WO2013032245A2 - Support structure for solar panels - Google Patents

Abstract

The present invention relates to a support structure for solar panels, comprising: an upper frame formed to enable solar panels to be arranged in sequence thereon; a support pipe which extends along the direction of the arrangement of the solar panels, which has a circular cross section, and both ends of which are sealed; and an intermediate frame which is fixed at an outer surface of the support pipe, and which is formed as an arc to support the inclined state of the solar panels.

Description

Support structure of solar panel

The present invention relates to a support structure of a solar panel.

Solar cells, which are spotlighted as an alternative to fossil fuels, use cells, which are the smallest unit that receives power to produce electricity, in the form of modules, and then use modules in the form of arrays. It is one of the problems.

Recently, technologies for overcoming the limitations of land installation sites have been proposed, such as rivers and lakes with calm waves. Korean Patent No. 0936567 is a solar water panel panel device installed to be suspended in the inner surface of the water, 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.

The double electron (No. 0936567) is a frame for buoyancy, which suggests that the outer circumferential surface is formed in a semi-cylindrical shape and the inner circumferential surface is formed to have a rectangular cross-sectional space, but the cost for production is complicated and difficult to standardize. It can be excessive. In the latter case (0975212), a box-type buoyancy sphere is installed at each intersection point of the horizontal member and the vertical member, so that the process and cost for the manufacture and assembly of the buoyancy spheres are accompanied, and the number of parts increases. It is also disadvantageous in terms of maintenance.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and an object thereof is to provide a support structure for a solar panel having excellent structural stability and durability while saving manufacturing costs.

In order to solve the above problems, the support structure of the solar panel according to the present invention, the upper frame formed to be arranged the solar panel; A support pipe extending along one array direction of the solar panel and having a circular cross section sealed at both ends; And an intermediate frame fixedly installed on an outer circumferential surface of the support pipe and formed in an arc so that the solar panel is supported in an inclined state.

As an example related to the present invention, the intermediate frame and the support pipe may be formed of Fiber Reinforced Plastic (FRP) or Glass Fiber Reinforced Plastic (GRP).

As an example related to the present invention, the intermediate frame may have a cylindrical straight tube cut into a predetermined width and angle, and both ends of the intermediate frame may support the upper and lower ends of the upper frame, respectively. Can be.

As an example related to the present invention, the intermediate frame may be formed in plural to be disposed at a plurality of positions of the upper frame, and the support pipe may be disposed in parallel so that the pair of intermediate frames is supported externally at two positions. Can be.

As an example related to the present invention, the intermediate frame and the receiving pipe may further include a buffer member disposed between.

As an example related to the present invention, the intermediate frame and the support pipe are fastened by bolts and nuts, and both ends of the bolts may have washers formed by FRP or GRP, respectively.

As an example related to the present invention, the method may further include a scaffold disposed inscribed in each of the intermediate frames.

As an example related to the present invention, the sealing of both ends of the support pipe is a form in which the cap provided separately from the support pipe is bonded by an adhesive, and the cap is sealed by a surface finishing layer formed by GRP or FRP. By forming the surface finishing layer in the form of a cap attached to both ends of the support pipe, or by inserting a rubber ring into the cap and then inserted into the support pipe.

As an example related to the present invention, buoyancy bodies having a specific gravity smaller than that of water may be further enclosed in the support pipe.

As an example related to the present invention, the support pipe may further include a fixed pipe which is formed in a parallel pair and fixes the support pipe by vertically penetrating the support pipe.

In this case, the support pipe is formed by FRP or GRP, the connection portion of the support pipe with the fixed pipe may be sealed by the surface finishing layer formed by FRP or GRP.

According to the solar panel support structure according to the present invention, as a structure for supporting the solar panel, since the buoyancy body uses a pipe extending in the array direction of the solar panel, the number of buoyancy bodies relative to the total arrangement of the solar panel can be reduced. It has the advantage of excellent mass production.

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

1 is a perspective view showing a state in which the solar panel support structure 100 associated with the present invention in operation

2 is a perspective view of a solar panel support structure 100 according to the present invention

3 is a side view of the solar panel support structure 100 of FIG.

4 is an enlarged cross-sectional view showing an example of the fixing structure of the upper frame 110 and the intermediate frame 120.

5 is an enlarged cross-sectional view illustrating an example of a fixing structure of the intermediate frame 120 and the support pipe 130.

6 is a cross-sectional view showing an example of the sealing structure of the support pipe 130

7 is a cross-sectional view showing another example of the sealing structure of the support pipe 130 '

8 is a cross-sectional view showing another example of the sealing structure of the support pipe 130 "

9 is a perspective view showing the assembly 200 is assembled and connected to the solar panel support structure 100 according to the present invention.

Hereinafter, with reference to the accompanying drawings, a solar panel support structure related to the present invention will be described in detail.

1 is a perspective view showing a state in which a solar panel support structure 100 according to the present invention is in operation, FIG. 2 is a perspective view of a solar panel support structure 100 according to the present invention, and FIG. 3 is a solar panel support of FIG. 2. Side view of the structure 100.

As shown in these figures, the solar panel support structure 100 is configured to be installed in a floating state, such as a river or lake. The solar panel S is in a form that is constantly arranged on the solar panel support structure 100. The direction and number of such arrangements may vary depending on the electricity production capacity of the unit cells constituting the solar panel S or the operating environment, and FIG. 1 illustrates that the solar panels S are arranged in a structure of two rows and four columns. Is showing.

2 and 3, the solar panel support structure 100 includes an upper frame 110, an intermediate frame 120, and a support pipe 130 as a whole.

The upper frame 110 is formed in a shape extending in a plane direction so as to support the array of solar panels (S). The upper frame 110 is formed of a rigid material such as aluminum or stainless steel, FRP or GRP, and may include an accessory for fixing the solar panel (S).

The intermediate frame 120 is fixed to the upper frame 110 so that the solar panel S is supported in an inclined state. In the shape of the shape, the intermediate frame 120 is formed in a band shape having an arc cross section. In terms of manufacture, the intermediate frame 120 is formed in a shape in which a cylindrical straight tube is cut at a predetermined width and angle. For example, the intermediate frame 120 may be implemented by cutting a large diameter straight pipe by a predetermined width, and then dividing the cut pieces into half (eg, 180 degrees). The intermediate frame 120 is formed of Fiber Reinforced Plastic (FRP) or Glass Fiber Reinforced Plastic (GRP). The FRP or GRP material is excellent in rigidity, durability, etc., it is possible to maintain the device in a stable water environment. Furthermore, the arc shape cut at a certain width and angle provides a reduction in material and elasticity due to a certain amount of deformation, thereby preventing the lower support pipe 130 from absorbing the shocks to be transmitted to the upper frame 110. Can be.

Both ends of the intermediate frame 120 formed in the arc shape is formed to support the upper and lower sides of the upper frame 110, respectively. That is, the angle by the installation of the intermediate frame 120 determines the inclination angle of the upper frame 110 and the solar panel (S). 2 and 3 show that the intermediate frame 120 is fixed to the support pipe 130. In addition, the intermediate frame 120 may be formed to be rotatable with respect to the support pipe 130 to adjust the inclination angle of the solar panel (S). The trace of rotation of the intermediate frame 120 may be matched to the arc shape of the intermediate frame 120. In this case, mechanical means such as rollers, racks or sprockets for rotating guide the intermediate frame 120 may be disposed between the intermediate frame 120 and the support pipe 130.

The receiving pipe 130 is able to support the intermediate frame 120, and is formed in a form extending along one array direction of the solar panel (S). In the shape, the support pipe 130 is formed in a cylindrical straight tube shape, both ends are sealed to provide buoyancy.

In general, the support pipes 130 are paired so that the solar panel support structure 100 can have stability. The intermediate frame 120 is disposed in plural along the extending direction of the support pipe 130, and is externally disposed on the outer circumferential surfaces of both support pipes 130. The support pipe 130 is fixed by the fixed pipe 140 passing through the support pipe 130 in the vertical direction so that each of the support pipes 130 does not flow with each other. The fixing structure of the support pipe 130 and the fixed pipe 140 will be described later with reference to FIG. 4.

On the manufacturing side, the support pipe 130 may use a straight pipe formed by FRP or GRP. The support pipe 130 formed by the FRP or the GRP like the intermediate frame 120 is excellent in rigidity, durability, etc., so that the device can be stably maintained in the water environment. Specifically, the intermediate frame 120 or the support pipe 130 formed by FRP or GRP has a specific gravity of about 2.2 compared to the case of forming a frame or a support using aluminum having a specific gravity of 2.7 or steel having a specific gravity of 7.86, and thus weight It can get great buoyancy and construction cost is low. In addition, in the long-term use, if the steel material is used, it may cause environmental pollution because corrosion occurs, and additional cost is generated when a separate external coating does not cause the problem of increased construction costs.

The intermediate frame 120 or the support pipe 130 may be additionally applied with a sunscreen to prevent denaturation by ultraviolet rays when used in the water or sea.

2 and 3, the scaffold 150 may be disposed to be inscribed in the intermediate frame 120. Scaffold 150 is installed for maintenance of the solar panel support structure 100, it may be formed by FRP or GRP material. In addition, the scaffold 150 may be manufactured using a resin mortar having a high weight in order to ensure structural safety from typhoons or waves of the entire structure.

The receiving pipe 130 is configured such that external water does not penetrate through the sealing. When leakage occurs due to other factors, the buoyancy may be lowered to prevent the solar panel support structure 100 from sinking. The buoyancy body having a specific gravity smaller than water may be enclosed in the support pipe 130. 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.

4 is an enlarged cross-sectional view illustrating an example of a fixing structure of the upper frame 110 and the intermediate frame 120.

Referring to FIG. 4, the intermediate frame 120 is a laminate in which several layers are stacked and includes an outer layer 121, a core layer 122, and an inner layer 123. The outer layer 121 and the inner layer 123 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. It can be formed to increase the rigidity with respect to the internal pressure in the direction. The core layer 122 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 an advantage of being excellent in rigidity, elastic deformation, strong against impact, light weight, and excellent in workability. In addition, there is no leakage, excellent corrosion resistance can be used semi-permanently. The structure of the receiving pipe 130 may also be manufactured by a manufacturing method similar to that of the intermediate frame 120.

Again, as shown in FIG. 4, an angle 125 may be attached to the intermediate frame 120 to fix the upper frame 110. For a firm fixation of the angle 125, the angle 125 may be attached by the surface finishing layer 126 formed by FRP or GRP. The surface bonding layer 126 is, for example, a mat or roving made of glass fiber is impregnated with a resin and then cured and molded. The surface bonding layer 126 may be formed by a plurality of hand layup operations. The angle 125 fixed as described above may obtain a firm attachment state by the strong bonding force between the surface finishing layer 125 and the intermediate frame 120 having similar materials. When the angle 125 is attached by the surface bonding layer 126, the upper frame 110 is fixed by the bolt 112 or the like. The angle 125 or the bolt 112 may be formed of a material such as stainless steel for corrosion resistance.

5 is an enlarged cross-sectional view illustrating an example of a fixing structure of the intermediate frame 120 and the support pipe 130.

As shown in FIG. 5, the intermediate frame 120 and the support pipe 130 may be fixed by the bolt 170 in a state of being externally circumscribed. A plurality of bolts may be fastened for firm fixing.

A shock absorbing member 173 may be installed between the intermediate frame 120 and the support pipe 130 to mitigate the flow or impact transmission between the intermediate frame 120 and the support pipe 130. The shock absorbing member 173 may be formed by a material such as a rubber plate, for example, and may be formed to have a shape along the outer circumferential surface of the intermediate frame 120 or the support pipe 130 to prevent flow.

Washers 171 and 172 formed by FRP or GRP may be disposed at both ends of the bolt 170 so as to increase the fastening force by the bolt 170. Washers 171 and 172 can be used to cut the FRP or GRP pipe into pieces.

According to FIG. 5, the fixed pipe 140 is disposed through the support pipe 130. In order to install the fixed pipe 140, the support pipe 130 is drilled with holes as much as the diameter of the fixed pipe 140. In order to seal the support pipe 130, the connection portion of the fixed pipe 140 with the support pipe 130 may be finished by the surface bonding layer 141 formed by FRP or GRP.

In terms of material, the fixed pipe 140 may be formed by various materials such as aluminum, steel, plastic, etc. in addition to the FRP or GRP.

Hereinafter, the sealing structure of the support pipe will be described with reference to FIGS. 6 to 8. Sealing of the backing pipe 130 may be implemented by various methods.

6 is a view in which the partition member 131 formed by FRP or GRP is attached to the support pipe 130 by the surface finishing layer 132 formed by FRP or GRP, and FIG. 7 is formed by rubber, plastic, or metal. After inserting the formed cap 131 ′ into the support pipe 130 ′, the sealing portion is sealed using the adhesive 132 ′. Fig. 8 shows the rubber ring 132 " inserted in the cap 131 " and then inserted into the support pipe 130 ". In addition, the cap can be sealed by a surface finishing layer formed by GRP or FRP. .

9 is a perspective view showing an assembly 200 to which the solar panel support structure 100 according to the present invention is connected and assembled.

The solar panel support structure 100 described above may be operated separately, but may be connected to each other to increase the amount of power generation as shown in FIG. To this end, the solar panel support structure 100 and the adjacent solar panel support structure 100 are connected by a connection member (joint). In the connection portion, in addition to connecting the fixed pipe and the fixed pipe as shown in Figure 9 it is also possible to interconnect the support pipe and the support pipe.

The assembly 200 interconnecting the solar panel support structures 100 provides stability from tipping or tipping over by typhoons.

The support structure of the solar panel described above is not limited to the configuration and method of the embodiments described above. The above embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

Claims (11)

An upper frame formed to arrange solar panels; A support pipe extending along one array direction of the solar panel and having a circular cross section sealed at both ends; And Fixed to the outer circumferential surface of the support pipe, comprising a middle frame formed in an arc (arc) so that the solar panel is supported in an inclined state, the support structure of the solar panel. The method of claim 1, The intermediate frame and the support pipe is formed of Fiber Reinforced Plastic (FRP) or Glass Fiber Reinforced Plastic (GRP), the support structure of a solar panel. The method of claim 1, The intermediate frame is formed in a shape in which a cylindrical straight tube is cut at a predetermined width and angle, Both ends of the intermediate frame is formed to support the upper and lower ends of the upper frame, respectively, support structure of a solar panel. The method of claim 3, The intermediate frame is formed in plurality so as to be arranged in a plurality of positions of the upper frame, The support pipe is a support structure of a solar panel, the pair is arranged in parallel so that each intermediate frame is supported externally in two positions. The method of claim 4, wherein The support structure of the solar panel further comprises a buffer member disposed between the intermediate frame and the support pipe. The method of claim 4, wherein The intermediate frame and the support pipe is fastened by bolts and nuts, Both ends of the bolt, the washer formed by the FRP or GRP, respectively, the solar cell support structure. The method of claim 4, wherein Further comprising a scaffold disposed inscribed in each of the intermediate frame, the support structure of the solar panel. The method of claim 1, Sealing at both ends of the support pipe, the cap provided separately from the support pipe is bonded by an adhesive, the cap is sealed by a surface finishing layer formed by GRP or FRP, the surface finishing layer cap Formed and attached to both ends of the support pipe, or inserted into the support pipe after the rubber ring is inserted into the cap, implemented by any one of the solar cell support structure. The method of claim 1, Inside the support pipe, A support structure for a solar panel, in which buoyancy bodies having a specific gravity smaller than that of water are further enclosed. The method of claim 1, The support pipes are formed in parallel pairs, And a fixing pipe for vertically penetrating each of the supporting pipes to fix the respective supporting pipes. The method of claim 10, The support pipe is formed by FRP or GRP, and the connection portion of the support pipe with the fixed pipe is sealed by a surface finishing layer formed by FRP or GRP, support structure of a solar panel.

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