JPWO2017145500A1 - Solar power plant - Google Patents

Abstract

A photovoltaic power generation apparatus 10 that is one aspect of the present disclosure includes a solar cell module 11, a gantry frame 14 on which the module frame 13 is mounted, a fixing bracket for fixing the module frame 13 to the gantry frame 14, and a roof material 102. And a plurality of anchors 80 each having a shaft portion 82 that protrudes to the front side of the roof material. The first gantry frame 30 is provided across at least two anchors 80, and is a long first gantry frame 30 fixed to the shaft portion 82 of the anchor 80, and a guide rail portion that slidably supports the fixing bracket. 44 and has a second frame 40 that is shorter than the first frame 30 and is fixed to the top of the first frame 30.

Description

  The present disclosure relates to a photovoltaic power generation apparatus.

  Patent Document 1 is provided with a pedestal portion fixed to a roof base plate, an anchor provided on the pedestal portion, and having a shaft portion protruding from the through hole of the roof material to the front side of the roof material, and fixed to the shaft portion of the anchor. A mounting device for a solar cell module including a mounting frame is disclosed. In the solar power generation device, the solar cell module is fixed on the gantry frame by using a presser fitting that presses the flange portion that protrudes outside the module frame.

JP 2014-194133 A

  By the way, it is calculated | required that a solar power generation device is excellent in workability while being able to fix a solar cell module firmly with respect to a roof. The solar power generation device disclosed in Patent Document 1 has room for improvement particularly in terms of workability.

  A photovoltaic power generation apparatus according to the present disclosure includes a solar cell module, a solar cell module having a module frame installed at an edge of the panel, a gantry frame on which the module frame is mounted, and the module frame as a gantry frame. A plurality of anchors having a fixing bracket for fixing, a pedestal portion fixed to the roof base plate, and a shaft portion standing on the pedestal portion and penetrating through the roof material and projecting to the front side of the roof material The module frame has an outer groove that opens toward the outside of the module, the fixing bracket is inserted into the outer groove, and the gantry frame is provided across at least two anchors. A long first frame that is fixed to the frame, and a guide rail that slidably supports the fixing bracket. The first frame is shorter than the first frame. And a second frame-frame that is fixed to the upper portion of the gantry frame.

  According to the solar power generation device which is one mode of the present disclosure, it is easy to attach the solar cell module to the roof, and excellent workability is obtained. In addition, the solar cell module can be firmly fixed to the roof.

It is a disassembled perspective view which shows the solar power generation device which is an example of embodiment. It is AA sectional view taken on the line in FIG. In the solar power generation device which is an example of embodiment, it is a figure which shows the cross section of the boundary position of two solar cell modules adjacently arranged by the eaves-ridge direction. It is a perspective view which shows the 1st metal fitting which is an example of embodiment. It is a perspective view which shows the 2nd metal fitting which is an example of embodiment. It is a perspective view which shows the 3rd metal fitting which is an example of embodiment. It is BB sectional drawing in FIG. It is a disassembled perspective view which shows the mount frame and anchor which are an example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is sectional drawing of the mount frame which is another example of embodiment. It is a figure which shows a mode that the conventional solar power generation device is constructed.

  According to the photovoltaic power generation apparatus that is one aspect of the present disclosure, a solar battery is obtained by a simple method in which a fixing bracket is inserted into the guide rail portion of the second mount frame and the fixing bracket is inserted into an outer groove of the module frame. The module can be fixed to the gantry frame. The second frame is attached to an anchor fixed to the base plate via the first frame. Since the second gantry frame can be fixed to the first gantry frame on the ground, the first gantry frame with the second gantry frame may be attached to the anchor on the roof. Although the details will be described later, in the conventional structure in which the solar cell module is fixed to the gantry frame attached to the anchor using the presser bracket, the work of fixing each presser bracket is troublesome, and the posture is unreasonable. Work may be forced (see FIG. 15 described later). The solar power generation device which is one mode of the present disclosure has excellent workability with a small work load at the time of construction as compared with the conventional structure while maintaining stable fixation of the solar cell module to the roof.

  In the photovoltaic power generation apparatus that is one aspect of the present disclosure, a first gantry frame provided across a plurality of anchors and a second gantry frame that is shorter than the first gantry frame are used in combination. The first frame has a simple structure compared to the second frame having the guide rail portion. The second frame is preferably manufactured by extruding a metal material mainly composed of aluminum, but the first frame is made of, for example, a relatively inexpensive steel plate. That is, by using the expensive second frame only for the portion where the fixing bracket is attached, the length is shortened, and the inexpensive first frame is extended over each anchor, thereby impairing the workability and fixability. Material costs can be greatly reduced without any problems.

  Further, since the strength of the second gantry frame can be taken into the strength of the first gantry frame, the load resistance of the first gantry frame is increased. Or the material usage-amount of a 2nd mount frame can be reduced, ensuring load resistance. A force (negative pressure) for lifting the module acts on the second frame to which the solar cell module is fixed. However, since the second frame is assembled to the first frame, it is resistant to negative pressure. Improves.

  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 embodiment illustrated below, an elongated frame is disposed along the eaves direction of the roof. In the following, the direction of fixing brackets along the roof eaves direction is sometimes referred to as “vertical direction”, and the direction of fixing brackets along the roof girder direction (direction perpendicular to the roof eaves direction) is The direction of the fixing bracket along the direction perpendicular to the roof base plate is referred to as “vertical direction”. The longitudinal direction of the gantry frame and the vertical direction are the same direction, and the width direction of the gantry frame and the horizontal direction are the same direction. In the drawing, the direction of the eaves and the vertical direction of the roof are indicated by an arrow α, the girder and horizontal directions are indicated by an arrow β, and the vertical direction is indicated by an arrow γ.

  FIG. 1 is an exploded perspective view of a photovoltaic power generation apparatus 10 that is an example of an embodiment. As illustrated in FIG. 1, the solar power generation device 10 includes a solar cell panel 12 and a module frame 13 (hereinafter referred to as “frame 13”) installed at an edge of the panel. 11. Furthermore, the solar power generation device 10 is fixed to a gantry frame 14 on which the frame 13 is placed, a fixing bracket for fixing the frame 13 to the gantry frame 14, and a base plate 101 (see FIG. 2 described later) of the roof 100. A plurality of anchors 80. In FIG. 1, for convenience of explanation, regarding two solar cell modules 11 arranged adjacent to each other in the eaves-ridge direction, the modules arranged on the eaves side are the solar cell modules 11A, and the modules arranged on the building side are the solar cell modules 11B. And

  The solar power generation device 10 is configured by arranging a plurality of solar cell modules 11 side by side on an elongated frame 14. The gantry frame 14 includes a first gantry frame 30 provided across at least two anchors 80 and a second gantry frame 40 including a guide rail portion 44 that slidably supports the fixing bracket. The first gantry frame 30 is fixed to the shaft portion 82 of each anchor 80. The second frame 40 is shorter than the first frame 30 and is fixed to the upper part of the first frame 30.

  The gantry frame 14 is disposed on the roof material 102. On the roof 100, a roof material 102 is laid on a field board 101. The roofing material 102 is not particularly limited, but FIG. 1 shows a Japanese tile. In the present embodiment, the shaft portion 82 of the anchor 80 protrudes to the front side of the roof material 102 through the through-hole 103 formed in a part of the roof material 102, and the gantry frame 14 is formed on the protruding portion of the shaft portion 82. The first frame 30 is fixed.

  In the solar power generation device 10, the 1st metal fitting 50 and the 2nd metal fitting 60 are used as a fixing metal fitting. The frame 13 has an outer groove (see FIG. 3 described later) that opens toward the outside of the solar cell module 11, and the fixture is inserted into the outer groove. The solar power generation device 10 includes a third metal fitting 70 that is not inserted into the outer groove of the frame 13 but is used for fixing the frame 13 to the gantry frame 14.

  The solar cell panel 12 is a substantially flat panel in which, for example, a plurality of solar cells are sandwiched between a glass plate and a resin back sheet. The solar cell module 11 and the solar cell panel 12 have a substantially rectangular shape in plan view. The solar cell module 11 is disposed on the roof 100 in a state where the short sides of the adjacent solar cell modules 11 are substantially in contact with each other such that the short sides are along the eaves-ridge direction. Note that the solar cell module 11 may have a plan view shape other than a rectangle, and may be, for example, a square or a trapezoid.

  The frame 13 protects the edge of the solar cell panel 12 and is used for fixing the solar cell module 11 to the second gantry frame 40. The first metal fitting 50 and the second metal fitting 60 are engaged with the frame 13 placed on the second frame 40 to fix the solar cell module 11 to the second frame 40. The frame 13 includes two long side frames provided along two long sides of the solar cell panel 12 and two short side frames provided along two short sides.

  As described above, the gantry frame 14 includes the first gantry frame 30 and the second gantry frame 40, and is arranged on the roof 100 such that the longitudinal direction thereof is along the eaves-ridge direction. The first gantry frame 30 is provided across at least two anchors 80 arranged in the eaves-ridge direction, and has a length capable of mounting a plurality of solar cell modules 11 in the eaves-ridge direction. It is preferable that at least both ends of the first gantry frame 30 in the longitudinal direction or the vicinity thereof are fixed to the shaft portion 82 of the anchor 80. The solar cell module 11 is mounted on the first frame 30 via the second frame 40.

  The gantry frames 14 are arranged substantially in parallel with each other at an appropriate interval in the girder direction of the roof 100. One solar cell module 11 is supported by at least two gantry frames 14. The first gantry frame 30 is provided across the two anchors 80, and the second gantry frame 40 is provided at a portion on which the frame 13 is placed and a fixing bracket is installed. Specifically, the second frame frame 40 is provided at a position corresponding to the eaves side end and the building side end of each solar cell module 11, and the eaves side end and the building side of the module are placed on the second frame 40. The end is placed. A second gantry frame 40 is provided at the boundary between the two solar cell modules 11A and 11B adjacently arranged in the eaves-ridge direction so as to straddle both modules.

  2 is a cross-sectional view taken along line AA in FIG. As illustrated in FIG. 2, in the solar power generation device 10, the first mount frame 30 is fixed to the shaft portion 82 of the anchor 80 fixed to the base plate 101, and the second mount frame is fixed to the first mount frame 30. The frame 13 of the solar cell module 11 is fixed to the frame 40. That is, the solar cell module 11 is fixed to the base plate 101 via the second frame 40, the first frame 30, and the anchor 80.

  The anchor 80 has a pedestal portion 81 fixed to the base plate 101, and a shaft portion 82 that stands on the pedestal portion 81 and penetrates the roof material 102 and protrudes to the front side of the roof material. A cap 87 is attached to the front side of the roof material 102 to the shaft portion 82 protruding from the through hole 103 of the roof material 102, and a sealing material 88 is provided in the gap between the through hole 103 and the shaft portion 82. Filled. In addition, an elastic member 86 that contacts the back surface of the roof material 102 located around the through hole 103 and a support member 85 that supports the elastic member 86 are attached to the shaft portion 82. The elastic member 86 is a member that is elastically deformed by being pushed by the roof material 102. For the elastic member 86, for example, rubber, resin foam or the like is used.

  The pedestal portion 81 is formed in a substantially flat plate shape and is fixed to the base plate 101 using screws 84. The pedestal portion 81 has, for example, a substantially square shape in plan view, and a plurality of through-holes 83 into which screws 84 are inserted are formed at end edges of the pedestal portion 81. For the screw 84, for example, a wood screw is used. The shaft portion 82 is erected substantially perpendicularly to the upper surface at the center of the upper surface of the pedestal portion 81. The shaft portion 82 is formed with a screw for attaching a nut 89 or the like.

  A portion protruding from the through hole 103 of the shaft portion 82 is passed through a through hole 34 (see FIG. 8 described later) formed in the lower wall portion 32 of the first mount frame 30. Then, the lower wall portion 32 is fixed to the shaft portion 82 using the nut 89 and the washer 90. Specifically, the nut 89 and the washer 90 are attached to the shaft portion 82, the first frame frame 30 is placed on the washer 90, and then the washer 92 and the nut 90 are attached to the shaft portion 82, thereby 30 is fixed to the shaft portion 82.

  FIG. 3 is a cross-sectional view of the boundary position between the solar cell modules 11A and 11B. As illustrated in FIG. 3, the frames 13 </ b> A and 13 </ b> B mounted on the gantry frame 14 include main body portions 20 </ b> A and 20 </ b> B, inner grooves 22 </ b> A and 22 </ b> B that open toward the inside of the module, and openings toward the outside of the module. And outer grooves 24A and 24B. Each frame 13A, 13B is placed on the second frame 40 as described above. Each of the frames 13A and 13B has inner flange portions 25A and 25B projecting inside the module. 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 main body 20A has a hollow, substantially prismatic shape. The frame 13A has a first flange portion 21A erected on the upper surface of the main body portion 20A, 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 portion 20A and the first flange portion 21A. 22A is formed. The first flange portion 21A extends straight upward from the outside of the main body portion 20A, and is bent inward to have a substantially L-shaped cross section. Further, the frame 13A has a second flange 23A erected on the lower surface of the main body 20A, and is a gap into which the second metal fitting 60 can be inserted between the lower surface of the main body 20A and the second flange 23A. An outer groove 24A is formed. The second flange portion 23A extends straight downward from the inside of the main body portion 20A, and is bent outward so as to have a substantially L-shaped cross section.

  The second gantry frame 40 on which the frames 13A and 13B are placed is placed on the side wall portions 31a and 31b of the first gantry frame 30, and is fixed to the upper portions of the side wall portions 31a and 31b using screws 36. For example, a drill screw or a tapping screw is used as the screw 36. The 2nd mount frame 40 has the guide rail part 44 which supports the 1st metal fitting 50, the 2nd metal fitting 60, and the 3rd metal fitting 70 so that sliding is possible.

  The second mount frame 40, the first metal fitting 50, and the third metal fitting 70 are formed with through holes through which pins 46 are inserted, and each metal fitting is positioned on the second mount frame 40 by the pins 46. For example, a bolt is used for the pin 46. The first metal fitting 50 is inserted into the outer groove 24B of the frame 13B, and the second metal fitting 60 that engages with the third metal fitting 70 is inserted into the outer groove 24A of the frame 13A.

  The first metal fitting 50 fixes the frame 13 (hereinafter also referred to as “eave side frame”) installed at the eaves side end of the solar cell module 11 to the second frame 40. The second metal fitting 60 fixes the frame 13 (hereinafter sometimes referred to as “building side frame”) installed at the ridge side end of the solar cell module 11 to the second frame 40. Further, the third metal fitting 70 fixes the ridge-side frame to the second mount frame 40 together with the second metal fitting 60.

  4 to 6 are perspective views of the first metal fitting 50, the second metal fitting 60, and the third metal fitting 70. Here, description will be given assuming that each metal fitting is installed at a boundary position between the solar cell modules 11A and 11B. At the boundary position, the metal fittings are arranged from the ridge side in the order of the first metal fitting 50, the second metal fitting 60, and the third metal fitting 70 (see FIG. 3).

  As illustrated in FIG. 4, the first metal fitting 50 includes a base portion 51 that is slidably engaged with the guide rail portion 44 of the second gantry frame 40, and a flange portion 52 erected on the eaves side end portion of the base portion 51. And a standing wall portion 53 erected on the ridge side end portion of the base portion 51. A through hole 54 through which the pin 46 is inserted is formed in the base 51. The lateral length of the base portion 51 is longer than the lateral lengths of the flange portion 52 and the standing wall portion 53, and the base portion 51 projects to both lateral sides from positions corresponding to both lateral ends of the flange portion 52 and the standing wall portion 53. The flange portion 52 and the standing wall portion 53 do not interfere with the flange portion 43, and both lateral ends of the base portion 51 are inserted between the base portion 41 and the flange portion 43 constituting the guide rail portion 44.

  The flange 52 is a portion inserted into the outer groove 24B, and is formed in a substantially L shape by folding the eaves side end of the metal fitting toward the ridge. The flange portion 52 is formed between the base portion 51 and a gap in which the bottom plate of the frame 13B can be inserted in a state where the base portion 51 is inserted into the guide rail portion 44. The standing wall portion 53 is formed substantially perpendicular to the base portion 51 by bending the ridge side end portion of the metal fitting upward. The standing wall 53 faces the tip of the inner flange 25B of the frame 13B and is disposed in the vicinity of the tip, and prevents the solar cell module 11B from moving toward the ridge.

  As illustrated in FIG. 5, the second metal fitting 60 includes a base portion 61 that is slidably engaged with the guide rail portion 44, and a flange portion 62 that stands on the ridge side end portion of the base portion 61. The lateral length of the base 61 is longer than the lateral length of the flange 62. The base portion 61 projects from both sides in the lateral direction from positions corresponding to both lateral ends of the flange portion 62, and the protruding portion is inserted between the base portion 41 and the flange portion 43 constituting the guide rail portion 44. The flange portion 62 is a portion that is inserted into the outer groove 24A, and is formed in a substantially L shape by folding the ridge side end portion of the metal fitting toward the eave side.

  On the base 61, a protrusion 63 protruding upward is formed. Further, the flange portion 62 is formed with a protrusion 64 protruding downward. The protrusion 63 abuts on the flange 43 constituting the guide rail portion 44, and the protrusion 64 abuts on the bottom plate of the frame 13 A inserted between the base 61 and the flange 62, so that the frame 13 A and the second frame frame 40 Increase the bond strength. Further, the second metal fitting 60 engages with the third metal fitting 70. A recess 65 is formed at the eaves side end of the base 61 as an engaging portion that engages with the third metal fitting 70.

  As illustrated in FIG. 6, the third metal fitting 70 includes a base portion 71 that is slidably engaged with the guide rail portion 44, a standing wall portion 72 that is erected on the eaves side end portion of the base portion 71, and an upper portion of the standing wall portion 72. And a flange 73 extending to the ridge side. The eaves 73 is formed, for example, by bending a part of the standing wall 72 to the ridge side. The lateral length of the base portion 71 is longer than the lateral length of the standing wall portion 72. The base portion 71 protrudes from the positions corresponding to both ends of the standing wall portion 72 in the horizontal direction, and the protruding portion is inserted between the base portion 41 and the flange portion 43 constituting the guide rail portion 44. The third metal fitting 70 has an extending portion 75 that extends from both lateral ends of the base portion 71 to the eaves side beyond the standing wall portion 72 and is inserted between the base portion 41 and the flange portion 43.

  The base 71 is formed with a substantially semicircular convex portion 74 as an engaging portion that engages with the second metal fitting 60. By fitting the convex portion 74 of the third metal fitting 70 into the concave portion 65 of the second metal fitting 60, each metal fitting is engaged. A through hole 76 through which the pin 46 is inserted is formed in the base 71. The standing wall portion 72 faces the tip of the inner flange portion 25A of the frame 13A and is disposed in the vicinity of the tip, and prevents the solar cell module 11A from moving toward the eaves side. Moreover, the collar part 73 protrudes on the inner collar part 25A, and prevents the frame 13A from being lifted.

  In the solar power generation device 10, for example, the first metal fitting 50 is inserted into the guide rail portion 44 of the second gantry frame 40 to be pinned, the eaves side frame is placed on the second gantry frame 40, and the flange portion 52 is placed in the outer groove. The eaves side frame is fixed to the second gantry frame 40 by inserting. Then, the ridge-side frame is placed on the second mount frame 40 in which the third metal fitting 70 is inserted and pinned to the guide rail portion 44, and the flange portion 62 of the second metal fitting 60 is inserted into the outer groove of the ridge-side frame. Then, the ridge side frame is fixed to the second gantry frame 40. The solar power generation device 10 can be constructed by a simple method of repeating this procedure from the eaves side to the building side.

  Hereinafter, the configuration of the gantry frame 14 will be described in detail with reference to FIGS. 7 and 8. 7 is a cross-sectional view taken along the line BB in FIG. 1, and FIG. 8 is an exploded perspective view of the gantry frame 14 and the anchor 80.

  As illustrated in FIGS. 7 and 8, the gantry frame 14 has a second gantry frame 40 with a short length placed on the upper part of the long first gantry frame 30 and is fixed to each other using screws 36. Has a structure. For the first gantry frame 30 having a length straddling at least two anchors 80, the length of the second gantry frame 40 is, for example, about 3% to 15% of the length of the first gantry frame 30, The distance between the anchors 80 is shorter. A plurality of second frame frames 40 are installed on one first frame 30. The number of second frame frames 40 installed on one first frame 30 is at least the number of solar cell modules 11 arranged on the frame 14 plus one.

  The first mount frame 30 is preferably made of a metal material mainly composed of steel in order to reduce material costs. As a suitable metal material constituting the first gantry frame 30, a steel plate having a plating layer for preventing corrosion on the surface can be cited. For example, the first pedestal frame 30 is manufactured by bending the highly corrosion-resistant steel plate to form the side wall portions 31 a and 31 b and the lower wall portion 32, and providing the through hole 34 in the lower wall portion 32. On the other hand, the second gantry frame 40 is preferably made of a metal material mainly composed of aluminum from the viewpoints of formability, lightness, and the like, and is manufactured, for example, by extrusion molding of an aluminum alloy.

  When the first gantry frame 30 and the second gantry frame 40 are manufactured with the same length, the manufacturing cost is the first gantry frame 30 <the second gantry frame 40. In the present embodiment, the inexpensive first pedestal frame 30 is formed in a long shape straddling each anchor 80, and the expensive second pedestal frame 40 is used only for the portion on which the frame 13 is placed, so that the workability and the fixing property are improved. Manufacturing costs can be greatly reduced without loss.

  The first gantry frame 30 includes a lower wall portion 32 fixed to the shaft portion 82 of the anchor 80 and a pair of side wall portions 31 a and 31 b erected on the lower wall portion 32. A plurality of through holes 34 through which the shaft portion 82 is inserted are formed in the lower wall portion 32 in the longitudinal direction of the first gantry frame 30. The through holes 34 are long holes that are long in the longitudinal direction of the first gantry frame 30, and are formed at, for example, both longitudinal ends of the first gantry frame 30 or in the vicinity thereof.

  The side wall portions 31 a and 31 b are provided upright at both ends in the width direction of the lower wall portion 32. The side wall portions 31a and 31b are formed substantially perpendicular to the lower wall portion 32, and are arranged to face each other substantially in parallel. The vertical lengths (heights) of the side wall portions 31a and 31b are determined in consideration of the load resistance of the first gantry frame 30, and usually the frame strength (particularly, the vertical direction acts as the height increases). Strength against load is improved. Since the first mount frame 30 is reinforced by assembling the second mount frame 40, the required load resistance can be ensured even if the side wall portions 31a and 31b are lowered.

  As described above, the second gantry frame 40 is placed on the side wall portions 31a and 31b and screwed thereto. A through hole 35 through which the screw 36 is inserted is formed in the upper part of the side wall portions 31a and 31b. A plurality of through holes 35 are formed in the longitudinal direction of the first gantry frame 30. It is preferable that at least two second pedestal frames 40 are fixed to each of the side wall portions 31a and 31b with a total of four screws 36.

  The upper end portions of the side wall portions 31 a and 31 b are bent inside the first mount frame 30. As a result, a pair of projecting portions 33 projecting to the inside of the frame is formed at the upper end portion of the first mount frame 30. The overhang portion 33 increases the rigidity of the side wall portions 31a and 31b, and particularly improves the durability against a load acting in the width direction of the frame. Further, the overhang portion 33 functions as a hook portion on which the second gantry frame 40 is hooked, and strengthens the coupling force between the first gantry frame 30 and the second gantry frame 40. The overhang length of the overhang portion 33 is set to a length that does not hinder the fixing operation of the first mount frame 30 to the anchor 80, and is, for example, less than 20% of the width of the first mount frame 30.

  The second gantry frame 40 includes a base 41 that is placed on the side wall portions 31 a and 31 b of the first gantry frame 30, and a pair of flanges 43 that are erected on the upper surface of the base 41. The base portion 41 is formed in a substantially flat plate shape, is longer in the vertical direction than in the horizontal direction, and both lateral end portions (both width direction end portions) project outward from both sides in the width direction of the first frame 30. And the collar part 43 is formed in the width direction both ends of the base 41. FIG. The flange 43 is formed over the entire length in the longitudinal direction of the second frame 40. The flange portion 43 extends straight upward from both ends in the width direction of the base portion 41 and is bent inward to have a substantially L-shaped cross section. The frame 13 is placed on each flange 43.

  The 2nd mount frame 40 has the guide rail part 44 as above-mentioned. The guide rail portion 44 includes a base portion 41 and a flange portion 43, and part of the first metal fitting 50, the second metal fitting 60, and the third metal fitting 70 is inserted between the base portion 41 and the flange portion 43. Each metal fitting is supported by the guide rail portion 44 (the collar portion 43) so as to be slidable in the longitudinal direction of the second gantry frame 40 in a state in which the fitting is not removed upward. A through hole 45 through which the pin 46 is inserted is formed in the base 41. The metal fittings are positioned on the second frame 40 by inserting the pins 46 with the through holes of the first metal fitting 50 and the third metal fitting 70 aligned with the through holes 45.

  The second frame 40 has a pair of leg portions 42a and 42b that extend downward along the side wall portions 31a and 31b of the first frame 30 and are fixed to the side wall portions 31a and 31b, respectively. Leg portions 42a and 42b are formed on the second frame 40 over the entire length in the longitudinal direction. The leg portions 42 a and 42 b are inserted inside the first mount frame 30. The leg portions 42a and 42b extend downward from the bottom surface of the base portion 41 beyond positions facing the through holes 35 formed in the side wall portions 31a and 31b, and are fixed to the side wall portions 31a and 31b using screws 36, respectively. . In addition, you may provide the connection part which connects the lower ends of leg part 42a, 42b in the 2nd mount frame 40. As shown in FIG.

  The leg portions 42 a and 42 b extend from the inside of the lower surface of the base portion 41 rather than the position corresponding to the tip of each overhang portion 33 of the first mount frame 30. The leg portions 42 a and 42 b have shapes along the inner surfaces of the side wall portions 31 a and 31 b including the overhang portion 33. In the gantry frame 14, the leg portions 42 a and 42 b go under the overhang portions 33, so that the second gantry frame 40 is hooked on the first gantry frame 30. And the 2nd mount frame 40 has each overhang | projection part 33 clamped by the base 41 and leg part 42a, 42b. The leg portions 42a and 42b are screwed to the side wall portions 31a and 31b, but by being hooked by the overhanging portion 33, the durability against the negative pressure of the second gantry frame 40 is further improved.

  The solar power generation device 10 having the above configuration is superior in workability compared to the conventional solar power generation device 200 illustrated in FIG. Moreover, the solar power generation device 10 has a load resistance equal to or higher than that of the solar power generation device 200. Also in the case of the photovoltaic power generation apparatus 200, the gantry frame is fixed to the shaft portion of the anchor, and the solar cell module 201 is placed on the frame. In this apparatus, the solar cell module 201 is fixed to the gantry frame by sunlight. This is significantly different from the case of the power generation device 10. This difference is due to the different structures of the gantry frame, the fixing bracket, and the module frame.

  As shown in FIG. 15, in the case of the photovoltaic power generation apparatus 200, the module frame is fixed to the gantry frame by attaching the presser fitting 203 to the shaft portion of the bolt 202 fixed in advance to the gantry frame. The presser fitting 203 presses the flange that protrudes to the outside of the module frame against the gantry frame. It is necessary to attach at least two presser fittings 203 between the two solar cell modules 201. The holding work of the presser fitting 203 may take a long time, and the work with an unreasonable posture may be forced.

  On the other hand, in the case of the solar power generation device 10, as described above, after attaching the fixing bracket to the guide rail portion 44 of the second mount frame 40, the fixing bracket is inserted into the outer groove of the frame 13. It can be constructed by various methods. And the frame 13 of each solar cell module 11 should just be arrange | positioned on the 2nd mount frame 40 in an order from the eaves side of the roof 100. FIG. In the case of the solar power generation device 10, there is no work in a posture as illustrated in FIG. 15, and construction can be performed in a relatively short time. The second gantry frame 40 may be assembled to the first gantry frame 30 on the ground. If the first gantry frame 30 with the second gantry frame 40 is fixed to the shaft portion 82 of the anchor 80 on the roof 100, Good.

  9 to 14 are cross-sectional views showing gantry frames 110, 120, 130, 140, and 150, which are other examples of the embodiment, respectively. In the following, the same components as those in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted, and differences from the above-described embodiment will be described.

  The gantry frame 110 illustrated in FIG. 9 is different from the gantry frame 14 in that the leg portions 112a and 112b include a second gantry frame 111 that extends long in the vertical direction. In the gantry frame 110, the base 41 on which the fixing bracket is placed is provided at a position away from the upper end of the first gantry frame 30. That is, the guide rail portion 44 that supports the fixing bracket and the flange portion 43 on which the frame 13 is placed are formed at higher positions than in the case of the gantry frame 14.

  Similarly to the leg portions 42a and 42b, the leg portions 112a and 112b extend from the lower surface of the base portion 41 and are inserted into the first mount frame 30. The leg portions 112a and 112b go under the overhang portions 33 and are screwed onto the side wall portions 31a and 31b. Stopped. On the other hand, in the leg portions 112a and 112b, the vertical length of the first portion 113, which is a portion formed substantially perpendicular to the lower surface of the base portion 41, wraps under the overhang portion 33 and is screwed onto the side wall portions 31a and 31b. It is longer than the length of the second portion 114 that is the portion to be stopped. The first portion 113 is a leg portion for raising the base 41 on which the fixing bracket is placed, and separating the base 41 from the upper end of the first mount frame 30.

  When snow accumulates on the solar cell panel 12, the panel may be bent by the weight of the snow. And when the bending of the solar cell panel 12 becomes large, the panel may come into contact with the first gantry frame 30 disposed on the back side of the panel and the panel may be damaged. Therefore, by using the second gantry frame 111 that separates the base portion 41 constituting the guide rail portion 44 from the upper end of the first gantry frame 30, the gap between the solar cell panel 12 and the first gantry frame 30 is increased. Damage to the solar cell panel 12 can be prevented. The solar power generation device using the gantry frame 110 is suitable for heavy snow areas. According to the gantry frame 110, the raising amount of the solar cell module 11 can be adjusted by changing the length of the first portion 113.

  A gantry frame 120 illustrated in FIG. 10 includes a second gantry frame 121 in which legs 122 a and 122 b extend to the outside of the first gantry frame 30. The leg portions 122a and 122b extend along the outer surfaces of the side wall portions 31a and 31b from the outside of the lower surface of the base portion 41 from the positions corresponding to both ends in the width direction of the first mount frame 30. The leg portions 122a and 122b are formed substantially perpendicular to the lower surface of the base portion 41 from the base to the tip. In the case of the second gantry frame 40, it is necessary to insert the first gantry frame 30 from both longitudinal ends to the first gantry frame 30 and slide it to a target position. In the case of the gantry frame 120, the first gantry frame The second mount frame 121 can be placed directly on 30 target positions. The leg portions 122a and 122b are fixed to the side wall portions 31a and 31b using, for example, a rivet 123.

  The gantry frame 130 illustrated in FIG. 11 includes a first gantry frame 131 in which the upper ends of the side wall portions 133a and 133b are bent to the outside of the frame, and leg portions 134a and 134b that extend straight downward from the lower surface of the base 41. 2 frame frames 132. At the upper end portion of the first gantry frame 131, an overhanging portion 135 is formed that projects to the outside of the frame. As in the case of the gantry frame 14, the second gantry frame 132 has legs 134 a and 134 b inserted inside the first gantry frame 131 and fixed to the side wall parts 133 a and 133 b using screws 36. Also in the case of the gantry frame 130, since the leg portions 134 a and 134 b are not hooked on the first gantry frame 131, the second gantry frame 132 can be placed directly on the target position of the first gantry frame 131.

  12 and 13 includes a first frame 141 having a lower wall portion 143 fixed to the shaft portion 82 of the anchor 80 and a side wall portion 144 erected on the lower wall portion 143. Each is provided. Further, the first gantry frame 141 has an upper wall portion 145 formed substantially parallel to the lower wall portion 143 from the upper end of the side wall portion 144. The upper wall portion 145 is disposed opposite to the lower wall portion 143, and the side wall portion 144 is formed substantially perpendicular to the lower wall portion 143 and the upper wall portion 145. In the case of the first gantry frame 141, since the side is greatly opened, it is easy to fix the lower wall portion 143 and the shaft portion 82.

  The gantry frames 140 and 150 include second gantry frames 142 and 151 having different shapes. Similar to the second frame 40 and the like, the second frame 142 that constitutes the frame 140 includes a base 41, a flange 43, and a leg 146 that is fixed to the side wall 144. The leg portion 146 extends downward from one end portion in the width direction of the base portion 41 along the outer surface of the side wall portion 144, and is fixed to the upper portion of the side wall portion 144 using a rivet 147. Since the first frame 141 has only one side wall 144, the second frame 142 also has only one leg 146 that is screwed to the side wall 144. However, the second pedestal frame 142 has a claw portion 148 that wraps around from the other end in the width direction of the base portion 41 under the upper wall portion 145 and is hooked on the upper wall portion 145.

  The second frame 151 that constitutes the frame 150 includes a second base 152 that is placed on the upper wall 145 of the first frame 141 and a pair of raising legs 153 a that are erected on the upper surface of the second base 152. , 153b, and the second gantry frame 142. The base portion 41 on which the fixing bracket is mounted and which constitutes the guide rail portion 44 is raised by the raising legs 153 a and 153 b and is provided at a position away from the upper end of the first gantry frame 141.

  The raising legs 153 a and 153 b extend upward from both ends in the width direction of the second base 152 and are connected to both ends in the width direction of the base 41. The leg portion 146 extends downward from one end portion in the width direction of the second base portion 152, and the claw portion 148 turns under the upper wall portion 145 from the other end portion in the width direction of the second base portion 152. According to the 2nd mount frame 151, the raising amount of the solar cell module 11 can be adjusted by changing the length of the leg parts 153a and 153b for raising. The solar power generation device using the raising legs 153a and 153b is suitable for a snowy area.

  The gantry frame 160 illustrated in FIG. 14 includes a second gantry frame 161 having two types of legs 163 and 164. Further, the base 162 of the second gantry frame 161 does not protrude from the first gantry frame 30 like the base 41 of the second gantry frame 40. And the collar part 43 is provided in the position which is located in a line with the side wall parts 31a and 31b in the up-down direction. The leg portion 163 is inserted into the first gantry frame 30 and fixed to the side wall portion 31 b using the screw 36, similarly to the leg portion 42 b of the second gantry frame 40. On the other hand, the leg portion 164 is provided outside the first gantry frame 30. The leg portion 164 extends downward from one end in the width direction of the base portion 162 along the outer surface of the side wall portion 31a, and is fixed to the side wall portion 31a using a screw 36.

  According to the second pedestal frame 161, the leg portion 163 formed on the other end in the width direction of the base portion 162 is inserted inside the first pedestal frame 30 and wraps under the overhanging portion 33, so that it can withstand negative pressure. Can increase the sex. On the other hand, the leg portion 164 formed on one end side in the width direction of the base portion 162 is disposed along the outer surface of the side wall portion 31 a, so that the second gantry frame 161 is placed directly on the target position of the first gantry frame 30. Can be placed. That is, the second mount frame 161 having the two types of leg portions 163 and 164 is easy to assemble to the first mount frame 30 and has excellent durability against negative pressure.

  Note that the second gantry frame 161 can be said to be a frame having the leg portion 42b of the second gantry frame 40 and the leg portion 146 of the second gantry frame 142. As described above, the gantry frame may be configured by rearranging the components of the above-described embodiment.

  DESCRIPTION OF SYMBOLS 10 Solar power generation device, 11, 11A, 11B Solar cell module, 12 Solar cell panel, 13 Module frame, 14 Mounting frame, 20A, 20B Main body part, 21A, 21B 1st collar part, 22A, 22B Inner groove | channel, 23A, 23B 2nd collar part, 24A, 24B outer groove, 25A, 25B inner collar part, 30 1st mount frame, 31a, 31b side wall part, 32 lower wall part, 33 overhang part, 34, 35 through-hole, 36 screw, 40 Second base frame, 41 base, 42a, 42b leg, 43 collar, 44 guide rail, 45 through hole, 46 pin, 50 first fitting, 51 base, 52 collar, 53 standing wall, 54 through hole, 60 2nd metal fitting, 61 base part, 62 collar part, 63,64 protrusion, 65 recessed part, 70 3rd metal fitting, 71 base part, 72 standing wall part, 73 Ridge, 74 Convex, 75 Extension, 76 Through-hole, 80 Anchor, 81 Base, 82 Shaft, 83 Through-hole, 84 Screw, 85 Support member, 86 Elastic member, 87 Cap, 88 Sealing material, 89 , 91 Nut, 90, 92 Washer, 100 Roof, 101 Base plate, 102 Roof material, 103 Through hole, 110 Mounting frame, 111 Second mounting frame, 112a, 112b Leg, 113 First part, 114 Second part, 120 frame, 121 second frame, 122a, 122b leg, 123 rivet, 130 frame, 131 first frame, 132 second frame, 133a, 133b side wall, 134a, 134b leg, 135 overhang, 140 Mounting frame, 141 First mounting frame, 142 2 frame, 143 lower wall, 144 side wall, 145 upper wall, 146 legs, 147 rivets, 148 claw, 150 frame, 151 second frame, 152 second base, 153a, 153b for raising Leg, 160 frame, 161 Second frame, 162 base, 163, 164 leg

Claims (6)

A solar cell module having a solar cell panel and a module frame installed at an edge of the panel;
A gantry frame on which the module frame is mounted;
A fixing bracket for fixing the module frame to the gantry frame;
A plurality of anchors having a pedestal portion fixed to the roof base plate, and a shaft portion standing on the pedestal portion and penetrating through the roof material and projecting to the front side of the roof material;
With
The module frame has an outer groove that opens toward the outside of the module;
The fixing bracket is inserted into the outer groove,
The gantry frame is provided across at least two anchors, and includes a long first gantry frame that is fixed to the shaft portion of each anchor, and a guide rail portion that slidably supports the fixing bracket. And a second frame that is shorter than the first frame and is fixed to an upper portion of the first frame. The first pedestal frame has a lower wall portion fixed to the shaft portion of the anchor, and a side wall portion standing on the lower wall portion,
2. The photovoltaic power generation apparatus according to claim 1, wherein the second frame includes a leg portion that extends downward along the side wall portion of the first frame and is fixed to the side wall portion.   The photovoltaic power generation apparatus according to claim 2, wherein the side wall portions are respectively erected at both end portions in the width direction of the lower wall portion, and each upper end portion is bent inside or outside the frame.   The solar power generator according to any one of claims 1 to 3, wherein the second frame is hooked on the first frame. The first mount frame is made of a metal material mainly composed of steel,
The solar power generator according to any one of claims 1 to 4, wherein the second mount frame is made of a metal material mainly composed of aluminum.   6. The sunlight according to claim 1, wherein the second mount frame includes a lifting leg portion that raises a base portion on which the fixing bracket is placed and separates the base from the first mount frame. Power generation device.

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