JP2017197948A - Fixing structure for solar battery module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fixing structure for a solar battery module capable of fixing the solar battery module even when the solar battery module product changes and a gap dimension between the adjacent solar battery modules changes.SOLUTION: A fixing metal fitting 46 includes a lower fixing metal fitting 48 and an upper fixing metal fitting 50, the fixing metal fitting holding two adjacent solar battery modules 12, 14 in between with a lower receiving metal fitting 44. The lower fixing metal fitting 48 has a cutout part 52C formed thereon and the upper fixing metal fitting 50 has a cutout part 58C formed thereon, making the lower fixing metal fitting 48 and the upper fixing metal fitting 50 relatively movable through the cutout parts 52C, 58C with reference to a bolt 40. The configuration enables the solar battery module 12 and the solar battery module 14 to contact with or separate from each other in a planar direction, through the lower fixing metal fitting 48 and the upper fixing metal fitting 50. As such, a dimentional difference is absorbed even when the product changes and a gap dimension between the adjacent solar battery modules 12, 14 changes.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a solar cell module fixing structure.

  For example, in the invention described in Patent Document 1, a technique including a long leg metal fitting and a short leg metal fitting is disclosed as a fixing metal fitting for a solar cell module. It is possible to follow the module in the height direction.

JP 2014-47570 A

  On the other hand, various products of the solar cell module are on the market, and the outer dimensions thereof are different for each product. For this reason, if the product is different, the gap between adjacent solar cell modules will be different, but in the above prior art, it is not possible to follow along the surface direction of the solar cell module, so for each product of the solar cell module It becomes necessary to manufacture different fixing brackets.

  In view of the above facts, the present invention has an object to obtain a solar cell module fixing structure that can fix a solar cell module even if the product of the solar cell module changes and the gap size between adjacent solar cell modules changes. It is.

  In order to achieve the above object, a solar cell module fixing structure according to a first aspect includes a receiving bracket that supports end portions of two solar cell modules arranged adjacent to each other, and the two solar cell modules. A pair of fixing brackets that respectively contact the upper surfaces of the end portions and sandwich the end portions of the two solar cell modules with the lower bracket; and the pair of fixing brackets disposed between the two solar cell modules. And a fastening member that increases the holding force for holding the two solar cell modules by moving them toward the lower fitting side, and the pair of fixing brackets is one solar cell module via the fastening member. One fixing bracket that presses the upper surface of the other solar cell, and presses the upper surface of the other solar cell module through the fastening member over the one fixing bracket, and It is configured to include the other fixing bracket which is capable relative separable along a plane direction thereof with respect to the solar cell module, a.

  In the solar cell module fixing structure according to the first aspect, the lower metal fitting supporting the lower surfaces of the end portions of the two solar cell modules arranged adjacent to each other and the upper surfaces of the end portions of the two solar cell modules are in contact with each other. The end portions of the two solar cell modules are sandwiched between the pair of fixing brackets. Then, the pair of fixing metal fittings moves to the receiving metal fitting side by being tightened by a fastening member disposed between the two solar cell modules, and thereby the holding force for holding the two solar cell modules is respectively Increase.

  Here, the pair of fixing brackets includes one fixing bracket and the other fixing bracket, and the one fixing bracket presses the upper surface of one solar cell module via a fastening member. It has become. In addition, the other fixing bracket overlaps with the one fixing bracket and presses the upper surface of the other solar cell module via the fastening member. It is possible to make contact and separation relative to the battery module along the surface direction.

  That is, in the pair of fixing brackets, the amount of overlap between the one fixing bracket and the other fixing bracket can be changed. Thereby, even if the product of a solar cell module changes and the gap | interval dimension between adjacent solar cell modules changes, a solar cell module can be fixed with the said pair of fixing metal fittings.

  The solar cell module fixing structure according to a second aspect is the solar cell module fixing structure according to the first aspect, wherein the fastening member includes a bolt provided on the lower metal fitting and a nut screwed to the bolt. And includes a sliding means that is provided on the pair of fixing brackets and reduces the amount of overlap between the other fixing bracket and the one fixing bracket when the tightening force by the nut is increased. Yes.

  In the solar cell module fixing structure according to the second aspect, the fastening member is configured to include a bolt provided on the lower fitting and a nut screwed to the bolt, and the pair of fixing fittings Is provided with sliding means. When the fastening force by the nut increases, this sliding means reduces the amount of overlap between the other fixing bracket and the one fixing bracket.

  That is, when the nut is screwed onto the bolt, the other fixing bracket is moved in a direction relatively separated from the one fixing bracket by the sliding means. Thereby, a pair of fixing metal fittings (one fixing metal fitting and the other fixing metal fitting) are respectively arranged in accordance with the gap between one solar cell module and the other solar cell module. Each end can be securely held.

  A solar cell module fixing structure according to a third aspect is the solar cell module fixing structure according to the second aspect, wherein the fixing metal member includes an upper wall portion that presses an upper surface of the solar cell module, and the upper wall portion. And a leg portion disposed between the two solar cell modules, wherein the slide means is formed at a lower end of the leg portion and is inclined toward the upper wall portion side toward the bolt side. 1 inclined surface.

  In the solar cell module fixing structure according to the third aspect, the fixing bracket includes an upper wall portion that presses the upper surface of the solar cell module, and a leg portion that is connected to the upper wall portion. Is arranged between two solar cell modules. The sliding means is a first inclined surface formed at the lower end of the leg portion, and the first inclined surface is inclined toward the upper wall portion side toward the bolt side disposed between the two solar cell modules. ing.

  Therefore, when the nut is screwed onto the bolt, the bolt side of the fixing bracket is pressed to the receiving bracket side rather than the opposite side of the bolt via the first inclined surface of the leg portion of the fixing bracket. Accordingly, the upper wall portion of the other fixing bracket and the upper wall portion of the one fixing bracket are pushed apart from each other, and as a result, the other fixing bracket and the one fixing bracket can be slid in a direction away from each other.

  The solar cell module fixing structure according to a fourth aspect is the solar cell module fixing structure according to the second aspect or the third aspect, wherein the slide means is an upper surface of an upper wall portion that presses an upper surface of the solar cell module. It is the 2nd inclined surface which is formed in this and inclines toward the downward side as it goes to the said bolt side.

  In the solar cell module fixing structure according to the fourth aspect, the sliding means is a second inclined surface formed on the upper surface of the upper wall portion of the fixing bracket, and the second inclined surface is on the lower side as it goes to the bolt side. It is inclined toward.

  Therefore, when the nut is screwed onto the bolt, the bolt side of the fixing bracket is pressed to the lower fitting side rather than the opposite side of the bolt via the second inclined surface of the upper wall portion of the fixing bracket. . Accordingly, the upper wall portion of the other fixing bracket and the upper wall portion of the one fixing bracket are pushed apart from each other, and as a result, the other fixing bracket and the one fixing bracket can be slid in a direction away from each other.

  The solar cell module fixing structure according to a fifth aspect is the solar cell module fixing structure according to any one of the first to fourth aspects, wherein the solar cell module is grounded to the fixing bracket. A protrusion is provided.

  In the solar cell module fixing structure according to the fifth aspect, since the protrusion for grounding the solar cell module is provided on the fixture, the solar cell module is grounded by fixing the solar cell module to the fixture. Can do.

  The solar cell module fixing structure according to a sixth aspect is the solar cell module fixing structure according to any one of the first aspect to the fifth aspect, wherein the solar cell module is disposed on an upper surface of the lower fitting. There is provided a restricting portion that bites the lower surface of the solar cell and restricts the movement of the solar cell module.

  In the solar cell module fixing structure according to the sixth aspect, a restricting portion is provided on the upper surface of the lower metal fitting, and the restricting portion bites the lower surface of the solar cell module and restricts the movement of the solar cell module. Therefore, it is possible to prevent the solar cell module from moving relative to the lower fitting.

  As described above, the solar cell module fixing structure according to the present invention can fix the solar cell module even if the product of the solar cell module changes and the gap size between adjacent solar cell modules changes. Has an excellent effect.

It is a disassembled perspective view which shows the state by which the several solar cell module is laid by the flat roof by the solar cell module fixing structure which concerns on this embodiment. It is a top view which shows the state by which the several solar cell module was fixed by the solar cell module fixing structure which concerns on this embodiment. FIG. 3 is a cross-sectional view taken along line 3-3 shown in FIG. It is a disassembled perspective view which shows the solar cell module fixing structure which concerns on this embodiment. (A) is sectional drawing which shows the state in which the volt | bolt was fixed to the mount frame, and (B) is sectional drawing which shows the state in which the base metal fitting was attached to the volt | bolt. (A) is sectional drawing which shows the state in which the solar cell module was mounted in the lower receiving metal fitting, (B) is sectional drawing which shows the state in which the lower fixing metal fitting was attached to one solar cell module. (A) is sectional drawing which shows the state by which the upper fixing metal fitting was attached to the other solar cell module, (B) is sectional drawing which shows the state in which two solar cell modules were fixed to the mount frame. (A), (B) is a top view for demonstrating the effect | action of the solar cell module which concerns on this Embodiment. (A), (B) is a side view which respectively shows the modification of a pair of fixing metal fixture which comprises the solar cell module fixing structure which concerns on this embodiment. (A), (B) is a perspective view which shows the modification of the upper fixing metal fitting of the solar cell module fixing structure which concerns on this embodiment, respectively. (A) is a perspective view which shows the modification of the receiving metal fitting of the solar cell module fixing structure which concerns on this embodiment, (B) is sectional drawing for demonstrating the effect | action of (A).

  Hereinafter, a solar cell module fixing structure according to an embodiment of the present invention will be described with reference to the drawings.

  In FIG. 1, a plurality of solar cell modules (the other solar cell module) 12 and a solar cell module (the other solar cell module) 14 arranged adjacent to each other by the solar cell module fixing structure 10 according to the present embodiment. A perspective view showing the fixed state is shown.

  For example, as shown in FIG. 1, the plurality of solar cell modules 12 and 14 are laid on the land roof 18 via the mount 16. Here, the gantry 16 includes a lower beam 34 and an upper beam 32. The upper crosspiece 32 and the lower crosspiece 34 are each made of extruded material made of aluminum, and a groove portion is formed along the longitudinal direction of the upper crosspiece 32 and the lower crosspiece 34 at the center in the width direction of the upper crosspiece 32 and the lower crosspiece 34. 32A and 34A are formed, respectively.

  The lower rail 34 is fixed to the land roof 18 via an anchor bolt 35 and a dedicated fixing bracket 36 driven into the land roof 18. Further, the upper beam 32 is fixed to the lower beam 34 via a dedicated fixing bracket 38 in a state orthogonal to the lower beam 34. In this embodiment, the solar cell module 12 is attached to the upper beam 32. 14 are fixed (described later).

  Note that the direct-current power generated by the solar cell modules 12 and 14 is supplied to a power conditioner (not shown). In this power conditioner, DC power is converted into AC power, and the power generated by the solar cell module is distributed to a general load such as an indoor lighting device through a distribution board connected to the power conditioner. The electric power generated by being connected to the commercial power system via the watt-hour meter is transmitted to the electric power company.

  On the other hand, FIG. 2 is a plan view showing a state in which a plurality of solar cell modules 12 and 14 arranged adjacent to each other are fixed by the solar cell module fixing structure 10 according to the present embodiment.

  As shown in FIG. 1 and FIG. 2, the solar cell modules 12, 14 are provided at solar cell panels 20, 22 having a substantially rectangular shape in plan view, and end portions 24, 26 of the solar cell panels 20, 22. The rectangular frames 28 and 30 are respectively formed. Moreover, the solar cell panels 20 and 22 are comprised by photovoltaic devices, such as a single crystal silicon, a polycrystalline silicon, an amorphous silicon, and a CIGS compound semiconductor. On the other hand, the frames 28 and 30 are made of an aluminum alloy, and as shown in FIG. 3, the cross-sectional shape when cut along the plate thickness direction of the solar cell panels 20 and 22 is substantially E-shaped. doing.

  The frames 28 and 30 will be described in detail. The frames 28 and 30 are provided with peripheral walls 28A and 30A that constitute the outer shape of the frames 28 and 30 and are arranged along the thickness direction of the solar cell panels 20 and 22, respectively. Upper walls 28B and 30B project from the upper ends of the peripheral walls 28A and 30A toward the inside of the frames 28 and 30, respectively. Further, lower walls 28C and 30C project from the lower ends of the peripheral walls 28A and 30A toward the inside of the frames 28 and 30, respectively. Further, middle walls 28D and 30D project toward the inside of the frame 28 between the upper wall 28B and the lower wall 28C and between the upper wall 30B and the lower wall 30C.

  The solar cell panel 20 is sandwiched between the upper wall 28B and the middle wall 28D of the frame 28, and the solar cell panel 22 is sandwiched between the upper wall 30B and the middle wall 30D of the frame 30. Therefore, the lower surface 20A of the solar cell panel 20 and the lower surface 22A of the solar cell panel 22 are provided with a gap t ′ between the upper surface 28C1 of the lower wall 28C of the frame 28 and the upper surface 30C1 of the lower wall 30C of the frame 30, respectively. . This prevents the lower surface 20A of the solar cell panel 20 and the lower surface 22A of the solar cell panel 22 from directly contacting the placement surface.

  The upper wall 28B of the frame 28 is inclined in a direction approaching the middle wall 28D as it is separated from the peripheral wall 28A, and the upper wall 30B of the frame 30 is closer to the middle wall 30D as it is separated from the peripheral wall 30A. Inclined to. As a result, the upper walls 28B and 30B are in contact with the upper surface 20B of the solar cell panel 20 and the upper surface 22B of the solar cell panel 22 in a state where they have elasticity, respectively, and the upper walls 28B and 30B and the middle walls 28D and 30D. Thus, the end portions 24 and 26 of the solar cell panels 20 and 22 are securely sandwiched, respectively.

  As described above, in the present embodiment, the solar cell modules 12 and 14 are fixed to the upper rail 32. For this reason, a head 40A of a bolt (part of a fastening member) 40 is inserted into the groove 34A at a predetermined position along the longitudinal direction of the upper bar 32, and a nut is attached to the screw 40B of the bolt 40. 42 is screwed and the bolt 40 is fixed to the upper crosspiece 32.

  Here, the lower metal fitting 44 and the pair of fixing metal fittings 46 used when the solar cell modules 12 and 14 are fixed to the upper rail 32 will be described.

  FIG. 4 is an exploded perspective view showing the receiving metal fitting 44 and the pair of fixing metal fittings 46. 3 and 4 is formed of iron, stainless steel, or the like, has a rectangular shape in plan view, and has a through hole 44A in the center. A weld nut 45 is provided on the upper surface 44B of the receiving bracket 44 with the through hole 44A as the center, and the weld nut 45 can be screwed into the bolt 40. Further, stoppers 44C and 44D that are bent substantially vertically upward are provided at both ends in the longitudinal direction of the lower metal fitting 44, respectively. A pair of fixing metal fittings 46 are arranged on the lower receiving metal fitting 44.

  The pair of fixing metal fittings 46 is formed of iron, stainless steel, or the like. The pair of fixing brackets 46 includes a lower fixing bracket (one fixing bracket) 48 and an upper fixing bracket (the other fixing bracket) 50, and the upper fixing bracket 50 is above the lower fixing bracket 48. Some of them overlap. The lower fixing bracket 48 can support the solar cell module 14 together with the lower receiving bracket 44, and the upper fixing bracket 50 can support the solar cell module 12 together with the lower receiving bracket 44.

Hereinafter, specific configurations of the upper fixing bracket 50 and the lower fixing bracket 48 will be described.
First, the lower fixing bracket 48 will be described. The lower fixing bracket 48 includes an upper wall portion 52 having a rectangular shape in plan view. The upper wall 52 is set to be larger than the width of the lower fitting 44. Further, from the center portion of the outer edge portion 52A on the upper fixing metal fitting 50 side of the upper wall portion 52, a long hole-like cutout portion 52C is cut out toward the outer edge portion 52B facing the outer edge portion 52A. . The threaded portion 40B of the bolt 40 can be inserted into the notch 52C.

  Further, in the upper wall portion 52, a pair of leg portions 56 are suspended from a pair of outer edge portions 52D arranged in parallel with the notch portions 52C, and the pair of leg portions 56 are viewed in a plan view. It is arranged on the outer side in the width direction of the support bracket 44. Further, a contact piece 54 protrudes from the outer edge portion 52B of the upper wall portion 52, and the contact piece 54 is inclined downwardly toward the direction away from the upper wall portion 52, and the frame of the solar cell module 14 is formed. 30 can be brought into contact with the upper wall 30B.

  Next, the upper fixing metal fitting 50 will be described. The upper fixing metal fitting 50 includes an upper wall portion 58 that has a rectangular shape in plan view, like the lower fixing metal fitting 48. The upper wall portion 58 is set to be larger than the width of the lower fitting 44. Further, from the center portion of the outer edge portion 58A on the lower fixing bracket 48 side of the upper wall portion 58, a long hole-like notch portion 58C is cut out toward the outer edge portion 58B facing the outer edge portion 58A. .

  The cutout portion 58C is formed so as to overlap vertically with the cutout portion 52C of the lower fixing bracket 48, and the screw portion 40B of the bolt 40 can be inserted into the cutout portion 58C. That is, the lower fixing metal 48 and the upper fixing metal 50 can be moved relative to each other via the notch 52C of the lower fixing metal 48 and the notch 58C of the upper fixing metal 50 with the bolt 40 as a reference.

  Further, in the upper wall portion 58, a pair of leg portions 62 are suspended from a pair of outer edge portions 58D arranged in parallel with the notch portions 58C, and the pair of leg portions 62 are viewed in a plan view. It is arranged on the outer side in the width direction of the support bracket 44. Further, a contact piece 60 protrudes from the outer edge portion 58B of the upper wall portion 58, and the contact piece 60 is inclined downward toward the direction away from the upper wall portion 58, and the frame of the solar cell module 12 is formed. 28 can be brought into contact with the upper wall 28B.

  As described above, the pair of leg portions 62 of the upper fixing metal fitting 50 and the pair of leg portions 56 of the lower fixing metal fitting 48 are arranged on the outside of the lower metal fitting 44 in plan view. When the nut 42 is screwed into the threaded portion 40B of 40, the lower end 62A of the leg portion 62 of the upper fixing bracket 50 and the lower end 56A of the leg portion 56 of the lower fixing bracket 48 come into contact with the upper surface 32B of the upper rail 32. It is possible. Thereby, it is made for the fastening force by the volt | bolt 40 and the nut 42 not to act on the solar cell modules 12 and 14 more than necessary.

  Since the upper fixing bracket 50 partially overlaps the lower fixing bracket 48, the upper wall portion 58 of the upper fixing bracket 50 has an upper wall portion corresponding to the plate thickness. It will be arranged above 52. For this reason, the contact piece 60 of the upper fixing bracket 50 has a larger inclination angle with respect to the upper wall portion 58 than the contact piece 54 of the lower fixing bracket 48.

  Next, the operation and effect of the solar cell module fixing structure according to the present embodiment will be described.

  First, the fixing procedure of the solar cell modules 12 and 14 according to the present embodiment will be described. FIG. 1 and FIG. 5 (A) show an upper bar 32 constituting the upper part of the mount 16 for fixing the solar cell modules 12 and 14. As described above, the head portion 40A of the bolt 40 is inserted into a predetermined position of the groove portion 34A of the upper rail 32, and the nut 42 is screwed into the screw portion 40B of the bolt 40 to fix the bolt 40 to the upper rail 32. Is done. Then, as shown in FIG. 5B, the weld nut 45 of the lower bracket 44 is screwed into the threaded portion 40B of the bolt 40, and the lower bracket is placed at a predetermined position in the height direction with respect to the upper rail 32. 44 is arranged.

  Next, as shown in FIG. 6A, the end 24 (frame 28) of the solar cell module 12 is placed on one side of the lower bracket 44 with the bolt 40 interposed therebetween, and the other end of the lower bracket 44. The end portion 26 (frame 30) of the solar cell module 14 is placed on. At this time, the lower wall 28C of the frame 28 of the solar cell module 12 is disposed inside the stopper 44C of the lower receiving bracket 44, and the lower wall 30C of the frame 30 of the solar cell module 14 is lower than the stopper 44D of the lower receiving bracket 44. Arranged inside.

  For this reason, when the lower wall 28 </ b> C of the frame 28 comes into contact with the stopper 44 </ b> C of the lower metal fitting 44, the movement of the solar cell module 12 in the direction away from the bolt 40 is restricted. Similarly to the solar cell module 12, the lower wall 30 </ b> C of the frame 30 abuts against the stopper 44 </ b> D of the lower metal fitting 44, so that the solar cell module 14 is restricted from moving away from the bolt 40. It will be.

  Next, as shown in FIG. 6B, the lower fixing bracket 48 is moved from the upper side of the bolt 40 to the lower receiving bracket 44 side, and the threaded portion 40B of the bolt 40 is inserted into the notch 52C of the lower fixing bracket 48. To insert. Then, the contact piece 54 protruding from the upper wall portion 52 of the lower fixing bracket 48 is brought into contact with the upper wall 30 </ b> B of the frame 30 of the solar cell module 14.

  7A, the upper fixing bracket 50 is moved from the upper side of the bolt 40 toward the lower receiving bracket 44, and the screw portion 40B of the bolt 40 is attached to the notch 58C of the upper fixing bracket 50. Insert it. As a result, the upper fixing bracket 50 overlaps with the lower fixing bracket 48, and the contact piece 60 protruding from the upper wall portion 58 of the upper fixing bracket 50 is brought into contact with the upper wall 28 </ b> B of the frame 28 of the solar cell module 12.

  In this state, as shown in FIG. 7B, when the nut 64 is screwed into the threaded portion 40B of the bolt 40, the upper wall portion of the lower fixing bracket 48 is passed through the upper wall portion 58 of the upper fixing bracket 50. 52 is pressed. As a result, the contact piece 54 of the lower fixing bracket 48 presses the upper wall 30B of the frame 30 of the solar cell module 14, and the contact piece 60 of the upper fixing bracket 50 presses the upper wall 28B of the frame 28 of the solar cell module 12. Press. The solar cell module 14 is sandwiched between the lower receiving bracket 44 and the lower fixing bracket 48, and the solar cell module 12 is sandwiched between the lower receiving bracket 44 and the upper fixing bracket 50.

  That is, in this embodiment, as shown in FIG. 3 and FIG. 4, the frame 28 of the adjacent solar cell module 12 through the bolt 40 and the nut 64 with the lower fitting 44 and the pair of fixing fittings 46, The frame 30 of the solar cell module 14 is sandwiched.

  Further, in the present embodiment, the pair of fixing brackets 46 includes a lower fixing bracket 48 and an upper fixing bracket 50, and the lower fixing bracket 48 is formed with a notch 52 </ b> C. A notch 58C is formed in the. The notch portion 58C is formed so as to overlap the notch portion 52C vertically, and the lower fixing bracket 48 and the upper fixing bracket are interposed via the notch portion 52C and the notch portion 58C with reference to the bolt 40. 50 is relatively movable.

  Thereby, in this embodiment, as FIG. 8 (A) and (B) show, the solar cell module 12 and the solar cell module 14 are the surface through the lower fixing bracket 48 and the upper fixing bracket 50. It is possible to make contact and separation relatively along the direction. Therefore, even when the product of the solar cell module changes and the gap size (t1, t2) changes between the adjacent solar cell modules 12, 14, the dimensional difference can be absorbed.

  As described above, in the present embodiment, the lower fixing bracket 48 and the upper fixing bracket 50 are arranged in accordance with the gap t between the solar cell module 12 and the solar cell module 14. 48 can securely hold the frame 28 of the solar cell module 12 and the frame 30 of the solar cell module 14.

  Further, as shown in FIGS. 3 and 4, in this embodiment, the pair of leg portions 56 of the upper fixing bracket 50 and the pair of leg portions 62 of the lower fixing bracket 48 are respectively outside the lower receiving bracket 44 in plan view. The lower end 62A of the leg portion 62 and the lower end 56A of the leg portion 56 can be brought into contact with the upper surface 32B of the upper bar 32. In other words, the upper fixing bracket 50 and the lower fixing bracket 48 can be tightened with the bolt 40 and the nut 64 until the lower end 62A of the leg portion 62 and the lower end 56A of the leg portion 56 abut against the upper surface 32B of the upper bar 32.

  Therefore, when the nut 64 is screwed into the screw portion 40B of the bolt 40, the upper wall portion 58 of the upper fixing bracket 50 and the upper wall portion 52 of the lower fixing bracket 48 are connected to the bolt 40 side via the nut 64. It is pressed downward rather than the opposite side of the bolt 40. As a result, the upper wall portion 58 of the upper fixing metal fitting 50 and the upper wall portion 52 of the lower fixing metal fitting 48 are pushed apart from each other. As a result, the upper fixing metal fitting 50 moves away from the solar cell module 14. Thereby, the amount of overlap between the upper fixing bracket 50 and the lower fixing bracket 48 is reduced, and the lower fixing bracket 48 and the upper fixing bracket 50 are arranged in accordance with the gap t between the solar cell module 12 and the solar cell module 14. Become.

(Other embodiments)
Furthermore, in the present embodiment, as shown in FIG. 9A, the lower end 56A of the leg portion 56 of the lower fixing bracket 48 and the lower end 62A of the leg portion 62 of the upper fixing bracket 50 are Inclined surfaces (first inclined surfaces) 66 and 68 that incline upward toward the bolt 40 (see FIG. 3) side of the metal fitting 44 (see FIG. 3) may be formed.

  In this case, when the nut 64 (see FIG. 3) is screwed into the threaded portion 40B of the bolt 40, the lower end 56A of the leg portion 56 and the lower end 62A of the leg portion 62 of the fixing bracket 46 shown in FIG. It abuts on the upper surface 32B (see FIG. 3) of the crosspiece 32 (see FIG. 3). When the nut 64 is further tightened from this state, the bolt 40 side of the fixing bracket 46 is pressed to the lower bracket 44 side rather than the opposite side of the bolt 40 through the inclined surfaces 66 and 68 of the leg portions 56 and 62. The As a result, the upper wall portion 52 of the lower fixing bracket 48 and the upper wall portion 58 of the upper fixing bracket 50 are pushed apart from each other, and as a result, the lower fixing bracket 48 and the upper fixing bracket 50 can be slid in directions away from each other. it can.

  In addition to this, as shown in FIG. 9 (B), in the upper wall portion 52 of the lower fixing bracket 48 and the upper wall portion 58 of the upper fixing bracket 50 in the pair of fixing brackets 46, the lower receiving bracket 44 ( Inclined surfaces (second inclined surfaces) 70 and 72 that incline toward the upper side as they go to the bolt 40 side of FIG. 3 may be formed. In this case, the lower end 56A of the leg portion 56 of the fixing bracket 46 and the lower end 62A of the leg portion 62 do not need to contact the upper surface 32B (see FIG. 3) of the upper bar 32 (see FIG. 3). The upper wall portion 52 of the lower fixing bracket 48 and the upper wall portion 58 of the upper fixing bracket 50 can be pushed apart from each other. The first inclined surface and the second inclined surface may be formed only on the upper fixing metal fitting 50 side.

  Furthermore, as shown in FIGS. 10A and 10B, protrusions 74 and 76 that ground the solar cell module 12 to the upper fixing bracket 50 may be formed. For example, in FIG. 10A, protrusions 74 are provided at the lower portions of both ends of the tip of the contact piece 60 of the upper fixing metal fitting 50, respectively. As shown in FIG. 3, the abutment piece 60 of the upper fixing bracket 50 abuts on the upper wall 28 </ b> B of the frame 28 of the solar cell module 12, but the nut 64 is attached to the screw portion 40 </ b> B of the bolt 40. When screwed together, the protrusion 74 bites into the upper wall 28B of the frame 28.

  Further, in FIG. 10B, in the pair of leg portions 62 of the upper fixing bracket 50, a protruding portion 76 is provided at the center portion in the vertical direction of the end surface on the contact piece 60 side. As shown in FIG. 3, the abutment piece 60 of the upper fixing bracket 50 abuts on the upper wall 28 </ b> B of the frame 28 of the solar cell module 12, but the nut 64 is attached to the screw portion 40 </ b> B of the bolt 40. When screwed together, the upper fixing bracket 50 slides in a direction away from the solar cell module 14 (in the direction of arrow A), that is, in a direction away from the solar cell module 14. The portion 76 bites into the peripheral wall 28 </ b> A of the frame 28.

  Generally, although not shown, the solar cell module is covered with an insulating film. For this reason, in the state which fixed the solar cell module to the mount via the fixing bracket, the solar cell module and the solar cell module are penetrated by the protrusions 74 and 76 shown in FIGS. 10 (A) and 10 (B). The fixing bracket can be electrically connected. Then, the solar cell module, the lower metal fitting 44, and the mount are made conductive through the fixing bracket, and as a result, the solar cell module can be grounded.

  Furthermore, as shown in FIGS. 11A and 11B, a claw-shaped restricting portion 78 that bites against the lower wall 30 </ b> C of the frame 30 of the solar cell module 14 is provided on the upper surface 44 </ b> B of the lower fitting 44. May be. According to this, in a state where the solar cell module 12 is placed on the receiving bracket 44, the regulating portion 78 bites against the lower wall 30 </ b> C of the frame 30 of the solar cell module 12, thereby moving the solar cell module 12. While being able to regulate, the solar cell module 12 can be grounded.

  As described above, the present invention has been described with reference to one embodiment. However, the present invention is not limited to the embodiment, and the above-described embodiments are within the scope of the present invention. Various modifications and substitutions can be made to the embodiment.

DESCRIPTION OF SYMBOLS 10 Solar cell module fixing structure 12 Solar cell module 14 Solar cell module 24 End part (end part of solar cell module)
26 End (end of solar cell module)
28 frame (end of solar cell module)
28B Upper wall (upper surface of end portion of solar cell module)
28C Lower wall (lower surface of solar cell module)
30 frames (end of solar cell module)
30B Upper wall (upper surface of the end of the solar cell module)
30C Lower wall (lower surface of solar cell module)
40 bolt (fastening member)
44 Lower mounting bracket 46 Fixing bracket 48 Lower fixing bracket 50 Upper fixing bracket 64 Nut (fastening member)
66 Inclined surface (sliding means, first inclined surface)
68 Inclined surface (sliding means, first inclined surface)
70 inclined surface (sliding means, second inclined surface)
72 Inclined surface (sliding means, second inclined surface)
74 Projection part 76 Projection part 78 Restriction part

Claims (6)

A base metal fitting that supports the ends of two solar cell modules arranged adjacent to each other;
A pair of fixing brackets that respectively contact the upper surfaces of the end portions of the two solar cell modules and sandwich the end portions of the two solar cell modules with the lower bracket;
Fastening members that are arranged between the two solar cell modules and increase the clamping force for clamping the two solar cell modules by moving the pair of fixing metal fittings to the lower fitting metal side,
With
The pair of fixing brackets are:
One fixing bracket that presses the upper surface of one solar cell module through the fastening member,
The upper surface of the other solar cell module is pressed over the one fixing bracket via the fastening member, and can be relatively contacted and separated along the surface direction with respect to the one solar cell module. The other fixing bracket,
A solar cell module fixing structure configured to include. The fastening member includes a bolt provided on the lower metal fitting, and a nut screwed to the bolt,
2. The sun according to claim 1, further comprising a slide unit that is provided on the pair of fixing brackets and reduces an overlapping amount between the other fixing bracket and the one fixing bracket when a tightening force by the nut is increased. Battery module fixing structure. The fixing bracket includes an upper wall portion that presses an upper surface of the solar cell module, and a leg portion that is connected to the upper wall portion and disposed between the two solar cell modules,
3. The solar cell module fixing structure according to claim 2, wherein the sliding means is a first inclined surface formed at a lower end of the leg portion and inclined toward the upper wall portion side toward the bolt side.   The said slide means is a 2nd inclined surface which is formed in the upper surface of the upper wall part which presses the upper surface of the said solar cell module, and inclines toward the downward side as it goes to the said bolt side. Solar cell module fixing structure.   The solar cell module fixing structure according to any one of claims 1 to 4, wherein the fixing metal fitting is provided with a protrusion for grounding the solar cell module.   The regulation part which bites into the undersurface of the solar cell module and regulates the movement of the solar cell module is provided on the upper surface of the lower metal fitting. Solar cell module fixing structure.