JP6779031B2 - Arrangement structure of solar cell module and solar cell module - Google Patents

Description

The present invention relates to a solar cell module arrangement structure and a solar cell module.

Conventionally, a roof tile-integrated solar cell module that functions as a roof tile has been known. This roof tile-integrated solar cell module is a solar cell module having both a function as a solar cell and a function as a roof tile (for example, Patent Document 1). The tile-integrated solar cell module has a frame attached to the solar cell panel to protect the end face of the solar cell panel, and the frame is directly fixed to the roof base without using mounting brackets to cover the roof. It constitutes a part.

Japanese Unexamined Patent Publication No. 2014-3073 Japanese Unexamined Patent Publication No. 2006-286898

By the way, some solar cell modules have a gasket arranged between the frame and the solar cell panel from the viewpoint of improving water stopping property and vibration isolation (for example, Patent Document 2).
The conventional solar cell module uses a gasket in a substantially "U" shape. The end of the solar cell panel is attached to the gasket, and the solar cell panel with the gasket attached is fitted into the frame together with the gasket. It is installed. That is, the conventional solar cell module is assembled by attaching a gasket to the end of the solar cell panel and then fitting it into the frame.

However, in the solar cell panel using a glass plate or the like, there are some individual differences in the thickness and shape of the solar cell panel due to the processing of the members. Therefore, the solar cell panel may not be attached to the gasket accurately, and the gasket may not fit the frame accurately. In such a case, if the end portion of the solar cell panel is forcibly fitted into the frame, excessive force is applied to the solar cell panel, which may damage the solar cell panel. Further, due to the structure of such a solar cell module, the process of attaching a gasket to the end of the solar cell panel and the process of fitting the solar cell panel into the frame must be performed in separate processes, and the assembly work for the operator. There is also the problem that it is troublesome.

Therefore, an object of the present invention is to provide a solar cell module and an arrangement structure of the solar cell module that can be easily assembled as compared with the conventional one.

In the invention according to claim 1 for solving the above-mentioned problems, a plurality of solar cell modules are arranged in the direction of the eaves of the roof with respect to the roof base, and the solar cell modules adjacent to the eaves are overlapped. In the arrangement structure of the solar cell modules arranged in steps with
The solar cell module includes a solar cell panel and a holding member for holding the solar cell panel, the holding member has an eaves side frame portion, and the eaves side frame portion has at least two divided pieces. However, the two divided pieces are used to hold the eaves-side end of the solar cell panel, and one of the two divided pieces is removable from the other divided piece. Among the solar cell modules adjacent to the eaves building direction, the eaves side frame portion of the solar cell module on the building side is placed on the surface of the solar cell module on the eaves side on the light receiving surface side, and is mounted on the surface of the building side. The solar cell module is characterized in that its own solar cell panel can move in the direction of the eaves building by removing the one divided piece of the eaves side frame portion with respect to the other divided piece. This is the layout structure of the modules.
According to the second aspect of the present invention, the one divided piece includes a first gasket portion that contacts one part of the solar cell panel, and the other divided piece is another of the solar cell panel. The arrangement structure of the solar cell module according to claim 1, further comprising a second gasket portion that comes into contact with the portion.
That is, according to the present invention, a plurality of solar cell modules are arranged in the direction of the eaves of the roof with respect to the roof base, and the solar cell modules adjacent to the eaves direction are arranged in a stepped manner with overlapping portions. In the arrangement structure, the solar cell module includes a solar cell panel and a holding member for holding the solar cell panel, the holding member has an eaves side frame portion, and the eaves side frame portion has at least two. It has a divided piece, and the two divided pieces are used to hold the eaves-side end of the solar cell panel. In the two divided pieces, one divided piece is attached to and detached from the other divided piece. It is possible, the one split piece comprises a first gasket portion that contacts one portion of the solar cell panel, and the other split piece contacts the other portion of the solar cell panel. Of the solar cell modules adjacent to the eaves building direction, the eaves side frame part of the solar cell module on the building side is placed on the surface of the solar cell module on the eaves side on the light receiving surface side. It is related to the arrangement structure of the solar cell module.

According to the configuration of the present invention, one divided piece of the eaves side frame portion is removable to the other divided piece, and a gasket portion is provided for each of the one divided piece and the other divided piece. .. Then, by assembling these divided pieces, it is possible to hold the eaves side end portion of the solar cell panel. Therefore, it is not necessary to attach the gasket part to the eaves side end of the solar cell panel in advance, and the gasket part can be attached to the eaves side end of the solar cell panel at the same time as assembling one divided piece and the other divided piece. , Workability at the time of assembly is high.
Further, according to the configuration of the present invention, a glass plate or the like is used as a part of the solar cell panel, and even if there are individual differences in the shape and thickness of the glass plate or the like, the divided pieces are assembled to form the eaves of the solar cell panel. Since the side end is held, it is possible to absorb individual differences between products. Therefore, it is not necessary to forcibly fit the gasket portion into the frame or the like, and it is possible to prevent damage caused by fitting the gasket portion into the frame or the like as in the conventional case.
According to the configuration of the present invention, the eaves side frame portion of the solar cell module on the ridge side is placed on the surface of the solar cell module on the eaves side on the light receiving surface side, so that the weight of the solar cell module on the ridge side is self-weight. The solar cell module on the eaves side can be pressed down, and even if a blowing force acts on the solar cell module on the eaves side, the solar cell module on the eaves side is hard to come off from the roof base. Further, since the eaves side frame of the solar cell module on the ridge side is placed on the surface of the solar cell module on the eaves side on the light receiving surface side, the ridge side with the solar cell module attached to the roof base. It is possible to remove the first divided piece from the second divided piece of the eaves side frame portion of the solar cell module. Therefore, for example, even when the gasket portion of the first divided piece is worn out due to wear or the like, only the first divided piece can be replaced, and maintenance is easy.

By the way, in the solar cell module, when the solar cell panel of a specific solar cell module is damaged due to initial failure or the like and needs to be replaced or maintenance is performed, the used solar cell panel is replaced with a new solar cell panel. May be replaced.
However, the conventional solar cell module has a problem that the workability is poor because the solar cell module needs to be moved when the solar cell panel is removed from the frame. In particular, in the case of a roof tile-integrated solar cell module, since the solar cell module is directly attached to the roof base, it is necessary to re-roof the roof when replacing the entire solar cell module, which causes a problem that workability is worse.

Therefore, in the invention according to claim 1 , the solar cell module on the ridge side has its own solar cell panel by removing the one divided piece of the eaves side frame portion with respect to the other divided piece. that Do not be moved in the eaves building direction.

According to the configuration of the present invention, by removing one of the divided pieces from the other divided piece, the solar cell panel of the solar cell module on the ridge side can be moved toward the eaves, so that the solar cell module can be used as a roof base. The used solar panel can be removed by simply pulling out the used solar panel toward the eaves while it is attached, and by moving the new solar panel toward the eaves and inserting it into the frame on the ridge side. It can be installed. That is, according to the configuration of the present invention, the solar cell panel can be attached to and detached from the eaves side frame portion in a state where the solar cell module is attached to the roof base, and maintenance and replacement work of the solar cell panel are easy.

According to the third aspect of the present invention, the solar cell module on the ridge side removes the one divided piece of the eaves side frame portion with respect to the other divided piece, so that the end face of the solar cell panel on the eaves side is used. The solar cell module arrangement structure according to claim 1 or 2 , wherein the solar cell module is exposed to the outside.

According to the configuration of the present invention, work such as maintenance is easier.

By the way, when holding the eaves-side end of the solar cell panel using a split piece having a skeleton part and a gasket part, if the gasket part of the split piece and the skeleton part are not sufficiently adhered, the solar cell module is assembled. At that time, the gasket portion may come off from the skeleton portion, or the positional relationship between the gasket portion and the skeleton portion may shift.
In particular, since maintenance work and replacement work are performed at a high place, the skeleton portion and the gasket portion are disassembled when the divided pieces are divided and performed in the maintenance work and replacement work as in the above invention. As a result, workability is significantly reduced.

Therefore, in the invention according to claim 4 , the solar cell panel has one side extending in the girder direction toward the eaves side, and the one divided piece has a first skeleton portion and a first gasket portion. However, the first gasket portion is in contact with one portion of the solar cell panel, is interposed between the solar cell panel and the first skeleton portion, and is interposed between the first skeleton portion and the first skeleton portion. The first gasket portion extends continuously or intermittently along one side of the eaves side, and one of the first gasket portion and the first skeleton portion extends in the direction of one side of the eaves side. The first convex portion is provided, the other is provided with a first concave groove extending in the same direction as the first convex portion, and the first gasket portion and the first skeleton portion are the first convex portion. The arrangement structure of the solar cell module according to any one of claims 1 to 3 , wherein the first concave groove is fitted to be integrated.
That is, in the present invention, the solar cell panel has one side extending in the girder direction on the eaves side, and the one divided piece has a first skeleton portion and the first gasket portion, and the first One gasket portion is interposed between the solar cell panel and the first skeleton portion, and the first skeleton portion and the first gasket portion are continuously or intermittently along one side of the eaves side. One of the first skeleton portion and the first gasket portion extends, and one of the first skeleton portion and the first gasket portion includes a first convex portion extending in the direction of one side of the eaves side, and the other extends in the same direction as the first convex portion. The first concave groove is provided, and the first gasket portion and the first skeleton portion are integrated by fitting the first convex groove portion and the first concave groove, respectively.

According to the configuration of the present invention, the first gasket portion and the first skeleton portion are integrated by fitting the first convex portion and the first concave groove, respectively, and thus the solar cell module in a factory or the like. It is possible to prevent the first gasket portion from coming off from the first skeleton portion when performing assembly work, maintenance work at a high place, or the like. Therefore, the first gasket portion can be easily attached to the first skeleton portion, and the positional relationship does not easily shift.
Further, according to the configuration of the present invention, since the first convex portion extending in the girder direction and the first concave groove are fitted, the first gasket portion is the first skeleton portion even if a load is applied in the eaves direction. However, it can be prevented from coming off toward the eaves.
Further, according to the configuration of the present invention, since the first ridge portion extending in the girder direction and the first concave groove are fitted, the first ridge portion and the first concave groove are fitted to form the first ridge. The ingress of rainwater into the eaves-side end face side of the solar cell panel at the interface between the skeleton portion and the first gasket portion is hindered, and it is difficult for rainwater to reach the eaves-side end face side of the solar cell panel. Therefore, failure due to infiltration of rainwater from the eaves side end surface of the solar cell panel is unlikely to occur.

The invention according to claim 5, the length of the first ridge portion and the first concave groove extending direction, in claim 4, wherein the at eaves side of one side more than 1/3 It is the arrangement structure of the said solar cell module.

According to the configuration of the present invention, since the length of the first convex groove portion and the first concave groove is 1/3 or more of one side of the eaves side of the solar cell panel, rainwater is more likely to be applied to the eaves side end surface of the solar cell panel. It is hard to reach, and it is more difficult for troubles due to infiltration of rainwater from the end face on the eaves side of the solar cell panel to occur.

In the invention according to claim 6 , the solar cell panel has one side extending in the girder direction toward the eaves side, and the other divided piece has a second skeleton portion and a second gasket portion. The second gasket portion is in contact with another portion of the solar cell panel, is interposed between the solar cell panel and the second skeleton portion, and is interposed between the second skeleton portion and the second skeleton portion. The gasket portion extends continuously or intermittently along one side of the eaves side, and one of the second gasket portion and the second skeleton portion extends in the direction of one side of the eaves side. The strip portion is provided, and the other is provided with a second concave groove extending in the same direction as the second convex strip portion, and the second gasket portion and the second skeleton portion are the second convex strip portion and the second ridge portion. The arrangement structure of the solar cell module according to any one of claims 1 to 5 , wherein the solar cell modules are integrated by fitting the two concave grooves.
That is, the solar panel has one side extending in the girder direction toward the eaves side, the other divided piece has a second skeleton portion and the second gasket portion, and the second gasket portion has a second gasket portion. The second skeleton portion and the second gasket portion are interposed between the solar panel and the second skeleton portion, and the second skeleton portion and the second gasket portion extend continuously or intermittently along one side of the eaves side. One of the second skeleton portion and the second gasket portion includes a second convex portion extending in one side direction on the eaves side, and the other is a second concave portion extending in the same direction as the second convex portion. A groove is provided, and the second gasket portion and the second skeleton portion are integrated by fitting the second convex groove portion and the second concave groove, respectively.

According to the configuration of the present invention, the second gasket portion and the second skeleton portion are integrated by fitting the second convex groove portion and the second concave groove, respectively, so that when assembling the eaves side frame portion. In addition, it is possible to prevent the second gasket portion from coming off from the second skeleton portion. Therefore, the second gasket portion can be easily attached to the second skeleton portion, and the positional relationship does not easily shift.
Further, according to the configuration of the present invention, since the second convex groove portion extending in the girder direction and the second concave groove are fitted, the second gasket portion is the second skeleton portion even if a load is applied in the eaves direction. However, it can be prevented from coming off toward the eaves.
Further, according to the configuration of the present invention, since the second ridge portion extending in the girder direction and the second concave groove are fitted, the second ridge portion and the second concave groove are fitted to form a second. The ingress of rainwater into the eaves-side end face side of the solar cell panel at the interface between the skeleton portion and the second gasket portion is hindered, and it is difficult for rainwater to reach the eaves-side end face side of the solar cell panel. Therefore, failure due to infiltration of rainwater from the eaves side end surface of the solar cell panel is unlikely to occur.

In the invention according to claim 7 , the holding member has a first engaging portion and a ridge-side frame portion for holding the ridge-side end of the solar cell panel, and the ridge-side frame portion is the first. The solar cell module on the ridge side has a second engaging portion that can be engaged with the first engaging portion, and the first engaging portion is on the eaves side in a direction intersecting the light receiving surface of its own solar cell panel. The solar cell module arrangement structure according to any one of claims 1 to 6 , wherein the solar cell module is engaged with the second engaging portion of the solar cell module.

According to the configuration of the present invention, the first engaging portion of the solar cell module on the ridge side and the second engaging portion of the solar cell module on the eaves side are engaged in a direction intersecting the light receiving surface of the solar cell panel. ing. Therefore, even if a blowing force is applied to the solar cell module on the ridge side due to a strong wind or the like, the solar cell module on the ridge side can be locked by the second engaging portion of the solar cell module on the eaves side, and the solar cell module on the ridge side is hard to come off from the roof base.

In the arrangement structure of the solar cell module according to claim 7 , it is preferable that the other divided piece includes the first engaging portion (claim 8 ).

The solar cell according to claim 9 , wherein the solar cell panel has a solar cell interposed between a glass plate and a sealing member, according to any one of claims 1 to 8. It is the arrangement structure of the battery module.

According to the configuration of the present invention, even a solar cell panel using a glass plate in which individual differences are likely to occur can absorb individual differences.

In the above invention, a plurality of solar cell modules are arranged in the direction of the eaves of the roof with respect to the roof base, and the solar cell modules adjacent to the eaves direction are arranged in a stepped manner with overlapping portions. In the structure, the solar cell module includes a solar cell panel and a holding member for holding the solar cell panel, the holding member has an eaves side frame portion, and the eaves side frame portion is divided into at least two parts. It has a piece, and the two pieces are used to hold the eaves-side end of the solar cell panel, and one of the two pieces is removable from the other piece. The solar cell module on the building side can move its own solar cell panel in the direction of the eaves building by removing the one divided piece of the eaves side frame portion with respect to the other divided piece. It is related to the arrangement structure of the solar cell module.

According to this configuration, by removing one of the divided pieces from the other divided piece, the solar cell panel of the solar cell module on the ridge side can be moved toward the eaves. Therefore, the used solar cell panel can be removed by simply pulling out the used solar cell panel toward the eaves with the solar cell module attached to the roof base, and the new solar cell panel can be moved toward the eaves. It can be installed by inserting it into the frame on the ridge side. Therefore, maintenance and replacement work of the solar cell panel are easy.
In the invention according to claim 10 , the holding member has the eaves side frame portion, the ridge side frame portion, the left side frame portion, and the right side frame portion, and the eaves side frame portion and the ridge side frame portion. Each has a holding recess, the eaves-side end of the solar cell panel is inserted into the holding recess of the eaves-side frame, and the solar cell panel is inserted into the holding recess of the ridge-side frame. The ridge side end portion of the above is inserted, and the left side frame portion and the right side frame portion both support the back surface of the solar cell panel, and connect the ridge side frame portion and the eaves side frame portion. On the left side frame portion, the vicinity of the left end portion of the solar cell panel is placed, and on the right side frame portion, the vicinity of the right end portion of the solar cell panel is placed. It has one solar cell module and another solar cell module adjacent to the one solar cell module in the girder direction, and the right end surface of the solar cell panel of the one solar cell module is in the girder direction. The arrangement structure of the solar cell module according to any one of claims 1 to 9 , wherein the solar cell panel of another adjacent solar cell module directly faces the left end surface of the solar cell panel .

The invention according to claim 11 is installed so as to be adjacent to another solar cell module in the eaves direction with respect to the roof base, and is arranged in a stepped manner with an overlapping portion with respect to the other solar cell module. A solar cell module including a solar cell panel and a holding member for holding the solar cell panel, the holding member having an eaves side frame portion, and the eaves side frame portion having at least two divided pieces. The two divided pieces are used to hold the eaves-side end of the solar cell panel, and one of the two divided pieces is removable from the other divided piece. The one divided piece includes a first gasket portion that contacts one part of the solar cell panel, and the other divided piece has a second gasket portion that contacts the other part of the solar cell panel. When installed on the roof base, the eaves side frame portion is placed on the surface of the other solar cell module on the light receiving surface side , and is installed on the roof base. The solar cell module is characterized in that its own solar cell panel can be moved in the direction of the eaves by removing the one divided piece of the eaves side frame portion with respect to the other divided piece .

According to the configuration of the present invention, one divided piece of the eaves side frame portion is removable to the other divided piece, and a gasket portion is provided for each of the one divided piece and the other divided piece. .. Therefore, it is possible to hold the eaves-side end of the solar cell panel by assembling these divided pieces. Therefore, it is not necessary to attach the gasket part to the eaves side end of the solar cell panel in advance, and it is possible to attach the gasket part to the eaves side end of the solar cell panel at the same time as assembling one divided piece and the other divided piece. It can be assembled and has high workability.
Further, according to the configuration of the present invention, a glass plate or the like is used as a part of the solar cell panel, and even if there are individual differences in the shape and thickness of the glass plate or the like, the divided pieces are assembled to form the eaves of the solar cell panel. Since the side end portion is held, individual differences can be absorbed, and it is not necessary to forcibly fit the gasket portion to the frame or the like. Therefore, it is possible to prevent damage caused by fitting the conventional gasket portion into the frame or the like.
According to the configuration of the present invention, since the eaves side frame portion is placed on the surface of the other solar cell module on the light receiving surface side, the other solar cell module can be pressed by its own weight, and the other solar cell module can be pressed. Even if a blowing force acts on the battery module, it is possible to prevent other solar cell modules from coming off from the roof base.

The invention related to the present invention is a solar cell module including a solar cell panel and a holding member for holding the solar cell panel. The solar cell panel includes at least one side, and the holding member comprises at least one side. It has a frame portion, the frame portion holds an end portion of the solar cell panel, has a first skeleton portion and a first gasket portion, and the first gasket portion is the solar cell. It is interposed between the panel and the first skeleton portion, and the first skeleton portion and the first gasket portion extend continuously or intermittently along one side of the solar cell panel, and the first One of the gasket portion and the first skeleton portion has a first convex portion extending in one side direction, and the other has a first concave groove extending in the same direction as the first convex portion. wherein said first skeletal portion and the first gasket portion is a solar cell module that has become integrated by engagement of the first groove and the first ridge portion.
That is, the present invention is a solar cell module including a solar cell panel and a holding member for holding the solar cell panel. The solar cell panel has at least one side, and the holding member has a frame portion. The frame portion holds the end portion of the solar cell panel, and has a first skeleton portion and a first gasket portion, and the first gasket portion includes the solar cell panel. It is interposed between the first skeleton portion, and the first skeleton portion and the first gasket portion extend continuously or intermittently along one side of the solar cell panel, and the first skeleton portion. And one of the first gasket portions is provided with a first convex portion extending in one side direction, and the other is provided with a first concave groove extending in the same direction as the first convex portion. The 1 gasket portion and the 1st skeleton portion are integrated by fitting the 1st convex portion and the 1st concave groove, respectively.

According to the configuration of this, the first skeletal portion and the first gasket portion, since the integrally fitted each of the first ridge portion first groove, when assembling the eaves-side frame unit , The first gasket portion can be prevented from coming off from the first skeleton portion, the first gasket portion can be easily attached to the first skeleton portion, and the positional relationship does not easily shift.

According to the present invention, it can be assembled more easily than before.

It is a schematic diagram of the roof structure of the 1st Embodiment of this invention. It is a perspective view of the solar cell module with a snow stop function of FIG. It is a top view of the solar cell module with a snow stop function of FIG. 2 is an explanatory view of the solar cell panel of FIG. 2, FIG. 2A is a plan view of the solar cell panel, and FIG. 2B is a sectional view taken along the line AA of FIG. 2A. It is an exploded perspective view of the holding member of FIG. It is sectional drawing around the ridge side frame part of FIG. It is an exploded perspective view of the ridge side frame part of FIG. It is a perspective view which looked at the ridge side frame part of FIG. 5 from another angle. 5 is an explanatory view of the ridge-side gasket portion, FIG. 5A is a cross-sectional perspective view of the ridge-side gasket portion, and FIG. 5B is a cross-sectional view showing the cross section of FIG. 5 in more detail. FIG. 5 is a perspective view of the eaves side frame portion of FIG. 5 as viewed from another direction. It is an exploded perspective view of the frame portion on the eaves side of FIG. It is sectional drawing of the frame part on the eaves side of FIG. 10 is an explanatory view of the eaves side gasket portion, FIG. 10A is a cross-sectional perspective view of the eaves side gasket portion, and FIG. 10B is a cross-sectional view of the eaves side gasket portion. It is sectional drawing of the left side frame part of FIG. FIG. 5 is a perspective view of the right frame portion of FIG. 5 as viewed from another angle. It is sectional drawing of the right side frame part of FIG. It is sectional drawing around the insertion metal fitting of the solar cell module of FIG. It is a perspective view of the solar cell module which does not have a snow stop function of FIG. It is sectional drawing of the solar cell module of FIG. It is an exploded perspective view of the frame portion on the eaves side of FIG. It is a perspective view of the tile member of FIG. It is explanatory drawing of the eaves metal fitting of FIG. 1, (a) is the perspective view of the eaves metal fitting, (b) is the sectional view of (a), and (c) is seen from the angle different from (a). It is a perspective view. It is a perspective view of the intermediate mounting bracket of FIG. It is a perspective view which shows the foundation roof structure of FIG. It is explanatory drawing when the 1st stage solar cell module is fixed to the eaves metal fitting, (a) is the perspective view which shows the situation which the solar cell module is attached to the eaves metal fitting, and (b) is juxtaposed in the girder direction. It is a perspective view which shows the situation which is brought close to a tile member. It is explanatory drawing when the 1st stage solar cell module is fixed to the eaves metal fitting, (a) is the perspective view which shows the situation which the solar cell module is attached to the eaves metal fitting, and (b) is juxtaposed in the girder direction. It is a perspective view which shows the situation which brings the solar cell module close to each other. It is explanatory drawing when the 1st stage solar cell module is fixed to the eaves metal fitting, (a) is the cross-sectional view which shows the state which attached the solar cell module to the eaves metal fitting, and (b) is parallel in the girder direction. It is sectional drawing which shows the situation in which the solar cell module to be installed is brought close to each other. It is sectional drawing which shows the situation of the right side frame part and the left side frame part when adjoining solar cell modules are brought close to each other in a column direction. It is explanatory drawing when the 2nd stage solar cell module is fixed to the intermediate mounting bracket and the 1st stage solar cell module, (a) is the 2nd stage solar cell module with the 1st stage solar cell module. It is a perspective view which shows the situation which the battery module and a tile member are straddled, and (b) is the perspective view which shows the situation which the solar cell modules which are arranged side by side in the girder direction are brought close to each other. It is sectional drawing which shows the situation when the solar cell module of the 2nd stage is attached to a tile member. It is sectional drawing which shows the situation at the time of attaching the 2nd stage solar cell module to the 1st stage solar cell module. It is explanatory drawing at the time of fixing the 2nd stage solar cell module to the 1st stage solar cell module, (a) attaches the 2nd stage solar cell module to the 1st stage solar cell module. It is a perspective view which shows the situation, (b) is the perspective view which shows the situation which the solar cell modules arranged side by side in the column direction are brought close to each other. It is explanatory drawing at the time of exchanging the solar cell panel of the roof structure of 1st Embodiment of this invention. It is explanatory drawing of the position adjustment function of the roof structure of 1st Embodiment of this invention, (a) shows the case where the inclination angle of a foundation roof structure is small, (b) shows the case where the inclination angle of a foundation roof structure is large. Represent. It is explanatory drawing of the position adjustment function of the roof structure of 1st Embodiment of this invention, (a) shows the case where the inclination angle of a foundation roof structure is small, (b) shows the case where the inclination angle of a foundation roof structure is large. Represent. It is explanatory drawing of the snow stop function of the roof structure of 1st Embodiment of this invention. It is explanatory drawing of the typical flow of rainwater of the roof structure of 1st Embodiment of this invention. It is a perspective view which shows the roof structure of the 2nd Embodiment of this invention. It is a perspective view of the solar cell module with a snow stop function of FIG. 38. It is a top view of the solar cell module with a snow stop function of FIG. 38. It is an exploded perspective view of the holding member of FIG. 39. It is explanatory drawing near the ridge side frame part of FIG. 38, (a) is the cross-sectional view which passes through a mounting hole and a mounting hole, (b) is a sectional view which passes through a fixing hole and a fixing hole. It is an exploded perspective view of the ridge side frame part of FIG. 41. It is a perspective view which looked at the ridge side frame part of FIG. 41 from another angle. It is a perspective view which saw the eaves side frame part of FIG. 41 from another direction. It is an exploded perspective view of the frame portion on the eaves side of FIG. 41. It is sectional drawing of the frame part on the eaves side of FIG. 41. It is sectional drawing of the left side frame part of FIG. 41. It is sectional drawing of the right side frame part of FIG. 41. It is a perspective view of the solar cell module which does not have a snow stop function of FIG. 38. FIG. 5 is a cross-sectional view of the vicinity of the eaves side frame portion of the solar cell module of FIG. It is explanatory drawing when the 1st stage solar cell module is fixed to the eaves metal fitting, (a) is the perspective view which shows the situation which the solar cell module is attached to the eaves metal fitting, and (b) is juxtaposed in the girder direction. It is a perspective view which shows the situation which is brought close to a tile member. It is explanatory drawing when the 1st stage solar cell module is fixed to the eaves metal fitting, (a) is the perspective view which shows the situation which the solar cell module is attached to the eaves metal fitting, and (b) is juxtaposed in the girder direction. It is a perspective view which shows the situation which brings the solar cell module close to each other. It is sectional drawing which shows the situation which attaches the 1st stage solar cell module to the eaves metal fitting. It is explanatory drawing which shows the situation which the solar cell modules which are arranged side by side in the column direction are brought close to each other, (a) is the perspective view which shows the situation which the building side frame part is brought close, and (b) is connecting between the building side frame part. It is a perspective view which shows the situation. It is explanatory drawing when the 2nd stage solar cell module is fixed to the intermediate mounting bracket and the 1st stage solar cell module, (a) is the 2nd stage solar cell module with the 1st stage solar cell module. It is a perspective view which shows the situation which the battery module and a tile member are straddled, and (b) is the perspective view which shows the situation which the solar cell modules which are arranged side by side in the girder direction are brought close to each other. It is sectional drawing which shows the situation which attached the solar cell module of the 2nd stage to a tile member. It is sectional drawing which shows the situation which attached the 2nd stage solar cell module to the 1st stage solar cell module. It is explanatory drawing at the time of fixing the 2nd stage solar cell module to the 1st stage solar cell module, (a) attaches the 2nd stage solar cell module to the 1st stage solar cell module. It is a perspective view which shows the situation, (b) is the perspective view which shows the situation which the solar cell modules arranged side by side in the column direction are brought close to each other. It is a perspective view of the eaves side frame part of another embodiment of this invention. It is a perspective view of the eaves side frame part of another embodiment of this invention. It is explanatory drawing at the time of installing the roof structure of another embodiment of this invention, and is the figure at the time of laying the solar cell module from the left side, (a) is the 1st stage of the 2nd stage solar cell module. It is a perspective view which shows the situation which the solar cell module of an eye is attached over the tile member, and (b) is the perspective view which shows the situation which the solar cell modules which are arranged side by side in the girder direction are brought close to each other. It is sectional drawing of the eaves side frame part of another embodiment of this invention. It is explanatory drawing of the eaves side frame part of another embodiment of this invention, (a) shows the state which assembled the divided piece, (b) is the time when the divided piece is disassembled and used solar cell panel is replaced. Represents the state of.

Hereinafter, embodiments of the present invention will be described in detail.

In the roof structure 1 of the first embodiment of the present invention, as shown in FIG. 1, a plurality of tile members 300 and a plurality of solar cell modules 2 are laid on the roof base 301 of the foundation roof structure 304. ..
The roof structure 1 of the present embodiment is preferably adopted in a cold region where snowfall or the like occurs, and is a mixture of two types of solar cell modules 2 (2a, 2b). That is, as shown in FIG. 36, the solar cell module 2 of the present embodiment has a snow stop function that restricts the snow 250 accumulated on the solar cell module 2 from moving toward the eaves. There are a solar cell module 2a with a function (hereinafter, also referred to as a first solar cell module 2a) and a solar cell module 2b without a snow blocking function (hereinafter, also referred to as a second solar cell module 2b).

As shown in FIG. 1, the solar cell module 2 of the present embodiment is a roof tile-integrated solar cell module having both a photoelectric conversion function as a solar cell and a function as a roof tile. That is, the solar cell module 2 is used as a roof tile together with the roof tile member 300.
The solar cell module 2 includes a solar cell panel 5 and a holding member 6 as can be read from FIGS. 2 and 18.

The solar cell panel 5 is a photoelectric conversion device that converts light energy into electrical energy.
The solar cell panel 5 is a plate-shaped panel having a planar spread as shown in FIG. 4A, and has a light receiving surface 7 on the front side.
The solar cell panel 5 has a substantially polygonal shape having horizontal sides 10 and 11 facing in the vertical direction Y when viewed from the front. The solar cell panel 5 of the present embodiment is a horizontally long rectangular solar cell panel, and includes horizontal sides 10 and 11 extending in the horizontal direction X and vertical sides 12 and 13 extending in the vertical direction Y.

The solar cell panel 5 is a so-called crystalline solar cell panel, and as shown in FIG. 4B, a plurality of solar cells 192 are interposed between the glass plate 190 and the sealing member 191. , Solar cells 192 and 192 are electrically connected in series and / or in parallel by a wiring member 193.

As can be read from FIGS. 1, 2, and 18, the holding member 6 is a member that holds the solar cell panel 5, and is also a mounting member that attaches the entire solar cell module 2 to the roof base 301.
Two types of holding members 6a and 6b are adopted for the holding member 6 of the present embodiment, and the first solar cell module 2a having the snow blocking function shown in FIG. 2 and the snow blocking function shown in FIG. 18 The structure is slightly different from that of the second solar cell module 2b.

The first solar cell module 2a is formed from the overlapping portion 8 overlapping the solar cell panel 5 and the four sides 10 to 13 of the solar cell panel 5 when the light receiving surface 7 of the solar cell panel 5 is viewed in a plan view as shown in FIG. It is provided with overhanging portions 9a to 9c.
The superimposing portion 8 is a portion that overlaps with the solar cell panel 5 in the thickness direction, and is a portion that is hidden by the solar cell panel 5 when the light receiving surface 7 is viewed in a plan view.
The ridge-side overhanging portion 9a (eave-building-side overhanging portion) is a portion of the solar cell panel 5 overhanging from the ridge-side side 10 (building-side side).
The eaves-side overhanging portion 9b (eave-building-side overhanging portion) is a portion of the solar cell panel 5 protruding from the eaves-end side 11 (the eaves-side overhanging side).
The girder side overhanging portion 9c is a portion overhanging from the left side 12 of the solar cell panel 5.

As can be read from FIGS. 2 and 5, the holding member 6a of the first solar cell module 2a is formed from the frame portions 15 to 18 extending along the four sides 10 to 13 of the solar cell panel 5 and the insertion fittings 20 and 21. It is configured.

The ridge side frame portion 15 is a long body extending along the ridge side 10 (one side of the ridge side) of the solar cell panel 5 when the roof structure 1 is assembled as shown in FIG. It is a part that holds the ridge side 10 of 5.
As shown in FIG. 7, the ridge side frame portion 15 includes a holding main body portion 25 and a conductive member 26.

The holding main body portion 25 is a portion provided with a holding recess 30 into which a ridge-side end portion of the solar cell panel 5 can be inserted, and is composed of a skeleton portion 27 (frame portion) and a ridge-side gasket portion 28.
The skeleton portion 27 is an upper frame that protects the ridge-side end portion of the solar cell panel 5, and is formed by coating the surface of a core member that is a conductor with a protective layer having a lower electrical conductivity than the conductor. Specifically, the skeleton portion 27 is formed by performing anodizing treatment on the surface of an aluminum drawing material.

As shown in FIG. 8, the skeleton portion 27 includes a recess forming portion 31 and a fixing portion 32.
As shown in FIG. 6, the recess forming portion 31 is a portion that forms a holding recess 30 that can be fitted with the ridge-side end of the solar cell panel 5. The recess forming portion 31 has a substantially “U” shape in cross-sectional view, and the holding recess 30 is formed by the front side wall portion 35, the connecting wall portion 36, and the back surface side wall portion 37.
As shown in FIG. 7, the holding recess 30 is a concave portion extending along the ridge side 10 of the solar cell panel 5, and is a portion for holding the solar cell panel 5.
The front side wall portion 35 is a wall portion that covers the front side of the solar cell panel 5 as shown in FIG.
As shown in FIG. 6, the connecting wall portion 36 is a wall portion that connects the front side wall portion 35 and the back side wall portion 37. The connection wall portion 36 is erected in a direction orthogonal to the light receiving surface 7 of the solar cell panel 5 from the ridge side end portion of the back side wall portion 37, and the front side wall portion 35 is erected in the middle portion in the erection direction. The ridge side end is connected. That is, the connecting wall portion 36 forms a protruding wall portion 38 that protrudes upward from the front side wall portion 35.
The back side wall portion 37 is a wall portion that covers the back side of the solar cell panel 5.
The back side wall portion 37 extends from the connecting wall portion 36 in the same direction as the front side wall portion 35, and is arranged so as to face the front side wall portion 35 at a predetermined distance in the thickness direction.

As shown in FIG. 6, the fixing portion 32 is a portion having an “L” -shaped cross section, and includes a fixing plate portion 40 and a standing wall portion 41.
As shown in FIG. 8, the fixing plate portion 40 is a plate-shaped portion that projects from the connecting wall portion 36 toward the ridge and extends in the lateral direction X.
In the fixing plate portion 40, a plurality of fixing holes 44 are arranged side by side at predetermined intervals in the longitudinal direction thereof.
As shown in FIG. 27A, the fixing hole 44 is a hole for fixing to the roof tile rod 307 of the roof base 301 by the fastening element 39. The fixing hole 44 is a through hole penetrating the fixing plate portion 40 in the member thickness direction, and the fastening element 39 can be inserted therethrough.
The fastening element 39 is a known fastening element, and in the present embodiment, it is a nail.
The "fastening element" in this specification is a superordinate concept such as a screw, a nail, and a stud.

The vertical wall portion 41 is a wall portion erected downward from the ridge-side end portion of the fixed plate portion 40 as shown in FIG. 8, and is a long plate-shaped portion extending in the lateral direction X.
As shown in FIGS. 6 and 7, a plurality of mounting holes 42 are arranged side by side in the vertical wall portion 41 at predetermined intervals in the longitudinal direction (horizontal direction X).
The mounting hole 42 is a hole for mounting the conductive member 26 by the fastening element 43, and is an engaging hole that can be engaged with the fastening element 43.
The mounting hole 42 is a bottomed hole or a through hole having a depth in the member thickness direction from the surface on the ridge side.
The fastening element 43 is a known fastening element, and in this embodiment, it is a screw.

As shown in FIG. 6, the ridge-side gasket portion 28 is interposed between the solar cell panel 5 and the holding recess 30 to close the gap between the solar cell panel 5 and the holding recess 30. That is, the ridge-side gasket portion 28 comes into direct contact with the ridge-side end portion of the solar cell panel 5 to prevent the solar cell panel 5 from being displaced or coming off with respect to the skeleton portion 27.

The ridge-side gasket portion 28 is formed of an elastic cushioning material, and when the solar cell module 2 is assembled, the self-elastically deforms the pressing force in the insertion direction of the solar cell panel 5 into the holding recess 30. It is possible to relax or absorb with.
The ridge-side gasket portion 28 is a long body extending in the lateral direction X as shown in FIG. 9A.
As shown in FIG. 9B, the ridge-side gasket portion 28 is an integrally molded product in which a plurality of gasket portions 45, 46 made of different materials are integrally molded.
In the present embodiment, in the ridge side gasket portion 28, two types of gasket portions 45 and 46 having different hardness are formed by extrusion molding.
That is, as shown in FIG. 9B, the ridge-side gasket portion 28 is composed of a hard gasket portion 45 and a soft gasket portion 46 that is softer than the hard gasket portion 45, and these are directly fixed and inseparably integrated. It has become.

As can be read from FIG. 9, the hard gasket portion 45 is a long body having a “U” cross-sectional shape, and includes a front side cushioning portion 48, an end face side cushioning portion 49, and a back surface side cushioning portion 50. There is.
As can be read from FIGS. 6 and 9 (b), the front side cushioning portion 48 is a portion interposed between a part of the front surface of the solar cell panel 5 and the front side wall portion 35, and is pulled out to the inner side surface. A rib 51 for preventing the fall is formed.
The rib 51 is a convex strip piece extending in the horizontal direction X as shown in FIG. 9A, and can prevent the solar cell panel 5 from being displaced in the vertical direction.
The end face side cushioning portion 49 is a portion interposed between the end face of the solar cell panel 5 and the connecting wall portion 36, and the ridge side surface thereof is fixed to the soft gasket portion 46.
The upper end portion (front side end portion) of the end face side cushioning portion 49 is connected to the ridge side end portion of the front side cushioning portion 48, and the lower end portion (back surface side end portion) thereof is the ridge side cushioning portion 50 ridge. It is connected to the side end.
The back surface side buffer portion 50 is a portion facing the front side buffer portion 48 with the solar cell panel 5 interposed therebetween, and is interposed between a part of the back surface of the solar cell panel 5 and the back surface side wall portion 37. It is a part.
Similar to the front cushioning portion 48, the back surface side cushioning portion 50 is formed with ribs 52 for preventing falling off on the inner side surface.
The rib 52 is a convex strip piece that is paired with the rib 51 and extends in the lateral direction, and can prevent the solar cell panel 5 from being displaced in the vertical direction.

The shore A hardness of the hard gasket portion 45 is preferably 60 or more, and more preferably 80 or more.
Within this range, the solar cell panel 5 can be held firmly without being too soft.
The shore A hardness of the hard gasket portion 45 is preferably 100 or less, and more preferably 87 or less.
Within this range, the solar cell panel 5 is not too hard and is not easily damaged.
As used herein, the term "shore A hardness" refers to a type A shore hardness conforming to ASTM D 2240.

The soft gasket portion 46 is a portion interposed between the end face side cushioning portion 49 of the hard gasket portion 45 and the connecting wall portion 36 of the skeleton portion 27, and is a gasket softer than the hardness of the hard gasket portion 45.
As shown in FIG. 9B, the soft gasket portion 46 is a hollow body having an annular cross-sectional shape, and a buffer space 53 is formed in the center thereof.
The buffer space 53 is a space that cushions the pressure applied to the ridge-side gasket portion 28 when the solar cell module 2 is assembled, and is a space that extends in the lateral direction X (extending direction of the ridge-side side of the solar cell panel 5). is there.

As described above, the shore A hardness of the soft gasket portion 46 is softer than the shore A hardness of the hard gasket portion 45, preferably 60 or less, and more preferably less than 60.
Within this range, it is not too hard and has a high cushioning effect.
The shore A hardness of the soft gasket portion 46 is preferably 40 or more.
Within this range, the shape can be maintained without being too soft and crushed.

As shown in FIG. 8, the conductive member 26 is a member attached to the holding main body 25, and forms a conductive path between the solar cell modules 2 and 2 to be released to the ground when the roof structure 1 is assembled. It is a member to be used.
The conductive member 26 is formed by bending a horizontally long rectangular metal plate into an "L" shape, and is bent from a connecting portion 55 connecting to the holding main body portion 25 and an end portion of the connecting portion 55. It includes an engaging portion 56 (second engaging portion).

The connecting portion 55 is a portion connected to the vertical wall portion 41 of the skeleton portion 27 as shown in FIG. 7, and is provided with a plurality of insertion holes 57 through which the fastening element 43 can be inserted.
The insertion holes 57 are through holes penetrating in the thickness direction of the connecting portion 55, and are arranged side by side with a predetermined interval in the lateral direction X.
The fastening element 43 is a known fastening element, and in this embodiment, it is a screw.

The engaging portion 56 (second conductive portion) is an engaging piece that engages with a part of the eaves side frame portion 16 of the solar cell module 2 adjacent to the ridge side when the roof structure 1 is assembled. It is a locking piece that locks the blow-up of the solar cell module 2 adjacent to the side.
The engaging portion 56 is also a conductive portion that contacts and electrically connects with the eaves side frame portion 16 of the solar cell module 2 adjacent to the ridge side.
The overhang length of the engaging portion 56 from the connecting portion 55 is preferably 3% or more and 21% or less of the vertical sides 12 and 13 of the solar cell panel 5.

Here, the positional relationship of each component of the ridge side frame portion 15 will be described.

As can be read from FIGS. 6 and 7, the conductive member 26 is integrated with the holding main body 25 by the fastening element 43. That is, the connecting portion 55 of the conductive member 26 overlaps the standing wall portion 41 of the holding main body portion 25 in the vertical direction Y, and the insertion hole 57 of the connecting portion 55 forms a communication hole with the mounting hole 42 of the standing wall portion 41. ing. Then, in the ridge side frame portion 15, a fastening element 43 having conductivity is inserted into the communication hole.
The engaging portion 56 of the conductive member 26 is located above the fixing plate portion 40 of the holding main body portion 25 and forms a step. That is, the engaging portion 56 of the conductive member 26 is stepwise continuous with the fixing plate portion 40 of the holding main body portion 25 via a part of the connecting portion 55 of the conductive member 26.
Further, the engaging portion 56 of the conductive member 26 is cantileveredly supported by the connecting portion 55 of the conductive member 26.

As shown in FIG. 6, the ridge-side gasket portion 28 is attached along the inner wall of the holding recess 30 of the holding main body portion 25.
Specifically, as can be read from FIGS. 6 and 9, the front side cushioning portion 48 of the hard gasket portion 45 faces the front side wall portion 35 of the skeleton portion 27 and is in surface contact with the back side cushioning portion 50. Faces and is in surface contact with the back side wall portion 37 of the skeleton portion 27. The front side buffer 48 and the back side buffer 50 face each other with a predetermined interval, and the rib 51 of the front side buffer 48 faces the rib 52 of the back surface side buffer 50 via the space. ing.
The soft gasket portion 46 is located between the end face side cushioning portion 49 of the hard gasket portion 45 and the back surface side wall portion 37 of the skeleton portion 27, and is in surface contact with the back surface side wall portion 37 of the skeleton portion 27.

Subsequently, the eaves side frame portion 16 will be described.

The eaves side frame portion 16 is a portion that holds the eaves side end portion of the solar cell panel 5 when the roof structure 1 is assembled as shown in FIG.
The eaves side frame portion 16 is a long body extending along the eaves side side 11 of the solar cell panel 5 as shown in FIG. 3, and the eaves side end portion of the solar cell panel 5 can be inserted as shown in FIG. It is provided with a holding recess 60. Further, in the eaves side frame portion 16, the holding recess 60 can be divided into a plurality of divided pieces 22 and 23 as shown in FIG.

As shown in FIG. 12, the eaves side frame portion 16 includes a first skeleton portion 61, a second skeleton portion 62, and an eaves side gasket portion 63.

The first skeleton portion 61, together with the second skeleton portion 62, is a portion that constitutes a lower frame that protects the eaves-side end portion of the solar cell panel 5.
As shown in FIG. 12, the first skeleton portion 61 includes a first recess forming portion 65 and a snow stopper portion 66.
As shown in FIG. 10, the first recess forming portion 65 is a portion forming a part of the holding recess 60 that can be fitted with the eaves side end portion of the solar cell panel 5, and is the eaves side of the solar cell panel 5. It is a long part extending along the side 11.
The first concave portion forming portion 65 has a substantially "L" -shaped cross section, and is composed of a front side wall portion 67 and an end surface side wall portion 68.
The front side wall portion 67 is a wall portion that covers the front side of the solar cell panel 5. As shown in FIG. 12, the front side wall portion 67 extends from the end surface side wall portion 68 in the vertical direction Y, and has a first concave groove 69 in the middle portion in the extending direction.

As can be read from FIGS. 10 and 12, the first concave groove 69 is a meshing portion that meshes with a part of the first gasket portion 100 of the eaves-side gasket portion 63, and specifically, has a bottom portion and a front side wall portion. It is a bottomed groove having a depth in the thickness direction of 67.
The first concave groove 69 has a linear opening shape and is formed over the entire lateral direction X. Further, the first concave groove 69 has a cross-sectional shape of "T", and has a depth in the thickness direction of the front side wall portion 67, and a depth direction of the first groove forming portion 72 and the first groove forming portion 72. The second groove forming portions 73 and 74 having a depth in a direction intersecting the thickness direction of the front side wall portion 67 from the end portion of the front side wall portion 67 are provided.

The length of the first concave groove 69 in the extending direction is preferably 1/3 or more, more preferably 2/3 or more, and even more preferably 3/4 of the eaves side side 11.

The end face side wall portion 68 is a wall portion that covers the end face side of the solar cell panel 5.
The upper end of the end face side wall portion 68 is connected to the front side wall portion 67 and the snow stopper portion 66, and the lower end portion thereof is a connection portion with the second skeleton portion 62.

The snow stopper 66 is a portion that regulates the movement of snow in the eaves direction when the roof structure 1 is assembled, and is a snow stopper piece that protrudes upward from the first recess forming portion 65. That is, as shown in FIG. 10, the snow stopper 66 has a long plate shape having a certain thickness in outer shape, and when the roof structure 1 is assembled, the front side wall portion 67 is connected to the light receiving surface 7 of the solar cell panel 5. It is a convex strip projecting in the direction orthogonal to the opposite.
Further, as shown in FIG. 11, the snow stopper 66 extends in the lateral direction X, and cutouts 58, 59, 64 are formed at both ends and an intermediate portion in the extending direction.

The cutout portions 58, 59, 64 are cutouts for draining rainwater and the like, and are water passage ports for flowing water passing over the solar cell panel 5 to the eaves side. As shown in FIG. 11, the cutout portions 58, 59, 64 are notches having a width in the lateral direction X and a depth from the tip end side to the base end side in the protruding direction of the snow stopper 66.
The notch 58 is located at one end of the snow stop 66 in the longitudinal direction (lateral direction X), as shown in FIG. 37, and is adjacent to the other in the girder direction when the roof structure 1 is assembled. A water passage 97 is formed together with the notch 59 of the solar cell module 2.
The notch 59 is located at the other end of the snow stopper 66 in the longitudinal direction (horizontal direction X), and is a notch of another solar cell module 2 adjacent in the girder direction when the roof structure 1 is assembled. Together with 58, it forms one channel 97.
The notch portion 64 is a notch located at the center of the snow stopper portion 66 in the longitudinal direction (horizontal direction X).

Further, the first skeleton portion 61 includes an insertion hole 71 extending across the snow stopper portion 66 and the end surface side wall portion 68. As shown in FIG. 11, the insertion hole 71 is a hole through which the temporary fastening element 70 can be inserted, and is a through hole that penetrates the snow stopper 66 in the projecting direction.
The temporary fastening element 70 is a known temporary fastening element, and is a screw in this embodiment.
The "temporary fastening element" in this specification is a kind of fastening element, and refers to a fastening element that can be fastened and released, and refers to a superordinate concept such as a screw or a combination of a bolt and a nut. ..

As can be read from FIGS. 10 and 12, the second skeleton portion 62 includes a second recess forming portion 75, a cover portion 76, and a fixing portion 77.

The second recess-forming portion 75, together with the first recess-forming portion 65 of the first skeleton portion 61, constitutes a holding recess 60 that can be fitted with the eaves-side end portion of the solar cell panel 5, and is a portion of the solar cell panel 5. It is a long member extending along the eaves side side 11.
The second concave portion forming portion 75 is a long plate-shaped portion extending in the lateral direction X, and includes a back surface side wall portion 78.
The back side wall portion 78 is a wall portion that covers the back side of the solar cell panel 5. The back side wall portion 78 extends from the cover portion 76 in the vertical direction Y, and is provided with a second concave groove 79 in the intermediate portion in the extending direction.

As shown in FIG. 12, the second concave groove 79 is a meshing portion that meshes with a part of the second gasket portion 101 of the eaves-side gasket portion 63. Specifically, the second concave groove 79 has a bottom portion and is in the thickness direction of the back surface side wall portion 78. It is a bottomed groove with a depth.
The second concave groove 79 has an opening shape on a straight line and is formed over the entire lateral direction X. Further, the second concave groove 79 has a cross-sectional shape of "T", and has a depth in the thickness direction of the back side wall portion 78 and a depth direction of the first groove forming portion 83 and the first groove forming portion 83. The second groove forming portions 84 and 85 having a depth in a direction intersecting the thickness direction of the back side wall portion 78 from the end portion of the back surface

The length of the second concave groove 79 in the extending direction is preferably 1/3 or more, more preferably 2/3 or more, and further preferably 3/4 of the eaves side side 11.

The cover portion 76 is a portion that constitutes the appearance of the solar cell module 2a together with the snow stopper portion 66 and the end face side wall portion 68 of the first skeleton portion 61 when the roof structure 1 is assembled. That is, the cover portion 76 is a portion that functions as a front cover together with the snow stopper portion 66 and the end face side wall portion 68.

As shown in FIG. 12, the cover portion 76 is a wall portion that rises downward from the eaves-side end portion of the back side wall portion 78.
The cover portion 76 is composed of a connecting portion 80, an upright wall portion 87 that stands upright from the connecting portion 80 downward, and an inclined wall portion 88 that is inclined at a predetermined angle from the lower end portion of the upright wall portion 87.

As shown in FIG. 12, the connecting portion 80 is a portion that connects to the end surface side wall portion 68 of the first skeleton portion 61, and is a portion that continuously projects from the eaves side end portion of the back surface side wall portion 78 toward the eaves side.
The connecting portion 80 includes a fastening receiving portion 82 that can be fastened to the temporary fastening element 70 in a direction orthogonal to the overhanging direction.
The fastening receiving portion 82 is a fastening hole that can be fastened to the temporary fastening element 70, and is a bottomed hole extending from the upper surface in the member thickness direction.

As shown in FIG. 10, the fixing portion 77 includes a spacing maintaining wall portion 90 and an engaging portion 91 (engagement piece on the eaves side).
The space maintaining wall portion 90 is a portion that maintains a distance between the second recess forming portion 75 and the engaging portion 91 in the vertical direction Y.
The space-maintaining wall portion 90 is a plate-shaped wall portion, and is continuously connected to the back side wall portion 78 in a stepped manner via the wall portion 95.
Further, a rib 92 extending in the lateral direction X is formed on the lower surface of the space maintaining wall portion 90, and the rigidity of the lateral direction X is reinforced by the rib 92.

As shown in FIG. 27, the engaging portion 91 is an engaging piece that can be engaged with the eaves tip metal fitting 302, and has an “L” -shaped cross section. The engaging portion 91 includes a standing wall portion 93 and a locking wall portion 94.
The vertical wall portion 93 is a wall portion that connects the spacing wall portion 90 and the locking wall portion 94, and the spacing maintaining wall portion 90 and the locking wall portion 94 are continuous in a stepped manner via the vertical wall portion 93. ..

Similar to the skeleton portion 27 of the ridge side frame portion 15, the skeleton portions 61 and 62 are formed by coating the surface of the core member, which is a conductor, with a protective layer having a lower electrical conductivity than the conductor. Is formed by anodizing the surface of an aluminum drawing material.

As shown in FIG. 12, the eaves-side gasket portion 63 is interposed between the solar cell panel 5 and the holding recess 60 to close the gap between the solar cell panel 5 and the holding recess 60. That is, the eaves-side gasket portion 63 comes into direct contact with the end portion of the solar cell panel 5 to prevent the solar cell panel 5 from being displaced or coming off with respect to the skeleton portions 61 and 62.
The eaves side gasket portion 63 is formed of an elastic cushioning material.
The eaves-side gasket portion 63 is a long body that extends continuously or intermittently in the lateral direction X as shown in FIG. 13A, and has a cross-sectional shape of “U” as shown in FIG. 13B. doing.

The eaves-side gasket portion 63 includes a first gasket portion 100 and a second gasket portion 101 as shown in FIG. 13 (b).
As shown in FIG. 11, the first gasket portion 100 is a portion that constitutes the first division piece 22 together with the first skeleton portion 61, and has an “L” -shaped cross section.
As shown in FIG. 13, the first gasket portion 100 includes a front side cushioning portion 102 and an end face side cushioning portion 103.
The front side cushioning portion 102 is a portion interposed between a part of the front surface of the solar cell panel 5 and the front side wall portion 67, and as shown in FIG. 13B, the main body portion 105 and the folded portion 106 The first convex portion 107, the slit 108, and the rib 109 are provided.

The main body 105 is a long plate-shaped portion having a width in the vertical direction Y and extending in the horizontal direction X.
As can be read from FIGS. 13 and 12, the folded-back portion 106 is a portion folded back from the lateral end (longitudinal direction Y) of the main body 105, and is the end of the front side wall portion 67 of the first skeleton portion 61. It is possible to cover the part.
As shown in FIG. 12, the first ridge portion 107 is a portion paired with the first concave groove 69 of the front side wall portion 67 of the first skeleton portion 61, and is outside the main body portion 105 with reference to the solar cell panel 5. It is a protruding part.

As shown in FIG. 12, the first ridge portion 107 includes a protruding main body 110 and locking portions 111 and 112.
The protruding main body 110 is a wall portion that protrudes upward from the main body portion 105, and is a portion that forms the skeleton of the first convex strip portion 107.
The locking portions 111 and 112 are locking pieces protruding in the vertical direction Y from the tip of the protruding main body 110 in the protruding direction from the main body 105. The locking portions 111 and 112 project in a direction away from each other with the protruding main body 110 interposed therebetween.
The locking portions 111 and 112 can be engaged with the second groove forming portions 73 and 74 of the first concave groove 69 of the first skeleton portion 61.

The length of the first ridge portion 107 in the extending direction is preferably 1/3 or more, more preferably 2/3 or more, and 3/4 of the length of the eaves side side 11. More preferred.

As shown in FIG. 13, the slit 108 is a slit that extends in the lateral direction X and has a depth in the thickness direction of the main body 105. That is, a part of the main body 105 is cut out by the slit 108 to form a thick portion and a thin portion, and in addition to the elasticity due to its own material, the elasticity is also added by the slit 108. There is.

The rib 109 is a convex strip piece that comes into contact with the front surface of the solar cell panel 5 to prevent the solar cell panel 5 from falling off.
The rib 109 is formed on the opposite surface to the slit 108 of the main body 105.

The end face side cushioning portion 103 is a portion interposed between a part of the eaves side end face of the solar cell panel 5 and the end face side wall portion 68.

As shown in FIG. 11, the second gasket portion 101 is a paired portion forming the second divided piece 23 together with the second skeleton portion 62, and includes a back surface side buffer portion 115.
As can be read from FIGS. 13 and 12, the back surface side cushioning portion 115 is a portion interposed between a part of the back surface of the solar cell panel 5 and the back surface side wall portion 78, and is a portion interposed between the main body portion 116 and the second. It includes a ridge portion 117, a slit 118, and a rib 119.

The main body 116 is a long plate-shaped portion having a width in the vertical direction Y and extending in the horizontal direction X.
The second ridge portion 117 is a portion paired with the second concave groove 79 of the back side wall portion 78 of the second skeleton portion 62, and is a portion protruding outward from the main body portion 116 with reference to the solar cell panel 5. ..
As shown in FIG. 12, the second ridge portion 117 includes a protruding main body 120 and locking portions 121 and 122.
The protruding main body 120 is a wall portion that protrudes downward from the main body portion 116, and is a portion that forms the skeleton of the second ridge portion 117.
The locking portions 121 and 122 are locking pieces that project vertically from the tip of the protruding main body 120 in the protruding direction from the main body 116. The locking portions 121 and 122 project in a direction in which they are separated from each other with the protruding main body 120 in between.
The locking portions 121 and 122 can be engaged with the second groove forming portions 84 and 85 of the second concave groove 79 of the second skeleton portion 62.

The length of the second convex portion 117 in the extending direction is preferably 1/3 or more, more preferably 2/3 or more, and 3/4 of the length of the eaves side side 11. More preferred.

As shown in FIG. 13, the slit 118 is a slit that extends in the lateral direction X and has a depth in the thickness direction of the main body 116. That is, a part of the main body 116 is cut out by the slit 118 to form a thick portion and a thin portion, and in addition to the elasticity due to its own material, the elasticity is also added by the slit 118. There is.

The rib 119 is a convex strip piece that comes into contact with the front surface of the solar cell panel 5 to prevent the solar cell panel 5 from falling off.
The rib 119 is formed on the opposite surface to the slit 118 of the main body 116.

Here, the positional relationship of each component of the eaves side frame portion 16 will be described.

As can be read from FIG. 11, the first skeleton portion 61 is integrated with the second skeleton portion 62 by the temporary fastening element 70, and can be attached to and detached from the second skeleton portion 62 by removing the temporary fastening element 70. It has become. That is, the snow stopper 66 and the end surface side wall portion 68 of the first skeleton portion 61 overlap with the connection portion 80 of the second skeleton portion 62 in the thickness direction, and the insertion hole 71 of the snow stopper 66 is as shown in FIG. A communication hole is formed with the fastening receiving portion 82 of the connecting portion 80. The eaves side frame portion 16 has a temporary fastening element 70 inserted into the communication hole.
The outer surface (end surface on the eaves side) of the connection portion 80 is flush with the outer surface (end surface on the eaves side) of the snow stopper 66 and the end surface side wall portion 68 with reference to the solar cell panel 5. ing.

The first recess forming portion 65 of the first skeleton portion 61 and the second recess forming portion 75 of the second skeleton portion 62 are connected to form a holding recess 60.
The eaves-side gasket portion 63 is attached along the inner wall of the holding recess 60 formed by the skeleton portions 61 and 62.
The first gasket portion 100 is integrated with the first skeleton portion 61 to form the first divided piece 22, and the second gasket portion 101 is integrated with the second skeleton portion 62 to form the second divided piece 23. Is forming.
As shown in FIG. 12, the first convex portion 107 of the front side cushioning portion 102 of the first gasket portion 100 is inserted into the first concave groove 69 of the front side wall portion 67 of the first skeleton portion 61.
Specifically, as shown in FIG. 12, the protruding main body 110 is located in the first groove forming portion 72, and the locking portions 111 and 112 are located in the second groove forming portions 73 and 74. There is. The locking portions 111 and 112 are engaged with the inner walls of the second groove forming portions 73 and 74 to prevent the first gasket portion 100 from separating from the first skeleton portion 61.
The front side cushioning portion 102 of the first gasket portion 100 faces and is in surface contact with the front side wall portion 67 of the first skeleton portion 61, and the end surface side cushioning portion 103 is the end surface side wall portion 68 of the first skeleton portion 61. Face-to-face contact. The folded-back portion 106 of the first gasket portion 100 wraps and covers the end surface of the front side wall portion 67.

The second convex portion 117 of the back surface side buffer portion 115 of the second gasket portion 101 is inserted into the second concave groove 79 of the back surface side wall portion 78 of the second skeleton portion 62 as shown in FIG.
Specifically, the protruding main body 120 is located in the first groove forming portion 83 as shown in FIG. 12, and the locking portions 121 and 122 are located in the second groove forming portions 84 and 85. .. The locking portions 121 and 122 are engaged with the inner walls of the second groove forming portions 84 and 85 to prevent the second gasket portion 101 from separating from the second skeleton portion 62.
The back surface side cushioning portion 115 of the second gasket portion 101 faces and is in surface contact with the back surface side wall portion 78 of the second skeleton portion 62. A part of the back surface side cushioning portion 115 projects from the wall portion 95.
The back surface side cushioning portion 115 of the second gasket portion 101 faces the front side cushioning portion 102 of the first gasket portion 100 at a predetermined interval, and the rear end portion of the solar cell panel 5 is inserted within the interval. It is possible. Further, the rib 119 of the back surface side cushioning portion 115 faces the rib 92 of the front side cushioning portion 102.

As shown in FIG. 3, the left frame portion 17 is a left frame along the left side 12 of the solar cell panel 5, and is a member that supports the back surface of the solar cell panel 5. Further, the left side frame portion 17 is also a member that connects the ridge side frame portion 15 and the eaves side frame portion 16 as can be read from FIG.
The left frame portion 17 is formed by coating the surface of a core member serving as a conductor with a protective layer having a lower electrical conductivity than that of the conductor. Specifically, the surface of an aluminum drawing material is anodized. It is formed by going.
As shown in FIG. 14, the left frame portion 17 includes a skeleton portion 130 and a flow path forming portion 131.
The skeleton portion 130 is a portion on which the back surface of the solar cell panel 5 is placed, and is a rod-shaped portion extending in the vertical direction Y as shown in FIG.
As shown in FIG. 14, the skeleton portion 130 includes a main body portion 140 and a closing portion 141 projecting to the left from the upper end portion of the main body portion 140.
The main body 140 is a rod-shaped body having a quadrangular outer shape, and the inside thereof is hollow.
The closing portion 141 is a plate-shaped portion protruding from the top surface (upper surface) of the main body portion 140, and is a portion that closes the flow path 135 together with the other solar cell modules 2 when the roof structure 1 is assembled.

Further, the skeleton portion 130 is provided with a ridge-side connecting portion 132 that can be connected to the ridge-side frame portion 15 at one end in the longitudinal direction as shown in FIG. 5, and the eaves-side frame at the other end in the longitudinal direction. The eaves side connecting portion 133 that can be connected to the portion 16 is provided. The skeleton portion 130 includes a mounting portion 139 to which the insertion metal fitting 20 can be attached to the intermediate portion in the longitudinal direction.

The flow path forming portion 131 is a portion protruding to the left side from the skeleton portion 130, and when the roof structure 1 is assembled, rainwater or the like flowing down on the solar cell module 2 is released to the eaves side and / or the roof base 301 side. It is the part that forms the rain gutter. That is, the flow path forming portion 131 is a portion that forms the flow path 135 through which rainwater or the like can pass together with the outer surface of the skeleton portion 130 with reference to the solar cell panel 5.
The flow path forming portion 131 is also a portion that is electrically connected to the right frame portion 18 of the other solar cell module 2 when the roof structure 1 is assembled.
As shown in FIG. 14, the flow path forming portion 131 has an “L” -shaped cross section, and includes a bottom surface forming portion 136 (extended portion) and a side wall forming portion 137 (rising portion).
The bottom surface forming portion 136 is a portion connected to the lower end portion of the main body portion 140 of the skeleton portion 130 and continuous with the bottom surface of the main body portion 140 of the skeleton portion 130. Further, the bottom surface forming portion 136 is an extended portion extending from the outer surface of the main body portion 140 in the lateral direction X, and is a portion constituting the bottom portion of the flow path 135.

The side wall forming portion 137 is a rising piece rising from the end portion (left end portion) in the projecting direction of the bottom surface forming portion 136, and is a portion forming the side wall of the flow path 135.
The side wall forming portion 137 has a conductive portion 138 (fourth conductive portion, overhanging side conductive portion) attached to the tip portion in the rising direction from the bottom surface forming portion 136.
The conductive portion 138 is a portion formed of a conductor and serves as an electrical contact point with the conductive portion 150 of the right frame portion 18 of the other solar cell module 2. The conductive portion 138 constitutes the tip portion of the side wall forming portion 137 and has a sharply pointed sword tip shape. That is, the conductive portion 138 comes into contact with the conductive portion 150 of the right frame portion 18 and can be point-contacted. The conductive portion 138 is a separate member from the side wall forming portion 137, and is adhered to the tip surface of the side wall forming portion 137.

The right frame portion 18 is a right frame along the right side 13 of the solar cell panel 5 as shown in FIG. 3, and is a member that connects the ridge side frame portion 15 and the eaves side frame portion 16 as shown in FIG.
As can be read from FIGS. 5 and 15, the right frame portion 18 is a portion that supports the back surface of the solar cell panel 5, and is a rod-shaped portion that extends in the vertical direction Y.
The right frame portion 18 is formed by coating the surface of a core member serving as a conductor with a protective layer having a lower electrical conductivity than that of the conductor. Specifically, the surface of an aluminum drawing material is anodized. It is formed by going.
As shown in FIG. 15, the right frame portion 18 includes a skeleton portion 145 and a closing portion 146.
The skeleton portion 145 is a rod-shaped body having a quadrangular outer shape, and the inside thereof is hollow.
As shown in FIG. 5, the skeleton portion 145 is provided with a ridge-side connecting portion 147 that can be connected to the ridge-side frame portion 15 at one end in the longitudinal direction, and the eaves-side frame portion at the other end in the longitudinal direction. It is provided with an eaves-side connection portion 148 that can be connected to 16.
The skeleton portion 145 includes a mounting portion 149 to which the insertion metal fitting 21 can be attached to the intermediate portion in the longitudinal direction. Further, as shown in FIG. 15, the skeleton portion 145 is provided with a conductive portion 150 (third conductive portion, overlapping side conductive portion) whose core member is exposed from the protective layer on the bottom surface thereof.
The conductive portion 150 is a portion that can be electrically connected to the conductive portion 138 of the left frame portion 17 of the solar cell module 2 adjacent in the girder direction. The conductive portion 150 is a concavo-convex portion in which a plurality of convex portions 151 are formed as shown in FIG.
The convex portion 151 has a triangular cross-sectional shape and is a ridge extending in the vertical direction, and has a sharp tip in the protruding direction.

The closing portion 146 is a portion that closes the flow path 135 formed by the flow path forming portion 131 of the left frame portion 17 of the other solar cell module 2. The closing portion 146 is a protruding portion protruding to the right from the outer surface of the skeleton portion 145, and is a portion covering the flow path 135.

The insertion fittings 20 and 21 are portions that are electrically connected by engaging with the conductive member 26 of the solar cell module 2 on the eaves side when the roof structure 1 is assembled.
As shown in FIG. 5, the insertion fittings 20 and 21 include insertion portions 160 and 161 and reinforcing bars 162 and 163.
As shown in FIG. 17, the insertion portions 160 and 161 have a substantially "U" -shaped cross section, and have a back surface arrangement portion 165, a space forming portion 166, and a locking piece 167 (first engaging portion). I have.
The back surface arrangement portion 165 is a portion arranged on the back surface side of the solar cell panel 5, and is also a back surface support portion that supports the back surface of the solar cell panel 5.
As shown in FIG. 17, the space forming portion 166 is a portion where the back surface arranging portion 165 and the locking piece 167 are separated from each other at a predetermined interval to form a space 170 sandwiched between the back surface arranging portion 165 and the locking piece 167. Is.
A back surface arrangement portion 165 is connected to the upper end portion of the space forming portion 166, and a locking piece 167 is connected to the lower end portion.
The space 170 is a space that has a depth in the eaves direction when the roof structure 1 is assembled, and an engaging portion 56 of the conductive member 26 of the ridge side frame portion 15 of the solar cell module 2 on the eaves side can be inserted. is there.

The locking piece 167 is a portion that can be engaged with the engaging portion 56 of the conductive member 26 of the ridge side frame portion 15 of the solar cell module 2 on the eaves side, and is a portion that faces the back surface arrangement portion 165 with the space 170 in between. Is.
The locking piece 167 includes a main body plate portion 171 (facing portion) and a folded portion 172 (first conductive portion, overlapping side conductive portion).
The main body plate portion 171 is a facing portion facing the back surface arranging portion 165 at intervals, and is a plate-shaped portion erected from the space forming portion 166.
The length (length in the vertical direction) of the main body plate portion 171 is preferably 1/3 or more and 1/2 or less of the length of the vertical side 12 or the vertical side 13 of the entire solar cell module 2.

The folded-back portion 172 is a portion folded back from the eaves-side end portion of the main body plate portion 171 to the solar cell panel 5 side.
The folded-back portion 172 is a pressing portion that presses the conductive member 26 of the solar cell module 2 on the eaves side when the roof structure 1 is assembled, and is a conductive portion that serves as an electrical contact point with the conductive member 26 of the solar cell module 2. It is also a department.
The folded-back portion 172 is a portion that gives elasticity to the locking piece 167, and the angle formed by the main body plate portion 171 is bent at an acute angle, and the vicinity of the tip portion thereof can come into contact with the conductive member 26. That is, the main body plate portion 171 and the folded portion 172 have an overlapping portion when the solar cell panel 5 is viewed in a plan view, and in the overlapping portion, a gap is formed between the main body plate portion 171 and the folded portion 172. ..

As can be read from FIGS. 5 and 17, the insertion portions 160 and 161 are provided with connection portions 175 and 176 that can be connected to the skeleton portions 130 and 145 of the frame portions 17 and 18 at the outer end portions in the lateral direction.

As shown in FIG. 5, the reinforcing bars 162 and 163 are reinforcing bars that connect the eaves side frame portion 16 and the insertion portions 160 and 161 to reinforce the rigidity of the solar cell panel 5, and the roof structure 1 is assembled. This is a portion that holds the insertion portions 160 and 161 when a blowing force due to a strong wind or the like is applied to the insertion portions 160 and 161.
The reinforcing bars 162, 163 are elongated plate-shaped portions extending in the vertical direction Y, and are eaves-side connecting portions 178,179 that can be connected to the eaves-side frame portion 16 at one end in the longitudinal direction (vertical direction Y). Is provided, and the insertion side connection portions 180 and 181 that can be connected to the insertion portions 160 and 161 are provided at the other end in the longitudinal direction.

Subsequently, the positional relationship of each component of the first solar cell module 2a will be described.

As shown in FIG. 3, the solar cell panel 5 is held by the holding member 6a, and the light receiving surface 7 is exposed from the holding member 6.
Specifically, the ridge-side end of the solar cell panel 5 is inserted into the holding recess 30 of the ridge-side frame 15 as shown in FIG. 6, and the eaves-side end of the solar cell panel 5 is shown in FIG. As described above, it is inserted into the holding recess 60 of the eaves side frame portion 16.
The vicinity of the left end portion of the solar cell panel 5 is placed on the main body 140 of the left frame portion 17, and the vicinity of the right end portion of the solar cell panel 5 is closed with the skeleton portion 145 of the right frame portion 18. It is placed on the part 146.

Further, in the ridge side frame portion 15, the holding main body portion 25 straddles the overlapping portion 8 and the ridge side overhanging portion 9a, and the conductive member 26 is located at the ridge side overhanging portion 9a.
The eaves side frame portion 16 straddles the superimposing portion 8 and the eaves side overhanging portion 9b, and the engaging portion 91 is located at the superimposing portion 8.
In the left frame portion 17, the main body portion 140 of the skeleton portion 130 is located at the superimposing portion 8, and the closing portion 141 and the flow path forming portion 131 of the skeleton portion 130 are located at the girder side overhanging portion 9c. That is, the conductive portion 138 is located at the girder side overhanging portion 9c.
The right frame portion 18 is located at the superimposing portion 8. That is, the conductive portion 150 is located at the superimposing portion 8.
The insertion brackets 20 and 21 are located at the overlapping portion 8. That is, the locking piece 167 is located at the superimposing portion 8.

Subsequently, the second solar cell module 2b having no snow stop function will be described. The same configuration as that of the first solar cell module 2a with a snow stopper function will be given the same number and the description thereof will be omitted.

As shown in FIG. 18, the shape of the eaves side frame portion 200 of the holding member 6b of the second solar cell module 2b is different from the shape of the eaves side frame portion 16 of the holding member 6a of the first solar cell module 2a. That is, the eaves-side frame portion 200 of the holding member 6b does not have the snow stopper 66 like the eaves-side frame portion 16 of the first solar cell module 2a.
The eaves side frame portion 200 is a portion that holds the eaves side end portion of the solar cell panel 5 when the roof structure 1 is assembled, like the eaves side frame portion 16 of the first solar cell module 2a.
The eaves side frame portion 200 is a long body extending along the eaves side side 11 of the solar cell panel 5, and as shown in FIG. 19, a holding recess 201 into which the eaves side end portion of the solar cell panel 5 can be inserted is provided. I have.
Further, the eaves side frame portion 200 includes a first skeleton portion 202, a second skeleton portion 203, and an eaves side gasket portion 63.
The first skeleton portion 202, together with the second skeleton portion 203, is a portion that constitutes a lower frame that protects the eaves-side end portion of the solar cell panel 5.
The first skeleton portion 202 includes a first recess forming portion 206 as shown in FIG.
The first recess forming portion 206 is a portion forming a part of the holding recess 201 that can be fitted with the eaves side end portion of the solar cell panel 5, and has a length extending along the eaves side side 11 of the solar cell panel 5. It is a member of the scale.

As shown in FIG. 19, the first concave portion forming portion 206 is a portion having a substantially “L” -shaped cross section, and is composed of a front side wall portion 210 and an end face side wall portion 211.
The front side wall portion 210 is a wall portion that covers a part of the front side of the solar cell panel 5. The front side wall portion 210 extends in the vertical direction Y from the end surface side wall portion 211, and includes a first concave groove 69 in the intermediate portion in the extending direction.
The end face side wall portion 211 is a wall portion that covers the end face side of the solar cell panel 5, and is a portion that functions as a front cover that forms the appearance of the eaves side end portion of the second solar cell module 2b.
As shown in FIG. 20, the end face side wall portion 211 has an insertion hole 212 in the middle portion in the height direction thereof.
The insertion hole 212 is a hole through which the temporary fastening element 215 can be inserted, and is a through hole penetrating in the thickness direction.

As shown in FIG. 19, the second skeleton portion 203 includes a second recess forming portion 216, a connecting portion 217, and a fixing portion 77.

The second recess-forming portion 216, together with the first recess-forming portion 206 of the first skeleton portion 202, constitutes a holding recess 201 that can be fitted to the eaves-side end portion of the solar cell panel 5, and is a portion of the solar cell panel 5. It is a long member extending along the eaves side side 11.
The second recess forming portion 216 includes a back side wall portion 78.
The back side wall portion 78 is a wall portion that covers the back side of the solar cell panel 5.

The connecting portion 217 is a portion that connects to the end surface side wall portion 211 of the first skeleton portion 202, and is a portion that is erected downward from the eaves end side end portion of the back surface side wall portion 78.
The connecting portion 217 is composed of an upright wall portion 218 that stands upright downward from the back side wall portion 78 and an inclined wall portion 219 that is inclined at a predetermined angle from the lower end portion of the upright wall portion 218.
The upright wall portion 218 includes a fastening receiving portion 220 that can be fastened to the temporary fastening element 215.
The fastening receiving portion 220 is an engaging hole that can be engaged with the temporary fastening element 215, and is a hole that extends in the member thickness direction of the upright wall portion 218.

Here, the positional relationship of each component of the eaves side frame portion 200 will be described.

As can be read from FIG. 20, the first skeleton portion 202 is integrated with the second skeleton portion 203 by the temporary fastening element 215, and can be attached to and detached from the second skeleton portion 203 by removing the temporary fastening element 215. It has become. That is, the end face side wall portion 211 of the first skeleton portion 202 overlaps with the upright wall portion 218 of the second skeleton portion 203 in the thickness direction, and the insertion hole 212 of the first skeleton portion 202 is the first as shown in FIG. 2 A communication hole is formed with the fastening receiving portion 220 of the skeleton portion 203. Then, in the eaves side frame portion 200, the temporary fastening element 215 is inserted into the communication hole.
Further, as shown in FIG. 20, the first gasket portion 100 is integrated with the first skeleton portion 202 to form the first partition piece 207, and the second gasket portion 101 is integrated with the second skeleton portion 203. The second divided piece 208 is formed.
Further, the eaves side frame portion 200 is located at the eaves side overhanging portion 9b as in the eaves side frame portion 16 of the first embodiment.

Subsequently, the positional relationship of each component of the second solar cell module 2b will be described.

The solar cell panel 5 is held by the holding member 6b, and the light receiving surface 7 is exposed from the holding member 6b. Specifically, the ridge-side end of the solar cell panel 5 is inserted into the holding recess 30 of the ridge-side frame 15, and the eaves-side end of the solar panel 5 is the holding recess of the eaves-side frame 200. It is inserted in 201.

Subsequently, the remaining constituent members of the roof structure 1 will be described.

The roof tile member 300 is a known roof tile, and is a member fixed to the roof base 301 by a fastening element 305 such as a nail.
As shown in FIG. 21, the tile member 300 has a certain thickness and has a substantially quadrangular shape in a plan view.
The tile member 300 is provided with a fixing hole 310 at the end in the ridge direction for fixing to the roof base 301. The fixing hole 310 is a through hole penetrating in the member thickness direction, and the fastening element 305 can be inserted therethrough.

The eaves edge metal fitting 302 is a metal fitting that is directly attached to the tile rail 306 of the foundation roof structure 304 and fixes the solar cell module 2 to the foundation roof structure 304.
The eaves edge metal fitting 302 is formed by bending a single plate material.
As shown in FIG. 22, the eaves metal fitting 302 is composed of a first plate portion 311, a connecting plate portion 312, and a second plate portion 313.
The first plate portion 311 is a mounting portion to be attached to the roof base 301, and includes a fixing hole 315 and a notch portion 316.

The connection plate portion 312 is a plate portion that connects the end portion of the first plate portion 311 and the end portion of the second plate portion 313, and forms a step between the first plate portion 311 and the second plate portion 313. It is a part to do.
A part of the connecting plate portion 312 is cut up to form a cut-up portion 317. That is, the connecting plate portion 312 is formed with a through hole 318 penetrating in the thickness direction by the cut-up portion 317.
The cut-up portion 317 forms the same plane as the first plate portion 311 and is flush with each other.
The through hole 318 is a rain escape hole that allows rainwater or the like to escape.
The second plate portion 313 is an engaging piece that can be engaged with the engaging portion 91 of the solar cell module 2.
The second plate portion 313 is located higher than the first plate portion 311 and is continuously connected to the first plate portion 311 in a stepped manner via the connecting plate portion 312.

The intermediate mounting bracket 303 is a member formed by bending a single plate material as shown in FIG. 23.
The intermediate mounting bracket 303 is a member that is integrally mounted on the roof tile member 300, and includes a first plate portion 330, a connecting plate portion 331, and a second plate portion 332 (metal fitting side overhanging portion).
The first plate portion 330 is a mounting portion to be attached to the roof tile member 300, and includes a mounting hole 333.
The mounting hole 333 is a through hole penetrating in the member thickness direction, and the fastening element 305 can be inserted therethrough.
The connection plate portion 331 is a plate portion that connects the end portion of the first plate portion 330 and the end portion of the second plate portion 332, and forms a step between the first plate portion 330 and the second plate portion 332. It is a part to do.
The second plate portion 332 is an engaging piece that can be engaged with the insertion fittings 20 and 21 of the solar cell module 2.
The second plate portion 332 is located at a position lower than the first plate portion 330, and is continuous with the first plate portion 330 in a stepped manner via the connecting plate portion 331.

As shown in FIG. 24, the foundation roof structure 304 has a roof tile 306, a tile bar 307, and a roof base 301 on which a field board 308 is laid on an inclined surface at a predetermined angle.
The tile crosspiece 306 is a long body extending in the girder direction, and is a member having a right-angled triangular cross section.
The slope of the tile rail 306 is provided so as to face a direction intersecting the slope direction (eave building direction) of the slope.
The tile bar 307 is a member that supports the tile member 300 and the solar cell module 2, and is a long body extending in the girder direction.
The tile rods 307 are arranged side by side at predetermined intervals in the inclination direction.
The field board 308 is a member arranged between the tile bars 307 and 307 arranged side by side, and is a rectangular board material.

Subsequently, the procedure for assembling the roof structure 1 according to the first embodiment of the present invention will be described.

As can be read from FIG. 25A, a plurality of eaves metal fittings 302 are attached to the tile rail 306 of the foundation roof structure 304 in advance.

At this time, as can be read from FIG. 27A, the fastening element 320 such as a nail is inserted into the tile rail 306 through the fixing hole 315 of the eaves metal fitting 302, and the eaves metal fitting 302 and the tile rail 306 are integrally formed. It has become. Further, the second plate portion 313 of the eaves tip metal fitting 302 projects from the tile rail 306 of the foundation roof structure 304, and is cantileveredly supported by the connecting plate portion 312.

Subsequently, the tile member 300 and the first-stage solar cell module 2 are laid on the foundation roof structure 304.

First, the roof tile member 300 is placed on the roof tile rod 307, and the fastening element 335 such as a nail is placed with the intermediate mounting bracket 303 attached to the ridge side end of the roof tile member 300.

At this time, as can be read from FIG. 30, the fastening element 335 is driven into the roof tile rod 307 through the mounting hole 333 of the first plate portion 330 of the intermediate mounting bracket 303, and the intermediate mounting bracket 303 and the roof tile member 300. Are united. Further, the second plate portion 332 of the intermediate mounting bracket 303 projects from the tile member 300 toward the ridge side, and is supported in a cantilever shape by the connecting plate portion 331.

Subsequently, as shown in FIG. 25 (a), the first-stage solar cell module 2 (2A) is hooked on the eaves tip metal fitting 302, moved to the ridge side, and placed on the tile bar 307 of the foundation roof structure 304. As shown in 25 (b), the solar cell module 2A is positioned so as to be relatively close to the tile member 300 installed in advance. Then, the solar cell module 2A is fixed to the foundation roof structure 304 by a fastening element 39 such as a nail.

At this time, the left end portion of the tile member 300 is located below the closing portion 146 of the right frame portion 18 of the solar cell module 2A, and the right end surface of the solar cell panel 5 is close to the left end surface of the tile member 300. Face to face.
Further, in the solar cell module 2A, as can be read from FIG. 27, the engaging portion 91 of the eaves side frame portion 200 is engaged with the second plate portion 313 of the eaves metal fitting 302, and the fixing plate of the ridge side frame portion 15 is engaged. The portion 40 is placed on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the roof tile rod 307 through the fixing hole 44 of the fixing plate portion 40 of the ridge side frame portion 15 of the solar cell module 2A.

Subsequently, as shown in FIG. 26 (a), the solar cell module 2 (2B) is hooked on the eaves tip metal fitting 302 and moved to the ridge side, and placed on the tile bar 307 of the foundation roof structure 304, and is placed on the tile rod 307 of the foundation roof structure 304, and is placed in FIG. ), The solar cell module 2B is positioned so as to be relatively close to the adjacent solar cell module 2A in the girder direction.
Here, at the time of this positioning, as shown in FIG. 28, the sun so that the tip of the conductive portion 138 of the left frame portion 17 of the solar cell module 2A contacts the protective layer of the right frame portion 18 of the solar cell module 2B. The battery module 2B is moved to scrape a part of the protective layer to expose the conductive portion 150.
Then, in a state where the conductive portion 138 of the left frame portion 17 bites into the conductive portion 150 of the right frame portion 18, the solar cell module 2B is fixed to the foundation roof structure 304 by a fastening element 39 such as a nail.

At this time, in the direction of the eaves building, as shown in FIG. 27A, in the solar cell module 2B, the engaging portion 91 of the eaves side frame portion 200 is engaged with the second plate portion 313 of the eaves tip metal fitting 302. The fixing plate portion 40 of the ridge side frame portion 15 is placed on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the roof tile rod 307 through the fixing hole 44 of the fixing plate portion 40 of the ridge side frame portion 15 of the solar cell module 2B.
On the other hand, in the girder direction, as shown in FIG. 27B, in the solar cell module 2B, the right frame portion 18 is engaged with the left frame portion 17 of the solar cell module 2A, and the left frame portion of the solar cell module 2A. It is positioned by 17.
Specifically, in the left frame portion 17 of the solar cell module 2A, the conductive portion 138 located at the tip of the side wall forming portion 137 is located on the lower surface of the skeleton portion 145 of the right frame portion 18 of the solar cell module 2B. Is in contact with. The tip of the conductive portion 138 of the left frame portion 17 of the solar cell module 2A is inserted into the recess between the convex portions 151 and 151 of the conductive portion 150 of the right frame portion 18 of the solar cell module 2B, and the conductive portion 150 It is engaged with the convex portion 151 of the. In the left frame portion 17 of the solar cell module 2A, the closing portion 141 is in contact with or close to the closing portion 146 of the right frame portion 18 of the solar cell module 2B, and the upper part of the flow path 135 is covered by the closing portion 146. ing.
Further, in the solar cell panel 5 of the solar cell module 2B, the right side 13 is close to the left side 12 of the solar cell panel 5 of the solar cell module 2A, and the right end surface is the left end surface of the solar cell panel 5 of the solar cell module 2A. Face to face.

When the laying of the first-stage solar cell module 2 on the foundation roof structure 304 is completed, the second-stage roof tile member 300 and the solar cell module 2 are laid.
Specifically, as shown in FIG. 29A, the second-stage solar cell module 2 (2C) is slid toward the eaves side, and the intermediate mounting bracket 303 and the first-stage solar cell module attached to the roof tile member 300. A part of the ridge side frame portion 15 of 2A is inserted and placed on the tile bar 307 of the foundation roof structure 304. Then, as shown in FIG. 29B, the solar cell module 2C is positioned relatively close to the pre-installed second-stage roof tile member 300, and the solar cell module 2C is positioned by the fastening element 39 such as a nail. The solar cell module 2C is fixed to the foundation roof structure 304.

At this time, the second-stage solar cell module 2C is arranged across the intermediate mounting bracket 303 and the first-stage solar cell module 2A in the girder direction, as can be read from FIGS. 29 (a) and 29 (b). ing. The central portion of the solar cell panel 5 of the second-stage solar cell module 2C in the girder direction is located near the boundary portion between the tile member 300 and the first-stage solar cell module 2A.
In the second-stage solar cell module 2C, as shown in FIG. 31, a part of the eaves side frame portion 16 is mounted on a part of the front side wall portion 35 of the ridge side frame portion 15 of the first-stage solar cell module 2A. There is. Further, the insertion portion 161 of the right insertion bracket 21 is engaged with the second plate portion 332 of the intermediate mounting bracket 303, and the insertion portion 160 of the left insertion bracket 20 is the first-stage solar cell module 2A. It is engaged with the engaging portion 56 of the ridge side frame portion 15.

Specifically, in the second-stage solar cell module 2C, as shown in FIG. 31, the second plate portion 332 of the intermediate mounting bracket 303 is inserted into the space 170 of the insertion portion 161 of the insertion bracket 21 on the right side. The folded portion 172 of the locking piece 167 of the above is entered in a pressed state, and the folded portion 172 is pressing the second plate portion 332 upward by the elastic restoring force. The contact portion between the folded-back portion 172 of the locking piece 167 of the insertion portion 161 and the second plate portion 332 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 2C.
The tip of the second plate portion 332 of the intermediate mounting bracket 303 does not reach the space forming portion 166 of the insertion portion 161 of the insertion bracket 21 on the right side, and the tip of the second plate portion 332 of the intermediate mounting bracket 303 does not reach. There is a gap between the insertion portion 161 and the space forming portion 166 of the insertion portion 161. That is, an adjustable space 185 in the eaves building direction is formed on the projection surface of the second plate portion 332 of the intermediate mounting bracket 303 in the insertion direction.

Further, as shown in FIG. 30, the second-stage solar cell module 2C has an engaging portion 56 of the ridge-side frame portion 15 of the first-stage solar cell module 2A in the space 170 of the insertion portion 160 of the insertion bracket 20 on the left side as shown in FIG. Is entering, and the folded-back portion 172 of the locking piece 167 of the insertion portion 160 presses the engaging portion 56 upward by the elastic restoring force. The contact portion between the folded-back portion 172 of the locking piece 167 of the insertion portion 160 and the engaging portion 56 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 2C.
As shown in FIG. 31, the tip of the engaging portion 56 of the ridge side frame portion 15 of the first-stage solar cell module 2A reaches the space forming portion 166 of the insertion portion 160 of the insertion bracket 20 on the left side. However, there is a gap between the tip of the engaging portion 56 of the ridge side frame portion 15 of the solar cell module 2A in the insertion direction and the space forming portion 166 of the insertion portion 160. That is, an adjustable space 186 toward the eaves building is formed on the projection surface in the insertion direction of the engaging portion 56 of the ridge side frame portion 15 of the solar cell module 2A.
The second-stage solar cell module 2C is mounted on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the tile bar 307 through the fixing hole 44 of the fixing plate portion 40 of the ridge side frame portion 15 of the solar cell module 2C.
The snow stopper 66 and the end face side wall portion 68 of the first skeleton portion 61 of the second-stage solar cell module 2C and the cover portion 76 of the second skeleton portion 62 are exposed from the first-stage tile member 300 and the solar cell module 2A. It constitutes the appearance of the eaves side of the second-stage solar cell module 2C.

Subsequently, as shown in FIG. 32A, the second-stage solar cell module 2 (2D) is slid toward the eaves side, and a part of the ridge-side frame portion 15 of the first-stage solar cell modules 2A and 2B is inserted. Then, it is placed on the tile bar 307 of the foundation roof structure 304. Then, as shown in FIG. 32B, the solar cell module 2D is positioned relatively close to the solar cell module 2C adjacent in the girder direction, and the solar cell is positioned by a fastening element 39 such as a nail. Module 2D is fixed to the foundation roof structure 304.

At this time, the second-stage solar cell modules 2D are arranged across the first-stage solar cell modules 2A and 2B in the girder direction, as can be read from FIGS. 32 (a) and 32 (b). The central portion of the solar cell panel 5 of the second-stage solar cell module 2D in the girder direction is located near the boundary portion of the first-stage solar cell modules 2A and 2B.
In the second-stage solar cell module 2D, the insertion portion 161 of the right insertion bracket 21 is engaged with the engagement portion 56 of the ridge side frame portion 15 of the first-stage solar cell module 2A, and the left side The insertion portion 160 of the insertion fitting 20 is engaged with the engagement portion 56 of the ridge side frame portion 15 of the first-stage solar cell module 2B.

Specifically, in the second-stage solar cell module 2D, the ridge-side frame portions 15 of the first-stage solar cell modules 2A and 2B are provided in the spaces 170 and 170 of the insertion portions 161, 160 of the insertion fittings 21 and 20. The engaging portions 56, 56 of the 15 have entered, and the folded portions 172, 172 of the locking pieces 167, 167 of the insertion portions 161, 160 have the engaging portions 56, 56 directed upward by the elastic restoring force. Pressing. The contact portion between the folded portion 172, 172 of the locking piece 167, 167 of the insertion portion 161, 160 and the engaging portion 56, 56 is the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 2D. Located on top.
Further, the second-stage solar cell module 2D is mounted on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the tile rod 307 through the fixing hole 44 of the fixing plate portion 40 of the ridge side frame portion 15 of the solar cell module 2D.

In the solar cell module 2D, the right frame portion 18 is engaged with the left frame portion 17 of the solar cell module 2C in the girder direction, and is positioned by the right frame portion 17 of the solar cell module 2C.
Specifically, in the left frame portion 17 of the solar cell module 2C, the conductive portion 138 located at the tip of the side wall forming portion 137 is located on the lower surface of the skeleton portion 145 of the right frame portion 18 of the solar cell module 2D. Is in contact with. The tip of the conductive portion 138 of the left frame portion 17 of the solar cell module 2C is inserted into the recess between the convex portions 151 and 151 of the conductive portion 150 of the right frame portion 18 of the solar cell module 2D, and the conductive portion 150 It is engaged with the convex portion 151 of the. In the left frame portion 17 of the solar cell module 2C, the closing portion 141 is in contact with or close to the closing portion 146 of the right frame portion 18 of the solar cell module 2D, and the upper part of the flow path 135 is covered by the closing portion 146. ing.
Further, in the solar cell panel 5 of the solar cell module 2D, the right side 13 is close to the left side 12 of the solar cell panel 5 of the solar cell module 2C, and the right end surface is the left end surface of the solar cell panel 5 of the solar cell module 2C. Face to face.

When the laying of the second-stage solar cell module 2 on the foundation roof structure 304 is completed, the tile members 300 and the solar cell module 2 of the third and subsequent stages are laid to complete the roof structure 1.

By the way, in the roof structure using the roof tile integrated solar cell module, many solar cell modules are arranged side by side in the basic roof structure 304, but due to initial defects, falling objects, etc., only some solar cell panels are installed. It may be damaged.

Therefore, the solar cell modules 2a and 2b used in the roof structure 1 of the present embodiment can be replaced with the solar cell panel 5 in a state of being attached to the foundation roof structure 304.
That is, in the solar cell module 2, the eaves side frame portion 16 can be divided into a plurality of parts as described above, and when the used solar cell panel 5 is replaced with a new solar cell panel 5, FIG. 33 As shown in FIG. 11, the temporary fastening element 70 is removed from the insertion hole 71 and the fastening receiving portion 82, and as shown in FIG. 11, the second divided piece 23 including the second skeleton portion 62 and the second gasket portion 101 to the first skeleton portion 61 and The first divided piece 22 including the first gasket portion 100 is removed. Then, the end face of the used solar cell panel 5 on the eaves side is exposed to the outside, and the used solar cell panel 5 is opened toward the eaves building and can be moved to the eaves side. Pull out the battery panel 5 from the ridge side frame portion 15.
Then, a new solar cell panel 5 is inserted into the holding recess 30 of the ridge side frame portion 15, and the first division piece 22 is attached to the second division piece 23 by the temporary fastening element 70. By doing so, in the new solar cell panel 5, the ridge side end portion is held in the holding recess 30 of the ridge side frame portion 15, and the eaves side end portion is held in the holding recess 60 of the eaves side frame portion 16 to form the foundation. It is fixed to the roof structure 304.

Further, in the second solar cell module 2b as well as the first solar cell module 2a, the eaves side frame portion 200 can be divided into a plurality of parts, and the used solar cell panel 5 is replaced with a new solar cell panel 5. When doing so, the temporary fastening element 215 is removed from the insertion hole 212 and the fastening receiving portion 220 in the same manner as described above, and as shown in FIG. 20, from the second divided piece 208 composed of the second skeleton portion 203 and the second gasket portion 101. The first divided piece 207 including the first skeleton portion 202 and the first gasket portion 100 is removed. Then, the end surface of the used solar cell panel 5 on the eaves side is opened toward the eaves, so that the used solar cell panel 5 is pulled out from the ridge side frame portion 15 on the eaves side.
Then, a new solar cell panel 5 is inserted into the holding recess 30 of the ridge side frame portion 15, and the first division piece 207 is attached to the second division piece 208 by the temporary fastening element 215. By doing so, in the new solar cell panel 5, the ridge side end portion is held in the holding recess 30 of the ridge side frame portion 15, and the eaves side end portion is held in the holding recess 201 of the eaves side frame portion 200 to form the foundation. It is fixed to the roof structure 304.

As described above, since the solar cell modules 2a and 2b of the present embodiment can be replaced with the solar cell panel 5 in a state of being attached to the foundation roof structure 304, maintenance and the like are easy. Further, in the solar cell modules 2a and 2b, since the soft gasket portion 46 is provided on the outside of the hard gasket portion 45 in the insertion direction of the new solar cell panel 5, the new solar cell panel 5 is placed in the ridge side frame portion. When inserting into the holding recess 30 of 15, it is possible to prevent damage due to stress at the time of insertion.

According to the solar cell module 2 of the first embodiment, the ridge side end portion of the solar cell panel 5 is inserted into the ridge side frame portion 15, and the ridge side end portion of the solar cell panel 5 is sandwiched by the hard gasket portion 45. There is. Further, since the ridge side frame portion 15 is provided with the soft gasket portion 46 on the outside of the hard gasket portion 45 in the insertion direction of the solar cell panel 5, the soft gasket portion 46 is elastically deformed and the sun is formed. It is possible to absorb individual differences in the dimensions of the battery panel 5.

By the way, the solar cell module 2 may be attached to the existing foundation roof structure 304, and the gradient differs depending on the foundation roof structure 304. Therefore, the conventional solar cell module requires a frame that matches the gradient of the foundation roof structure 304, which causes a problem that the manufacturing cost increases.

Therefore, in the solar cell module 2 of the present embodiment, the pockets of the insertion fittings 20 and 21 are deeply formed, and the insertion length S (insertion length) of the insertion fittings 20 and 21 into the engaging portion 56. By adjusting, it is possible to cope with changes in the slope of the foundation roof structure 304. That is, it can be installed on a plurality of types of roof bases 301 having different slopes.
Specifically, as shown in FIG. 34A, when the inclination angle θ of the foundation roof structure 304 with respect to the horizontal plane is small, the insertion length of the insertion fitting 21 (insertion fitting 20) into the engaging portion 56. As shown in FIG. 35A, the overlap width T between the solar cell module 2C on the eaves side and the solar cell module 2E on the ridge side is increased by lengthening the S, and the sun when the roof structure 1 is viewed from the vertical direction. Adjust the length D of the exposed portion of the battery panel 5 in the eaves direction. On the other hand, as shown in FIG. 34B, when the inclination angle θ of the foundation roof structure 304 is large, the insertion length S of the insertion fitting 21 (insertion fitting 20) into the engaging portion 56 is shortened. As shown in FIG. 35B, the overlapping width T of the solar cell module 2C on the eaves side and the solar cell module 2E on the ridge side is reduced, and the solar cell panel 5 is exposed when the roof structure 1 is viewed from the vertical direction. Adjust the length D of the part in the eaves direction.

As described above, according to the solar cell module 2 of the present embodiment, the length of the exposed portion of the solar cell panel 5 in the eaves direction when the roof structure 1 is viewed from the vertical direction regardless of the slope of the foundation roof structure 304. Since D can be unified, the roof structure has a high degree of design.
Further, since the same holding member 6 can be installed on the roof base 301 regardless of the slope of the foundation roof structure 304, the solar cell modules 2 constituting the roof structure 1 can be unified, and the manufacturing cost can be reduced.
Further, since the solar cell modules 2 constituting the roof structure 1 can be unified, there is no possibility that the solar cell modules that do not match the gradient of the foundation roof structure 304 will be delivered to the site as in the conventional case.

Further, according to the roof structure 1 of the present embodiment, the pockets of the insertion fittings 20 and 21 of the solar cell module 2 are deeply formed, and the second plate portion 332 of the intermediate mounting fitting 303 attached to the tile member 300 is formed. By adjusting the insertion length (insertion length) of, it is possible to cope with changes in the slope of the foundation roof structure 304. That is, since the tile member 300 and the intermediate mounting bracket 303 can be installed on a plurality of types of roof bases 301 having different slopes, the intermediate mounting brackets that do not match the slope of the foundation roof structure 304 as in the conventional case can be installed. There is no risk of delivery to the site.

According to the roof structure 1 of the first embodiment, in the solar cell module 2A on the eaves side, as shown in FIG. 31, the engaging portion 56 of the conductive member 26 having conductivity makes the solar cell module 2C on the ridge side conductive. The holding member 6 is in contact with the folded-back portion 172 of the insertion fitting 21 to be held, and is electrically connected to the holding member 6 of the solar cell module 2C on the ridge side. That is, since the electric charge charged by the solar cell module 2A can be released to the solar cell module 2C without using a separate wiring member, the workability is better than before and the installation work can be simplified. Furthermore, it is possible to reduce the number of parts such as wiring members.
Further, in the solar cell module 2A, as shown in FIG. 27B, the conductive portion 138 of the left frame portion 17 is in contact with the conductive portion 150 of the right frame portion 18 of the solar cell module 2B adjacent in the girder direction and is held. The member 6 is electrically connected to the holding member 6 of the solar cell module 2B adjacent in the girder direction. That is, since the electric charge charged by the solar cell module 2A can be released to the solar cell module 2B without using a separate wiring member, the workability is better than before and the installation work can be simplified. Further cost reduction is possible.
In this way, if the structure (grounding structure) for grounding between the solar cell modules 2 is used, the solar cell panel 5 of the solar cell module 2 of the roof structure 1 is discharged and the holding member 6 is charged. Even so, the electric charge can be released to each solar cell module 2. Therefore, by grounding the holding member 6 of any of the solar cell modules 2 constituting the roof structure 1 to the ground, it is possible to ground the holding member 6 of each solar cell module 2 through the holding member 6. Therefore, the roof structure is highly safe.

According to the solar cell module 2 of the first embodiment, the first skeleton portion 61 is provided with the first concave groove 69, the first gasket portion 100 is provided with the first convex groove portion 107, and the first concave groove 69 is provided. And the first ridge portion 107 are fitted and integrated to form the first division piece 22, so that when the eaves side frame portion 16 is assembled, the first gasket portion 100 is disengaged from the first skeleton portion 61. It is difficult and the eaves side frame portion 16 is easy to assemble.
Similarly, according to the solar cell module 2 of the first embodiment, the second skeleton portion 62 is provided with the second concave groove 79, and the second gasket portion 101 is provided with the second convex portion 117. Since the concave groove 79 and the second convex portion 117 are fitted and integrated to form the second divided piece 23, the second gasket portion 101 is the second skeleton portion when the eaves side frame portion 16 is assembled. It is hard to come off from 62, and the eaves side frame portion 16 can be easily assembled.

Further, according to the solar cell module 2 of the first embodiment, the front side buffer portion 102 of the first gasket portion 100 is provided with the first convex portion 107 extending in the girder direction, and the first skeleton portion 61 Since it fits with the first concave groove 69 extending in the girder direction of the front side wall portion 67, rainwater transmitted in the direction of the eaves on the surface of the solar cell panel 5 on the light receiving surface side is the first convex portion 107 and the first concave groove. It is blocked by 69, and it is difficult to enter the gap between the eaves side end surface of the solar cell panel 5 and the end surface side buffer portion 103 of the first gasket portion 100. Therefore, it is possible to prevent the solar cell panel 5 from being damaged due to the intrusion of rainwater from the eaves side end surface of the solar cell panel 5.

According to the roof structure 1 of the first embodiment, since the eaves side frame portion 16 of the solar cell module 2a is provided with the snow stopper 66, as shown in FIG. 36, the snow stopper 66 roofs the snow even in a cold region. The inclination of the roof can prevent it from falling to the ground.
Further, since the snow stopper 66 constitutes a part of the divided piece 22, the snow stopper 66 can be installed at the same time as the eaves side frame portion 16 is assembled, and the work of installing the snow stopper on site is unnecessary. Will be. Therefore, the workability is better than the conventional one, and the workability can be simplified.

According to the roof structure 1 of the first embodiment, as shown in FIG. 37, a notch portion 64 as a water passage is formed in the center of the solar cell module 2, and the notch portion is also formed at the end portion of the solar cell module 2. 58 is combined with the notch 59 of another solar cell module 2 adjacent in the girder direction to form one water passage 97. Therefore, even when the snow melts and becomes water during the daytime or the like, water can flow along the slope from the notches 58, 59, 64 which are the water passages.

According to the solar cell module 2 of the first embodiment, the insertion fittings 20 and 21 and the eaves side frame portion 16 are connected by the reinforcing bars 162 and 163, and the insertion fitting 20 and the left side frame portion 17 are connected and inserted. Since the metal fitting 21 and the right frame portion 18 are connected, the holding member 6 is unlikely to be deformed in the vertical and horizontal directions. Therefore, it is possible to prevent the holding member 6 from being deformed when a load is applied to the snow stopper 66 due to snow accumulation.

According to the solar cell module 2 of the first embodiment, in the eaves side frame portion 16, the lengths of the first convex portion 107 and the first concave groove 69 that are fitted to each other are the lengths of the eaves side sides of the solar cell panel 5. It is more than 1/3 of the 11th. Therefore, rainwater is less likely to reach the eaves-side end surface of the solar cell panel 5, and failure or the like due to infiltration of rainwater from the eaves-side end surface of the solar cell panel 5 is less likely to occur.
Similarly, in the eaves side frame portion 16, since the lengths of the second convex portion 117 and the second concave groove 79 that are fitted to each other are 1/3 or more of the eaves side side 11 of the solar cell panel 5, the solar cell Rainwater is less likely to reach the eaves-side end surface of the panel 5, and failures due to infiltration of rainwater from the eaves-side end surface of the solar cell panel 5 are less likely to occur.

Subsequently, the roof structure 400 of the second embodiment will be described. In addition, about the same structure as the roof structure 1 of the 1st Embodiment, the same code numbering is given and the description is omitted.

As shown in FIG. 38, the roof structure 400 of the second embodiment of the present invention has the tile member 300 and the solar cell module 402 with respect to the roof base 301 of the foundation roof structure 304, similarly to the roof structure 1 of the first embodiment. It is laid, and the structure of the solar cell module 402 is different from that of the first embodiment.

The solar cell module 402 of the second embodiment includes a solar cell panel 5 and a holding member 403 as shown in FIG. 39.
Further, the solar cell module 402 of the second embodiment employs two types of holding members 403a and 403b as in the solar cell module 2 of the first embodiment, as can be read from FIGS. 41 and 50. There is a first solar cell module 402a having a snow blocking function and a second solar cell module 402b having no snow blocking function.

The first solar cell module 402a projects from the overlapping portion 411 that overlaps the solar cell panel 5 and the four sides 10 to 13 of the solar cell panel 5 when the light receiving surface of the solar cell panel 5 is viewed in a plan view as shown in FIG. The overhanging portions 412a, 412b, and 412c are provided.
The superimposing portion 411 is a portion that overlaps with the solar cell panel 5 in the thickness direction, and is a portion that is hidden by the solar cell panel 5 when the light receiving surface 7 is viewed in a plan view.
The ridge-side overhanging portion 412a (eave-building-side overhanging portion) is a portion of the solar cell panel 5 overhanging from the ridge-side side 10 (building-side side).
The eaves-side overhanging portion 412b (eave-building side overhanging portion) is a portion of the solar cell panel 5 overhanging from the eaves-end side 11 (the eaves-side side).
The girder side overhanging portion 412c is a portion overhanging from the left side 12 of the solar cell panel 5.

As can be read from FIG. 41, the holding member 403a of the first solar cell module 402a is composed of a frame portion 405 to 408 extending along four sides 10 to 13 of the solar cell panel 5 and a reinforcing bar 410.

As shown in FIG. 43, the ridge side frame portion 405 includes a holding main body portion 420 and a conductive member 421 (second conductive portion).
As shown in FIG. 42, the holding main body portion 420 is a portion provided with a holding recess 422 into which the eaves side end portion of the solar cell panel 5 can be inserted, and includes a skeleton portion 423 and a ridge side gasket portion 28.
The skeleton portion 423 is an upper frame that protects the ridge-side end portion of the solar cell panel 5, and is formed by coating the surface of a core member that is a conductor with a protective layer having a lower electrical conductivity than that of the conductor. Specifically, the skeleton portion 423 is formed by performing anodizing treatment on the surface of an aluminum drawing material.

The skeleton portion 423 includes a recess forming portion 425, a fixing portion 426, and a connecting wall portion 427, as can be read from FIGS. 42 and 44.
As shown in FIG. 42, the recess forming portion 425 is a portion that forms a holding recess 422 that can be fitted with the ridge-side end of the solar cell panel 5.
The holding recess 422 is a concave portion extending along the ridge side 10 of the solar cell panel 5, and is a portion for holding the solar cell panel 5.

As shown in FIG. 42, the recess forming portion 425 is a portion having a substantially “U” shape in cross-sectional view, and the holding recess 422 is formed by the front side wall portion 430, the connecting wall portion 431, and the back surface side wall portion 432. ing.
The front side wall portion 430 is a wall portion that covers the front side of the solar cell panel 5.
The connecting wall portion 431 is a wall portion that connects the ridge-side end of the front side wall 430 and the ridge-side end of the back side wall 432. The connection wall portion 431 is erected in a direction orthogonal to the light receiving surface 7 of the solar cell panel 5 from the ridge side end portion of the back side wall portion 432, and the front side wall portion 430 is erected at the upper end portion in the erection direction. The ridge side end is connected.
The back side wall portion 432 is a wall portion that covers the back side of the solar cell panel 5.
The back side wall portion 432 extends from the connecting wall portion 431 in the same direction as the front side wall portion 430, and is arranged so as to face the front side wall portion 430 at a predetermined interval in the thickness direction.

As can be read from FIG. 42, the fixed portion 426 is a portion that continuously extends from the back side wall portion 432 and projects from the connecting wall portion 431 toward the ridge side.
The fixing portion 426 includes a plurality of fixing holes 436 and a plurality of mounting holes 437.
The fixing hole 436 is a through hole for fixing the roof tile base 301 to the roof tile rod 307 by the fastening element 39, and the fastening element 39 can be inserted therethrough.
The fixing holes 436 have a depth in the member thickness direction from the top surface, and are arranged side by side at predetermined intervals in the lateral direction.

The mounting hole 437 is a bottomed hole or a through hole for mounting the conductive member 421 by the fastening element 43, and can be engaged with the fastening element 43.
The mounting holes 437 have a depth in the member thickness direction from the top surface, and are arranged side by side with a predetermined interval in the lateral direction X.
The mounting hole 437 is provided near the ridge-side end of the fixing portion 426, and is located closer to the ridge than the fixing hole 436.

The connecting wall portion 427 is a wall portion connected to each of the left frame portion 407, the reinforcing bar 410, and the right frame portion 408 shown in FIG. 41.
As shown in FIG. 43, the connecting wall portion 427 is a plate-shaped portion that is bent downward from the eaves-end side end portion of the back side wall portion 432. The connecting wall portion 427 extends in the lateral direction, and is provided with a fixing hole 428 for attaching the reinforcing bar 410 by the fastening element 504 in the intermediate portion thereof.
As can be read from FIG. 41, the fixing hole 428 is a bottomed hole or a through hole for fixing the reinforcing bar 410 by the fastening element 504, and can be engaged with the fastening element 504.
The fastening element 504 is a known fastening element, and in this embodiment, it is a screw.

The conductive member 421 is a member formed of a conductor and forming a conductive path for releasing to the ground. As can be read from FIGS. 43 and 44, the conductive member 421 includes a mounting plate portion 440, a standing wall portion 441, and an engaging plate portion 442 (second engaging portion).

As shown in FIG. 43, the mounting plate portion 440 is a plate-shaped portion to be attached to the fixing portion 426, and is a plate portion extending from the lower end of the standing wall portion 441 toward the ridge side.
As can be read from FIG. 42, the mounting plate portion 440 includes a plurality of fixing holes 445 and a plurality of mounting holes 446.
The fixing hole 445 is a hole paired with the fixing hole 436 of the fixing portion 426 as shown in FIG. 42B, and is a hole forming a communication hole with the fixing hole 436 when assembled. That is, the fixing hole 445 is a through hole for fixing the roof tile base 301 to the roof tile rod 307 by the fastening element 39, and the fastening element 39 can be inserted therethrough.
Further, the fixing holes 445 are arranged side by side at a predetermined interval in the longitudinal direction (horizontal direction X) of the mounting plate portion 440.

The mounting hole 446 is a hole paired with the mounting hole 437 of the fixing portion 426 as shown in FIG. 42A, and is a hole forming a communication hole with the mounting hole 437. That is, the mounting hole 446 is a through hole for fixing to the fixing portion 426 by the fastening element 43, and the fastening element 43 can be inserted therethrough.
Further, the mounting holes 446 are arranged side by side with a predetermined interval in the longitudinal direction (horizontal direction) of the mounting plate portion 440.
As shown in FIG. 44, the mounting hole 446 is provided near the ridge-side end of the mounting plate portion 440, and is located closer to the ridge than the fixing hole 445.

As shown in FIG. 44, the standing wall portion 441 is a wall portion that is bent upward from the eaves side end portion of the mounting plate portion 440, and is bent downward from the ridge side end portion of the engaging plate portion 442. It is also a wall part. That is, the standing wall portion 441 is a wall portion that forms a step between the mounting plate portion 440 and the engaging plate portion 442, and is a wall portion that rises in the vertical direction.

The engaging plate portion 442 is a blow-up prevention portion that engages with the eaves side frame portion 406 of the other solar cell module 402 to prevent the other solar cell module 402 from blowing up, and the eaves side frame of the other solar cell module 402. This is a portion that forms a conductive path with the portion 406.
As shown in FIG. 44, the engaging plate portion 442 is a plate portion extending from the upper end portion of the standing wall portion 441 to the eaves side, and is continuously connected to the mounting plate portion 440 via the standing wall portion 441 in a stepped manner.

As can be read from FIGS. 43 and 44, the engaging plate portion 442 includes a main body plate portion 450, a left side connecting portion 451 (fourth conductive portion), and a right side connecting portion 452 (third conductive portion).
The main body plate portion 450 is a horizontally long rectangular plate portion, and the eaves side end portion is folded back to form a wall thickness portion 459 that is thicker than other portions.

The left side connection portion 451 is provided at one end (left end) of the main body plate portion 450 in the lateral direction X, and is a portion that can be connected to the right side connection portion 452 of the other solar cell module 402.
The left side connection portion 451 includes a connection piece 453 that is continuous with the main body plate portion 450 in a stepwise manner and is cantilevered with respect to the main body plate portion 450.
The connection piece 453 projects outward from the main body plate portion 450 in the lateral direction X when viewed in a plan view, and includes a notch portion 455 extending from the end portion in the projecting direction toward the base end side.
As shown in FIG. 55, the notch portion 455 is a notch into which a part of the temporary fastening element 456 can be inserted, and is an arc-shaped notch along the insertion portion of the temporary fastening element 456.

The right side connection portion 452 is provided at the other end portion (right end portion) of the main body plate portion 450 in the lateral direction X, and is a portion that can be connected to the left side connection portion 451 of the other solar cell module 402.
The right side connection portion 452 includes a connection hole 454.
The connection hole 454 is a through hole or a bottomed hole having a depth in the member thickness direction from the top surface of the main body plate portion 450, and is an engagement hole that can be engaged with a part of the temporary fastening element 456.
The temporary fastening element 456 is a known temporary fastening element that can be fastened and unfastened without breaking.

Here, the positional relationship of each component of the ridge side frame portion 405 will be described.

As can be read from FIG. 43, the conductive member 421 is integrated with the holding main body portion 420 by the fastening element 43. That is, as shown in FIG. 42A, the mounting plate portion 440 of the conductive member 421 overlaps the fixing portion 426 of the holding main body portion 420 in the thickness direction and is in surface contact with the mounting plate portion 440, and the mounting hole 446 of the mounting plate portion 440 , A communication hole is formed with the mounting hole 437. Then, in the ridge side frame portion 405, a fastening element 43 having conductivity is inserted into the communication hole.
Further, the fixing hole 445 of the mounting plate portion 440 forms a communication hole with the fixing hole 436 as shown in FIG. 42 (b), and the fastening element 39 can be inserted into the communication hole.
As can be read from FIG. 42, the engaging plate portion 442 of the conductive member 421 is located above the front side wall portion 430 of the holding main body portion 420 and is inserted between the engaging plate portion 442 and the front side wall portion 430 of the holding main body portion 420. It forms a space 435.
The insertion space 435 is a space in which the ridge side is closed by the vertical wall portion 441 and the eaves side is open. That is, as shown in FIG. 58, the insertion space 435 is open in the same direction as the holding recess 422, and the engaging portion 472 of the eaves side frame portion 406 can be inserted from the eaves side.

The ridge-side gasket portion 28 is attached along the inner wall of the holding recess 422 of the holding main body portion 420. Specifically, the front side cushioning portion 48 of the hard gasket portion 45 is in surface contact with the front side wall portion 430 of the skeleton portion 423, and the back surface side cushioning portion 50 is the back side side wall portion 432 of the skeleton portion 423. Face-to-face contact.
The soft gasket portion 46 is located between the end face side cushioning portion 49 of the hard gasket portion 45 and the connecting wall portion 431 of the skeleton portion 423, and is in surface contact with the wall portions 430 and 432 of the skeleton portion 423. ..

Next, the eaves side frame portion 406 will be described.

As shown in FIG. 47, the eaves side frame portion 406 is a portion that holds the eaves side end portion of the solar cell panel 5. The eaves side frame portion 406 is a long body extending along the eaves side side 11 of the solar cell panel 5, and includes a holding recess 60 into which the eaves side end portion of the solar cell panel 5 can be inserted.
Further, the eaves side frame portion 406 can be divided into a plurality of divided pieces 22 and 458 as shown in FIG. 46, and the first skeleton portion 61, the second skeleton portion 462, the eaves side gasket portion 63, and the conductivity. It includes members 436 and 464 (first conductive portion).

The second skeleton portion 462 is formed by coating the surface of a core member serving as a conductor with a protective layer having a lower electrical conductivity than that of the conductor, and as shown in FIG. 47, the second recess forming portion 75 and a cover. A portion 467 and a fixing portion 468 are provided.

The cover portion 467 is a portion that constitutes the appearance of the solar cell module 402a together with the snow stopper portion 66 and the end face side wall portion 68 of the first skeleton portion 61 when the roof structure 1 is assembled. That is, the cover portion 467 is a portion that functions as a front cover together with the snow stopper portion 66 and the end face side wall portion 68.

As shown in FIG. 47, the cover portion 467 includes a connecting portion 471 and an upright wall portion 87 that stands upright downward from the connecting portion 471.

The connecting portion 471 is a portion that connects to the end surface side wall portion 68 of the first skeleton portion 61, and is a portion that projects from the eaves side end portion of the back surface side wall portion 78 toward the eaves side.
As shown in FIG. 46, the connecting portion 471 includes a fastening receiving portion 82 that can be fastened to the temporary fastening element 70 in a direction orthogonal to the overhanging direction.

As shown in FIG. 47, the fixing portion 468 includes a spacing maintaining wall portion 473, a mounting wall portion 475, and an engaging portion 472 (first engaging portion).

The space maintaining wall portion 473 is a portion that maintains a distance between the second recess forming portion 75 and the engaging portion 472 in the vertical direction Y.
The space-maintaining wall portion 473 is a plate-shaped wall portion, and is continuously connected to the back side wall portion 78 in a stepped manner via the wall portion 95.
A rib 92 extending in the lateral direction is formed on the lower surface of the space maintaining wall portion 473, and the rib 92 reinforces the rigidity in the lateral direction X.
Further, the interval maintenance wall portion 473 is provided with a fixing hole 474 that can be fastened to the fastening element 505 in the intermediate portion in the lateral direction X as shown in FIG. 41.
The fixing hole 474 is a bottomed hole or a through hole for fixing the reinforcing bar 410 by the fastening element 505, and can be engaged with the fastening element 505.

The mounting wall portion 475 is a wall portion for mounting the conductive members 464 and 464.
The mounting wall portion 475 is a wall portion that connects the spacing wall portion 473 and the engaging wall portion 476, and the spacing maintaining wall portion 473 and the engaging wall portion 476 are continuous in a stepped manner via the mounting wall portion 475. ing.
The mounting wall portion 475 is provided with mounting holes 477,478 in the vicinity of both ends in the lateral direction X.
The mounting holes 477,478 are bottomed holes or through holes to which the conductive members 464 and 464 can be mounted by the conductive fastening elements 490 and 491, and can be engaged with the fastening elements 490 and 491.

The engaging portion 472 is a portion that can be engaged with each of the eaves tip metal fitting 302 and the ridge side frame portion 405 of the other solar cell module 402. As shown in FIG. 47, the engaging portion 472 is a portion having a "U" -shaped cross section, and includes an upper plate portion 480, a connecting plate portion 481, and a lower plate portion 482, and the upper plate portion 480. The insertion space 483 is formed by the connecting plate portion 481 and the lower plate portion 482.
The upper plate portion 480 is a plate-shaped portion that is connected to the lower end portion of the mounting wall portion 475 and is stepwise continuous with the spacing maintaining wall portion 473 via the mounting wall portion 475.
The connection plate portion 481 is a portion that connects the ridge-side end of the upper plate portion 480 and the ridge-side end of the lower plate portion 482, and the distance between the upper plate portion 480 and the lower plate portion 482 is set to a predetermined interval. It is a part to be maintained. As shown in FIG. 47, the eaves-side surface of the connection plate portion 481 forms the same plane as the eaves-side surface of the mounting wall portion 475 and is flush with each other.
The lower plate portion 482 is a plate-shaped portion that is located below the upper plate portion 480 and faces the upper plate portion 480 and the insertion space 483 in the vertical direction.

The conductive members 464 and 464 are members formed of a conductor and forming a conductive path for releasing to the ground.
The conductive members 464 and 464 are members formed by bending a single thin metal plate, and include a mounting plate portion 485 and an elastic plate portion 486.
The mounting plate portion 485 is a plate portion for mounting on the second skeleton portion 462, and mounting holes 487 and 488 are provided in the vicinity of both end portions in the lateral direction X.
As can be read from FIG. 45, the mounting holes 487 and 488 are through holes that can be mounted to the second skeleton portion 462 by the conductive fastening elements 490 and 491, and the fastening elements 490 and 491 can be inserted through the mounting holes 487 and 488. It has become.
The fastening elements 490 and 491 are conductive fastening elements, and in this embodiment, they are screws.

The elastic plate portion 486 is a portion that can be elastically deformed, and is composed of a connecting plate portion 495 and a folded portion 496.
The connection plate portion 495 is a portion bent from the lower end portion of the mounting plate portion 485 toward the ridge side, and is a portion that supports the folded portion 496 in a cantilever shape.
The folded-back portion 496 is a portion that is folded back from the ridge-side end portion of the connecting plate portion 495, and the folded-back portion is further bent in a mountain shape, and includes a pressing portion 497.

Here, the positional relationship of each component of the eaves side frame portion 406 will be described.

As can be read from FIG. 46, the first skeleton portion 61 is integrated with the second skeleton portion 462 by the temporary fastening element 70, and can be attached to and detached from the second skeleton portion 462 by removing the temporary fastening element 70. It has become. That is, the snow stopper 66 and the end surface side wall portion 68 of the first skeleton portion 61 overlap with the connection portion 471 of the second skeleton portion 462 in the thickness direction, and the insertion hole 71 of the snow stopper 66 is as shown in FIG. 47. A communication hole is formed with the fastening receiving portion 82 of the connecting portion 471. Then, in the eaves side frame portion 406, a temporary fastening element 70 is inserted into the communication hole.
With reference to the solar cell panel 5, the outer surface of the connecting portion 471 forms the same plane as the outer surface of the snow stopper 66 and the end surface side wall portion 68, and is flush with each other.

The first recess forming portion 65 of the first skeleton portion 61 and the second recess forming portion 75 of the second skeleton portion 462 are connected to form a holding recess 60. The eaves-side gasket portion 63 is attached along the inner wall of the holding recess 60 formed by the skeleton portions 61 and 462.

As shown in FIG. 46, the first gasket portion 100 is integrated with the first skeleton portion 61 to form the first partition piece 22, and the second gasket portion 101 is integrated with the second skeleton portion 462. The second divided piece 458 is formed.

As can be read from FIGS. 45 and 47, the conductive members 464 and 464 are attached with the mounting plate portions 485 and 485 in surface contact with the mounting wall portion 475 by the fastening elements 490 and 491, and the connecting plate portion 495 is attached. It is placed on the upper plate portion 480. Further, in the conductive members 464 and 464, the folded-back portion 496 is folded back from the upper surface side of the upper plate portion 480 to the lower surface side so as to cover the end surface thereof, and the pressing portion 497 is located in the insertion space 483. Further, a space is formed between the pressing portion 497 and the upper plate portion 480, and there is a play for the pressing portion 497 to move to the upper plate portion 480 side.

The left frame portion 407 is a member substantially similar to the left frame portion 17 of the first embodiment, and as shown in FIG. 48, the bottom surface of the main body portion 140 of the left frame portion 17 is cut out. Further, the left frame portion 407 is rounded because the conductive portion 138 is not provided at the tip of the side wall forming portion 137 of the flow path forming portion 131.

The right frame portion 408 is a member substantially similar to the right frame portion 18 of the first embodiment. In the right frame portion 408, as shown in FIG. 49, the bottom surface of the skeleton portion 145 of the right frame portion 18 is cut out, and the conductive portion 150 is not formed.

The reinforcing bar 410 is a bar that suppresses distortion of the holding member 6 and bending of the solar cell panel 5, and as shown in FIG. 41, the intermediate portion of the ridge side frame portion 405 in the lateral direction X and the lateral portion of the eaves side frame portion 406. It is a member connecting the intermediate portion of the direction X.
The reinforcing bar 410 includes a long crosspiece body 500 and a ridge-side connecting portion 503 that can be connected to the ridge-side frame portion 405 at one end in the longitudinal direction thereof, and an eaves tip at the other end in the longitudinal direction thereof. The eaves side connection portion 502 that can be connected to the side frame portion 406 is provided.

The crosspiece body 500 is a long plate-shaped portion extending in the vertical direction.
The ridge-side connection portion 503 is a vertical wall portion that stands upright with respect to the crosspiece main body 500, and has a fixing hole 506.
The fixing hole 506 is a through hole for fixing to the ridge side frame portion 405 by the fastening element 504, and the fastening element 504 can be inserted through the fixing hole 506.
The eaves side connection portion 502 includes a fixing hole 507 penetrating in the thickness direction of the crosspiece main body 500.
The fixing hole 507 is a through hole for fixing to the eaves side frame portion 406 by the fastening element 505, and the fastening element 505 can be inserted through the fixing hole 507.

Subsequently, the positional relationship of each component of the first solar cell module 402a will be described.

The solar cell panel 5 is held by the holding member 403a, and the light receiving surface 7 is exposed from the holding member 403. Specifically, the ridge-side end of the solar cell panel 5 is inserted into the holding recess 422 of the ridge-side frame 405, and the eaves-side end of the solar cell panel 5 is the holding recess of the eaves-side frame 406. It is inserted in 60.
The vicinity of the left end portion of the solar cell panel 5 is placed on the main body 140 of the left frame portion 407, and the vicinity of the right end portion of the solar cell panel 5 is closed with the skeleton portion 145 of the right frame portion 408. It is placed on the part 146.

Further, in the ridge side frame portion 405, the holding main body portion 420 straddles the overlapping portion 411 and the ridge side overhanging portion 412a, and most of the conductive members 421 are located at the ridge side overhanging portion 412a.
The eaves side frame portion 406 straddles the superimposing portion 411 and the eaves side overhanging portion 412b, and the engaging portion 472 is located at the superimposing portion 411. Further, the conductive members 436 and 464 are located at the overlapping portion 411. That is, the pressing portion 497 is located at the superimposing portion 411.
The reinforcing bar 410 is located at the overlapping portion 411.

Subsequently, the second solar cell module 402b having no snow blocking function will be described. The same configuration as that of the first solar cell module 402a with a snow stopper function will be assigned the same number and the description thereof will be omitted.

As shown in FIGS. 50 and 51, the shape of the eaves side frame portion 550 of the holding member 403b of the second solar cell module 402b is the same as the shape of the eaves side frame portion 406 of the holding member 403a of the first solar cell module 402a. different. That is, the eaves-side frame portion 550 of the holding member 403b does not have the snow stopper 66 like the eaves-side frame portion 406 of the first solar cell module 402a.
The eaves side frame portion 550 is a portion that holds the eaves side end portion of the solar cell panel 5 when the roof structure 1 is assembled, like the eaves side frame portion 406 of the first solar cell module 402a.
The eaves side frame portion 550 is a long body extending along the eaves side side 11 of the solar cell panel 5, and includes a holding recess 201 into which the eaves side end portion of the solar cell panel 5 can be inserted.
Further, the eaves side frame portion 550 includes a first skeleton portion 202, a second skeleton portion 553, and an eaves side gasket portion 63, as shown in FIG.
The second skeleton portion 553 includes a second recess forming portion 216, a connecting portion 217, and a fixing portion 468.

Here, the positional relationship of each component of the eaves side frame portion 550 will be described.

As can be read from FIG. 50, the first skeleton portion 202 is integrated with the second skeleton portion 553 by the temporary fastening element 215, and can be attached to and detached from the second skeleton portion 553 by removing the temporary fastening element 215. It has become. That is, as shown in FIG. 51, the end face side wall portion 211 of the first skeleton portion 202 overlaps with the upright wall portion 218 of the second skeleton portion 553 in the thickness direction, and the insertion hole 212 of the first skeleton portion 202 is the first. 2 A communication hole is formed with the fastening receiving portion 220 of the skeleton portion 553. Then, the eaves side frame portion 550 has a temporary fastening element 215 inserted into the communication hole.
Further, the first gasket portion 100 is integrally formed with the first skeleton portion 202 to form the first division piece 555, and the second gasket portion 101 is integrally with the second skeleton portion 553 to form the second division. It forms a piece 556.

Subsequently, the positional relationship of each component of the second solar cell module 402b will be described.

The solar cell panel 5 is held by the holding member 403b, and the light receiving surface 7 is exposed from the holding member 403b. Specifically, the ridge-side end of the solar cell panel 5 is inserted into the holding recess 422 of the ridge-side frame 405, and the eaves-side end of the solar panel 5 is the holding recess of the eaves-side frame 550. It is inserted in 201.

Subsequently, the procedure for assembling the roof structure 400 according to the second embodiment of the present invention will be described.

Similar to the procedure for assembling the roof structure 1 of the first embodiment, a plurality of eaves metal fittings 302 are attached to the tile rail 306 of the foundation roof structure 304 in advance, and the tile member 300 and the first-stage solar cell module 402 are attached to the foundation roof structure 304. I will lay it.

First, the roof tile member 300 is placed on the roof tile rod 307, and the fastening element 335 such as a nail is placed with the intermediate mounting bracket 303 attached to the ridge side end of the roof tile member 300.

At this time, unlike the roof structure 1 of the first embodiment, the intermediate mounting bracket 303 has the first plate portion 330 mounted on the tile member 300, and the second plate portion 332 has the second plate portion 332 with respect to the first plate portion 330. Install so that it is on the eaves side. That is, a space is formed between the tile member 300 and the second plate portion 332.

Subsequently, as shown in FIG. 52 (a), the first-stage solar cell module 402 (402A) is hooked on the eaves tip metal fitting 302, moved to the ridge side, and placed on the tile bar 307 of the foundation roof structure 304. As in 52 (b), the solar cell module 402A is positioned relatively close to the pre-installed roof tile member 300. Then, the solar cell module 2A is fixed to the foundation roof structure 304 by a fastening element 39 such as a nail.

At this time, the left end of the tile member 300 is located below the closing portion 146 of the right frame portion 408 of the solar cell module 402A, and the left end surface of the solar cell panel 5 is close to the right end surface of the tile member 300. Face to face.
Further, in the solar cell module 402A, as shown in FIG. 54, the engaging portion 472 of the eaves side frame portion 550 and the conductive member 464 are engaged with the second plate portion 313 of the eaves metal fitting 302. Specifically, the second plate portion 313 of the eaves metal fitting 302 is inserted into the insertion space 483 of the engaging portion 472 of the eaves side frame portion 550 while pressing the conductive member 464, and the pressing portion 497 of the conductive member 464 is inserted. The restoring force presses the second plate portion 313 toward the lower plate portion 482 of the engaging portion 472.
Further, the fixing portion 426 of the ridge side frame portion 405 is placed on the tile bar 307 of the foundation roof structure 304, and the fastening element 39 is a fixing hole of the fixing portion 426 of the ridge side frame portion 405 of the solar cell module 402A. The fixing holes 445 of the conductive member 421 and the 436 are inserted into the tile rod 307.

Subsequently, as shown in FIG. 53 (a), the eaves side frame portion 550 of the solar cell module 402B (402) is hooked on the eaves metal fitting 302 and placed on the tile bar 307 of the foundation roof structure 304, and is placed on the tile rod 307 of the foundation roof structure 304. As shown in b), the solar cell module 402B is positioned so as to be relatively close to the adjacent solar cell module 402A in the girder direction. Then, the solar cell module 402B is fixed to the foundation roof structure 304 by a fastening element 39 such as a nail.

At this time, in the direction of the eaves, in the solar cell module 402B, the engaging portion 472 of the eaves side frame portion 550 and the conductive member 463 are engaged with the second plate portion 313 of the eaves metal fitting 302.
In the solar cell module 402B, the fixed portion 426 of the ridge side frame portion 405 is placed on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the tile rod 307 through the fixing hole 436 of the fixing portion 426 of the ridge side frame portion 405 of the solar cell module 402B and the fixing hole 445 of the conductive member 421.
On the other hand, in the girder direction, the left frame portion 407 of the solar cell module 402A is in contact with or in close proximity to the closing portion 146 of the right frame portion 408 of the other solar cell module 402B whose closing portion 141 is adjacent in the girder direction. The upper part of the flow path 135 is covered with the closing portion 146.
As can be read from FIG. 55, the left side connection portion 451 of the conductive member 421 of the solar cell module 402A is connected to the right side connection portion 452 of the conductive member 421 of the other solar cell module 402B adjacent in the column direction, and the solar cell. The conductive member 421 of the module 402A and the conductive member 421 of the other solar cell module 402B are electrically connected to have the same potential.
Specifically, the connection piece 453 of the left side connection portion 451 of the conductive member 421 of the solar cell module 402A covers the right side connection portion 452 of the conductive member 421 of the solar cell module 402B, and is cut when viewed in a plan view. The notch 455 overlaps the connection hole 454 of the right side connection 452. Then, a temporary fastening element 456 is inserted across the cutout portion 455 of the left side connecting portion 451 and the connecting hole 454 of the right side connecting portion 452, and the left side connecting portion 451 and the right side connecting portion 452 are integrated.

When the laying of the first-stage solar cell module 402 on the foundation roof structure 304 is completed, the second-stage roof tile member 300 and the solar cell module 402 are laid.
Specifically, as shown in FIG. 56A, the intermediate mounting bracket 303 and the first-stage solar cell module in which the eaves-side frame portion 406 of the second-stage solar cell module 402C (402) is attached to the roof tile member 300. It is hooked on the ridge side frame portion 405 of 402A, moved to the ridge side, and placed on the tile bar 307 of the foundation roof structure 304. Then, as shown in FIG. 56B, the solar cell module 402C is positioned relatively close to the pre-installed second-stage roof tile member 300, and the fastening element 39 such as a nail or the like 39. Fixes the solar cell module 402C to the foundation roof structure 304.

At this time, as can be read from FIG. 56, the second-stage solar cell module 402C is arranged so as to straddle the intermediate mounting bracket 303 and the first-stage solar cell module 402A in the girder direction. The central portion of the solar cell panel 5 of the second-stage solar cell module 402C in the girder direction is located near the boundary portion between the tile member 300 and the first-stage solar cell module 402A.
As can be read from FIGS. 57 and 58, in the second-stage solar cell module 402C, the engaging portion 472 of the eaves-side frame portion 406 is the second plate portion 332 of the intermediate mounting bracket 303 and the first-stage solar cell module 402A. It is engaged with the conductive member 421 of the ridge side frame portion 405.
Specifically, the second-stage solar cell module 402C is inserted by passing the second plate portion 332 of the intermediate mounting bracket 303 between the pressing portion 497 of the conductive member 464 and the lower plate portion 482 of the engaging portion 472. It is entering the space 483. That is, the pressing portion 497 of the conductive member 464 is pressed by the second plate portion 332 of the intermediate mounting bracket 303 and elastically deformed, and the elastic restoring force causes the second plate portion 332 of the intermediate mounting bracket 303 to face downward. Pressing. The contact portion between the pressing portion 497 of the conductive member 464 and the second plate portion 332 of the intermediate mounting bracket 303 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second stage solar cell module 2C.
Further, in the second-stage solar cell module 402C, as shown in FIG. 58, the engaging plate portion 442 of the conductive member 421 of the first-stage solar cell module 402A is pressed with the pressing portion 497 of the conductive member 463 and the lower plate of the engaging portion 472. It is passed between the portions 482 and entered into the insertion space 483. That is, the pressing portion 497 of the conductive member 463 is pressed by the engaging plate portion 442 of the conductive member 421 and elastically deformed, and the elastic restoring force thereof presses the engaging plate portion 442 of the conductive member 421 downward. ..
The contact portion between the pressing portion 497 of the conductive member 463 and the engaging plate portion 442 of the conductive member 421 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 402C.
The second-stage solar cell module 402C is mounted on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the tile rod 307 through the fixing hole 436 of the fixing portion 426 of the ridge side frame portion 405 of the solar cell module 402C and the fixing hole 445 of the conductive member 421.

Subsequently, as shown in FIG. 59 (a), the eaves-side frame portion 406 of the second-stage solar cell module 402D (402) is hooked on the ridge-side frame portion 405 of the first-stage solar cell modules 402A and 402B to the ridge side. And place it on the tile bar 307 of the foundation roof structure 304. Then, as shown in FIG. 59 (b), the solar cell module 402D is positioned relatively close to the solar cell module 402C adjacent in the girder direction, and the solar cell module 402D is positioned by the fastening element 39 such as a nail. The battery module 402D is fixed to the foundation roof structure 304.

At this time, the second-stage solar cell module 402D is arranged across the first-stage solar cell modules 402A and 402B in the girder direction. The central portion of the solar cell panel 5 of the second-stage solar cell module 402D in the girder direction is located near the boundary portion of the first-stage solar cell modules 402A and 402B.
In the second-stage solar cell module 402D, the engaging portion 472 of the eaves-side frame portion 406 engages with the conductive members 421 and 421 of the ridge-side frame portions 405 and 405 of the first-stage solar cell modules 402A and 402B, respectively. ing.
Specifically, in the second-stage solar cell module 402D, the engaging plate portion 442 of the conductive member 421 of the first-stage solar cell module 402A is formed by pressing the pressing portion 497 of the conductive member 464 and the lower plate portion 482 of the engaging portion 472. It is passed between them and entered into the insertion space 483. That is, the pressing portion 497 of the conductive member 464 is pressed by the engaging plate portion 442 of the conductive member 421 and elastically deformed, and the elastic restoring force thereof presses the engaging plate portion 442 of the conductive member 421 downward. .. The contact portion between the pressing portion 497 of the conductive member 464 and the engaging plate portion 442 of the conductive member 421 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 402D.
Similarly, in the second-stage solar cell module 402D, the engaging plate portion 442 of the conductive member 421 of the first-stage solar cell module 402B is placed between the pressing portion 497 of the conductive member 463 and the lower plate portion 482 of the engaging portion 472. It is passed through and entered into the insertion space 483. That is, the pressing portion 497 of the conductive member 463 is pressed by the engaging plate portion 442 of the conductive member 421 and elastically deformed, and the elastic restoring force thereof presses the engaging plate portion 442 of the conductive member 421 downward. .. The contact portion between the pressing portion 497 of the conductive member 463 and the engaging plate portion 442 of the conductive member 421 is located on the projection surface in the vertical direction of the light receiving surface 7 of the second-stage solar cell module 402D.
Further, the second-stage solar cell module 402D is mounted on the tile bar 307 of the foundation roof structure 304. Further, the fastening element 39 is driven into the tile rod 307 through the fixing hole 436 of the fixing portion 426 of the ridge side frame portion 405 of the solar cell module 402D and the fixing hole 445 of the conductive member 421.
In the left frame portion 407 of the solar cell module 402C, the closing portion 141 is in contact with or close to the closing portion 146 of the right frame portion 408 of the solar cell module 402D, and the upper part of the flow path 135 is covered by the closing portion 146. ing.

When the laying of the second-stage solar cell module 402 on the foundation roof structure 304 is completed, the tile members 300 and the solar cell module 402 of the third and subsequent stages are laid to complete the roof structure 1.

According to the solar cell module 402 of the present embodiment, since the solar cell panel 5 is reinforced by the reinforcing bar 410, it is not easily damaged.

In the above-described embodiment, the crystalline solar cell panel is adopted as the solar cell panel 5, but the present invention is not limited to this, and the solar cell panel 5 may be another type of solar cell panel. Good. For example, it may be a thin-film solar cell panel in which a thin-film layer is laminated on a glass substrate.

In the above-described embodiment, notches 58, 59, and 64 are formed at both ends and the intermediate portion of the snow stopper 66 in the extending direction, and rainwater or the like flowing on the solar cell panel 5 is allowed to pass to the eaves side. However, the present invention is not limited to this. For example, as shown in FIG. 60, instead of providing the notch portion 64 in the division piece 23, the second division pieces 23, 23 having no notch portions 64 are spaced apart from the first division piece 22 at predetermined intervals. A gap 560 may be formed in the lateral direction X to form a water passage port.
Further, for example, instead of providing the notch portions 58 and 59 in the division piece 23, the second division piece 23 having no notch portion 64 is not installed up to both ends of the first division piece 22 in the lateral direction X, and the first Water passage ports 561 and 562 are formed on the divided pieces 22 without the second divided pieces 23 being provided. Then, the water passages 561 and 562 of the solar cell modules 2 and 2 adjacent to each other in the girder direction may be overlapped to form the water passage 563.

In the above-described embodiment, the snow stopper 66 of the eaves side frame portion 16 has one notch 64 formed in the middle portion in the extending direction, but the present invention is not limited to this. As shown in FIG. 61, the snow stopper 66 of the eaves side frame portion 16 may have a plurality of notches 64 formed in the middle portion in the extending direction.

In the above-described embodiment, the tile members 300 and the solar cell modules 2, 402 are laid in the order from the right side to the left side with respect to the foundation roof structure 304, but the present invention is not limited to this, and FIG. As described above, the tile member 300 and the solar cell modules 2, 402 may be laid in the order from the right side to the left side with respect to the foundation roof structure 304.

In the above-described embodiment, the first concave groove 69 is formed in the first skeleton portion 61, and the first convex groove portion 107 is formed in the first gasket portion 100, but the present invention is not limited thereto. Instead, as shown in FIG. 63, the first ridge portion 107 may be formed in the first skeleton portion 61, and the first concave groove 69 may be formed in the first gasket portion 100. That is, the relationship of unevenness may be reversed.
Similarly, in the above-described embodiment, the second concave groove 79 is formed in the second skeleton portion 62, and the second convex groove portion 117 is formed in the second gasket portion 101, but the present invention is limited thereto. However, the second ridge portion 117 may be formed in the second skeleton portion 62, and the second concave groove 79 may be formed in the second gasket portion 101.

In the above-described embodiment, the first gasket portion 100 covers the end surface of the solar cell panel 5 on the eaves side, but the present invention is not limited to this. As shown in FIG. 64A, the second gasket portion 101 may cover the end surface of the solar cell panel 5 on the eaves side. That is, the end face side cushioning portion 103 may be provided in the second gasket portion 101 of the second divided piece 23.
In this case, when replacing the solar cell panel 5, as shown in FIG. 64 (b), the end face side cushioning portion 103 of the second divided piece 23 is elastically deformed, and the used solar cell panel 5 is pulled out. It is preferable to replace it.

In the above-described embodiment, the ridge-side gasket portion 28 is formed by extrusion molding of two layers of a hard gasket portion 45 and a soft gasket portion 46, but the present invention is not limited thereto. The hard gasket portion 45 and the soft gasket portion 46 may be separately formed by extrusion molding, and then the hard gasket portion 45 and the soft gasket portion 46 may be bonded and integrated. Further, the ridge side gasket portion 28 may be formed of one kind of material.

1,400 Roof structure 2a, 402a 1st solar cell module 2b, 402b 2nd solar cell module 5 Solar cell panel 6a, 6b, 403a, 403b Holding member 7 Light receiving surface 9b, 412b Eaves side overhang (eave building side extension) Departure)
16,406 Eaves side frame part 22,207,457,555 1st division piece 23,208,458,556 2nd division piece 56 Engagement part (2nd engagement part)
61, 202 1st skeleton part 62,203 2nd skeleton part 69 1st concave groove 79 2nd concave groove 100 1st gasket part 101 2nd gasket part 107 1st convex part 117 2nd convex part 167 Locking piece (1st engaging part)
301 Roof base 442 Engagement plate part (2nd engagement part)
472 Engagement part (1st engagement part)

Claims (11)

In the arrangement structure of the solar cell modules in which a plurality of solar cell modules are arranged in the roof eaves direction with respect to the roof base and the solar cell modules adjacent to the eaves building direction are arranged in a stepped manner with overlapping portions.
The solar cell module includes a solar cell panel and a holding member that holds the solar cell panel.
The holding member has an eaves side frame portion and has an eaves side frame portion.
The eaves-side frame portion has at least two divided pieces, and the two divided pieces are used to hold the eaves-side end portion of the solar cell panel.
In the two divided pieces, one divided piece can be attached to and detached from the other divided piece.
Among the solar cell modules adjacent to the eaves building direction, the eaves side frame portion of the solar cell module on the ridge side is placed on the surface of the solar cell module on the eaves side on the light receiving surface side .
The solar cell module on the ridge side is characterized in that its own solar cell panel can move in the direction of the ridge by removing the one divided piece of the eaves side frame portion with respect to the other divided piece. Arrangement structure of the solar cell module. The one divided piece includes a first gasket portion that comes into contact with one part of the solar cell panel.
The arrangement structure of the solar cell module according to claim 1, wherein the other divided piece includes a second gasket portion that comes into contact with another portion of the solar cell panel. The solar cell module on the ridge side is characterized in that the eaves side end face of its own solar cell panel is exposed to the outside by removing the one divided piece of the eaves side frame portion with respect to the other divided piece. The arrangement structure of the solar cell module according to claim 1 or 2 . The solar cell panel has one side extending in the girder direction on the eaves side.
The one divided piece has a first skeleton portion and a first gasket portion.
The first gasket portion is in contact with one portion of the solar cell panel, and is interposed between the solar cell panel and the first skeleton portion.
The first skeleton portion and the first gasket portion extend continuously or intermittently along one side of the eaves side.
One of the first gasket portion and the first skeleton portion includes a first convex portion extending in one side direction on the eaves side, and the other is a first concave portion extending in the same direction as the first convex portion. It has a groove and
The invention according to any one of claims 1 to 3 , wherein the first gasket portion and the first skeleton portion are integrated by fitting the first convex portion and the first concave groove. Arrangement structure of solar cell modules. The arrangement structure of the solar cell module according to claim 4 , wherein the length of the first convex portion and the first concave groove in the extending direction is 1/3 or more of one side of the eaves side. The solar cell panel has one side extending in the girder direction on the eaves side.
The other divided piece has a second skeleton portion and a second gasket portion.
The second gasket portion is in contact with another portion of the solar cell panel, and is interposed between the solar cell panel and the second skeleton portion.
The second skeleton portion and the second gasket portion extend continuously or intermittently along one side of the eaves side.
One of the second gasket portion and the second skeleton portion includes a second convex portion extending in one side direction on the eaves side, and the other is a second concave portion extending in the same direction as the second convex portion. It has a groove and
The invention according to any one of claims 1 to 5 , wherein the second gasket portion and the second skeleton portion are integrated by fitting the second convex portion and the second concave groove. Arrangement structure of solar cell modules. The holding member has a first engaging portion and a ridge-side frame portion that holds the ridge-side end of the solar cell panel.
The ridge side frame portion has a second engaging portion that can be engaged with the first engaging portion.
The solar cell module on the ridge side has the first engaging portion engaged with the second engaging portion of the solar cell module on the eaves side in the direction intersecting the light receiving surface of its own solar cell panel. The arrangement structure of the solar cell module according to any one of claims 1 to 6 . The arrangement structure of the solar cell module according to claim 7 , wherein the other divided piece includes the first engaging portion. The arrangement structure of a solar cell module according to any one of claims 1 to 8 , wherein the solar cell panel has a solar cell interposed between a glass plate and a sealing member. The holding member has the eaves side frame portion, the ridge side frame portion, the left side frame portion, and the right side frame portion.
The eaves side frame portion and the ridge side frame portion each have a holding recess.
The eaves-side end of the solar cell panel is inserted into the holding recess of the eaves-side frame.
The ridge-side end of the solar cell panel is inserted into the holding recess of the ridge-side frame.
Both the left side frame portion and the right side frame portion support the back surface of the solar cell panel, and connect the ridge side frame portion and the eaves side frame portion.
The vicinity of the left end portion of the solar cell panel is placed on the left side frame portion, and the vicinity of the right end portion of the solar cell panel is placed on the right side frame portion.
It has one solar cell module and another solar cell module adjacent to the one solar cell module in the column direction.
Right end surface of the solar cell panel of the one solar cell module according to claim 1-9, characterized in that it is directly facing the left end surface of the solar cell panel of another solar cell module adjacent to the girder direction Arrangement structure of the solar cell module described in any one. Installed so that it is adjacent to the roof base in the direction of the eaves with other solar cell modules.
A solar cell module that is arranged in a stepped manner with an overlapping portion with respect to the other solar cell modules.
Includes a solar cell panel and a holding member that holds the solar cell panel.
The holding member has an eaves side frame portion and has an eaves side frame portion.
The eaves-side frame portion has at least two divided pieces, and the two divided pieces are used to hold the eaves-side end portion of the solar cell panel.
In the two divided pieces, one divided piece can be attached to and detached from the other divided piece.
The one divided piece includes a first gasket portion that comes into contact with one part of the solar cell panel.
The other split piece comprises a second gasket portion that comes into contact with the other portion of the solar cell panel.
The eaves-side frame unit, when installed in the roof bed is shall be placed on the surface of the light-receiving surface side of the other solar cell modules,
It is characterized in that its own solar cell panel can be moved in the direction of the eaves by removing the one divided piece of the eaves side frame portion with respect to the other divided piece in the state of being installed on the roof base. Solar cell module.

Images