JP2017206911A - Holding mechanism for corner member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a holding mechanism for a corner member that holds corner members of diverse sizes and shapes to suit a roof form and contributes toward formation of a solar cell module array of excellent design.SOLUTION: A holding mechanism for a corner member includes: a first holding member located at each of corners that face a same direction of a solar cell module array connected to an edge part of a frame and located on both sides of the frame, the first holding member holding either of corner members that are located partially opposite each other; and a second holding member holding a corner member on a side and a corner member on the other side located partially opposite the corner member on the side. The first holding member includes a connection part connected with the edge part of the frame, and a movement restricting part that restricts movement of the corner member on the side in a direction of extension of the frame and a direction orthogonal to the direction of extension of the frame. A side of the corner member on the side opposite the corner member on the other side and a part of the corner member on the other side opposite the corner member on the side that extend in a same direction as the direction of extension of the frame protrude outward of the frame, and the second holding member is installed at the outwardly protruded location.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a holding mechanism for a corner member disposed at a corner of a solar cell module array.

  Conventionally, when a plurality of rectangular solar cell modules are used to form a solar cell module array on the roof surface, a plurality of solar cell module rows arranged in the beam direction are arranged from the eave side toward the ridge side.

  In a general house roof, the length of the side of the roof surface often changes in the girder direction from the eave side toward the ridge side. For example, when the length in the girder direction is shortened from the eave side toward the ridge side, the number of solar cell modules constituting the solar cell module row is increased from the eave side toward the ridge side in accordance with the roof shape. Less. Therefore, both end portions (end portions in the girder direction of the roof) of the solar cell module array are stepped and inferior in design.

  In view of the above problems, by arranging substantially triangular corner covers and solar cell modules (hereinafter referred to as “corner members”) at both ends of the solar cell module row, both side ends of the solar cell module array are linear. The structure which makes is known (for example, refer patent document 1).

  The configuration of Patent Document 1 is as follows.

  The pedestals extending from the eaves side toward the ridge side are arranged at equal intervals in the girder direction, and the length of the gantry becomes longer from both ends of the girder direction toward the center. And the rectangular solar cell module is arrange | positioned toward the ridge side from the eaves side between adjacent mounts, and is being fixed to the mount. Since the positions of the ends of the gantry do not coincide on the ridge side, a rectangular solar cell module cannot be arranged. Therefore, a corner member having a substantially right triangle is arranged at the ridge side end of the solar cell module row arranged from the eaves side toward the ridge side. In the corner member having a substantially right triangle, one of the sides forming a right angle is fixed to the gantry, and the other one is fixed to the adjacent rectangular solar cell module. By having said structure, the substantially right-angled triangular corner member is located continuously in the both-sides edge part of a solar cell module array, and the both-sides edge part of a solar cell module array becomes a linear form.

Japanese Patent No. 3692292

  However, Patent Document 1 is premised on the use of corner members having a substantially right triangle shape of the same size. Therefore, the inclination angle of the both ends of the solar cell module array is determined, and the shape of the solar cell module array cannot be flexibly matched to the roof shape. Moreover, even if it is going to use the corner member of a different size and shape in order to match a roof shape, the structure of the above-mentioned patent document 1 prepares a base of various lengths, or the corner member is fixed to the base unless the base is extended. Cannot be practical.

  In view of the above-mentioned problems, the present invention provides a highly practical corner member holding mechanism that can contribute to the formation of a solar cell module array having high design that matches the shape of the roof by holding corner members of various sizes and shapes. The purpose is to do.

The present invention is arranged at a corner of a solar cell module row fixed to a pedestal installed at a fixed interval on an installation surface, and has a side extending in the same direction as the direction in which the pedestal extends, and the solar cell module A corner member holding mechanism having opposing sides,
A first holding member that is connected to an end of the gantry and is located at each corner in the same direction of the solar cell module row that is located across the gantry, and holds one of the corner members that face each other. When,
A second holding member that holds the one corner member and the other corner member that partially faces the one corner member;
The first holding member is a movement restriction that restricts movement of the connecting portion connected to an end of the gantry and movement of the one corner member in a direction in which the gantry extends and a direction orthogonal to the direction in which the gantry extends. Are provided, and
The side facing the other corner member of the one corner member and the part of the side facing the one corner member of the other corner member respectively extending in the same direction as the extending direction of the gantry, It protrudes to the outside of the gantry, and the second holding member is installed at a location protruding to the outside.

  According to the disclosed technology, it is possible to provide a corner member holding mechanism with high practicality that can contribute to the formation of a solar cell module array having a high design property that holds corner members of various sizes and shapes and matches the roof shape.

It is the schematic which shows an example which installed the solar cell module array which implemented the holding | maintenance mechanism of the corner member which concerns on embodiment on the roof surface, (A) is a whole top view, (B) is the partial expanded perspective view of (A). FIG. It is a partial expansion perspective view of the location F shown to FIG. 1 (B). It is a perspective view explaining the relationship between a mount frame, a corner member, and a 1st holding member. It is a perspective view explaining the relationship between a mount frame, a corner member, and a 2nd holding member. It is a partial expansion perspective view which shows the state which hold | maintained the eaves side corner member and the ridge side corner member with the 2nd holding member. It is the elements on larger scale of the location G shown to FIG. 1 (A).

  Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and the overlapping description may be abbreviate | omitted.

  FIG. 1A is an overall plan view showing an example in which a solar cell module array in which a corner member holding mechanism according to an embodiment is implemented is installed on a roof surface. Note that the solar cell module array AR in the illustrated example is based on a configuration having a plurality of solar cell modules 1 and corner members 3.

  FIG. 1B is a partially enlarged perspective view of a location E of the solar cell module array shown in FIG. FIG. 1B is a diagram for explaining the configuration and arrangement of the corner member 3, and the first and second members from the top of FIG. 1A are omitted. In this specification, the girder direction refers to the arrow X1-X2 direction, and the water flow direction refers to the arrow Y1-Y2 direction. The eaves side refers to the arrow Y2 side, and the ridge side refers to the arrow Y1 side.

  The roof shape of the roof surface 100 which is the installation surface of the solar cell module array shown in FIG. 1 (A) was a parallelogram. This is to explain that the corner member holding mechanism of the present embodiment can exhibit design properties not only on a normal roof shape but also on various roof surfaces. Therefore, the corner member holding mechanism of the present embodiment can be similarly applied to roof shapes other than the parallelogram, such as typical dormitory roofs and gable roofs. Further, the installation surface may be on the wall surface of the building or the ground.

  On the roof surface 100 of the present embodiment, a plurality of mounts 2 parallel to the girder direction are installed at regular intervals in the water flow direction, and a plurality of rectangular solar cell modules 1 are fixed to the mount 2. Further, a corner member 3 is held at a corner of the solar cell module 1 to form a solar cell module array AR.

  The solar cell modules 1 in the illustrated example are arranged in a plurality of rows in the water flow direction. Moreover, although one solar cell module 1 is disposed in the girder direction, the present invention is not limited to this, and a plurality of adjacent solar cell modules 1 may be disposed.

  The outer periphery of the solar cell module 1 is surrounded by a frame body 10, and the frame body 10 and the gantry 2 are fixed on the roof surface 100 by fixing them with bolts. The frame body 10 includes a pair of short sides 11 and a pair of long sides 12.

  The corner member 3 in the illustrated example has a flat panel 300 and a frame body 30, and the outer peripheral edge of the panel 300 is surrounded by the frame body 30. The frame body 30 has a first side 31 and a second side 32 that form a substantially right angle, and a hypotenuse 33, and the acute angle on the ridge side (arrow Y1 side) of a substantially right triangle is horizontal (along the frame 2). A third side 34 cut away in the direction). The first side 31 faces the solar cell module 1, and the second side 32 and the third side 34 extend in the same direction as the direction in which the gantry 2 extends. The corner members 3 are arranged at the corners of the solar cell module 1, whereby both side edges of the solar cell module array AR are linear and can exhibit design.

  Conventionally, the corner member arrange | positioned at the corner part of the solar cell module 1 has used the corner member of the substantially right triangle shape of the same size. However, in this embodiment, as shown in FIG. 1A, corner members 3 having various shapes are used.

  In the solar cell module array AR of FIG. 1, the corner member 8 of the same size is installed in order from the left side (arrow X1 side) to the right side (arrow X2 side). An example is shown. However, as for the some corner member 8 arrange | positioned at the left end (arrow X1 side) of the solar cell module array AR, the corner member 3 which is not the same size may be arrange | positioned as needed. On the other hand, the plurality of corner members 3 arranged on the right end (arrow X2 side) of the solar cell module array AR have a third side 34 formed longer from the eave side to the ridge side (arrow Y2-Y1 direction). Various shape corner members 3 are arranged. The corner member 3 is not limited to the shape of the illustrated example, and may be a polygonal shape of a triangle or more.

  In this embodiment, the corner member 3 formed in a plurality of shapes can be used on the roof surface of various shapes by using the holding mechanism of the corner member.

  Hereinafter, the corner member holding mechanism according to the present embodiment that enables the use of corner members 3 having various shapes will be described with reference to FIGS. 2 to 5 are partially enlarged views at a location F in FIG.

  FIG. 2 is a partially enlarged perspective view showing a state in which the corner member 3 is held on the gantry 2 by the holding mechanism. In FIG. 2, the panel 300n of the corner member 3n on the eaves side and the solar cell module 1 are omitted for the sake of explanation. FIG. 3A is an exploded perspective view illustrating the relationship among the gantry 2, the corner member 3, and the first holding member 4. FIG. 3B is an assembly diagram for explaining an assembly state of the gantry 2, the corner member 3, and the first holding member 4, and is a perspective view seen from the left side (arrow X 2 side) of the solar cell module array AR. FIG. 3C is a side view of FIG. The frame body 30 of the corner member 3 shown in FIGS. 3A to 3C shows only the first side 31 for the sake of explanation.

  FIG. 4 is a partial perspective view illustrating the relationship among the gantry 2, the corner member 3, and the second holding member 5. FIG. 4A is a perspective view seen from the ridge side (arrow Y1 side) of the solar cell module array AR. FIG. 4B is a bottom perspective view of FIG. 4A and 4B omit the ridge-side corner member 3m and the solar cell module 1 for the sake of explanation.

  FIG. 5 is a partially enlarged perspective view showing a state where the eave-side corner member and the ridge-side corner member are held by the second holding member. Also in FIG. 5, the solar cell module 1 is omitted for the sake of explanation.

  The holding mechanism of the present embodiment is connected to the end of the gantry 2 and is one corner member (hereinafter referred to as “a corner member”) positioned at each corner of the solar cell module 1 located across the gantry 2. The first holding member 4 that holds 3n is held, the eaves-side corner member 3n, and the other corner member (hereinafter referred to as the “ridge-side corner member”) 3m are held. A second holding member 5.

(First holding member 4)
First, the arrangement configuration of the first holding member 4 at the location F will be described with reference to FIGS. 2 and 3. The first holding member 4 is connected to the end of the gantry 2.

  The gantry 2 to which the first holding member 4 is connected has a base portion 21 and an upright portion 22 having a T-shape in a sectional view rising from the base portion 21. The base portion 21 includes a pedestal 21a having a mountain-shaped screw hole portion 21b and a flange portion 21c extending in the horizontal direction from the top portion of the screw hole portion 21b. A gap S1 is formed between the bottom surface of the base 21a and the lower surface of the flange portion 21c. One side of the adjacent eaves-side solar cell module and the ridge-side solar cell module facing each other is held by the upright portion 22 and the base portion 21 of the same gantry 2.

  The first side 31 constituting the frame body 30 includes a side portion 313 and a first flange portion protruding from one end (upper side (arrow Z1 side)) of the side portion 313 (hereinafter referred to as “upper flange portion”). 311 and a second flange portion (hereinafter referred to as a “lower flange portion”) 312 protruding from the other end (lower side (arrow Z2 side)) of the side portion 313.

  Further, the frame body 30 is provided with a third flange portion (hereinafter referred to as “medium flange portion”) 314 having an L-shaped cross section that protrudes from the approximate center of the side portion 313. Each flange portion protrudes from the side portion 313 in the same direction. The intermediate flange portion 314 has a connection side 314a whose one side is connected to a substantially central position of the side portion 313, and a standing side 314b that rises in the orthogonal direction from the other side of the connection side 314a.

  The tip of the upright side 314b is located on the lower flange portion 312 side of the upper flange portion 311 and a gap S2 is provided between the upright side 314b and the upper flange portion 311. In addition, a notch portion 314c is formed at the end of the intermediate flange portion 314 by notching a part of the rising side 314b.

  For example, the first side 31, the third side 34, and the oblique side 33 shown in FIG. In other words, the middle flange portion 344 of the third side 34 is horizontally mounted between the middle flange portion 314 installed on the first side 31 and the middle flange portion 334 installed on the oblique side 33. At this time, the middle flange portion 344 is disposed at the position of the notch portion 314c of the middle flange portion 314 and the notch portion 334c of the middle flange portion 334. Therefore, the middle flange portion 344 of the third side 34 is held on the connection sides 314 a and 334 a of the middle flange portions 314 and 334.

  Although not shown in the drawings, the first side 31 and the second side 32, and the second side 32 and the oblique side 33 are assembled based on the same technical idea to constitute the frame body 30.

  When the sides of the frame body 30 are assembled in the above-described configuration, a common gap S2 is formed on the same plane between the upper flange portion of each side and the rising side of the middle flange portion (for example, FIG. 2). The panel 300 of the corner member 3 is inserted into the gap S2, and the panel 300 is held by the lower surface of the upper flange portion 311 and the upper surface of the standing side 314b. The panel 300 may be anything in the form of a plate, and may be a solar cell module.

  The first side 31 constituting the frame body 30 of the present embodiment includes a notch portion 312a in which the lower flange portion 312 is notched at an end portion on the other corner member side (ridge side (arrow Y1 side)), An extending portion 313a is formed. The extending portion 313a corresponds to the side portion 313 where the notch portion 312a is located.

  The first holding member 4 constituting the holding mechanism of the corner member 3 includes a connecting portion 41 that can be connected to an end of one side (the arrow X2 side) of the gantry 2 in the direction in which the gantry 2 extends, and the corner member 3. A projection that is a movement restricting portion that restricts movement in the direction in which the gantry 2 extends (girder direction (arrow X1-X2 direction)) and movement in the direction orthogonal to the girder direction (water flow direction (arrow Y1-Y2 direction)) Part 42.

  The connecting portion 41 extends in the width direction of the gantry 2 (direction perpendicular to the girder direction (arrow Y1-Y2 direction)). The connecting portion 41 is formed with a bolt hole 41a formed at a position corresponding to the screw hole portion 21b of the base 21a of the pedestal 2 and a support piece 41b for holding the flange portion 21c. The support piece 41b protrudes toward the gantry 2 side.

  The protruding portion 42 is connected to the surface (arrow X2 side) opposite to the gantry 2 at the eaves side end portion (arrow Y2 side) of the connecting portion 41. The protrusion 42 extends in the direction opposite to the gantry 2 (arrow X2 side), and the tip is formed in a bent shape. Therefore, the protrusion 42 has an inverted L-shaped cross section, and has a side surface 42a facing the gantry 2 side and a side surface 42b facing the eaves side.

  As for the 1st holding member 4 of the said structure, the support piece 41b is arrange | positioned in clearance gap S1 between the bottom face of the base 21a of the mount frame 2, and the lower surface of the flange part 21c, and the bolt hole 41a and the screw hole part 21b of the base 21a. Arranged at the end of the gantry 2 in a matched manner. And the 1st holding member 4 is attached to the edge part of the mount frame 2 by screwing in the volt | bolt B1 toward the screw hole part 21b of the base 21a from the bolt hole 41a of the connection part 41. FIG.

  And it arrange | positions so that the 1st edge | side 31 which comprises the frame body 30 of the corner member 3 may follow the 1st holding member 4 connected with the mount frame 2. FIG. At this time, the 1st holding member 4 is located in the notch 312a. That is, the extending portion 313 a of the first side 31 faces the side surface 42 a on the frame 2 side of the protruding portion 42 constituting the first holding member 4, and the end portion of the lower flange portion 312 of the first side 31 protrudes. It faces the eaves side surface 42b of the portion 42.

  Therefore, the protrusion part 42 can regulate the movement of the corner member 3 in the girder direction when the side face 42a and the extending part 313a come into contact with each other. Moreover, the protrusion part 42 can control the movement of the water flow direction of the corner member 3 because the side surface 42b on the eaves side contacts the end part of the lower flange part 312 of the first side 31.

  Although the illustrated projecting portion 42 is shown in the case where the tip portion is formed in a bent shape, it is not limited to this, and may be a curved shape such as a U-shape or a semicircular arc shape. It is preferable to increase the regulation force by increasing the contact area with one side 31. Moreover, although the projection part 42 of the said structure was demonstrated as an example of a movement control part in this embodiment, the structure which regulates the movement of the digit direction of the corner member 3 and the movement of a water flow direction by another means instead of a projection part. May be implemented.

(Second holding member 5)
Next, the 2nd holding member 5 is demonstrated, referring FIG.1, FIG.4, FIG.5.
As shown in FIG. 1 (B), the third side 34n of the eaves-side corner member 3n and the part of the second side 32m of the ridge-side corner member 3m on the arrow X2 side are outside the gantry 2 (arrow X2 side). The 2nd holding member 5 of this embodiment is installed in the location projected outside.

  The illustrated second holding member 5 includes a main holding member 51 and an auxiliary holding member 52. The main holding member 51 and the auxiliary holding member 52 are bolted to the outside of the third side 34n of the eave-side corner member 3n. Further, the main holding member 51 and the auxiliary holding member 52 are arranged in parallel in the digit direction of the third side 34n. The interval between the main holding member 51 and the auxiliary holding member 52 arranged in parallel is appropriately changed according to the length of the third side 34 of the frame body 30 and the like. In addition, as for the corner member 3 used in FIG. 1 (A), the 3rd edge | side 34 becomes long as it goes to the ridge side (arrow Y1 side). Therefore, the interval between the main holding member 51 and the auxiliary holding member 52 may be increased toward the ridge side. Further, when the length of the third side 34 is very short and both the main holding member 51 and the auxiliary holding member 52 cannot be installed, only the main holding member 51 is arranged. That is, only the main holding member 51 may be sufficient as the 2nd holding member 5 of this invention.

  The main holding member 51 has a bolt hole (not shown) and is fixed to the third side 34n of the corner member 3n on the eave side, and from one end (upper side (arrow Z1 side)) of the side portion 513. From the first flange portion (hereinafter referred to as “upper flange portion”) 511 that is a protruding portion that protrudes toward the corner member 3m on the ridge side, and the other end (lower side (arrow Z2 side)) of the side portion 513 And a second flange portion (also referred to as a “lower flange portion”) 512 that is a protruding portion protruding toward the corner member 3m on the ridge side.

  Similar to the main holding member 51, the auxiliary holding member 52 has an upper flange portion 521, a lower flange portion 522, and a side portion 523. A bolt hole (not shown) is formed in the side portion 523.

  The main holding member 51 and the auxiliary holding member 52 are brought into contact with the outer surfaces of the side portions 513 and 523 on the outer side of the third side 34n of the corner member 3n on the eaves side, and are joined by bolts B2 and B3. The upper flange portion 521, the lower flange portion 522, and the side portion 523 hold the second side 32m of the corner member 3m on the ridge side.

  In the upper flange portion 511 of the main holding member 51 of the present embodiment, a long hole 511a extending in the direction along the second side 32m is provided. Further, a stop portion 514 for stopping the movement of the corner member 3m in the spar direction is provided in a space formed by the upper flange portion 521, the lower flange portion 522, and the side portion 523 of the main holding member 51. The stop portion 514 has, for example, an L shape, and includes an upper side 514a that comes into contact with the upper flange portion 511 and a vertical side 514b that extends vertically from one end of the upper side 514a into the space. The stopper 514 in the illustrated example is L-shaped, but is not limited thereto, and may be C-shaped or U-shaped. A screw hole is provided in the upper side 514a. The vertical side 514b is disposed so as to be on the gantry 2 side (arrow X1 side) in the space of the main holding member 51, and restricts the movement of the corner member 3m stored in the space in the digit direction. Specifically, as shown in FIG. 5, the vertical side 514b is disposed in the vicinity of the second side 32m of the corner member 3m, so that the vertical side 514b and the end of the second side 32m are in contact with each other. Therefore, the movement of the corner member 3m in the girder direction is restricted.

  The stopper 514 is positioned and fixed in the space of the main holding member 51 by being fastened to the screw hole of the upper side 514a by a bolt B4 which is a fixing member inserted through the elongated hole 511a of the upper flange 511. . The stopper 514 having the above-described configuration is slidable within the opening range of the long hole 511a by the long hole 511a. Therefore, it is possible to finely adjust the fastening position of the stopper 514 according to the site as appropriate.

  In addition, although the stop part 514 of the example of illustration is connected with the upper flange part 511 side, it may not be restricted to this but may be connected with the lower flange part 512 side.

  The portions of the eaves-side corner member 3n and the ridge-side corner member 3m protruding from the mount 2 are supported by the second holding member 5. Therefore, the eaves-side corner member 3n and the ridge-side corner member 3m are prevented from hanging down or falling toward the installation surface such as a roof at the portion protruding from the gantry 2. The second holding member 5 may be composed of a main holding member 51 and an auxiliary holding member 52. By changing the fixing interval between the main holding member 51 and the auxiliary holding member 52, the corner member 3n on the eaves side is changed. Even if the length of the protruding portion of the corner member 3m on the ridge side from the gantry 2 becomes longer, they can be supported with each other efficiently.

  The corner member holding mechanism and holding configuration described above are similarly implemented in other corner portions. Therefore, when the corner member holding mechanism according to the present embodiment is implemented, even a corner member of various sizes and shapes can be effectively held, and a solar cell module having high designability for various shapes of roof shapes An array can be formed.

  Next, the holding mechanism of the corner member in the location G of the solar cell module array AR shown in FIG. 1 (A) will be described with reference to FIGS. In FIG. 6, the solar cell module 1 is omitted for the sake of explanation.

    FIG. 6A is a partially enlarged perspective view of a portion G shown in FIG. 1A, and is a partial perspective view illustrating the relationship among the gantry 2, the corner member 3, and the holding mechanism. FIG. 6A is a perspective view seen from the ridge side (arrow Y1 side) of the solar cell module array AR. FIG. 6B is a partial side view of FIG. 6A and a partially transparent view.

  A portion G shown in FIG. 1A indicates a connecting portion between the solar cell module 1up and the corner member 3up arranged on the most ridge side (hereinafter referred to as “the highest level side”) of the solar cell module array AR. .

  The holding mechanism for the uppermost corner member 3up is continuously in contact with the first holding member 400 connected to the end of the gantry 2 and a part of the gantry 2 and the third side 34up of the corner member 3up. A reinforcing member 6 is included.

  The reinforcing member 6 has a substantially U-shaped cross section, and has a length extending from a part of the gantry 2 to at least a part of the third side 34up of the corner member 3up. At the position of the gantry 2, the reinforcing member 6 is held by the standing part 22 and the base part 21. Further, the cross-sectional shape of the reinforcing member 6 may be a substantially C shape, a substantially I shape, or the like.

  The first holding member 400 in the illustrated example is a first holding member in that a restricting portion 430 that restricts the movement of the reinforcing member 6 in the ridge direction is provided on the side surface (arrow Y1 side) of the linking portion 410. It is different from the member 4.

  The restricting portion 430 has a base portion 430a connected to the side surface on the ridge side opposite to the protruding portion 420 of the connecting portion 410, and an L-shaped arm portion 430b connected to the upper end of the base portion 430a. ing. The arm portion 430b prevents the reinforcing member 6 from moving in the ridge direction.

  In the illustrated example, the holding member 7 that holds the reinforcing member 6 is bolted to the outside of the third side 34up of the corner member 3up. The holding member 7 has a substantially U-shaped cross section, and the reinforcing member 6 is inserted into a space formed by the U shape. The holding member 7 in the illustrated example may have substantially the same configuration as the auxiliary holding member 52 shown in FIG.

  At the end opposite to the end supported by the gantry 2, there is a gap between the reinforcing member 6 and the third side 34 up due to the thickness of the standing portion 22 and the holding member 7 of the gantry 2. is there. Therefore, it is preferable to provide a pedestal 9 that fills the gap between the reinforcing member 6 and the third side 34up at the end opposite to the end supported by the gantry 2 of the reinforcing member 6. Then, the reinforcing member 6 and the third side 34up are fixed with screws or the like through the base 9. Thereby, the reinforcing member 6 is fixed.

  Therefore, the uppermost corner member 3up is held on the gantry 2 by at least the first holding member 400 and the reinforcing member 6 described above. In addition, since the reinforcing member 6 is long and is simply screwed, the uppermost corner member 3 having the third side 34 having various lengths can be reliably held.

  The preferred embodiment has been described in detail above. However, the present invention is not limited to the above-described embodiment, and various modifications and replacements are made to the above-described embodiment without departing from the scope described in the claims. Can be added. For example, the gantry 2 used in the illustrated solar cell module array is a horizontal beam, but the holding mechanism of this embodiment can also be implemented in a solar cell module array using a vertical beam.

DESCRIPTION OF SYMBOLS 1 Solar cell module 2 Base 3 Corner member 30 Frame body 31 1st edge | side (side facing a solar cell module)
311 Upper flange (first flange)
312 Lower flange (second flange)
313 Side 312a Notch 32 Second side (side extending in the same direction as the frame extends)
34 Third side (side extending in the same direction as the frame extends)
4,400 1st support member 41 Connection part 42 Protrusion part (movement control part)
5 2nd support member 511 Upper flange part (protrusion part)
512 Lower flange (protrusion)
513 Side 514 Stop

Claims (6)

A side that is arranged at a corner of a solar cell module row fixed to a pedestal installed at a fixed interval on the installation surface, extends in the same direction as the direction in which the pedestal extends, and a side that faces the solar cell module; A corner member holding mechanism having
A first holding member that is connected to an end of the gantry and is located at each corner in the same direction of the solar cell module row that is located across the gantry, and holds one of the corner members that face each other. When,
A second holding member that holds the one corner member and the other corner member that partially faces the one corner member;
The first holding member is a movement restriction that restricts movement of the connecting portion connected to an end of the gantry and movement of the one corner member in a direction in which the gantry extends and a direction orthogonal to the direction in which the gantry extends. Are provided, and
The side facing the other corner member of the one corner member and the part of the side facing the one corner member of the other corner member respectively extending in the same direction as the extending direction of the gantry, A corner member holding mechanism, wherein the corner member holding mechanism protrudes outside the gantry, and the second holding member is installed at a position protruding outward. The corner member is
A flat panel, and a frame body that holds the outer periphery of the panel;
The frame body includes a side portion, a first flange portion protruding from one end of the side portion, and a second flange portion protruding from the other end of the side portion,
In the side of the one corner member facing the solar cell module, the frame body is formed with a notch in the second flange portion at the end on the other corner member side,
2. The corner member holding mechanism according to claim 1, wherein the movement restricting portion is located at the notch portion and has side surfaces respectively opposed to the second flange portion and the side portion.   The corner member holding mechanism according to claim 2, wherein the movement restricting portion is bent or curved along the side portion at a position facing the side portion.   The corner member holding mechanism according to any one of claims 1 to 3, wherein a plurality of the second holding members are installed in a direction in which the gantry extends.   The second holding member includes a side portion fixed to the one corner member, a protruding portion that protrudes from both ends of the side portion toward the other corner member, and holds the other corner member; The corner member holding mechanism according to any one of claims 1 to 4, further comprising a stop portion that restricts movement of the other corner member in a direction in which the frame extends.   The corner member holding mechanism according to claim 5, wherein the stopper is connected to one of the protrusions.

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