JP6771201B2 - Solar power generator - Google Patents

Description

The present disclosure relates to a photovoltaic power generation device.

The photovoltaic power generation device is constructed by attaching a plurality of solar cell modules to the roof. For example, Patent Document 1 includes sunlight including an eaves-side engaging hook that engages with an eaves-side solar cell module and a ridge-side engaging hook that engages with a ridge-side solar cell module. The power generation device is disclosed. Such fixtures are fixed to the roof with screws.

Japanese Unexamined Patent Publication No. 2015-214877

By the way, in a photovoltaic power generation device, it is important that the solar cell module can be firmly fixed to the roof while ensuring good workability and maintainability. In terms of maintainability, it is required that only a part of the plurality of solar cell modules constituting the photovoltaic power generation device can be easily removed and replaced.

A photovoltaic device according to one aspect of the present disclosure includes a first solar cell panel, a first outer groove that opens toward the outside of the module, and a first frame installed at an end of the panel. It has a first solar cell module, a second solar cell panel, and a second frame including a second outer groove opened toward the outside of the module and installed at an end of the panel, and the first solar cell. The second solar cell module arranged adjacent to the ridge side of the module with a gap between the battery module and the first solar cell module fixed to the roof and installed at the ridge side end of the first solar cell module. A mounting bracket on which the first frame and the second frame installed at the eaves-side end of the second solar cell module are mounted, and a first engaging portion inserted into the first outer groove of the first frame. And a second engaging portion to be inserted into the second outer groove of the second frame, and a fixing bracket fixed to the mount bracket by using a bolt, and the fixing bracket has the gap. The first and second engaging portions can be inserted into the first and second outer grooves, respectively, by rotating inside, or the first engaging portion has the first engaging portion, and the said. It is composed of a first metal fitting that can be arranged in the gap and a second metal fitting that has the second engaging portion and can be arranged in the gap.

According to one aspect of the present disclosure, it is possible to provide a photovoltaic power generation device which has good workability and maintainability and can firmly fix the solar cell module to the roof.

It is an exploded perspective view of the solar power generation apparatus which is an example of an embodiment. It is sectional drawing of the solar cell module which is an example of embodiment. It is a top view of the mount metal fitting which is an example of embodiment. It is sectional drawing of AA line in FIG. It is a perspective view of the base metal fitting which is an example of an embodiment. It is a cross-sectional view in the horizontal direction which shows the state which attached the base metal fitting to the mount metal fitting. It is a perspective view of the fixing metal fitting which is an example of an embodiment. It is a vertical sectional view which shows the mounting structure of the photovoltaic power generation apparatus which is an example of embodiment. FIG. 8A is an enlarged view showing a part of FIG. 8A. It is a perspective view of the fixing metal fitting which is another example of embodiment. It is a vertical sectional view which shows the mounting structure of the photovoltaic power generation apparatus which is another example of embodiment. FIG. 10A is an enlarged view showing a part of FIG. 10A. It is a perspective view of the fixing metal fitting which is another example of embodiment. It is a vertical sectional view which shows the mounting structure of the photovoltaic power generation apparatus which is another example of embodiment. FIG. 12A is an enlarged view showing a part of FIG. 12A. It is a vertical sectional view which shows the mounting structure of the photovoltaic power generation apparatus which is another example of embodiment.

The photovoltaic power generation device according to one aspect of the present disclosure is arranged in a gap between a mounting bracket that supports two solar cell modules and each module, and is inserted into an outer groove of each module frame and fixed to the mounting bracket. It is provided with a fixing bracket to be used. According to such a configuration, the photovoltaic power generation device can be constructed by a simple method of mounting two solar cell modules on the mount metal fittings and attaching the fixing metal fittings to the gaps between the modules. Further, by removing the fixing bracket, for example, only one module out of a plurality of solar cell modules constituting the photovoltaic power generation device can be easily removed and replaced. Each solar cell module is firmly fixed on a mounting bracket screwed to the roof, and a photovoltaic power generation device having excellent load bearing capacity is constructed.

Hereinafter, an example of the embodiment will be described in detail with reference to the drawings. Since the drawings referred to in the embodiments are schematically described, the dimensions and the like of the components drawn in the drawings should be determined in consideration of the following description. In the present specification, the description of "abbreviated to" is intended to include not only the case where they are completely the same but also the case where they are recognized to be substantially the same, if substantially the same is explained as an example. The embodiments described below are examples, and the photovoltaic power generation device of the present disclosure is not limited thereto.

In the following, the direction of the mounting brackets, etc. along the roof eaves direction is defined as the "vertical direction", and the direction of the mounting brackets, etc. along the roof girder direction (direction perpendicular to the eaves building direction) is "horizontal (left and right)". And. The direction of the mounting bracket or the like along the direction perpendicular to the roof surface on which the mounting bracket is placed (when the mounting bracket is mounted on the roof material, the surface of the roofing material) is defined as the "vertical direction". In the drawing, the roof eaves direction / vertical direction is indicated by an arrow α, the girder direction / horizontal direction is indicated by an arrow β, and the vertical direction is indicated by an arrow γ. Unless otherwise specified, the upper end of the mounting bracket or the like means the upper end in the vertical direction.

FIG. 1 is an exploded perspective view of the photovoltaic power generation device 10 which is an example of the embodiment. As illustrated in FIG. 1, the photovoltaic cell module 10 includes a solar cell module 11A (first solar cell module), a solar cell module 11B (second solar cell module), a mounting bracket 30, and a fixing bracket 50. To be equipped with. The solar cell module 11A includes a solar cell panel 12A (first solar cell panel) and an outer groove 24A (see FIG. 8A described later) which is a first outer groove opened toward the outside of the module, and an edge of the panel. It has a frame 13A (first frame) installed in the unit. The solar cell module 11B includes a solar cell panel 12B (second solar cell panel) and an outer groove 24B (see FIG. 8A) which is a second outer groove open toward the outside of the module, and is located at an end of the panel. It has an installed frame 13B (second frame). The solar cell module 11B is arranged adjacent to the ridge side of the solar cell module 11A with a gap S (see FIG. 8A) between the solar cell module 11B and the solar cell module 11A.

The photovoltaic power generation device 10 is constructed by attaching a plurality of solar cell modules 11 (11A, 11B) to the roof 100. In this specification, for convenience of explanation, with respect to the two solar cell modules 11 arranged adjacent to each other in the eaves direction, the module arranged on the eaves side is the solar cell module 11A, and the module arranged on the building side is the sun. The battery module 11B. In this embodiment, it is assumed that all the solar cell modules 11 have the same shape.

As will be described in detail later, the mounting bracket 30 is fixed to the roof 100, and the frame 13A installed at the ridge side end of the solar cell module 11A and the frame 13B installed at the eaves side end of the solar cell module 11B are It is a metal fitting that can be placed. The fixing bracket 50 includes a first engaging portion 52 (see FIG. 8B and the like) inserted into the outer groove 24A of the frame 13A and a second engaging portion 53 (see FIG. 8B and the like) inserted into the outer groove 24B of the frame 13B. ), And is a metal fitting fixed to the mount metal fitting 30 by using a bolt 16. The fixing bracket 50 is configured so that the first engaging portion 52 and the second engaging portion 53 can be inserted into the outer grooves 24A and 24B, respectively, by rotating in the gap S.

The fixing metal fitting is composed of a first metal fitting having a first engaging portion and being able to be arranged in the gap S, and a second metal fitting having a second engaging portion and being able to be arranged in the gap S. It may be (see the photovoltaic power generation devices 10X and 10Y described later).

In the present embodiment, the ground metal fitting 15 is provided on the mount metal fitting 30, and the frames 13A and 13B are installed on the mount metal fitting 30 via the ground metal fitting 15. It is preferable that the photovoltaic power generation device 10 includes a base metal fitting 40 to which the bolt 16 is fastened, and the mount metal fitting 30 has a guide rail portion 34 that slidably supports the base metal fitting 40 toward the eaves. Then, the fixing metal fitting 50 is fixed to the mounting metal fitting 30 via the base metal fitting 40 inserted into the guide rail portion 34.

The photovoltaic power generation device 10 is attached to the roof 100 on which the roofing material 101 is laid. The roofing material 101 is, for example, a slate roof tile. Since the roofing material 101 is arranged in the direction of the eaves while overlapping the roofing material 101 on the ridge side with a part of the roofing material 101 on the eaves side, a step is formed in the portion where the roofing materials 101 overlap. The roof to which the photovoltaic power generation device 10 is attached is not limited to the roof 100.

The photovoltaic power generation device 10 is constructed by fixing the solar cell module 11 on a plurality of mounting brackets 30 arranged on the roof material 101. The mounting bracket 30 is placed on, for example, the roofing material 101 and the spacer 105, and is screwed to the field plate 102 (see FIG. 8A described later) of the roof 100. The spacer 105 is provided in a stepped portion formed between the roofing materials 101, and fills the stepped portion to enable stable mounting of the mounting bracket 30. By arranging the mounting bracket 30 directly on the roof material 101 and the spacer 105, the height of the solar cell module 11 from the roof surface (the surface of the roof material 101) can be lowered, and the roof 100 and the photovoltaic power generation device can be lowered. The sense of unity of 10 is improved.

As described above, the solar cell module 11 has a solar cell panel 12 and a frame 13. The solar cell panel 12 is, for example, a substantially flat panel in which a plurality of solar cells are sandwiched between two protective members. The frame 13 is formed by, for example, extruding a metal material containing aluminum as a main component, and is installed so as to surround the four sides of the solar cell panel 12. A coating film is generally formed on the surface of the frame 13.

The solar cell module 11 is fixed to the mount metal fitting 30 by using the frame 13 by using the base metal fitting 40, the fixing metal fitting 50, and the bolt 16. In the example shown in FIG. 1, a plurality of solar cell modules 11 are arranged so that the short side direction of the solar cell module 11 having a substantially rectangular shape in a plan view is substantially parallel to the eaves building direction. The solar cell modules 11 adjacent to each other in the girder direction are arranged in a substantially contacted state, and the solar cell modules 11 adjacent to each other in the eaves direction (solar cell modules 11A, 11B) are arranged with a gap S.

It is preferable that the solar cell module 11 is fixed to the mount metal fitting 30 at a total of four locations, two locations on the eaves side end and two locations on the ridge side end. On the back side of one solar cell module 11, for example, mount metal fittings 30 are arranged at positions corresponding to the left and right of the eaves side end of the module and positions corresponding to the left and right of the ridge side end. The frames 13A and 13B of the two solar cell modules are mounted on the mount metal fittings 30 arranged at the boundary between the solar cell modules 11A and 11B.

The eaves-side end and the ridge-side end of the photovoltaic power generation device 10 may be fixed to the roof 100 by using the mount metal fitting 30, the base metal fitting 40, and the fixing metal fitting 50, or are fixed by using a special metal fitting. May be good.

In the example shown in FIG. 1, a plurality of mounting brackets 30 are arranged side by side in the eaves building direction and the girder direction. The mounting brackets 30 arranged in the eaves building direction are arranged at regular intervals in the eaves building direction according to the length of each solar cell module 11 along the eaves building direction. Each mounting bracket 30 is fixed to the roof 100 so that the guide rail portion 34 is along the eaves building direction. The frames 13A and 13B are mounted on the mounting bracket 30 so as to be substantially orthogonal to the guide rail portion 34.

FIG. 2 is a cross-sectional view of an end portion of the solar cell module 11. As illustrated in FIG. 2, the frame 13 installed at the end of the solar cell panel 12 has a main body portion 20 having a hollow prismatic shape, an inner groove 22 opening toward the inside of the module, and the outside of the module. It has an outer groove 24 that opens toward. Further, the frame 13 has an inner flange portion 25 overhanging inside the module. The main body 20, the outer groove 24, and the inner flange 25 are located on the back side of the solar cell panel 12, and in particular, the outer groove 24 and the inner flange 25 are used for fixing the solar cell module 11 to the mounting bracket 30. ..

The frame 13 has a hook portion 21 erected on the upper surface of the main body portion 20, and an inner groove 22 which is a gap into which the solar cell panel 12 can be inserted is formed between the upper surface of the main body portion 20 and the hook portion 21. To. The hook portion 21 extends straight upward from the outside of the main body portion 20 and is bent inward in the middle to form a substantially L-shaped cross section. That is, the hook portion 21 covers the side surface of the solar cell panel 12 along the vertical direction and projects on the light receiving surface of the solar cell panel 12. The length of the portion of the hook portion 21 overhanging the light receiving surface is substantially the same as the width of the main body portion 20, for example. The frame 13 is provided with a bottom plate 23 extending on the opposite side (outside) of the inner flange portion 25, and an outer groove 24 is formed between the lower surface of the main body portion 20 and the bottom plate 23. The bottom plate 23 forms the bottom surface of the frame 13 together with the inner flange portion 25.

FIG. 3 is a plan view of the mounting bracket 30, and FIG. 4 is a sectional view taken along line AA in FIG. As illustrated in FIGS. 3 and 4, the mount metal fitting 30 has a base portion 31 on which the base metal fitting 40 is placed, and a flange portion 32 protruding from the lower portion of the base portion 31 to the left and right. The mount metal fitting 30 is a plate-shaped fixing portion arranged along the roof surface, and has a fixing portion formed with a through hole through which a screw for fixing the metal fitting to the roof 100 is passed. The through hole is preferably formed at a position separated from the end of the fixed portion by 10 mm or more. In this embodiment, a flange portion 32 is provided as a fixing portion.

The mount metal fitting 30 has a vertically long shape along the eaves building direction. The ridge side edge portion 30b of the mount metal fitting 30 is preferably inclined with respect to the eaves building direction and the girder direction of the roof 100. Since the guide rail portion 34 preferably extends straight along the eaves building direction, the ridge side edge portion 30b is inclined by forming the cut surface of the ridge side edge portion 30b diagonally with respect to the vertical direction and the horizontal direction. It is preferable to let it. In this case, the drainage property of rainwater or the like can be improved without impairing the workability. That is, rainwater or the like is not blocked by the mount fitting 30, and flows along the inclined ridge side edge 30b.

It is preferable that the eaves side edge portion 30a of the mount metal fitting 30 is inclined at substantially the same angle as the ridge side edge portion 30b with respect to the eaves building direction and the girder direction of the roof 100. That is, it is preferable that the eaves side edge portion 30a is formed substantially parallel to the ridge side edge portion 30b. The inclination of the eaves side edge 30a does not affect the drainage property, but in general, since the mounting bracket 30 is manufactured by cutting a long member, each end is cut in the same direction and at the same angle. By doing so, waste of materials can be eliminated. In addition, marks such as V-grooves and engravings used for marking in the direction of the eaves may be formed on the mount metal fitting 30. The mark is formed in the center of the upper surface of the upper wall portion 31a in the vicinity of the eaves side edge portion 30a, for example.

It is preferable that the ridge side edge portion 30b of the mounting bracket 30 is inclined at an angle θ of about 3 ° to 15 ° with respect to the girder direction of the roof 100. When the angle θ is within the range, it becomes easy to achieve both good workability and drainage. The eaves side edge portion 30a is also preferably inclined at an angle θ of about 3 ° to 15 ° with respect to the girder direction. The mount metal fitting 30 has, for example, a substantially parallel quadrilateral shape in a plan view having substantially the same diagonal size.

The base portion 31 has an upper wall portion 31a on which the base metal fitting 40 is placed, and a side wall portion 31b extending downward from both ends in the lateral direction of the upper wall portion 31a and connecting the upper wall portion 31a and the flange portion 32. In the base portion 31, for example, each side wall portion 31b is formed substantially perpendicular to the upper wall portion 31a. A recess 31c recessed downward over the entire length in the vertical direction is formed in the central portion in the horizontal direction of the upper wall portion 31a. By providing the recess 31c, it is possible to prevent the tip of the shaft portion of the bolt 16 fixed to the base metal fitting 40 from interfering with the upper wall portion 31a.

A hook portion 33 is formed on the base portion 31. A pair of hooks 33 are erected on both ends of the upper wall portion 31a in the lateral direction of the mount metal fitting 30. The hook portion 33 extends straight upward from both ends in the lateral direction of the upper wall portion 31a, and is bent inward in the middle to form a substantially L-shaped cross section. The upper wall portion 31a and the hook portion 33 form a guide rail portion 34 that slidably supports the base metal fitting 40 in the vertical direction.

The upper wall portion 31a of the base portion 31 is formed at a position higher than the flange portion 32 in contact with the roof surface in a portion other than the recess 31c. Therefore, a space is provided under the upper wall portion 31a with the roof surface. It is preferable that the mount metal fitting 30 has a drainage groove 37 formed so as to provide a space between the mount metal fitting 30 and the roof surface over the entire length in the vertical direction along the eaves building direction. Drainage grooves 37 are formed on the left and right sides of the recess 31c in the mount metal fitting 30. By providing the drainage ditch 37, the drainage property of the roof 100 at the installation location of the photovoltaic power generation device 10 is further improved.

The flange portion 32 projects outward from the lower portion of the base portion 31 and is formed over the entire length of the mounting bracket 30 in the vertical direction. The flange portion 32 preferably extends to the inside of the base portion 31, that is, below the upper wall portion 31a. The lateral length of the portion extending inward of the base portion 31 may be shorter than the lateral length of the hook portion 33. Each side wall portion 31b of the base portion 31 is formed, for example, substantially perpendicular to the flange portion 32. A plurality of through holes 35 through which screws 107 (see FIG. 8A described later) are passed are formed in each flange portion 32 side by side in the eaves direction.

As described above, the through hole 35 is preferably formed at a position separated from the end of the flange portion 32 by 10 mm or more. By forming the through hole 35 away from the end of the flange portion 32, rainwater or the like is less likely to enter the portion to which the screw 107 is attached. The through hole 35 is separated from, for example, the outer end 32a, which is the outer end of the flange portion 32 along the vertical direction, and both ends of the flange portion 32 in the vertical direction (eave side edge portion 30a and ridge side edge portion 30b) by 10 mm or more. It is formed at the position. Further, it is preferable that the through hole 35 is formed at a position which is an inner end of the flange portion 32 along the vertical direction and is separated from the inner end 32b in contact with the drainage groove 37 by 10 mm or more. The through hole 35 is formed at positions substantially equidistant from, for example, the outer end 32a and the inner end 32b.

The mounting bracket 30 may be formed with a binding band hole 36 through which a binding band (not shown) for fixing the wiring drawn from each solar cell module 11 is passed. In the example shown in FIG. 3, a total of four binding band holes 36 are formed at both ends of the upper wall portion 31a in the vertical direction. For example, the wiring extending in the girder direction of the roof 100 is fixed to the eaves-side end or the ridge-side end of the mounting bracket 30 by using the binding band passed through the binding band hole 36.

The mounting bracket 30 may be provided with an alignment mark 38 used at the time of construction. In the example shown in FIG. 3, a linear alignment mark 38 extending laterally from the outer end 32a is formed on the upper surface of each flange portion 32. The alignment marks 38 formed on the left and right flange portions 32 are arranged side by side and formed on the same straight line. The mounting bracket 30 is arranged on the roof 100, for example, so that the alignment mark 38 coincides with the eaves side edge of the roofing material 101.

FIG. 5 is a perspective view of the base metal fitting 40, and FIG. 6 is a horizontal sectional view showing a state in which the base metal fitting 40 is attached to the mount metal fitting 30. As illustrated in FIGS. 5 and 6, the base metal fitting 40 has a base portion 41 to which a bolt 16 for fixing the fixing metal fitting 50 is fastened and an extension portion 42 inserted into the guide rail portion 34 of the mounting metal fitting 30. Have. The base portion 41 has a width that can be arranged between the hook portions 33 of the mount metal fittings 30, and is formed long in the vertical direction along the eaves building direction.

The extending portion 42 projects from the left and right sides of the base 41. When the extension portion 42 is inserted into the guide rail portion 34, the base metal fitting 40 engages with the mount metal fitting 30 and the base metal fitting 40 cannot be pulled out upward. The extending portion 42 is slightly bent upward at the root, and the upper surface thereof is located slightly above the upper surface of the base portion 41. The upper surface of the extending portion 42 is substantially flat. For example, when the bolt 16 is fastened to the base portion 41, it comes into contact with the lower surface of the hook portion 33 forming the guide rail portion 34, and the base metal fitting 40 is in contact with the mounting metal fitting 30. Is firmly fixed. On the other hand, the base metal fitting 40 can be slid along the guide rail portion 34 until the bolt 16 is fastened.

The base metal fitting 40 may have an engaging portion 43 and a ridge-side standing wall portion 44. As described above, the frames 13A and 13B have inner flange portions 25A and 25B overhanging inside the solar cell modules 11A and 11B on the back side of the solar cell modules 11A and 11B, respectively. As illustrated in FIG. 8 described later, the engaging portion 43 projects upward from the upper end of the mounting bracket 30 and engages with the inner flange portion 25A (first inner flange portion) of the frame 13A. The ridge-side standing wall portion 44 projects upward from the upper end of the mounting bracket 30 and is arranged so as to face the tip of the inner flange portion 25B (second inner flange portion) of the frame 13B.

The engaging portion 43 is formed in a substantially L-shaped cross section at the eaves side end portion (one end portion in the vertical direction) of the base portion 41 with a gap between the base portion 41 and the inner flange portion 25A into which the inner flange portion 25A can be inserted. The ridge-side standing wall portion 44 is formed at a height that does not interfere with the installation of the frame 13B and at a position facing the tip of the inner flange portion 25B. The ridge-side standing wall portion 44 is formed, for example, by bending a part of the metal plate constituting the base portion 41 upward between the ridge-side end portion (the other end portion in the vertical direction) of the base portion 41 and the central portion in the vertical direction. Therefore, an opening 48 is formed on the eaves side of the ridge side standing wall portion 44 so as to enable the bending.

It is preferable that the base metal fitting 40 is formed with a bolt fastening portion 46 into which the bolt 16 is screwed and a temporary fixing bolt fastening portion 47 into which the temporary fixing bolt 17 (see FIG. 8A described later) is screwed. The bolt fastening portion 46 is formed between the engaging portion 43 of the base portion 41 and the ridge side standing wall portion 44, and is formed in a portion that overlaps the recess 31c of the mounting bracket 30 in the vertical direction. The temporary fixing bolt fastening portion 47 is formed on the ridge side portion of the base 41 with respect to the ridge side standing wall portion 44. Each bolt fastening portion is formed, for example, by burring and screwing a metal plate constituting the base 41.

FIG. 7 is a perspective view of the fixing bracket 50. As illustrated in FIG. 7, the fixing bracket 50 includes a base 51 having a through hole 55 through which the bolt 16 is passed, a first engaging portion 52 extending from the base 51 to the eaves side, and a base 51 to the ridge side. It has a second engaging portion 53 extending to. The first engaging portion 52 is a portion to be inserted into the outer groove 24A of the frame 13A, and the second engaging portion 53 is a portion to be inserted into the outer groove 24B of the frame 13B. The fixing metal fitting 50 is a metal fitting in which the first engaging portion 52 and the second engaging portion 53 are connected by a base portion 51, and each engaging portion is integrated.

The fixing metal fitting 50 is a metal fitting having a substantially parallel quadrilateral shape in a plan view, which is elongated in the direction in which the base portion 51 and each engaging portion are aligned. The plan view shape of the fixing bracket 50 is not particularly limited, but it is preferably a parallel quadrilateral shape excluding a rectangle. The eaves-side edge 50a and the ridge-side edge 50b of the fixing bracket 50, that is, the eaves-side edge of the first engaging portion 52 and the ridge-side edge of the second engaging portion 53 are substantially parallel to each other and are parallel to each other. Form the short side of a quadrilateral. The two obtuse-angled corners of the parallelogram are formed at an angle of, for example, 120 °. The two acute-angled corners may be chamfered. The plan view shape of the fixing bracket 50 may be another parallel polygonal shape such as a parallel hexagon.

When the fixing bracket 50 has a substantially parallel four-sided shape in a plan view, the length (long side length) of the fixing bracket 50 is, for example, equal to or larger than the width of the gap S and the frame from the innermost part of the outer groove 24A of the frame 13A. It is less than or equal to the length to the innermost part of the outer groove 24B of 13B. The fixing bracket 50 may have a length such that the eaves side edge portion 50a and the ridge side edge portion 50b forming the short side of the parallelogram abut on the innermost portions of the outer grooves 24A and 24B, respectively. Further, the width (length of the short side) of the fixing bracket 50 is set so that each engaging portion completely comes out of the outer grooves 24A and 24B when the fixing bracket 50 is rotated so that the long side faces in the lateral direction. It is preferably less than the width of the gap S. The thickness of the fixing bracket 50 may be any thickness that can be inserted into the outer grooves 24A and 24B.

The fixing bracket 50 is slightly bent upward at the boundary between the base 51 and the first engaging portion 52, and the lower surface of the first engaging portion 52 is located slightly above the lower surface of the base 51. As illustrated in FIG. 8 to be described later, the tip of the bottom plate 23A of the frame 13A slightly rises from the top of the mount metal fitting 30 due to the inclination of the roof surface. Therefore, by forming a step at the boundary between the base portion 51 and the first engaging portion 52, the fixing bracket 50 can be easily attached to the frames 13A and 13B.

Even if the fixing bracket 50 is slightly curved or bent so that the first engaging portion 52 and the second engaging portion 53 gently lower toward the tips (eave side edge portion 50a and ridge side edge portion 50b). Good. In the example shown in FIG. 7, there is no step at the boundary between the base 51 and the second engaging portion 53, but a step may be formed at the boundary.

The base 51 is a portion to which the bolt 16 is attached and has a substantially circular through hole 55. The through hole 55 is formed, for example, around the intersection of the diagonal lines of the fixing bracket 50 having a substantially parallel quadrilateral shape in a plan view. Two instrument insertion holes 56 may be formed in the base 51. Each instrument insertion hole 56 is a hole smaller than the through hole 55 and is formed with the through hole 55 interposed therebetween. The through hole 55 and each instrument insertion hole 56 are located, for example, on substantially the same straight line. The fixing bracket 50 can rotate in the gap S. For example, during the rotation operation, a bifurcated instrument (not shown) is inserted into the instrument insertion hole 56 to rotate the fixing bracket 50 around the bolt 16. be able to.

The first engaging portion 52 extends from the eaves-side end of the base 51 to the eaves side, and the second engaging portion 53 extends from the ridge-side end of the base 51 to the ridge side. It is preferable that each engaging portion has a protrusion 54 projecting downward. The protrusions 54 are formed at both ends in the lateral direction of each engaging portion. The protrusion 54 is formed by pressing, for example, a metal plate constituting each engaging portion from the upper surface side.

8A and 8B are vertical cross-sectional views showing the mounting structure of the photovoltaic power generation device 10, and the ridge-side end of the solar cell module 11A and the ridge side end of the solar cell module 11A are used by using the mounting bracket 30, the base bracket 40, and the fixing bracket 50. The structure which fixes the eaves side end part of the solar cell module 11B to the roof 100 is shown.

As illustrated in FIGS. 8A and 8B, a frame 13A installed at the ridge side end of the solar cell module 11A and an eaves side end of the solar cell module 11B are placed on the mount metal fitting 30 via the ground metal fitting 15. The frame 13B installed in the above is mounted. Then, the fixing metal fitting 50 in which the first engaging portion 52 is inserted into the outer groove 24A of the frame 13A and the second engaging portion 53 is inserted into the outer groove 24B of the frame 13B attaches the bolt 16 to the base metal fitting 40. It is fastened using. For the bolt 16, for example, a bolt having a wrench hole into which a hexagon wrench can be inserted into the head is used.

The mounting bracket 30 is fixed to the field plate 102 of the roof 100 by a screw 107 attached to the flange portion 32 which is a plate-shaped fixing portion. In the example shown in FIG. 8, the mounting bracket 30 is arranged so that the alignment mark 38 and the eaves side edge of the roofing material 101 coincide with each other, and the ridge side portion of the mounting bracket 30 is on the roofing material 101 and the eaves side portion. Is fixed on the spacer 105. Some of the screws 107 are passed through the through holes 35 of the flange portion 32 and the through holes 106 of the spacer 105, penetrate the roofing material 101, and are fixed to the field plate 102. For the screw 107, for example, a wood screw with packing is used. A rubber sheet 103 (for example, a butyl rubber sheet) is provided between the mounting metal fitting 30, the roofing material 101, and the spacer 105.

The solar cell modules 11A and 11B are fixed on the mounting bracket 30 so that the solar cell panels 12A and 12B are substantially parallel to the field plate 102 of the roof 100. Since the roof surface, which is the surface of the roofing material 101, is not parallel to the field plate 102, the upper end (upper surface of the hook portion 33) of the mounting bracket 30 on which the frames 13A and 13B are mounted is also not parallel to the field plate 102. Therefore, the tip of the bottom plate 23A of the frame 13A rises slightly from above the mounting bracket 30, and the heights of the outer grooves 24A and 24B from the upper end of the mounting bracket 30 are slightly higher in the outer groove 24A. Therefore, the above-mentioned step is formed at the boundary between the base 51 of the fixing bracket 50 and the first engaging portion 52. Further, the heights of the hook portions 21A and 21B are also slightly higher in the hook portions 21A.

The base metal fitting 40 is inserted into the guide rail portion 34 (see FIG. 4 and the like) of the mount metal fitting 30. As described above, the guide rail portion 34 is formed over the entire length in the vertical direction along the eaves direction of the mount metal fitting 30. Therefore, the base metal fitting 40 can be slid toward the eaves building within a range that does not protrude from the mount metal fitting 30 until the frames 13A and 13B are placed on the mount metal fitting 30 and the bolts 16 are fastened. The frames 13A and 13B are placed on the portion of the mount metal fitting 30 to which the base metal fitting 40 is attached, but since the base metal fitting 40 is slidable as described above, the degree of freedom in arranging the frames 13A and 13B is high and workability is high. Excellent for.

The base metal fitting 40 can be temporarily fixed by using temporary fixing bolts 17 so as not to move toward the eaves when arranging the frames 13A and 13B. The temporary fixing bolt 17 is screwed into the temporary fixing bolt fastening portion 47 formed on the base 41 of the base metal fitting 40, and the tip of the shaft portion is pressed against the upper wall portion 31a of the mounting metal fitting 30, so that the purpose of the mounting metal fitting 30 is Temporarily fix the base metal fitting 40 at the position to be. The position of the base metal fitting 40 can be easily adjusted by loosening the temporary fixing bolt 17.

The frame 13A is placed on the hook portion 33 of the mount fitting 30 via the ground fitting 15, and is arranged on the eaves side of the position corresponding to the bolt fastening portion 46 of the base fitting 40. The ground fitting 15 has a protrusion protruding upward and a through hole through which a bolt 16 and a spacer 90 described later are passed. The protrusion of the grounding metal fitting 15 breaks through the coating film formed on the surface of the frame 13A and bites into the bottom surface of the frame 13A to be grounded. The protrusion of the ground fitting 15 also bites into the bottom surface of the frame 13B in the same manner.

An engaging portion 43 of the base metal fitting 40 is erected on the eaves side of the frame 13A, and the engaging portion 43 projects and engages on the inner flange portion 25A of the frame 13A. In other words, the inner flange portion 25A is inserted between the base portion 41 and the engaging portion 43 of the base metal fitting 40. The inner flange portion 25A is pressed from above by the engaging portion 43, for example, when a negative pressure acts on the solar cell module 11A.

The frame 13B is placed on the hook portion 33 of the mount fitting 30 via the ground fitting 15, and is arranged closer to the ridge than the position corresponding to the bolt fastening portion 46 of the base fitting 40. That is, the frame 13B is arranged with a gap S through which the bolt 16 is passed from the frame 13A. Since the ridge-side vertical wall portion 44 is provided on the ridge side of the frame 13B at a position facing the tip of the inner flange portion 25B, the solar cell module 11B is prevented from moving to the ridge side.

The fixing bracket 50 is attached across the frames 13A and 13B by inserting the first engaging portion 52 into the outer groove 24A of the frame 13A and the second engaging portion 53 into the outer groove 24B of the frame 13B. ing. The bolt 16 for fixing the fixing metal fitting 50 is passed through the through hole 55 of the base portion 51 and screwed into the bolt fastening portion 46 of the base metal fitting 40. When the bolt 16 fastened to the base metal fitting 40 presses the base 51 from above, the protrusions 54 (see FIG. 7) of the engaging portions inserted into the outer grooves 24A and 24B are formed on the upper surfaces of the bottom plates 23A and 23B. It is in strong contact.

The fixing bracket 50 is configured to be rotatable at the lower part of the gap S. The fixing bracket 50 is bolted to the base bracket 40 to a degree that it can rotate, and then rotates about the central axis of the bolt 16. Specifically, with the solar cell module 11A arranged on the eaves side of the bolt 16, the first engaging portion 52 is inserted into the outer groove 24A by rotating the fixing bracket 50 using the above-mentioned bifurcated device. Can be included. Then, by arranging the solar cell module 11B on the ridge side of the bolt 16 and inserting the second engaging portion 53 into the outer groove 24B, the fixing bracket 50 is attached across the frames 13A and 13B. The bolt 16 is fastened to the base metal fitting 40 after, for example, the second engaging portion 53 is inserted into the outer groove 24B.

The fixing bracket 50 in which each engaging portion is inserted into the outer grooves 24A and 24B is rotated around the central axis of the bolt 16 to pull out each engaging portion from the outer grooves 24A and 24B and the fixing bracket 50. Can be removed from the frames 13A and 13B. Specifically, by loosening the bolt 16 and rotating the fixing bracket 50 so that the width direction of the fixing bracket 50 is along the lateral direction, each engaging portion can be pulled out from the outer grooves 24A and 24B. That is, in the mounting structure of the photovoltaic power generation device 10, each engaging portion can be inserted and removed from the outer grooves 24A and 24B of the frames 13A and 13B by rotating the fixing bracket 50 around the bolt 16.

When the fixing bracket 50 has a parallel polygonal shape in a plan view, preferably a substantially parallel quadrilateral shape, the end surface of the eaves side edge portion (eave side edge portion 50a) of the first engaging portion 52 inserted into the outer groove 24A is It may be substantially in contact with the outer groove 24A along the innermost portion. Further, the end surface of the ridge-side edge portion (ridge-side edge portion 50b) of the second engaging portion 53 inserted into the outer groove 24B may be substantially in contact with the innermost portion of the outer groove 24B. The frames 13A and 13B can be pressed by inserting the engaging portions all the way into the outer grooves 24A and 24B. If the plan view shape of the fixing bracket 50 is a substantially parallel four-sided shape excluding a rectangle, even if the end faces of the engaging portions are attached in a state of being in contact with the innermost portions of the outer grooves 24A and 24B, the width direction ( The fixing bracket 50 can be rotated so that the long side) is along the lateral direction.

That is, the fixing metal fitting 50 is a metal fitting having a substantially parallel polygonal shape in a plan view that rotates in the gap S, and the first end surface of the first engaging portion 52 substantially abuts along the innermost portion of the outer groove 24A. Moreover, it is preferable that the second end surface of the second engaging portion 53 is substantially in contact with the innermost portion of the outer groove 24B. In the present embodiment, the first end surface of the first engaging portion 52 is the end surface of the eaves side edge portion 50a forming one short side of the parallelogram. The second end surface of the second engaging portion 53 is an end surface of the ridge side edge portion 50b forming the other short side of the parallelogram, which is substantially parallel to the first end surface.

A spacer 90 that supports the base 51 of the fixing bracket 50 may be provided between the fixing bracket 50 and the base bracket 40. The spacer 90 is, for example, a tubular body through which the bolt 16 is passed, and is arranged on the base metal fitting 40 so that the hole of the cylinder, the through hole 55, and the bolt fastening portion 46 are aligned with each other. In the example shown in FIG. 8, the tips of the bottom plates 23A and 23B of the frames 13A and 13B project upward from the upper end of the mounting bracket 30 and substantially contact the upper end of the spacer 90 inserted into the gap S. There is.

In the above mounting structure of the photovoltaic power generation device 10, the bolt 16 is screwed into the bolt fastening portion 46 of the base metal fitting 40 so that the fixing metal fitting 50 strongly abuts on the bottom plates 23A and 23B of the frames 13A and 13B and the base. The metal fitting 40 is firmly fixed to the mount metal fitting 30. When the bolt 16 is screwed into the bolt fastening portion 46, the base metal fitting 40 is lifted upward, and the extension portion 42 inserted into the guide rail portion 34 is in a state of being strongly in contact with the hook portion 33.

The photovoltaic power generation device 10 has a cover 80 arranged on the gap S straddling the frame 13A and the frame 13B, and is inserted into the outer groove 24A of the frame 13A and fixed to the frame 13A, and the cover 80 is screwed. It may be provided with a support metal fitting 85 to be stopped. The cover 80 has substantially the same length as the long side of the solar cell module 11, for example, and covers the entire gap S. The cover 80 has a base 81 that is attached from the frame 13A to the frame 13B and covers the gap S, and two legs 82 that extend downward from the base 81 and are inserted into the gap S. Each leg 82 is formed, for example, parallel to each other.

In the cover 80, the eaves side portion of the base 81 is arranged on the hook portion 21A of the frame 13A, and the ridge side portion of the base 81 is arranged on the hook portion 21B of the frame 13B. The leg 82 on the eave side is in contact with the side surface of the frame 13A along the vertical direction, and the leg 82 on the ridge side is in contact with the side surface of the frame 13B along the vertical direction. As described above, the heights of the hooks 21A and 21B from the upper end of the mounting bracket 30 are slightly higher in the hooks 21A. Therefore, for example, the eaves side portion of the base 81 is located slightly above the ridge side portion. It is tilted to do. Further, since the upper surfaces of the tips of the hooks 21A and 21B are inclined downward toward the tip, the tip of the base 81 is also slightly bent downward according to the shape of the hook.

The support metal fitting 85 is arranged in the gap S between the frames 13A and 13B, and the upper portion of the support metal fitting 85 is in contact with the back surface of the base portion 81. The cover 80 is fixed to the upper part of the support metal fitting 85 by using a screw 86 penetrating the central portion in the width direction of the base portion 81.

The support metal fitting 85 preferably has a claw portion 88 to be inserted into the outer groove 24A of the frame 13A. The claw portion 88 is formed by, for example, bending the lower portion of the support metal fitting 85 to the side opposite to the upper portion (eave side). The support metal fitting 85 extends downward along the main body 20A of the frame 13A and is fixed to the main body 20A by using screws 87, and is fixed to the frame 13A by inserting the claw portion 88 into the outer groove 24A. ing. For the screws 86 and 87, for example, drill screws are used.

As described above, although the photovoltaic power generation device 10 is easy to construct, each solar cell module 11 can be firmly fixed to the roof 100 and has excellent load bearing capacity. In the photovoltaic power generation device 10, for example, by loosening the bolt 16 for fixing the target solar cell module 11 and rotating the fixing bracket 50, each engaging portion is pulled out from the outer grooves 24A and 24B, and the fixing bracket 50 is removed from the frame 13A. , 13B can be removed.

That is, even if the solar cell module 11 is not located at the end of the photovoltaic cell generator 10, only one target solar cell module 11 can be easily removed and replaced without removing the surrounding solar cell modules 11. It is possible. As described above, the photovoltaic power generation device 10 is also excellent in maintainability.

Next, the solar power generation device 10X, which is another example of the embodiment, will be described in detail with reference to FIGS. 9 and 10A and 10B. In the following, the same reference numerals are used for the components common to the above-mentioned photovoltaic power generation device 10, and duplicate description will be omitted. The photovoltaic power generation device 10X (see FIG. 10A) is different from the photovoltaic power generation device 10 in that the fixing bracket 60 (see FIG. 9) is used instead of the fixing bracket 50. Further, no spacer is provided between the fixing metal fitting 60 and the base metal fitting 40. The photovoltaic power generation device 10X is in common with the photovoltaic power generation device 10 in other respects.

FIG. 9 is a perspective view of the fixing bracket 60. As illustrated in FIG. 9, the fixing metal fitting 60 is composed of a first metal fitting 61A and a second metal fitting 61B. The first metal fitting 61A has a first base portion 62A in which a through hole 65A (first through hole) through which a bolt 16 is passed is formed, and a first engaging portion 63A. The second metal fitting 61B has a second base portion 62B which is arranged so as to overlap with the first base portion 62A and has a through hole 65B (second through hole) through which the bolt 16 is passed, and a second engaging portion 63B. The first engaging portion 63A is a portion to be inserted into the outer groove 24A of the frame 13A. The second engaging portion 63B is a portion to be inserted into the outer groove 24B of the frame 13B.

In the fixing metal fitting 60, the first engaging portion 63A of the first base portion 62A is attached on the first base portion 62A of the first metal fitting 61A. In the first metal fitting 61A, a step is formed by bending the boundary portion between the first base portion 62A and the first engaging portion 63A upward. On the other hand, the second metal fitting 61B does not have a large step like the first metal fitting 61A, but may be slightly bent upward at the boundary between the second base portion 62B and the second engaging portion 63B. The thickness of the fixing bracket 60 may be any thickness that can be inserted into the outer grooves 24A and 24B.

The first metal fitting 61A is a metal fitting having a substantially rectangular shape in a plan view that is long in the lateral direction. The lateral length of the first metal fitting 61A is not particularly limited, but an example of a suitable length is longer than the distance between the hooks 33 of the mount metal fitting 30 and shorter than the lateral length of the mount metal fitting 30. As shown in FIG. 10 described later, the first metal fitting 61A is arranged on the hook portion 33 via the ground metal fitting 15. The vertical length of the first metal fitting 61A is shorter than the sum of the depth length of the outer groove 24A and the width of the gap S.

A through hole 65A is formed in the lateral central portion of the first base portion 62A. The through hole 65A is, for example, an elongated hole long in the vertical direction. The step at the boundary between the first base portion 62A and the first engaging portion 63A is formed to be slightly higher than the height corresponding to the thickness of the bottom plate 23A, for example, in consideration of the lifting of the bottom plate 23A of the frame 13A due to the inclination of the roof surface. To. Further, the first metal fitting 61A may be slightly curved or bent so that the first base portion 62A and the first engaging portion 63A gently lower toward the respective tips.

The first engaging portion 63A extends from the eaves side end portion of the first base portion 62A to the eaves side. The first engaging portion 63A preferably has a protrusion 64A (first protrusion) protruding downward. The protrusions 64A are formed at both ends in the lateral direction of the first engaging portion 63A.

The second metal fitting 61B is a metal fitting having a substantially rectangular shape in a plan view that is long in the lateral direction. The lateral length of the first metal fitting 61A is substantially the same as, for example, the lateral length of the first metal fitting 61A. The vertical length of the second metal fitting 61B is shorter than the sum of the depth length of the outer groove 24B and the width of the gap S. Similar to the first metal fitting 61A, a long through hole 65B in the vertical direction is formed in the central portion in the horizontal direction of the second base portion 62B. The second metal fitting 61B may be slightly curved or bent so that the second base portion 62B and the second engaging portion 63B gently lower toward the respective tips.

The second engaging portion 63B extends from the ridge-side end of the second base 62B to the ridge side. The second engaging portion 63B preferably has a protrusion 64B (second protrusion) that projects downward. The protrusions 64B are formed at both ends in the lateral direction of the second engaging portion 63B.

10A and 10B are vertical sectional views showing a mounting structure of the photovoltaic power generation device 10X. In FIGS. A and B10, the ridge-side end of the solar cell module 11A and the eaves of the solar cell module 11B are used by using the first metal fitting 61A and the second metal fitting 61B constituting the mounting metal fitting 30, the base metal fitting 40, and the fixing metal fitting 60. The structure which fixes the side end part to the roof 100 is shown.

As illustrated in FIGS. 10A and 10B, the first engaging portion 63A of the first metal fitting 61A is formed in the outer groove 24A of the frame 13A of the solar cell module 11A mounted on the mounting metal fitting 30 via the grounding metal fitting 15. It is inserted. Further, the second engaging portion 63B of the second metal fitting 61B is inserted into the outer groove 24B of the frame 13B of the solar cell module 11B. Then, the first metal fitting 61A and the second metal fitting 61B are fastened to the base metal fitting 40 engaged with the mount metal fitting 30 by using the bolt 16.

The first metal fitting 61A and the second metal fitting 61B are mounted so that the second base portion 62B is overlapped on the first base portion 62A so that the through holes 65A and 65B through which the bolt 16 is passed are aligned at the lower part of the gap S. The bolt 16 is passed through the through holes 65A and 65B and screwed into the bolt fastening portion 46 of the base metal fitting 40. The fixing metal fitting 60 composed of two metal fittings connected by bolts 16 and integrated is attached across the frames 13A and 13B.

In the mounting structure of the photovoltaic power generation device 10X, the bolt 16 fastened to the base metal fitting 40 presses the first base portion 62A of the first metal fitting 61A and the second base portion 62B of the second metal fitting 61B from above. The protrusions 64A and 64B (see FIG. 9) of the engaging portions inserted into the outer grooves 24A and 24B of the frames 13A and 13B are in strong contact with the upper surfaces of the bottom plates 23A and 23B. Further, the first base portion 62A is strongly in contact with the hook portion 33 of the mount fitting 30 via the ground fitting 15.

It is preferable that the first engaging portion 63A of the first metal fitting 61A is deeply inserted into the outer groove 24A. Similarly, it is preferable that the second engaging portion 63B of the second metal fitting 61B is deeply inserted into the outer groove 24B. The end surface of the eaves side edge portion of the first engaging portion 63A may be substantially in contact with the innermost portion of the outer groove 24A, and the end surface of the ridge side edge portion of the second engaging portion 63B is the outer groove. It may be substantially in contact with the innermost part of 24B.

The photovoltaic power generation device 10X having the above-described configuration has excellent load bearing capacity, although it is easy to install and has good maintainability, like the photovoltaic power generation device 10. In the photovoltaic power generation device 10X, for example, the first metal fitting 61A is inserted into the outer groove 24A of the frame 13A, the first metal fitting 61A and the second metal fitting 61B are fixed to the base metal fitting 40, and then the first metal fitting 61B is inserted into the outer groove 24B of the frame 13B. It can be installed by a simple procedure of inserting 2 metal fittings 61B.

Specifically, first, the first engaging portion 63A of the first metal fitting 61A is inserted into the outer groove 24A of the frame 13A of the solar cell module 11A mounted on the mounting metal fitting 30. Next, the second base portion 62B of the second metal fitting 61B is arranged on the first base portion 62A of the first metal fitting 61A, and each metal fitting is fixed to the base metal fitting 40 with the bolt 16. Then, by arranging the solar cell module 11B on the ridge side of the second metal fitting 61B and inserting the second engaging portion 63B into the outer groove 24B of the frame 13B, the fixing metal fitting 60 is attached across the frames 13A and 13B. .. The bolt 16 may be fastened to the base metal fitting 40 after the second engaging portion 63B is inserted into the outer groove 24B.

Also in the photovoltaic power generation device 10X, it is possible to easily remove and replace only the target solar cell module 11. For example, after removing the bolt 16 for fixing the solar cell module 11 to be replaced, the second metal fitting 61B installed on the ridge side of the module is laterally shifted to a position where it does not overlap with the first metal fitting 61A. Only the module can be removed.

Next, the photovoltaic power generation device 10Y, which is another example of the embodiment, will be described in detail with reference to FIGS. 11 and 12A and 12B. In the following, the same reference numerals are used for the components common to the above-mentioned photovoltaic power generation devices 10 and 10X, and duplicate description will be omitted. The photovoltaic power generation device 10Y (see FIG. 12A) is different from the photovoltaic power generation device 10 in that the fixing bracket 70 (see FIG. 11) is used instead of the fixing bracket 50. Further, a spacer 91 is provided under the fixing metal fitting 60, and the fixing metal fitting 60 is fastened to the base metal fitting 40 by using bolts 18. The photovoltaic power generation device 10Y is in common with the photovoltaic power generation device 10 in other respects.

FIG. 11 is a perspective view of the fixing bracket 70. As illustrated in FIG. 11, the fixing metal fitting 70 includes a first metal fitting 71A, a second metal fitting 71B, and a holding metal fitting 71C. The first metal fitting 71A has a first engaging portion 73A inserted into the outer groove 24A of the frame 13A, and the second metal fitting 71B has a second engaging portion 73B inserted into the outer groove 24B of the frame 13B. The pressing metal fitting 71C is arranged so as to straddle the first metal fitting 71A and the second metal fitting 71B, and is a metal fitting that presses the first metal fitting 71A and the second metal fitting 71B from above. The presser foot fitting 71C is arranged on the first base portion 72A of the first metal fitting 71A and the second base portion 72B of the second metal fitting 71B.

The first metal fittings 71A and the second metal fittings 71B are arranged next to each other in the gap S between the frames 13A and 13B in the eaves building direction without overlapping in the vertical direction. The first metal fitting 71A and the second metal fitting 71B are, for example, metal fittings having a substantially rectangular shape in a plan view that are long in the horizontal direction, and have substantially the same horizontal length and vertical length as each other. An example of a suitable lateral length is longer than the distance between the hooks 33 of the mounting bracket 30 and shorter than the lateral length of the mounting bracket 30. The first metal fittings 71A and the second metal fittings 71B have a vertical length that does not interfere with the arrangement of the pressing metal fittings 71C and does not come into contact with each other with the engaging portions inserted all the way into the outer grooves 24A and 24B. preferable.

A notch 75A for passing the bolt 18 is formed in the lateral central portion of the first base portion 72A of the first metal fitting 71A. Further, a notch 75B is also formed in the lateral central portion of the second base portion 72B of the second metal fitting 71B. The first metal fittings 71A and the second metal fittings 71B are arranged adjacent to each other in the eaves building direction so that the notches 75A and 75B overlap in the eaves building direction, and bolts are formed in the portions where the notches 75A and 75B of the metal fittings are formed. 18 is passed.

The ridge-side end of the first base 72A may be bent upward. At the ridge-side end of the first base 72A, standing walls are formed on both sides of the notch 75A. The standing wall portion is formed at a height that does not come into contact with the base portion 76 of the holding metal fitting 71C arranged on the first base portion 72A, and is used, for example, when attaching or detaching the first metal fitting 71A. Similar standing wall portions may be formed on both sides of the notch 75B at the eaves side end portion of the second base portion 72B.

The first engaging portion 73A of the first metal fitting 71A extends from the eaves side end of the first base 72A to the eaves side, and the second base 72B of the second metal fitting 71B is the ridge side end of the second base 72B. It extends from the department to the ridge side. It is preferable that the first engaging portion 73A has a protrusion 74A (first protrusion) protruding downward, and the second engaging portion 73B has a protrusion 74B (second protrusion) protruding downward. The protrusions 74A and 74B are formed at both ends in the lateral direction of each engaging portion.

The presser foot fitting 71C is a metal fitting having a substantially inverted U shape in the side view, which is long in the lateral direction. The presser foot fitting 71C has a base portion 76 in which a through hole 79 for passing a bolt 18 is formed, a first leg portion 77 extending downward from the eaves side end portion of the base portion 76, and a ridge side end portion of the base portion 76 downward. It has an extended second leg 78. The lateral length of the presser foot fitting 71C is shorter than, for example, the lateral length of the first metal fitting 71A and the second metal fitting 71B. The vertical length (width) of the presser foot fitting 71C is such that it can be inserted into the gap S (less than the width of the gap S) and can be arranged across the first metal fitting 71A and the second metal fitting 71B.

The first leg portion 77 is a portion that comes into contact with the first base portion 72A of the first metal fitting 71A. The second leg portion 78 is a portion that abuts on the second base portion 72B of the second metal fitting 71B. As shown in FIG. 12, which will be described later, the height of the upper surface of the first base 72A from the upper end of the mounting bracket 30 is higher than the height of the upper surface of the second base 72B, so that the second leg 78 is the first leg. It is formed longer than 77. A plurality of protrusions may be formed at the lower end of each leg.

12A and 12B are vertical sectional views showing a mounting structure of the photovoltaic power generation device 10Y. 12A and 12B show the ridge-side end of the solar cell module 11A and the solar cell using the first metal fitting 71A, the second metal fitting 71B, and the holding metal fitting 71C constituting the mounting metal fitting 30, the base metal fitting 40, and the fixing metal fitting 70. The structure which fixes the eaves side end of module 11B to roof 100 is shown.

As illustrated in FIGS. 12A and 12B, the first engaging portion 73A of the first metal fitting 71A is formed in the outer groove 24A of the frame 13A of the solar cell module 11A mounted on the mounting metal fitting 30 via the grounding metal fitting 15. It is inserted. Further, the second engaging portion 73B of the second metal fitting 71B is inserted into the outer groove 24B of the frame 13B of the solar cell module 11B. Then, the first metal fitting 71A and the second metal fitting 71B are pressed from above by the pressing metal fitting 71C fastened to the base metal fitting 40 using the bolt 18.

Spacers 91 for supporting the respective metal fittings may be provided under the first metal fitting 71A and the second metal fitting 71B. The spacer 91 is, for example, a plate-shaped member having a width shorter than the width of the gap S and long in the lateral direction, and is arranged on the hook portion 33 of the mount metal fitting 30 via the ground metal fitting 15. Since the tip of the bottom plate 23A of the frame 13A is slightly raised due to the inclination of the roof surface, the spacer 91 is formed so that the thickness of the eaves side portion is thicker than that of the ridge side portion. Further, the spacer 91 is formed with a through hole through which the bolt 18 is passed.

The bolt 18 passed through the through hole 79 of the presser foot fitting 71C passes through the portions where the notches 75A and 75B of the first metal fitting 71A and the second metal fitting 71B are formed, and the through holes of the spacer 91 and the ground metal fitting 15. It is screwed into the bolt fastening portion 46 of the base metal fitting 40. The fixing metal fitting 70 composed of three metal fittings in which the pressing metal fitting 71C is fixed and integrated on the first metal fitting 71A and the second metal fitting 71B by the bolt 18, is attached across the frames 13A and 13B.

The first base portion 72A of the first metal fitting 71A is arranged on the spacer 91 and is pressed from above by the first leg portion 77 of the pressing metal fitting 71C. The first engaging portion 73A is deeply inserted into the outer groove 24A of the frame 13A, and the end surface of the first engaging portion 73A is substantially in contact with the outermost portion of the outer groove 24A. When the first base portion 72A is pressed from above by the pressing metal fitting 71C, the protrusion 74A (see FIG. 11) of the first engaging portion 73A inserted into the outer groove 24A is strongly in contact with the upper surface of the bottom plate 23A. .. Further, the first base portion 72A is strongly in contact with the eaves side portion of the spacer 91 arranged on the hook portion 33 of the mount metal fitting 30.

The second base portion 72B of the second metal fitting 71B is arranged on the spacer 91 and is pressed from above by the second leg portion 78 of the pressing metal fitting 71C. The second engaging portion 73B is deeply inserted into the outer groove 24B of the frame 13B, and the end surface of the second engaging portion 73B is substantially in contact with the outermost portion of the outer groove 24B. When the first base portion 72A is pressed from above by the pressing metal fitting 71C, the protrusion 74B (see FIG. 11) of the second engaging portion 73B inserted into the outer groove 24B is strongly in contact with the upper surface of the bottom plate 23B. .. Further, the second base portion 72B is in strong contact with the ridge-side portion of the spacer 91 arranged on the hook portion 33 of the mount metal fitting 30.

The photovoltaic power generation device 10Y having the above-described configuration, like the photovoltaic power generation devices 10 and 10X, has excellent load bearing capacity despite being easy to install and having good maintainability. In the photovoltaic power generation device 10Y, for example, the first metal fitting 71A is inserted into the outer groove 24A of the frame 13A, and the second metal fitting 71B is inserted into the outer groove 24B of the frame 13B, straddling the first metal fitting 71A and the second metal fitting 71B. It can be installed by a simple procedure of attaching the presser foot fitting 71C.

Specifically, first, the first engaging portion 73A of the first metal fitting 71A is inserted into the outer groove 24A of the frame 13A of the solar cell module 11A mounted on the mounting metal fitting 30, and the first base portion of the first metal fitting 71A is inserted. The spacer 91 is placed under the 72A. Next, the solar cell module 11B in which the second engaging portion 73B of the second metal fitting 71B is inserted into the outer groove 24B of the frame 13B is arranged on the ridge side of the spacer 91. Then, the pressing metal fitting 71C is arranged straddling the first metal fitting 71A and the second metal fitting 71B, and the bolt 18 passed through the through hole 79 of the pressing metal fitting 71C is fastened to the base metal fitting 40. After attaching the holding metal fitting 71C, it is also possible to arrange the solar cell module 11A on the ridge side of the second metal fitting 71B and insert the second engaging portion 73B into the outer groove 24B.

Also in the photovoltaic power generation device 10Y, it is possible to easily remove and replace only the target solar cell module 11. For example, by loosening the bolt 18 for fixing the solar cell module 11 to be replaced and removing the holding metal fitting 71C, only the module can be removed.

As illustrated in FIG. 13, a cover 80Y having a snow stopper 84 erected on the upper surface of the base 81 may be mounted on the gap S of the frames 13A and 13B. The snow stopper 84 is formed at the eaves side portion of the base 81 higher than the head of the screw 86 that fixes the cover 80Y to the support metal fitting 85. The height of the snow stopper 84 is, for example, about 7 mm. The snow stopper 84 may be formed over the entire length of the cover 80Y, but in that case, it is preferable to form drain holes at predetermined intervals.

10,10X, 10Y solar power generation device, 11,11A, 11B solar cell module, 12,12A, 12B solar cell panel, 13,13A, 13B frame, 15 ground fittings, 16,18 bolts, 17 temporary fixing bolts, 20 , 20A, 20B Main body, 21,21A, 21B Hook, 22 Inner groove, 23, 23A, 23B Bottom plate, 24, 24A, 24B Outer groove, 25, 25A, 25B Inner flange, 30 Mount bracket, 30a Eaves side Edge, 30b ridge side edge, 31 base, 31a upper wall, 31b side wall, 31c recess, 32 flange, 32a outer end, 32b inner end, 33 hook, 34 guide rail, 35 through hole, 36 Bundling band hole, 37 drain groove, 38 alignment mark, 40 base bracket, 41 base, 42 extension, 43 engagement, 44 building side standing wall, 46 bolt fastening, 47 temporary fixing bolt fastening, 48 Opening, 50 fixing bracket, 50a eaves side edge, 50b ridge side edge, 51 base, 52 1st engaging part, 53 2nd engaging part, 54 protrusion, 55 through hole, 56 instrument insertion hole, 60 fixing Bracket, 61A 1st Bracket, 61B 2nd Bracket, 62A 1st Base, 62B 2nd Base, 63A 1st Engagement, 63B 2nd Engagement, 64A, 64B Protrusion, 65A, 65B Through Hole, 70 Fixing Bracket , 71A 1st metal fitting, 71B 2nd metal fitting, 71C presser metal fitting, 72A 1st base, 72B 2nd base, 73A 1st engaging part, 73B 2nd engaging part, 74A, 74B protrusion, 75A, 75B notch, 76 base, 77 1st leg, 78 2nd leg, 79 through hole, 80, 80Y cover, 81 base, 82 leg, 84 snow stopper, 85 support bracket, 86,87 screw, 88 claw, 100 roof , 90, 91 spacers, 101 roofing materials, 102 field boards, 103 rubber sheets, 105 spacers, 106 through holes, 107 screws, S gaps

Claims (7)

A first solar cell module having a first solar cell panel and a first frame including a first outer groove opening toward the outside of the module and installed at the end of the panel.
It has a second solar cell panel and a second frame including a second outer groove that opens toward the outside of the module and is installed at the end of the panel, and is between the first solar cell module. The second solar cell module placed next to each other on the ridge side of the module with a gap,
A mounting bracket fixed to the roof and on which the first frame installed at the ridge-side end of the first solar cell module and the second frame installed at the eaves-side end of the second solar cell module are mounted. When,
It has a first engaging portion to be inserted into the first outer groove of the first frame and a second engaging portion to be inserted into the second outer groove of the second frame, and uses bolts. The fixing bracket fixed to the mounting bracket and
The base metal fitting to which the bolt is fastened and
With
The fixing bracket
Is it configured so that the first and second engaging portions can be inserted into the first and second outer grooves by rotating in the gap?
Alternatively, it is composed of a first metal fitting having the first engaging portion and being able to be arranged in the gap, and a second metal fitting having the second engaging portion and being able to be arranged in the gap.
The mount bracket has a guide rail portion that slidably supports the base bracket toward the eaves of the roof.
The fixing metal fitting is a photovoltaic power generation device fixed to the mounting metal fitting via the base metal fitting inserted into the guide rail portion . The first frame has a first inner collar portion overhanging inside the first solar cell module.
The photovoltaic power generation device according to claim 1, wherein the base metal fitting has an engaging portion that protrudes upward from the upper end of the mount metal fitting and engages with the first inner collar portion. The second frame has a second inner collar portion overhanging inside the second solar cell module.
The photovoltaic power generation device according to claim 1 or 2, wherein the base metal fitting has a ridge-side standing wall portion that projects upward from the upper end of the mount metal fitting and is arranged so as to face the tip of the second inner collar portion. The fixing metal fitting is a metal fitting having a substantially parallel polygonal shape in a plan view that rotates in the gap.
The first end surface of the first engaging portion is substantially in contact with the innermost portion of the first outer groove, and the second end surface of the second engaging portion is substantially parallel to the first end surface. The photovoltaic power generation device according to any one of claims 1 to 3 , which is substantially in contact with the innermost portion of the second outer groove. The fixing metal fitting is composed of the first metal fitting and the second metal fitting.
The first metal fitting has a first base portion formed with a first through hole through which the bolt is passed, and the first engaging portion.
The second metal fitting has a second base portion which is arranged so as to overlap with the first base portion and has a second through hole through which the bolt is passed, and the second engaging portion, according to claims 1 to 3. The photovoltaic power generation device according to any one item . The fixing metal fittings are arranged so as to straddle the first metal fitting, the second metal fitting, the first metal fitting and the second metal fitting, and press the first and second metal fittings from above. The solar power generation device according to any one of claims 1 to 3 , which is composed of the above . A cover arranged on the gap across the first frame and the second frame,
A support fitting that is inserted into the first outer groove of the first frame, fixed to the first frame, and the cover is screwed.
The solar power generation device according to any one of claims 1 to 6 .

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