JP2016065396A - Photovoltaic power generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a structure at low cost which increases stiffness of an entire device including at least two pieces solar cell modules and mounting base frames, and which prevents an excessive contact against the mounting base frame in the case where a solar cell module is deflected due to accumulated snow.SOLUTION: A photovoltaic power generation device includes: a mounting base frame having a lower side guide rail; a fixing member having a base part which is fitted in by sliding and being inserted into the lower side guide rail and which has a shape so that it can be fixed to the lower side guide rail, and protrusion parts protrusively provided at an eaves side, a ridge side of a standing wall part erected on the base part, and for fixing and supporting two pieces of solar cell modules by each protrusion part being combined with module frames of the two solar cell modules; and a spacer having a shape which can be fitted in by the base part being slid and inserted along the ridge eaves direction, having an upper side guide rail in which the base part is fixed, and inserted between the mounting base frame and the intermediate fixing member.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a solar power generation device including two solar cell modules installed side by side on a roof.

  Conventionally, various fixing structures used for installing a solar cell module on a roof have been proposed.

  In the solar cell module installed on the roof, a structure for preventing inconvenience in the case where bending occurs due to snow has been proposed. For example, Patent Document 1 describes that a spacer is disposed between a frame of a solar cell module and the mount in order to prevent a cable from being sandwiched between the solar cell module bent by snow and the mount. ing.

JP 2012-251304 A

  By the way, when installing at least two solar cell modules side by side in the building direction on a base fixed on the roof, the entire photovoltaic power generation apparatus including the base and the solar cell module in order to increase strength against a load due to wind or the like There is a demand for higher rigidity. In addition, when a solar cell module is installed on the roof in a snowy area where there is a lot of snow, even if the solar cell module is bent due to snow, it would be desirable to avoid excessive contact with the frame on the roof surface side. There is also a request. It is desirable to realize a structure that realizes these demands at low cost by sharing parts with a structure that is used outside a snowy area.

  A photovoltaic power generation apparatus according to the present invention is two solar cell modules installed side by side in a roof ridge direction, each solar cell module being a solar cell panel and a module provided at the periphery of the solar cell panel A solar cell module having a frame, a lower guide rail provided along the direction of the ridge in the upper part, a pedestal frame fixed along the direction of the ridge on the roof, and along the direction of the ridge The base part has a shape that can be fixed to the bottom surface of the lower guide rail by being slid into the lower guide rail of the gantry frame, the standing wall part standing on the base part, and the eave side of the standing wall part The eaves-side protrusions are assembled to the module frame of the solar cell module installed on the eaves side. An intermediate fixing member that fixes and supports the two solar cell modules by combining the ridge-side projecting portion with the module frame of the solar cell module installed on the ridge side, It has a shape that can be fitted by sliding the base portion of the intermediate fixing member along the direction of the building, and has an upper guide rail to which the base portion is fixed, between the gantry frame and the intermediate fixing member. And an intermediate spacer that is inserted into and fixed to the bottom surface of the lower guide frame.

  According to the photovoltaic power generation apparatus according to the present invention, the rigidity of the entire apparatus including at least two solar cell modules and the gantry frame can be increased, and the solar cell module is excessively deformed when the solar cell module is bent due to snow. It is possible to realize a structure that can prevent a simple contact at low cost.

It is a perspective view which installs and shows the solar power generation device of this embodiment on a roof. It is AA sectional drawing in FIG. It is the B section enlarged view in FIG. It is a figure which abbreviate | omits and shows a solar cell module in CC cross section in FIG. It is a perspective view of an intermediate spacer. It is DD sectional drawing in FIG. It is EE sectional drawing of FIG. 6A. It is the perspective view (a) of an attachment tool, and FF expanded sectional view (b) of (a). It is a perspective view of an eaves side fixing member. It is a perspective view of an eaves side cover member. It is GG sectional drawing in FIG. It is a perspective view of a ridge side fixing member. It is a perspective view of a ridge side cover member. It is a perspective view which isolate | separates and shows a mount frame, a spacer, and an intermediate | middle fixing member. In the solar power generation device of this embodiment, it is a figure corresponding to Drawing 6A in the state where a spacer was removed and installed on the roof. In the solar power generation device of this embodiment, it is a figure corresponding to Drawing 7A in the state where a spacer was removed and installed on a roof. In the solar power generation device of this embodiment, it is a figure corresponding to FIG. 2 in the state which removed the spacer and installed on the roof. It is a figure which abbreviate | omits and shows a solar cell module in the KK cross section in FIG. It is a perspective view which isolate | separates and shows a mount frame and an intermediate | middle fixing member. It is a figure corresponding to FIG. 4 which shows another example of this embodiment. It is a figure corresponding to FIG. 4 which shows another example of this embodiment.

  Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In this description, specific shapes, materials, numerical values, directions, and the like are examples for facilitating the understanding of the present invention, and can be appropriately changed according to the application, purpose, specification, and the like. In addition, when a plurality of embodiments or modifications are included below, the components in the plurality of embodiments or modifications can be combined as appropriate. In the following description, repeated description of substantially similar elements may be omitted in all drawings.

  FIG. 1 is a perspective view showing a photovoltaic power generation apparatus 10 according to the present embodiment installed on a roof 100. 2 is a cross-sectional view taken along the line AA in FIG. FIG. 3 is an enlarged view of a portion B in FIG. 4 is a diagram in which the solar cell modules 1a and 1b are omitted in the CC cross section in FIG. FIG. 5 is a perspective view of the intermediate spacer 20a.

  In the following, for convenience of explanation, the “length direction (X direction)” is a direction parallel to the installation surface of the solar power generation device 10 along the direction in which the solar cell modules 1 are installed side by side. The “width direction (Y direction)” means a direction orthogonal to the building direction and parallel to the installation surface of the photovoltaic power generation apparatus 10. In the present embodiment, the “length direction” is made to coincide with the “ridge house direction” along the direction from the building to the eaves. In FIG. 1, the upper right side is indicated as “building side” and the lower left side is indicated as “eave side”. The roof 100 is inclined downward from the building side toward the eaves side. Moreover, the up-down direction means a direction perpendicular to the ground plane of the solar power generation device 10, and the light receiving surface side of the solar cell panel SP is on the upper side and the back surface side is on the lower side.

  Below, although the case where the two solar cell modules 1a and 1b are installed side by side in a building direction is demonstrated, this invention is not limited to this. For example, it may be applied when three or more solar cell modules are installed side by side in the building direction, or a solar cell module row in which two or more solar cell modules are installed side by side in the building direction. It may be applied when a plurality of rows are provided in the width direction (Y direction) orthogonal to the building direction.

  The solar power generation device 10 includes two solar cell modules 1 (1a, 1b), two frame frames 12, and a plurality of spacers 20 (an intermediate spacer 20a, an eaves side spacer 20b, a ridge) fixed to each frame frame 12. Side spacer 20c) (FIG. 5, FIG. 6A, FIG. 7A), intermediate fixing member 50, eaves side fixing member 51 (FIG. 6D), and ridge side fixing member 52 (FIG. 7B). As shown in FIG. 1, the two solar cell modules 1 a and 1 b are installed on the roof 100 side by side in the building direction. Each solar cell module 1a, 1b has a solar cell panel SP in which a plurality of solar cell elements are sandwiched between protective members such as glass plates, and a module frame 2 provided on the periphery of the solar cell panel SP. In the drawings, the solar cell modules are described using the reference numerals 1a and 1b, but in the specification, they may be described collectively using the reference numerals 1. The spacers are also described using the reference numerals 20a, 20b, and 20c in the drawings, but may be collectively described using the reference numerals 20 in the specification.

  The solar cell module 1 is generally rectangular in plan view. However, the solar cell module 1 may have a plan view shape other than a rectangle. The solar cell module 1 includes a solar cell panel SP and a module frame 2 that surrounds the solar cell panel SP. In the present embodiment, the two solar cell modules 1a and 1b are installed such that the short side direction is parallel to the building direction.

  The module frame 2 of the solar cell module 1 protects the periphery of the solar cell panel SP and functions as a member for attaching the solar cell module 1 to a gantry frame 12 described later. The module frame 2 is a long member formed by extruding a metal material such as aluminum. As shown in FIG. 3, the module frame 2 has a substantially rectangular shape that is long in the vertical direction. In the upper part of the module frame 2, an inner groove portion 3 that accommodates the peripheral edge portion of the solar cell panel SP is formed. A peripheral edge portion of the solar cell panel SP is inserted into the inner groove portion 3 and fixed with an adhesive or the like.

  The module frame 2 has a tubular portion 4 adjacent to the inner groove portion 3. The tubular portion 4 increases the rigidity of the module frame 2 and reduces the weight by making it hollow. An outer groove 5 is formed in the lower part of the side surface of the tubular portion 4 of the module frame 2.

  The outer groove portion 5 is opened so as to face the side opposite to the solar cell panel SP, that is, the outside of the solar cell module 1 when combined with the solar cell panel SP. The outer groove portion 5 includes protrusions 50c and 50d of an intermediate fixing member 50 (FIGS. 2 and 4), a protrusion 51c of an eaves-side fixing member 51 (FIG. 6D), and a ridge-side fixing member 52 (FIG. 7B). The protrusion 52c is inserted and used to fix the solar cell module 1 to these members. The depth d of the outer groove portion 5 is preferably set to a depth that can completely accommodate the protruding portions 50c, 50d, 51c, and 52c.

  The solar cell module 1 (1a, 1b) is installed on the roof 100 via the two gantry frames 12. The gantry frame 12 is a long member that is installed along the direction of the roof of the roof 100. The gantry frame 12 is preferably formed by, for example, extrusion molding of aluminum. The gantry frame 12 may be formed as a long member by continuously bending a metal plate by roll forming or the like. The solar cell modules 1a and 1b are mounted and fixed on a gantry frame 12 fixed on the roof 100 at a predetermined interval in the arrow Y direction.

  As shown in FIGS. 4 and 8, the gantry frame 12 includes a tubular portion 14 having a substantially rectangular cross-sectional shape, for example. The tubular portion 14 can increase the rigidity of the gantry frame 12. Further, the gantry frame 12 includes a lower guide rail 15 formed on the upper portion. The lower guide rail 15 is provided with projecting portions 15b and 15c projecting upward from both ends of a rail bottom surface 15a corresponding to the upper wall of the tubular portion 14 and projecting inward in an L-shaped cross section. As a result, two lower engaging recesses 15d and 15e facing each other are formed. An intermediate spacer 20a, which will be described later, is fixed to the rail bottom surface 15a.

  The roof 100 and the structure for fixing the gantry frame 12 to the roof 100 will be described later.

  The spacer 20 (intermediate spacer 20a, eaves side spacer 20b, ridge side spacer 20c) will be described. The spacer 20 is used for raising the solar cell module 1 so as to be largely separated from the upper end of the gantry frame 12. “Raising” is used to prevent the solar cell module 1 from excessively contacting the gantry frame 12 even when the module 1 is bent by the weight of the upper snow, particularly in a heavy snowy region. The spacer 20 is disposed between the gantry frame 12 and the module frame 2 of the solar cell module 1. As shown in FIG. 5, the spacer 20 includes a lower plate portion 21 and an upper plate portion 22, two inner plate portions 23, two outer wall portions 24, and two intermediate plate portions 25 that are arranged in parallel in the vertical direction. , And the upper guide rail 26. The spacer 20 is configured using a spacer material formed by extruding a metal material such as aluminum, for example.

  The width (length along the Y direction) of the upper plate portion 22 is larger than the width of the lower plate portion 21. The lower plate portion 21 and the upper plate portion 22 are connected in the vertical direction by two inner plate portions 23. The lower plate portion 21 has an insertion portion 21 a that protrudes outward in the width direction from the connecting portion with the inner plate portion 23. Further, two outer wall portions 24 extend in parallel to the lower side from both widthwise end portions of the upper plate portion 22 so as to face each other. The two intermediate plate portions 25 connect the outer surface of the inner plate portion 23 and the inner surface of the outer wall portion 24 to structurally reinforce the inner plate portion 23 and the outer wall portion 24.

  The insertion portions 21 a at both ends in the width direction of the lower plate portion 21 are respectively inserted into the lower engagement recesses 15 d and 15 e of the lower guide rail 15 provided in the gantry frame 12, and are fixed to appropriate portions of the gantry frame 12. Is done. The lower guide rail 15 opens between the overhang portions 15b and 15c, and also opens at both ends in the building direction X (FIG. 8), which is the longitudinal direction of the gantry frame 12. The insertion portions 21a at both ends of the lower plate portion 21 are such that the width of the lower plate portion 21 is wider than the opening width between the overhang portions 15b and 15c of the lower guide rail 15, and the width between the lower engagement recesses 15d and 15e. The width between the outer surfaces of the two inner plate portions 23 connected to the lower plate portion 21 is narrower than the opening width between the projecting portions 15b and 15c of the lower guide rail 15. . Accordingly, the insertion portion 21a is slid along the ridge direction X while being inserted into the lower engagement recesses 15d and 15e of the lower guide rail 15, that is, the insertion portion 21a is inserted into the lower guide rail 15 by sliding. The spacer 20 can be combined with the lower guide rail 15 so as to fit into the lower guide rail 15. It is preferable that the lower surface of the lower plate portion 21 of the spacer 20 has a shape corresponding to the surface shape of the rail bottom surface 15a. For example, the lower surface of the lower plate portion 21 and the rail bottom surface 15a may be flat. The shape that can be slidable is the same in the following description.

  At this time, the distance between the lower plate portion 21 and the intermediate plate portion 25 is made larger than the height of the lower engagement recesses 15d and 15e, so that the upper side surfaces of the overhang portions 15b and 15c of the gantry frame 12 and the spacer 20 are intermediate. Since a gap is formed between the lower surface of the plate portion 25, the spacer 20 can be fitted into the lower guide rail 15 smoothly. Note that the lower side surfaces of the overhang portions 15b and 15c and the upper side surface of the insertion portions 21a of the spacer 20 may be opposed to each other with almost no gap.

  Further, in a state where the spacer 20 is mounted on the gantry frame 12, the width between the inner side surfaces of the outer wall portion 24 is set so as to face the outer side surfaces that are both side surfaces of the gantry frame 12 in close contact with each other. As shown in FIG. 5, a screw insertion hole 24a is formed in each outer wall 24, and the spacer 20 can be screwed and fixed to the tubular portion 14 of the gantry frame 12 by a drill screw 38 through the screw insertion hole 24a. . As a result, the spacer 20 is fixed to the gantry frame 12. Therefore, the lower plate portion 21 of the spacer 20 has a shape that can be fitted by being slid into the lower guide rail 15 of the gantry frame 12 along the building direction X, and the rail of the lower guide rail 15 Fixed to the bottom surface 15a.

  In the present embodiment, as shown in FIGS. 2 and 5, two screw insertion holes 24a are formed in each outer wall portion 24, but only one screw insertion hole 24a may be provided. Alternatively, the screw insertion hole 24 a may be formed only in one of the two outer wall portions 24, and the spacer 20 may be fixed to the gantry frame 12 by a screw inserted into the screw insertion hole 24 a.

  Further, the spacer 20 includes an upper guide rail 26 at the upper part thereof. The upper guide rail 26 is provided with projecting portions 26b and 26c projecting upward from both ends of the rail bottom surface 26a corresponding to the upper wall of the upper plate portion 22 and projecting inward in an L-shaped cross section. As a result, two upper engaging recesses 26d and 26e facing each other are formed. An intermediate fixing member 50, an eaves side fixing member 51, and a ridge side fixing member 52, which will be described later, are fixed to the upper side of the rail bottom surface 26a.

  As shown in FIGS. 2 and 4, the intermediate fixing member 50 includes a flat plate-like base portion 50 a, an upright wall portion 50 b erected vertically to the base portion 50 a, an eaves side protrusion portion 50 c, and a ridge side protrusion portion 50 d. Have. The intermediate fixing member 50 is formed by integrally molding from a metal material such as aluminum, for example.

  The standing wall portion 50b is erected in a direction substantially orthogonal to the intermediate portion in the width direction of the base portion 50a, and the width (length along the Y direction) of the standing wall portion 50b is smaller than the width of the base portion 50a. The eaves-side and ridge-side protrusions 50c and 50d are provided so as to project in a direction substantially orthogonal to the standing wall 50b from the same position in the vertical direction of the middle portion in the vertical direction on both sides in the X direction of the standing wall 50b. More specifically, when the intermediate fixing member 50 is assembled to the intermediate spacer 20a via the gantry frame 12, the eaves side protruding portion is formed on one side surface (the left side surface in FIG. 2) of the standing wall portion 50b facing the eave side module 1a side. 50c is formed. Further, a ridge-side protruding portion 50d is formed on the other side surface (right side surface in FIG. 2) facing the ridge-side module 1b side. Each protrusion part 50c, 50d of the intermediate | middle fixing member 50 is formed in the same shape and dimension, for example. For example, each protrusion 50c, 50d has a rectangular cross section and side shape, and protrudes from the standing wall 50b by the same protrusion length.

  Both end portions of the base portion 50a in the width direction (Y direction) are slidably inserted into the upper engaging recesses 26d and 26e of the upper guide rail 26 of the intermediate spacer 20a. In the inserted state in this way, the base portion 50a is fixed to an appropriate location of the intermediate spacer 20a. The upper guide rail 26 opens between the projecting portions 26b and 26c, and also opens at both ends of the intermediate spacer 20a in the building direction X (FIG. 8). The width of the base portion 50a is wider than the opening width between the projecting portions 26b and 26c of the upper guide rail 26, narrower than the width between the upper engaging concave portions 26d and 26e, and is connected to the base portion 50a. The width of the upper guide rail 26 is provided to be narrower than the opening width between the projecting portions 26b and 26c. Further, the upper guide rail 26 of the intermediate spacer 20 a has a shape that can be fitted by sliding the base portion 50 a of the intermediate fixing member 50 along the building direction X. Thus, the base portion 50a is fitted to the upper guide rail 26 by sliding both ends in the width direction of the base portion 50a into the upper engagement recesses 26d and 26e of the upper guide rail 26 along the building direction X. The intermediate fixing member 50 can be combined with the upper guide rail 26 so as to match.

  Thus, the intermediate spacer 20a is inserted between the gantry frame 12 and the intermediate fixing member 50. It is preferable that the lower surface of the base portion 50a has a shape corresponding to the surface shape of the rail bottom surface 26a of the upper guide rail 26.

  At this time, by increasing the height of the overhang portions 26 b and 26 c of the upper guide rail 26, a gap is generated between the lower side surface of the overhang portions 26 b and 26 c and the upper side surface of the base portion 50 a of the intermediate fixing member 50. Accordingly, the intermediate fixing member 50 can be fitted into the upper guide rail 26 smoothly. Note that the lower side surfaces of the overhang portions 26b and 26c and the upper side surfaces of both end portions in the width direction of the base portion 50a may be opposed to each other with almost no gap.

  Further, the base portion 50a of the intermediate fixing member 50 is fixed to the rail bottom surface 26a by a drill screw 38 screwed in the vertical direction while being mounted on the rail bottom surface 26a of the upper guide rail 26 of the intermediate spacer 20a. Can do. As a result, the intermediate fixing member 50 is fixed to the intermediate spacer 20a. A V-shaped groove for facilitating positioning of the tip of the drill screw 38 may be formed on the upper surface of the base portion 50a. This groove is formed along the direction perpendicular to the longitudinal direction of the gantry frame 12, that is, the width direction of the intermediate fixing member 50 (the left-right direction in FIG. 2).

  Moreover, the eaves side protrusion part 50c of the intermediate | middle fixing member 50 is inserted in the outer side groove part 5 of the module frame 2 of the solar cell module 1a installed in the eaves side among two solar cell modules 1a and 1b so that it may mention later. And combined with the module frame 2. Further, the ridge-side protruding portion 50d of the intermediate fixing member 50 is inserted into the outer groove portion 5 of the module frame 2 of the solar cell module 1b installed on the ridge side, out of the two solar cell modules 1a and 1b. Combined with frame 2. Accordingly, the intermediate fixing member 50 fixes and supports the two solar cell modules 1a and 1b. Moreover, the protrusion length n from the standing wall part 50b of each protrusion part 50c, 50d is made shorter than the depth depth d (FIG. 3) of the outer side groove part 5 of each module 1a, 1b. Accordingly, the protruding portions 50c and 50d can be inserted into the corresponding outer groove portions 5 until the standing wall portion 50b comes into contact with the module frame 2 of the modules 1a and 1b. Moreover, the part extended above each protrusion part 50c, 50d currently formed in the same height among the standing wall parts 50b of the intermediate fixing member 50 is the flat-plate-shaped upper side wall part 50e. The upper side wall 50e is sandwiched between the module frames 2 of the solar cell modules 1a and 1b when the two solar cell modules 1a and 1b are installed on the gantry frame 12. The position of the upper end surface of the upper side wall portion 50e may be set to be substantially flush with the upper surface of the adjacent module frame 2 when sandwiched between the two solar cell modules 1a and 1b. When set in this way, the rigidity of the entire photovoltaic power generation apparatus 10 can be improved.

  On the other hand, the shape of the base portion 50 a of the intermediate fixing member 50 is fitted into the lower guide rail 15 of the gantry frame 12 by being slid and inserted along the building direction X, and is fixed to the rail bottom surface 15 a of the lower guide rail 15. It is a possible shape. As a result, as will be described later, when the configuration of the present embodiment is used in an area where the solar cell module 1 is not required to be raised, the spacer 20 can be removed and the intermediate fixing member 50 can be directly attached to the gantry frame 12. it can. For example, as shown in FIG. 13, which will be described later, the base portion 50a of the intermediate fixing member 50 can be slid and fixed to the lower guide rail 15 of the gantry frame 12.

  Next, the fixing structure of the gantry frame 12 to the roof 100 will be described, and then the eaves side spacer 20b, the eaves side fixing member 51, the ridge side spacer 20c, and the ridge side fixing member 52 will be described.

  6A is a cross-sectional view taken along the line DD in FIG. 1 and shows the solar cell module 1a installed on the eaves side and the eaves side ends of the gantry frame 12. FIG. 6B is an EE cross-sectional view of FIG. 6A. FIG. 6C is a perspective view (a) of the fixture 30 and an FF enlarged sectional view (b) of (a). FIG. 6D is a perspective view of the eaves side fixing member 51. FIG. 6E is a perspective view of the eaves side cover member 90a.

  As shown in FIG. 6A, a roof 100 on which the solar cell module 1 is installed has a waterproof sheet 104 such as asphalt roofing laid on a field board 102 that is a roof base material of a house, and a slate roof, for example, on the roof sheet. A large number of roofing materials 106 such as are stacked to form a step. In addition, as the roof material 106 which comprises the roof 100, you may use a tile roof, a metal plate roof, etc., for example.

  As shown in FIG. 6A and FIG. 9A to be described later, the gantry frame 12 is fixed to the roof 100 by a fixture 30 formed of a metal plate such as an iron plate, a stainless steel plate, or a steel plate.

  As illustrated in FIG. 6C, the attachment tool 30 includes a base plate 32 and a pair of support portions 33 a and 33 b erected from the base plate 32. The base plate 32 has a plurality of screw insertion holes 34. The pair of support portions 33a and 33b of the fixture 30 are opposed to each other with a space slightly larger than the width w1 of the gantry frame 12 (see FIG. 8). Each of the support portions 33a and 33b is provided with one female screw hole 35 and two through holes 36. In addition, you may form only one through-hole 36 in each support part 33a, 33b. Moreover, you may form the through-hole 36 only in the one side of the two support parts 33a and 33b. The female screw hole 35 is formed, for example, by cutting a female screw on the inner peripheral surface of a through-hole that has been subjected to burring and bulged outwardly, for example, in the shape of a truncated cone, as shown in the FF sectional view. Is done. If the female screw groove can be formed with the thickness of the metal plate constituting the fixture 30, the female screw may be cut on the inner circumference corresponding to the plate thickness of the through hole without performing burring.

  As shown in FIG. 6A, the fixture 30 is fixed to the base plate 102 by the wood screw 31 through each screw insertion hole 34. Further, the gantry frame 12 is inserted and disposed between the pair of support portions 33a and 33b. When the gantry frame 12 is fixed to the roof 100, the lower end of the gantry frame 12 is inserted from above the support portions 33 a and 33 b of the fixture 30 fixed to the roof 100. Then, as shown in FIGS. 6A and 6B, bolts 37 are screwed into the female screw holes 35 on both sides of the fixture 30, and the outer surface of the gantry frame 12 is sandwiched and temporarily fixed by the tips of the bolts 37. In this state, the gantry frame 12 is fixed to the fixture 30 by the drill screw 38 through the through holes 36 of the support portions 33a and 33b.

  Thus, the intermediate spacer 20a is fixed to the intermediate portion in the longitudinal direction of the gantry frame 12 fixed to the roof 100. Also, an eaves side spacer 20 b is fixed to the eaves side end of the gantry frame 12. A ridge-side spacer 20 c (FIG. 7A) is fixed to the ridge-side end of the gantry frame 12. The intermediate fixing member 50 is fixed on the upper side of the intermediate spacer 20a. An eaves side fixing member 51 is fixed to the upper side of the eaves side spacer 20b. A ridge-side fixing member 52 is fixed above the ridge-side spacer 20c. 2 and 3, the two solar cell modules 1 a and 1 b are combined with the intermediate fixing member 50, and the two solar cell modules 1 a and 1 b are fixed by the intermediate fixing member 50. Supported.

  This will be described in detail below. Hereinafter, for convenience, the solar cell module 1a installed on the eave side may be referred to as “eave side module 1a”, and the solar cell module 1b installed on the building side may be referred to as “building side module 1b”.

  As shown in FIG. 6A, the eave side end portion (left end portion in FIG. 6A) of the eave side module 1a is pressed against the eave side fixing member 51 fixed to the gantry frame 12 via the eave side spacer 20b. Further, as shown in FIG. 2, the ridge side end portion (left end portion of FIG. 2) of the eaves side module 1a is the eave side surface of the intermediate fixing member 50 fixed to the gantry frame 12 via the intermediate spacer 20a (FIG. 2). To the left side). Further, the eaves side end portion (right end portion in FIG. 2) of the ridge side module 1b is pressed against the ridge side surface (right side surface in FIG. 2) of the intermediate fixing member 50. Furthermore, as shown in FIG. 7A, the ridge-side end portion (right end portion in FIG. 7A) of the ridge-side module 1b is pressed against the ridge-side fixing member 52 fixed to the gantry frame 12 via the ridge-side spacer 20c. Thus, the two solar cell modules 1a and 1b are fixed in a state of being sandwiched from both sides so that the module frame 2 of the two solar cell modules 1a and 1b is integrated via the intermediate fixing member 50. Is done. For this reason, the rigidity as the whole photovoltaic power generation apparatus 10 can be made high so that it may mention later.

  The eaves side spacer 20b, the eaves side fixing member 51, and the eaves side cover member 90a will be described with reference to FIGS. 6A, 6D, and 6E. As shown in FIG. 6A, the eaves side spacer 20b is fixed to the upper side of the eaves side end portion of the gantry frame 12 by, for example, a drill screw. The structure of the eaves side spacer 20b is the same as that of the intermediate spacer 20a shown in FIGS. 2 and 4, and the member fixed on the upper side only changes from the intermediate fixing member 50 to the eaves side fixing member 51. Note that the eaves direction X length of the eaves side spacer 20b may be different from the eaves direction X length of the intermediate spacer 20a. The same applies to the ridge-side spacer 20c shown in FIG. 7A described later.

  The eaves side fixing member 51 is fixed to the upper side of the eaves side spacer 20b by, for example, a drill screw 38. In addition, the eaves side cover member 90 a is fixed to the eaves side end portion of the eaves side fixing member 51 with the drill screw 38.

  As shown in FIG. 6D, the eaves side fixing member 51 includes a base part (eave side base part) 51a, a standing wall part (eave side standing wall part) 51b, a protruding part (second ridge side protruding part) 51c, It has the side wall part 51d and the side wall part 51e. The eaves side fixing member 51 is preferably integrally formed of a metal material such as aluminum.

  The base portion 51a is a portion that is inserted into the upper guide rail 26 from the eave side end portion (the right end portion in FIG. 6A) of the eave side spacer 20b, and is formed in a plate shape. For example, a V-shaped groove 51f for facilitating positioning of the tip of the drill screw 38 is formed in the base portion 51a. The standing wall portion 51b is erected substantially perpendicular to the base portion 51a. The standing wall portion 51b is inserted between the two overhang portions 26b and 26c (see FIG. 5) of the upper guide rail 26 of the eaves side spacer 20b. Further, the base portion 51 a is fixed to the rail bottom surface 26 a of the upper guide rail 26.

  Similarly to the base portion 50 a of the intermediate fixing member 50, the base portion 51 a is fitted by being slid into the lower guide rail 15 of the gantry frame 12 along the building direction, and the rail bottom surface of the lower guide rail 15. It has a shape that can be fixed to 15a.

  A protruding portion 51c protrudes from one side of the standing wall portion 51b of the eaves side fixing member 51, that is, a side surface facing the ridge side (right side in FIG. 6D) in the attached state. The protrusion 51c is inserted into the outer groove 5 (see FIG. 3) formed in the module frame 2 of the eaves side module 1a, and is combined with the module frame 2. The protrusion 51c and the standing wall 51b are used for positioning the eaves-side module 1a. The protruding length n of the protruding portion 51c from the standing wall portion 51b is shorter than the depth d (see FIG. 3) of the outer groove portion 5 of the module frame 2 of the eaves side module 1a. Thereby, the protruding portion 51 c can be inserted into the outer groove portion 5 until the standing wall portion 51 b comes into contact with the module frame 2.

  The upper side wall portion 51d is connected to the upper end of the standing wall portion 51b, and is formed to extend in parallel to the base portion 51a and on the opposite side to the protruding portion 51c. The eaves side cover member 90a, which will be described later, is fixed to the upper side wall 51d with the drill screw 38 in a state where the eaves side fixing member 51 is attached to the gantry frame 12. The side wall 51e contacts the end face of the eaves side spacer 20b to position the eaves side fixing member 51, and is fixed by the eaves side cover member 90a and the drill screw 38.

  Further, the eaves side spacer 20 b is fixed to the rail bottom surface 15 a of the lower guide rail 15 of the gantry frame 12. Thereby, the eaves side spacer 20b is inserted and fixed between the gantry frame 12 and the eaves side fixing member 51.

  As shown in FIG. 6E, the eaves side cover member 90a has an L-shape in which an upper wall portion 91 and a side wall portion 92 are integrated. The eaves side cover member 90a is formed of resin, for example. The eaves side cover member 90a is fixed to the eaves side fixing member 51 by the drill screw 38 as described above, and is attached to cover the end surfaces of the eaves side fixing member 51 and the eaves side spacer 20b. For example, a V-shaped groove 93 is formed in the upper wall portion 91 and the side wall portion 92 so as to extend in the width direction so that the tip of the drill screw 38 can be easily positioned.

  Next, the ridge-side spacer 20c, the ridge-side fixing member 52, and the ridge-side cover member 90b will be described with reference to FIGS. 7A, 7B, and 7C. FIG. 7A is a cross-sectional view taken along the line GG in FIG. 1 and shows the ridge side end portions of the ridge side module 1 b and the gantry frame 12. The ridge-side spacer 20c is fixed to the upper side of the ridge-side end portion of the gantry frame 12 by, for example, a drill screw. The structure of the ridge-side spacer 20c is the same as that of the intermediate spacer 20a shown in FIGS. 2 and 4, and only the member fixed on the upper side is changed from the intermediate fixing member 50 to the ridge-side fixing member 52. The ridge-side fixing member 52 is fixed to the upper side of the ridge-side spacer 20c with, for example, a drill screw. The ridge-side cover member 90b is fixed to the ridge-side end portion of the ridge-side spacer 20c with a drill screw 38.

  FIG. 7B is a perspective view of the ridge side fixing member 52. The ridge-side fixing member 52 includes a base portion (ridge-side base portion) 52a, a standing wall portion (building-side standing wall portion) 52b, and a protruding portion (second eaves-side protruding portion) 52c. The ridge-side fixing member 52 has substantially the same configuration as the eaves-side fixing member 51 described with reference to FIG. 6D, and has no upper wall portion and side wall portions, and the protruding direction of the protruding portion 52c ( That is, they protrude from the standing wall 51b toward the eaves side). The base portion 52a, the standing wall portion 52b, the protruding portion 52c, and the groove 52f correspond to the base portion 51a, the standing wall portion 51b, the protruding portion 51c, and the groove 51f of the eaves side fixing member 51, respectively, and the basic configuration is the same. A duplicate description is omitted.

  Further, the base portion 52a of the ridge side fixing member 52 is fixed to the upper side of the rail bottom surface 26a (see FIG. 5) of the upper guide rail 26 of the eaves side spacer 20b. Similarly to the base portion 50a of the intermediate fixing member 50, the base portion 52a is fitted by being slid and inserted into the lower guide rail 15 of the gantry frame 12 along the building direction, and the rail bottom surface of the lower guide rail 15 is inserted. It has a shape that can be fixed to 15a. Further, the protrusion 52c of the ridge-side fixing member 52 is inserted into the outer groove portion 5 (see FIG. 3) formed in the module frame 2 of the ridge-side module 1b and combined with the module frame 2.

  The ridge-side spacer 20 c is fixed to the rail bottom surface 15 a of the lower guide rail 15 of the gantry frame 12. Thereby, the ridge-side spacer 20c is inserted and fixed between the gantry frame 12 and the ridge-side fixing member 52.

  FIG. 7C is a perspective view of the ridge side cover member 90b. The ridge-side cover member 90b is connected to the flat plate portion 94 provided to cover the longitudinal end surface of the gantry frame 12 and the ridge-side end surface of the ridge-side spacer 20c, and is bent at substantially right angles from both ends of the flat plate portion 94 and coupled in parallel. And a side wall portion 95 to be formed. Each side wall portion 95 is formed with a through hole 96 through which the drill screw 38 is inserted. The ridge-side cover member 90b is fixed to the ridge-side spacer 20c by screwing the drill screw 38 into the side surfaces on both sides in the width direction of the ridge-side spacer 20c from the through hole 96. Thereby, the opening part of the upper side guide rail 26 formed in the ridge side end surface of the ridge side spacer 20c is closed by the ridge side cover member 90b. In this state, the flat plate portion 94 of the ridge-side cover member 90 b also closes the opening at the ridge-side end of the gantry frame 12.

  With such a configuration, when the solar cell modules 1 a and 1 b are fixed to the gantry frame 12, first, the eaves-side fixing member 51 is fixed to the eaves-side end portion of the gantry frame 12. Specifically, the eaves side spacer 20b is fixed to the upper side of the gantry frame 12 with the drill screw 38, and the eaves side fixing member 51 is fixed to the eaves side spacer 20b with the drill screw 38. In this state, the eaves-side module 1 a is placed on the eaves-side spacer 20 b, and the protruding portion 51 c of the eaves-side fixing member 51 is inserted into the outer groove portion 5 of the module frame 2. Thereby, positioning of the eaves side module 1a is performed.

  Subsequently, as shown in FIG. 8, the intermediate spacer 20 a inserted into the lower guide rail 15 is slid from the ridge side end of the gantry frame 12. At this time, the base portion 50a of the intermediate fixing member 50 may be inserted into the upper guide rail 26 of the intermediate spacer 20a. And it arrange | positions in the state which inserted the eaves side protrusion part 50c of the intermediate | middle fixing member 50 in the outer side groove part 5 currently formed in the module frame 2 of the eaves side module 1a. In this state, the intermediate spacer 20 a is fixed to the gantry frame 12 with the drill screw 38. Further, the intermediate fixing member 50 is fixed to the intermediate spacer 20a with the drill screw 38. Thereby, the eaves-side module 1a is fixed on the gantry frame 12.

  Next, the ridge-side module 1b is placed on the intermediate spacer 20a, and the ridge-side protruding portion 50d of the intermediate fixing member 50 is inserted into the outer groove portion 5 of the eaves-side module frame 2. Thereby, the ridge-side module 1 b is positioned with respect to the gantry frame 12. At this time, the intermediate fixing member 50 is sandwiched between the module frames 2 of the eaves side module 1a and the ridge side module 1b with almost no gap.

  Thereafter, the ridge-side spacer 20 c inserted into the lower guide rail 15 from the ridge-side end of the gantry frame 12 is slid. At this time, the base portion 52a of the ridge-side fixing member 52 may be inserted into the upper guide rail 26 of the ridge-side spacer 20c. And the protrusion part 52c of the ridge side fixing member 52 is assembled | attached in the state inserted in the outer side groove part 5 of the module frame 2 of the ridge side module 1b. In this state, the ridge-side spacer 20 c is fixed to the gantry frame 12 with the drill screw 38. Further, the ridge-side fixing member 52 is fixed to the ridge-side spacer 20c with the drill screw 38. Thereby, the ridge-side module 1b is fixed to the gantry frame 12. Further, the two solar cell modules 1a and 1b are fixed in a state of being sandwiched from both sides so that the module frames 2 of the two solar cell modules 1a and 1b are integrated via the intermediate fixing member 50. The

  Finally, the ridge-side cover member 90b is fixed to the ridge-side spacer 20c with the drill screw 38. The ridge-side cover member 90b may be fixed to the gantry frame 12 with a drill screw 38. Thereby, the installation work of the solar cell modules 1a and 1b is completed.

  On the other hand, the base portions 50a, 51a, 52a of the intermediate fixing member 50, the eaves side fixing member 51, and the ridge side fixing member 52 are in a state before the corresponding spacers 20a, 20b, 20c are fixed to the rail bottom surface 26a. The lower guide rail 15 has a slidable shape. More specifically, each base portion 50a, 51a, 52a is formed on the rail bottom surface 15a of the lower guide rail 15 while both widthwise end portions are inserted into the two lower engaging recesses 15d, 15e of the lower guide rail 15. It has a shape that can slide along the eaves direction X. As a result, as will be described next, it is possible to share the structure and components used in an area where the solar cell module 1 is not required to be raised, that is, in a snowy area.

  9, 10, and 11 are views corresponding to FIGS. 6A, 7 </ b> A, and 2, respectively, in a state where the spacers 20 a, 20 b, and 20 c are removed and installed on the roof 100 in the solar power generation device 10. is there. FIG. 12 is a diagram in which the solar cell modules 1a and 1b are omitted in the KK cross section in FIG. FIG. 13 is a perspective view showing the gantry frame 12 and the intermediate fixing member 50 separately.

  9 to 13, the spacers 20 a, 20 b, and 20 c are removed and the intermediate fixing member 50, the eaves side fixing member 51, and the ridge side fixing member 52 are respectively located in the longitudinal direction intermediate portion and eave side of the gantry frame 12. It is fixed to the end and the ridge side end respectively. In addition, the base portions 50a, 51a, 52a of the fixing members 50, 51, 52 are inserted into the lower engaging recesses 15d, 15e (FIG. 12) provided on the upper portion of the gantry frame 12, and the rail bottom surface 15a. Move the slide. And each base part 50a, 51a, 52a is being fixed to the predetermined position of the rail bottom face 15a. In this state, the eaves side end of the eaves module 1a is pressed against the eaves fixing member 51. In addition, the ridge side end portion of the eaves side module 1a is pressed against the eave side surface (left side surface in FIG. 11) of the intermediate fixing member 50. Moreover, the eaves side edge part of the ridge side module 1b is pressed on the ridge side surface (right side surface of FIG. 11) of the intermediate fixing member 50. The ridge side end of the ridge side module 1b is pressed against the ridge side fixing member 52. The protrusions of the fixing members 50, 51, 52 are inserted into the corresponding outer grooves 5 of the module frame 2, and the two modules 1 a, 1 b are fixedly supported by the intermediate fixing member 50. It is the same as that of the structure.

  Thereby, the rigidity as the whole solar power generation device 10 can be made high similarly to the structure demonstrated in FIGS. 9 to 13, for example, the distance h1 (FIG. 9) between the ridge-side module 1b and the eaves-side module 1a and the gantry frame 12 is the same as that shown in FIG. 1 because the spacers 20a, 20b, and 20c are not provided. It becomes smaller than the distance h2 (FIG. 6A) in the case of the configuration of FIG. 9 and 11, the eaves-side cover member 90a and the ridge-side cover member 90b are those having a smaller vertical length than the configurations shown in FIGS. 6A and 7A, respectively. In addition, you may use what has the shape similar to the structure shown to FIG. 6A and FIG. 7A, respectively as an eaves side cover member and a ridge side cover member. Such a configuration shown in FIGS. 9 to 13 is effective in that the effect of increasing the rigidity of the solar power generation device 10 can be obtained in areas other than a snowy region.

  According to said structure, the intermediate | middle fixing member 50 is fixed in the state pinched | interposed by the two solar cell modules 1a and 1b almost without gap. In this state, the photovoltaic power generation apparatus 10 including the gantry frame 12, the spacers 20a, 20b, and 20c, the fixing members 50, 51, and 52, and the solar cell modules 1a and 1b can be regarded as an integral rigid object. . Therefore, the rigidity of the photovoltaic power generation apparatus 10 as a whole can be increased. Further, the rigidity can be increased by preventing the modules 1a and 1b from being lifted by the insertion structure of the protruding portions 50c and 50d with respect to the outer groove portion 5.

  In the present embodiment, the eaves side module 1a and the ridge side module 1b are fixed to the upper side of the gantry frame 12 via the spacers 20a, 20b, and 20c as described above. For this reason, the raising function of the spacers 20a, 20b, and 20c can prevent excessive contact with the lower frame 12 when the solar cell modules 1a and 1b are bent due to snow. Thereby, durability improvement of solar cell module 1a, 1b can be aimed at. In addition, each spacer 20a, 20b, 20c is configured using a spacer material formed by extrusion molding of a metal material, and processing work other than the work for forming the screw insertion hole 24a can be eliminated. For this reason, cost reduction can be further achieved.

  Further, with the spacers 20a, 20b, and 20c removed, the base portions 50a, 51a, and 52a of the fixing members 50, 51, and 52 are fitted by sliding into the lower guide rail 15 of the gantry frame 12. The rail bottom surface 15a can be fixed. For this reason, it is possible to realize a highly rigid structure used in a snowy region and other than a snowy region by simply removing the spacers 20a, 20b, and 20c, and to share components, thereby realizing a cheaper structure. .

  In addition, each spacer 20a, 20b, 20c is fitted into the lower guide rail 15 of the gantry frame 12 by sliding, and has a shape that can be fixed to the rail bottom surface 15a. For this reason, since each spacer 20a, 20b, 20c can be slid to the mount frame 12, and can be arrange | positioned in a predetermined position, the improvement of an assembly | attachment property can be aimed at.

  Each spacer 20a, 20b, 20c has an outer wall portion 24 that is fixed to the outer surface of the gantry frame 12 by screwing. Accordingly, the spacers 20a, 20b, and 20c can be prevented from being inclined with respect to the gantry frame 12, and the solar cell modules 1a and 1b can be stably fixed on the gantry frame 12.

  FIG. 14 is a diagram corresponding to FIG. 4 showing another example of the present embodiment. In the configuration of FIG. 14, in the configuration shown in FIG. 4, the intermediate spacer 20a has the reinforcing portion 27 formed on the outer surface of each outer wall portion 24. Each reinforcing portion 27 is coupled to two positions separated in the vertical direction at the upper portion of the outer surface of each outer wall portion 24. Each reinforcement part 27 is formed in the cylinder shape extended in the direction of a ridge with the cross-sectional rectangle including the upper part of the outer side wall part 24. As shown in FIG.

  In the case of the above configuration, even when a force is applied to the outer wall portion 24 from the solar cell modules 1a and 1b in the direction of bending deformation with respect to the upper plate portion 22 in the direction indicated by the arrow α, Strength can be secured. For this reason, the solar cell modules 1 a and 1 b can be more stably fixed to the gantry frame 12. Other configurations and operations are the same as those in FIGS. 1 to 13.

  FIG. 15 is a diagram corresponding to FIG. 4 showing another example of the present embodiment. In the configuration of FIG. 15, in the configuration shown in FIG. 4, the gantry frame 12 has first outer flange portions 16 that extend outward in the width direction (left-right direction in FIG. 15) at the upper ends of both ends in the width direction. Moreover, the intermediate spacer 20a has the 2nd outer side collar part 28 extended in the width direction outer side in the lower end part of the outer side wall part 24 formed in the width direction both ends. Then, the second outer flange portion 28 is overlapped with the first outer flange portion 16 and fixed by screws with a screw such as a drill screw 38.

  In the case of the above-described configuration, it is not necessary to extend each outer wall portion 24 greatly below the intermediate spacer 20a and overlap and fix it on the outer surface of the gantry frame 12. For this reason, it is not necessary to arrange | position the coupling | bond part of the intermediate spacer 20a in the outer side of the lower part of the mount frame 12. FIG. Thereby, the freedom degree of the installation position of the attachment tool 30 (FIG. 7A) for fixing the mount frame 12 to a roof can be made high. For example, in the longitudinal direction of the gantry frame 12, the attachment tool 30 can be easily installed even near a position that coincides with the intermediate spacer 20 a, and the gantry frame 12 can be fixed to the roof 100 using the attachment tool 30. Other configurations and operations are the same as those in FIGS. 1 to 13.

  14 and 15, the intermediate spacer 20a has been described. However, the eaves side spacer 20b and the ridge side spacer 20c can be similarly configured.

  In the above description, each spacer 20a, 20b, 20c has a shape having an insertion portion 21a to be inserted into the lower engagement recesses 15d, 15e of the gantry frame 12, but each spacer 20a, 20b, 20c It is good also as a structure which does not have the insertion part 21a. In this configuration, after the spacers 20 a, 20 b, and 20 c are placed from the upper side of the gantry frame 12, the spacers 20 a, 20 b, and 20 c may be fixed to the gantry frame 12.

  In the above description, the eaves side spacer 20b has a shape that can slide with respect to the gantry frame 12, and the eaves side fixing member 51 has a shape that can slide with respect to the eaves side spacer 20b. On the other hand, the eaves side spacer 20b and the eaves side fixing member 51 may be fixed to the gantry frame 12 and the eaves side spacer 20b without sliding.

  In the above description, the case where two solar cell modules 1a and 1b are fixed has been described. However, when three or more solar cell modules are installed side by side in the building direction, two or more solar cell modules are adjacent to each other. What is necessary is just to comprise so that the member which has the structure similar to the intermediate | middle fixing member 50 may be arrange | positioned. In this case, the eaves-side fixing member and the ridge-side fixing member are not limited to the shapes shown in FIGS. 6D and 7B, and may be arranged on the eaves side and the ridge side of one intermediate fixing member 50. For example, the same shape as the intermediate fixing member 50 may be used.

  DESCRIPTION OF SYMBOLS 1a Solar cell module (eave side module), 1b Solar cell module (ridge side module), 2 module frame, 3 inner groove part, 4 tubular part, 5 outer groove part, 6 collar part, 10 solar power generation device, 12 mount frame, 14 tubular portion, 15 lower guide rail, 15a rail bottom surface, 15b, 15c overhang, 15d, 15e lower engagement recess, 16 first outer flange, 20a intermediate spacer, 20b eaves side spacer, 20c ridge side spacer, 21 Lower plate portion, 21a insertion portion, 22 Upper plate portion, 23 Inner plate portion, 24 Outer wall portion, 24a Screw insertion hole, 25 Intermediate plate portion, 26 Upper guide rail, 26a Rail bottom surface, 26b, 26c Overhang portion, 26d , 26e Upper engaging recess, 27 Reinforcing part, 28 Second outer collar part, 30 Fixing tool, 31 Wood , 32 Base plate, 33a, 33b Support portion, 34 Screw insertion hole, 35 Female screw hole, 36 Through hole, 37 Bolt, 38 Drill screw, 50 Intermediate fixing member, 50a Base portion, 50b Standing wall portion, 50c Eave side protrusion, 50d Building side protrusion, 50e upper side wall part, 51 eaves side fixing member, 51a base part, 51b standing wall part, 51c protrusion part, 51d upper side wall part, 51e side wall part, 51f groove, 52 ridge side fixing member, 52a base part, 52b Standing wall part, 52c Projection part, 52f Groove, 90a Eaves side cover member, 90b Building side cover member, 91 Upper wall part, 92 Side wall part, 93 groove, 94 Flat plate part, 95 Side wall part, 96 Through hole, 100 Roof, 102 field board, 104 waterproof sheet, 106 roofing material, SP solar cell panel.

Claims (8)

Two solar cell modules installed side by side in the direction of the roof ridge, each solar cell module having a solar cell panel and a module frame provided on the periphery of the solar cell panel; ,
A gantry frame having a lower guide rail provided along the ridge direction at the top, and fixed along the ridge direction on the roof;
A base portion having a shape that is fitted by being slid and inserted into the lower guide rail of the gantry frame along the building direction and can be fixed to the bottom surface of the lower guide rail, and is erected on the base portion The solar cell installed on the eaves side, comprising a standing wall part, an eaves side projecting part projecting on the eave side of the standing wall part, and a ridge side projecting part projecting on the ridge side of the standing wall part The eaves-side protrusion is combined with the module frame of the module, and the ridge-side protrusion is combined with the module frame of the solar cell module installed on the ridge side, so that the two solar cell modules are fixedly supported. An intermediate fixing member, and a solar power generation device comprising:
The base portion of the intermediate fixing member is slidably inserted along the direction of the building, and has a shape that can be fitted, and has an upper guide rail to which the base portion is fixed, and the frame and the intermediate frame A photovoltaic power generation apparatus, further comprising an intermediate spacer that is inserted between the fixing member and fixed to the bottom surface of the lower guide frame. In the solar power generation device according to claim 1,
The intermediate spacer has a shape that can be fitted by sliding and inserting into the lower guide rail of the gantry frame along a building direction, and a lower plate portion fixed to a bottom surface of the lower guide rail. Having a solar power generation device. In the solar power generation device according to claim 1,
An eaves-side base portion having a shape that can be fixed to the lower guide rail, an eave-side standing wall portion standing on the eave-side base portion, and a second protruding from the ridge side of the eave-side standing wall portion An eaves-side fixing member in which the second ridge-side protrusion is combined with the module frame of the solar cell module installed on the eaves side.
An eaves-side spacer inserted between the gantry frame and the eaves-side fixing member;
A ridge-side base portion having a shape that can be fixed to the lower guide rail, a ridge-side standing wall portion standing on the ridge-side base portion, and a second protruding from the eaves side of the ridge-side standing wall portion An eaves-side protrusion, and a ridge-side fixing member in which the second eaves-side protrusion is combined with the module frame of the solar cell module installed on the ridge side;
A photovoltaic power generation device comprising: a ridge-side spacer inserted between the gantry frame and the ridge-side fixing member. In the solar power generation device according to claim 1,
The ridge-side base portion has a shape that can be fitted and fixed to the lower guide rail by being slid into the lower guide rail of the gantry frame along the ridge eave direction.
The ridge-side spacer has a plate portion fixed to the bottom surface of the lower guide rail and a shape that can be fitted by slidingly inserting the ridge-side base portion along the ridge direction, A solar power generation device comprising: an upper guide rail to which a side base portion is fixed. In the solar power generation device according to claim 1,
The intermediate spacer has an outer wall portion that extends parallel to the lower side from both ends in the width direction orthogonal to the building eaves direction, and has an outer wall portion that is screwed and fixed to the outer surface of the gantry frame. Power generation device. In the solar power generation device according to claim 4,
The intermediate spacer has a reinforcing portion formed in a cylindrical shape including the upper portion of the outer wall portion, coupled to two positions separated in the vertical direction at the upper portion of the outer surface of each outer wall portion. Photovoltaic generator. In the solar power generation device according to claim 1,
The gantry frame has first outer flanges extending outward in the width direction at upper ends of both ends in the width direction perpendicular to the building direction,
The intermediate spacer has second outer flanges extending outward in the width direction at lower ends of both end portions in the width direction orthogonal to the ridge direction, and the second outer flange is formed on the first outer flange. A solar power generation device that is superposed and fixed with screws. In the solar power generation device according to claim 1,
The said intermediate | middle spacer is a solar power generation device comprised using the spacer raw material formed by extrusion molding of the metal material.

Images