KR102501451B1 - Integral marine photovoltaic apparatus - Google Patents

Abstract

The present invention includes a plurality of marine photovoltaic power generation floating blocks arranged in a line, in which solar cells are coupled and floating on the sea; A mounting line disposed along the lower portion of the plurality of marine solar power generation floating blocks to moor the plurality of marine solar power generation floating blocks to each other and coupled to each of the marine solar power generation floating blocks; It relates to an integrated marine photovoltaic device, characterized in that it comprises a crossing line coupled while crossing the ground line.

Description

Integrated marine solar power generation device {INTEGRAL MARINE PHOTOVOLTAIC APPARATUS}

The present invention relates to solar power generation technology installed in the ocean.

Photovoltaic power generation devices are being installed beyond flat land, on lakes and reservoirs, and even on wide seas. When a photovoltaic device is installed on the sea, a structure for floating the photovoltaic panel on water is generally required.

Since the structure supporting these solar panels resists external forces caused by strong waves, tidal currents, typhoons, etc., the structure itself may be damaged or the connection part connecting the structures may easily fail.

In order to prevent this problem, a rigid body having greater rigidity and heavier weight may be used, but since the structure itself must float on the sea, there is a limit to increasing the rigidity or weight.

On the other hand, the cost of the structure cannot be ignored considering the scale of the photovoltaic power generation device, which is typically installed from several kilowatts to megawatts. That is, as a complicated structure is added to the structure and the stiffness increases, the cost also increases in proportion thereto.

Accordingly, the inventor of the present invention has completed the present invention after long research and trial and error for a method for stably operating a solar power generation device at sea.

The present invention is a device for generating solar power at sea, including a marine solar power generation floating block in which solar cells are integrally combined and a flexible cable for mooring the marine solar power generation floating block to each other, even against external forces such as waves. It is intended to provide an integrated marine solar power generation device that can withstand well.

In addition, in order to prevent the marine solar power generation floating block in which the solar cell is integrally combined from being conducted by external force, flexible cables are formed to replace each other under the marine solar power generation floating block. To provide an integrated marine solar power generation device. .

Meanwhile, other unspecified objects of the present invention will be additionally considered within the scope that can be easily inferred from the following detailed description and effects thereof.

According to an embodiment of the present invention, a plurality of marine solar power generation floating blocks arranged in a row, in which solar cells are coupled and floating on the sea;

A mounting line disposed along the lower portion of the plurality of marine solar power generation floating blocks to moor the plurality of marine solar power generation floating blocks to each other and coupled to each of the marine solar power generation floating blocks;

Characterized in that it comprises an intersection line combined while intersecting the reference line,

An all-in-one marine solar power generation device is provided.

According to one embodiment of the present invention, the crossing line may cross the ground line at the lower part of each floating block of marine solar power generation.

According to one embodiment of the present invention, a guide portion capable of accommodating the mounting line is formed at the bottom of the marine solar power generation floating block,

The bearing line may be coupled to both ends of the marine photovoltaic power generation floating block and a first coupling member while being accommodated in the guide unit.

According to one embodiment of the present invention, a pair of first frames to which both ends of the mounting line are coupled;

A pair of second frames coupled to both ends of the crossing line may be further included.

According to one embodiment of the present invention, both ends of the pair of first frames and both ends of the pair of second frames such that the pair of first frames and the pair of second frames form a quadrangular shape. They can be coupled to each other by floating couplings floating in the sea.

According to one embodiment of the present invention, the floating coupling part,

The first frame or the second frame may be coupled to each other by a first coupling member.

According to one embodiment of the present invention, it may further include an anchoring means coupled to the floating coupling part.

According to one embodiment of the present invention, the anchoring means may include an anchoring device penetrated into the seabed ground.

According to one embodiment of the present invention, the anchoring means,

a connection cable having one end connected to the floating coupler and facing the sea floor;

A center of gravity connected to the other end of the connection cable may be included.

According to one embodiment of the present invention, the center of gravity,

It may include a water receptor whose structure is maintained by the pressure of water contained therein.

The integrated marine solar power generation device according to the present invention includes a marine solar power generation floating block to which solar cells are integrally coupled and a flexible cable for mooring the marine solar power generation floating blocks to each other, thereby resisting external forces such as waves. It will hold up well without breaking.

In addition, through a structure in which flexible cables are formed to replace each other below the marine solar power generation floating block, the marine solar power generation floating block in which the solar cells are integrally coupled is not conducted to external force.

On the other hand, even if the effects are not explicitly mentioned here, it is added that the effects described in the following specification expected by the technical features of the present invention and their provisional effects are treated as described in the specification of the present invention.

1 is a view showing a marine solar power generation floating block to which solar cells are integrally coupled according to an embodiment of the present invention and a mounting line supporting the marine solar power generation floating block.
2 is a view showing a lower portion of a marine photovoltaic power generation floating block to which solar cells are integrally coupled according to an embodiment of the present invention.
3 is a view showing a marine solar power generation floating block to which solar cells are integrally coupled according to an embodiment of the present invention, and a support line and an intersection line supporting the marine solar power generation floating block.
FIG. 4 is a view showing that a reference line and an intersection line are combined according to an embodiment of the present invention.
5 is a view of a marine photovoltaic power generation floating block to which solar cells are integrally coupled according to an embodiment of the present invention is arranged in a grid, and a mounting line, an intersection line, a first frame, a second frame, and a floating block supporting it are arranged. It is a drawing showing the coupling part.
6 is a view showing a first frame according to a material according to an embodiment of the present invention and a coupling between the first frame and the floating coupling part.
7 is a view showing a photovoltaic device in which an anchoring means is coupled according to an embodiment of the present invention.
8 is a view showing anchoring means different from the anchoring means of FIG. 7 according to an embodiment of the present invention.
It is revealed that the accompanying drawings are illustrated as references for understanding the technical idea of the present invention, and thereby the scope of the present invention is not limited thereto.

In the description of the present invention, if it is determined that a related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Hereinafter, an embodiment of an integrated marine photovoltaic device according to the present invention will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and Redundant descriptions will be omitted.

1 shows a marine solar power generation floating block 100 to which a solar panel GP is integrally coupled according to an embodiment of the present invention and a mounting line 10 supporting the marine solar power generation floating block 100. is the drawing shown.

As shown in FIG. 1 , the integrated marine solar power generation device according to an embodiment of the present invention includes a marine solar power generation floating block 100 integrally coupled with a solar panel GP.

Since the offshore solar power generation floating block 100 needs to float on the sea, it may be made of a material lighter than water. Meanwhile, the marine solar power generation floating block 100 may include a hollow structure with an empty inside to float on the sea. To maintain high buoyancy and safety at sea, it may be formed of a light and durable material, such as polyethylene.

A plurality of solar panels GP may be integrally attached to the upper flat surface of the marine solar power generation floating block 100 . If the solar panel (GP) is integrally attached to the marine solar power generation floating block 100 in advance and manufactured, the installation of the solar panel (GP) integrated marine solar power generation floating block 100 on the sea is very simplified, The marine photovoltaic power generation floating block 100 and the solar panel GP are not well separated by waves or wind. Installation and maintenance costs can be greatly reduced.

A large number of solar panel (GP)-integrated marine solar power generation floating blocks 100 must be installed for solar power generation from several kilowatts to megawatts at sea. A large number of marine solar power generation floating blocks 100 are installed in a grid as shown in FIG. 3 or 5 or 7, and the marine solar power generation floating blocks 100 installed in a grid are connected to each other. will be put on hold

A mounting line 10 is used to connect the marine solar power generation floating blocks 100 arranged in a row to each other. That is, the mounting line 10 is coupled to the lower part of each marine solar power generation floating block 100 along the lower part of the marine solar power generation floating block 100 installed in a row and is spaced apart from the marine solar power generation floating block. (100) are connected to each other. Through this connection, a large amount of electricity is produced while mooring the marine solar power generation floating block 100 in one place.

At this time, the mounting line 10 may include a rope or cable or other various lines or strings. The mounting line 10 connects the marine photovoltaic power generation floating blocks 100 to each other, but must be rigid enough not to be broken by waves or wind.

As the mounting line 10 is formed of a flexible material, it can flow while adapting to the external force, rather than enduring and resisting the external force such as wind or waves. This structure can reduce the fatigue applied to the various connection parts of the marine photovoltaic device as they flow together with waves or wind.

The mounting line 10 is coupled to the lower portion of the marine solar power generation floating block 100, and a guide portion 110 capable of accommodating the mounting line 10 is formed at the lower portion of the marine solar power generation floating block 100. has been

2 is a view showing a lower portion of a marine solar power generation floating block 100 to which a solar panel GP is integrally coupled according to an embodiment of the present invention.

That is, as shown in FIG. 2, the lower part of the marine solar power generation floating block 100 to which the solar panel GP is integrally coupled is provided with a guide part 110 capable of accommodating the mounting line 10 throughout the lower part. formed along the longitudinal direction. The mounting line 10 is accommodated in the guide unit 110, and the mounting line 10 and the marine solar power generation floating block 100 are coupled to each other only at both ends of the marine solar power generation floating block 100.

The guide part 110 may have a semicircular or rectangular cross section depending on the shape of the mounting line 10 . Through the guide part 110, it becomes easy for the mounting line 10 to be seated on the floating block 100 for marine photovoltaic power generation.

The size of the guide part 110 may be formed in consideration of the size of the diameter of the mounting line 10 so that the mounting line 10 can be seated well. It should be formed relatively smaller or larger than the diameter of the carrying line 10. In general, it may be formed with 2/3 to 4/3 of the diameter of the mounting line 10.

At this time, the mounting line 10 and the marine photovoltaic power generation floating block 100 may be coupled by a connecting member RI. For this coupling, a pair of coupling parts 130 are formed at both ends of the marine solar power generation floating block 100, and the connection member RI is connected to the mounting line 10 and the marine solar power generation floating block 100 A pair of coupling parts 130 formed at both ends of are coupled to each other by making them fasten to each other.

Only both ends of the marine photovoltaic power generation floating block 100 are coupled to the mounting line 10, that is, coupled to the mounting line 10 only in the longitudinal direction, and the direction perpendicular to the longitudinal direction is not coupled to the mounting line 10. Therefore, the marine photovoltaic power generation floating block 100 has minimal force to resist the influence of external wind or waves, and can move while adapting to the wind or waves.

In this way, by giving a lot of freedom to the marine solar power generation floating block 100, fatigue caused by repeated loads caused by wind or waves is minimized, and damage is prevented to extend the life of the marine solar power generation floating block 100. be able to

The pair of coupling parts 130 may be metal rings. The connecting member RI may be a metal ring having a screw locking structure. It may be structured like a carabiner. It can be made of a metal material with excellent corrosion resistance in consideration of a high-salinity marine environment.

3 is a marine solar power generation floating block 100 to which a solar panel GP is integrally coupled according to an embodiment of the present invention and a mounting line 10 supporting the marine solar power generation floating block 100 and It is a view showing the intersection line 300.

As shown in FIG. 3, the marine solar power generation floating block 100 to which the solar panel GP is integrally combined is arranged in a lattice, and the marine solar power generation floating block 100 arranged in such a lattice At the lower part of ), the mounting line 10 and the crossing line 300 are installed to cross each other.

The mounting line 10 connects the marine solar power generation floating blocks 100 arranged in a row along the longitudinal direction, but does not restrict the marine solar power generation floating block 100 in the vertical direction of the longitudinal direction. Therefore, the marine solar power generation floating block 100 may be overturned or flow greatly back and forth due to external force. In order to prevent this, the crossing line 300 is installed in the vertical direction of the longitudinal direction of the marine solar power generation floating block 100. It will be.

That is, the intersection line 300 is formed while crossing each other at the bottom of the mounting line 10 and the marine solar power generation floating block 100 to prevent the marine solar power generation floating block 100 from tipping or shaking back and forth. .

At this time, the intersection line 300 is not directly connected to the marine solar power generation floating block 100. As described above, by granting a lot of freedom to the marine solar power generation floating block 100, the marine solar power generation floating block 100 ) is to minimize fatigue caused by repetitive loads applied to the person. Therefore, only the grounding line 10 is coupled to the marine solar power generation floating block 100, and the crossing line 300 intersects the grounding line 10 and is coupled to conduction of the marine solar power generation floating block 100. is to prevent

Through the structure of the mounting line 10 and the crossing line 300, the fatigue applied to the marine solar power generation floating block 100 is reduced and the marine solar power generation floating block 100 is prevented from being overturned.

FIG. 4 is a view showing a combination of a reference line 10 and an intersection line 300 according to an embodiment of the present invention.

The bearing line 10 and the crossing line 300 may be coupled to each other by the second coupling member 310 as shown in FIG. 4 . As described above, the intersection line 300 is not directly coupled to the marine solar power generation floating block 100. The crossing line 300 is combined with the mounting line 10 to prevent the front and rear large shaking or overturning of the marine solar power generation floating block 100.

At this time, the second coupling member 310 may be any coupling member capable of fixing the mounting line 10 and the crossing line 300 to each other. It may be a connecting ring, and various other fastening means may be used.

5 is a view of a marine solar power generation floating block 100 to which a solar panel (GP) is integrally coupled according to an embodiment of the present invention is arranged in a grid, and the mounting line 10 supporting it, the intersection line ( 300), a view showing the first frame 400, the second frame 500 and the floating coupler 600.

As shown in FIG. 5, the ground line 10 and the crossing line 300 cross-coupled at the lower part of the marine solar power generation floating block 100 arranged in a grid form a first frame 400 and a second frame, respectively. Both ends can be constrained by 500.

That is, both ends of the mounting line 10 may be coupled to the pair of first frames 400 , and both ends of the crossing line 300 may be coupled to the pair of second frames 500 .

At this time, the mounting line 10 may be coupled to the first frame 400 so that the marine solar power generation floating block 100 can also flow together with external force such as waves or wind. The crossing line 300 is to prevent the rocking or overturning of the ocean solar power floating block 100, and can be tightly coupled to the second frame 500.

If the intersection line 300 passes through the bottom of the marine solar power generation floating block 100 too loosely or loosely, the marine solar power generation floating block 100 may be overturned or shaken. Therefore, it is preferable that the cross line 300 passes through the bottom of the marine solar power generation floating block 100 in a state where both ends are pulled tight.

The first frame 400 may be a rigid body or made of a flexible material such as the mounting line 10 or the crossing line 300 . By being made of a flexible material, fatigue due to external force is also greatly reduced in the coupling portion between the mounting line 10 and the first frame 400 .

Like the first frame 400, the second frame 500 may also be made of a flexible material. It may be formed from a string, rope, cable, or the like. When the marine photovoltaic power generation floating block 100 moves due to wind or waves, the mounting line 10 also moves accordingly, and the crossing line 300 connected to the mounting line 10 also moves. Eventually, the first frame 400 connected to the mounting line 10 and the second frame 500 connected to the crossing line 300 also flow together with wind or waves, thereby causing damage to the marine solar power generation floating block 100 or connection parts. You can minimize the pressure or fatigue you lose.

The pair of first frames 400 and the pair of second frames 500 may be formed to form a quadrangular shape. That is, the marine photovoltaic power generation floating blocks 100 may be arranged in a grid in a quadrangular shape formed by the first frame 400 and the second frame 500 .

The pair of first frames 400 and the pair of second frames 500 may be directly coupled. In this case, the pair of first frames 400 and the pair of second frames 500 may be formed of a floating material. That is, the first frame 400 and the second frame 500 can be combined with the mounting line 10 and the crossing line 300 while floating on the sea without any other separate device.

A floating coupler may be disposed between both ends of the first frame 400 and both ends of the second frame 500 . That is, the marine photovoltaic power generation floating block unit may be disposed between one end of the first frame 400 and one end of the second frame 500 at four corners forming a square shape.

The marine solar power generation floating block 100 is arranged in a grid inside the frame structure formed in a square and connected to each other, so that the entire marine solar power generation floating block 100 behaves as a whole while flexibly responding to wind or waves on the other hand. be able to

6 is a view showing the first frame 400 and the coupling between the first frame 400 and the floating coupling part 600 according to the material according to an embodiment of the present invention.

As shown in FIG. 6 , the first frame 400 and the floating coupling part 600 may be coupled to each other by the first frame 400 and the first coupling member 620 . This combination structure may be similar to the combination of the marine solar power generation floating block 100 and the installation line 10.

7 is a view showing a photovoltaic device in which an anchoring means is coupled according to an embodiment of the present invention. A frame having a quadrangular shape and a plurality of marine photovoltaic power generation floating blocks 100 inside the frame are arranged in a grid and connected to each other to be able to flow integrally. If the second frame 500 and the marine photovoltaic power generation floating block 100 in the frame do not have anchoring means, they move aimlessly along the waves on the sea.

Therefore, these structures can be fixed to the seabed through anchoring means.

At this time, the anchoring means may be the anchoring device 700. In the anchoring device 700, one end is coupled to the floating coupling portion 600 and the other end is coupled to the sea floor underground so that the floating coupling portion 600 can be constrained and moored.

8 is a view showing anchoring means different from the anchoring means of FIG. 7 according to an embodiment of the present invention.

As shown in FIG. 8, the anchoring means may include a connection cable 910 having one end connected to the floating joint and the other end facing the sea floor, and a center of gravity 920 coupled to the end of the connection cable 910. there is.

At this time, the center of gravity 920 may be a water container whose structure is maintained by the pressure of the water accommodated therein. When the center of gravity 920 is located in the deep sea where there is little flow of water, it can function similarly to the anchoring device 700 that penetrates into the seabed and is coupled thereto. The anchoring device 700 is replaced through the configuration of the center of gravity 920 including the water receptor.

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the protection scope of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention belongs.

GP: solar panels
100: Offshore solar power marine solar power floating block
110: guide unit
130: a pair of coupling parts
RI: connecting member
10: Freeze line
300: intersection line
310: second coupling member
400: first frame
500: second frame
600: floating joint
620: first coupling member
700: anchoring device
910: connecting cable
920: center of gravity

Claims (10)

A plurality of marine solar power generation floating blocks arranged in a row in which solar cells are combined and floating on the sea-The marine solar power generation floating block is formed of a material lighter than water, and a plurality of solar panels are arranged on the upper flat surface. Attached integrally-;
A mounting line disposed along the lower portion of the plurality of marine solar power generation floating blocks to moor the plurality of marine solar power generation floating blocks to each other and coupled to each of the marine solar power generation floating blocks - the anchoring line is made of a flexible material. formed by -;
Including an intersection line combined while intersecting the reference line,
A guide portion capable of accommodating the mounting line is formed on the lower surface of the marine solar power generation floating block,
The guide part is formed along the longitudinal direction of the marine photovoltaic power generation floating block and is formed as a receiving groove open downward,
The mounting line is fastened and combined with a pair of coupling parts formed at both ends of the marine solar power generation floating block while being accommodated in the receiving groove,
The intersection line intersects the base line without connection with the marine solar power generation floating block at the bottom of each of the marine solar power generation floating blocks,
The intersecting point of the bearing line and the crossing line is coupled by a connecting ring at the lower part of the receiving groove,
Characterized in that the thickness of the rear end of the marine solar power generation floating block is formed greater than the thickness of the front end,
All-in-one marine solar power system.
delete delete According to claim 1,
a pair of first frames to which both ends of the mounting line are coupled;
Characterized in that it further comprises a pair of second frames to which both ends of the intersection line are coupled.
All-in-one marine solar power system. According to claim 4,
Both ends of the pair of first frames and both ends of the pair of second frames are floating in the sea so that the first frame and the pair of second frames form a quadrangular shape. characterized in that they are combined with each other by
All-in-one marine solar power system. According to claim 5,
The floating coupling part,
Characterized in that the first frame or the second frame and the first coupling member are coupled to each other,
All-in-one marine solar power system. According to claim 5,
Characterized in that it further comprises an anchoring means coupled to the floating coupling portion,
All-in-one marine solar power system. According to claim 7,
Characterized in that the anchoring means includes an anchoring device that penetrates the seabed ground,
All-in-one marine solar power system. According to claim 7,
The anchoring means is
a connection cable having one end connected to the floating coupler and facing the sea floor;
Characterized in that it comprises a center of gravity connected to the other end of the connection cable,
All-in-one marine solar power system. According to claim 9,
The center of gravity is
Characterized in that it comprises a water receptor whose structure is maintained by the pressure of the water contained therein.
All-in-one marine solar power system.

Images