KR20240002529A - Assembly facility for floating solar power generation system - Google Patents

Abstract

The present invention relates to a water solar power generation device assembly facility. More specifically, a water solar power generation device can be assembled on the water, and after assembly is completed, the solar power generation device can be easily and conveniently floated and installed on the water without any additional equipment. This relates to solar power generation device assembly facilities.
The floating solar power generation device assembly facility according to the present invention can install the solar power generation device by assembling the solar power generation device on a barge on the water and immediately floating it on the water.

Description

Assembly facility for floating solar power generation system}

The present invention relates to a water solar power generation device assembly facility. More specifically, a water solar power generation device can be assembled on the water, and after assembly is completed, the solar power generation device can be easily and conveniently floated and installed on the water without any additional equipment. This relates to solar power generation device assembly facilities.

Recently, floating solar power generation systems installed on the water surface of rivers, lakes, reservoirs, dams, etc. can efficiently utilize the land by using idle water surface areas, and there are fewer restrictions on slope and shading compared to solar power generation on land. The low temperature has a cooling effect that prevents overheating of the solar module, which has the advantage of relatively high power generation efficiency per area.

In general, a water floating solar power generation system includes a buoyant body with buoyancy, a frame unit that connects the buoyant bodies and where solar modules are installed and fixed, an anchor fixed to the seabed for mooring the frame, and an anchor and frame unit. It can be composed of connecting wires, etc.

In the case of floating solar power generation systems, unlike solar power generation devices on land where solar panels can simply be supported on the ground, it takes considerable cost, time, and manpower to complete assembly and installation on land and then move them to the water. There is.

Republic of Korea registered patent 10-1852879 Republic of Korea Public Patent No. 10-2013-0010596 Republic of Korea Public Patent No. 10-2016-0001553

The present invention is intended to solve the above-described conventional problems, and provides a floating solar power generation device assembly facility that can install the solar power generation device by assembling it on a barge on the water and then immediately floating it to the water. There is a purpose.

The floating solar power generation device assembly facility according to the present invention for achieving the above object includes a barge; A transfer device including a plurality of rail units installed on a barge at regular intervals and arranged in parallel with each other, and a plurality of transfer truck units installed on the rail units to be able to move along the rail units; A solar power generation device including a plurality of sub-assemblies mounted or placed on the transfer cart, a connection part connecting the sub-assemblies to each other, a support part installed on the connection part, and a solar cell module installed on the support part; It is provided with, and the transfer device is characterized in that it is formed so as to be able to assemble the solar power generation device on the barge and then launch the assembled solar power generation device onto the water.

The connection unit includes a first connection frame and a second connection frame installed in parallel with the rail unit on opposite sides of the subassembly to connect the subassemblies mounted on transfer carts on each rail unit to each other, The support portion has a direction crossing the connecting portions so as to connect support frames installed on each of the first and second connecting frames on the upper side of the subassembly, the support frames of one connection portion, and the support frames of adjacent connecting portions. It is extended and installed and includes a mounting frame on which the solar power generation module is fixed.

The rail unit includes first to third rail members spaced apart from each other at regular intervals and arranged in parallel with each other, and the transfer cart unit has first moving wheels to be able to move along the first to third rail members. It is characterized by having a third moving wheel installed.

The rail unit includes a first connecting member connecting the first rail member to the third rail member to maintain the gap between the first rail member and the third rail member, and the transfer device is configured to provide a It is characterized in that it includes a second connecting member connecting the rail parts to each other to maintain the gap between the parts.

The solar power generation device is installed across the connection parts to connect the connection parts, and further includes a footbridge formed to enable a worker to walk.

The end side of the bridge portion is characterized in that it is further provided with a rotation connection portion formed so as to be rotatably connected to the end side of the bridge portion of another adjacent solar power generation device.

The floating solar power generation device assembly facility according to the present invention can install the solar power generation device by assembling the solar power generation device on a barge on the water and immediately floating it on the water.

Figure 1 is a perspective view of a floating solar power generation device assembly facility according to the present invention.
Figures 2 and 3 are perspective views showing the transfer device and solar power generation device of the floating solar power generation device assembly facility according to the present invention.
Figure 4 is an enlarged perspective view of the transfer device and solar power generation device of the floating solar power generation device assembly facility according to the present invention.
Figure 5 is a perspective view showing the bridge portion of the floating solar power generation device assembly facility according to the present invention.
Figure 6 is a plan view illustrating the operation of the floating solar power generation device assembly facility according to the present invention.

Hereinafter, a floating solar power generation device assembly facility according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

1 to 6 show a floating solar power generation device assembly facility (1) according to the present invention. Referring to Figures 1 to 6, the floating solar power generation device assembly facility (1) according to the present invention can be configured to include a barge (100), a transfer device (200), and a solar power generation device (300). there is.

The barge 100 may include a buoyancy assembly 110, a frame 120, and a deck portion 130.

The buoyancy assembly 110 includes a main body with an accommodating space formed on the inside and an open top, a cover that is coupled to the upper part of the main body to seal the accommodating space, and is inserted into the accommodating space to occupy the accommodating space and has a buoyancy space inside. Each may include a plurality of formed buoyancy bodies.

The frame 120 is installed on the buoyancy assemblies 110 to connect the buoyancy assemblies 110 to each other.

The deck portion 130 is installed on the frame 120, and includes a deck plate with a drain hole through which water can drain, and allows water on the deck plate to be discharged onto the water and prevents water from flowing from the water onto the deck plate. It can be configured to include an inflow prevention part installed in the drain hole to prevent inflow.

The transfer device 200 is configured to assemble the solar power generation device 300 on the barge 100 and then launch the assembled solar power generation device 300 onto the water.

For this purpose, the transfer device 200 may be configured to include a plurality of rail units 210 and a transfer truck unit 250.

The rail units 210 are arranged at regular intervals on the barge 100 and are arranged side by side with each other. The rail units 210 each include a first rail member 211 to a third rail member 213. The first rail member 211 to the third rail member 213 are spaced apart from each other at a certain interval and are arranged side by side. Each of the first rail member 211 to the third rail member 213 has a structure in which the lower part and both sides in the width direction are closed and the upper part is open, allowing the wheel member to roll and move in a straight line along the longitudinal direction.

The first rail member 211 and the third rail member 213 are arranged to be spaced apart at an interval corresponding to the length of the buoyancy body so as to be located on both sides in the longitudinal direction of the buoyancy body, and the second rail member 212 is the first rail. It is disposed between the member 211 and the third rail member 213.

Each rail unit 210 has a first rail member 211 to third rail members 213 that connects the first rail member 211 to third rail members 213 to maintain the gap between the first rail member 211 and the third rail member 213. It is provided with a connecting member (215). The first connecting member 215 is installed between the first rail member 211 and the second rail member 212 and between the second rail member 212 and the third rail member 213, respectively. The first connection member 215 is installed in a direction crossing the first rail member 211 to the third rail member 213.

In addition, the transfer device 200 is provided with a second connecting member 216 that connects the rail parts 210 to each other to maintain the gap between the rail parts 210. The second connecting member 216 is installed between adjacent rail parts 210, and is installed in a direction crossing the rail parts 210.

The transfer truck unit 250 is installed on the rail unit 210 so that it can move along the rail unit 210. The transfer cart is formed so that the buoyancy body of the solar power generation device 300 can be mounted or placed on the top.

The transfer truck unit 250 moves for the first time to the lower part of the upper plate corresponding to the upper plate on which the buoyancy body of the solar power generation device 300 is mounted or placed and the first rail member 211 to the third rail member 213, respectively. Wheels 251 to 3rd moving wheels 253 are installed. The first to third movable wheels 251 to 253 are each installed on both sides of the transfer cart 250 in the width direction.

The solar power generation device 300 may be configured to include a secondary assembly 310, a connection part 320, a support part 330, and a solar cell module 340.

The secondary assembly 310 is provided in plurality and is mounted or placed on the transfer cart 250.

Each of the sub-assemblies 310 includes a main body with an accommodating space formed on the inside and an open top, a cover that is coupled to the upper part of the main body to seal the accommodating space, and is inserted into the accommodating space to occupy the accommodating space and has a buoyancy force inside. It can be composed of a plurality of subspheres in which space is formed.

The secondary assembly 310 may have the same configuration as the buoyancy assembly 110 of the barge 100 described above, and detailed description thereof will be omitted.

The connecting portion 320 connects the sub-assemblies 310 to each other. The connecting portion 320 is a first connecting portion installed in parallel with the rail portion 210 on opposite sides of the subassembly 310 to connect the subassemblies 310 mounted on the transfer carts on each rail portion 210 to each other. It can be configured to include a connection frame 321 and a second connection frame 322. The first connection frame 321 and the second connection frame 322 integrally connect a plurality of sub-assemblies 310 arranged in the front-back direction. The first connection frame 321 and the second connection frame 322 may be spaced apart at an interval corresponding to the first rail member 211 and the third rail member 213, and may be parallel to each rail portion 210. It is placed.

The support portion 330 is installed on the connection portion 320 and may include a support frame 331 and a mounting frame 335.

The support frame 331 is installed on each of the first connection frame 321 and the second connection frame 322 on the upper side of the buoyancy body, and is a vertical frame 332 to support the solar cell module 340 at an angle to one side. It can be configured to include an inclined frame 333 and a support frame 334.

The vertical frame 332 consists of a pair and is installed vertically on each of the first connection frame 321 and the second connection frame 322.

The inclined frame 333 consists of a pair, and is installed at an angle toward the top of the vertical frame 332 on each of the first connection frame 321 and the second connection frame 322, which are spaced a certain distance from the vertical frame 332. . The inclined frame 333 is formed to be longer than the vertical frame 332.

The support frame 334 has one side installed on the vertical frame 332 to connect the end of the vertical frame 332 and the inclined frame 333 installed on the first connection frame 321, and the other side is connected to the inclined frame 333. is installed in

The mounting frame 335 is composed of a pair, and has a direction crossing the connection parts 320 to connect the support frames 331 of one side connection part 320 and the support frames 331 of the adjacent connection parts 320 to each other. extended and installed. And, the solar cell module 340 is fixed on the mounting frame 335.

One of the mounting frames 335 is installed so as to span each point where the end side of the inclined frame 333 of the first connection frame 321 and one end of the support frame 334 connect and intersect, and the other The thin second connecting frame 322 is installed so as to span each point where the end of the vertical frame 332 and the other end of the support frame 334 are connected and intersect. A pair of mounting frames 335 are arranged side by side to support the upper and lower sides of the solar cell module 340, respectively.

The connection part 320, the support part 330, the support part 330, and the rail part 210 and the support part 330 described above can all be composed of 'C' beams or 'C' channels. In addition, the first connection frame 321 and the second connection frame 322 can be bolted to the vertical frame 332 and the inclined frame 333, respectively, and the vertical frame 332 and the inclined frame 333 are supported. Each can be bolted to the frame 334.

A plurality of solar cell modules 340 are installed adjacent to each other along the mounting frame 335. The solar cell module 340 is arranged parallel to the rail portion 210 and the connection portion 320, and is arranged in a direction crossing the rail portion 210 and the connection portion 320.

The solar power generation device 300 is installed on the connection portion 320 to enable movement to other adjacent solar power generation devices 300 and for workers or managers to walk and move around the solar cell module 340. . The bridge portion 350 is installed to cross the connecting portions 320 to connect the connecting portions 320 to each other.

In more detail, the bridge unit 350 may include a leg frame 351 and a footrest 353.

The leg frames 351 are composed of a pair, spaced apart from each other at a certain distance, arranged in parallel with each other, and extended and arranged in a direction intersecting the connection part 320 and the rail part 210.

The footrest 353 is connected and fixed on both sides in the width direction to the upper side of a pair of leg frames 351, and extends along the leg frames 351. Water drain holes of various shapes are formed in the footrest 353.

Meanwhile, the bridge portion 350 is further provided with a rotation connection portion that can be rotatably connected to an end of the bridge portion 350 of another adjacent solar power generation device 300.

As shown in this embodiment, the rotary connection unit is located on one side of the solar power generation device 300, which consists of six sub-assemblies 310, a connection part 320, a support part 330, and a solar cell module 340. It is intended to connect solar power generation devices 300 on different adjacent sides to each other, and may be configured to include a rotation bracket 356 and a rotation fastener.

The rotation bracket 356 may include a fitting portion 357 and a rotation plate 358.

The fitting portion 357 has a fitting groove formed on one side so that the end side of the leg frame 351 can be inserted. The fitting portion 357 and the leg frame 351 may be connected by bolting.

The rotating plate 358 extends a certain length from the fitting portion 357, has circular edges, and has a fastening hole 359 in the center.

The rotary fastener rotatably connects and couples the two-side rotary pieces 358 installed at the ends of the two-side footbridges 350, and can be composed of a bolt fastened to penetrate the fastening hole and a nut fastened to the end of the bolt. there is.

Damage can be reduced by allowing the solar power generation devices 300 on both sides to move up and down with each other when swells or waves occur at sea through the rotating connection as described above.

The floating solar power generation device assembly equipment according to the present invention described above has been described with reference to the attached drawings, but these are merely illustrative, and those skilled in the art will be able to make various modifications and other equivalent implementations. You will understand that an example is possible.

Therefore, the true scope of technical protection of the present invention should be determined only by the technical spirit of the attached claims.

1: Assembly equipment
100: barge
110: Buoyancy assembly
120: frame
130: deck part
200: transfer device
210: rail part
250: Transfer truck unit
251: 1st moving wheel
252: Second moving wheel
253: Third moving wheel
300: Solar power generation device
310: Substructure
320: connection part
330: support part
340: solar cell module
350: Ministry of Taoism

Claims (6)

barge;
A transfer device including a plurality of rail units installed on a barge at regular intervals and arranged in parallel with each other, and a plurality of transfer truck units installed on the rail units to be able to move along the rail units;
A solar power generation device including a plurality of sub-assemblies mounted or placed on the transfer cart, a connection part connecting the sub-assemblies to each other, a support part installed on the connection part, and a solar cell module installed on the support part; Equipped with
The transfer device is a floating solar power generation device assembly facility, characterized in that it is formed to be able to assemble the solar power generation device on the barge and then launch the assembled solar power generation device onto the water. According to paragraph 1,
The connection unit includes a first connection frame and a second connection frame installed in parallel with the rail unit on opposite sides of the subassembly to connect the subassemblies mounted on transfer carts on each rail unit to each other,
The support portion crosses the connection portions to connect support frames installed on each of the first connection frame and the second connection frame on the upper side of the subassembly, the support frames of one side connection portion, and the support frames of adjacent connection portions. A floating solar power generation device assembly facility that is extended and installed in one direction and includes a mounting frame to which the solar power generation module is fixed. According to paragraph 1,
The rail unit includes first to third rail members spaced apart at regular intervals and arranged in parallel with each other,
The floating solar power generation device assembly equipment, characterized in that the transfer truck unit is installed with first to third moving wheels so that it can move along the first to third rail members. According to paragraph 1 or 3.
The rail unit includes a first connecting member connecting the first rail member to the third rail member to maintain the gap between the first rail member and the third rail member,
The transfer device is a floating solar power generation device assembly facility, characterized in that it includes a second connection member connecting the rail parts to each other to maintain the gap between the rail parts. According to paragraph 1,
The solar power generation device is installed to cross the connection parts to connect the connection parts, and further includes a footbridge formed so that a worker can walk. According to clause 5,
Floating solar power generation device assembly equipment, characterized in that the end side of the bridge unit is further provided with a rotation connection part that can be rotatably connected to the end side of the bridge unit of another adjacent solar power generation device.

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