renewable energy production system characterized by.

Another preferred embodiment of the present invention is that the ballast water chamber is connected to a bulkhead formed at a certain length in the main water tube, a hydraulic oil pressure tank, and an air pressure tube for pressurizing air in the upper part of the ballast water chamber, and the seawater is sucked an air discharge pipe connected to the air pressure pipe to It provides a renewable energy production system, characterized in that it is.

Another preferred embodiment of the present invention is a complex renewable energy production system, characterized in that the anchors are installed at the four corners of the closed ship floating offshore platform or self-floating offshore platform in order to ensure structural stability through weight balance. provides

Another preferred embodiment of the present invention, the wave power unit, a plurality of bolt fixing holes formed to be bolted to the lower surface of the sub-frame or the sub-frame reinforcement panel, a plurality of buoys formed so that a buoy guider fixing angle is inserted and welded a hydraulic cylinder fixing bracket having a guider angle fixing groove and a hydraulic cylinder buffer spring fixing groove in the center; a plurality of buoy guider fixing angles inserted and welded into the angle fixing groove of the hydraulic cylinder fixing bracket and extended by a predetermined length therefrom and fixed to the first, second, and third buoy guider brackets; A plurality of buoy guider holes formed at the rounded conical end so that the buoy guider is inserted and penetrated, a hydraulic cylinder through hole formed in the center, two slits formed by a certain length on both sides of the through hole in the radial direction, and the buoy guider fixing angle and first, second, and third buoy guider brackets having a 'L'-shaped groove to be bolted together; One side is fixed by the buffer spring coupled to the buffer spring fixing groove of the hydraulic cylinder fixing bracket, the other side is fixed to the fixing plate attached to the second buoy guider bracket, and the hydraulic cylinder is the hydraulic cylinder through hole of the first buoy guider bracket. It is inserted through, the hydraulic cylinder shaft is coupled to the buoy through the second and third buoy guider brackets, and a hydraulic cylinder having a hydraulic oil inlet pipe and a hydraulic oil outlet pipe each having a check valve on the upper part; a plurality of buoy guiders inserted into the buoy guider holes of the second and third buoy guider brackets to guide the up and down movement of the buoys and coupled to the upper outer surface of the buoy; and a buoy coupled to the lower end of the buoy guider; provides a renewable energy production system comprising a.

In another preferred embodiment of the present invention, in order to limit the vertical movement of the buoy, a stopper is installed on the buoy guider so as to be positioned above the second buoy guider bracket and located below the third buoy guider bracket, characterized in that each is installed Provides a renewable energy production system.

Another preferred embodiment of the present invention provides a complex renewable energy production system, characterized in that a plurality of flanges are formed on the other side of the buoy guider shaft and the hydraulic cylinder shaft with one side embedded in the buoy in order to easily attach and detach the buoy. .

Another preferred embodiment of the present invention provides a composite renewable energy production system, characterized in that the buoy is cylindrical and the upper part is made of a waste plastic melt, and the lower part is made of styrofoam and the styrofoam protective case.

Another preferred embodiment of the present invention provides a composite renewable energy production system, characterized in that the wind power generator is installed at the four corners of the floating offshore platform of the closed ship and the self-floating offshore platform.

Another preferred embodiment of the present invention provides a complex renewable energy production system, characterized in that a plurality of photovoltaic panels are installed on the floating offshore platform of the closed ship and the self-floating offshore platform.

Another preferred embodiment of the present invention is that the AC electricity produced from the wave power generator and the wind generator matches the frequency through the AC/DC converter and the DC/AC synchronous inverter, and the direct current electricity produced by the solar power panel is electricity. It provides a complex renewable energy production system, characterized in that it can be used for various purposes after being collected by a transformer through a storage facility and a synchronous inverter.

The complex renewable energy production system according to the present invention can produce clean energy on a large scale with a high degree of integration by using wave power, wind power, and solar power at the same time in a single place, and can freely select an appropriate location in a sea area with good waves or wind have.

In addition, in the present invention, since a waste ship can be used, it is economical in terms of manufacturing cost, increases buoyancy by using a hollow cylindrical steel pipe as a component of an offshore platform, and the underwater pipe, frame support column, etc. The height of the platform can be adjusted stably like a normal ship because the anti-rust area can be reduced and the 'ballast water room' can be adjusted for buoyancy and balance.

1 is a conceptual diagram of a hybrid renewable energy floating offshore platform using an abandoned ship and installed with wind power, wave power and photovoltaic power generation devices.
2 is a plan view of a frame for the upper structure of a floating offshore platform using a closed ship.
3 is a bottom view of a frame for the lower structure of a floating offshore platform using a closed ship.
4 is a perspective view of the main frame for the upper and lower structures of the right floating offshore platform using a closed vessel.
5 is a front view of a floating offshore platform using an abandoned ship.
6 is a conceptual diagram of a self-floating offshore platform that does not use a closed vessel.
7 is a plan view of a frame for the superstructure of a self-floating offshore platform, without using a closed vessel.
8 is a side view (a) and a front view (b) of the structure of the self-floating offshore platform according to FIG. 7 ;
9 is a bottom view of the lower (underwater) structure of the self-floating offshore platform according to FIG. 7 ;
FIG. 10 is a perspective view of the main frame and submerged tube of the self-floating offshore platform according to FIG. 7 .
11 is a state diagram in which the main frame support column is connected to the main frame and the underwater pipe of the floating offshore platform.
12 is a detailed view in which the main frame, the sub-frame, and the sub-frame reinforcement channel of the floating offshore platform are combined.
13 is a wave power system configuration and hydraulic oil flow chart.
14 is a block diagram of a wave power generator.
15 is a detailed view of the buoy fixing unit.
16 is a detailed view of the first, second and third buoy guider brackets.
17 is a plan and elevation view of the buoy;
18 is an operation state diagram of the buoy and the hydraulic cylinder.
19 is a state diagram in which the buoy and the hydraulic cylinder are exemplarily coupled to the sub-frame and the sub-frame reinforcement channel.
20 is a block diagram of the ballast water chamber of the main submersible pipe.
21 is an exemplary view in which the solar panel is installed on the upper frame.
22 is a wiring diagram of a composite renewable energy power.

Hereinafter, the present invention will be described in detail by way of example with reference to the drawings. However, this description is not intended to limit the present invention.

The complex renewable energy production system according to the present invention, as schematically shown in FIG. 1, is largely a closed ship 100, a floating offshore platform 200 for a closed ship that is installed symmetrically on the left and right sides of the abolished ship 100 ), a plurality of wave power generators 300 installed under the offshore platform 200, a plurality of wind power generators 400 and a plurality of photovoltaic panels 500 installed on the offshore platform 200 consist of,

In addition, as a preferred embodiment of the present invention, the composite renewable energy production system does not use the abandoned ship 100 and the abolished ship floating offshore platform 200, and can use its own floating offshore platform 200a instead. . In this case, there is no consumption of wave power, and there is an advantage that there is little influence on severe waves.

Therefore, there is a method of floating the platform on the sea using a method using the scrapped ship 100 and a method not using the abolished ship 100 .

In the present invention, the reason why the platform should be floating on the sea is that the control center 6, hydraulic oil tank, communication tower, etc. must be installed above the sea level, cope with the difference in water depth or tidal flow, and move it to a place with good wind and sunlight. This is because it is necessary to secure the mobility and to promote structural stability.

There are discarded oil tankers, container ships, bulk carriers, etc., as the waste ship 100 used in the present invention, and these waste ships 100 can be purchased at a low price because the cost of dismantling is more expensive than the cost of scrap metal, so it is a good alternative. In addition, the advantage of using an abandoned ship is that the buoyancy is automatically adjusted and the structural stability of the platform is secured.

Although the configuration for coupling the floating offshore platform 200 of the abandoned ship to the abolished ship 100 is not shown in the drawing, it can be made using a known method such as welding, flange coupling, etc. on the side of the abandoned ship 100. , a detailed description is omitted herein.

Abandoned ship floating offshore platform 200 according to the present invention, as shown in detail in Figs. In particular, as shown in detail in Fig. 4, the abolished ship floating offshore platform 200 extends from both sides of the closed ship 100 by a predetermined length in both directions perpendicular to it and includes a plurality of horizontally and vertically coupled multiple platforms. It consists of a grid-type main frame (201). As shown in FIG. 2 , the main frame 201 and the sub-frame 202 use a hollow box girder, and are configured to float by a certain height from the sea level 1 .

Below the main frame 201, a submersible pipe consisting of a main submersible pipe 204 and a plurality of sub submersible pipes 203 is formed. The sub-submersible pipe 203 extends by a predetermined length in parallel with the main frame 201 in the vertical direction from both left and right sides of the closed ship 100 . And the main submersible pipe 204 is coupled to the outer end of the plurality of sub submersible pipes 203 .

And the main frame 201 and the main submersible pipe 204 are, as shown in FIG. 11, the main frame support column 206 by the main frame connecting bracket 205a and the main submersible pipe connecting bracket 205b, respectively. is connected with

In addition, according to the present invention, as shown in FIG. 5 , in order to increase the structural stability of the floating offshore platform 200 of the abandoned ship, a plurality of fixed towers 207 are installed on the deck of the abandoned ship 100 and It is connected to the upper end and the main submersible pipe 204 with a plurality of fixing wires 208 . Although only three fixed towers 207 are shown in FIG. 1, the number may be increased or decreased as necessary.

In the present invention, the self-floating offshore platform 200a used instead of using the closed ship 100 and the closed ship floating offshore platform 200 is, as shown in FIGS. 6 to 10, a waste The overall buoyancy is strengthened by adding an underwater reinforcement column 209, which is a circular steel pipe, to the lower part of the central part at the position of the ship 100, and a platform-type top plate (width and length are set to an appropriate scale) is placed in the center part to make the top plate of the ship Used as a deck (deck), in the middle part of the main frame support column to strengthen the bond between the main submersible pipe 203 and the main frame support column 206 at the bottom, the main submersible pipe 204 and the sub submersible pipe 203 ) are bound together in an X-shape with a wire. The self-floating offshore platform 200a may move freely using a tugboat.

7 and 8, the central portion 100a has an underwater reinforcing column 209, which is a circular steel pipe, at its lower end, and forms an upper plate on the main frame support column 206, and from the central portion 100a, left and right A plurality of lattice-type main frames 201 are formed extending by a predetermined length in both vertical directions.

The self-floating offshore platform 200a according to the preferred embodiment of the present invention also has a plurality of sub-frames 202 in the transverse and longitudinal directions of the grid-type main frame 201, as in the floating ship floating offshore platform 200. They are connected parallel to each other.

In addition, the water pipe consists of a plurality of sub-water pipes 203 and a plurality of main sub-water pipes 204, and parallel to the main frame 201 from the left and right sides of the central part 100a under the main frame 201 A plurality of sub-submersible pipes 203 are extended by a certain length and coupled, and the outermost sub-submersible pipe 203 in the longitudinal direction of the outer end and central part of the plurality of sub sub-submersible pipes 203 has a main sub-submersible pipe 204 ) are combined.

A plurality of main frame support pillars 206 are connected between the main frame 201 and the submersible pipes 203 and 204, and the four corners of the main submersible pipe 204 and the sub submersible pipe 203 of the central part 100a. Between the main frame 201 from the underwater reinforcement column 209 is connected.

In addition, in the closed ship floating offshore platform 200 and self-floating offshore platform 200a according to the present invention, the sub-submersible pipe 203 and the main sub-submersible pipe 204 are cylindrical steel pipes to increase buoyancy. Can be, the main frame 201 and the sub-frame 202, the coupling part or the coupling part between the sub-frames 202, the sub-frame reinforcement channel 210 is diagonally coupled.

As mentioned above, all the frames, underwater pipes, support columns, underwater reinforcement columns, etc. constituting the offshore platforms 200 and 200a according to the present invention are hollow hollow bodies to enhance buoyancy and reduce the total weight of the structure. Structural stability is promoted by greatly reducing the rust prevention area, especially in the case of an underwater structure using a round steel pipe.

8 and 10, except for the central portion 100a, from the middle portion of the main frame support column 206 or the underwater reinforcement column 209 adjacent thereto from the main frame support column 206 or underwater reinforcement A support pillar fixing wire 211 is coupled to the lower portion of the pillar 209 diagonally. In FIG. 10, only a part of the coupling state of the support pillar fixing wire 211 is illustrated for convenience.

3, 9, and 20, the closed ship floating offshore platform 200 or self-floating offshore platform 200a can maintain an appropriate height from the sea level 1 according to the sea level situation. A total of four ballast water chambers 220 are provided by a partition wall 221 by a predetermined length at both ends of the outermost main submersible pipe 204 so as to be.

More specifically, as shown in detail in FIG. 20 , the ballast water chamber 220 is formed by the bulkhead 221 at a predetermined length in the main submersible pipe 204 . The air pressure pipe 222 may be connected to the hydraulic oil pressure tank 340 to pressurize air in the upper part of the ballast water chamber 220 . In addition, the ballast water chamber 220 is provided with a seawater discharge/suction pipe 224 for discharging or sucking seawater. An air discharge pipe 223 is connected to the air pressure pipe 222 . Solenoid valves 225a , 225b , and 225c are respectively provided between the air discharge pipe 223 , the seawater discharge/suction pipe 224 , and the air discharge pipe 223 and the hydraulic oil pressure tank 340 .

For example, the height adjustment of the offshore platforms 200 and 200a is, as shown in detail in FIGS. 13 and 20, the air outlet pipe 223 is closed with a solenoid valve 225a, and the air pressure pipe 222 and The seawater discharge/suction pipe 224 is opened by the solenoid valves 225b and 225c, respectively, and then the buoyancy of the ballast water chamber 220 is adjusted by using the compressed air in the hydraulic oil pressure tank 340 to suit the situation.

In order to secure structural stability through the weight balance, anchors are installed at the four corners of the floating offshore platform 200 or the self-floating offshore platform 200a of the closed ship.

The wave power device 300 installed at the lower part of the floating offshore platform 200, 200a according to the present invention, as shown in FIGS. 13 to 19, A plurality of wave power generation units 310, a hydraulic oil pressure tank 340 for storing hydraulic oil in a compressed state by compression in the hydraulic cylinder 326 of the wave power generation unit 310, the hydraulic oil pressure tank 340. A hydraulic motor 350 operated by compressed hydraulic oil, a generator 360 that produces electricity by the hydraulic motor 350, and an atmospheric pressure hydraulic oil storage tank 370 for storing hydraulic oil that is in a normal pressure state after power generation. do.

Wave power generation uses the rise and fall of the sea level to convert the up and down kinetic energy of waves into axial motion using an energy conversion device, and then converts it into electrical energy. The wave power generation device 300 according to the present invention is configured without being limited by restrictions such as the installation location or water depth of the device, unlike the existing wave power device.

The principle of wave power generation performed in the present invention is that when the sea level moves up and down by the waves generated by the wind, the buoy 330 moves up and down by buoyancy, and the pressure is applied to the piston of the hydraulic cylinder 326. By compressing hydraulic oil through movement, a method of generating power by operating the hydraulic motor 350 with the compressed hydraulic oil is used. Here, the condition that the piston of the hydraulic cylinder 326 can operate must satisfy the following equation:

S x P < V - G

In the above formula,

S is the piston cross-sectional area,

P is the set pressure,

V is the buoyancy force,

G is the weight of the buoy.

The diameter and length of the hydraulic cylinder 326 satisfying the above conditions, the set pressure, the size, weight, and buoyancy of the buoy 330 are determined in consideration of several variables, and this determination is determined by the total wave power facility capacity, It is an important matter that determines economic efficiency and competitiveness.

Among the wave power generation device 300 according to the present invention, the wave power generation unit 310, as shown in FIG. 19, has a plurality of sub-frame 202 or sub-frame reinforcement channel 210 in the form of hanging from the bottom.

The wave power generation unit 310, as shown in FIG. 14, is a hydraulic cylinder fixing bracket 314 that is bolted to the lower surface of the sub-frame 202 or the sub-frame reinforcement channel 210; A plurality of buoy guider fixing angles 315 fixed to the hydraulic cylinder fixing bracket 314; First, second, third buoy guider brackets (319a, 319b, 319c) coupled to the buoy guider fixing angle 315; One side is coupled to the hydraulic cylinder fixing bracket 314 by a buffer spring, the other side is a hydraulic cylinder 326 coupled to the second buoy guider bracket (319b); a plurality of buoy guiders 327 coupled to the second and third buoy guider brackets 319b and 319c; and a buoy 330 coupled to the lower end of the buoy guider 327 .

15 is a bottom view of the hydraulic cylinder fixing bracket 314 sequentially from above; Hydraulic cylinder fixing bracket 314, buoy guider fixing angle 315, and three buoy guider brackets (319a, 319b, 319c) is an elevation view of the combined state; and a plan view of the buoy guider brackets 319a, 319b, 319c.

The hydraulic cylinder fixing bracket 314 is, as shown in detail in the plan view of FIG. 15, a plurality of bolt fixing holes 311 formed to be bolted to the lower surface of the sub-frame 202 or the sub-frame reinforcement channel 210, buoy guider A plurality of buoy guider angle fixing grooves 312 formed so that the fixing angle 315 is inserted and welded, and a hydraulic cylinder buffer spring fixing groove 313 in the center.

Four buoy guider fixing angles 315 are inserted and welded into the angle fixing groove 312 of the hydraulic cylinder fixing bracket 314, and extending from the hydraulic cylinder fixing bracket 314 by a certain length, and the first and second 2 and 3 are fixed by bolts to the guider brackets 319a, 319b, and 319c of the third buoy (refer to the upper figure of FIG. 16).

The first buoy guider bracket 319a, as shown in detail in the figure below of FIG. 16, has four rounded conical ends, and four buoy guider holes through which the buoy guider 327 is inserted and penetrated at each conical end. (316). In addition, the first buoy guider bracket 319a has a hydraulic cylinder through hole 317 in the center thereof, and two slits 317a are formed by a predetermined length on both sides of the through hole 317 in the radial direction. The two slits 317a, the hydraulic oil inlet pipe 324 and the hydraulic oil outlet pipe 325 of the hydraulic cylinder 326 shown in FIG. 14 when assembling the hydraulic cylinder 326 are the first buoy guider bracket 319a. function to pass through.

The first, second, and third buoy guider brackets 319a, 319b, and 319c have a 'L'-shaped groove 318 to be bolted to the buoy guider fixing angle 315. 15 and 16 show a state in which the buoy guider fixing angle 315 is joined to the bracket.

14 and 17, one side of the hydraulic cylinder 326 is fixed by a buffer spring 320 coupled to the buffer spring fixing groove 313 of the hydraulic cylinder fixing bracket 314, and the other side is It is fixed to the fixing plate 321 attached to the second buoy guider bracket 319b. The hydraulic cylinder 326 is inserted through the hydraulic cylinder through-hole 317 of the first buoy guider bracket 319a, and the hydraulic cylinder shaft 322 passes through the second and third buoy guider brackets 319b and 319c. Then, it is coupled to the buoy 330 . In addition, a hydraulic oil inlet pipe 324 and a hydraulic oil outlet pipe 325 are provided at the upper portion of the hydraulic cylinder 326, and a check valve 323 is provided in the hydraulic oil inlet pipe 324 and the hydraulic oil outlet pipe 325, respectively. .

The four buoy guiders 327 coupled to the upper outer surface of the buoy 330 are buoy guider holes 316 of the second and third buoy guider brackets 319b and 319c to guide the up and down movement of the buoy 330 . After being inserted into the upper outer surface of the buoy 330 is coupled.

14, the second buoy guider bracket (319b) above and below the third buoy guider bracket (319c) is a stopper (327) on the buoy guider (327) to limit the vertical movement of the buoy 330. 328) respectively.

14 and 17, the other side of the buoy guider shaft 327a and the hydraulic cylinder shaft 322, one side of which is embedded in the buoy 330, has five flanges ( 329) is formed.

As shown in detail in FIG. 17, the buoy 330 has a cylindrical shape and the upper part is made of a waste plastic melt 331, and the lower part is made of styrofoam 332 and a low-density polyester material with a styrofoam protective case 333. is done It is preferable to embed the buoy guider shaft 327a, which is a member for connecting the hydraulic cylinder shaft 322 and the buoy guider 327 with the buoy 330, in the waste plastic melt 331.

With reference to FIGS. 14 and 18 , the hydraulic oil compression process of the hydraulic cylinder 326 by raising the buoy 330 will be described. When the buoy 330 rises by the waves, four buoy guiders 327 and hydraulic cylinder shaft 322 connected to the top of the buoy 330 rise together, at this time, three buoy guider brackets 319a on the buoy 330. , 319b, 319c) serves to guide the buoy 330 and the hydraulic cylinder shaft 322 from shaking left and right. And the guider fixing angle 315 serves to fix the hydraulic cylinder fixing bracket 314 and three buoy guider brackets (319a, 319b, 319c).

Hereinafter, a process of generating wave power according to the present invention will be described with reference to FIG. 13 .

When the wave rises and the buoy 330 moves up and down, the piston of the hydraulic cylinder 326 moves up and down, whereby the hydraulic oil in the hydraulic cylinder 326 is compressed. The hydraulic oil compressed in the individual hydraulic cylinders 326 is sent to the hydraulic oil pressure tank 340 , and the hydraulic oil maintains a high pressure while compressing the air in the hydraulic oil pressure tank 340 . The compressed hydraulic oil operates the hydraulic motor 350 to generate power in the generator 360 . The hydraulic oil that operates the hydraulic motor 350 is moved to the atmospheric hydraulic oil storage tank 370, and the hydraulic oil in the atmospheric hydraulic oil storage tank 370 is introduced into each hydraulic cylinder 326 and then the hydraulic cylinder 326 by the waves. ) to recycle. The inflow and outflow of hydraulic oil in the hydraulic cylinder 326 is made by a check valve 323 installed in the hydraulic oil inlet pipe 324 and the hydraulic oil outlet pipe 325 and operated automatically.

The complex renewable energy production system according to the present invention is a wind power generator 400 installed at the four corners of the floating offshore platform 200 and the self-floating offshore platform 200a and the offshore platform 200a. It includes a plurality of photovoltaic panels 500 (see FIG. 21) to be installed. Since the wind power generator 400 and the photovoltaic panel 500 are known, a detailed description thereof will be omitted.

The hydraulic oil pressure tank 340 , the hydraulic motor 350 , the generator 360 , the atmospheric hydraulic oil storage tank 370 , etc. may be installed on the ship, and in addition to various control facilities and other necessary facilities, for example, an electric storage facility (ESS). Production facilities, substations, etc. can be installed in the control center (6) building on the ship.

The electrical energy produced by the three complex renewable energies of the present invention, wave power, wind power, and solar power generation, requires a process of integrating them. This is because the produced electric energy is divided into alternating current and direct current by energy source.

22, the wave power generator 300 and the wind power generator 400 both generate alternating current electricity, but the frequency is different, so the frequency must be adjusted using the synchronous inverter 3, and the solar panel 500 ) is direct current, so it must be converted into alternating current having the same frequency with the synchronous inverter (3). This integrated electricity is used for various purposes through the transformer 5 . That is, it can be used as power for offshore platforms, sold as power using an undersea power transmission line, or used as a power source for facilities that electrolyze into hydrogen (H ₂ ) and oxygen (O ₂ ) using seawater. can envision a business.

In the above, even though all components constituting the embodiment of the present invention have been described as being combined or operated in combination, the present invention is not necessarily limited to this embodiment. That is, within the scope of the object of the present invention, all the components may operate by selectively combining one or more.

In addition, terms such as "include", "compose" or "have" described above mean that the corresponding component may be inherent unless otherwise stated, so excluding other components Rather, it should be construed as being able to include other components further. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1: sea level 2: AC/DC converter
3: DC/AC synchronous inverter 4: Electricity storage facility (ESS)
5: Transformer 6: Control Center
100: abandoned ship
100a: central part
200: abandoned ship floating offshore platform
200a: Self-Floating Offshore Platform
201: main frame 202: minor frame
203: secondary submersible pipe 204: main submersible pipe
205a: main frame connection bracket 205b: main water pipe connection bracket
206: main frame support column 207: fixed tower
208: fixed wire 209: underwater reinforcement pole
210: sub-frame reinforcement channel 211: support pole fixing wire
220: ballast water room 221: bulkhead
222: air pressure pipe 223: air exhaust pipe
224: seawater discharge/suction pipe 225a, 225b, 225c: solenoid valve
300 : wave power generator
310: wave power unit 311: bolt fixing hole
312: angle fixing groove 313: buffer spring fixing groove
314: hydraulic cylinder fixing bracket 315: buoy guider fixing angle
316: buoy guider hole 317: hydraulic cylinder through hole
317a: slit 318: 'L' shaped groove
319a, 319b, 319c: 1st, 2nd and 3rd buoy guider brackets
320: buffer spring 321: fixing plate
322: hydraulic cylinder shaft 323: check valve
324: hydraulic oil inlet pipe 325: hydraulic oil outlet pipe
326: hydraulic cylinder 327: buoy guider
327a: buoy guider axis 328: stopper
329: flange 330: buoy
331: waste plastic melt 332: Styrofoam
333; Styrofoam protective case 340: hydraulic oil pressure tank
350: hydraulic motor 360: generator
370: atmospheric pressure hydraulic oil storage tank
400 : wind generator
500 : solar power panel

Claims (16)

Abandoned ship (100);
As a floating offshore platform 200 that is symmetrically installed on the left and right sides of the abandoned ship 100,
A plurality of lattice-type main frames 201 extending vertically from both left and right sides of the abolished ship 100 by a predetermined length and coupled in parallel to each other in the horizontal and vertical directions,
A plurality of sub-submersible pipes 203 and the plurality of sub-submersible pipes 203 extended by a predetermined length in parallel with the main frame 201 from both left and right sides of the closed ship 100 under the main frame 201 and the plurality of sub sub-submersible pipes 203 Submersible pipes (203, 204) consisting of a main submersible pipe (204) coupled to the outer end of the
A closed ship floating offshore platform 200 having a plurality of main frame support columns 206 connecting between the main frame 201 and the underwater pipes 203 and 204; and
a plurality of wave power units 310,
A hydraulic oil pressure tank 340 for storing hydraulic oil in a compressed state by compression in the hydraulic cylinder 326 of the wave power generation unit 310,
A hydraulic motor 350 operated by the compressed hydraulic oil in the hydraulic oil pressure tank 340,
A generator 360 that generates electricity by the hydraulic motor 350,
Wave power generation device 300 having an atmospheric pressure hydraulic oil storage tank 370 for storing hydraulic oil in a normal pressure state after power generation; A complex renewable energy production system comprising a. The method of claim 1,
In order to give the structural stability of the offshore platform 200, the upper end of the plurality of fixed towers 207 installed on the deck of the abandoned ship 100 and the main submersible pipe 204 are connected with a plurality of fixed wires 208 A complex renewable energy production system characterized by. The method of claim 1,
Instead of the closed ship floating offshore platform 200, a self-floating offshore platform 200a is used, and the self-floating offshore platform 200a is,
A plurality of lattice-type main frames 201 coupled to extend by a predetermined length in both left and right vertical directions from the central portion 100a;
A plurality of sub-frames 202 coupled in parallel to each other in the transverse and longitudinal directions of the grid-type main frame 201;
A plurality of sub-submersible pipes 203 and the plurality of sub-submersible pipes 203 extended by a predetermined length parallel to the main frame 201 from both left and right sides of the central part 100a under the main frame 201, and the plurality of sub sub-submersible pipes 203 ) Submersible pipes (203, 204) consisting of a main submersible pipe (204) coupled to the outermost sub submersible pipe (203) in the longitudinal direction of the outer end and the central part;
A plurality of main frame support pillars 206 connecting between the main frame 201 and the underwater pipes (203, 204); and
Composite renewable energy production system, characterized in that it has an underwater reinforcement column 209 connecting the main frame 201 from the four corners and the central part 100a of the main submersible pipe 204 and the sub submersible pipe 203 on both sides in the longitudinal direction. . 4. The method of claim 1 or 3,
A composite renewable energy production system, characterized in that the sub-submersible pipe 203 and the main sub-submersible pipe 204 are cylindrical steel pipes to increase buoyancy. 4. The method of claim 1 or 3,
A composite renewable energy production system, characterized in that the sub-frame reinforcement channel 210 is diagonally coupled to each other at the coupling part of the main frame 201 and the sub-frame 202 or the coupling part between the sub-frames 202. 4. The method of claim 3,
Except for the central portion (100a), from the middle part of the main frame support column (206) or the underwater reinforcement column (209) to the adjacent main frame support column (206) or the underwater reinforcement column (209) diagonally to the lower portion of the support column Composite renewable energy production system, characterized in that the fixed wire 211 is coupled. 4. The method of claim 1 or 3,
A ballast water chamber 220 by a certain length at both ends of the outermost main submersible pipe 204 so that the closed ship floating offshore platform 200 or self-floating offshore platform 200a can maintain an appropriate height from the sea level (1). ) A complex renewable energy production system, characterized in that it is provided. 8. The method of claim 7,
The ballast water chamber 220 is connected to the bulkhead 221 and the hydraulic oil pressure tank 340 formed at a predetermined length in the main water pipe 204 to pressurize air to pressurize air in the upper part of the ballast water chamber 220 . It includes a pipe 222, an air discharge pipe 223 connected to an air pressure pipe 222 to suck seawater, and a seawater discharge/suction pipe 224 installed at the bottom of the main submersible pipe 204, and the air discharge pipe (223), the seawater discharge/suction pipe 224, and the air discharge pipe 223 and the hydraulic oil pressure tank 340, respectively, the solenoid valves (225a, 225b, 225c) are respectively provided Renewable energy production system. 4. The method of claim 1 or 3,
In order to ensure structural stability through weight balance, the complex renewable energy production system, characterized in that the anchors are installed at the four corners of the floating offshore platform 200 or the self-floating offshore platform 200a of the abandoned ship. The method of claim 1,
The wave power unit 310 is,
A plurality of bolt fixing holes 311 formed to be bolted to the bottom surface of the sub-frame 202 or the sub-frame reinforcement channel 210, a plurality of buoy guider angle fixing grooves 312 formed so that the buoy guider fixing angle 315 is inserted and welded ), and a hydraulic cylinder fixing bracket 314 having a hydraulic cylinder buffer spring fixing groove 313 in the center;
A plurality of buoy guiders are inserted and welded into the angle fixing groove 312 of the hydraulic cylinder fixing bracket 314 and extended by a predetermined length therefrom and fixed to the first, second, and third buoy guider brackets 319a, 319b, 319c. Fixed angle 315;
A plurality of buoy guider holes 316 formed in the rounded conical end so that the buoy guider 327 is inserted and penetrated, the hydraulic cylinder through hole 317 formed in the center, and the through hole 317 by a certain length on both sides in the radial direction First, second, and third buoy guider brackets 319a, 319b, 319c having two slits 317 formed, and a 'L'-shaped groove 318 to be bolted to the buoy guider fixing angle 315;
One side is fixed by a buffer spring 320 coupled to the buffer spring fixing groove 313 of the hydraulic cylinder fixing bracket 314, and the other side is fixed to the fixing plate 321 attached to the second buoy guider bracket 319b and , the hydraulic cylinder 326 is inserted through the hydraulic cylinder through hole 317 of the first buoy guider bracket 319a, and the hydraulic cylinder shaft 322 passes through the second and third buoy guider brackets 319b and 319c. and coupled to the buoy 330, the hydraulic oil inlet pipe 324 and the hydraulic oil outlet pipe 325 each having a check valve 323 on the upper part of the hydraulic cylinder 326;
A plurality of buoy guiders inserted into the buoy guider holes 316 of the second and third buoy guider brackets 319b and 319c to guide the up and down movement of the buoy 330 and coupled to the upper outer surface of the buoy 330 ( 327); and
a buoy 330 coupled to the lower end of the buoy guider 327;
Renewable energy production system comprising a. 11. The method of claim 10,
In order to limit the vertical movement of the buoy 330, the second buoy guider bracket 319b is positioned above the third buoy guider bracket 319c, and a stopper 328 is installed on the buoy guider 327 to be positioned below the bracket 319c, respectively. Renewable energy production system, characterized in that. 12. The method of claim 11,
In order to easily attach and detach the buoy 330, a plurality of flanges 329 are formed on the other side of the buoy guider shaft 327a and the hydraulic cylinder shaft 322, one side of which is embedded in the buoy 330. Renewable energy production system. 11. The method of claim 10,
The buoy 330 has a cylindrical shape, and the upper part is made of a waste plastic melt (331), and the lower part is made of Styrofoam (332) and the Styrofoam protective case (333). 4. The method of claim 1 or 3,
Composite renewable energy production system, characterized in that the wind power generator 400 is installed at the four corners of the closed ship floating offshore platform 200 and the self floating offshore platform 200a. 4. The method of claim 1 or 3,
A complex renewable energy production system, characterized in that a plurality of photovoltaic panels 500 are installed on the floating offshore platform 200 and self-floating offshore platform 200a. The method of claim 1,
The alternating current electricity produced from the wave power generator 300 and the wind power generator 400 matches the frequency through the AC/DC converter 2 and the DC/AC synchronous inverter 3, and is produced by the photovoltaic panel 500 The combined renewable energy production system, characterized in that the DC electricity can be used for various purposes after being collected by a transformer (5) through an electricity storage facility (ESS) (4) and a synchronous inverter (3).

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