JP2017172161A - Solar power generation device and installation method of solar power generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar power generation device superior in workability capable of easily installing a base attachment to a roof.SOLUTION: A solar power generation device 10 in a disclosed aspect includes: a solar cell panel 12; a solar cell module 11 which has a module frame 13 attached to the edge part of the panel; a plurality of base attachments 30 which are fixed to a roof 100 and on which the module frame 13 is mounted; and a resin joint member 40 for coupling at least two base attachments 30.SELECTED DRAWING: Figure 3

Description

  The present disclosure relates to a photovoltaic power generation apparatus and a construction method for the photovoltaic power generation apparatus.

  Patent Document 1 discloses a solar power generation apparatus in which a plurality of short base metal fittings on which a solar cell module is placed are installed on a decorative slate tile roof, and the solar cell module is fixed to the roof. In the solar power generation device of Patent Document 1, many base metal fittings are scattered on the slate roof tile. For this reason, there is a problem that the positioning of the base metal is troublesome and it takes time to install the metal. In addition, as illustrated in FIG. 12, a method of fixing a solar cell module to a roof using a long base metal fitting extending in the roof girder direction is also known.

Japanese Patent Laying-Open No. 2015-214877

  When long base metal fittings are used, the installation of the metal fittings is easier and easier to install than when many short base metal fittings are installed, but the roof weight increases and the material cost increases. There is a problem that costs such as transportation costs increase.

  A photovoltaic power generation apparatus according to one embodiment of the present disclosure is fixed to a solar cell module having a solar cell panel and a module frame installed at an edge of the panel, and the module frame is mounted thereon. A plurality of base metal fittings and a resin joint member connecting at least two base metal fittings are provided.

  A construction method of a photovoltaic power generation apparatus according to an aspect of the present disclosure includes a solar battery module having a solar battery panel, a module frame installed at an edge of the panel, and a plurality of bases on which the module frame is mounted. A construction method of a solar power generation apparatus including a metal fitting, wherein at least two base metal fittings are connected by a joint member, and a long body composed of the base metal fitting and the joint member is disposed on the roof. , Fix each base bracket to the roof.

  According to the photovoltaic power generation apparatus that is one aspect of the present disclosure, it is easy to install the base metal fitting on the roof, and excellent workability is obtained. Further, it is possible to reduce the weight of the roof and the cost such as material costs.

It is a top view of the solar power generation device which is a 1st embodiment. It is a disassembled perspective view of the solar power generation device which is 1st Embodiment. It is a perspective view which shows a horizontal crosspiece part and its vicinity. In FIG. 3, it is a figure which shows the state which removed the joint member from the base metal fitting. It is AA sectional view taken on the line in FIG. It is sectional drawing of the crosspiece part of the solar power generation device which is 1st Embodiment, and its vicinity. It is a disassembled perspective view of the solar power generation device which is 2nd Embodiment. It is a perspective view of a vertical crosspiece. FIG. 9 is a sectional view taken along line BB in FIG. 8. It is sectional drawing of the base metal fitting part of the solar power generation device which is 2nd Embodiment. It is a figure which shows the conventional solar power generation device. It is a figure which shows the conventional solar power generation device.

  According to the photovoltaic power generation apparatus that is one aspect of the present disclosure, a long body composed of a plurality of base metal fittings and joint members can be arranged on the roof, and the base metal fittings can be fixed to the roof. . For this reason, construction is easier than in the case where the base fittings are individually arranged. Further, by using the resin joint member, it is possible to reduce the weight of the roof and the cost such as the material cost as compared with the case where the long base metal fitting is used.

  Hereinafter, an example of an embodiment will be described in detail with reference to the drawings. Since the drawings referred to in the embodiments are schematically described, the dimensional ratios of the components drawn in the drawings should be determined in consideration of the following description. In the present specification, the description of “substantially” is intended to include the case where substantially the same is recognized as substantially the same as the case where substantially the same is described as an example.

  In the following, the direction of the base metal fittings along the roof eaves direction may be referred to as “vertical direction”, and the direction of the base metal fittings along the roof girder direction (direction perpendicular to the roof eaves direction) is referred to as “horizontal”. The direction of the base metal fitting along the direction perpendicular to the roof base plate is referred to as “vertical direction”. In the drawing, the direction of the eaves and the vertical direction of the roof are indicated by an arrow α, the girder direction and the horizontal direction are indicated by an arrow β, and the vertical direction is indicated by an arrow γ.

  FIGS. 1-6 shows the solar power generation device 10 which is 1st Embodiment. 7-10 shows the solar power generation device 50 which is 2nd Embodiment. In addition, embodiment described below is an illustration, Comprising: The solar power generation device and construction method of this indication are not limited to them.

  FIG. 1 is a plan view of the solar power generation device 10, and FIG. 2 is an exploded perspective view of the solar power generation device 10. As illustrated in FIGS. 1 and 2, the solar power generation device 10 includes a solar battery panel 12 and a module frame 13 (hereinafter referred to as “frame 13”) installed at an edge of the panel. A solar cell module 11 is provided. The solar cell module 11 has, for example, a substantially rectangular shape, a square shape, a trapezoidal shape, or the like in plan view. Further, the solar power generation device 10 includes a plurality of base metal fittings 30 on which the frame 13 is mounted and a resin joint member 40 that connects at least two base metal fittings 30 while being fixed to the roof 100.

  The solar power generation device 10 includes a horizontal rail portion 16 disposed on the back side of the solar cell module 11. A plurality of crosspieces 16 are provided along the girder direction of the roof 100. The horizontal crosspiece 16 is a long body composed of a plurality of base metal fittings 30 and joint members 40 that connect the metal fittings. After fixing the base metal fitting 30 to the roof 100, it is also possible to remove the joint member 40 (the same applies to the second embodiment described later). When removing the joint member, a metal member may be used.

  The solar power generation device 10 has a plurality of rows of solar cell modules 11 along the girder direction. In the present embodiment, the short sides of the solar cell module 11 having a substantially rectangular shape in plan view are substantially parallel to the eaves-ridge direction, and the short sides of the plurality of solar cell modules 11 constituting each row are substantially in contact with each other. Module is placed. The number of the solar cell modules 11 constituting the column extending in the girder direction increases in the column located on the eaves side of the roof 1 and is the same in some adjacent columns. However, the number, arrangement, etc. of the solar cell modules 11 constituting the solar power generation device 10 are not particularly limited.

  On the roof 100, a roof material 101 is disposed at least at a part of the periphery of the solar power generation device 10. On the other hand, the roof material 101 is not disposed under the solar power generation device 10. Examples of the roofing material 101 include Japanese tiles, Western tiles, flat tiles (flat ceramic tiles), slate tiles, and the like. The shape of the roof 100 on which the solar power generation device 10 can be installed is not particularly limited, and may be, for example, a dormitory roof, a square roof, or a gable roof.

  The solar cell module 11 has a cable 18 for taking out electric power from the solar cell panel 12. The solar battery panel 12 is filled between, for example, a plurality of solar battery cells, a glass substrate disposed on the light receiving surface side of the cell, a back sheet disposed on the back surface side of the cell, and each protection member. And a sealing material. A terminal box is generally provided on the back surface of the solar cell panel 12, and the cable 18 is drawn from the box. The frame 13 protects the edge of the solar cell panel 12 and is used for fixing the solar cell module 11 to the roof 100. The frame 13 is configured by connecting a plurality of frames with corner pieces, for example, and surrounds the four sides of the solar cell panel 12.

  The solar power generation device 10 further includes a base plate 14 laid on the field plate 102 of the roof 100. In the present embodiment, the crosspiece 16 is disposed on the base plate 14. The base metal fitting 30 constituting the horizontal crosspiece 16 passes through the base plate 14 and is directly screwed to the base plate 102. The base plate 14 is a sheet metal having a substantially rectangular shape in plan view, for example, and is fixed to the base plate 102 together with the base metal fitting 30. Although each base metal fitting 30 can be directly fixed on the base plate 102, the use of the base plate 14 makes it easier to align the crosspiece 16 and improves the workability.

  For example, two base plates 14 are provided on the back side of one solar cell module 11. The base plate 14 is disposed on the field plate 102 from one side (hereinafter, “left side”) of the roof 100 on the eaves side. On the base plate 14 disposed on the left side, a part of the base plate 14 disposed adjacent to the other side in the beam direction (hereinafter referred to as “right side”) is overlaid. In addition, a part of the base plate 14 disposed adjacent to the ridge side is overlaid on the base plate 14 disposed on the eaves side. In this way, the base plate 14 is sequentially installed from the left on the eaves side to the right on the ridge side. The base plate 14 may be disposed in order from the right side of the eaves side of the roof 100. In this case, a part of the base plate 14 disposed adjacent to the left side is superimposed on the base plate 14 on the right side.

  The base plate 14 (upper base plate) that is overlaid on the base plate 14 (lower base plate) is pressed so as not to be lifted up by the horizontal rail portion 16 installed on the lower base plate 14. That is, the end portion of the upper base plate 14 is inserted between the lower base plate 14 and the joint member 40 or into a concave portion 38 (see FIG. 5) of the base fitting 30 described later, and the horizontal rail portion 16 floats on the base plate 14. It also functions as a stop. Moreover, the side plate 15 which functions as a drainer is provided in the both ends of the horizontal direction of the solar power generation device 10. In general, a waterproof sheet is provided on the base plate 102, and a waterproof tape is attached to the edge or the like of the base plate 14 (both not shown).

  As described above, the horizontal crosspiece 16 is arranged on the base plate 14 so that the longitudinal direction thereof is along the girder direction of the roof 100. One horizontal crosspiece 16 is arranged at the ridge side end of each base plate 14. It is preferable that the crosspieces 16 arranged adjacent to each other in the girder direction are connected to each other and arranged in a line along the girder direction. The length of the horizontal crosspiece 16 is set to be substantially the same as the horizontal length of the base plate 14, for example. Since each base plate 14 is arranged with the end of the right plate overlapped with the end of the left plate, the horizontal beam 16 is arranged on the right side of each plate, so that the horizontal beam adjacent to the beam direction is arranged. The parts 16 can be connected to each other.

  An eaves edge cover 17 is provided at the eaves side end of the solar power generation device 10. An intermediate cover 25 is provided between the two solar cell modules 11. The eaves cover 17 is a metal member that extends in the beam direction of the roof 100 and has, for example, substantially the same length as the long side of the solar cell module 11. The elongate eaves edge cover 17 is attached to the eaves edge side crosspiece 104 installed on the eaves edge base plate 103. The eaves-end base plate 103 is shorter than the base plate 14 in the vertical direction, and is provided only at the eaves-side end of the solar power generation device 10. The eaves covers 17 adjacent to each other in the girder direction are preferably connected to each other.

  The eaves crosspiece 104 is composed of, for example, a base metal fitting and a resin joint member, like the horizontal crosspiece 16. Similarly to the base metal fitting 30, the base metal fitting preferably has a pedestal part on which a bolt guide rail part and an engaging part described later are formed, and a fixing part screwed to the base plate 102. In addition, you may provide the elongate body which does not have a resin-made joint member in which the several base metal fitting was connected by the eaves end cover 17 in the eaves side edge part of the solar power generation device 10. FIG.

  On the back side of one solar cell module 11, at least two horizontal beam portions 16, or the horizontal beam portions 16 and the eaves edge horizontal beam portions 104 are arranged one by one. And the solar cell module 11 is supported by the some base metal fixture which comprises two horizontal rail parts. One solar cell module 11 is supported by at least four, preferably eight base fittings.

  With reference to FIGS. 3 to 5, the configuration of the crosspiece 16 will be described in detail. FIG. 3 is a perspective view showing the crosspiece 16 and the vicinity thereof. 4 is a view showing a state where the joint member 40 is removed from the base metal fitting 30, and FIG. 5 is a cross-sectional view taken along line AA in FIG.

  As illustrated in FIG. 3 to FIG. 5, the horizontal rail portion 16 includes two base metal members 30 and a long joint member 40 that connects the base metal members 30. Two base metal fittings 30 arranged at the eaves side end portion of the base plate 14 are located one on the left side of the plate and the other on the right side of the plate, and are connected by a joint member 40 to be integrated as a horizontal beam portion 16. It has become. In other words, the horizontal crosspiece 16 is configured by assembling two short base fittings 30 on one long joint member 40.

  Although details will be described later, by using the crosspiece 16 in which the two base metal fittings 30 are integrated, the workability is improved as compared with the case where the base metal fittings 30 are individually arranged. Further, since the resin joint member 40 is lightweight, the weight of the roof 100 is hardly increased. In addition, since the resin-made joint member 40 is inexpensive, it is advantageous in terms of cost compared to, for example, a case where a long metal fitting is used.

  As described above, the horizontal rail portion 16 is installed on the roof 100 by fixing the base metal fittings 30 to the base plate 102. Each base metal fitting 30 is fixed to the base plate 102 using screws 39 penetrating the base plate 14. As the screw 39, for example, a tapping screw is used. The joint member 40 may be directly fixed to the base plate 102, but preferably only the base metal fitting 30 is fixed to the base plate 102 from the viewpoint of workability and the like. The joint member 40 is fixed to the base metal fitting 30 and is not fixed to the base plate 14 and the base plate 102. The base metal fitting 30 and the joint member 40 preferably have engaging portions that engage with each other.

  Both of the base metal fitting 30 and the joint member 40 have a shape that is long in the longitudinal direction of the horizontal rail portion 16 (the girder direction of the roof 100). The length of the base metal fitting 30 is shorter than the joint member 40, for example, is 1/3 or less of the length of the joint member 40. The joint member 40 extends from the end of the base metal fitting 30 to both sides in the lateral direction, and is connected to another joint member 40 that is adjacently disposed.

  The base metal fitting 30 includes a pedestal portion 31 on which the frame 13 of the solar cell module 11 is placed and a fixing portion 32 that is fixed to the base plate 102. The height of the pedestal portion 31 is set so that, for example, the height of the light receiving surface (upper surface) of the solar cell module 11 is approximately the same as the height of the upper surface of the roof material 101 disposed around. The pedestal portion 31 includes an upper surface portion 31a on which the frame 13 is placed, and side surface portions 31b extending downward from both longitudinal ends of the upper surface portion 31a. The fixing part 32 extends from the eaves side end of the pedestal part 31 to the eaves side and is screwed to the base plate 102. A plurality of through holes (not shown) through which the screws 39 are inserted are formed in the fixing portion 32.

  A bolt guide rail portion 33 that holds the bolt 27 is formed on the pedestal portion 31 along the longitudinal direction. As will be described later, the bolts 27 are used to fix the frame 13 to the base metal fitting 30. The bolt guide rail portion 33 slidably holds the head of the bolt 27 so that the shaft portion of the bolt 27 stands on the upper surface (upper surface portion 31 a) of the pedestal portion 31 on which the frame 13 is placed. The bolt guide rail portion 33 includes a groove 34 formed on the upper surface portion 31 a of the pedestal portion 31, and an overhang portion 35 that protrudes so as to block a part of the groove 34 from both sides of the groove 34. The head portion of the bolt 27 is accommodated in the groove 34 so as not to be pulled upward by the overhanging portion 35.

  The pedestal portion 31 is formed with a step portion 36 as the engagement portion. The step portion 36 is formed on each side surface portion 31 b of the pedestal portion 31. The step portion 36 is a portion where the tip of the leg portion 42 that is an engaging portion of the joint member 40 is hooked, that is, a fixing portion of the joint member 40 in the base metal fitting 30. The step portion 36 is formed, for example, by denting the lower portion of the side surface portion 31b inward from the upper portion. A recess 38 into which the end of the base plate 14 is inserted is formed in the lower portion of the pedestal 31. The recess 38 is formed on the ridge side of the pedestal portion 31, and the base plate 14 disposed on the ridge side of the pedestal portion 31 is inserted into the recess 38. The stepped portion 36 and the recessed portion 38 are preferably formed over the entire length of the pedestal portion 31.

  The joint member 40 is a long resin member having a substantially flat plate-like base portion 41 and a pair of leg portions 42 extending downward from both ends in the width direction of the base portion 41. Each leg portion 42 is formed substantially perpendicular to the base portion 41, and the joint member 40 has a substantially U-shaped cross section in the width direction. An extension portion 44 extending in the longitudinal direction from the end of the leg portion 42 is provided at the longitudinal end portion of the joint member 40. The extending portion 44 is inserted into the inside of another joint member 40 that is adjacently disposed, and is used to connect the joint members 40 to each other. In addition, the shape of the extension part 44 is not specifically limited, For example, you may extend from the end of the base 41.

  The joint member 40 has a plurality of openings 43 arranged in the longitudinal direction. The number of openings 43 corresponds to the number of base metal fittings 30 connected by the joint member 40. In the present embodiment, two openings 43 are formed in the base 41. Since the portion of the joint member 40 in which the opening 43 is formed is composed of only a pair of leg portions 42, for example, it can be said that the three base portions 41 are arranged at intervals in the longitudinal direction of the joint member 40. The joint member 40 is fitted to the base metal fitting 30 from the upper surface portion 31 a side of the pedestal portion 31. And each base metal fitting 30 has an upper surface exposed from the opening 43 on which the frame 13 of the solar cell module 11 is placed.

  By fitting the pedestal portion 31 into the opening 43 of the joint member 40, the leg portion 42 formed at the edge of the opening 43 is fixed to the side surface portion 31 b of the pedestal portion 31. The upper surface of the base metal fitting 30 is preferably located on the same plane as the upper end of the joint member 40 or above the upper end so as not to affect the fixing of the frame 13 to the base metal fitting 30. In this case, since the portion located at the edge of the opening 43 of the base portion 41 is hooked and engaged with the pedestal portion 31, the relative movement of the base metal fitting 30 and the joint member 40 with respect to the longitudinal direction of the horizontal rail portion 16 is prevented. The

  The leg portion 42 functions as the engaging portion and is hooked on the step portion 36 that is the engaging portion of the base metal fitting 30. The distal end portion of each leg portion 42 is bent inward and has a substantially L-shaped cross section. For this reason, by fitting the pedestal portion 31 into the opening 43, the leg portions 42 are respectively hooked on the step portions 36 formed on the side surface portions 31b of the pedestal portion 31, whereby the joint member 40 is pulled upward. It is fixed to the base metal fitting 30 in a state without it. The interval between the leg portions 42 is substantially the same as the width of the pedestal portion 31, for example. Each leg portion 42 is fixed to each side surface portion 31b with the pedestal portion 31 sandwiched from both sides in the width direction. The leg portion 42 may be fixed to the base metal fitting 30 using a fastening member such as a screw, but is preferably fixed without using a fastening member.

  The joint member 40 includes a holding portion 45 that holds the cable 18 drawn from the back side of the solar cell panel 12. The holding portion 45 is formed on the leg portion 42 located between the two openings 43. The holding portion 45 is a substantially semicircular recess that opens toward the distal end side of the leg portion 42, and the distal end side of the leg portion 42 is preferably slightly narrowed. The cable 18 of each solar cell module 11 is connected with the cable 18 of the module arrange | positioned adjacently, for example. Since a gap is provided between the joint member 40 and the base plate 14, the cable 18 can be routed under the joint member 40. However, when the cable 18 is fitted into the holding portion 45, for example, the cable 18 is better organized. Workability is improved. Note that the shape, arrangement, and the like of the holding portion 45 are not particularly limited, and can be changed as appropriate according to the wiring specifications.

  FIG. 6 is a vertical cross-sectional view of the crosspiece 16 of the solar power generation device 10 and the vicinity thereof. In FIG. 6, of the two solar cell modules 11 fixed to the base metal fitting 30 of the horizontal rail portion 16, the solar cell module 11 </ b> A is disposed on the eave side, and the solar cell module is disposed on the ridge side. 11B.

  As illustrated in FIG. 6, the frame 13 </ b> A of the solar cell module 11 </ b> A and the frame 13 </ b> B of the solar cell module 11 </ b> B are placed on the base metal fitting 30. Frames 13A and 13B have hollow main body portions 20A and 20B, flange portions 21A and 21B standing on the upper surface of the main body portion, and flange portions 22A and 22B projecting outward, respectively. Since the cross-sectional shapes of the frames 13A and 13B are the same as each other, the contents common to these will be described below using the frame 13A as an example.

  The flange portion 21A extends straight upward from the outside of the main body portion 20A, and is bent inward in the middle to have a substantially L-shaped cross section. An inner groove, which is a gap into which the solar cell panel 12A can be inserted, is formed between the upper surface of the main body portion 20A and the flange portion 21A. The flange portion 22A has a substantially L-shaped cross section and projects outward from the lower end of the main body portion 20A. In the example shown in FIG. 6, the intermediate cover 25 is installed between the solar cell modules 11A and 11B.

  The frame 13 </ b> A placed on the upper surface of the base metal fitting 30 is fixed to the metal fitting using the presser metal fitting 24. The presser fitting 24 has a through hole through which the shaft portion of the bolt 27 standing on the base metal fitting 30 is inserted. The presser fitting 24 has a substantially L-shaped cross section, and presses the flange portion 22 </ b> A of the frame 13 </ b> A to the base metal fixture 30. A presser fitting 24, a washer 29, and a nut 28 are attached to the shaft portion of the bolt 27 in order from the bottom, and the frame 13 </ b> A is fixed to the base metal fitting 30 by tightening the nut 28. The intermediate cover 25 is fitted between the solar battery modules 11 </ b> A and 11 </ b> B by being fitted into a cover receiver 26 fixed to the shaft portion of the bolt 27 together with the presser fitting 24.

  The frame 13B is disposed on the ridge side of the bolt 27. The frame 13B is fixed to the upper surface of the base metal fitting 30 by inserting the flange portion 22B of the frame 13B between the presser fitting 24 and the upper surface of the base metal fitting 30. That is, the presser fitting 24 protrudes above the flange portion 22B, thereby preventing the frame 13B from coming off upward. The frame 13B installed at the ridge side end of the solar cell module 11B is placed on, for example, the base metal 30 or other base metal disposed on the ridge side, and is fixed to the metal fitting in the same manner as the frame 13A.

  The solar power generation device 10 lays the base plate 14 and the like on the base plate 102, arranges the horizontal rail portion 16 thereon, and fixes the base metal fitting 30 of the horizontal rail portion 16 together with the plate to the base plate 102, It is constructed by fixing the module frame 13 to each bracket. As described above, the solar cell module 11 is fixed on the base metal fitting 30 in order from the eaves side using the holding metal fitting 24.

  In the construction procedure of the photovoltaic power generation apparatus 10, at least two base metal fittings 30 are connected by a joint member 40, and a long body (horizontal beam portion 16) composed of the metal fittings and the joint member 40 is attached to the roof 100. The process of fixing each said metal fitting to the roof 100 after arrange | positioning on is included. In this case, it is not necessary to adjust the interval between the base metal parts 30 connected by the joint member 40, and the construction is easier than in the case where the base metal parts 30 are individually arranged. In other words, in the construction of the solar power generation measure 10, the crosspieces 16 are arranged along the beam direction of the roof 100, but the interval between the base metal fittings 30 arranged in the beam direction is adjusted in advance by the joint member 40. Moreover, it is only necessary to adjust the interval between the horizontal beam portions 16 with respect to the eave building direction of the roof 100, and it is necessary to adjust the interval between the plurality of base metal fittings 30 constituting each horizontal beam portion 16 in the eave building direction. There is no. The joint member may be removed after each base metal fitting 30 is screwed to the base plate 102, but the resin-made joint member 40 is lightweight and inexpensive, so it is not necessary to remove it.

  FIG. 7 is an exploded perspective view of the photovoltaic power generation apparatus 50 according to the second embodiment. In the following, the same components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted, and differences from the first embodiment will be mainly described.

  As illustrated in FIG. 7, the solar power generation device 50 includes a solar cell panel 12 and a module frame 53 (hereinafter referred to as “frame 53”) installed at an edge of the panel. 51 is provided. Furthermore, the solar power generation device 50 includes a plurality of base metal fittings 70 on which the frame 53 is placed and a resin joint member 80 that connects at least two base metal fittings 70 while being fixed to the roof 110.

  The solar power generation device 50 includes a vertical beam portion 56 disposed on the back side of the solar cell module 51. A plurality of vertical crosspieces 56 are provided along the eaves direction of the roof 110. The vertical crosspiece 56 is a long body composed of a plurality of base metal fittings 70 and joint members 80 that connect the metal fittings. In addition, the number, arrangement | sequence, etc. of the solar cell module 51 which comprise the solar power generation device 50 are not specifically limited.

  The solar power generation device 50 further includes a fixing bracket for fixing the frame 53 to the base bracket 70. And the base metal fitting 70 has the guide rail part 74 which supports a fixed metal fitting so that sliding is possible. The frame 53 has an outer groove (see FIG. 10 described later) that opens toward the outside of the solar cell module 51, and the fixture is inserted into the outer groove. In the present embodiment, the first metal fitting 66 and the second metal fitting 67 are used as the fixing metal fittings. The solar power generation device 50 includes a third metal fitting 68 that is not inserted into the outer groove of the frame 53 but is used for fixing the frame 53 to the base metal fitting 70.

  On the roof 110, a roof material 111 is laid on a field board 112. The roof material 111 is also disposed under the solar power generation device 50. The roof material 111 is, for example, a slate tile. Since the roof material 111 is arranged in the eaves ridge direction while the roof material 111 on the ridge side is overlapped with a part of the roof material 111 on the eave side, a step is formed in a portion where the roof material 111 overlaps. The solar power generation device 50 preferably includes a spacer 58 that fills the step. The base metal fitting 70 constituting the vertical beam portion 56 is placed on the spacer 58 and fixed to the roof 110. The thickness of the spacer 58 is gradually reduced from the ridge side toward the eave side. By providing such a spacer 58, the vertical crosspiece 56 can be stably fixed along the inclination of the roof 110.

  As described above, the vertical crosspiece 56 is arranged on the roof 110 such that the longitudinal direction thereof is along the eaves-ridge direction. Although the length of the vertical beam portion 56 is not particularly limited, it is preferable that the vertical beam portion 56 has a length extending over a plurality of solar cell modules 51. The vertical crosspieces 56 are arranged substantially in parallel with each other at an appropriate interval in the beam direction of the roof 110. On the back side of one solar cell module 51, at least two vertical crosspieces 56 are arranged. One solar cell module 51 is supported by at least four base fittings 70.

  With reference to FIG.8 and FIG.9, it demonstrates in full detail about the structure of the vertical crosspiece 56. FIG. 8 is a perspective view of the vertical crosspiece 56, and FIG. 9 is a cross-sectional view taken along the line BB in FIG.

  As illustrated in FIGS. 8 and 9, the vertical beam portion 56 includes three base metal members 70 and two resin joint members 80 that connect the base metal members 70. In other words, the vertical crosspiece 56 is configured by assembling three short base fittings 70 to two long joint members 80. In FIG. 8, the vertical beam portion 56 including the three joint members 80 and the two joint members 80 is illustrated. However, the length of the vertical beam portion 56 is increased by increasing the number of the base metal members 70 and the joint members 80. It can also be extended.

  In the vertical cross section 56, the two joint members 80 have, for example, substantially the same length, and are connected via a base metal fitting 70 at the center in the longitudinal direction. And one base metal fitting 70 is being fixed to the eaves side edge part and the ridge side edge part of each joint member 80, respectively. Each base metal fitting 70 is provided at substantially equal intervals in the longitudinal direction of the vertical crosspiece 56. For this reason, for example, by aligning one of the base metal fittings 70 constituting the vertical beam portion 56 with the eaves side of the roof 110, the other two base metal fittings 70 are arranged along the eaves building direction on the ridge side of the metal fittings. Arranged at substantially equal intervals. The joint member 80 may have a length extending over all the base fittings 70, but is preferably divided into two parts from the viewpoint of handleability and the like.

  Both the base metal fitting 70 and the joint member 80 have a shape that is long in the longitudinal direction of the vertical crosspiece 56 (the eaves-ridge direction of the roof 110). The length of the base metal fitting 70 is shorter than the joint member 80, for example, 1/3 or less of the length of the joint member 80. The joint member 80 is fixed to the base metal fitting 70 and is not fixed to the field plate 112. The base metal fitting 70 and the joint member 80 each preferably have an engaging portion that engages with each other.

  The base metal fitting 70 includes a base portion 71 on which the fixing metal fitting is placed, a pair of flange portions 72 erected on the upper surface of the base portion 71, and a pair of flange portions 73 projecting laterally from the lower portion of the base portion 71. The base metal fitting 70 is preferably made of a metal material mainly composed of aluminum, and is manufactured, for example, by extrusion molding of an aluminum alloy. The base 71 has an internal space that is open at both ends in the longitudinal direction, and includes an upper wall 71a, a lower wall 71b, and a pair of side walls 71c. The pair of side wall portions 71c are formed substantially perpendicular to the upper wall portion 71a and the lower wall portion 71b at both ends in the width direction of the upper wall portion 71a and the lower wall portion 71b. The lower wall portion 71 b forms the bottom surface of the base metal fitting 70 together with the flange portion 73.

  Two through holes 75 through which pins 69 (see FIG. 10 described later) used for positioning of the fixing metal are inserted are formed in the upper wall portion 71a. The shaft portion of the pin 69 inserted through the through hole 75 is accommodated in the internal space of the base portion 71. Since the joint member 80 is inserted into the internal space of the base metal fitting 70 as will be described later, the pin 69 is preferably provided near the center in the longitudinal direction of the base metal fitting 70 so as not to interfere with the joint member 80.

  A through hole 77 is formed in the base metal fitting 70 as the engaging portion. The through holes 77 are respectively formed in the side wall portions 71 c of the base portion 71 at both longitudinal ends of the base metal fitting 70. The through hole 77 is a portion where the projection 83 which is an engaging portion of the joint member 80 is fitted and hooked, that is, a fixing portion of the joint member 80 in the base metal fitting 70. A concave portion or a step portion may be formed in the side wall portion 71 c instead of the through hole 77.

  The collar portion 72 is formed at both ends in the width direction of the upper wall portion 71a. The collar portion 72 extends straight upward from both ends in the width direction of the base portion 71, and is bent inward in the middle to have a substantially L-shaped cross section. The upper wall portion 71a and the flange portion 72 of the base portion 71 constitute a guide rail portion 74 that slidably supports the fixing bracket. A part of the first metal fitting 66, the second metal fitting 67, and the third metal fitting 68 is inserted between the base portion 71 and the flange portion 72, and is supported so as to be slidable in the longitudinal direction of the base metal fitting 70 in a state where it does not come out upward. The

  The flange portion 73 is a portion that is fixed to the base plate 112 via the spacer 58. The flange portion 73 projects laterally from the lower end portion of the base portion 71 and is formed on both sides in the width direction of the base metal fitting 70. The lower wall portion 71b of the base portion 71 and the lower surfaces of the flange portions 73 are substantially flat surfaces that are continuous without forming a step at the boundary positions of the respective portions, and contact the upper surface of the spacer 58 without any gap, for example. As described above, each flange portion 73 forms the substantially flat bottom surface of the base metal fitting 70 together with the lower wall portion 71b. Each flange portion 73 has a through hole 76 through which a screw 78 (see FIG. 10 described later) is inserted, and is screwed to the base plate 112.

  The joint member 80 is a long resin-made member having a substantially flat plate-like base portion 81 and a pair of leg portions 82 extending downward from both ends of the base portion 81 in the width direction. Each leg portion 82 is formed substantially perpendicular to the base portion 81, and the joint member 80 has a substantially U-shaped cross section in the width direction. The joint member 80 is inserted into the internal space of the base 71 that constitutes the base metal fitting 70. The joint member 80 is inserted into the base portion 71 such that the base portion 81 is along the inner surface of the upper wall portion 71a of the base portion 71 and the leg portion 82 is along the inner surface of the side wall portion 71c.

  The joint member 80 has, as the engaging portion, a protrusion 83 that fits into a through hole 77 that is an engaging portion of the base metal fitting 70 and is caught on the edge of the hole. The protrusions 83 are formed on the outer surfaces of the leg portions 82 at both ends in the longitudinal direction of the joint member 80 inserted into the internal space of the base metal fitting 70. When the joint member 80 is inserted into the internal space of the base metal fitting 70, the projection 83 is fitted in the through hole 77 formed in the side wall portion 71 c and is caught on the edge of the through hole 77. As a result, the joint member 80 is fixed to the base metal fitting 70 and cannot be easily removed.

  As in the case of the joint member 40, the joint member 80 may have a holding portion that holds the cable 18 drawn from the back side of the solar cell panel 12. The holding part can be formed in the leg part 82, for example.

  FIG. 10 is a vertical cross-sectional view of the base metal part of the solar power generation device 50 (the boundary position between the solar cell modules 51A and 51B). In FIG. 10, of the two solar cell modules 11 fixed to the base metal fitting 70, the one disposed on the eave side is defined as a solar cell module 51 </ b> A, and the one disposed on the ridge side is defined as a solar cell module 51 </ b> B.

  As illustrated in FIG. 10, the base metal fitting 70 is placed on the spacer 58 and fixed to the field board 112 using screws 78. The spacer 58 is formed with a through hole 59 through which the screw 78 is inserted. As the screw 78, for example, a wood screw is used. On the base metal fitting 70, the frame 53A of the solar cell module 51A and the frame 53B of the solar cell module 51B are mounted, and the frames 53A and 53B are fixed to the base metal fitting 70 using a fixing metal fitting.

  Frames 53A and 53B have hollow main body portions 60A and 60B, inner grooves 62A and 62B that open toward the inside of the module, and outer grooves 64A and 64B that open toward the outside of the module, respectively. Each of the frames 53A and 53B has inner flange portions 65A and 65B projecting inside the module. Since the cross-sectional shapes of the frames 53A and 53B are the same, the contents common to these will be described below using the frame 53A as an example.

  The frame 53A has a first flange 61A erected on the upper surface of the main body 60A, and an inner groove that is a gap into which the solar cell panel 12A can be inserted between the upper surface of the main body 60A and the first flange 61A. 62A is formed. The first flange portion 61A extends straight upward from the outside of the main body portion 60A, and is bent inward in the middle to have a substantially L-shaped cross section. The frame 53A has a second flange 63A standing on the lower surface of the main body 60A, and is a gap into which the second metal fitting 67 can be inserted between the lower surface of the main body 60A and the second flange 63A. An outer groove 64A is formed. The second flange portion 63A extends straight downward from the inside of the main body portion 60A, and is bent outward in the middle to have a substantially L-shaped cross section.

  A through-hole through which a pin 69 is inserted is formed in the base metal fitting 70, the first metal fitting 66, and the third metal fitting 68. The first metal fitting 66 and the third metal fitting 68 are positioned on the base metal fitting 70 by the pin 69. The For example, a bolt is used for the pin 69. The first metal fitting 66 is inserted into the outer groove 64B of the frame 53B, and the second metal fitting 67 that engages with the third metal fitting 68 is inserted into the outer groove 64A of the frame 53A. The first metal fitting 66 fixes the frame 53 installed at the eaves side end of the solar cell module 51 to the base metal fitting 70. The second metal fitting 67 fixes the frame 53 installed at the ridge side end of the solar cell module 51 to the base metal fitting 70. The third metal fitting 68 fixes the frame 53 installed at the ridge side end of the module together with the second metal fitting 67 to the base metal fitting 70.

  As described above, the solar power generation device 50 can be constructed by a simple method of attaching the fixing bracket to the guide rail portion 74 of the base bracket 70 and then inserting the fixing bracket into the outer groove of the frame 53. And the frame 53 of each solar cell module 51 should just be arrange | positioned on the base metal fitting 70 in order from the eaves side of the roof 100. FIG. In the case of the solar power generation device 50, there is no work in a posture as illustrated in FIG. 11, and construction can be performed in a relatively short time. Further, in the construction procedure of the solar power generation device 50, as in the case of the solar power generation device 10, the vertical beam portion 56 that is a long body in which a plurality of base metal fittings 70 are connected by the joint member 80 is provided on the roof 110. A step of fixing each of the metal fittings to the roof 110 after being arranged in the step.

  As described above, the solar power generation devices 10 and 50 are superior in workability compared to the conventional solar power generation device 200 illustrated in FIG. As shown in FIG. 11, in the case of the photovoltaic power generation apparatus 200, the base metal fittings 202 that support the solar cell module 201 are scattered, so that the positioning of the base metal fittings 202 is troublesome and the installation of the metal fittings takes time. Take it. On the other hand, in the case of the photovoltaic power generation devices 10 and 50, after connecting a plurality of base metal fittings with joint members and arranging a long body composed of the metal fittings and the joint members on the roof, Each bracket can be fixed to the roof. For this reason, it becomes unnecessary to adjust the space | interval of each base metal fitting connected with the joint member, and construction is easy compared with the case where a base metal fitting is arrange | positioned separately. For example, if one base metal fitting is arranged at a target location on the roof, other base metal fittings connected by joint members are also arranged at the target location.

  On the other hand, in the case of the solar power generation device 300 illustrated in FIG. 12, by using the long base metal fitting 301, the installation of the metal fitting is easier and the workability is improved as compared with the case of the solar power generation device 200. However, the weight of the roof increases, and the costs such as material costs also increase. On the other hand, in the case of the solar power generation device 10, by using a resin joint member, it is possible to reduce the weight of the roof and the cost such as material costs.

  DESCRIPTION OF SYMBOLS 10 Solar power generation device, 11, 11A, 11B Solar cell module, 12, 12A, 12B Solar cell panel, 13, 13A, 13B Module frame, 14 Base plate, 15 Side plate, 16 Side rail, 17 Front cover, 18 Cable , 20A, 20B body part, 21A, 21B collar part, 22A, 22B collar part, 24 presser fitting, 25 intermediate cover, 26 cover support, 27 bolt, 28 nut, 29 washer, 30 base bracket, 31 base part, 31a upper surface Part, 31b side part, 32 fixing part, 33 bolt guide rail part, 34 groove, 35 overhang part, 36 step part, 38 recessed part, 39 screw, 40 joint member, 41 base part, 42 leg part, 43 opening part, 44 extension Out part, 45 Holding part, 50 Solar power generation device, 51, 51 , 51B Solar cell module, 53, 53A, 53B Module frame, 56 Vertical beam, 58 Spacer, 59 Through hole, 60A, 60B Body, 61A, 61B First flange, 62A, 62B Inner groove, 63A, 63B No. 2 flanges, 64A, 64B outer groove, 65A, 65B inner flange, 66 first bracket, 67 second bracket, 68 third bracket, 69 pin, 70 base bracket, 71 base, 71a upper wall, 71b lower wall Part, 71c side wall part, 72 flange part, 73 flange part, 74 guide rail part, 75, 76, 77 through hole, 78 screw, 80 joint member, 81 base part, 82 leg part, 83 protrusion, 100, 110 roof, 101 , 111 Roofing material, 102,112 Base plate, 103 base plate, 104 crosshead

Claims (8)

A solar cell module having a solar cell panel and a module frame installed at an edge of the panel;
A plurality of base brackets fixed to the roof and on which the module frame is mounted;
A resin joint member connecting at least two of the base metal fittings;
A solar power generation device comprising: The joint member has a plurality of openings arranged in the longitudinal direction thereof,
2. The photovoltaic power generation apparatus according to claim 1, wherein an upper surface on which each module frame is placed is exposed from each opening. Each base metal fitting has an internal space whose both ends in the longitudinal direction are open,
The solar power generation apparatus according to claim 1, wherein the joint member is inserted into the internal space.   The said base metal fitting and the said joint member are photovoltaic power generation apparatuses of any one of Claims 1-3 which each have an engaging part engaged with each other. The solar cell module has a cable for taking out electric power from the solar cell panel,
The said joint member is a solar power generation device of any one of Claims 1-4 which has a holding part holding the said cable. A base plate laid on the roof top plate,
The elongate body comprised by the said base metal fitting and the said joint member which connects the said each metal fitting is arrange | positioned along the girder direction of the said roof on the said base plate, Any one of Claims 1-5 The solar power generation device of Claim 1. A fixing bracket for fixing the module frame to the base bracket;
The base bracket has a guide rail portion that slidably supports the fixed bracket,
The elongate body comprised by the said joint member which connects the said some metal fittings and the said each metal fitting is arrange | positioned along the eaves-ridge direction of the said roof, In any one of Claims 1-5 The solar power generation device described. A solar cell module having a solar cell panel and a module frame installed at an edge of the panel;
A plurality of base brackets on which the module frame is mounted;
A construction method of a solar power generation apparatus comprising:
At least two base fittings are connected by a joint member, a long body composed of the base fitting and the joint member is disposed on the roof, and then the base fitting is fixed to the roof. Photovoltaic generator construction method.

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