JP5153406B2 - Solar cell module mounting device - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a solar cell module mounting device for mounting a plurality of solar cell modules provided side by side to a building, and more particularly, to a solar cell module mounting device including mounting members arranged at equal intervals in a building. Is.

  With regard to the solar cell module mounting apparatus, conventionally, a flange formed on the frame of the solar cell module is sandwiched between a claw metal fitting and a base metal fitting (installation member), and the base metal fitting is further mounted on the roof. A method has been proposed in which the solar cell module is installed on the roof by screwing to (see, for example, Patent Document 1).

JP 11-324259 A

  When installing a plurality of solar cell modules side by side on the roof, for example, there is a case where it is desired to install a small module having a size smaller than that of a normal solar cell module at the end of the solar cell module array. However, according to the prior art, the rafters to which the base metal fittings are screwed are generally provided at equal intervals on the roof, so when the length of the small solar cell module is less than the predetermined pitch number of the rafters, It cannot be installed.

  That is, when the position where the solar cell module installation member can be provided has predetermined restrictions (conditions) such as rafters provided at equal intervals on the roof, the installation position and installation direction of the solar cell module And the installation flexibility, such as the installation range, was greatly limited.

  The present invention has been made in view of the above, and relaxes the restriction of the degree of freedom of installation of the solar cell module due to the limitation of the installation position of the installation member of the solar cell module, and more with respect to the installation conditions of the solar cell module. It aims at obtaining the attachment device of the solar cell module which can be taken as what increased the freedom degree.

  In order to solve the above-described problems and achieve the object, the solar cell module mounting apparatus of the present invention includes a plurality of solar cell modules each having a solar cell panel and a frame surrounding an outer edge portion of the solar cell panel. In a solar cell module mounting apparatus to be attached to a building, a pair of connecting members that are disposed at opposite corners of adjacent solar cell modules and connect the frames of adjacent solar cell modules together, and the building And a plurality of installation members for fixing the solar cell module to a building by supporting the frame of the integrated solar cell module.

  According to this invention, the connecting member connects and integrates adjacent solar cell modules, and the installation member supports the frame of the integrated solar cell module and fixes the solar cell module to the roof. The effect of relaxing the restriction of the degree of freedom of installation of the solar cell module due to the restriction of the installation position of the installation member of the solar cell module and increasing the degree of freedom with respect to the installation conditions of the solar cell module. Play.

  Embodiments of a solar cell module according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment FIG. 1 is a perspective view of a solar cell module to which a solar cell module mounting apparatus according to the present invention is applied, and shows a state in which a frame is attached to a solar cell panel. FIG. 2 is a front view of the solar cell module. 1 and 2, the solar cell module 80 includes a solar cell panel 70 in which a plurality of solar cells 60 are arranged, and a frame 10 that surrounds the outer edge of the solar cell panel 70 over the entire circumference. The frame 10 is configured by connecting two opposing long side frames 10a and 10a and two opposing short side frames 10b and 10b.

  In the solar cell panel 70, a transparent substrate (glass) (not shown) is arranged on the light receiving surface side, and a plurality of solar cells 60 connected in series or in parallel are arranged side by side on the back surface side of the transparent substrate. The battery cell 60 is produced by sealing with a resin such as EVA (ethylene vinyl acetate) or an electrically insulating material such as PET (polyethylene terephthalate).

  The frame 10 is manufactured by extrusion molding of aluminum or the like, and covers the outer edge of the solar cell panel 70 over the entire circumference with a U-shaped portion having a U-shaped cross section. The frame 10 is fixed to the solar cell panel 70 via a butyl-based sealing material or a silicon-based adhesive filled in the U-shaped portion to reinforce the solar cell panel 70, and the solar cell panel 70. It should be attached to an installation member (not shown) provided in a building such as a house or a building.

  FIG. 3 is a perspective view showing an embodiment of a solar cell module mounting apparatus according to the present invention. The example shown in FIG. 3 shows a case where a regular solar cell module 80 and a small solar cell module 80A having a size 1/2 the regular size are installed. In addition, the solar cell modules 80 and 80A are shown only by the frame 10 so that the method of supporting the mounting device can be clearly understood. The solar cell modules 80 and 80A are provided side by side so that one of the short side frames 10b are adjacent to each other. The solar cell module mounting device fixes a pair of connecting members 50 and 50 that connect two adjacent solar cell modules 80 and 80A together, and the integrated solar cell modules 80 and 80A to the roof. And a plurality of installation members 55.

  The connecting member 50 is disposed at both corners of the short side frames 10b, 10b facing each other of the adjacent solar cell modules 80, 80A, and is connected in the connecting direction of the adjacent solar cell modules 80, 80A. The end portions of the extending long side frames 10a and 10a that are opposed to each other are sandwiched between the two divided members and firmly connected, so that the solar cell modules 80 and 80A are integrated.

  The installation member 55 is arranged at a predetermined interval in a direction perpendicular to the inclination direction of the roof (that is, the ridgeline direction of the roof), and supports the frame 10 of the solar cell modules 80 and 80A integrated by the connecting member 50. Thus, the solar cell modules 80 and 80A are fixed to the roof. Specifically, the installation member 55 is screwed to a rafter 75 provided at a predetermined pitch D on the roof, and supports the solar cell modules 80 and 80A from the rafter 75. The pitch D of the rafters 75 is, for example, 455 mm. In addition, in the solar cell module mounting device of the present embodiment, the installation member 55 is not limited to that shown in FIG.

  FIG. 4 is a cross-sectional view showing a cross-sectional shape of the frame 10 (long-side frame 10a) of the solar cell modules 80 and 80A. The frame 10 has a U-shaped cross section and has a U-shaped part 11 that sandwiches the outer edge of the solar cell panel 2 over the entire circumference, and an extension formed so as to extend from the U-shaped part 11 to the back side of the panel. 12, an inner flange portion 13 formed to extend inward from the lower end of the extension portion 12, and an outer flange portion 14 formed to extend outward from the back surface of the U-shaped portion 11. . The front end edge portion of the outer flange portion 14 is bent upward so as to engage with an upper connection fitting of the connection member 50 described later. The outer flange portion 14 is provided on the two long side frames 10a and 10a extending in the connecting direction of the frame 10, but is provided on the two short side frames 10b and 10b orthogonal to the connecting direction. It is not done. The two short-side frames 10b and 10b facing each other adjacent to each other of the solar cell modules 80 and 80A are in close contact with each other on the back surfaces where the outer flange portion 14 is not provided.

  FIG. 5 is a perspective view showing a state in which the connecting member 50 connects two adjacent solar cell modules. FIG. 6 is a perspective view of the state in which the connecting member 50 connects two adjacent solar cell modules as viewed from the back side. FIG. 7 is a cross-sectional view of the connecting portion showing the cross-sectional shape of the connecting member 50. In FIGS. 5 and 6, only the frame 10 is shown so that the method of supporting the solar cell module can be clearly understood. 5 to 7, the connecting member 50 includes an upper connecting fitting 51 that engages with the outer flange portion 14 of the long side frame 10a, the inner flange portion 13 of the long side frame 10a, and the inner flange portion 13 of the short side frame 10b. And a lower connection fitting 52 that engages with the lower connection fitting 52.

  The upper connection fitting 51 has a substantially L-shaped cross section, and includes a main body portion 51a extending along the outer surface of the long side frame 10a, and a flange portion 51b formed to extend outward from the lower end of the main body portion 51a. Has been. A hollow portion 51c is formed in the main body 51a in order to improve the strength, and the upper connecting fitting 51 has the hollow portion 51c in close contact with the outer surface of the long side frame 10a. Further, the upper end edge of the main body 51a is bent so as to be folded inward to form a holding portion 51d, and the upper connecting metal 51 engages the holding edge 51d with the tip edge of the outer flange portion 14. In this way, the outer flange portion 14 is gripped from the outside. A fastening hole 51e is drilled in the main surface of the flange portion 51b.

  The lower connecting bracket 52 is substantially flat and has a main body 52a extending along the lower surface of the long side frame 10a, and a holding portion 52b formed by folding the inner edge of the main body 52a so as to be folded upward. The lower connecting fitting 52 holds the inner flange portion 13 from the inside so that the holding portion 52b is engaged with the inner flange portion 13. As shown in FIG. 6, the holding portion 52b has a sandwiched portion 52c formed by partially removing the upper portion of the central portion that is bent so as to be folded upward. The lower connection fitting 52 sandwiches the two short-side frames 10b and 10b (inner flange portions 13) facing each other from both sides in the coupling direction by the sandwiching portion 52c. The lower connection fitting 52 suppresses the separation of the integrated solar cell modules 80 and 80A and restricts the movement of itself (the connection member 50) in the module connection direction by the sandwiched portion 52c. A fastening hole 52e is formed in the main surface of the main body 52a.

  The upper connecting bracket 51 and the lower connecting bracket 52 include a bolt that sandwiches both ends of the long side frames 10a and 10a of the solar cell modules 80 and 80A facing each other in the vertical direction and penetrates the fastening holes 51e and 52e, and the bolt The solar cell modules 80 and 80A are firmly connected and integrated with each other by a nut engaged with the screw. In addition, the holding part 51d, the holding part 52b, and the sandwiching part 52c realize a strong connection between the solar cell module 80 and the solar cell module 80A, and also function as a detent for itself (the connecting member 50).

  With the above-described structure, the connecting member 50 integrally connects the fixed solar cell module 80 and the small solar cell module 80A. Thereby, the bending of the flame | frame 10 at the time of a surface load or a local load application can be suppressed, and the high intensity | strength of a solar cell module is enabled.

  According to the solar cell module mounting apparatus having such a configuration, the connecting member 50 is firmly connected and integrated with the adjacent solar cell modules 80 and 80A, and the installation member 55 is integrated with the solar cell module 80 and 80A. Since the 80A frame 10 is supported and fixed to the roof, it is possible to install a small solar cell module 80A that could not be installed conventionally.

  In the present embodiment, two short side frames 10b, 10b adjacent to each other are generally opposed to each other, and the two long side frames 10a, 10a extending in the connecting direction with their end portions butted are connected to each other. The two solar cell modules are connected by sandwiching both ends with the connecting member 50. However, the present invention is not limited to this, and when connecting two solar cell modules having the same long side frame length, The frames may be opposed to each other, and the short side frames extending in the connecting direction with butting ends may be sandwiched between the connecting members 50 and connected.

  FIG. 8 is a front view showing another application example of the solar cell module mounting apparatus of this embodiment. In this example, a regular solar cell module 80 and a small trapezoidal solar cell module 80B are installed. The connecting member 50 integrally connects the adjacent solar cell modules 80 and 80B. The connecting member 50 is disposed at opposite corners of the adjacent solar cell modules 80 and 80B. The installation members 55 are arranged at a predetermined pitch in a direction orthogonal to the inclination direction of the roof, and support the frame 10 of the solar cell modules 80 and 80B integrated. The installation member 55 is disposed on a rafter 75 provided at a predetermined pitch D on the roof, and supports the solar cell modules 80 and 80B from the rafter 75.

  FIG. 9 is a front view showing still another application example of the solar cell module mounting device of this embodiment. In this example, a regular solar cell module 80 and a small triangular solar cell module 80C are installed. The connecting member 50 integrally connects the adjacent solar cell modules 80 and 80C. The connecting member 50 is disposed at opposite corners of the adjacent solar cell modules 80 and 80C. The installation members 55 are arranged at a predetermined pitch in a direction orthogonal to the inclination direction of the roof, and support the frames 10 of the solar cell modules 80 and 80C integrated. The installation member 55 is disposed on a rafter 75 provided at a predetermined pitch D on the roof, and supports the solar cell modules 80 and 80C from the rafter 75.

  As described above, according to the solar cell module mounting device of the present embodiment, the connecting member 50 connects and integrates adjacent solar cell modules, and the installation member 55 includes the integrated solar cell module. The frame 10 is supported and fixed to the roof, so that it is possible to install small, small trapezoidal, and small triangular solar cell modules that could not be installed in the past. The restriction on the degree of freedom of installation of the battery module can be relaxed and the degree of freedom can be increased with respect to the installation conditions of the solar cell module.

  As described above, the solar cell module mounting apparatus according to the present invention is suitable for being applied to a solar cell module mounting apparatus that mounts a plurality of installed solar cell modules on a roof. The present invention is optimally applied to a solar cell module mounting apparatus including mounting members arranged at intervals.

It is a perspective view which shows a mode that a flame | frame is attached to the solar cell panel of the solar cell module to which the attachment apparatus of the solar cell module concerning this invention is applied. It is a front view of a solar cell module. It is a perspective view which shows embodiment of the attachment apparatus of the solar cell module concerning this invention. It is sectional drawing which shows the cross-sectional shape of the flame | frame of a solar cell module. It is a perspective view which shows a mode that a connection member connects two adjacent solar cell modules. It is the perspective view which looked at a mode that a connecting member connects two adjacent solar cell modules from the back side. It is sectional drawing of the connection part which shows the cross-sectional shape of a connection member. It is a front view which shows the other application example of the attachment apparatus of the solar cell module of this embodiment. It is a front view which shows the further another application example of the attachment apparatus of the solar cell module of this embodiment.

Explanation of symbols

10 frame 10a long side frame 10b short side frame 11 U-shaped part of frame (edge holding part)
12 Frame extension 13 Frame inner flange 14 Frame outer flange 50 Connection member 51 Upper connection bracket 51a Upper connection bracket main body 51b Upper connection bracket flange 51c Upper connection bracket hollow 51d Upper connection bracket holding Part 51e Fastening hole of upper coupling metal 52 Lower coupling metal 52a Lower coupling metal body 52b Lower coupling metal clamping part 52c Lower coupling metal clamping part 52e Lower coupling metal fastening hole 55 Installation member 60 Solar cell 70 Solar Battery panel 80 Solar cell module

Claims (3)

In a solar cell module mounting apparatus in which a plurality of solar cell modules having a solar cell panel and a frame surrounding an outer edge portion of the solar cell panel are mounted side by side on a building, in opposite corner portions of adjacent solar cell modules A pair of connecting members arranged and integrated by sandwiching and connecting two mutually facing end portions of the frames extending in the connecting direction of the adjacent solar cell modules;
A plurality of installation members that are arranged at equal intervals in the building and support the frame of the integrated solar cell module and fix the solar cell module to the building ;
The frame extending in the connecting direction is
An edge holding part for holding an outer edge part of the solar cell panel;
An outer flange having an extending portion extending outward from the edge holding portion, and a tip edge portion formed by bending the tip of the extending portion upward;
An extension extending from the edge holding portion to the back side of the solar cell panel;
An inner flange extending inwardly from the extension,
The connecting member is
The upper connecting bracket main body disposed along the edge holding portion and the extension of the frame extending in the connecting direction, and the upper connecting bracket main body folded so that the upper end of the upper connecting bracket main body is folded inward. An upper connecting bracket having an upper connecting bracket folded portion formed by
Formed by bending the lower connecting bracket main body portion disposed along the inner flange of the frame extending in the connecting direction and the lower connecting bracket main body portion so that the inner edge of the lower connecting bracket main body portion is folded upward. A lower connecting bracket having a lower connecting bracket folded portion,
The upper connecting bracket and the lower connecting bracket have the leading edge inserted between the upper connecting bracket folded portion and the upper connecting bracket main body, and the lower connecting bracket main body and the lower connecting bracket folded. The solar cell module mounting apparatus , wherein the solar cell module is fastened with the frame of the adjacent solar cell module sandwiched in the vertical direction in a state where the inner flange is inserted between the two parts . The solar cell module mounting device according to claim 1, wherein the lower connecting bracket includes a sandwiching portion that sandwiches two frames of adjacent solar cell modules facing each other from both sides in the coupling direction. . The said installation member is arrange | positioned at the rafter provided at equal intervals by the predetermined width in the direction orthogonal to the inclination of a roof. The attachment apparatus of the solar cell module of Claim 1 or 2 characterized by the above-mentioned.

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