JP6192453B2 - Roof structure, solar cell module fixture, solar cell module mounting structure, and solar cell module mounting method - Google Patents

Description

  The present invention relates to a roof structure formed by mounting a solar cell module, a solar cell module mounting tool for mounting a solar cell module on a roof, a solar cell module mounting structure, and a solar cell module mounting method. is there.

  In recent years, solar power generation systems have been popularized. A solar power generation system is formed by installing a solar cell module on a building such as a general house or building, and it is possible to supply generated power to the building and sell surplus power to an electric power company. ing.

  The following two structures are known as mounting structures for attaching the solar cell module to the building. The first structure is a structure in which a roof material such as a tile or a metal plate is spread on a roof base, and a solar cell module is further mounted thereon. The second structure is a structure in which the solar cell module is provided with a tile function, and the solar cell module is spread on the roof base.

As a 1st structure, there exists a structure disclosed by patent document 1, for example. The solar cell module fixture (hereinafter also simply referred to as a fixture) employed in this roof structure includes a plate-like portion (intermediate plate member, pressing plate member) for sandwiching the solar cell module, and a base portion (fixed portion). ). In this roof structure, when the roof material is spread on the roof base, the base portion of the fixture is attached together with the roof material.
From this, in the process of constructing the roof structure, a basic roof structure, that is, a roof structure serving as a foundation with the foundation portion exposed from the upper side of the laid roofing material is formed. And if this plate-shaped part is attached to the exposed base part with respect to this basic roof structure, the roof structure which fixes a solar cell module on the roof material and the base part will be constructed. That is, the roof structure in which the solar cell module is attached to the upper side of the portion where the roofing material is spread is constructed.

  More specifically, in the roof structure disclosed in Patent Document 1, a fastening member such as a screw nail is inserted by overlapping the mounting hole for the roofing material and the mounting hole formed in the base portion of the mounting tool, The roofing material and the base part are fixed to the roof base. At this time, of the two roof materials adjacent to each other in a step shape, the roof material located on the eave side and a part of the base portion are fixed together. Then, the roof material located on the eave side and the mounting holes for the base portion, that is, the mounting holes for inserting the fastening elements are covered with another roof material located on the ridge side. For this reason, it can be set as the structure where rain water etc. do not permeate into the roof base | substrate side easily from the hole for attachment for fixing a base part, and rain does not leak easily.

As a 2nd structure, there exists a structure disclosed by patent document 2 and patent document 3, for example. In the roof structure disclosed in Patent Document 2, the fixing portion of the suspension is fixed to the roof base (field plate) with a nail, and a roof material module including a metal roof member and a solar cell is mounted on the upper side of the suspension. It has a placed structure. More specifically, the portion near the eaves-side end of the roofing material module is placed on the suspension and is supported at a position away from the roof base. And in this roof structure, the ridge side end of another adjacent roof material module is positioned below the eave side end of the roof material module, and these two roof material modules are fixed integrally with a connecting member. doing.
That is, in the structure disclosed in Patent Document 2, a roof material module including at least a metal roof member and a solar cell is assembled in advance using a set screw or the like (set screw 54 or the like in Patent Document 2). It can be said that it is a structure which attaches a material module to a roof base | substrate via a hanging element, and also fixes roof material modules integrally.

  In the roof structure disclosed in Patent Document 3, a metal roof material having a solar cell attached to the surface thereof is attached to a fixture that is directly attached to a base plate. That is, it can be said that this roof structure is a structure in which members made of solar cells and metal roof materials are integrally formed in advance and directly attached to the base plate via the fixing bracket.

JP 2011-163062 A JP 2000-96775 A JP-A-8-270151

  In the above-described mounting structure of the prior art, it is assumed that a solar cell module is mounted when a new roof is constructed. Therefore, when it is going to attach a solar cell module to the existing roof structure already formed by roofing materials, such as a tile, on a roof base | substrate, attachment work may become complicated.

  More specifically, in the structure disclosed in Patent Document 1, since it is necessary to fix the base portion of the fixture together with the roofing material to the roof base, when the solar cell module is attached to the existing roof structure, it is already sown. It may be necessary to remove roofing materials such as tiles. That is, it becomes necessary to remove the already-sown roofing material and attach the fixture together with the roofing material to the exposed roof base.

  In addition, in the structures disclosed in Patent Documents 2 and 3, when a solar cell module is attached to an existing roof structure, it is necessary to remove roof materials such as tiles that have already been laid. That is, it is necessary to remove the already-sown roofing material, attach a hanging member or a fixing bracket to the roof base, and attach a roofing material module (a member made of a roof member and a solar cell) to the upper side. .

  That is, in the above-described conventional roof structure, when the solar cell module is attached to the existing roof structure in which the roof material has already been sown, an operation to remove the sown roof material occurs. And the removal operation | work of this roof material is an effort, and the attachment operation | work of a solar cell module may become complicated.

  In view of the above-described problems of the prior art, the present invention provides a technique capable of easily mounting a solar cell module even when the solar cell module is attached to an existing roof structure already covered with a roofing material. This is the issue.

  The invention according to claim 1 for solving the above-mentioned problem is a roof structure in which a roofing material is laid and a solar cell module is installed on the roofing material via a mounting tool. In the roof structure in which the bottom side portion of the surface on the eave side is laid on the ridge side of another roof material, the roof material faces the eave side on the basis of the installation state. Eaves side wall surface portion is formed, and the fixture has a main body portion and a holding member fixed to the roof material, and the holding member holds a side portion of the solar cell module, or the sun. A member for fixing an electric module is held, and the main body part is attached to an eave side attachment surface fixed to the eaves side wall surface part, and a holding member to which the holding member is attached while covering the roof material. Mounting part and top surface of the roofing material A and a contacting leg, said eaves side mounting surface is a roof structure characterized in that it is fixed via a fastening element with respect to the eaves side wall portion.

The roof structure of the present invention is laid in a state where the bottom side portion of the eave side surface which is a part of the roof material is overlapped with the ridge side of the other roof material. That is, the eaves side surface of the roofing material located on the ridge side intersects with the upper surface of the roofing material located on the eaves side, forming a step. And the fixture for attaching a solar cell module is being fixed to the part which forms this level | step difference. In other words, the fixture is fixed to the step portion formed when the roofing materials are overlapped.
According to this structure, the fixture can be fixed without inserting screws, nails, and the like (fastening elements) in the direction from the upper surface of the roof toward the roof base. Specifically, the portion forming the step is located between the upper surface of the roof material on the eave side and the upper surface of the roof material on the ridge side, and is a surface intersecting with these. Therefore, when a screw, a nail, or the like is inserted through this surface, the fixture can be fixed without forming a through hole on the upper surface.

For this reason, in the roof structure of this invention, even if it attaches a fixture with respect to the existing roof structure formed by covering the roof material, it becomes possible to exhibit high waterproofness.
More specifically, in a conventional structure in which a through hole is formed on the top surface of the roof material, there is a possibility that rainwater or the like may enter the roof base side from the through hole that penetrates the roof material in the vertical direction. Therefore, it will be necessary to make it the structure which covers the through-hole formed in the upper surface of a roof material with another roof material, or to implement a caulking process.
On the other hand, in the roof structure of the present invention, the fixture can be fixed without forming a through hole in the upper surface of the roof material. Therefore, even if a fixture is attached to the roof material forming the existing roof structure, high waterproofness can be secured. Therefore, it is possible to directly fix the fixture to the roof material constituting the roof structure without dismantling the existing roof structure that has already been constructed. Further, when fixing the fixture, the fixture can be fixed by a simple attachment operation such as simply inserting the fastening element.
That is, in the roof structure of the present invention, it is easy to fix the fixture for attaching the solar cell module, so that the solar cell module can be easily attached.

  The invention according to claim 2 is the roof structure according to claim 1, wherein a lower end side of the eaves-side mounting surface fixed to the roof material is in contact with an upper surface of another roof material. is there.

  According to this structure, a part of fixture will contact | abut from the upper side to the roof material different from the roof material which fixed the fixture. From this, it becomes possible to disperse the load that the fixture receives from the solar cell module or the like on the plurality of roof materials, and a structure in which a large load is not applied to the roof material to which the fixtures are fixed can be achieved. In other words, it is possible to suppress deterioration, breakage, and the like of the roof material to which the fixture is fixed.

  According to a third aspect of the present invention, the main body portion is formed by bending a single metal plate, the leg portion has a planar portion in surface contact with the upper surface of the roof material, and the eaves The holding member mounting portion is provided between a side mounting surface and the leg portion, and a virtual surface that is flush with the planar portion intersects the eave side mounting surface substantially perpendicularly. Item 3. The roof structure according to item 1 or 2.

  According to this configuration, the load is not concentrated on the portion where the fixture is fixed, and a suitable load distribution is possible.

  Invention of Claim 4 is interposed between the roof material in which the eaves side wall surface portion exists on the surface toward the eave side, and the solar cell module, and in the fixture for fixing the solar cell module to the roof material, It has a main body portion and a holding member fixed to the roof material side, and the holding member holds a side portion of the solar cell module or a member for fixing the solar power module. The main body portion is in contact with the eaves side wall surface portion and is attached to the eaves side wall surface portion via a fastening element, and the main body portion is covered with a gap above the roof material and the holding member. A mounting member for a solar cell module, comprising: a holding member mounting portion for mounting the mounting member via a fastening element; and a leg portion that contacts the upper surface side of the roof material.

  The invention according to claim 5 is provided with a plurality of roofing materials having eaves side wall surface portions on the surface facing the eaves side, and the roofing materials are arranged in rows and steps and placed with a planar spread. An attachment structure for attaching a solar cell module to a roof, comprising the attachment for a solar cell module according to claim 4, wherein the eave side attachment surface is connected to the eave side wall surface portion via a fastening element. The solar cell module mounting structure is characterized in that the solar cell module mounting fixture is fixed to the roof material by fixing.

  The solar cell module attachment of the present invention and the solar cell module attachment structure of the present invention are the same as the above-described roof structure of the present invention, and even when the attachment is attached to an existing roof structure. It is possible to exhibit high waterproofness. Therefore, it is possible to fix the fixture directly to the roof material that constitutes the roof structure that has already been sown, and it is possible to fix the fixture by a simple attachment operation such as simply inserting a fastening element.

  The invention according to claim 6 is a solar cell module mounting method using the solar cell module fixture according to claim 4, with respect to the eaves side wall surface portion present on the surface facing the eave side of the roofing material, A solar cell module mounting method comprising a step of fixing the eave side mounting surface via a fastening element.

  It is preferable that the fixture of the solar cell module of this invention is fixed by such a construction method.

  According to the present invention, even if a fixture is attached to a roof material that forms an existing roof structure, high waterproofness can be secured. From this, it is possible to easily fix the fixture to the roof material without dismantling the existing roof structure that has already been constructed, so that the installation work of the solar cell module can be simplified.

It is a perspective view which shows the roof structure which concerns on embodiment of this invention. It is a perspective view which shows the roof material employ | adopted with the roof structure of FIG. It is a perspective view which shows the fixture of FIG. It is a perspective view which shows the main-body part of FIG. It is a perspective view which shows the holding | maintenance part of FIG. It is a disassembled perspective view which shows the holding | maintenance part of FIG. FIG. 6 is a perspective view illustrating a state in which the holding unit in FIG. 3 is viewed from a direction different from that in FIG. 5. It is explanatory drawing which shows a mode that a holding | maintenance part is attached to the main-body part of FIG. 3, and attaches in order of (a)-(c). It is a disassembled perspective view which shows the fixture of FIG. It is a perspective view which shows the construction procedure of the roof structure of this embodiment, and shows the state which attached the fixture to the eaves side part of the roof, and attached the main-body part which is a part of fixture to the ridge side part of the roof. . It is explanatory drawing which shows a mode that a main-body part is attached with respect to a basic roof structure. It is sectional drawing which shows a mode that a main-body part is attached with respect to a basic roof structure. It is explanatory drawing which shows a mode that a holding | maintenance part is attached with respect to the main-body part attached to the basic roof structure. It is sectional drawing which shows the roof structure of the state similar to FIG. It is a perspective view which shows the construction procedure of the roof structure of embodiment, and is a perspective view which shows the state which further mounted the solar cell module with respect to the roof structure of the state of FIG. It is a figure which shows the construction procedure of the roof structure of embodiment, and is sectional drawing which shows a mode that a holding | maintenance part is attached to the main-body part located in the ridge side with respect to the roof structure of the state of FIG. It is a perspective view which shows the construction procedure of the roof structure of embodiment, attaches a holding | maintenance part to the main-body part located in the ridge side from the state of FIG. 16, and connects the cables of the adjacent solar cell module, and this cable The state latched by the shape part is shown. It is explanatory drawing which shows a mode that the inclination at the time of attachment of the attachment tool of FIG. 1 is adjusted, (a) shows the state which the attachment tool inclined, (b) shows the state which the attachment tool is in a normal attitude | position. Show. It is a perspective view which shows the roof material different from FIG. It is explanatory drawing which shows a mode that the main-body part of FIG. 3 is attached with respect to the basic roof structure constructed by rolling the roof material shown in FIG. It is a perspective view which shows the main-body part different from FIG. It is a perspective view which shows the main-body part different from FIG. 4, FIG. 21, (a) shows the state seen from the eaves side, (b) shows the state seen from the ridge side. It is explanatory drawing which shows the rail member for attaching the fixture of a form different from FIG.4, FIG.21, FIG.22 and a solar cell module.

  Hereinafter, although embodiment of this invention is described in detail, this invention is not limited to these examples. In the following description, unless otherwise specified, the positional relationship between the top, bottom, left, and right is described based on the normal installation position (FIG. 1).

  In the roof structure 1 of the present embodiment, the solar cell module 5 is provided via a fixture 4 (a fixture for the solar cell module) with respect to the basic roof structure 3 formed by roofing the roof material 2 on the roof base. It is attached.

  The roofing material 2 is formed by plating a metal plate such as a Galvalume steel plate and then pressing it into a predetermined shape. As shown in FIG. 2, the roofing material 2 of the present embodiment includes a substantially rectangular flat plate-like roofing material body 10, and a front upright plate part 11 formed by folding the front end side portion of the roofing material body 10 downward. The rear standing plate portion 12 is formed by raising the rear end portion of the roof material main body 10 upward, and is formed so as to be integrated.

The front vertical plate portion 11 is a vertical plate-like portion protruding downward from the front end side portion of the roof material main body 10.
In addition, the front end side part of the roofing material main body 10 is a part which becomes an eaves side end part at the time of installation on a roof. That is, the front standing board part 11 is formed in the part located in the eaves side at the time of installation on a roof, and the front end surface 11a (eave side wall surface part) of the front standing board part 11 turns into a surface which goes to the eaves side.

  As shown in FIG. 3, the fixture 4 mainly has a main body 20 and a holding portion 21 (holding member).

  The main body 20 is formed by punching an appropriate metal such as a Galvalume steel plate into a predetermined shape and bending it. That is, the main body portion 20 is formed by bending a single metal plate. More specifically, the main body 20 includes an upright rectangular flat plate-like front plate portion 25 and a rectangular flat plate-like base plate portion 26 formed by bending the upper end portion of the front plate portion 25 rearward (attaching a holding member). Part) and a rear leg part 27 (leg part) continuous with the rear part of the base plate part 26.

  The front plate portion 25 is a vertical plate-like portion located at the front end portion (the end portion on the eaves side) of the main body portion 20, and the vicinity of the upper end is bent toward the rear. That is, the front plate part 25 is formed by an upright rectangular flat plate, a lower plate part 25a positioned on the lower side, and an upper plate part 25b protruding upward from the upper end of the lower plate part 25a. .

  The lower plate portion 25a of the front plate portion 25 is provided with a plurality of mounting holes 30 that penetrate the front plate portion 25 in the thickness direction. More specifically, the two mounting holes 30 are arranged in parallel with a gap in the horizontal direction. The mounting hole 30a, which is one of the two mounting holes 30, is a long hole extending in the vertical direction. On the other hand, the other mounting hole 30b is a round hole having a circular opening when viewed from the front. That is, the two mounting holes 30 are holes having different opening shapes, and only one of them is a long hole extending in the vertical direction. In other words, at least one of the plurality of mounting holes 30 is a long hole extending in the vertical direction.

  The base plate part 26 is a part located at the upper end of the main body part 20 and has a placement surface on which the holding part 21 (see FIG. 3) can be placed. That is, the base plate part 26 is a part that functions as a fixing base for fixing the holding part 21.

  As shown in FIG. 4, the base plate portion 26 is provided with a through hole that penetrates the base plate portion 26 in the thickness direction. More specifically, two through holes arranged in parallel with a space in the left-right direction are provided in the vicinity of the rear side (ridge side) of the base plate part 26.

  These two through holes serve as a holder attachment hole 33 for fixing the holding portion 21 (see FIG. 3). A fixing member such as a blind nut (not shown in FIG. 4; see FIG. 8) is attached to the holder attachment hole 33, and a fastening element such as a screw is attached in a loosened state. It has become.

  The rear leg portion 27 includes a vertical plate-like support plate portion 37 that is suspended downward from the rear end portion (end portion on the ridge side) of the base plate portion 26, and a rectangular shape that protrudes rearward from the lower end of the support plate portion 37. It has a configuration having a flat pressing plate portion 38 (planar portion).

The support plate portion 37 is positioned so as to face the front plate portion 25 with a space in the front-rear direction (inter-beam direction), and the lower end portion thereof is positioned above the lower end portion of the front plate portion 25. Yes. Therefore, the pressing plate portion 38 is also positioned above the lower end portion of the front plate portion 25.
Further, the pressing plate portion 38 is a horizontal plate-like portion, whereas the front plate portion 25 is an upright plate-like portion. In other words, the pressing plate portion 38 forms a surface extending in the horizontal direction, whereas the front plate portion 25 forms a surface extending in the direction including the height direction. That is, the virtual plane that is the same plane as the surface formed by the pressing plate portion 38 intersects the surface formed by the front plate portion 25 (lower plate portion 25a) substantially perpendicularly.

  The pressing plate portion 38 is provided with a spacer mounting hole 35 that is a through-hole penetrating the pressing plate portion 38 in the thickness direction, and a hook-like portion 36 formed by cutting and raising a part of the pressing plate portion 38. It has been.

  A plurality of spacer mounting holes 35 are provided in the pressing plate portion 38, and more specifically, the two spacer mounting holes 35 are formed in parallel with a gap in the left-right direction (column direction). That is, one spacer mounting hole 35 is formed at a position near one end in the left-right direction of the pressing plate 38, and the other spacer mounting hole 35 is near the other end in the left-right direction of the pressing plate 38. Formed in position. Each of these is a through hole having a circular opening shape.

  The hook-shaped portion 36 is provided in the vicinity of the center in the width direction of the pressing plate portion 38 and is located between the two spacer mounting holes 35. That is, in the pressing plate portion 38, the spacer mounting hole 35, the hook-shaped portion 36, and the spacer mounting hole 35 are formed in parallel in this order from the one end portion side in the left-right direction to the other end portion side. Yes.

  The hook-like portion 36 is formed by making a cut in the pressing plate portion 38 having a substantially “U” shape when viewed from the front, and raising a portion surrounded by the cut. That is, the hook-shaped portion 36 is formed by cutting and raising a part of the pressing plate portion 38 and bending the tip portion into a hook shape. Therefore, the bowl-shaped portion 36 is a flat plate-like portion formed by folding an upright rectangular flat plate portion protruding upward from the pressing plate portion 38 and an upper end portion of the vertical plate portion to the front side (eave side). Part. And this hook-shaped part 36 forms the space by which the front was open | released in the downward side of the part turned up the front.

  As shown in FIG. 5, the holding portion 21 is a holding portion main body 42 to which a pressing plate member 43 is attached.

  As shown in FIG. 6, the holding portion main body 42 is a portion formed by bending a single metal plate in a step shape. That is, the holding portion main body 42 is formed so that the first flat plate portion 47, the first standing plate portion 48, the second flat plate portion 49, and the second standing plate portion 50, all of which are rectangular flat plate portions, are successively connected. Has been. Among these, the first upright plate portion 48 and the second upright plate portion 50 are in an upright posture.

  More specifically, in the holding portion main body 42, the first standing plate portion 48 protrudes upward from the eaves side end portion of the first flat plate portion 47, and the second flat plate portion from the upper end of the first standing plate portion 48. 49 protrudes toward the eaves side, and the second upright plate portion 50 protrudes upward from the eaves side end of the second flat plate portion 49.

  The first flat plate portion 47 is provided with a plurality of attachment long holes 53. That is, the two long mounting holes 53 are formed in parallel in the left-right direction (column direction) with a space therebetween.

As shown in FIG. 7, each of the attachment long holes 53 is slightly forward (on the eaves side and in FIG. 7) slightly from the rear end of the first flat plate portion 47 (the ridge side end and the front end in FIG. 7). It extends from the portion located rearward) to the wall surface of the first standing plate portion 48.
In other words, the mounting long hole 53 includes a long hole extending portion 53a that penetrates the wall surface of the first standing plate portion 48 in the thickness direction, and a long hole main body portion 53b that penetrates the first flat plate portion 47 in the thickness direction. Is a long hole formed continuously. The elongated hole extending portion 53a is a through-hole whose opening shape is a substantially rectangular shape, and the length in the width direction is longer than that of the elongated hole main body portion 53b. And the long hole extension part 53a is designed by the magnitude | size which can pass the head of a screw | thread. The elongated hole main body 53b is designed to have a dimension that allows the shaft portion of the screw to pass but not the head portion of the screw.

  Further, as shown in FIG. 6, the second standing plate portion 50 is formed with a plate fixing hole 55 for fixing the pressing plate member 43. The plate fixing hole 55 is a female screw hole that penetrates the second upright plate portion 50 in the member thickness direction, and is formed so as to be parallel to each other with a space in the left-right direction (column direction).

  The holding plate member 43 is a member having a substantially “U” shape when viewed from the side, and includes a rectangular plate-like front plate portion 58 standing upright and a rectangular plate-like shape protruding rearward from the upper end of the front plate portion 58. The top plate portion 59 and a rectangular flat plate-like lower plate portion 60 protruding rearward from the lower end of the front plate portion 58 are configured.

  The front plate portion 58 of the pressing plate member 43 is also provided with a plate fixing hole 61 that penetrates the front plate portion 58 in the thickness direction. The plate fixing holes 61 are through holes that penetrate the front plate portion 58 in the thickness direction, and are formed so as to be arranged in parallel in the left-right direction (column direction).

  Then, the assembly structure of the fixture 4 is demonstrated.

  As shown in FIG. 3, the fixture 4 is fixed in a state where the holding portion 21 is placed on the base plate portion 26. That is, the fixture 4 is formed by fixing the holding portion 21 to the main body portion 20. The assembly structure of the fixture 4 will be described in detail along the recommended procedure for attaching the holding part 21 to the main body part 20.

  Here, as described above, a fixing member such as a blind nut is attached to the holder attachment hole 33 of the base plate portion 26, and further, a fastening element such as a screw is attached in a loosened state ( (See FIG. 4, FIG. 8, etc.)

  And when attaching the holding | maintenance part 21 to the main-body part 20, as shown in Fig.8 (a), it hold | maintains in the part of the back side (ridge side) rather than the fastening element inserted in the holder attachment hole 33. The first standing plate part 48 of the part main body 42 is assumed to be positioned. Then, when the holding portion main body 42 is slid and moved forward (on the eaves side and on the left side in FIG. 8) as it is, the head of the fastening element (screw) becomes the elongated hole extension 53a of the mounting elongated hole 53 (FIG. 7 and the like). (Refer to FIG. 8 (b)). By tightening the fastening element (screw) in this state, the holding portion main body 42 is fixed to the base plate portion 26 (see FIG. 8C).

Further, a holding plate member 43 is fixed to the holding portion main body 42.
That is, as shown in FIGS. 6 and 9, the second standing plate portion 50 of the holding portion main body 42 and the front plate portion 58 of the pressing plate member 43 are overlapped to fix the second standing plate portion 50. It is assumed that the hole 55 and the plate fixing hole 61 of the front plate portion 58 are matched. That is, these holes are in communication. Then, the pressing plate member 43 is fixed to the holding portion main body 42 by inserting a fastening element such as a screw through them.

  In the fixture 4 assembled in this way, as shown in FIG. 3, the first concave portion 65 constituted by the base plate portion 26 and the second flat plate portion 49, the second flat plate portion 49 and the holding plate member 43. A second recess 66 constituted by the top plate portion 59 is formed.

  The first concave portion 65 is a space formed between the upper surface of the base plate portion 26 and the lower surface of the second flat plate portion 49 and opens toward the front side (eave side). On the other hand, the 2nd recessed part 66 is the space formed between the upper surface of the 2nd flat plate part 49, and the lower surface of the top-plate part 59, and is opened toward the back side (ridge side). That is, the 1st recessed part 65 and the 2nd recessed part 66 are the states opened in the reverse direction, respectively.

Further, protection members 70 are attached to the insides of the first recess 65 and the second recess 66, respectively. In the first recess 65, a protective member 70 is attached in the vicinity of the end on the back side (the rear side and the ridge side). The protection member 70 is provided so as to cover at least a part of the front surface (eave side end surface) of the first standing plate part 48 and at least a part of the lower surface of the second flat plate part 49. In the second recess 66, at least the lower surface of the top plate portion 59 is covered with the protective member 70.
The protective member 70 is formed of an elastic body such as rubber.

  Furthermore, the construction method of the roof structure 1 of this embodiment is demonstrated.

First, as shown in FIG. 10, the main body portion 20 of the fixture 4 is attached to the basic roof structure 3 formed by roofing the roof material 2 on the roof base.
More specifically, the main body 20 is temporarily placed at a predetermined arrangement position of the fixture 4, and the rear end surface (eave-side mounting surface) of the front plate 25 of the main body 20 is the front vertical plate of the roofing material 2. 11 is brought into contact. In other words, the ridge-side end surface located at the ridge-side end of the front plate portion 25 is in a state of being in contact with the front upright plate portion 11. In other words, the front plate portion 25 of the main body portion 20 and the front end surface 11a of the roof material 2 are in contact with each other. And the main-body part 20 is fixed to the roofing material 2 via fastening elements, such as a screw.
The fastening element is a general concept such as a screw, a wood screw, or a nail.

  In this embodiment, the main body part 20 attached to the part closest to the eaves end, that is, the main body part 20 attached to the upper part of the eaves part, and the main body part 20 attached to other parts are different in attachment method.

First, the main body 20 attached to the ridge side will be described.
In this embodiment, as shown in FIG. 11 and FIG. 12, the front plate portion 25 located on the front side (eave edge side) of the main body portion 20 and the front standing plate portion 11 of the roof material 2 are overlapped, and these are overlapped. The body portion 20 is fixed to the roofing material 2 by being integrally fixed via a fastening element. In other words, the front plate portion 25 and the front upright plate portion 11 are in contact with each other (or in a state of being close to each other with a slight gap), and these are fixed integrally. More specifically, the fastening element is inserted into the mounting hole 30 by aligning the fastening element with the portion of the front plate portion 25 where the mounting hole 30 is formed and screwing the fastening element from that state. At the same time, a through-hole is formed in the roofing material 2 so as to extend in the horizontal direction (column direction).

  At this time, both the front plate portion 25 and the front upright plate portion 11 are in an upright posture, and the fastening element penetrates them in the thickness direction. That is, in this embodiment, when fixing the main-body part 20 on a roof, it has the structure which inserts a fastening element along a horizontal direction (column direction).

According to such a structure, compared with the structure which inserts a fastening element from the upper surface side of the roofing material 2, it can be comprised so that it is hard to leak.
That is, when a fastening element is inserted from the upper surface side of the roofing material 2 and a through-hole penetrating the roofing material 2 in the vertical direction is formed, rainwater or the like passes from the through hole to the back surface side (roof base side) of the roofing material 2. May intrude. On the other hand, in this embodiment, it is the structure which penetrates a fastening element along a horizontal direction. Therefore, the formed through hole is also a through hole extending in the horizontal direction. Accordingly, it is possible to obtain a structure in which rainwater or the like hardly enters the through hole and does not easily flow to the back surface side of the roofing material 2.

  That is, when attaching the fixture 4 to the already formed foundation roof structure 3, it is possible to attach the main body portion 20 temporarily on the roof and fix it with a fastening element, so that a highly waterproof attachment is possible. Thus, in this embodiment, the fixture 4 can be fixed on the roof without removing the roofing material 2 or the like. Furthermore, in order to fix the fixture 4, it is a structure which does not need to disassemble the already constructed foundation roof structure 3. Therefore, simplification of the attachment work can be achieved.

  Further, as shown in FIGS. 11 and 12, the main body 20 is fixed in a state of straddling two roofing materials 2 (for example, a roofing material 2a and a roofing material 2b) that are arranged in a step shape in the row direction. Has been. That is, a step formed at a portion where two roof materials 2 are connected, more specifically, a step formed by the roof material main body 10 and the front standing plate portion 11 of the roof material 2b located on the upper side (ridge side). It is in a straddling state. For this reason, the base plate part 26 which is a part of the main body part 20 is placed on the roofing material 2 in a state of being spaced apart from the roofing material 2, that is, at a position away from the roofing material 2. It is in a state. For this reason, a rivet or the like attached to the back side of the base plate portion 26 does not contact the roofing material 2.

And the lower end part of the front board part 25 is contacting with the upper surface of the roof material 2a located in the eaves side among the main-body parts 20, and the roof material in which the press board part 38 of the rear side leg part 27 is located in the ridge side. It is in contact with the upper surface of 2b. More specifically, among the main body parts 20 fixed to the front standing board part 11 of the roofing material 2b located on the upper side (ridge side), the front plate part 25 is the roofing material 2a located on the lower side (eave side). It is in a state of touching the top. That is, a part of the main body 20 is in contact with the roof material 2a different from the roof material 2b to which the main body 20 is fixed from above.
Further, the pressing plate portion 38 of the rear leg portion 27 is in contact with the upper surface of the roofing material 2b located on the ridge side. That is, it is in the state which contacted the upper surface of the roofing material 2b which fixed the main-body part 20 from upper direction.

Thereby, the load which the fixture 4 receives when installing the solar cell module 5 can be distributed to the plurality of roofing materials 2. Therefore, the load is not concentrated on one roof material 2 and the deterioration and breakage of the roof material 2 can be suppressed.
Note that the load received by the fixture 4 includes a snow load, a wind pressure load caused by a strong wind such as a typhoon, and the like in addition to the own weight of the solar cell module 5.

  In addition to this, the front plate portion 25 provided with the mounting hole 30 for inserting the fastening element acts as a leg portion that receives a load in front of the main body portion 20. Thus, the structure is such that a load is not easily applied to the fastening element inserted in the vicinity of the mounting hole 30, and in other words, through the mounting hole 30. That is, the load applied to the vicinity of the mounting hole 30 can be distributed to the roofing material 2. For this reason, it is difficult to apply a load in the direction in which the fastening element is pulled out, and unintentional dropping of the fixture 4 from the roofing material 2 can be suppressed.

Then, the main-body part 20 attached to the eaves end side is demonstrated.
In this embodiment, as shown in FIGS. 11 and 12, only the main body portion 20 attached to the eaves end side is provided with a through hole for attachment in the pressing plate portion 38 of the rear leg portion 27. And the lower surface of the press board part 38 and the upper surface of the roofing material 2 are piled up, these are inserted by a fastening element, and are being fixed integrally. That is, the fastening element is inserted from the upper surface side of the roofing material 2 only when the main body portion 20 located closest to the eaves side is attached.

  If it demonstrates in detail, the fixture 4 attached to the eaves end side will be normally attached to the edge part vicinity of the eaves end side of the foundation roof structure 3. FIG. This part becomes a part near the eaves side edge part among the roofing materials 2 located in the most eaves side among the roofing materials 2 blown by the foundation roof structure 3. FIG. Here, on the lower side of the portion near the eave side end portion, as shown in FIG. 12, an eaves tip drainer 73 is arranged between the roof bases of the roof material 2. And this eaves edge drainer 73 is a member which spreads in planar shape.

  For this reason, in the part near the eaves side edge part, even if a fastening element is inserted from the upper surface side of the roofing material 2 and a through hole extending in the vertical direction is formed, it is difficult for rainwater or the like to reach the roof base. It has become. That is, even if rainwater or the like flows into the through-hole extending in the vertical direction, the flow of rainwater or the like is blocked by the eaves drainer 73, and the rainwater or the like is difficult to enter the roof base side.

  That is, in this embodiment, even if a through-hole extending in the vertical direction is formed in the roofing material 2, a portion where rainwater or the like is difficult to enter the roof base side, that is, the vicinity of the end portion on the eaves side of the foundation roof structure 3 The fastening element is inserted from the upper surface side of the roofing material 2 only when the main body 20 is fixed to the part. In other words, the main body in the region where the eaves drainer 73 is arranged in the entire region of the basic roof structure 3, that is, the region where a member having a planar shape is arranged between the roofing material 2 and the roof base. Only when the part 20 is fixed, the fastening element is inserted from the upper surface side of the roofing material 2. As a result, the fixture 4 located closest to the eaves side is more firmly fixed while preventing rainwater or the like from entering the roof base.

As described above, in the present embodiment, the fastening element is inserted from the upper surface side of the roofing material 2 only when the main body portion 20 positioned closest to the eaves side is attached. In other words, the other main body part 20 except the main body part 20 located closest to the eaves side is configured to be attached without inserting a fastening element from the upper surface side. That is, the fastening elements for fixing the main body portion 20 located on the ridge side are all inserted along the horizontal direction.
That is, at least one of the main body portions 20 employed in the roof structure 1 is attached without inserting a fastening element from the upper surface side. In other words, at least one of the main body portions 20 employed in the roof structure 1 has only a direction along which the insertion direction of the fastening element for fixing to the roof material 2 is in the horizontal direction. Furthermore, the fastening elements for fixing the main body 20 to the roofing material 2 are all inserted from the lateral direction.

  And the process of attaching the holding | maintenance part 21 to this main-body part 20 is implemented following the process of attaching the main-body part 20 with respect to the foundation roof structure 3. FIG.

  That is, as described above, from the state where the first standing plate portion 48 is positioned at the rear portion of the holder mounting hole 33, the holder main body 42 is slid forward to enter the holder mounting hole 33. The fastening element (screw) previously attached is tightened (see FIGS. 8 and 13). As a result, as shown in FIG. 14, the holding portion 21 is fixed to the main body portion 20.

  In the step of fixing the holding portion 21 to the main body portion 20, the holding portion 21 may be fixed to the main body portion 20 after the holding portion main body 42 and the pressing plate member 43 are fixed integrally in advance. Alternatively, only the holding part main body 42 may be fixed to the main body part 20 in advance, and the pressing plate member 43 may be attached to the holding part main body 42 fixed to the main body part 20.

  Subsequently, a step of attaching the first-stage solar cell module 5 is performed.

  As shown in FIGS. 15 and 16, the second recess 66 of the fixture 4 located closest to the eaves side and the eaves side end of the solar cell module 5 are fitted. That is, the eaves side end portion of the solar cell module 5 is disposed between the lower surface of the pressing plate member 43 and the upper surface of the holding portion main body 42 (base plate portion 26). It is assumed that it is pinched.

  And the ridge side edge part of the solar cell module 5 is mounted on the main-body part 20 located in the ridge side. More specifically, the ridge-side end portion of the solar cell module 5 is placed on the eaves-side portion of the upper surface of the base plate portion 26 located at the upper end of the main body portion 20.

  With the ridge side end of the solar cell module 5 thus placed, the holding portion 21 is attached to the main body portion 20 located on the ridge side. In addition, the attachment method of this holding | maintenance part 21 is the same as the case where the holding | maintenance part 21 is attached to the main-body part 20 located in the eaves end side most. That is, the holding part main body 42 is slid forward and the fastening element (screw) previously attached to the holder attachment hole 33 is tightened (see FIG. 8 and the like).

  Then, the cables extending from the adjacent solar cell modules 5 are connected to each other, and this cable is locked to the hook-like portion 36 (see FIG. 3 and the like) provided on the fixture 4. As a result, as shown in FIG. 17, the first-stage solar cell module 5 is attached.

  And the process of attaching the solar cell module 5 after the 2nd step is performed sequentially similarly to the 1st step. Thereby, the roof structure 1 of this embodiment as shown in FIG. 1 is completed.

  By the way, in the fixture 4 of this embodiment, as above-mentioned, one attachment hole 30a is made into a long hole among the attachment holes 30 formed in the front board part 25 of the main-body part 20, and the other attachment hole. It is a 30b round hole (refer to Drawing 3 etc.). From this, after fixing the fixture 4 to the roofing material 2, the inclination of the fixture 4 can be adjusted.

  If it demonstrates concretely with an example, when the main-body part 20 was fixed with respect to the roofing material 2, as shown in Fig.18 (a), suppose that the fixture 4 was the state inclined. In this case, by slightly loosening the fastening element (screw or the like) inserted through the mounting hole 30a which is a long hole, the main body portion 20 is centered on the fastening element inserted through the other mounting hole 30b. It will be in a swingable state. As a result, the fixture 4 is shifted from the tilted posture (the posture shown in FIG. 18A) to the posture in which the fixture 4 is normally attached (the posture shown in FIG. 18B). Can do. That is, the inclination of the fixture 4 can be adjusted.

In the above-described embodiment, the example in which the roof material 2 in which the upper surface of the roof material main body 10 is flat is shown, but the roof structure of the present invention is not limited to this.
As shown in FIG. 19, the roof structure of the present invention may employ a roof material 102 in which irregularities are formed on the upper surface of the roof material main body 110. The fixture 4 of the above-described embodiment can be suitably used even when such a roof material 102 is employed.

  More specifically, it is assumed that the main body 20 is attached to the basic roof structure 103 in which such a roofing material 102 is formed by being laid on the roof base as in the case described above. At this time, as shown in FIG. 19, a case where a recessed portion formed on the upper surface of the roof material 102 is located below the pressing plate portion 38 is considered. That is, it is conceivable that a part that is depressed downward is located in a part of the pressing plate part 38 and a part that is not depressed downward is located in the other part of the pressing plate part 38. In this case, when a load is applied to the fixture 4, the pressing plate portion 38 may not be stabilized in a horizontal state.

  Therefore, as shown in FIG. 3 and the like, the main body portion 20 is provided with a spacer mounting hole 35 in the pressing plate portion 38. Then, as shown in FIG. 20, a spacer member 115 can be attached.

  When the spacer member 115 is attached, at least a part of the spacer member 115 is interposed between the pressing plate portion 38 and the roof material 102. Then, the lower part of the spacer member 115 attached integrally with the pressing plate part 38 and projecting downward from the lower surface of the pressing plate part 38 is in contact with the upper surface of the portion depressed below the roof material 102. Therefore, even when a load is applied to the pressing plate portion 38 from above, the pressing plate portion 38 does not wobble and is stable in a horizontal state. That is, the position of the portion of the pressing plate portion 38 that is located above the recessed portion of the roof material 102 is maintained by the spacer member 115.

  That is, the fixture 4 of the above-described embodiment can be mounted with high stability even when the roof material 102 having an uneven surface formed on the top surface of the roof material main body 110 and can be used preferably. It has become.

  In the above-described embodiment, a part of the pressing plate portion 38 is cut and raised to form the hook-shaped portion 36, but the present invention is not limited to this. The main body 120 having the hook-like portion 136 different from the hook-like portion 36 will be described in detail with reference to FIG. In addition, about the thing equivalent to the above-mentioned main-body part 20, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  The main body 120 is formed with a standing wall 139 that protrudes upward from the rear end portion of the pressing plate 138. A hook-shaped portion 136 is formed at the upper end portion of the standing wall portion 139.

  The hook-shaped portion 136 is a rectangular flat plate-like portion, and protrudes from the upper end portion of the standing wall portion 139 to the eaves side. The hook-shaped portion 136 is also provided in the vicinity of the center of the standing wall portion 139 in the width direction.

  Here, the standing wall portion 139 is formed by folding the rear end portion (eave side end portion) of the pressing plate portion 138 upward, and the hook-shaped portion 136 has a portion on the upper end side of the standing wall portion 139 in front (eave side). ). That is, these portions are formed by bending a metal plate punched into a predetermined shape.

That is, the shapes of the hook-shaped portions 36 and 136 formed in the main body portions 20 and 120 may be changed as appropriate, and the arrangement position, the number, and the like may be changed as appropriate. That is, only one hook-shaped portion 36, 136 may be formed, or a plurality of hook-shaped portions 36, 136 may be formed. For example, two hook-shaped portions 36 may be provided, and these may be arranged in parallel with a gap in the width direction of the pressing plate portion 38 (the left-right direction and the column direction).
Furthermore, the fixture of the solar cell module of the present invention is not limited to that of such an embodiment, and may include a main body 220 as described below.

  The hook-like portion 236 in the main body 220 is formed by making a cut in a substantially “U” shape in front view in the pressing plate portion 238 and raising a portion surrounded by the cut. That is, it is formed by cutting and raising a part of the pressing plate portion 238 and bending the tip portion into a hook shape.

In the above-described embodiment, the hook-shaped portion 36 is provided between the two spacer mounting holes 35. However, in the main body portion 220, the hook-shaped portion 236 is located behind (the ridge side) from the spacer mounting hole 235. ing.
That is, in the main body 220, as shown in FIG. 22B, two spacer mounting holes 235 and two fixing holes 237 are provided near the front end (near the eaves side) of the pressing plate 238. ing. The fixing hole 237 is a hole for inserting a fastening element when attached to the eaves portion, and has an opening diameter larger than that of the spacer attaching hole 235.

  The spacer mounting hole 235 and the fixing hole 237 are formed so as to be parallel to each other with an interval in the left-right direction (column direction). Specifically, the spacer mounting hole 235, the fixing hole 237, the fixing hole 237, and the spacer mounting hole 235 are arranged in parallel in this order from the one side end side to the other end side in the left-right direction. Is forming. A hook-shaped portion 236 is formed in the vicinity of the center in the width direction (left-right direction) of the pressing plate portion 238 behind the row of through holes (ridge side).

A protective member 270 is attached to the base plate portion 26 of the main body 220.
The protective member 270 has a substantially rectangular parallelepiped shape, is attached to the front end (eave side end) of the base plate portion 26, and extends in the width direction of the base plate portion 26. More specifically, the protection member 270 is in a state extending from one end portion to the other end portion in the width direction of the base plate portion 26. The protective member 270 is a foam sealing material having elasticity, and acts as a buffer material when the side portion of the solar cell module 5 is placed on the base plate portion 26.
More specifically, when the side portions of the solar cell module 5 are placed on the base plate portion 26, if these are in wide surface contact, the side portions of the solar cell module 5 may be rubbed and damaged. Therefore, the main body 220 has a structure in which the protective member 270 is attached to the upper surface of the base plate portion 26, and the protective member 270 is interposed between the solar cell module 5 and the base plate portion 26 when the solar cell module 5 is placed. Intervene. Thereby, the solar cell module 5 and the base plate part 26 are not in direct contact over a wide range, and damage to the solar cell module 5 can be prevented.

  Further, in the main body 220, a wiring fixing hole 245 is provided in the upper plate portion 225b of the front plate portion 225.

The wiring fixing holes 245 are through-holes penetrating the upper plate portion 225b in the thickness direction, and are provided one each in the vicinity of one end portion in the width direction of the front plate portion 225 and in the vicinity of the other end portion. ing.
The wiring fixing hole 245 is a through hole for fixing a binding tool for bundling wiring extending from the solar cell module 5 and a ground wire. Specifically, the wiring fixing hole 245 is a hole for attaching a binding tool or a ground wire via a fixing member (not shown), or directly inserting and fixing the binding tool or the ground wire. . That is, the wiring fixing hole 245 serves as a wiring fixing portion for directly or indirectly fixing the wiring continuous with the solar cell module 5.

  In above-mentioned embodiment, although the example which attached the holding | maintenance part 21 which hold | maintains the side part of the solar cell module 5 directly with respect to the main-body part 20 was shown, this invention is not limited to this. For example, as shown in FIG. 23, a holding portion 321 for fixing the rail-like mount 308 may be attached to the main body portion 320. That is, a fixture that indirectly holds the solar cell module 5 by interposing the rail mount 308 between the holding portion 321 and the solar cell module 5 may be used. The rail mount 308, the holding part 321 and the main body part 320 according to such an embodiment will be described in detail below.

  The rail-like mount 308 is the same as a known one, and is a long member for fixing the solar cell module 5.

In the main body 320, the position of the holder mounting hole 333 formed in the base plate 26 is a position different from the main body 20 described above. More specifically, one is provided in the vicinity of the center of the base plate part 26 in the front-rear direction (inter-beam direction), and in the vicinity of one side end part and the other side end part in the left-right direction (width direction and row direction). A holder attachment hole 333 is formed one by one. And this holder attachment hole 333 is a through-hole which penetrates the base-plate part 26 in thickness direction. That is, in the vicinity of the center of the base plate part 26 in the front-rear direction, two through-holes arranged in parallel with a space in the left-right direction are provided.
In addition, in the above-mentioned main-body part 20, it was set as the state attached to the holder attachment hole 33 in the state which loosened fastening elements, such as a screw. On the other hand, in the main body 320 of the present embodiment, the fastening element is not attached in advance to the holder attachment hole 333.

  The holding portion 321 is located between the rectangular plate-shaped attachment plate portion 350, the upright plate-shaped sandwiching plate portion 351 protruding upward from the attachment plate portion 350, and the two sandwiching plate portions 351, and connects them. A connecting plate portion 352.

  The attachment plate part 350 is in a state of being located at the lower end part of the holding part 321 and at both end parts in the left-right direction. That is, at the lower end portion of the holding portion 321, the two attachment plate portions 350 are arranged in parallel with a gap in the left-right direction. Each of the two attachment plate portions 350 is provided with attachment holes 355 (only one is shown and the other is not shown). The attachment hole 355 is a through hole that penetrates the attachment plate portion 350 in the thickness direction.

  Further, the sandwiching plate portion 351 protrudes upward from the inner end portion in the parallel direction of the two mounting plate portions 350. The two sandwiching plate portions 351 are opposed to each other with a predetermined interval in the left-right direction.

And this holding | maintenance part 321 can position the rail-shaped mount 308 between the two clamping board parts 351, and can hold | maintain the rail-shaped mount 308. FIG. And it becomes possible to fix the rail-shaped mount 308 on the roof by fixing the holding section 321 to the main body 320 fixed to the foundation roof structure 3 and fixing the rail-shaped mount 308 to the holding section 321. ing.
In addition, when fixing the holding | maintenance part 321 to the main-body part 320, the attachment hole 355 of the holding | maintenance part 321 and the holder attachment hole 333 of the main-body part 320 are piled up, and it is set as the state which penetrated the fastening element to these. . Thus, the main body 320 and the holding part 321 can be fixed integrally.

DESCRIPTION OF SYMBOLS 1 Roof structure 2 Roofing material 4 Attachment (Attachment of a solar cell module)
5 Solar cell module 11a Front end surface (eave side wall surface)
20, 120, 220, 320 Main body part 21 Holding part (holding member)
26 Base plate (holding member mounting part)
27 Rear leg (leg)
38, 138, 238 Pressing plate part (planar part)

Claims (6)

A roof structure in which a roofing material is laid and a solar cell module is further installed thereon via a fixture, the roofing material having an eave side surface, and the bottom side portion of the eave side surface is the other In the roof structure that is laid on the ridge side of the roof material of
The roof material has an eaves side wall surface portion formed on the surface toward the eave side on the basis of the installation state,
The fixture has a main body portion and a holding member fixed to the roof material,
The holding member holds a side portion of the solar cell module, or holds a member for fixing the solar power module,
The main body includes an eaves side mounting surface fixed to the eaves side wall surface part, a holding member mounting part that covers the roof material and to which a holding member is attached, and a leg part that contacts the upper surface side of the roof material. Have
The roof structure, wherein the eaves side mounting surface is fixed to the eaves side wall surface part via a fastening element.   The roof structure according to claim 1, wherein a lower end side of the eaves-side attachment surface fixed to the roof material is in contact with an upper surface of another roof material.   The main body portion is formed by bending a single metal plate, the leg portion has a planar portion in surface contact with the upper surface of the roof material, and the eave side attachment surface and the leg portion The roof structure according to claim 1 or 2, wherein the holding member mounting portion is provided therebetween, and a virtual plane that is flush with the planar portion intersects the eave side mounting surface substantially perpendicularly. . In the fixture for fixing the solar cell module to the roof material, which is interposed between the roof material having the eaves side wall surface portion on the surface facing the eaves side, and the solar cell module,
Having a main body and a holding member fixed to the roof material side;
The holding member holds a side portion of the solar cell module, or holds a member for fixing the solar power module,
The main body part is in contact with the eaves side wall surface part and is attached to the eaves side wall surface part via a fastening element, and the main body part is covered with a gap above the roof material and the holding member is fastened. A mounting member for a solar cell module, comprising: a holding member mounting portion for mounting via an element; and a leg portion in contact with an upper surface side of the roof material. A plurality of roofing materials having eaves side wall surfaces on the surface facing the eaves side are provided, and the solar cell module is attached to the roof on which the roofing materials are arranged in rows and steps and are mounted with a planar spread. Mounting structure,
The solar cell module fixture according to claim 4 is provided,
The solar cell module mounting structure, wherein the eaves side mounting surface is fixed to the eaves side wall surface part via a fastening element, whereby the solar cell module mounting fixture is fixed to the roof material. A solar cell module mounting method using the solar cell module mounting tool according to claim 4,
A method for mounting a solar cell module, comprising a step of fixing the eaves side mounting surface via a fastening element to an eaves side wall surface portion present on a surface facing the eave side of the roofing material.

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