JP4430019B2 - Solar cell module and mounting structure of solar cell module on folding roof - Google Patents

Description

  The present invention relates to a solar cell module for roof installation and a structure for attaching the solar cell module to a folded roof.

  In the form of installing solar cells on the roof, a form in which the roof material in which the solar cells are integrated on the surface is rolled up, and a form in which the solar cell module is installed on the upper surface of the existing roof (hereinafter simply referred to as a stationary type) Say). In the stationary type installation form, a pedestal is constructed on the roof, and a solar cell module is arranged on the upper surface thereof. On roofs that have been sculpted with folding roofing materials, the mountain and valleys are alternately continuous, so a support frame similar to the previous frame is built on the top of the mountain, and the solar cell module on the top. Are fixed with various metal fittings (see Patent Documents 1, 2, and 3).

JP 2003-155803 A (paragraph number 0009, FIGS. 2 and 3) Japanese Patent No. 3352647 (paragraph number 0013, FIG. 3) JP 2002-294955 A (paragraph number 0051, FIG. 3)

  Most conventional solar cell modules of a stationary type are composed of crystalline solar cells, and the whole is a hard panel. Therefore, the weight of each solar cell module is large, and a support frame, a mounting bracket, and the like must be frequently used for installation. Momentum, the weight of the entire roof after installing the solar cell is increased, and it is inevitable that the load on the building frame increases. In addition, the size of the solar cell module varies depending on the manufacturer, and the vertical and horizontal sizes of the solar cell module and the working width of the folding roof material do not match, so the size of the solar cell module and the function of the roof material Depending on the width, it is necessary to prepare a dedicated support frame, mounting bracket, and the like, which increases the installation cost of the solar cell module.

  When installing solar cell modules in a straight line or in a grid, it is necessary to prepare a separate connection fitting for connecting adjacent solar cell modules, which further increases installation effort and cost. To increase. There are solar cell modules equipped with a frame and a connection structure for facilitating the connection between adjacent modules, but even in that case, it is necessary to prepare a support frame and a support rail dedicated to the connection, installation costs and roof Inevitable increase in weight.

  An object of the present invention is to provide a solar cell module that has a simple structure and can be reduced in weight as compared with a crystalline solar cell module, and that requires less cost for installation. The purpose of the present invention is to install the solar cell module on the roof surface with a simpler structure, greatly reducing the construction cost compared to the conventional installation structure, and reducing the total weight of the roof by the simple installation structure. Another object of the present invention is to provide a structure for mounting a solar cell module to a folded roof that can reduce the load weight on the building frame.

In the solar cell module of the present invention, the folded roofing material 10 includes mountain portions 11 and valley portions 12 that are alternately continuous , and the adjacent folded roofing materials 10 protrude above the upper surface of the mountain portion 11. It is assumed that the solar cell module is installed on the roof connected by the seam fastening structure 13 . The solar cell module M includes a base body 1 supported by the roof surface of the folded roof material 10 and a battery body 2 attached to the base body 1. The base body 1 includes a pair of fastening walls 3 fastened and fixed to the mountain portion 11 of the folded roofing material 10 by fastening fasteners 25, a pair of leg walls 4 rising upward continuously from the fastening wall 3, and both leg walls 4. It has an assembly wall 5 that connects the two. A groove 6 is formed in the fastening wall 3 and the leg wall 4 by notching the straddle structure 13. The battery body 2 is composed of a film-type amorphous solar cell in which a solar cell layer 21 is formed on the surface of a plastic film substrate 20, and the plastic film substrate 20 is stuck and fixed to the assembly wall 5.

  In the structure for attaching the solar cell module to the folded roof according to the present invention, the solar cell module M is installed on the surface of the folded roof material 10 provided with alternately continuous mountain portions 11 and valley portions 12. Adjacent folded roofing materials 10 are connected to each other via a fastening structure 13 protruding above the mountain portion 11. The solar cell module M includes a base body 1 supported by the folded roofing material 10 and a sheet-like battery body 2 attached to the base body 1. The base body 1 includes a pair of fastening walls 3 that are fastened and fixed to the mountain portion 11 of the folded roofing material 10 by fastening fasteners 25, a pair of leg walls 4 that rises continuously upward from the fastening wall 3, and both leg walls 4. An assembly wall 5 that connects the two to each other is provided, and a groove 6 is formed in the fastening wall 3 and the leg wall 4 so as to cut over the fastening structure 13. The fastening bracket 25 includes a pair of mounting legs 30 that sandwich the neck portion 17 of the fastening structure 13 and a pair of presser walls 33 that sandwich the fastening wall 3 in cooperation with the mountain portion 11 and vertically. 26 and a bolt 27 for pulling and fixing the pair of mounting legs 30 together. Thus, the solar cell module M is directly fixed to the mountain portion 11 of the stencil roofing material 10 with a plurality of fasteners 25.

  The metal fitting body 26 is continuous with the pair of mounting legs 30, the fastening seats 31 for the bolts 27 that are opposed to each other at the upper parts of the mounting legs 30, the upper wall 32 that connects the fastening seats 31, and the lower part of the mounting legs 30. The presser wall 33 is formed by being integrally bent. A frame receiving seat 41 for receiving and supporting the temporary frame 40 and a bolt 42 are fastened and fixed to the upper surface of the upper wall 32.

  In the present invention, since the solar cell module is constituted by the base body 1 mounted on the roof surface of the folded roofing material 10 and the battery body 2 made of a film type amorphous solar cell, a conventional crystalline solar cell module Compared with, module weight can be greatly reduced. Since the battery body 2 is composed of a film-type amorphous solar cell, the solar cell module can be easily lengthened compared to the conventional crystal module, and the production efficiency of the solar cell module can be improved by that much, and the construction work Can be reduced.

  Further, the base body 1 is constituted by the fastening wall 3, the leg wall 4, the assembly wall 5, and the like, and the fastening wall 3 is fastened to the mountain portion 11 of the folded roof material 10 by the fastening metal fitting 25, thereby the solar cell module. Since it is directly fixed to the folded roofing material 10, it is possible to minimize the metal fittings and the frame necessary for installing the solar cell module, and the solar cell system for the roof and the building frame together with the weight reduction of the solar cell module. The load weight can be reduced. Of course, it is possible to reduce the labor and installation cost as much as the metal fittings and frame can be omitted.

  According to the solar cell module in which the fastening wall 3 and the leg wall 4 of the base body 1 are formed by notching the groove 6 that straddles the fastening structure 13, the adjacent folded plate roofing materials 10 are located above the top surface of the mountain portion 11. The solar cell module is directly fixed to the folded roofing material 10 by placing the base body 1 with the groove 6 straddling the fastening structure 13 in the roof connected to the fastening structure 13 protruding to Therefore, the solar cell module can be folded in a simpler structure by omitting the frame, support frame, or fasteners for fixing the frame, which was indispensable in the conventional solar cell module installation structure. It can be installed on the material 10.

  In the solar cell module mounting structure according to the present invention, the base body 1 and the sheet-shaped battery body 2 attached to the base body 1 constitute a solar cell module M, and the base body 1 is made of the folded roofing material 10. Since it is directly fixed to the mountain portion 11 with the fastening bracket 25, the overall weight can be greatly reduced compared to a solar cell system constituted by a conventional crystalline solar cell module.

  Further, the fastening wall 3 provided on the base body 1 is fastened and fixed to the mountain portion 11 of the folded roofing material 10 with the fastening bracket 25 fastened to the screw fastening structure 13, and the folded roofing material 10 itself is made solar. Since it is used as a base for the battery module M and a base that is indispensable in this type of structure, and a metal fitting for fixing the base are omitted, a metal fitting necessary for installing the solar cell module M is omitted. In addition to minimizing the weight of the solar cell module M, the load weight of the solar cell system on the roof and the building frame can be reduced. Of course, construction work and installation costs can be greatly reduced by the amount that can be omitted.

  A pair of mounting legs 30, a fastening seat 31, an upper wall 32 connecting the fastening seats 31, and a presser wall 33 continuous to the lower part of the mounting leg 30 are integrally bent to form the metal fitting body 26, and the upper wall 32 According to the solar cell module mounting structure in which the frame receiving seat 41 that receives and supports the temporary frame 40 and the bolt 42 are fastened and fixed to the upper surface of the solar cell module, the temporary frame 40 is assembled to the frame receiving seat 41 and the bolt 42 to Since the scaffolding can be constructed along the upper surface of the battery module M, the solar cell module M can be repaired or replaced without damaging the solar cell module M. Maintenance work and replacement of parts after the solar cell module M is installed Work etc. can be performed effectively.

(Example) FIG. 1 thru | or FIG. 5 shows the Example of the solar cell module which concerns on this invention, and the attachment structure to the folding plate roof. In FIG. 5, the solar cell module M includes a base body 1 and a battery body 2 attached to the base body 1. The base body 1 is a horizontally long panel that is integrally provided with a pair of fastening walls 3, a pair of leg walls 4 that rises continuously upward from the fastening wall 3, and an assembly wall 5 that connects the upper ends of both leg walls 4. It consists of a body, and a steel plate is formed by roll forming or bender forming.

As shown in FIG. 3, the adjacent folding roof materials 10 are connected to each other by a screw fastening structure 13 protruding above the upper surface of the mountain portion 11 . The clamping Yuikabe 3 and leg wall 4, notches are formed in predetermined intervals a groove 6 for straddling ze clamping structure 13 as shown in FIG. The adjacent pitch of the groove | channel 6 is made to correspond with the adjacent pitch of the brazing structure 13 adjacent to a horizontal direction.

  As shown in FIG. 1, the battery body 2 is a film-type amorphous solar cell in which a solar cell layer 21 is formed on the surface of a plastic film substrate 20. Film-type amorphous solar cells can reduce the weight per unit area compared to crystalline solar cells with a solar cell layer formed on the surface of a glass substrate, and can be curved and deformed. Have. Incidentally, the battery body 2 of this embodiment has a weight of only 1 kg per square meter, and can be reduced to 1/10 of the weight of the conventional crystalline solar battery.

  The plastic film substrate 20 is made of a plastic material, such as a fluororesin, which is resistant to weathering, especially ultraviolet rays, and a solar cell layer 21 is formed on one surface thereof by a plasma CVD method. The battery body 2 is integrated with the base body 1 by bonding the plastic film substrate 20 to the previous assembly wall 5. Reference numeral 22 in FIG. 1 indicates an adhesive layer.

  Examples of installation of the solar cell module M are shown in FIGS. In the folded roofing material 10 in this installation example, crest portions 11 are formed at both ends of the inverted trapezoidal trough portion 12, and joints 13 a and 13 b are bent at the end portions of the crest portion 11. The adjacent peak portion 11 of the folded roofing material 10 is received and supported by a tight frame 15 fixed to the roof base, and is adjacent to the suspension 16 fixed to the tight frame 15 by fastening the joints 13a and 13b. The folded roof materials 10 are connected.

  As described above, in the roof in which the adjacent folded plate roof materials 10 are connected to each other via the fastening structure 13 protruding above the mountain portion 11, each groove 6 straddles the fastening structure 13. In this manner, the base body 1 is placed on the upper surface of the mountain portion 11 and the fastening wall 3 of the base body 1 is fixed with the fastening metal fitting 25 fastened to the fastening structure 13 so that the solar cell module M is folded. Fix directly to the material 10.

  1 and 4, the fastening bracket 25 includes a clip-shaped bracket main body 26, and bolts 27 and nuts 28 that fasten the bracket main body 26 to the fastening structure 13. The metal fitting body 26 connects a pair of mounting legs 30 that sandwich the neck portion 17 of the fastening structure 13, a fastening seat 31 for the bolt 27 that is opposed to each other at the upper part of the both mounting legs 30, and upper ends of the fastening seats 31. The upper wall 32 and the presser wall 33 continuous to the lower part of the attachment leg 30 are integrally provided, and a steel material having a thickness of more than 2 mm is bent and formed. A bolt insertion hole is formed in the center of the fastening seat 31 in the width direction, and reinforcing ribs 34 having a teardrop-shaped outer shape are formed on both sides of the fastening seat 31 (see FIG. 4).

  A pair of mounting legs 30 continuing to the vertical fastening seat 31 is formed in a partial arc shape and is bent in a downward concavity, and a presser wall 33 is bent laterally at the lower end thereof. The fastening bracket 25 in the free state is set such that the facing distance of the refracting portion 35 between the mounting leg 30 and the pressing wall 33 is set slightly larger than the left and right width of the hose fastening structure 13 as shown in FIG. In addition, in a state where the opposing fastening seats 31 are fastened and fixed with bolts 27 and nuts 28, the refracting portion 35 holds the neck portion 17 of the fastening structure 13 to the left and right, and the presser wall 33 connects the fastening wall 3 to the mountain portion 11. It is clamped and fixed up and down in cooperation with.

  In order to firmly press the holding wall 33 against the fastening wall 3 by using the pulling fastening force of the bolt 27, an inclined wall 36 is provided in the lower half portion of the mounting leg 30. When the bolt 27 is tightened after the fastener 25 is locked to the fastening structure 13 from above, the inclined wall 36 comes into contact with the lower jaw part of the fastening part and is fastened by the fastening reaction force received from the lower jaw part. The entire metal fitting 25 is gradually pushed downward. As a result, the presser wall 33 comes into close contact with the fastening wall 3, and the fastening wall 3 facing the groove 6 can be firmly clamped and fixed in cooperation with the mountain portion 11 and the tight frame 15.

  Similarly, by fastening the intersecting portion between the helical fastening structure 13 and the base body 1 with the fastening bracket 25, the solar cell module M that is long on the left and right can be installed in a state orthogonal to the roof eaves direction. Note that both ends of the solar cell module M may protrude from the mountain portion 11 in a cantilever shape as shown in FIG. Although it depends on the adjacent pitch of the mountain portion 11 of the folded roofing material 10 and the fastening structure 13, when the adjacent pitch of the mountain portion 11 is relatively small, as shown in FIG. What is necessary is just to fasten the intersection part of the screw fastening structure 13 and the base body 1 with the fastening bracket 25 every 2 pitches (or 3 pitches). In addition, when the adjacent pitch of the adjacent fastening structures 13 is large, all the intersections between the fastening structures 13 and the base body 1 may be fastened with the fastening fittings 25.

  When the solar cell module M is installed adjacent to the eave building as shown in FIG. 2, for example, only the fastening wall 3 positioned on the eaves side of the lowermost solar cell module M is used as the folded roof material 10. After fixing, the next-stage solar cell module M is placed at a predetermined interval above it. In addition, the fastening bracket 25 is fastened to the screw fastening structure 13 exposed between the upper and lower base bodies 1, 1, and the fastening wall 3 positioned on the ridge side of the lower base body 1 and the upper base body 1 are connected. Both of the fastening walls 3 located on the eaves side are simultaneously fixed by the fastening fittings 25.

  Thereafter, in the same manner, a plurality of solar cell modules M are fixed so as to be adjacent to each other in the eave building direction, and further installed in a state adjacent to the horizontal direction, so that the total area as shown in FIG. Can build a large photovoltaic system. Although not shown, the electric power generated by each solar cell module M is output to an output regulator via an output cable derived from each module, where the voltage is adjusted and then converted into an alternating current. Supplied to commercial power.

  On the upper surface of the upper wall 32 of the metal fitting body 26, a frame receiving seat 41 for supporting the temporary frame 40 is inserted from the inner surface side of the upper wall 32 to the bolt 42 from the upper surface side of the upper wall 32. The nut 43 is screwed and fixed. The frame receiving seat 41 is formed of a steel plate cut into a square or a circle, and an insertion hole for the bolt 42 is provided in the center portion thereof. As shown in FIG. 4, the temporary frame 40 is made of a channel material having a hat-shaped cross section, and an insertion hole 44 through which the bolt 42 is inserted is formed in the channel groove wall. The adjacent pitch of the insertion hole 44 is made to correspond to the adjacent pitch of the volt | bolt 42 which comprises a volt | bolt row | line | column of a horizontal direction. If necessary, a temporary frame 40 in which the adjacent pitch of the insertion holes 44 is matched with the adjacent pitch of the bolts 42 constituting the bolt row in the eave building direction can also be provided.

  The temporary frame 40 can be supported in parallel with the solar cell module M by placing the temporary frame 40 on the upper surface of the frame receiving seat 41 in a state where each insertion hole 44 is fitted over the bolt 42. It can support in the state orthogonal to the solar cell module M. In any case, by using the temporary frame 40 supported by the frame receiving seat 41 as a scaffold, the maintenance or replacement work can be effectively performed without stepping on the existing solar cell module M. If necessary, a scaffold panel may be fastened to the upper surface of the temporary frame 40.

  In the above-described embodiment, the case where the adjacent folding roof materials 10 are connected to each other by the round-tightening structure 13 is described. When the fastening structure 13 is used for connection, the metal fitting body 26 shown in FIG. 6 is used. In the corner tightening structure 13, the bolting portion is caulked and deformed on one side of the hanging member 16. Therefore, one mounting leg 30 of the metal fitting body 26 is formed continuously and perpendicularly to the fastening seat 31, and only the other mounting leg 30 forms an inclined wall 36. Since others are the same as the previous embodiment, the same reference numerals are assigned to the same members, and descriptions thereof are omitted. The following examples are similarly treated.

  In a state where the metal fitting body 26 is fastened to the fastening structure 13 with the bolt 27, the fastening structure 13 is sandwiched and fixed between the vertical mounting leg 30 and the inclined wall 36, and the bent portion 35 contacts the neck portion 17. There is no. In the state in which the bolt 27 is completely fastened, the inclined wall 36 receives the tightening reaction force from the lower jaw portion of the helical tightening structure 13 as in the previous embodiment, so that the presser wall 33 is brought into close contact with the fastening wall 3. The fastening wall 3 facing the groove 6 can be firmly clamped and fixed in cooperation with the mountain portion 11 and the tight frame 15.

7 and 8 show a modification of the base body 1. There, the fastening wall 3 of the base body 1 is inclined upward toward the edge of the wall so that the bent portion 3a between the fastening wall 3 and the leg wall 4 is received by the mountain portion 11 of the folding plate roofing material 10. . In this case, the fastening bracket 25 is formed in a state where a hook-shaped locking piece 37 is formed continuously from the eaves edge and the ridge edge of the holding wall 33, and the fastening bracket 25 is fastened to the screw fastening structure 13. The fastening wall 3 of the base body 1 can be pressed and fixed by the locking piece 37. In this fixed state, the presser wall 33 floats away from the mountain portion 11, and only the bent portion 3 a presses the mountain portion 11 of the folding roof material 10.

9 and 10 show another modification of the base body 1. In the base body 1 shown in FIG. 9 , the vertical height of the leg wall 4 on the ridge side is larger than the vertical height of the leg wall 4 on the eaves side, and the assembly wall 5 is inclined downward toward the eaves side. . Thus, when the assembly wall 5 is inclined downward toward the eaves side, even when the roof has a small gradient, the incident angle of sunlight with respect to the battery body 2 is increased, and the power generation efficiency of the solar cell module M is increased. Can be improved.

In the base body 1 shown in FIG. 10 , the assembly wall 5 is formed with an upwardly curved surface so that the battery body 2 can be arranged along the curved surface.

Depending on the folded roof material 10, a plurality of valley portions 12 and mountain portions 11 may be formed between the mountain portions 11 at both ends. In such cases, it is possible to conclude a fastening wall 3 of the base body 1 with one side bolts on the mountain portion 11 located between the middle.

In addition to the above, the base body 1 can be formed of an aluminum plate material or a stainless steel plate material. The groove 6 only needs to be able to straddle the fastening structure 13, and its shape and groove height are not limited to the structures described in the embodiments . Gold instrument body 26 may be configured to respectively mounting leg 30 and the fastening seat 31 and the upper wall 32 and the pressing wall 33 by a pair of brackets having integrally.

It is a vertical front view which shows the installation structure of a solar cell module. It is a perspective view which shows the example of installation of a solar cell module. It is a vertical front view which shows the relational structure of a folding roof material and a solar cell module. It is the sectional view on the AA line in FIG. It is a perspective view of a solar cell module. It is a vertical front view which shows another Example of a fastener. It is sectional drawing which shows another Example of a base body. It is a vertical side view which shows another Example of a fastener. It is sectional drawing which shows another Example of a solar cell module. It is sectional drawing which shows another Example of a solar cell module.

Explanation of symbols

1 base material 2 cell body 3 fastening wall 4 legged wall 6 grooves 25 fastening fitting 26 fitting body 27 bolt 30 fixing leg 31 fastening seat 33 pressing the wall M solar cell module

Claims (3)

The origami roofing material (10) is provided with alternating mountain portions (11) and valley portions (12) ,
It is a solar cell module (M) installed on the roof where adjacent folded roofing materials (10) are connected by a screw fastening structure (13) protruding above the upper surface of the mountain portion (11) ,
The solar cell module (M) includes a base body (1) supported by the roof surface of the folded roofing material (10) and a battery body (2) attached to the base body (1).
The base body (1) has a pair of fastening walls (3) fastened and fastened to the mountain parts (11) of the folded roofing material (10) by fastening metal fittings (25), and is continuously upward to the fastening walls (3). A pair of leg walls (4) that stand up and an assembly wall (5) that connects the two leg walls (4),
The fastening wall (3) and the leg wall (4) are notched and formed with a groove (6) straddling the fastening structure (13).
The battery body (2) is composed of a film-type amorphous solar cell formed by forming a solar cell layer (21) on the surface of the plastic film substrate (20),
A solar cell module in which a plastic film substrate (20) is adhered and fixed to the assembly wall (5). The solar cell module (M) is installed on the surface of the folded roofing material (10) provided with alternately continuous mountain portions (11) and valley portions (12),
Adjacent folding roof materials (10) are connected to each other via a fastening structure (13) protruding above the mountain portion (11),
The solar cell module (M) includes a base body (1) supported by the folded roofing material (10) and a sheet-like battery body (2) attached to the base body (1).
The base body (1) has a pair of fastening walls (3) fastened and fastened to the mountain parts (11) of the folded roofing material (10) by fastening metal fittings (25), and is continuously upward to the fastening walls (3). A pair of leg walls (4) and an assembly wall (5) for connecting the two leg walls (4) to each other, and a fastening structure (13) on the fastening wall (3) and the leg wall (4). A groove (6) straddling the notch is formed,
The fastening bracket (25) is clamped up and down in cooperation with a pair of mounting legs (30) that sandwich the neck portion (17) of the fastening structure (13) and the fastening wall (3) with the mountain portion (11). A metal fitting body (26) having a pair of holding walls (33) and a bolt (27) for pulling and fixing the pair of mounting legs (30),
The solar cell module (M) is directly fixed to the mountain portion (11) of the folded roofing material (10) with a plurality of fasteners (25) . Mounting structure. The metal fitting body (26) connects the pair of mounting legs (30), the fastening seat (31) for the bolt (27) facing each other at the upper part of both mounting legs (30), and the fastening seats (31). The wall (32) and the presser wall (33) continuous to the lower part of the mounting leg (30) are integrally bent and formed.
The upper surface of the upper wall (32), the support to the frame seat receiving temporary frame (40) and (41) a bolt (42) and is to folding plate roof solar cell module according to claim 2, wherein you have fastened Mounting structure.

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