KR20130110932A - Solarcell panel supporting structure having device for coupling buoyant member thereof - Google Patents

Abstract

PURPOSE: A support structure of a floating solar cell plate having a buoyant body fixing device minimizes the deformation of a buoyant body and the concentration of stress by surrounding the buoyant body. CONSTITUTION: A first frame horizontally supports a solar cell plate. A second frame (140) is inclined from a horizontal plane of the first frame. A buoyant body (160) is extended in one direction to support the second frame. A buoyant body fixing unit (200) surrounds the buoyant body. The buoyant body fixing unit fixes the buoyant body when the second frame is in contact with the buoyant body.

Description

SOLARCELL PANEL SUPPORTING STRUCTURE HAVING DEVICE FOR COUPLING BUOYANT MEMBER THEREOF}

The present invention relates to a buoyancy body fixing device of the supporting structure of the floating solar panel is installed to float on the surface of the river or lake.

Solar cells, which are in the spotlight as alternative energy for fossil fuels, use cells in the form of modules, which are the smallest unit that receives sunlight, and produce power. Since the energy produced by the solar cells is proportional to the area, securing an installation site (area) is also an important problem.

Recently, technologies for overcoming the limitations of land installation sites have been proposed, such as rivers and lakes with calm waves. Korean Patent No. 1012954 is a solar water panel panel device that is installed to be floating on the inner surface of the water, and Korean Patent No. 0975212 is a solar panel for installing a buoyancy sphere at the intersection of the horizontal member and the vertical member arranged in a grid Each structure is presented.

In general, the support structure of the solar panel is in the form having a frame for directly supporting the solar panel and the lower structure for fixing the frame so that the solar panel can achieve a constant arrangement. In solar panels installed in lakes and rivers, it is important to secure a stable fixing force from water or strong winds, and it is also necessary to maintain the construction and maintenance after construction. The buoyancy body, which is a means of allowing the floating structure of the floating solar panel to float on the water, is a place where the intermediate support supporting the solar panel is fixed, but also directly receives external force caused by strong wind or water surface. You need a solid device that can. On the other hand, the construction difficulty or construction time or cost when fixing the buoyancy body needs to be taken into account.

The present invention has been made in view of the above-mentioned, floating type having a buoyancy fixing device that can be easily connected between the buoyancy body and the intermediate support, or between the buoyancy body and buoyancy body exerted so that the support structure floats on the water It is an object of the present invention to provide a supporting structure of a solar panel and its fixing device.

In order to solve the above problems, the support structure of a floating solar panel having a buoyancy body fixing apparatus related to the present invention, the first frame formed to support the solar panel flat; A second frame coupled to the first frame and formed such that the first frame is inclined with respect to a horizontal plane; A buoyancy body extending in one direction so as to support the second frame and sealed at both ends; And a buoyancy body fixing part formed to wrap the buoyancy body and configured to be fixed to the buoyancy body in a state of circumscribing the second frame to the buoyancy body.

As an example related to the present invention, the buoyancy body fixing portion, the clamp is formed to surround the buoyancy body; And a frame fixing part positioned at one side of the clamp and formed to be fixed in a state where the second frame is placed thereon.

As an example related to the present invention, both ends of the clamp may be provided with a pair of flanges formed to be fastened to each other, and a buffer pad may be disposed between the pair of flanges.

As an example related to the present invention, the frame fixing part includes: a support block disposed on an upper surface of the second frame; A buffer block disposed between the second frame and the clamp; And one end of the bolt fixedly supported by the clamp.

As an example related to the present invention, the support structure of the solar panel may be disposed on the support block and fastened together with the support block, and may further include a scaffold support formed to support the scaffold.

As an example related to the present invention, the supporting structure of the solar panel may further include a connection member formed at one side of the clamp and connected to an adjacent buoyancy body.

As an example related to the present invention, the connection member may include: a first connection part protruding in the radial direction of the buoyancy body; And a second connection part protruding in the longitudinal direction of the buoyancy body from the side of the first connection part.

As an example related to the present invention, the second frame is disposed in a vertical direction with respect to the buoyancy body, and the buoyancy body fixing part has an X shape with respect to the central axis direction of the buoyancy body in the state where the second frame is placed. A band portion wound at an angle to the second frame and the buoyancy body; And band fasteners formed to bind both ends of the band part.

As an example related to the present invention, the second frame or the buoyancy body may be formed of Fiber Reinforced Plastic (FRP) or Glass Fiber Reinforced Plastic (GRP).

As an example related to the present invention, the second frame may have a cross-sectional structure of an arc shape.

According to the solar panel support structure according to the present invention, by fixing the solar panel and the first, second frame to the buoyancy body by the buoyancy body fixing portion, it is formed to wrap the buoyancy body to concentrate the deformation and stress of the buoyancy body Can be minimized, and the structural stability from strong winds or waves near the surface of the water can be secured.

According to the solar panel support structure according to the present invention, since the worker can be assembled as a simple operation of fastening the bolt, the operation is easy and installation time and manpower can be reduced.

According to an example related to the present invention, since the frame structure is formed of FRP or GRP material, durability in the water phase is excellent, environmentally friendly, and high structural stability can be obtained from impact or shaking.

1 is a perspective view of a support structure 100 of a floating solar panel having a buoyancy body fixing device related to the present invention
Figure 2 is a side view showing a state in which the solar panel support structure of Figure 1 interconnected
3 is an exploded perspective view of the buoyancy body fixing part 200 according to an embodiment related to the present invention
4 is a perspective view illustrating a state in which the buoyancy body fixing part 200 of FIG. 3 is assembled.
5 is a cross-sectional view illustrating a state in which the buoyancy body fixing part 200 of FIG. 3 is assembled.
6 is a conceptual plan view showing an assembled state of the floating solar panel support structure 300 having a buoyancy body fixing part 400 according to another embodiment related to the present invention.
FIG. 7 is a side view of the solar panel support structure 300 of FIG. 6.
8 is an enlarged plan view of the buoyancy body fixing part 400 of FIG.
9 is an enlarged side view of the buoyancy body fixing part 400 of FIG. 6.

Hereinafter, with reference to the accompanying drawings, the supporting structure of a floating solar panel having a buoyancy body fixing apparatus related to the present invention will be described in detail.

1 is a perspective view of a solar panel support structure 100 having an interframe coupling structure for supporting a solar panel according to the present invention, and FIG. 2 is a side view showing a state in which the solar panel support structures of FIG. 1 are connected to each other.

Referring to these drawings, the solar panel support structure 100 is configured to be installed in a floating state, such as a river or lake. However, here is an example of the floating support structure 100, the interframe coupling structure for the support of the solar panel according to the present invention can be applied to a fixed support structure fixed to the land or the ocean.

The solar panel support structure 100 supports the first frame 110, 130, the solar panel fixing device 120, and the first frame 110, 130 in a lattice arrangement for arranging the solar panel SP in a plane. The second frame 140, the frame coupling device 150 for coupling the first frame (110, 130) and the second frame 140, the buoyancy buoyancy formed to support the second frame 140 and float on the water surface Sieve 160 and the like are provided.

The first frames 110 and 130 are formed in a two-dimensional direction so as to support the solar panel SP. Specifically, according to FIG. 1, the first frames 110 and 130 may include a horizontal first frame 110 that directly supports the solar panel SP, and a vertical first frame that supports the horizontal first frame 110. 130 is provided. The first frames 110 and 130 may be formed of a rigid material such as aluminum, stainless steel, FRP or GRP. Both ends of the horizontal first frame 110 are coupled to both ends of the second frame 140 by frame coupling devices 150, respectively.

The shape of the first frame (110, 130) includes a frame body extending in one direction, the frame body may have a hollow portion is formed with an opening in the direction in which the solar panel (SP) is placed. In the middle of the hollow portion may be provided along the extending direction of the first frame (110, 130) and a reinforcing wall portion formed to partition the hollow portion.

The second frame 140 has differential heights at both ends thereof so that the solar panel SP and the first frames 110 and 130 are supported in an inclined state. In the shape of the shape, the second frame 140 is formed in a band shape having an arc cross section. In terms of manufacturing, the second frame 140 may be formed in a shape in which a cylindrical straight pipe is cut at a predetermined width and angle. As an example, the second frame 140 may be implemented by cutting a large diameter straight pipe by a predetermined width, and then dividing the cut pieces by a predetermined angle size (eg, 180 degrees). The second frame 140 may be formed of fiber reinforced plastic (FRP) or glass fiber reinforced plastic (GRP). In detail, the second frame 140 may include an outer layer, a core layer, and an inner layer as stacks in which several layers are stacked. The outer layer and the inner layer include a weft layer wound so that the glass fibers impregnated in the resin are arranged in parallel with the circumferential direction, and a warp layer wound so that the fiber yarns are arranged in parallel with the longitudinal direction, thereby being rigid against radial and longitudinal pressure resistances. It can be formed to increase. The core layer is formed by impregnating the mortar with a resin, so that the pipe has a constant weight and rigidity. The glass fiber composite pipe formed as described above has the advantage of being elastically deformable and strong in impact, light weight, and excellent in workability. In addition, there is no leakage, excellent corrosion resistance can be used semi-permanently. The configuration of the buoyancy body 160 to be described later may also be manufactured by a manufacturing method similar to the second frame 140. As such, the second frame 140 formed of the FRP or GRP material is excellent in rigidity, durability, and the like, so that the device can be stably maintained in the water environment. Furthermore, the arc shape cut at a certain width and angle provides a reduction in material and elasticity due to a certain degree of deformation, thereby absorbing the impact of the lower buoyancy body 160 to be transmitted to the first frames 110 and 130. And it can prevent, and conversely buffers the shock or vibration received by the first frame (110, 130).

Both ends of the second frame 140 formed in an arc shape are formed to support the upper side and the lower side of the first frame 110, 130, respectively. That is, the angle due to the installation of the second frame 140 determines the inclination angles of the first frames 110 and 130 and the solar panel SP. In FIG. 1, the second frame 140 is fixed to the buoyancy body 160. In addition, the second frame 140 may be formed to be rotatable with respect to the buoyancy body 160 to adjust the inclination angle of the solar panel SP.

The second frame 140 or the buoyancy body 160 may be additionally applied with a sunscreen to prevent denaturation by ultraviolet rays when used in rivers, lakes or the sea.

The buoyancy body 160 is able to support the second frame 140, and is formed in a form extending along the horizontal arrangement direction of the solar panel (SP). In the shape, the buoyancy body 160 is formed in a cylindrical straight tube shape, both ends are sealed to provide buoyancy. In order to fix the second frame 140 to the buoyancy body 160, the buoyancy body fixing part 200 is mounted on the buoyancy body 160. The buoyancy body fixing part 200 will be described in detail later with reference to FIG. 3 or less.

As a whole, the buoyancy body 160 is a pair so that the solar panel support structure 100 is not conductive and has stability. The second frame 140 is arranged in plural pieces such as ribs along the extending direction of the buoyancy body 160 and is externally disposed on the outer circumferential surfaces of both buoyancy bodies 160. The buoyancy body 160 is fixed by a fixed pipe (not shown in detail) connecting the buoyancy body 160 in the vertical direction so that each of the buoyancy bodies 160 does not flow with each other. As shown in FIG. 2, one support structure 100 completed by two buoyancy bodies 160 is connected by an adjacent support structure and a connecting pipe 180 to form a matrix as a whole. A buffer 181 may be provided between the buoyancy body 160 and the connection pipe 180 to mitigate the impact of the support structure 100 and the adjacent support structure 100 from shaking due to wind or waves. have.

On the manufacturing side, the buoyancy body 160 may use a straight pipe formed of fiber reinforced plastic (FRP) or glass fiber reinforced plastic (GRP) as described above. The buoyancy body 160 formed by the FRP or GRP is excellent in rigidity, durability, etc., it is possible to maintain the device stably in the water environment. That is, the specific gravity of the second frame 140 or buoyancy body 160 formed by FRP or GRP compared to the case of using a frame or a base using aluminum or steel, so the specific gravity is about 2.2 can obtain a large buoyancy to weight The construction cost is also low. In addition, in the long-term use, there is no fear of causing environmental pollution due to corrosion, and there is no need to apply an external coating separately, thereby reducing the costs associated with installation or construction.

The buoyancy body 160 is configured such that external water does not penetrate through the sealing. When leakage occurs due to other factors, buoyancy may be lowered to prevent the solar panel support structure 100 from sinking, the buoyancy body 160 may have a buoyancy body having a smaller specific gravity than water. Such a buoyancy body may be formed of polystyrofoam or urethane foam, or the like, and as another example, may be implemented by arranging a plurality of sealed small diameter pipes.

As shown in FIGS. 1 and 2, the scaffold 170 may be disposed to be inscribed in the second frame 140. Scaffold 170 is installed for maintenance of the solar panel support structure 100, it can be formed by FRP or GRP material. Specifically, the scaffold 170 may be manufactured in a form in which a resin mortar is treated on a surface of the FRP after the composite frame is manufactured by a pultrusion method to prevent slippage.

3 is an exploded perspective view of the buoyancy body fixing part 200 according to an embodiment related to the present invention, Figure 4 is a perspective view showing a state in which the buoyancy body fixing part 200 of Figure 3 is assembled, Figure 5 is a view 3 is a cross-sectional view showing a state in which the buoyancy body fixing part 200 is assembled.

As shown in these figures, the buoyancy body fixing part 200 is formed to wrap the buoyancy body 160, the buoyancy body 160 in a state of circumscribing the second frame 140 to the buoyancy body 160 It is configured to be fixed to). The buoyancy body fixing part 200 may not only support the load received by the second frame 140 but also act as an element for buffering or connecting the buoyancy body 160 and the adjacent buoyancy body 160.

In detail, the buoyancy body fixing part 200 may be clamped to be formed to wrap the buoyancy body 160, and may be fixed to a state in which the second frame 140 is placed on one side of the clamp 210. It is provided with a frame fixing portion to be formed.

The clamp 210 may be formed in the form of a band made of stainless steel or resin-based or glass fiber reinforced composite materials, and may be formed in the form of a 'C' ring for ease of assembly and adjustment of fixing force. Both ends of the clamp 210 may be provided with a pair of flange portions 211 formed to be coupled to each other. The flange portion 211 may be formed of the same or different materials as the clamp 210, and the buffer pad 212 may be disposed between the pair of flange portions 211. The shock absorbing pad 212 may be formed of rubber, resin, or metal, and reduces the spreading or loosening of the clamp 210 during assembly by the flange bolt 213.

The frame fixing part supports the support block 230 disposed on the upper surface of the second frame 140, the buffer block 240 disposed between the second frame 140 and the clamp 210, and one end of which is fixed to the clamp 210. Bolts 250 are provided. An upper portion of the support block 230 may be fastened together with the support block 230, and a scaffold support 260 formed to support the scaffold 170 may be disposed. The frame fixing part may be formed in a structure capable of supporting the second frame 140 or the footrest 170 at a time.

The support block 230 has a fastening hole through which the bolt 250 can be passed, and the second frame allows surface contact between the scaffold support 260 disposed on the upper side and the second frame 140 disposed on the lower side. It may be formed in a round shape similar to the shape of 140, and may have a function of a washer to prevent loosening of the nut 251 fastened to the bolt 250. The support block 230 may be formed of metal, resin, or GRP / FRP material.

The buffer block 240 is formed to prevent the second frame 140 from directly transmitting an impact to the clamp 210, and to prevent the sliding of the bolt 250 of the clamp 210 by preventing slippage. . The buffer block 240 may be formed of rubber or resin, and the upper surface has a round shape surface like the second frame 140 so as to be in surface contact with the second frame 140 and the clamp 210. The lower surface may have a round shape surface, such as the outer circumferential surface of the clamp 210.

The bolt 250 may be attached to the clamp 210 in a form in which one end is fixed by welding or inserting. That is, the bolt 250 may be formed in a shape that does not pass through the buoyancy body 160, and as a result, the water 250 inherently blocks water from penetrating into the buoyancy body 160 by attachment of the bolt 250.

The scaffold support 260 is formed to allow the scaffold 170 to be horizontally supported by the fastening of the bolt 250.

As such, the support block 230, the buffer block 240, and the bolt 250 and the scaffold support 260 are fixed to the clamp 210 by the bolt 250 at the same time, and the assembly of the clamp 210 is performed at the same time. The clamp 210, that is, the buoyancy body fixing part 200, is disposed at a plurality of positions along the direction of the buoyancy body 160 (see FIG. 1).

Again, referring to FIG. 1, one side of the clamp 210 may be provided with a connecting member 220 for connecting the buoyancy body 160 to the adjacent buoyancy body 160. The connection member 220 may include a first connector 221 protruding in the radial direction of the buoyancy body 160 and a second connector 222 protruding in the longitudinal direction of the buoyancy body 160 from the side of the first connector 221. It may be provided. The connection member 220 integrally attached to the clamp 210 can reduce the number of parts or assembly for fixing or supporting the buoyancy body 160, and can provide simplicity of field construction.

6 is a conceptual plan view illustrating an assembled state of the floating solar panel support structure 300 having the buoyancy body fixing part 400 according to another embodiment of the present invention, and FIG. 7 is the solar panel of FIG. 6. 8 is an enlarged plan view of the buoyancy body fixing part 400 of FIG. 6, and FIG. 9 is an enlarged side view of the buoyancy body fixing part 400 of FIG. 6.

In this embodiment, it is shown that the buoyancy body fixing part 400 is provided with a band part 410 and a band fastener 420. That is, in a state in which the second frame 340 is disposed in the vertical direction with respect to the buoyancy body 360, the band frame 410 is wound to fix the second frame 340 to the buoyancy body 360. 8 and 9, the band part 410 has the second frame 340 and the buoyancy body 360 in an X shape with respect to the direction of the central axis of the buoyancy body 360 while the second frame 340 is placed. Wound on). Both ends of the band portion 410 are tied by the band fastener 420. The band part 410 may be made of a metal material such as resin or stainless steel, and the band fastener 420 may be made of a metal material such as stainless steel. According to this embodiment, the fixing operation of the buoyancy body 360 can be much simpler, it is possible to reduce the required parts or cost.

The support structure of the floating solar panel having the buoyancy fixing device described above is not limited to the configuration and method of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: solar panel support structure 110, 130: the first frame
120: solar panel fixing device 140: the second frame
150: frame coupling device 160: buoyancy body
170: scaffold 180: connecting pipe
200: buoyant body fixing portion 210: clamp
211: flange portion 212: buffer pad
220: connecting member 221: first connecting portion
222: second connection portion 230: support block
240: buffer block 250: bolt
260: scaffold support 400: buoyancy body fixing portion
410: band portion 420: band fastener

Claims (10)

A first frame formed to support the solar panel flatly;
A second frame coupled to the first frame and formed such that the first frame is inclined with respect to a horizontal plane;
A buoyancy body extending in one direction so as to support the second frame and sealed at both ends; And
A floating solar panel having a buoyancy body fixing device formed to wrap the buoyancy body and including a buoyancy body fixing part configured to be fixed to the buoyancy body in a state of circumscribing the second frame to the buoyancy body. Supporting structure.
The method of claim 1,
The buoyancy body fixing part,
A clamp formed to wrap the buoyancy body; And
Located on one side of the clamp and including the frame fixed to be formed to be fixed to the second frame is mounted, the support structure of a floating solar panel having a buoyancy body fixing device.
3. The method of claim 2,
At both ends of the clamp, a pair of flanges are provided to be coupled to each other to be fastened,
A support structure for a floating solar panel having a buoyancy body fixing device, the buffer pad is disposed between the pair of flanges.
3. The method of claim 2,
The frame fixing part,
A support block disposed on an upper surface of the second frame;
A buffer block disposed between the second frame and the clamp; And
A support structure for a floating solar panel having a buoyancy body fixing device, the one end of which includes a bolt fixedly supported to the clamp.
5. The method of claim 4,
A support structure for a floating solar panel having a buoyancy body fixing device is disposed on top of the support block is fastened with the support block, and formed to support the footrest, buoyancy body fixing device.
5. The method of claim 4,
It is formed on one side of the clamp, and further comprising a connecting member for connecting with an adjacent buoyancy body, support structure of a floating solar panel having a buoyancy body fixing device.
The method according to claim 6,
The connecting member includes:
A first connection part protruding in the radial direction of the buoyancy body;
And a second connection portion protruding in the longitudinal direction of the buoyancy body from the side of the first connection portion.
The method of claim 1,
The second frame is disposed in a direction perpendicular to the buoyancy body,
The buoyancy body fixing part,
A band part wound around the second frame and the buoyancy body at an angle in an X shape with respect to the direction of the central axis of the buoyancy body in the state where the second frame is placed; And
A support structure for a floating solar panel having a buoyancy body fixing device comprising a band fastener formed to bind both ends of the band portion.
The method of claim 1,
The second frame or the buoyancy body is formed of Fiber Reinforced Plastic (FRP) or Glass Fiber Reinforced Plastic (Glassfiber Reinforced Plastic; GRP), the support structure of a floating solar panel having a buoyancy fixing device.
The method of claim 1,
The second frame has an arc-shaped cross-sectional structure, the supporting structure of a floating solar panel having a buoyancy fixing device.

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