JP5178131B2 - Solar cell module mounting jig and mounting structure - Google Patents

Description

  The present invention relates to an attachment jig for attaching a solar cell module to a flat roof such as a folded plate roof having a plurality of tops or projections, and an attachment structure using the attachment jig.

  Conventionally, attachment hardware and an attachment structure for attaching a solar cell module to a folded plate roof are known (see Patent Documents 1 and 2).

  For example, in Patent Document 1, a mounting bracket is installed on the top of a folded plate roof, the solar cell module is fixed to a fastening bolt protruding upward from the mounting bracket, and the solar cell module is parallel to the roof surface. It is attached.

Further, in Patent Document 2, a clamp piece of left and right separates is tightened with a bolt to clamp the top of the folded plate roof, a frame fixing bracket is attached to the left and right clamp piece, and the solar cell module is inclined with respect to the roof surface. The structure to install is disclosed.
Japanese Patent No. 3299877 JP 2001-193231 A

  However, in the mounting hardware of Patent Document 1, in order to install the solar cell module obliquely with respect to the roof surface, a mounting hardware provided with fastening bolts having different lengths on the upper side and the lower side must be separately manufactured. I must.

  Moreover, in the structure of patent document 2, the number of attachment parts increases, installation takes time, and when a separate left-right clamp piece is attached to the top part of a folded-plate roof, it is easy to produce a shift | offset | difference.

  Accordingly, the present invention provides a solar cell module mounting jig that can be easily mounted and can be supported by adjusting the angle and height according to the installation angle of the solar cell module, and the mounting jig. The object is to provide a mounting structure using the.

  In order to achieve the above object, a solar cell module mounting jig according to the present invention is a mounting jig for mounting a solar cell module on a flat roof having a plurality of tops or projections, the flat roof A pair of sandwiching portions arranged between any top or convex portion, a connecting portion that extends upward from the upper edge of one sandwiching portion and is folded back and connected to the upper edge of the other sandwiching portion, An insertion opening that opens a part of the folded portion of the connecting portion, a support body that has a pedestal portion that supports the solar cell module by inserting a lower portion into the insertion opening, two opposing surfaces of the connecting portion, and A through hole penetrating the support and a bolt portion inserted through the through hole to fasten two opposing surfaces of the connecting portion are provided.

  Here, the sandwiching portion is formed in a shape that matches the outer shape from the side surface to the top surface of the top portion or the convex portion, and the connecting portion is formed by folding the plate member integrated with the sandwiching portion in half. The insertion opening may be configured to be opened in a slit shape at a portion excluding both side edges of the connection portion.

  Further, the solar cell module mounting structure of the present invention is a solar cell module mounting structure in which the solar cell module is tilted and mounted on a flat roof having a plurality of tops or projections, and the solar cell module mounting structure is described above. The holding part of the tool is attached to the top or convex part of the flat roof facing the upper side and the lower side of the slope, respectively, and the insertion port has an upper side above the lower side. A support body having a long protruding length is inserted, and the bolt portion is attached to the through hole and fastened, whereby the clamping portion is crimped to the top portion or the convex portion.

  In the solar cell module mounting jig and mounting structure of the present invention configured as described above, a pair of sandwiching portions that sandwich the top or convex portion of the flat roof are connected by a connecting portion. In addition, a support body having an arbitrary length having a pedestal portion can be inserted into the insertion opening of the connection portion, and fixing of the support body and fastening of the connection portion for crimping the clamping portion to the top portion or the convex portion can be performed at the same time. it can.

  For this reason, the installation of the solar cell module is facilitated, and the installation angle can be easily adjusted only by changing the length of the support to be attached or the angle of the pedestal.

  Further, by forming the sandwiched portion into a shape that matches the outer shape of the folded plate roof from the top or the side surface of the convex portion to the top surface, the degree of adhesion with the top portion or the convex portion can be increased and can be made difficult to shift. .

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 2 is a perspective view for explaining an operation process for attaching the solar cell module 1 to the folded roof 2 as a flat roof.

  The folded plate roof 2 is a flat roof provided with top portions 21 at a predetermined pitch. Such a folded plate roof 2 is formed of, for example, a corrugated polyvinyl chloride coated steel plate, and the folded chevron forms the top 21 as shown in FIG.

  Further, as shown in FIGS. 2 and 4, a roof frame 22 and a ceiling 23 that support the folded plate roof 2 are provided below the folded plate roof 2.

  As shown in FIG. 1, the mounting jig 3 according to the present embodiment supports a sandwiching metal fitting 31 attached to the top portion 21 of the folded plate roof 2 and the solar cell module 1 in which the lower part is inserted into the sandwiching metal fitting 31. A support fitting 32 as a body, and a clamping fitting 31 and a bolt portion 33 attached to the through holes 314 and 322 of the support fitting 32 are provided.

  As shown in FIG. 3, the sandwiching metal 31 extends upward from a pair of sandwiching portions 311, 311 disposed across the top portion 21 of the folded plate roof 2 and the upper edge of one sandwiching portion 311. The connecting portion 312 that is folded back and connected to the upper edge of the other sandwiching portion 311, the insertion port 313 that opens a part of the folded portion 312 a of the connecting portion 312, and the two opposing surfaces of the connecting portion 312 pass through. A through hole 314 is provided.

  For example, the sandwiching portions 311 and 311 and the connecting portion 312 are formed by bending a single stainless steel plate. Further, the sandwiching portions 311 and 311 are each formed into a bowl shape matching the outer shape from the side surface to the upper surface of the top portion 21 (see FIGS. 1 and 3B).

  Then, the connecting portion 312 extending straight upward from the upper edge of the one sandwiching portion 311 is folded in half at the middle folded portion 312a and is extended toward the upper edge of the other sandwiching portion 311. That is, two opposing surfaces of the sandwiching portions 311 and 311 and the connecting portion 312 are formed symmetrically with respect to the perpendicular line from the folded portion 312a as shown in FIG.

  A through hole 314 penetrating in the horizontal direction is formed in two faces of the connecting portion 312 that are folded in two and facing each other. The through hole 314 is provided at a position where the clamping portions 311 and 311 move in the closing direction when a bolt portion 33 described later is attached and tightened.

  In addition, the folded portion 312a of the connecting portion 312 has an insertion port 313 in which portions excluding both side edges are cut out in a slit shape so as to be slightly wider than the width of the insertion portion 321 of the support fitting 32 described later. Is formed. Further, the insertion port 313 is communicated with a hollow portion between two opposing surfaces of the connecting portion 312.

  The support metal fitting 32 is a metal fitting formed in an approximately L shape in a side view, and a flat plate portion extending in the vertical direction becomes an insertion portion 321, and a flat plate portion extending obliquely from the upper edge of the insertion portion 321. Becomes the pedestal 323 on which the solar cell module 1 is placed.

  A through hole 322 is formed in the insertion portion 321 at a position that communicates with the through hole 314 of the connecting portion 312 when the support fitting 32 is inserted from the insertion port 313. That is, the through holes 314 and 322 that penetrate the two opposing surfaces of the connecting portion 312 and the support fitting 32 are formed.

  In addition, the pedestal portion 323 is provided with a mounting hole 324 that penetrates in the vertical direction, and is used for mounting the solar cell module 1. That is, the pedestal part 323 is formed to be inclined at an angle corresponding to the installation angle of the solar cell module 1 and supports the solar cell module 1 from below with a surface.

  The bolt portion 33 includes a bolt 331 that is inserted into the through hole 314 of the connecting portion 312 and the through hole 322 of the support fitting 32, and a nut 332 that is screwed to the bolt 331.

  On the other hand, the height at which the solar cell module 1 is supported can be changed by changing the length of the insertion portion 321 of the support fitting 32.

  In FIG. 2, a mounting jig 3A in which a support metal 32A having a short projecting length is inserted is arranged on the lower side of the inclined solar cell module 1, and a mounting tool 3B having a long projecting length is inserted in the upper side. The state where the jig 3B is arranged is shown.

  That is, the difference between the support fitting 32B installed on the upper side and the support fitting 32A installed on the lower side defines the inclination angle of the solar cell module 1 installed thereon. If such mounting jigs 3A and 3B are used, the same part is used for the holding metal fitting 31, and the support metal fittings 32A and 32B are made into metal fittings having a desired protruding length, so that the photovoltaic power generation can be efficiently performed. It is possible to easily attach the solar cell module 1 to.

  Next, the construction method of the attachment structure of the solar cell module 1 using the attachment jig 3 of the present embodiment will be described.

  First, as shown in FIG. 1, the sandwiching metal fitting 31 is attached by sandwiching the top portion 21 of the folded plate roof 21 with sandwiching portions 311 and 311. Then, the insertion portion 321 of the support metal fitting 32 is inserted into the insertion port 313 of the holding metal fitting 31.

  At this time, as shown in FIG. 2, when the solar cell module 1 is inclined, mounting jigs 3A and 3A are attached to the top portion 21 of the folded plate roof 2 facing the lower side of the inclination, and the upper side of the inclination is attached. Mounting jigs 3B and 3B are attached to the top 21 facing each other.

  When the solar cell module 1 is lowered onto the mounting jigs 3A, 3A, 3B, 3B, the solar cells placed on the flat pedestals 323,... Inclined according to the installation angle. Module 1 is stable. Therefore, the solar cell module 1 is fixed to the pedestal portions 323,... Through bolts (not shown) through the mounting holes 324,.

  FIG. 4 is a cross-sectional view of the state in which a plurality of solar cell modules 1,...

  These solar cell modules 1,... Are mounted jigs 3 </ b> A, 3 </ b> B (3 </ b> C, 3 </ b> D) that are attached to the top portions 21,. It is installed on the top.

  Moreover, in order to arrange | position solar cell module 1, ... efficiently on the limited folded-plate roof 2, in projection jig 3A-3D, the protrusion length of the support metal fittings 32, ... is each adjusted. In addition, the projecting direction and angle of the pedestal 323 are also adjusted.

  Next, the effect | action of the attachment jig 3 and the attachment structure of the solar cell module 1 of this Embodiment is demonstrated.

  In the mounting jig 3 and the mounting structure of the solar cell module 1 of the present embodiment configured as described above, the pair of sandwiching portions 311 and 311 that sandwich the top portion 21 of the folded plate roof 2 are connected by the connecting portion 312. One clamping bracket 31 is provided.

  For this reason, the holding metal fitting 31 can be easily fitted to the top portion 21 without causing a positional shift as in the case of attaching a separate clamp that is divided into left and right in the past.

  Further, since the support fitting 32 having the insertion portion 321 having an arbitrary length can be inserted into the insertion port 313 of the connection portion 312, the height for supporting the solar cell module 1 can be easily adjusted. .

  Furthermore, the inclination angle of the pedestal portion 323 can be easily adjusted if only the support fitting 32 is provided. Moreover, the solar cell module 1 can be stably supported from below by the flat pedestal portion 323.

  Furthermore, after inserting the insertion part 321 of the support metal fitting 32 into the insertion port 313, the bolt 331 is inserted into the through hole 314 of the holding metal fitting 31 and the through hole 322 of the support metal fitting 32, and the nut 332 is screwed. The fixing of the support fitting 32 and the fastening of the connecting portion 312 for pressing the holding portions 311 and 311 to the top portion 21 can be performed at the same time.

  For this reason, the installation of the solar cell module 1 is facilitated, and the installation angle of the solar cell module 1 can be easily adjusted only by changing the length of the protruding length of the support bracket 32 to be attached or the inclination angle of the pedestal 323. Can do.

  That is, since the power generation efficiency of the solar cell module 1 varies depending on the direction with respect to the sun, if the installation angle of the solar cell module 1 can be adjusted by changing the support bracket 32, the optimal installation angle can be easily obtained.

  In addition, by forming the sandwiching portions 311 and 311 into a shape that matches the outer shape from the side surface to the top surface of the top portion 21 of the folded roof 2, the degree of close contact with the top portion 21 is increased and it is difficult to shift. .

  Although the best embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design changes that do not depart from the gist of the present invention are possible. Are included in the present invention.

  For example, in the said embodiment, although the case where the attachment jig | tool 3 was attached to the top part 21 of the folded-plate roof 2 as a flat roof was demonstrated, it is not limited to this, A corrugated slate board, a corrugated as a flat roof The attachment jig 3 can be attached to the top of the roof of a zinc iron plate, corrugated glass, or corrugated plastic plate.

  Moreover, the structure which attaches the attachment jig | tool 3 to the square tile-bar part which is a flat roof can be used as the flat roof made of the steel-plate tile-bar roof where the core material called a tile rod was provided with the predetermined pitch. .

It is a perspective view explaining the work process at the time of attaching the attachment jig of the best embodiment of this invention to the top part of a folded-plate roof. It is a perspective view explaining the operation | work process which attaches a solar cell module. It is a figure explaining the structure of an attachment jig, Comprising: (a) is a front view, (b) is a side view. It is sectional drawing explaining the attachment structure of the solar cell module of the best embodiment of this invention.

Explanation of symbols

1 Solar cell module 2 Folded plate roof (flat roof)
21 Top part 3, 3A-3D Mounting jig 311 Clamping part 312 Connection part 312a Folding part 313 Insertion port 314 Through-hole 32, 32A, 32B Support metal fitting (support)
322 Through-hole 323 Base part 33 Bolt part

Claims (5)

An attachment jig for attaching a solar cell module to a flat roof having a plurality of tops or projections,
A pair of sandwiching portions arranged across an arbitrary top or convex portion of the flat roof, and a connection extending upward from the upper edge of one sandwiching portion and folded back to be connected to the upper edge of the other sandwiching portion , A flat plate portion inserted between two opposing surfaces of the connecting portion from the insertion port, and a pedestal portion for supporting the solar cell module A through hole that penetrates the two opposing surfaces of the connecting portion and the support, and a bolt portion that is inserted through the through hole and fastens the two opposing surfaces of the connecting portion ,
The solar cell module mounting jig , wherein the pedestal portion is inclined with respect to the flat plate portion extending vertically . The sandwiching portion is formed in a shape that matches the outer shape from the side surface to the top surface of the top portion or the convex portion, and the connecting portion is formed by folding a plate material integrated with the sandwiching portion into two, The solar cell module mounting jig according to claim 1 , wherein the insertion opening is opened in a slit shape in a portion excluding both side edges of the connection portion. The solar cell module mounting jig according to claim 1 or 2 , wherein the support is formed in a substantially L shape in a side view. The solar cell module mounting jig according to any one of claims 1 to 3, wherein the inclination of the pedestal portion is set to an angle corresponding to an installation angle of the solar cell module. A solar cell module mounting structure for mounting a solar cell module inclined on a flat roof having a plurality of tops or projections,
The mounting portion of the solar cell module mounting jig according to any one of claims 1 to 4 is mounted on the top or convex portion of the flat roof facing the upper and lower sides of the slope, respectively.
In the insertion port, a support body having a longer protruding length than the lower side is inserted into the upper side,
A mounting structure for a solar cell module, wherein the bolt portion is attached to the through hole and tightened so that the clamping portion is crimped to the top portion or the convex portion.

Images