JP2008255707A - Panel plate fixing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce cost by facilitating the fixation of a panel plate to a base and enhancing waterproofness. <P>SOLUTION: Pedestals 5b and 6b of right-side and left-side frames 5 and 6 of solar cell modules 1 and 1' adjacent to each other on right and left sides are arranged on a rubber sheet 12. Screws 13a and 13b are inserted through holes 5g and 6g of the pedestals 5b and 6b, and fixed by being screwed into a sheathing roof board 11. A cover member 14 is arranged on a gap between the right-side and left-side frames 5 and 6 of the solar cell modules 1 and 1', and protrusive streaks 17a and 17b of planar portions 16a and 16b are fitted into recessed streaks 5i and 6i of the right-side and left-side frames 5 and 6, respectively. A screw 21 is screwed into the rubber sheet 12 and the sheathing roof board 11 from an operating hole 20 and a hole 19, and the cover member 14 is fixed by means of a fixing portion 18. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a panel plate fixing method for fixing, for example, a plurality of panels such as a solar cell module that generates power by sunlight on a roof.

  In recent years, solar power generation, which is installed on the roof of a house or the like as part of eco-energy and environmental measures, and generates power using sunlight, has attracted attention. In general, this solar power generation is to obtain power from a solar cell module in which a plurality of solar cells made of single crystal, polycrystal, amorphous silicon, etc. are arranged on a substrate and electrodes, wirings, etc. are arranged. Depending on the installation area, a plurality of solar cell modules are arranged in parallel.

  The conventional solar cell module is fixed on the roof by fixing a so-called rail made of metal in the inclined direction on the roof base plate, and screwing the sides of a plurality of solar cell modules on the rail, It defines the gap between battery modules.

  However, since the above-described rail is required for fixing the conventional solar cell module, the cost is increased, and the thickness of the rail is added to the thickness of the solar cell module, so that the appearance is not good. In addition, there is no sufficient measure for rainwater between the solar cell modules, and it is inevitable that rainwater is flooded onto the field plate.

  An object of the present invention is to provide a panel plate fixing method that solves the above-described problems, eliminates the need for rails, reduces costs, simplifies the process, and increases waterproofness.

  The technical features of the panel plate fixing method according to the present invention for achieving the above-described object are as follows. In the panel plate fixing method, a plurality of frame-like panel plates are arranged and fixed in a plane on a base. The frame of the panel plate is fixed on the base with a gap, a long cover member is attached between the frames so as to cover the gap, and the cover member is placed on the frames on both sides. Engage and fix to the base.

  According to the panel plate fixing method of the present invention, the panel plate can be easily fixed to the base body, the waterproofness is increased, and the cost is reduced.

The present invention will be described in detail based on the embodiments shown in the drawings.
FIG. 1 shows an exploded perspective view of a solar cell module 1 as a panel plate fixed on a roof. For example, a rectangular solar cell panel 2 having a size of about 1800 × 900 mm in length and width and around 5 mm in thickness is An aluminum alloy is extruded to be formed into a hollow, substantially quadrangular prism, and the upper frame 3 and the lower frame 4 that support the long side of the solar cell panel 2, and the right frame 5 that is similarly extruded and supports the short side; It is clamped by the left frame 6. And the solar cell module 1 is formed by fixing flame | frames via a screw. In FIG. 1, the area of the solar cell panel 2 is schematically shown smaller than the actual size in order to clearly display the structure.

  2 is an AA ′ sectional view of the upper frame 3, FIG. 3 is a BB ′ sectional view of the lower frame 4, FIG. 4 is a CC ′ sectional view of the right frame 5, and FIG. DD ′ cross-sectional views are shown, and the right frame 5 and the left frame 6 use the same members symmetrically.

  The length of the upper frame 3 is substantially the same as the length of the long side of the solar cell panel 2, and the solar cell panel 2 is located on the lower inner side of the upper frame 3 whose height and width are about 30 mm. A groove portion 3a is provided in the longitudinal direction to sandwich the ridge, and an eaves-like flange portion 3b is extended outward on the upper outer side, and two convex strip portions 3c, 3d are provided on the lower surface of the flange portion 3b. Are provided in the longitudinal direction. On the inner side, thread grooves 3e and 3f for threading are formed along the longitudinal direction. Furthermore, screw holes 3g and 3h are formed on the upper frame 3 in order to fix the lower frame 4 to another solar module adjacent to the upper side on the roof.

  Further, the lower frame 4 having the same length as the upper frame 3 is provided with a partition plate 4a for increasing the strength inside, and a groove portion 4b for sandwiching the solar cell panel 2 is provided inside the upper portion, and the upper surface thereof is provided on the upper surface. Are provided with recesses 4c and 4d in the longitudinal direction. Similarly to the upper frame 3, screw grooves 4 e and 4 f are formed in the longitudinal direction inside. Furthermore, on the lower frame 4, screw holes 4g and 4h are formed at positions where the screw holes 3g and 3h of the other upper frame 3 adjacent to the lower side overlap.

  The right frame 5 is substantially L-shaped with a height of about 30 mm, which is the same as the upper frame 3 and the lower frame 4, and the length of the right frame 5 is higher than the length of the short side of the solar cell panel 2. It is lengthened by the width of 4. A groove portion 5a for sandwiching the solar cell panel 2 is provided inside the upper portion of the right frame 5, and an L-shaped pedestal 5b for fixing projects in the longitudinal direction outside the lower portion. After the extrusion molding, the groove portion 5a in contact with the upper frame 3 and the lower frame 4 is cut so as not to get in the way.

  Further, holes 5c to 5f for inserting screws through the screw grooves 3e, 3f, 4e, and 4f of the upper frame 3 and the lower frame 4 are formed in the side surface of the right frame 5. Furthermore, holes 5g and 5h are formed in the pedestal 5b for fixing on the roof. On the upper surface of the right frame 5, a recess 5i for fitting a part of a cover member described later along the longitudinal direction is formed. The left frame 6 is also manufactured in the same manner as the right frame 5.

  When assembling, the solar cell panel 2 is fitted into the groove 3a of the upper frame 3 and the groove 4b of the lower frame 4, and then the groove 5a of the right frame 5 and the groove 6a of the left frame 6 are fitted into the solar cell panel 2. . In this case, the grooves 3a, 4b, 5a, and 6a may be filled with, for example, butyl rubber to improve waterproofness, adhesion, and the like.

  Next, the screws 7 are screwed into the screw grooves 3e and 3f of the upper frame 3 and the screw grooves 4e and 4f of the lower frame 4 from the holes 5c to 5f and 6c to 6f on the side surfaces of the right frame 5 and the left frame 6, respectively. When the screws are tapped while fixing the frames, the solar cell module 1 is completed as shown in FIG.

  FIG. 7 shows a cross-sectional view of a state in which a plurality of solar cell modules 1 are connected side by side on the roof in the left-right direction. A rubber sheet 12 having a predetermined width is bonded along the inclined direction on the roof base plate 11. The solar cell modules 1 are sequentially arranged downward from above the roof while the flange portion 3b of the upper frame 3 of the lower solar cell module 1 is superimposed on the lower frame 4 of the upper solar cell module 1. At this time, the pedestal 5b of the right frame 5 and the pedestal 6b of the left frame 6 of the solar cell modules 1, 1 'adjacent to the left and right are arranged on the rubber sheet 12 while being held at a predetermined interval. Screws 13a and 13b are inserted into holes 5g and 6g provided in the pedestals 5b and 6b, and are screwed and fixed to the base plate 11 via the rubber sheet 12. Note that the right frame 5 and the left frame 6 may be directly fixed to the field board 11 without using the rubber sheet 12.

  On the adjacent right frame 5 and left frame 6, that is, in the gap between the solar cell modules 1, 1 ', a long cover member 14 for waterproofing manufactured by press molding is attached.

  The long cover member 14 having a top portion 15 whose upper surface is bent in a mountain shape is formed on the lower surface of the flat portions 16a and 16b projecting from both mounting portions to the left and right sides, and the concave strip portion 5i of the right frame 5 and the left frame 6 Convex ridges 17a and 17b that engage with the concave ridge 6i are formed. Fixed portions 18 are suspended directly below the top portions 15, and holes 19 are provided at several locations in the longitudinal direction of the fixed portions 18. Screws are operated on the top portions 15 directly above the hole portions 19. An operation hole 20 is provided.

  The flat portions 16a and 16b of the cover member 14 are placed on the right frame 5 and the left frame 6 of the solar cell modules 1 and 1 'arranged on the roof, and the projecting strip portions 17a and 17b are formed into the recess strip portion 5i. , 6i. In this case, a convex strip portion may be formed on the right frame 5 and the left frame 6 and a concave strip portion may be formed on the plane portions 16a and 16b. In addition, it can substitute with packing instead of providing these ridge part and a concave part. Further, the screw 21 is screwed into the rubber sheet 12 and the base plate 11 from the operation hole 20 and the hole portion 19, and the cover member 14 is fixed by the fixing portion 18. The operation hole 20 for inserting the screw 21 has a small area with respect to the entire cover member 14 and does not affect the water leakage so much, but the operation hole 20 is sealed with a seal member after screwing. It may be occluded.

  As for the arrangement along the inclination direction of the solar cell modules 1, as shown in FIG. 8, the flange portion 3 b of the upper frame 3 of the lower solar cell module 1 is connected to the lower frame of the upper solar cell module 1 ′. 4 are stacked. At this time, as described above, the solar cell modules 1 are arranged from the top of the roof, but the concave portions 4c and 4d provided on the lower frame 4 of the upper solar cell module 1 ′ installed earlier are arranged. Then, the solar cell module 1 is overlapped so that the ridges 3c and 3d of the upper frame 3 are fitted.

  The screw 22 is inserted through the screw holes 3g and 3h of the flange portion 3b of the upper frame 3 of the lower solar cell module 1 ', and the screw holes 4g and 4h of the upper solar cell module 1' are tapped and flanged. The part 3 b is fixed to the lower frame 4.

  In the present embodiment, the case where the panel-like solar cell module is held has been described. However, in addition to the photovoltaic power generation, the panel plate can be fixed on the roof or the like.

It is a disassembled perspective view of a solar cell module. It is A-A 'sectional drawing of an upper frame. It is B-B 'sectional drawing of a lower frame. It is C-C 'sectional drawing of a right side frame. It is D-D 'sectional drawing of a left side frame. It is a perspective view of a solar cell module. It is sectional drawing of the state connected in the left-right direction. It is sectional drawing of the state connected in the up-down direction.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell module 2 Solar cell panel 3 Upper frame 3a, 4b, 5a, 6a Groove part 3b Flange part 3c, 3d, 17a, 17b Projection part 3e, 3f, 4e, 4f Screw groove 3g, 3h, 4g, 4h, 5g 5h, 6g, 6h Screw hole 4 Lower frame 4c, 4d, 5i, 6i Recessed portion 5 Right frame 5b, 6b Pedestal 6 Left frame 5c-5f, 6c-6f, 19 Hole portion 11 Field plate 12 Rubber sheet 14 Cover member 15 Top portion 16a, 16b Planar portion 18 Fixing portion 20 Operation hole

Claims (5)

  In a panel plate fixing method in which a plurality of frame-like panel plates are arranged and fixed in a plane on a base, the frames of the panel plates on both sides are fixed on the base by providing gaps, and the gaps are covered. A panel plate fixing method comprising: attaching a long cover member between the frames, engaging the cover members on the frames on both sides and fixing the cover member to the base body.   The panel plate fixing method according to claim 1, wherein the cover member engages the flange with flat portions protruding from both stationary portions.   Engagement of the cover member with the frame is performed by fitting a ridge or a groove formed on the lower surface of the flat portion to a groove or a ridge formed on the frame. The panel board fixing method according to claim 2, wherein the panel board is fixed.   The panel plate fixing method according to claim 1, wherein the cover members are arranged along an inclination direction of the base body.   The panel plate fixing method according to claim 1, wherein the cover member is fixed to the base by screwing a fixing portion formed below the top of the cover member.

Images