KR200467819Y1 - Structure system for support of solar cell module - Google Patents

Abstract

”의 단면 형상을 갖는 U-브라켓(U-bracket, 500)과; 상기 U-브라켓의 U-볼트 체결용 홀에 체결되어 펄린(purlin)이 삼각트러스의 경사면에 체결되도록 하는 제2 U-볼트모듈(600)과; 상기 제2 U-볼트모듈과 U-브라켓에 의해 상기 삼각 트러스의 경사면에 체결되며, 태양전지모듈이 고정 및 지지될 수 있도록 다수개의 모듈 체결용 홀(710)이 형성된 펄린(700) 및; 상기 펄린의 모듈 체결용 홀에 대응되는 마운팅 홀이 후면에 형성되어 펄린의 상부에 고정 설치되는 태양전지모듈(800)이 포함되는 것을 특징으로 하는 태양전지모듈 지지용 구조물 시스템을 제공한다.
따라서 본 고안에 의하면, 태양전지모듈 지지용 구조물의 조립 및 체결 위치 수정이 용이하며 다양한 규격을 갖는 태양전지모듈에 대응한 구조물의 설치가 가능하므로 작업능률을 향상시킬 수 있으며, 종래 구조물보다 구조가 간단하며 제조원가 및 시공비를 절감할 수 있는 효과가 있다.The present invention relates to a structure system for supporting a solar cell module being constructed in a photovoltaic power plant. More specifically, a triangular truss and purlin for fixing and supporting a solar cell module installed on a panel roof are U-shaped. The present invention relates to a structure system for supporting a solar cell module which enables easy installation and fastening position adjustment through a bolt module and a bracket.
To this end, the present invention, in the solar cell module support structure system for fixedly supporting the solar cell module is installed on the roof of the building consisting of a panel (panel, 10), is fixed to the panel 10, A panel bracket (100) disposed on the upper surface of the panel corresponding to the position where the triangular truss is to be installed; L-bracket (L-bracket, 200) is fastened to the upper surface of the panel bracket, the side of the U-bolt fastening hole 210 is formed; The U-bolt fastening hole 210 of the L-bracket is fastened so that the triangular truss is fastened to the L-bracket, and the two U-bolts 310a and 310b have a shape connected to each other at a predetermined interval. A first U-bolt module 300; A triangular truss 400 fastened to the L-bracket by the first U-bolt module and installed on the panel; A plurality is installed in close contact with the inclined surface 410 formed on the upper portion of the triangular truss, the U-bolt fastening hole 510 is formed on the upper surface "

A U-bracket 500 having a cross-sectional shape of ”; A second U-bolt module 600 which is fastened to the U-bolt fastening hole of the U-bracket so that a purlin is fastened to the inclined surface of the triangular truss; A perlin 700 fastened to the inclined surface of the triangular truss by the second U-bolt module and the U-bracket, and having a plurality of module fastening holes 710 to fix and support the solar cell module; The mounting hole corresponding to the module fastening hole of the Perlin provides a solar cell module support structure system, characterized in that it comprises a solar cell module 800 is fixed to the upper portion of the perlin is installed.
Therefore, according to the present invention, it is easy to assemble and fix the fastening position of the structure for supporting the solar cell module and to install the structure corresponding to the solar cell module having a variety of specifications can improve the work efficiency, the structure than the conventional structure It is simple and has the effect of reducing manufacturing cost and construction cost.

Description

Structure system for solar cell module support {Structure system for support of solar cell module}

The present invention relates to a structure system for supporting a solar cell module being constructed in a photovoltaic power plant. More specifically, a triangular truss and purlin for fixing and supporting a solar cell module installed on a panel roof are U-shaped. The present invention relates to a structure system for supporting a solar cell module which enables easy installation and fastening position adjustment through a bolt module and a bracket.

In general, the structures that are constructed in solar power facilities are largely classified into square tube structures, H-beams, and space frame structures, and are flat roofs, shed roofs, and verandas that are roofs of buildings. ) And balcony, terrace, porch.

Each of the above structures has advantages and disadvantages, but in general, when the solar cell module is fastened, the arrangement of the solar cell module is uneven, and the number of components increases and the working time is long.

In order to solve the problem of the fastening structure of such a structure, 'Integrated solar system for photovoltaic power generation' of the Republic of Korea Patent Publication No. 10-0983456 (September 15, 2010) patented by the applicant and Korea 'Solar cell slide frameless system' of Korean Patent Publication No. 10-1056530 (August 05, 2011) and 'Solar cell slim frame system' of Korean Patent Publication No. 10-1056531 (2011. 08. 05) This has been proposed (see (a), (b) and (c) of FIG. 1).

However, the above-mentioned patented technologies are technologies that facilitate the installation and dismantling of solar cell modules (or solar cell modules) through various fastening methods between solar cell modules and structures, or the sun, such as triangular trusses and purlins. The structure for fixing and supporting the battery module on the roof of the building is not specifically mentioned, and the problem of the arrangement of the solar cell module due to the unbalanced height of the solar module and the place where the structure is installed is still produced in various specifications by manufacturers. It is not solved.

Therefore, the present invention provides a structure system for supporting a solar cell module that is easy to assemble and disassemble between structures through a specially manufactured U-bolt module and a bracket and to adjust a fastening position to solve such a problem.

Therefore, the object of the present invention was devised to solve the above problems, more specifically, the triangular truss and purlin for fixing and supporting the solar cell module installed on the panel roof U-bolt module and bracket It provides a structure system for supporting the solar cell module to enable easy installation and fastening position adjustment through.

”의 단면 형상을 갖는 U-브라켓(U-bracket, 500)과; 상기 U-브라켓의 U-볼트 체결용 홀에 체결되어 펄린(purlin)이 삼각트러스의 경사면에 체결되도록 하는 제2 U-볼트모듈(600)과; 상기 제2 U-볼트모듈과 U-브라켓에 의해 상기 삼각 트러스의 경사면에 체결되며, 태양전지모듈이 고정 및 지지될 수 있도록 다수개의 모듈 체결용 홀(710)이 형성된 펄린(700) 및; 상기 펄린의 모듈 체결용 홀에 대응되는 마운팅 홀이 후면에 형성되어 펄린의 상부에 고정 설치되는 태양전지모듈(800)이 포함되는 것을 특징으로 하는 태양전지모듈 지지용 구조물 시스템을 제공한다.According to a feature of the present invention for achieving the above object, in the solar cell module support structure system for supporting and fixing the solar cell module installed on the roof of the building consisting of a panel (panel, 10), the panel A panel bracket (100) fixedly installed at (10), the plurality of panel brackets being disposed on an upper surface of the panel corresponding to the position where the triangular truss is to be installed; L-bracket (L-bracket, 200) is fastened to the upper surface of the panel bracket, the side of the U-bolt fastening hole 210 is formed; The U-bolt fastening hole 210 of the L-bracket is fastened so that the triangular truss is fastened to the L-bracket, and the two U-bolts 310a and 310b have a shape connected to each other at a predetermined interval. A first U-bolt module 300; A triangular truss 400 fastened to the L-bracket by the first U-bolt module and installed on the panel; A plurality is installed in close contact with the inclined surface 410 formed on the upper portion of the triangular truss, the U-bolt fastening hole 510 is formed on the upper surface "

A U-bracket 500 having a cross-sectional shape of ”; A second U-bolt module 600 which is fastened to the U-bolt fastening hole of the U-bracket so that a purlin is fastened to the inclined surface of the triangular truss; A perlin 700 fastened to the inclined surface of the triangular truss by the second U-bolt module and the U-bracket, and having a plurality of module fastening holes 710 to fix and support the solar cell module; The mounting hole corresponding to the module fastening hole of the Perlin provides a solar cell module support structure system, characterized in that it comprises a solar cell module 800 is fixed to the upper portion of the perlin is installed.

Preferably, the panel bracket 100 is manufactured in the same manner as the outer circumferential surface shape of the convex portion so as to be fixed to the convex portion 11 formed on the upper surface of the panel 10.

Preferably, the panel bracket 100 is for fastening with the L-bracket 200 and the direct threading hole 110 through which the direct screw 20 for fixing the panel bracket to the panel passes. The bolt holes 120 through which the bolt 30 penetrates are formed, respectively.

Preferably, the U-bolt fastening hole 210 of the L-bracket 200 is characterized in that formed in the slot hole (slot hole) type to facilitate the fastening position adjustment of the triangular truss (400). .

Preferably, the U-bolt fastening hole 510 of the U-bracket 500 is characterized in that it is formed in a slot hole (slot hole) type to facilitate the fastening position adjustment of the Perlin 700.

According to the solar cell module support structure system of the present invention, there are the following effects.

The triangular truss and purlin for fixing and supporting the solar cell module installed on the panel roof are configured to be coupled to the L-bracket and the U-bracket through the first and second U-bolt modules.

1) The installation and replacement of triangular trusses and perlins can be easily adjusted, which shortens the installation and replacement time of the solar cell module. This makes it easy for beginners to work in hazardous spaces such as roofs.

2) Since the fastening height of the triangular truss installed on the panel roof can be adjusted through the first U-bolt module and the L-bracket, it can be installed regardless of the uneven height of the panel roof surface.

3) Since the fastening position of the perlin fastened to the triangular truss can be adjusted through the second U-bolt module and the U-bracket, it is applicable to solar cell modules of various standards.

4) Since the solar cell module is fixed and supported by triangular trusses and perlins, which are simpler than conventional solar cell module structures, manufacturing cost and construction cost can be reduced.

Figure 1 (a), (b), (c) is a view showing a conventional solar cell module coupling structure patented by the applicant
2 is a view showing the overall configuration of a structure system for supporting a solar cell module according to an embodiment of the present invention
3 is a view showing a fastening structure of a panel bracket and an L-bracket according to a preferred embodiment of the present invention
4 is a view showing a fastening structure of the L-bracket and the first U-bolt module and the triangular truss according to an embodiment of the present invention;
5 is a view showing the fastening structure of the perlin of the triangular truss through the U-bracket and the second U-bolt module according to an embodiment of the present invention
6 is a view showing a state before and after installation of the solar cell module of the structure system for supporting a solar cell module according to an embodiment of the present invention

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the present invention will be described in detail a structure system for supporting a solar cell module according to a preferred embodiment of the present invention.

First, in adding reference numerals to the elements of each drawing, it should be noted that the same reference numerals are used to refer to the same elements even though they are shown in different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related known configuration or function may obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First, prior to the detailed description of the solar cell module support structure system of the present invention, the solar cell module (or solar cell) is generally flat roof (Shed Roofing) or the roof (Shed roof) of the building to facilitate solar collection Installed in the roof, veranda and balcony, balcony, terrace, porch, in particular, the flat roof and the inclined roof are mainly constructed of panels, so the present invention It is a structure system for supporting a solar cell module to facilitate the installation of a solar cell module.

With reference to Figures 2 to 6, the present invention is the main technical constituent means of the structure system for supporting a solar cell module according to the preferred embodiment, the panel bracket 100, L-bracket 200, first / second U-bolt module (300, 600), triangular truss (400), U-bracket 500, Perlin 700, solar cell module (800).

Referring to FIGS. 1, 3, and 4, the panel bracket 100 is a bracket means fixed to the panel 10 and corresponds to a position where a triangular truss 400 to be described later is installed. A plurality is arranged on the upper surface of the panel.

Here, the panel bracket 100 is manufactured in the same manner as the outer circumferential surface shape of the convex portion so as to be fixed to the convex portion 11 formed on the upper surface of the panel 10.

On the other hand, the panel (panel, 10) is generally a metal panel for the roof construction of the prefabricated building is a roof construction member so that the compression styrofoam 12 is filled therein to have a heat insulating function.

In addition, the panel bracket 100 is a bolt for fastening the direct connection screw hole 110 through which the direct screw 20 for fixing the panel bracket to the panel passes, and the L-bracket 200 to be described later. Bolt holes 120 through which 30 are formed are formed, respectively, and the direct screw 20 penetrates the panel roof to a sufficient length so as to be fastened to the supporting steel 13 of the lower part of the panel roof. By having the panel bracket to support a structure such as triangular truss 400 and perlin 700 to be described later.

3 and 4, the L-bracket 200 is fastened to an upper surface of the panel bracket 100, and a bracket having a U-bolt fastening hole 210 formed at a side thereof. Means.

Here, a bolt hole 220 for fastening with the panel bracket 100 is formed on the lower surface of the L-bracket 200 to coincide with the bolt hole 120 formed in the panel bracket at the time of fastening. And nuts 30 and 40, and the bolt 30 penetrates through the bolt holes 120 and 220 from the lower side of the panel bracket 100 toward the L-bracket 200. Make the fastening work easy.

In addition, the U-bolt fastening hole 210 of the L-bracket 200 is formed in a slot hole type to easily adjust the fastening position of the triangular truss 400, the slot hole is a general circular The hole is a hole which extends up and down or right and left to adjust the fastening position of a fastening member such as a bolt in the hole.

Referring to FIG. 4, the first U-bolt module 300 is fastened to the U-bolt fastening hole 210 of the L-bracket 200 so that the triangular truss 400 is fastened to the L-bracket. The two U-bolts 310a and 310b have a shape connected to each other at a predetermined interval.

Here, the size and shape of the first U-bolt module 300 corresponds to the size and shape of the cross section of the straight member of the triangular truss 400 so that the first U-bolt module and the triangular truss are completely in close contact and fastened. For example, when the cross section of the straight member of the triangular truss has a square shape, a “c” shape formed to angulate the U-bolt portion of the first U-bolt module is used (see FIG. 4).

In addition, the first U-bolt module 300 by specially manufacturing the two U-bolts (310a, 310b) connected to each other by spaced apart at regular intervals, non-stop two U-bolts at a time (NON-STOP) As it can be fastened to facilitate the fastening operation, there is an advantage that can increase the tightening strength than when each U-bolt is fastened by the two U-bolts are connected.

1, 5 and 6, the triangular truss 400 is a structure that is fastened to the L-bracket 200 by the first U-bolt module 300, the panel 10 Many are installed in the system.

Here, the triangular truss is a pin or welded connection point between the members so that the straight members are not bent, and the members are not bent and the waste of materials can be reduced, so that the structure of bridges, buildings, etc. It is widely used as a structure, and in the present invention, it is used as a structure for supporting a solar cell module.

”의 형상으로 제작되며, 이는 상부에 후술하는 펄린(purlin, 700)을 체결하여 태양전지모듈(800)을 경사지게 설치하기 위함이다. In addition, the triangular truss 400 is connected to the four straight members, the inclined surface 410 is formed on the "

It is manufactured in the shape of “, which is intended to install the solar cell module 800 inclined by fastening the purlin (purlin, 700) to be described later on the top.

On the other hand, the triangular truss 400 may further reinforce the strength of the triangular truss by further connecting the reinforcing member crossing the upper and lower diagonally according to the specification and installation location of the solar cell module.

In addition, the fastening method of the L-bracket 200 and the triangular truss 400 by the first U-bolt module 300, first to the U-bolt fastening hole 210 formed on the side of the L-bracket Position the lower part of the triangular truss in close contact with each other, and then insert the first U-bolt module into the U-bolt fastening hole, and then tighten the nut 50 to the first U-bolt module.

In this case, as the U-bolt fastening hole 210 of the L-bracket 200 is drilled in the slot hole method, the fastening position between the L-bracket and the triangular truss, that is, the fastening height of the triangular truss can be adjusted, and thus the panel roof. Regardless of the uneven height of the surface, the installation height between the plurality of triangular trusses installed on the panel roof surface can be adjusted uniformly, thereby preventing the height error of the arrangement of the solar cell modules installed on the upper part of the triangular truss. .

Therefore, since the triangular truss 400 can be installed on the panel 10 only by using the panel bracket 100, the L-bracket 200, and the first U-bolt module 300, there are no welding accidents that occur frequently. It can be safely carried out by workers because it is not necessary, and it is easy to adjust fastening position and assemble / disassemble.

5, the U-bracket (U-bracket, 500) is in close contact with the inclined surface 410 formed on the upper portion of the triangular truss 400 is installed a plurality, the upper surface for fastening U-bolts The bracket means is formed with a hole (510).

”의 단면 형상을 갖는 브라켓으로, 하부면과 측면은 삼각트러스(400)의 경사면(410)에 밀착될 수 있도록 각지거나 하부면이 볼록하게 형성되며, 상부면에는 후술하는 제2 U-볼트모듈(600)을 체결시키기 위한 U-볼트 체결용 홀(510)이 형성된다.In other words, the U-bracket 500 is “

Bracket having a cross-sectional shape of ”, the lower surface and the side is angled or lower surface is convex so as to be in close contact with the inclined surface 410 of the triangular truss 400, the upper surface of the second U-bolt module will be described later A U-bolt fastening hole 510 for fastening the 600 is formed.

In addition, the U-bolt fastening hole 510 of the U-bracket is formed in a slot hole type to facilitate the fastening position adjustment of the perlin.

Referring to FIG. 5, the second U-bolt module 600 is fastened to the U-bolt fastening hole 510 of the U-bracket 500 so that a purlin 700 described below may be formed of a triangular truss. As a means for fastening to the inclined surface 410, like the first U-bolt module 300, the two U-bolts (610a, 610b) have a shape connected to each other at a predetermined interval.

Here, the size and shape of the second U-bolt module 600 corresponds to the cross-sectional size and shape of the perlin 700 so that the second U-bolt module and the perlin are completely in close contact and fastened. If the cross section of the 700 is a square shape, the U-bolt portions 610a and 610b of the second U-bolt module are formed so as to be angled to have a "c" shape (see FIG. 5).

2, 5, and 6, the purlin 700 is fastened to the inclined surface 410 of the triangular truss by the second U-bolt module 600 and the U-bracket 500. And, the solar cell module 800 is a structure of a horizontal member which is installed in a horizontal direction so that it can be fixed and supported.

Here, purlin is a horizontal member which is also called a midori and is used as a horizontal member that is parallel to the floor and eaves during the roof construction of the building and supports the rafters and shingles. It is a horizontal member for fixing and supporting the module.

In addition, the Perlin 700 is formed by a plurality of module fastening holes 710 corresponding to the mounting hole (mounting hole) position formed in the solar cell module 810 to be described later solar cell module by the module fastening holes To be fixed and supported.

In addition, in the fastening method of the perlin 700 and the triangular truss 400 by the second U-bolt module 600 and the U-bracket 500, first, the perlin is positioned on the inclined surface of the triangular truss. Insert the bracket so as to be in close contact with the lower surface and the side of the inclined surface, and insert the second U-bolt module into the U-bolt fastening hole 510 of the U-bracket, the nut (60) to the second U-bolt module Insert and fasten firmly so that Perlin is fastened to the triangular truss.

In this case, as the U-bracket and the U-bolt fastening hole of the U-bracket, which are movable in the installation position in the triangular truss, are drilled in the slot hole manner, the fastening position of the perlin fastened to the inclined surface of the triangular truss is easy. Is adjustable.

Therefore, the welding between the triangular truss and the perlin does not require any frequent accidents of welding, so the worker can safely carry out the operation, and corresponding to the solar cell module having various specifications for each manufacturer when installing and replacing the solar cell module. It is easy to install and maintain because only the fastening position of Perlin needs to be changed without replacing the structure.

Referring to FIGS. 1 and 6, the solar cell module 800 is a semiconductor device that directly converts light energy of sunlight into electrical energy. The module fastening hole 710 of the perlin 700 is described. A mounting hole (not shown) corresponding to the rear surface is fixedly installed on the top of the perlin.

Here, the mounting hole (mounting hole) of the solar cell module, a hole formed in the rear portion of the solar cell module for fastening with the structure, the same fastening of the bolt / nut by matching the position of the module fastening hole of Perlin The member can be fastened to the structure.

On the other hand, the solar cell module 800 is a module in which a plurality of solar cells (semiconductor material) of the semiconductor material is connected and connected in series and in parallel. It is various, such as a solar cell, which is a well-known technology, so a detailed description thereof will be omitted.

As such, in the structure system for supporting a solar cell module according to a preferred embodiment of the present invention, a triangular truss and a purlin for fixing and supporting a solar cell module installed on a panel roof are first / second U-bolts. Since the module is configured to be fastened to the L-bracket and the U-bracket, it is easy to adjust the installation and tightening position of the triangular truss and perlin, thereby reducing the time for installing and replacing the solar cell module, and requires separate welding work. Because only the first and second U-bolt modules and brackets are used, even beginners can easily work in dangerous spaces such as roofs, and fastening of triangular trusses installed on the panel roof through the first U-bolt modules and L-brackets Since the height can be adjusted, it can be installed regardless of the uneven height of the panel roof surface, and on the fastening of the Perlin fastened to the triangular truss through the second U-bolt module and the U-bracket. Because control is possible, and is applicable to solar battery modules of different specifications.

In addition, since the solar cell module is fixed and supported by triangular trusses and perlins, which are simpler than conventional solar cell module structures, there is an effect of reducing manufacturing costs and construction costs.

The description above is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to describe, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas falling within the scope of the present invention should be interpreted as being included in the scope of the present invention.

10: panel 11: convex
12: compression styrofoam 13: support steel
20: Direct connection screw 30: Bolt
40, 50, 60: nuts
100: panel bracket 110: direct connection hole
120, 220: Bolt hole 200: L-bracket
210, 510: U-bolt fastening hole 300: first U-bolt module
310a, 310b, 610a, 610b: U-bolt 400: triangular truss
410: slope 500: U-bracket
600: second U-bolt module 700: purlin
710: module fastening hole 800: solar cell module

Claims (5)

In the solar cell module support structure system for supporting and fixed installation of the solar cell module to be installed on the roof of the building consisting of panels (panel, 10),
A panel bracket (100) fixedly installed on the panel (10), the panel bracket (100) being disposed on the upper surface of the panel corresponding to the position where the triangular truss is to be installed;
L-bracket (L-bracket, 200) is fastened to the upper surface of the panel bracket, the side of the U-bolt fastening hole 210 is formed;
The U-bolt fastening hole 210 of the L-bracket is fastened so that the triangular truss is fastened to the L-bracket, and the two U-bolts 310a and 310b have a shape connected to each other at a predetermined interval. A first U-bolt module 300;
A triangular truss 400 fastened to the L-bracket by the first U-bolt module and installed on the panel;
A plurality is installed in close contact with the inclined surface 410 formed on the upper portion of the triangular truss, the U-bolt fastening hole 510 is formed on the upper surface "

A U-bracket 500 having a cross-sectional shape of ”;
A second U-bolt module 600 which is fastened to the U-bolt fastening hole of the U-bracket so that a purlin is fastened to the inclined surface of the triangular truss;
A perlin 700 fastened to the inclined surface of the triangular truss by the second U-bolt module and the U-bracket, and having a plurality of module fastening holes 710 to fix and support the solar cell module;
The solar cell module supporting structure system, characterized in that the mounting hole corresponding to the module fastening hole of the Perlin is formed on the rear side, the solar cell module 800 is fixed to the upper part of the Perlin.
The method according to claim 1,
The panel bracket (100), the solar cell module support structure system, characterized in that the same as the outer circumferential surface shape of the convex portion is manufactured to be fixed to the convex portion (11) formed on the upper surface of the panel (10).
The method according to claim 1,
The panel bracket 100 includes a direct threaded hole 110 through which a direct screw 20 for fixing the panel bracket to the panel passes, and a bolt 30 for fastening with the L-bracket 200. The solar cell module support structure system, characterized in that the bolt holes through which 120 are formed.
The method according to claim 1,
The U-bolt fastening hole 210 of the L-bracket 200 is a solar cell module support, characterized in that formed in a slot hole (slot hole) type to facilitate adjustment of the fastening position of the triangular truss (400). Structure system.
The method according to claim 1,
U-bolt fastening hole 510 of the U-bracket 500, for supporting the solar cell module, characterized in that formed in a slot hole (slot hole) type to facilitate adjustment of the fastening position of the Perlin 700. Structure system.

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