JP6678344B2 - Solar power generator - Google Patents

Description

  The present disclosure relates to a solar power generation device.

  A solar power generation device is constructed by attaching a plurality of solar cell modules to a roof. For example, Patent Document 1 discloses that a solar cell module is fixed by engaging upper and lower flanges of a lower frame of the solar cell module with frame mounting portions of horizontal rails installed at predetermined intervals on a roof. A power generator is disclosed.

Rev. 2012/096297

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

  A photovoltaic power generation device according to one aspect of the present disclosure includes a solar cell panel and a frame installed at an end of the panel, and first and second solar cells that are arranged adjacent to each other in the eaves ridge direction of the roof. A solar power generation device comprising: a second solar cell module, wherein each of the frames has an outer groove opened toward the outside of the module, and an engagement portion inserted into the outer groove of the second solar cell module A base metal fixed to the roof to support the respective frames of the respective solar cell modules, a hook inserted into the base metal, and inserted into the outer groove of the first solar cell module. A first fixing fitting disposed on the eaves side of the engaging portion on the base fitting, and a second fixing fixture for fixing the first fixing fitting to the base fitting. With fixing bracket That.

  According to an embodiment of the present disclosure, it is possible to provide a photovoltaic power generator having good workability and maintainability, and capable of firmly fixing a solar cell module to a roof.

It is a top view of the solar power generation device which is an example of an embodiment. It is sectional drawing of the solar cell module which is an example of embodiment. It is an exploded perspective view of a solar power generation device which is an example of an embodiment. It is a top view of a base metal fitting which is an example of an embodiment. It is a front view of a base metal fitting which is an example of an embodiment. FIG. 6 is a sectional view taken along line CC in FIG. 5. FIG. 2 is a sectional view taken along line AA in FIG. 1. It is a perspective view of the 1st fixing metal which is an example of an embodiment. It is a perspective view of the 2nd fixing metal which is an example of an embodiment. It is BB sectional drawing in FIG. It is a figure for explaining the construction method of the solar power generation device which is an example of an embodiment. It is a figure for explaining the construction method of the solar power generation device which is an example of an embodiment.

  A solar power generation device according to one aspect of the present disclosure includes a base metal fitting having an engagement portion that engages with a ridge-side solar cell module, and a second base metal that is inserted into the base metal fitting and engages with the eaves-side solar cell module. A first fixing member and a second fixing member for fixing the first fixing member to the base member. According to such a configuration, the solar power generation device can be constructed by a simple method of mounting two solar cell modules on the base metal fitting and attaching two fixing metal fittings. Further, by removing the second fixing bracket, for example, only one of the plurality of solar cell modules constituting the photovoltaic power generator can be easily removed and replaced. Each solar cell module is firmly fixed on a base fitting 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. The drawings referred to in the embodiments are schematically described, and 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 “substantially to” is intended to include the case where substantially the same is considered as well as substantially the same, when substantially the same is described as an example. The embodiment described below is an exemplification, and the solar power generation device of the present disclosure is not limited thereto.

  In the following, the direction of the base metal fittings etc. along the roof eaves direction may be referred to as “vertical direction”, and the direction of the base metal fittings etc. along the roof girder direction (the direction perpendicular to the roof eaves building direction) is referred to as “horizontal”. Direction (left and right), and the direction of the base bracket and the like along the direction perpendicular to the roof base plate is referred to as "up and down direction." In the drawing, an arrow α indicates the eaves ridge direction and the vertical direction of the roof, an arrow β indicates the girder direction and the horizontal direction, and an arrow γ indicates the vertical direction.

  FIG. 1 is a plan view of a photovoltaic power generator 10 as an example of the embodiment. FIG. 2 is a cross-sectional view of the solar cell module 11 constituting the photovoltaic power generation device 10, and FIG. 3 is an exploded perspective view of the photovoltaic power generation device 10. As illustrated in FIG. 1, the solar power generation device 10 includes a solar cell module 11 </ b> A (first solar cell module) and a solar cell module 11 </ b> B (second solar cell) that are arranged adjacent to each other in the eaves direction of the roof 100. Battery module). The photovoltaic power generator 10 is constructed by attaching a plurality of solar cell modules 11 (11A, 11B) to a roof 100.

  In this specification, for convenience of description, of two solar cell modules 11 arranged adjacent to each other in the eaves ridge direction, a module arranged on the eaves side is referred to as a solar cell module 11A, and a module arranged on the ridge side is referred to as a solar cell module. The battery module is assumed to be 11B. In the present embodiment, all the solar cell modules 11 have the same shape.

  As illustrated in FIGS. 1 to 3, each solar cell module 11 has a solar cell panel 12 and a frame 13 installed at an end of the panel, and each frame 13 faces the outside of the module. It has an outer groove 24 (see FIG. 2) that is opened. Although described in detail later (see FIG. 7), the photovoltaic power generation device 10 includes a base metal fitting 30, a first fixing metal fitting 50, and a second fixing metal fitting 60. The base metal fitting 30 has an engaging portion 40 inserted into the outer groove 24B of the solar cell module 11B, and is fixed to the roof 100 to support the frames 13A and 13B of the solar cell modules 11A and 11B. The first fixture 50 has a hook 54 inserted into the base 30 and a convex portion 52 inserted into the outer groove 24A of the solar cell module 11A. It is placed on the eaves side. The second fixing member 60 is a member for fixing the first fixing member 50 to the base member 30.

  The photovoltaic power generator 10 has a plurality of rows of solar cell modules 11 along the girder direction of the roof 100. In the present embodiment, a plurality of solar cell modules 11 constituting each row are arranged in such a manner that the short sides of the solar cell module 11 having a rectangular shape in a plan view are substantially parallel to the eaves building direction and the short sides are substantially in contact with each other. I have. In the example shown in FIG. 1, the number of the solar cell modules 11 constituting each column is the same, but the number and arrangement of the solar cell modules constituting the photovoltaic power generation device are not particularly limited. They may be arranged in a staggered manner.

  The photovoltaic power generator 10 includes a base plate 14 laid on a roof board 102 of a roof 100. Then, the base fitting 30 is mounted on the base plate 14. On the roof 100, a roofing material 101 is disposed at least partially around the solar power generation device 10. On the other hand, the roof material 101 is not arranged below the solar power generation device 10. Examples of the roofing material 101 include a Japanese tile, a Western tile, a flat tile, a slate tile, and the like. The shape of the roof 100 on which the photovoltaic power generation device 10 can be installed is not particularly limited, and may be, for example, any of a building roof, a square roof, and a gable roof. Note that the solar power generation device may be configured to have no base plate 14. In this case, for example, the base metal fitting 30 is arranged on the roof material 101 and fixed to the field board 102.

  The solar cell module 11 has, for example, a structure in which a frame 13 is installed around four sides of a solar cell panel 12 having a rectangular shape in plan view. The frame 13 is obtained by, for example, extruding a metal material mainly containing aluminum. Generally, a coating film is formed on the surface of the frame 13.

  As illustrated in FIG. 2, the frame 13 has a main body 20 having a hollow prism shape, an inner groove 22 opened toward the inside of the module, and an outer groove 24 opened toward the outside of the module. . In addition, the frame 13 has an inner flange portion 25 protruding inside the module. The frame 13 has a hook 21 erected on the upper surface of the main body 20, and an inner groove 22 is formed between the upper surface of the main body 20 and the hook 21 as a gap into which the solar cell panel 12 can be inserted. You. The hook portion 21 extends straight upward from the outside of the main body portion 20 and is bent inward on the way to form a substantially L-shaped cross section. The frame 13 is provided with a bottom plate 23 extending to the opposite side (outside) of the inner flange 25, and an outer groove 24 is formed between the lower surface of the main body 20 and the bottom plate 23.

  As illustrated in FIG. 3, a plurality of base plates 14 are laid on the base plate 102. In the present embodiment, the base fitting 30 is directly fixed to the base plate 102 by screws passing through the base plate 14. The base plate 14 is, for example, a sheet metal having a rectangular shape in a plan view, and is fixed to the base plate 102 together with the base fitting 30. Although the base fitting 30 can be fixed directly on the base plate 102, the use of the base plate 14 facilitates the positioning of the base fitting 30 and improves workability.

  For example, two base plates 14 are provided on the back side of one solar cell module 11, respectively. The base plate 14 is arranged on the field board 102 from one side in the girder direction on the eave side of the roof 100 (hereinafter, referred to as “left side”), for example. On the base plate 14 arranged on the left side, a part of the base plate 14 arranged adjacent to the other side in the beam direction (hereinafter referred to as “right side”) is overlapped. A part of the base plate 14 arranged adjacent to the ridge side is overlapped on the base plate 14 arranged on the eave side. In this way, the base plates 14 are installed in order from the left on the eave side to the right on the ridge side.

  The base plate 14 (upper base plate) superimposed on the base plate 14 (lower base plate) is pressed by a base metal fitting 30 installed on the lower base plate 14 so as not to float up. That is, the end of the upper base plate 14 is inserted between the lower base plate 14 and the base fitting 30, and the base fitting 30 also functions as a stopper for the base plate 14. Side plates 15 are provided at both lateral ends of the photovoltaic power generator 10, and an eaves base plate 16 is provided at an eaves-side end. Generally, a waterproof sheet is provided on the base plate 102, and a waterproof tape is attached to an edge of the base plate 14 and the like (neither is shown).

  The base fittings 30 are arranged one at a ridge side end of each base plate 14 along the girder direction of the roof 100. It is preferable that the respective base fittings 30 arranged adjacent to each other in the beam direction are connected to each other and arranged in a line along the beam direction. In the present embodiment, as described above, the end portions of the respective base plates 14 are arranged so as to overlap each other. The lateral length of each base plate 14 is longer than the lateral length of the base fitting 30, and both lateral ends of the base plate 14 extend from both lateral ends of the base fitting 30.

  An eaves cover 90 is provided at an eaves-side end of the photovoltaic power generator 10. A ridge cover 95 (see FIG. 1) is provided at the ridge side end of the solar power generation device 10. The eaves cover 90 and the ridge cover 95 are metal members extending in the girder direction of the roof 100, and have, for example, substantially the same length as the long sides of the solar cell module 11. In the present embodiment, the eaves cover 90 is fixed on the eaves-side base metal fitting 70 installed on the eaves-end base plate 16, and the ridge cover 95 is fixed on the base metal fitting 30.

  On the back side of one solar cell module 11, for example, two base plates 14 are laid, and at least four base fittings 30, or two base fittings 30 and two eaves-side base fittings 70 are arranged. One solar cell module 11 is mounted and supported on four base fittings.

  Hereinafter, the mounting structure of the solar cell modules 11A and 11B to the roof 100, in particular, the base metal fitting 30, the first fixing metal fitting 50, and the second fixing metal fitting 60 will be described in detail with reference to FIGS. 4 is a plan view of the base fitting 30, FIG. 5 is a front view of the base fitting 30, and FIG. 6 is a sectional view of the base fitting 30 (a sectional view taken along line CC in FIG. 5).

  As illustrated in FIGS. 4 to 6, the base fitting 30 has a pedestal portion 31 and a fixing portion 32. The pedestal portion 31 is a portion where the solar cell modules 11A and 11B are mounted and the first fixing bracket 50 (see FIGS. 7 and 8) is attached. The engaging portion 40 that engages with the frame 13B of the solar cell module 11B is formed on the pedestal portion 31. The fixing portion 32 is a portion that is screwed to the base plate 102 via the base plate 14. The fixing portion 32 is formed in a substantially flat plate shape, and extends from the eaves end of the pedestal portion 31 to the eaves side. In the example shown in FIG. 4, the fixing portions 32 are provided at two positions on the left and right at the same distance from the lateral center of the base fitting 30. The fixing portion 32 has a plurality of through-holes 34 through which screws 33 (see FIG. 7 described later) that pass through the base plate 14 and are fixed to the base plate 102 are formed.

  The base fitting 30 has an upper surface portion 31a that supports the frames 13A and 13B so that the frames 13A and 13B are at the same height with respect to the base plate 102 of the roof 100, and has a second fixing bracket 60 (see FIGS. 7 and 9) on the upper surface portion 31a. (See FIG. 3) is provided upright. In the present embodiment, the engaging portion 40 protrudes from the intermediate portion of the standing wall portion 41 to the ridge side. The upper surface portion 31a forms a part of the pedestal portion 31. The pedestal portion 31 further has side surface portions 31b and 31c extending downward from both ends in the longitudinal direction of the upper surface portion 31a, and is formed over the entire length of the base fitting 30. The portions of the upper surface portion 31a on which the frames 13A and 13B are mounted are formed at substantially the same height as each other and substantially parallel to the base plate 102.

  The pedestal 31 has a recess 35 (see FIG. 6) into which the end of the base plate 14 disposed adjacent to the ridge is inserted, and a notch 36 (see FIG. 6) into which the end of the base plate 14 disposed adjacent to the right is inserted. 5). A notch 37 (see FIG. 5) is formed in the center of the pedestal portion 31 in the lateral direction. The notches 36 and 37 are formed by notching lower portions of the side surfaces 31b and 31c. The notch 37 is formed between each fixing part 32. The notch 37 is formed, for example, in order to prevent rainwater or the like from being blocked by the base fitting 30. Further, a cable connected to the solar cell module 11 may be passed through the notch 37.

  The base fitting 30 has an engaging groove 38 into which the hook 54 of the first fixing fitting 50 is inserted (see FIGS. 4 and 6). The engagement groove 38 is provided adjacent to the eaves side of the upright wall portion 41 from which the engagement portion 40 protrudes. In the present embodiment, the upright wall portion 41 is provided upright at the center in the vertical direction of the upper surface portion 31a and extends along the horizontal direction. The engagement groove 38 is also formed at the center in the vertical direction of the upper surface portion 31a, and extends along the horizontal direction.

  The engagement groove 38 is formed below a portion of the upper surface portion 31a on which the frame 13A is mounted (hereinafter, may be referred to as a "frame mounting portion"). In other words, the engagement groove 38 is formed by a concave portion formed in the upper surface portion 31a and a frame mounting portion that partially closes the opening of the concave portion, and the remaining of the opening of the concave portion that is not covered by the frame mounting portion. Part of the hole serves as an insertion port for the hook portion 54 (opening of the engagement groove 38). The engagement groove 38 is formed in a portion of the pedestal portion 31 except for an opening 44 to be described later, and holds the first fixing bracket 50 so as to be slidable in the horizontal direction. The first fixture 50 inserted into the engagement groove 38 is not pulled out by being hooked on the frame mounting portion, and is fixed to the pedestal portion 31 by the second fixture 60 (see FIG. 7).

  As described above, the base metal fitting 30 has the upright wall portion 41 erected on the upper surface portion 31a and the engaging portion 40 protruding toward the ridge from an intermediate portion of the upright wall portion 41. The upright wall portion 41 is a portion to which the second fixing bracket 60 is attached, and is preferably formed substantially perpendicular to a portion of the upper surface portion 31a on which the frames 13A and 13B are placed. The engagement portion 40 is formed with a gap between the engagement portion 40 and the upper surface portion 31a so that the bottom plate 23B of the frame 13B can be inserted. It is preferable that the engaging portion 40 is formed substantially perpendicular to the upright wall portion 41.

  The base metal fitting 30 and the first fixing metal fitting 50 are formed with through holes 43 and 53 with which the second fixing metal fitting 60 is engaged, respectively (for the through hole 53, see FIG. 8 described later). The through hole 43 of the base fitting 30 is formed above the engaging portion 40 in the upright wall portion 41. In the present embodiment, a plurality of upright wall portions 41 that are divided at predetermined intervals by openings 44 described later are provided. Then, one through hole 43 is formed in each standing wall portion 41. The through-hole 43 has a substantially rectangular shape that is long in the lateral direction when viewed from the front, but the shape of the through-hole is not particularly limited.

  The base fitting 30 has an opening 44 formed by cutting off a portion of the pedestal portion 31 where the engagement groove 38 and the standing wall portion 41 are provided. In the example shown in FIG. 4, a total of three openings 44 are formed at the center in the horizontal direction of the base fitting 30 and at two places on the left and right sides of the base metal 30 at substantially equal distances from the center in the horizontal direction. The opening 44 functions, for example, as a drain port, and is also used when attaching the first fixture 50. For example, one or two or more first fixing members 50 are attached to one base member 30. When a plurality of first fixtures 50 are attached, a plurality of openings 44 are preferably formed.

  The pedestal portion 31 preferably has a hook portion 45 projecting above the inner flange portion 25A of the frame 13A, and a ridge-side standing wall portion 46 erected on the ridge side of the inner flange portion 25B of the frame 13B. The hook portion 45 has a substantially L-shaped cross section at the eaves-side end of the pedestal portion 31 with a gap between the upper surface portion 31a and the upper surface portion 31a. The ridge-side standing wall portion 46 is formed at a ridge-side end portion of the pedestal portion 31 at a height that does not hinder the installation of the frame 13B and at a position facing the tip of the inner flange portion 25B. The pedestal 31 has a joint insertion portion 48 into which a later-described joint fitting 47 is inserted. The joint insertion part 48 is formed on the eaves side of the pedestal part 31.

  FIG. 7 is a cross-sectional view taken along the line AA in FIG. 1, and is a cross-sectional view of the boundary between the solar cell modules 11A and 11B and the vicinity thereof. As illustrated in FIG. 7, the base metal fitting 30 is provided so as to straddle the ridge-side end of the solar cell module 11A and the eave-side end of the solar cell module 11B. The base fitting 30 is fixed to the base plate 102 below the solar cell module 11A. The screw 33 attached to the fixing portion 32 passes through the base plate 14 and is fixed to the base plate 102. The frames 13A, 13B of the solar cell modules 11A, 11B are mounted on the upper surface 31a of the pedestal 31, and are supported so that their heights from the base plate 102 are substantially the same.

  The frame 13B is placed on the ridge side of the upright wall portion 41 of the upper surface portion 31a, and is fixed to the pedestal portion 31 by inserting the engaging portion 40 into the outer groove 24B. In other words, the frame 13B is fixed to the pedestal portion 31 by inserting the bottom plate 23B between the upper surface portion 31a and the engaging portion 40. The ridge-side standing wall portion 46 is provided on the ridge side of the frame 13B at a position facing the tip of the inner flange portion 25B, so that the solar cell module 11B is prevented from moving to the ridge side.

  The frame 13 </ b> A is fixed to the pedestal part 31 using the first fixing fitting 50. As described above, the first fixture 50 has the hook portion 54 and the convex portion 52, and is attached on the pedestal portion 31 so as to be adjacent to the eaves side of the standing wall portion 41. When the hook 54 is inserted into the engagement groove 38, the first fixture 50 is caught by the pedestal 31 and does not come out upward. Then, the frame 13 </ b> A is fixed to the pedestal 31 by inserting the convex portion 52 into the outer groove 24 </ b> A of the frame 13 </ b> A. Since the hook 45 is provided on the eaves side of the frame 13A, the inner flange 25A is pressed from above when, for example, a negative pressure acts on the solar cell module 11A.

  In the photovoltaic power generator 10, the second fixing bracket 60 having a substantially inverted U-shaped cross section is attached so as to cover the upright wall 41 and the first fixing bracket 50 from above. The second fixture 60 is fixed to the upright wall 41 of the base 30 and the base 51 of the first fixture 50. The upright wall portion 41 of the base metal fitting 30, the base 51 of the first fixing metal fitting 50, and the second fixing metal fitting 60 are sandwiched by the frames 13A and 13B.

  Each base metal fitting 30 arranged adjacent to the roof 100 in the girder direction is connected using a joint metal fitting 47. The joint fitting 47 is an elongated member that extends straight in the longitudinal direction. A joint insertion portion 48 corresponding to the shape of the joint fitting 47 is formed in the base 31 of the base fitting 30. By inserting one joint fitting 47 into each joint insertion portion 48 of two base fittings 30 adjacent in the girder direction, the respective base fittings 30 are connected in a state of being arranged straight in the girder direction.

  FIG. 8 is a perspective view of the first fixture 50. As illustrated in FIGS. 7 and 8, the first fixture 50 has a base 51 that contacts the upright wall 41 of the base 30 and extends substantially parallel to the upright wall 41. The base 51 is provided substantially perpendicular to a portion of the upper surface 31a on which the frames 13A and 13B are mounted. As will be described in detail later, the first fixture 50 is attached and detached by sliding the first fixture 50 laterally between the opening 44 and the portion where the standing wall 41 of the base 30 is formed. Will be For this reason, it is preferable that the upper end of the base 51 be located higher than the upper end of the standing wall portion 41 in a state where the first fixture 50 is inserted into the outer groove 24A of the frame 13A.

  In the first fixture 50, the hooks 54 and the protruding portions 52 project from the lower end of the base 51 toward the eaves side. The protruding portion 52 is preferably formed substantially perpendicular to the base 51. The hook portion 54 extends straight downward from the lower end portion of the base portion 51, is bent toward the eaves on the way, and is formed in a substantially L-shaped cross section. A portion extending toward the eaves side of the hook portion 54 is formed substantially parallel to the convex portion 52 with a gap between the hook portion 54 and the convex portion 52 at which the bottom plate 23A and the frame mounting portion of the upper surface portion 31a can be inserted.

  The first fixing bracket 50 has a shape in which a convex portion 52 and a hook portion 54 protrude in the same direction from a plate-like base portion 51 that is longer in the horizontal direction than in the vertical direction. In the example shown in FIG. 8, the convex portion 52 and the hook portion 54 are provided over the entire length of the first fixing bracket 50 in the lateral direction. The through-hole 53 formed in the base 51 has a substantially rectangular shape that is long in the lateral direction and viewed from the front, but the shape of the through-hole is not particularly limited. The through-hole 53 is formed at a central portion in the vertical direction of the base 51 so as to be biased to one side in the horizontal direction of the base 51.

  FIG. 9 is a perspective view of the second fixture 60. As illustrated in FIGS. 7 and 9, the second fixing bracket 60 includes a main body 61 having a substantially inverted U-shaped cross section, and a claw (a first claw 62 and a first claw 62) protruding from a lower end of the main body 61. A second claw portion 63). The first claw portion 62 is a portion that engages with the through hole 43 of the base metal fitting 30 and protrudes from a lower end portion of the main body portion 61 located on the ridge side. The second claw portion 63 is a portion that engages with a through hole 53 (see FIG. 8 described later) of the first fixture 50, and protrudes from a lower end portion located on the eaves side of the main body portion 61.

  The second fixture 60 further has projections (first projections 64 and second projections 65) that bite into each of the frames 13A and 13B. The first protrusion 64 is formed on the ridge side portion of the main body portion 61 and contacts the main body portion 20B of the frame 13B, and the second protrusion 65 is formed on the eave side portion of the main body portion 61 and contacts the main body portion 20A of the frame 13A. doing. Since each projection breaks through the coating film formed on the surfaces of the frames 13A and 13B and comes into contact with the metal constituting each frame, it can be grounded using the second fixture 60.

  The second fixing bracket 60 has a first claw portion 62 at one lateral end on one side (ridge side portion) of a substantially inverted U-shaped main body portion 61 and a first claw portion 62 on the other side (eave side portion) of the main body portion 61. A second claw portion 63 is formed at the other end in the lateral direction. That is, the first claw portions 62 and the second claw portions 63 are formed at predetermined intervals in the lateral direction of the second fixture 60. Each of the first claw portion 62 and the second claw portion 63 is formed to be bent inward from the lower end portion of the main body portion 61 so as to be easily inserted into the through holes 43 and 53.

  In the example shown in FIG. 9, two first protrusions 64 are formed on one side (ridge side portion) of the main body 61, and two second protrusions 65 are formed on the other side (eave side portion) of the main body 61. ing. The first protrusion 64 and the second protrusion 65 only need to protrude outside the main body 61, and the shape of the protrusion, the degree of protrusion, and the like can be appropriately changed. The first protrusion 64 and the second protrusion 65 have, for example, the same shape and dimensions as each other, and are formed by cutting the main body 61 into a mountain shape and then bending the portion surrounded by the cut portion outward.

  FIG. 10 is a cross-sectional view taken along the line BB in FIG. 1, and is a cross-sectional view of the eaves-side end of the photovoltaic power generator 10 and its vicinity. As illustrated in FIG. 10, the solar power generation device 10 includes an eaves cover 90 attached to an eaves-side end of the device, and an eaves fixed to the roof 100 and supporting the eaves cover 90 and the frame 13A of the solar cell module 11A. And a side base fitting 70. In the present embodiment, the first fixture 50 and the second fixture 60 are also used for fixing the eave cover 90 to the eave-side base fixture 70. The eave-side base metal fitting 70 is, similarly to the base metal fitting 30, inserted by the engaging portion 80 (eave-side engaging portion) inserted into the outer groove 24A of the solar cell module 11A and the hook portion 54 of the first fixing metal fitting 50. Engagement groove 78 (eave side engagement groove). Then, the second fixing member 60 fixes the first fixing member 50 to the eave-side base member 70.

  The eaves-side base fitting 70 has a pedestal portion 71 and a fixing portion 72, and has a concave portion 75, an engagement groove 78, an engagement portion 80, an upright wall portion 81, a hook portion 85, a ridge side upright wall portion 86, and a joint insertion. The point 88 is provided in common with the base fitting 30. An opening, a notch, and the like are formed in the pedestal 71 in the same manner as in the case of the base fitting 30 (neither is shown). However, the fixed portion 72 extends from the ridge side end of the pedestal portion 71 to the ridge side, and the joint insertion portion 88 is formed on the ridge side of the pedestal portion 71.

  The eaves cover 90 is a decorative cover for hiding the eaves-side base fitting 70 and the like. The eaves cover 90 has a cover body 91 and a T-shaped portion 92 that engages with the eaves-side base fitting 70. The cover main body 91 includes a hollow first portion having a substantially pentagonal shape in cross section, and a plate-like portion extending from the first portion, which is mounted on the eave-side base metal fitting 70. And a second portion formed obliquely over the vicinity of the second portion. The T-shaped portion 92 protrudes downward from the lower end of the first portion of the cover main body 91.

  The eaves cover 90 is placed on the eaves side of the erecting wall 81 of the pedestal 71, and is fixed to the pedestal 71 by the engagement of the T-shaped part 92 with the pedestal 71. The T-shaped portion 92 is fixed to the pedestal 71 by the first fixture 50 inserted into the engagement groove 78 and the hook 85 formed at the eave-side end of the pedestal 71. The convex portion 52 of the first fixing bracket 50 is inserted between the first portion of the cover main body 91 and the T-shaped portion 92.

  Here, an example of a construction procedure of the photovoltaic power generator 10 will be described with reference to FIGS. 11 and 12. As described above, the photovoltaic power generation device 10 having the above configuration installs the base plate 14, the base metal fitting 30, the eave-side base metal fitting 70, and the like on the field plate 102, and then mounts the solar cell module 11 on the eaves of the roof 100. It is arranged and arranged in order from the side. The eaves cover 90 and the eaves-side end of the solar cell module 11A are fixed on the eaves-side base metal fitting 70 installed on the eaves-end base plate 16 using the first fixing metal fittings 50 and the second fixing metal fittings 60. Next, the ridge-side end of the solar cell module 11A is fixed on the base fitting 30, and the eave-side end of the solar cell module 11B is fixed on the base fitting 30.

  As illustrated in FIG. 11, when fixing the ridge-side end of the solar cell module 11A to the pedestal portion 31 of the base fitting 30, first, the outer groove 24A of the frame 13A installed at the ridge-side end is fixed. The convex portion 52 of the first fixture 50 is inserted. As a result, the first fixture 50 is engaged with the frame 13A. On the ridge side of the frame 13A, an upright wall portion 41 of the base fitting 30 is erected, but since the opening 44 is formed in the base fitting 30, the outer wall 24A of the frame 13A at the opening 44 is formed in the outer groove 24A. One fixing bracket 50 can be inserted.

  Subsequently, as illustrated in FIG. 12, the first fixing bracket 50 is slid in the lateral direction and inserted into the gap between the frame 13A and the upright wall 41. At this time, the through-hole 43 formed in the upright wall portion 41 and the through-hole 53 formed in the base portion 51 of the first fixing bracket 50 have a length corresponding to the distance between the respective claws of the second fixing bracket 60. The first fixture 50 is slid so as to be separated in the lateral direction. Then, the second fixing member 60 is fitted from above the standing wall portion 41 and the first fixing member 50, and the corresponding claws of the second fixing member 60 are inserted into the through holes 43 and 53, respectively. As a result, the first fixture 50 is fixed to the base fixture 30.

  Subsequently, the solar cell module 11B is placed on the ridge side portion of the pedestal portion 31 so that the engaging portion 40 is inserted into the outer groove 24B of the frame 13B installed at the eaves end of the solar cell module 11B. . Thereby, the ridge-side end of the solar cell module 11A and the eave-side end of the solar cell module 11B are fixed to the pedestal 31. At this time, the first projection 64 of the second fixing bracket 60 is in a state of being cut into the frame 13B, and the second projection 65 is in the state of being cut into the frame 13A. Therefore, as described above, the ground is taken using the second fixing bracket 60. be able to.

  The method of fixing each solar cell module 11 and the cover at the eaves-side end and the ridge-side end of the photovoltaic power generator 10 is the same as the above-described method of fixing each module at the boundary between the solar cell modules 11A and 11B. is there.

  As described above, according to the photovoltaic power generator 10 having the above-described configuration, the photovoltaic module 10 has good workability and maintainability, and can firmly fix the solar cell module 11 to the roof. In the photovoltaic power generator 10, for example, only the target solar cell module 11 can be easily removed and replaced. Specifically, the second fixture 60 corresponding to the solar cell module 11 to be replaced is removed from the base fixture 30 and the first fixture 50, and the first fixture 50 is slid to the opening 44. Thereby, the solar cell module 11 can be removed from the pedestal portion 31 of the base fitting 30. The photovoltaic power generation device 10 has excellent workability and maintainability, despite having excellent load resistance.

  Reference Signs List 10 solar power generation device, 11, 11A, 11B solar cell module, 12 solar cell panel, 13, 13A, 13B frame, 14 base plate, 15 side plate, 16 eaves base plate, 20, 20A, 20B main body, 21 hook, 22 inner groove, 23, 23A, 23B bottom plate, 24, 24A, 24B outer groove, 25, 25A, 25B inner flange portion, 30 base fitting, 31 pedestal portion, 31a upper surface portion, 31b, 31c side surface portion, 32 fixing portion, 33 screw, 34 through hole, 35 concave portion, 36, 37 notch, 38 engaging groove, 40 engaging portion, 41 standing wall, 43 through hole, 44 opening, 45 hook, 46 ridge side standing wall, 47 joint Metal fittings, 48 joint insertion part, 50 first fixing metal fittings, 51 base, 52 convex part, 53 through hole, 54 hook, 0 second fixing metal fittings, 61 main body part, 62 first claw part, 63 second claw part, 64 first protrusion, 65 second protrusion, 70 eave-side base metal fitting, 71 pedestal part, 72 fixing part, 75 concave part, 78 Engaging groove, 80 engaging part, 81 standing wall part, 85 hook part, 86 building side standing wall part, 88 joint insertion part, 90 eaves cover, 91 cover body, 92 T-shaped part, 95 building cover, 100 roof, 101 roof Lumber, 102 field board

Claims (7)

It has a solar cell panel and a frame installed at an end of the panel, and comprises first and second solar cell modules arranged adjacent to each other in the eaves direction of the roof, wherein each frame is a module. A solar power generation device having an outer groove opened toward the outside of the
A base fitting that has an engaging portion inserted into the outer groove of the second solar cell module and is fixed to the roof and supports each frame of each of the solar cell modules;
It has a hook inserted into the base metal fitting and a convex part inserted into the outer groove of the first solar cell module, and is arranged on the eaves side of the engaging part on the base metal fitting. A first fixing bracket,
A second fixture for fixing the first fixture to the base fixture,
A solar power generation device comprising: A base plate laid on a roof base plate of the roof,
The photovoltaic power generator according to claim 1, wherein the base metal is mounted on the base plate. The base bracket has an upper surface portion that supports the frames so that they are at the same height with respect to the roof base plate,
The photovoltaic power generator according to claim 1, wherein an upright wall portion with which the second fixture is engaged is provided upright on the upper surface portion. The base fitting has an engagement groove into which the hook of the first fixing fitting is inserted,
The photovoltaic power generator according to claim 3, wherein the engagement groove is provided adjacent to the upright wall portion.   The photovoltaic power generator according to any one of claims 1 to 4, wherein the base fitting and the first fixing fitting are formed with through holes with which the second fixing fitting is engaged.   The photovoltaic power generator according to any one of claims 1 to 5, wherein the second fixture has a projection that cuts into each of the frames. An eaves cover attached to the eaves-side end of the solar power generation device,
An eaves-side engaging portion inserted into the outer groove of the first solar cell module, and an eaves-side engaging groove into which the hook portion of the first fixing bracket is inserted are fixed to the roof. An eaves-side base bracket that supports the eaves cover and the frame of the first solar cell module.
With
The photovoltaic power generator according to any one of claims 1 to 6, wherein the second fixing member fixes the first fixing member to the eave-side base member.

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