JPH09250220A - Mounting structure of solar cell module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To mount solar cell modules on a tiled roof in such a state a eliminating rain leaking and resisting against wind pressure. SOLUTION: A channel steel 11 is fixed to a rafter 1 from above a roof board 2 in such a state as setting its groove faced upward. The head part of a bolt 12 having a nut 13 and a washer 14 fitted thereto is fitted in groove of the channel steel 11. Secondly, after the bolt 12 is made to pass through the top part of a roof tile 3, the nut 13 is fastened so as to be fixed to the channel steel 11. A lateral bar 4 is put on the roof tile 3 and fixed thereto by fastening the nut 20, and lastly the solar cell module is fitted to the lateral bar 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell module mounting device for mounting a solar cell module for photovoltaic power generation on a tiled roof.

[0002]

2. Description of the Related Art In a solar power generation device, a solar cell module is installed on the roof of a building to convert light energy of the sun into DC power. DC power is converted to AC power by an inverter and supplied to the load inside the building via the distribution board. FIG. 5 is a perspective view showing a conventional device for mounting a solar cell module. Conventionally, as shown in this figure, a snow stopper metal fitting 5 is used as a metal fitting for fixing the horizontal rail 4 on which the solar cell module is mounted. Originally, the snow stopper 5 is arranged on the roof to fix a member that prevents a large amount of snow from falling from the roof of a building in a snowy area. When fixing the horizontal rail 4 with the snow stopper 5, the snow stopper 5 is fixed to the base plate 2 with a nail, the horizontal rail 4 is fixed to the snow stopper 5, and the solar cell module is fixed to the horizontal rail 4. Both ends of the reinforcing plate 6 are fixed to the rafter 1, and the fixing portion of the snow stopper 5 is suppressed at the central portion of the reinforcing plate 6 to increase the mounting strength.

[0003]

However, when the above snow stopper 5 is used, if the force parallel to the roof tile 3 can be held but a force perpendicular to the roof tile 3, that is, a negative wind pressure acts, the snow stopper 3 can be used. Since 5 is a cantilever structure, the tip is lifted, and the horizontal rail 4 and the roof tile 3 are lifted accordingly, causing rain leakage. FIG. 6 is a vertical cross-sectional view showing a conventional solar cell module mounting device. In addition, as shown in this figure, the roof tile 3
When using the rod-shaped roof tile supporting bracket 7 to fix the cross rail 4 through the hole, it is desirable to fix the roof tile supporting bracket 7 to the rafter 1 when considering the mounting strength. But,
Since the roof tile support bracket 7 cannot be fixed to the rafter 1 at all times and is fixed to the base plate 2 via the plate 8, the strength is insufficient against negative wind pressure. The reason why the roof tile supporting bracket 7 cannot be fixed to the rafter 1 at all times is that the position where the roof tile supporting bracket 7 penetrates the roof tile 3 is the highest position of the roof tile 3 in order to prevent rain leakage, and the arrangement interval P _{1 of the} rafters ₁ This is because the arrangement interval P ₂ of the roof tile supporting bracket 7 is not the same and the position of the roof tile supporting bracket 7 and the position of the rafter 1 do not always match. An object of the present invention is to mount a solar cell module on a tiled roof without leaking rain and withstanding wind pressure.

[0004]

[Means for Solving the Problems] The above-mentioned object is a horizontal crossbar having a roof tile arranged on a roof plate fixed on a rafter of a roof and provided with a solar cell module which is arranged in a direction orthogonal to the rafter and carries out solar power generation. And a fixture for fixing the cross rail to the field board, in the solar cell module mounting device, the fixture is arranged below the cross rail, and both ends are fixed to the rafter from above the field board. A groove-shaped member having a groove formed in parallel with the cross rail, and a head fitted into the groove of the groove-shaped member,
A bolt that penetrates through the holes of the roof tile and the cross rail, a first nut that fastens the bolt head to fix the groove type member, and a bolt end portion that fastens the cross rail to the roof. This is achieved by being configured with a second nut that is fixed to the top of the tile. The above-mentioned object is a roof tile arranged on a roof plate fixed on a rafter of a roof, and a horizontal rail mounted with a solar cell module arranged in a direction orthogonal to the rafter for photovoltaic power generation. In a mounting device of a solar cell module having a fixing metal fitting to be fixed to, the fixing metal fitting, the long hole member which is arranged below the rafter and fixed at both ends to the rafter and forming a long hole in parallel with the cross rail, A bolt penetrating the long hole of the long hole member and the holes of the base plate, the roof tile, and the horizontal rail, and a first nut group for fastening and fixing the bolt head from both sides of the long hole member. , A second nut for fastening the bolt end portion to fix the cross rail to the roof tile top portion. According to the above configuration, the bolt can be fastened to any position of the groove-shaped member or the long-hole member having both ends fixed to the rafter, so if the bolt is fastened to the position where the height of the roof tile becomes the maximum, the solar cell module is obtained. It is possible to install it on a tiled roof without leaking rain and withstanding wind pressure.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a vertical sectional view showing the configuration of the embodiment of the present invention. As shown in this figure, a rafter 1 is nailed with a base plate 2, but up to this point the structure is a conventional roof. The attachment device 10 of the present embodiment includes a channel steel 11, a bolt 12, a nut 13, a nut 20, and a washer 14. A method of mounting the solar cell module using the mounting device 10 will be described below. First, with the groove of the channel steel 11 facing upward, both ends of the base plate 2 are attached to the rafter 1 with wood screws 1
Fix with 6. The bolt 12 with the groove of the channel steel 11 facing sideways
Alternatively, a clamp material may be used.

FIG. 2 is a side view showing the configuration of the embodiment of the present invention. This figure shows the channel steel 11 viewed from the axial direction, and the head of a bolt 12 having a nut 13 and a washer 14 attached to the groove of the channel steel 11 is fitted. Bolt 1 in this state
2 is in a state of being movable in the axial direction. Then, the bolt 12 is passed through the hole at the highest portion of the roof tile 3, and then the nut 13 is tightened to fix the groove steel 11. Then, a sealing material 15 is filled in the gap between the hole of the roof tile 3 and the bolt 12, the cross rail 4 is placed on the roof tile 3, and the nut 20 is tightened and fixed. Install the module. In this way, the cross rail 4 can be fixed to the rafter 1 using the mounting device 10.

Next, another embodiment will be described. Although the above embodiment is simple in structure in which the channel steel 11 is fixed to the rafter 1 from above the field board 2 with the wood screw 16, the joint strength between the channel steel 11 and the roof is relative to the rafter 1 and the field board 2. Wood screw 16
When a large joint strength is required, which is determined by the pull-out strength, the strength may be insufficient with respect to negative wind pressure in a region where a large typhoon strikes, for example. The thickness of the channel steel 11 for fixing the bolts 12 is restricted by the structure of the roof tile 3, so that the longer the length is, the lower the rigidity becomes and the sufficient strength cannot be obtained. Another embodiment describes an example in which sufficient strength is obtained.

FIG. 3 is a vertical sectional view showing the structure of another embodiment of the present invention. As shown in this figure, rafter 1 and base plate 2
Although it is fixed, it is a conventional roof structure so far. The mounting device 10 of the present embodiment has a gap 1
A combination of a pair of chevron steel 17 to form an elongated hole, a stud bolt 18, a nut 13, a nut 21, and a nut 2.
2, a washer 14, and a stopper 19. A method of mounting the solar cell module using the mounting device 10 will be described below. First, a pair of angle steel 17 is arranged in a direction orthogonal to the rafter 1, and both ends of the angle steel 17 are fixed to the lower side of the rafter 1 with wood screws 16.

FIG. 4 is a side view showing the configuration of another embodiment of the present invention. This figure shows the angle steel 17 as seen from the axial direction. The stud bolt 18 is passed between a pair of angle steel 17, and the nut 13, the stopper 19 and the nut 13, and the washer 14 are attached to both sides of the angle steel 17. . In this state, the stud bolt 17 is movable in the axial direction. Next, the stud bolts 17 are passed through the holes in the base plate 2 and the holes at the highest part of the roof tile 3, and then the nuts 13 are tightened to fix the angle steel 17. Then, the gap between the hole of the roof tile 3 and the stud bolt 17 is filled with the sealing material 15, and the cross rail 4 is attached.
The roof tile 3 is mounted on the roof tile 3 through the hole of (1), and the nut 21 is tightened and fixed. Finally, the unillustrated solar cell module is attached to the cross rail 4. In this way, the negative wind pressure acting on the mounting device 10 is received by the compression on the rafter 1, so that the horizontal rail 4 can be firmly fixed.

[0010]

According to the present invention, the bolt can be fastened to any position of the groove-shaped member or the long-hole member fixed to the rafter, so if the bolt is fastened to the position where the height of the roof tile is the highest, the sun The battery module can be mounted on a tiled roof without leaking rain and withstanding wind pressure.

[Brief description of drawings]

FIG. 1 is a longitudinal sectional view showing a configuration of an embodiment of the present invention.

FIG. 2 is a side view showing the configuration of the embodiment of the present invention.

FIG. 3 is a vertical sectional view showing the configuration of another embodiment of the present invention.

FIG. 4 is a side view showing a configuration of another embodiment of the present invention.

FIG. 5 is a perspective view showing a conventional device for mounting a solar cell module.

FIG. 6 is a vertical cross-sectional view showing a conventional solar cell module mounting device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Rafter 2 Field plate 3 Roof tile 4 Cross rail 5 Snow stop metal fitting 6 Reinforcing plate 7 Roof tile supporting metal fitting 8 Plate 10 Mounting device 11 Groove steel 12 Bolt 13 Nut 14 Washer 15 Sealing material 16 Wood screw 17 Mountain steel 18 Stud bolt 19 Stopper 20 Nut 21 Nut 22 Nut

Claims (2)

[Claims] 1. A cross rail mounted with a solar cell module arranged on a roof tile fixed on a roof rafter in a direction orthogonal to the rafter on a roof tile, and a cross rail, and the cross rail. In a device for mounting a solar cell module having a fixing bracket for fixing to a main plate, the fixing bracket is arranged below the horizontal rail, and both ends are fixed to the rafter from above the main plate to form a groove in parallel with the horizontal rail. The groove-shaped member and the head of the groove-shaped member are fitted in the grooves of the groove-shaped member, and the bolt that penetrates through the holes of the roof tile and the cross rail is fastened to the groove-shaped member by fastening the bolt head. The first nut,
A mounting device for a solar cell module, comprising: a second nut that fastens the end portion of the bolt and fixes the horizontal rail to the roof tile top portion. 2. A cross rail mounted with a solar cell module arranged on a roof tile fixed on a roof rafter in a direction perpendicular to the rafter on a roof tile fixed to the roof board, and the cross rail. In a mounting device for a solar cell module having a fixing bracket for fixing to a main plate, the fixing bracket is arranged below the rafter and fixed at both ends to the rafter to form a long hole member in which a long hole is formed in parallel with the cross rail. ,
A bolt penetrating the long hole of the long hole member and the holes of the base plate, the roof tile, and the horizontal rail, and a first nut group for fastening and fixing the bolt head from both sides of the long hole member. And a second nut that fastens the end portion of the bolt to fix the horizontal rail to the roof tile top portion.