JP2012001908A - Solar battery installation structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar battery installation structure for a metal-plate roof, which can form a stable and rigid fitting condition and eliminate a risk of water leakage.SOLUTION: The solar battery installation structure comprises rubber blocks and fixing metal pieces. Each of the rubber blocks is born on a roof surface on both sides of a standing seam that is positioned inside a groove on the bottom face of the rubber block, while the fixing metal pieces are firmly fixed on the roof by holding the standing seam at both sides of the rubber block along the standing seam. Each one of the fixing metal pieces has stoppers that are firmly fixed in front and behind the rubber block. A frame for solar battery module installation is born on and secured to the rubber blocks, and a solar battery module is fitted on the frame.

Description

  The present invention relates to a structure for attaching a solar cell to a metal plate thatched roof.

  As a structure for attaching a solar cell to a metal plate thatched roof, there is provided a structure in which a mounting hole is provided in a metal thatched plate by screwing or the like. In this structure, the above holes are water-stopped by waterproof packing or the like. Is done.

JP-A-10-169131

  However, with the mounting structure as described above, it is difficult to completely stop such mounting holes even if water is stopped by waterproof packing, etc., and it may cause rain leakage or snowmelt in snowy areas. There is a problem that it is easy to cause trouble.

  In view of the problems as described above, the present invention provides a structure for mounting a solar cell on a metal plate thatched roof that can form a stable and stable mounting state and can eliminate the risk of water leakage. The issue is to provide.

The above-described problem is a structure for mounting a solar cell on a metal plate thatched roof having a standing part,
Rubber block and mounting hardware are provided,
The rubber block has a groove portion on the lower surface portion, and the standing helix portion is passed through the groove portion, so that the rubber block is supported on the roof surfaces on both sides sandwiching the standing helix portion, and stands by the standing helix portion. Held in the positioning state in the lateral direction perpendicular to the direction in which the hull extends,
The mounting hardware is provided on both sides of the rubber block in the extending direction of the standing portion, and is attached to the roof in a fixed state by sandwiching the standing portion extending out from the groove portion of the rubber block,
These mounting hardware are provided with stoppers positioned before and after the rubber block in the extending direction of the standing part, and the front and rear stoppers hold the rubber block in a positioning state in the extending direction of the standing part. Each stopper is fixedly attached to the front and back of the rubber block,
A solar cell module mounting frame is supported and mounted on the rubber block, and the solar cell module is mounted on the frame. .

  In this mounting structure, a rubber-like block is used, and the rubber-like block is supported on the roof surfaces on both sides sandwiching the raised portion, and a frame for attaching a solar cell module is supported on the rubber-like block. Therefore, a mechanically stable attachment state can be formed by the elasticity of the rubber block.

  In addition, the rubber block is held in the positioning state in the lateral direction perpendicular to the extending direction of the standing portion by the standing portion passed through the groove portion of the lower surface portion, and the front and rear stoppers by the mounting hardware. In such a positioning and holding state, the stopper of each mounting hardware is fixedly attached to the front and back of the rubber block, and each mounting hardware is Since the structure is attached to the roof in a fixed state by sandwiching the hull portion, a stable and firm attachment state can be formed.

  In addition, each mounting hardware is configured so as to be attached to the metal plate-fired roof by sandwiching the standing part, so that the metal-made steel plate is perforated when attached to the metal plate-fired roof. Therefore, the risk of water leakage can be eliminated.

  Since the structure for attaching a solar cell to a metal plate thatched roof according to the present invention is as described above, it is possible to form a stable and secure attachment state and to eliminate the risk of water leakage. .

The attachment structure of embodiment is shown, A figure (I) is a front view, A figure (B) is a cross-sectional side view. FIG. 1 (a) is an exploded perspective view of the mounting structure, and FIG. 2 (b) is a perspective view of a rubber block. Fig. (A) is a front view showing a method of attaching the rubber block and the mounting hardware to the roof, and Fig. (B) is a side view of the same. Fig. (A) is a front view showing a method for attaching a solar cell module to the roof, and Fig. (B) is a side view of the same.

  Next, embodiments of the present invention will be described with reference to the drawings.

  In the mounting structure of the embodiment shown in FIGS. 1 to 4, reference numeral 1 denotes a metal plate-roofed roof, 2 denotes a standing roof portion, and in this embodiment, the standing shell portion 2 extends in the roof inclination direction. 3 is a rubber block, 4 and 4 are mounting hardware, 5 is a lower frame, 6 is an upper frame, and 7 is a solar cell module.

  The rubber block 3 has a rectangular parallelepiped shape or a cubic shape, and is provided with a groove portion 8 on the lower surface portion as shown in FIG. 2 (b), and stands in the groove portion 8 as shown in FIGS. The rubber block 3 is supported on the roof surfaces 9 on both sides sandwiching the standing portion 2 by passing the standing portion 2, and the standing portion 2 extends by the standing portion 2. In a lateral direction orthogonal to the direction, that is, a horizontal direction orthogonal to the roof inclination direction, the positioning state is maintained in a precise or a certain amount of play.

  In the present embodiment, the groove portion 8 is provided in a cross shape, but this can be used for a metal plate thatched roof having a standing portion extending in a horizontal direction perpendicular to the roof inclination direction. Therefore, when such combined use is not considered, the groove portion may be provided in a single character.

  Further, as shown in FIGS. 2 and 3, the rubber block 3 is provided with a hole 10 that penetrates in the vertical direction and is positioned at the cross-shaped intersection of the groove portion 8. A screw shaft 11 composed of a headed bolt for connecting the two is inserted and arranged so that the head 11a faces downward and the tip side protrudes upward from the upper surface of the rubber block 3 so as to be in an upward retaining state. ing. It goes without saying that the lower end portion of the screw shaft 11 is inserted in such an arrangement that does not hinder the standing portion 2 passed through the groove portion 8.

  As shown in FIGS. 2 to 4, the mounting hardware 4, 4 is provided on both sides of the rubber block 3 in the extending direction of the standing hull portion 2, that is, in the roof inclination direction. Each mounting hardware 4 is provided with a pair of clamping parts 4a, 4a, and the clamping parts 4a, 4a are arranged so as to sandwich the standing part 2 extending from the groove part 8 of the rubber block 3 and extending outward from both sides. By being fastened with bolts 4b, the standing hull portion 2 is sandwiched and attached to the roof in a fixed state.

  These mounting hardware 4 and 4 are provided with stoppers 4c and 4c positioned in front of and behind the rubber block 3 in the extending direction of the standing hull 2, and the rubber blocks are provided by the front and rear stoppers 4c and 4c. 3 is held in a well-positioned state in the direction in which the raised portion 2 extends, i.e., the roof inclination direction, and the stoppers 4c and 4c are fixed to the front and rear surfaces of the rubber block 3 with screws 4d or the like. It is attached.

  The lower frame 5 is supported on the rubber-like block 3 so as to be directed in the extending direction of the standing portion 2, and is rubber-like by a screw shaft 11 provided on the rubber-like block 3 as shown in FIG. An upper frame 6 connected to the block 3 and oriented in a direction orthogonal to the lower frame 5 is supported on the lower frame 5, and the upper and lower frames 5, 6 are attached to the screw hardware 12 at their intersections. The solar cell module 7 is attached to the upper frame 6 by a fixed hardware 13.

  In the above mounting structure, the rubber block 3 is used, and the rubber block 3 is supported on the roof surfaces 9 on both sides sandwiching the raised portion 2 and mounted on the rubber block 3 for mounting the solar cell module. Since the frame 5 is supported, it is possible to form a mechanically stable attachment state due to the elasticity of the rubber block 3.

  Moreover, the rubber block 3 is held in a positioning state in the lateral direction perpendicular to the extending direction of the standing portion 2 by the standing portion 2 passed through the groove portion 8 on the lower surface portion, and the mounting bracket 4 , 4 is held in the positioning state in the extending direction of the standing hull portion 2 by the front and rear stoppers 4c, 4c. It is attached to the front and rear surfaces of the door in a fixed state with screws 4d, and each mounting hardware 4 and 4 has a structure in which it is attached to the roof in a fixed state by sandwiching the standing flange portion 2, so that it is stable A good and firm mounting condition can be formed.

  When it is necessary to form a more firmly attached state, the rubber-like block 3 and the roof surfaces on both sides sandwiching the standing-up portion 2 may be bonded with an adhesive.

  In addition, each mounting hardware 4, 4 is configured to be attached to the metal plate-fired roof by sandwiching the standing-up portion 2, so that metal metal is used for attachment to the metal plate-fired roof. There is no need to perforate the plate, so that the risk of water leakage can be eliminated.

DESCRIPTION OF SYMBOLS 1 ... Metal plate thatched roof 2 ... Standing part 3 ... Rubber block 4 ... Mounting bracket 4a ... Holding part 4c ... Stopper 5, 6 ... Frame 7 ... Solar cell module 8 ... Groove part

Claims (1)

A solar cell mounting structure on a metal plate thatched roof with a standing edge,
Rubber block and mounting hardware are provided,
The rubber block has a groove portion on the lower surface portion, and the standing helix portion is passed through the groove portion, so that the rubber block is supported on the roof surfaces on both sides sandwiching the standing helix portion, and stands by the standing helix portion. Held in the positioning state in the lateral direction perpendicular to the direction in which the hull extends,
The mounting hardware is provided on both sides of the rubber block in the extending direction of the standing portion, and is attached to the roof in a fixed state by sandwiching the standing portion extending out from the groove portion of the rubber block,
These mounting hardware are provided with stoppers positioned before and after the rubber block in the extending direction of the standing part, and the front and rear stoppers hold the rubber block in a positioning state in the extending direction of the standing part. Each stopper is fixedly attached to the front and back of the rubber block,
A structure for mounting a solar cell on a metal plate roof, wherein a frame for mounting a solar cell module is supported and mounted on the rubber block, and the solar cell module is mounted on the frame.

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