JP7159009B2 - MODULE INSTALLATION TOOL AND SOLAR MODULE INSTALLATION STRUCTURE USING THE SAME - Google Patents

Description

TECHNICAL FIELD The present invention relates to a module installation tool provided on a stand for installing a solar cell module on a wall surface, and a solar cell module installation structure using the same.

Conventionally, a solar cell module equipped with a solar cell panel was mainly installed on the roof surface of a building. Patent Literature 1 describes a solar cell mount in which a solar cell module is installed on the wall surface of a building so as to receive not only direct light but also reflected light reflected from surrounding buildings and the like.

Walls of buildings are prone to deformation (interlayer deformation) due to horizontal loads such as earthquakes, and solar cell modules are also required to have the ability to follow this interlayer deformation.

JP 2016-000949 A

A glass plate is often used for the surface of the solar cell panel in the solar cell module. Therefore, when interlayer deformation occurs in the solar cell module, there is a problem that the solar cell panel is damaged by coming into contact with a metal member that fixes the solar cell panel, such as a metal fixture or a frame member around the solar cell panel. was there.

The present invention solves such problems and realizes a module installation tool having a structure in which the solar cell module and the installation tool for fixing the solar cell module do not come into contact with each other even if interlayer deformation occurs in the frame for wall installation. aim.

In order to achieve the above object, one aspect of the present invention provides a module installation tool for solar cell modules that is attached to a frame that fixes the rear surfaces of a plurality of solar cell modules in parallel in one direction while keeping the back surfaces of the solar cell modules along the wall surface of the building. In the facing side portions of the solar cell module, one side is the one side portion and the other side is the other side portion. and a connecting portion forming a stepped space that connects the receiving portion and the fixing portion while accommodating and holding the other side portion of the other solar cell module. In the connection portion, the angle formed by the receiving portion side facing surface facing the light receiving surface of the other solar cell module and the fixing portion side facing surface facing the space is an obtuse angle or a right angle. A connecting portion cushioning material is arranged in the connecting portion.

Another aspect of the present invention is a solar cell module installation structure in which a plurality of solar cell modules are installed on the wall surface of an outer wall, wherein a plurality of solar cell modules extend vertically and are arranged at intervals in the horizontal direction. It includes a pedestal including vertical shaft members, a plurality of rail reinforcing plates that horizontally connect and support the vertical shaft members, and a plurality of solar cell modules installed on the pedestal. A module installation tool of the present invention is attached to each of the rail reinforcing plates.

ADVANTAGE OF THE INVENTION According to this invention, even if interlayer deformation|transformation arises in the stand for wall installation, contact with the module installation tool which fixes a solar cell module is prevented.

FIG. 1 is a front view for explaining the first step of the construction method for the solar cell module installation structure according to one embodiment. FIG. 2 is a cross-sectional view showing the mounting structure of the vertical shaft member to the outer wall in the solar cell module installation structure according to one embodiment. FIG. 3 is a front view illustrating the second step of the construction method for the solar cell module installation structure according to one embodiment. FIG. 4A is a vertical cross-sectional view of a module installation tool according to one embodiment. FIG. 4B is a vertical cross-sectional view showing a module installation tool according to one modification. FIG. 5 is a front view explaining the third step of the construction method for the solar cell module installation structure according to one embodiment. FIG. 6 is a cross-sectional view showing the installation structure of the upper portion of the first-tier solar cell module and the lower portion of the second-tier solar cell module in the solar cell module installation structure according to one embodiment. FIG. 7 is a schematic front view showing a state in which an inter-layer deformation has occurred in a mounting frame for installing a solar cell module on a wall according to one embodiment.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail based on the drawings. The following description of preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its applications or its uses.

Here, first, the term "solar cell module" in the present application means a solar cell panel including a plurality of electrically connected solar cells protected by a sealing material such as a resin. means a product accompanied by, etc.

In the following description, since the solar cell module 10 is attached to the outer wall W of a building such as a house, the direction toward the roof of the building is "up" or "upper", and the direction toward the ground is Sometimes referred to as "lower" or "lower side." When the outer wall W is viewed from the front, the front side is sometimes called the "front side", the opposite side to the front side is called the "rear side", and the direction connecting the front and rear sides is sometimes called the "front-rear direction". In addition, the direction connecting the upper and lower sides is "vertical direction" (same as vertical direction), the direction orthogonal to this vertical direction and front and back direction is "horizontal direction" (same as horizontal direction), one side of this horizontal direction may be referred to as the "right side" and the other side as the "left side".

When a plurality of solar cell modules 10 are stacked from the ground side (lower side) to the roof side (upper side) and arranged in a multi-tiered manner, when any two solar cell modules 10 are compared, the upper solar cell The module 10 may be referred to as the “upper” solar cell module 10 and the lower solar cell module 10 as the “lower” solar cell module 10 . Each solar cell module 10 has two module connection cables for electrically connecting the solar cell modules 10 . The module connection cable for connecting to the upper solar cell module 10 is called "upper module connection cable 12", and the module connection cable for connecting to the lower solar cell module 10 is called "lower module connection cable 13". sometimes referred to as

(one embodiment)
A solar cell module installation structure and construction method thereof according to an embodiment will be described with reference to FIGS. 1 to 6. FIG. In the solar cell module installation structure according to the present embodiment, a plurality of units in which the solar cell modules 10 are installed in multiple stages in the vertical direction are provided in a plurality of rows in the horizontal direction. The construction method of the units in the middle row and the bottom and second tiers will be described. The construction method for the units in the third and subsequent rows and in both end rows is basically the same as that for the units in the second row.

<First step>
In the construction method of the solar cell module installation structure according to the present embodiment, as a first step, as shown in FIG. are horizontally spaced apart.

Specifically, first, the wall surface pop-out tool 21 is arranged and fixed at predetermined intervals in the vertical direction at the mounting position of the vertical shaft member 20 on the outer wall W. As shown in FIG. The wall projection tool 21 is formed of, for example, a steel plate, and as shown in FIG. 2, is a T-shaped member having a front plate 211 and a rear plate 212 connected to the center of the back surface and extending rearward. is. The wall projecting tool 21 has a front plate 211 arranged in parallel with the outer wall W, and a rear plate 212 inserted into the joint portion of the outer wall W. be concluded. The wall projection tool 21 is fixed to the outer wall W in this way.

Next, the mounting rails 22 are mounted at regular intervals in the vertical direction on the wall surface protruding tool 21 fixed to the position where the vertical shaft member 20 is to be mounted on the outer wall W. As shown in FIG. This mounting of the mounting rail 22 is performed at two points on each side of its length. The mounting rail 22 is formed of, for example, a plated steel plate, and as shown in FIG. The left half of the front plate 211 of the wall projection tool 21 is a rail mounting portion for the mounting rail 22 of the left unit, and the right half is a rail mounting portion for the mounting rail 22 of the right unit. Department. The mounting rail 22 has a front portion 221 that contacts a corresponding rail mounting portion of the front plate 211, a side portion 222 that extends toward the outer wall W, and an inner corner portion between the front portion 221 and the side portion 222 that is attached to the front plate. 211 (the inner corners of the front part 221 and the side part 222 may be in contact with the sides of the front plate 211). Then, a screw B1 is screwed from the mounting rail 22 side into the screw holes 221a, 211a formed in the front portion 221 of the mounting rail 22 and the front plate 211. As shown in FIG. The mounting rail 22 is mounted on the wall projection 21 in this way.

Next, the mounting rails 22 adjacent in the vertical direction are connected with the bridging material 23 . The bridging member 23 is formed of, for example, a plated steel plate and is a flat member. The bridging material 23 is arranged so that its upper end contacts the lower end of the side surface 222 of the upper mounting rail 22 and its lower end contacts the upper end of the side surface 222 of the lower mounting rail 22 . . In each of them, a screw (not shown) is screwed into the screw hole formed in the side surface portion 222 of the bridging member 23 and the mounting rail 22 from the side of the bridging member 23 . The bridging material 23 is attached to the mounting rail 22 in this manner.

In this way, the mounting rails 22 attached to the outer wall W and the bridging members 23 are alternately connected by the wall protrusions 21, and thus the vertical shaft members 20 attached to the outer wall W are constructed. Therefore, the mounting rails 22 and the bridge members 23 are vertical shaft members constituting the vertical shaft member 20 . In this case, the vertical shaft component member includes two types of members having different shapes, namely, the mounting rail 22 and the bridge member 23 . In addition, the vertical shaft member constituting member may include three or more types of members with different shapes, or may include only a single type of member, or may be one single member. good too.

When the gantry fixture 21, the mounting rail 22 and the bridging material 23 are made of metal, the mounting rail 22 is attached to the outer wall W by the gantry fixture 21, and the mounting rails 22 are connected by the bridging material 23 and electrically connected. effectively conducted. Therefore, the vertical shaft member 20 constitutes a grounding body as a whole. Therefore, the vertical shaft member 20 can be electrically connected to ground wires extending from various devices at arbitrary positions of the mounting rails 22 and the bridge members 23 that constitute the vertical shaft member 20 .

<Second step>
In the construction method of the solar cell module installation structure according to the present embodiment, as the second step, as shown in FIG.

Specifically, first, the rail reinforcing plate 30 is attached between the lower end portions of a pair of laterally adjacent vertical shaft members 20 so as to connect them. Further, another rail reinforcing plate 30 is attached between the pair of vertical shaft members 20 so as to connect them in parallel with a space slightly shorter than the height of the solar cell module 10 in the vertical direction. The rail reinforcing plate 30 is a plate-like member made of, for example, a plated steel plate. The rail reinforcing plate 30 is arranged so that its left end contacts the left vertical shaft member 20 and its right end contacts the right vertical shaft member 20 . In each of them, a screw (not shown) is screwed into a screw hole formed in the rail reinforcing plate 30 and the vertical shaft member 20 from the rail reinforcing plate 30 side. The rail reinforcing plate 30 is attached to the vertical shaft member 20 in this manner.

The mounting rails 22 and the bridging members 23, which are the vertical shaft members 20 described above, and the rail reinforcing plates 30 constitute a stand for installing the solar cell module.

Next, the module installation tool 50 is attached so as to overlap the lower rail reinforcing plate 30 attached between the lower ends of the vertical shaft members 20 .

4A and 6 are cross-sectional views showing an example of the module installation tool 50 according to this embodiment. As shown in FIG. 4A, the module installation tool 50 includes a receiving portion 50a that supports the lower side portion of one solar cell module 10, a fixing portion 50b that is fixed to the rail reinforcing plate 30 of the pedestal 1, and a fixing portion 50a. A connecting portion 50c that connects the portion 50b and presses the upper side portion of the other solar cell module 10 against the pedestal 1 by the back surface of the fixed portion 50b that faces the pedestal 1 . Here, the other solar cell module 10 is a solar cell module installed above the one solar cell module 10 . A space formed by the stepped portion 50c3 (hereinafter referred to as a space (clearance) C) is provided above the portion of the connecting portion 50c against which the upper side portion of the other solar cell module 10 is pressed. Note that the upper side portion and the lower side portion of the solar cell module 10 are side portions of the solar cell module 10 that face each other in the vertical direction. When the upper side portion is called the one side portion, the lower side portion is called the other side portion. Further, when the lower side portion thereof is called the one side portion, the upper side portion is called the other side portion.

Further, the receiving portion 50a, the connecting portion 50c, and the fixing portion 50b of the module installation tool 50 may be integrally formed. In this case, the material of the module installation tool 50 is not particularly limited, but for example, a highly corrosion-resistant plated steel sheet may be used.

In the stepped portion 50c3 provided in the connecting portion 50c, the fixing portion-side connecting portion 50c2 connected to the fixing portion 50b of the connecting portion 50c is connected to the receiving portion-side connecting portion 50c1 connected to the receiving portion 50a of the connecting portion 50c. It is bent rearward at an acute angle. The fixing portion 50b is formed by bending the upper end side of the fixing portion-side connecting portion 50c2 forward. Further, the angle at which the fixing portion 50b is bent forward is the same as the acute angle at which the fixing portion connecting portion 50c2 is bent rearward with respect to the receiving portion connecting portion 50c1. As a result, the surface of the fixing portion 50b and the surface of the receiving portion-side connecting portion 50c1 become parallel. The distance between the parallel surfaces is designed to be slightly larger than the thickness of the solar cell module 10 . Such a design is for interposing a connecting portion cushioning material 60C, which will be described later, between the solar cell module 10 and the receiving portion side connecting portion 50c1.

Further, the fixing portion 50b is provided with a screw hole 50b1 for a fastening screw to be fixed to the rail reinforcing plate 30. As shown in FIG.

The receiving portion 50a has a cross section perpendicular to the installation surface (wall surface) of the solar cell module 10 and protrudes forward of the gantry 1, that is, protrudes away from the surface opposite to the receiving portion side facing surface 50c4. It is L-shaped (see Figure 6). This configuration facilitates integral molding of the module installation tool 50 .

In addition, in order that the receiving portion 50a holds the solar cell module 10 more securely and protect the lower side portion of the solar cell module 10, the vertical cross section is U-shaped opening upward. good too. That is, the receiving portion 50a forms a U-shape by protruding from one side of the two sides of the L-shaped portion so as to face the other side. In this case, as shown in FIG. 4A, the L-shaped receiving portion 50a may be provided with a front cover portion 52 forming a U-shape, for example. That is, the front cover portion 52 may be formed separately from the receiving portion 50a. The front cover portion 52 rises from the front end surface of the receiving portion 50a and wraps around the lower surface of the receiving portion 50a, so that the cross section in the vertical direction with respect to the wall surface is L-shaped and protrudes toward the pedestal 1 side. In this case, the material of the front cover portion 52 is not particularly limited, but for example, a stainless steel plate may be used.

Further, cushioning materials 60A and 60B may be arranged on the inner surface of the receiving portion 50a so as to protect the lower side portion of the solar cell module 10 from impact. The receiving portion cushioning materials 60A and 60B may be elastic gaskets made of, for example, rubber.

The receiving portion cushioning material 60A has an L-shaped cross section along the inner surface of the receiving portion 50a. (see Figure 6). On the other hand, the other side of the L-shape is a free end, and a gap 60a is provided between the bottom surface of the other piece and the bottom surface of the receiving portion 50a. Further, the bottom surface of the receiving portion 50a and the bottom surface of the front cover portion 52 are provided with through holes 50a1 and 52a, respectively. In this way, the lower portion of the receiving portion cushioning material 60A having an L-shaped cross section is not fixed. By this, the rainwater or the water at the time of sprinkling, which has entered the receiving portion 50a, is discharged. Therefore, rainwater or the like does not accumulate in the receiving portion 50a even if the receiving portion 50a has a U-shaped cross section opening upward. Therefore, deterioration of the performance of the solar cell module 10 due to moisture is suppressed.

The method of attaching the front cover portion 52 to the receiving portion 50 is not particularly limited. For example, the front cover portion 52 may be adhered to the receiving portion 50a via an adhesive. Also, similar to the through-hole 50a1 in the bottom surface of the receiving portion 50a and the through-hole 52a in the bottom surface of the front cover portion 52, the holes may be overlapped with each other, and the two holes may be screw holes and screwed. do not have.

The receiving portion cushioning material 60B is arranged on the inner surface of the front cover portion 52 so as to face the receiving portion side connecting portion 50c1.

In addition, in the connection region of the receiving portion-side connecting portion 50c1 with the fixing portion-side connecting portion 50c2, the upper side portion and the upper side portion of the other solar cell module 10 installed in the lower stage of the solar cell module 10 installed in the receiving portion 50a. A connecting portion cushioning material 60C that contacts the end face may be arranged. The depth dimension of the connecting portion cushioning material 60C may match or substantially match the dimension to the vertical line of the back surface of the fixing portion 50b.

As shown in FIGS. 4A and 6, the connecting portion cushioning material 60C may be a gasket having an L-shaped cross section in the direction perpendicular to the longitudinal direction of the connecting portion 50c. One side of the L-shaped connecting portion cushioning material 60C is fixed to the receiving portion side facing surface 50c4. On the other hand, the other L-shaped sides are free ends. In addition, one side of the L-shaped portion of the connecting portion cushioning material 60C contacts the light receiving surface side of the upper side portion of the first-stage solar cell module 10A. The other L-shaped side contacts the end surface of the upper side portion of the first solar cell module 10A.

In this way, the other side of the L-shaped connecting portion cushioning material 60C is a free end and contacts the end surface of the upper side portion of the solar cell module 10A. Therefore, even if the later-described interlayer deformation occurs in the gantry 1, the other sides of the connection cushioning material 60C follow the movement of, for example, the end face of the upper side of the solar cell module 10A in the first stage, especially the corners thereof. Therefore, the corners of the solar cell module 10A are effectively protected.

The above-described space C is formed between the upper side of the connecting portion cushioning material 60C and the lower side of the fixed portion side connecting portion 50c2. Here, the height of the space C in the vertical direction may be, for example, about 10 mm, although it depends on the assumed value of the angle of interlayer deformation to be described later. The material of each of the cushioning materials 60A, 60B and 60C is not particularly limited, but for example thermoplastic elastomer may be used.

Next, at each of the left end portion and the right end portion of the rail reinforcing plate 30, a screw is inserted from the module installation tool 50 side into the screw hole 50b1 provided in the fixing portion 50b of the module installation tool 50 and the screw formed in the rail reinforcing plate 30. tightened in the hole. The module installation tool 50 is attached to the rail reinforcing plate 30 in this way.

Next, as shown in FIG. 3, the first solar cell module 10 is installed so as to seal the opening of the oblong rectangular frame formed by the pair of vertical shaft members 20, the rail reinforcing plate 30, and the module installation tool 50. do. The solar cell module 10 has a horizontally long rectangular module main body 11, and an upper module connecting cable 12 and a lower module connecting cable 13 extending from the rear surface thereof. Each of the upper module connection cable 12 and the lower module connection cable 13 has cable main bodies 121 and 131 of electric wires and connectors 122 and 132 attached to the ends thereof. The connector 122 of the upper module connection cable 12 and the connector 132 of the lower module connection cable 13 are connectable. From the viewpoint of preventing connection errors, it is preferable that the same type of connectors of the upper module connection cable 12 and the lower module connection cable 13 are not connectable to each other. The connection cable 13 is preferably provided with visual identification means such as color coding.

In the solar cell module 10 of the first stage, the lower side of the module main body 11 is first fitted into the U-shaped groove 43 of the module installation tool 50, and then the both sides of the rear surface (that is, the rear surface) of the module main body 11 are fitted. It is provided so that the pair of vertical shaft members 20 and the upper side of the back surface are in contact with the rail reinforcing plate 30 on the upper side. As a result, the vertical shaft member 20, the rail reinforcing plate 30, and the frame of the module installation tool 50 are installed. At least one of between the module main body 11 and the U-shaped groove portion 43 and between the module main body 11 and the rail reinforcing plate 30 may be provided with a gasket made of rubber or the like.

<Third step>
In the construction method of the solar cell module installation structure according to the present embodiment, as the third step, as shown in FIGS. Install the battery module 10 . The direction in which the solar cell modules 10 in the first stage and the solar cell modules 10 in the second stage are sequentially installed is the direction in which each solar cell module 10 is installed, and is, for example, one direction.

Specifically, first, the module installation tool 50 is attached so as to overlap the upper rail reinforcing plate 30 attached in the second step. As shown in FIG. 6 , the module installation tool 50 is arranged such that the fixed portion 50b is superimposed on the rail reinforcing plate 30 and the connecting portion 50c covers the upper side portion of the solar cell module 10 of the first stage. In such an arrangement, the connecting portion cushioning material 60C is caught on the upper side of the solar cell module 10 in the lower stage, so that the module installation tool 50 is prevented from falling during construction, and the module installation tool 50 and the solar cell module 10 in the lower stage are prevented from falling. There is no need to use your hand to hold it down.

At the left end and right end of the rail reinforcing plate 30, respectively, screws B2 are screwed into the fixing portion 50b of the module installing tool 50 and the screw holes 50b1 and 30a formed in the rail reinforcing plate 30 from the module installation tool 50 side. be As a result, the lower side of the solar cell module 10 in the first stage is fitted into the receiving portion 50a of the lower module installation tool 50, and the upper side thereof is connected to the connecting part 50c of the upper module installation tool 50 and the rail reinforcing plate. 30, and is installed in a state in which displacement in the front-rear direction is restricted.

Next, from the upper rail reinforcing plate 30 attached in the second step, they are connected between the pair of vertical shaft members 20 in parallel with a space slightly shorter than the height of the solar cell module 10 in the vertical direction. The rail reinforcing plate 30 is attached so that it does. The method of attaching the rail reinforcing plate 30 to the vertical shaft member 20 is the same as in the second step.

Next, the second solar cell module 10 is installed so as to close the opening of the oblong rectangular frame formed by the pair of vertical shaft members 20, the rail reinforcing plate 30, and the module installation tool 50. As shown in FIG. As shown in FIGS. 5 and 6, the second-tier solar cell module 10 has a lower side portion of the module main body 11 fitted into the receiving portion 50a of the module installation tool 50, and both side side portions of the back surface of the module main body 11. are provided so as to contact the pair of vertical shaft members 20 and the upper side of the back surface to the rail reinforcing plate 30, respectively, so that the vertical shaft member 20, the rail reinforcing plate 30, and the frame of the module installation tool 50 are installed. be.

The mounting frame 1 can be extended both vertically and horizontally by adding mounting rails 22, and the number of solar cell modules 10 that can be mounted is appropriately changed according to the installation area of the wall surface of the building. .

As shown in FIG. 6, the receiving portion-side facing surface 50c4 on the rear side (mount side) of the receiving portion-side connecting portion 50c1 is connected to the upper side portion of the light receiving surface of the solar cell module 10A in the first stage via the connecting portion cushioning material 60C. to face each other. In addition, the fixing part side facing surface 50c5 on the rear side of the fixing part side connection part 50c2 faces the upper end surface of the solar cell module 10A of the first stage via the connecting part cushioning material 60C. Here, the angle θ between the receiving portion side facing surface 50c4 and the fixing portion side facing surface 50c5 is an obtuse angle. That is, in the connecting portion 50c, the angle θ between the receiving portion side facing surface 50c4 facing the light receiving surface of the first stage solar cell module 10A and the fixing portion side facing surface 50c5 facing the space portion C is an obtuse angle.

In this way, the module installation tool 50 inserts the second-tier solar cell module 10B into the receiving portion 50a at the lower end, and then fixes the upper side portion of the first-tier solar cell module 10A with the connecting portion 50c. At this time, a space portion C is formed behind the fixing portion side connecting portion 50c2 of the connecting portion 50c and above the first-stage solar cell module 10A via the connecting portion cushioning material 60C.

In addition, as shown in FIG. 4B, as a modified example of the module installation tool 50, the angle θ of the step portion 50c3 forming the space portion C may be a right angle. In this case, the connecting portion cushioning material 60C is provided below the stepped portion 50c3 at intervals so that a desired space portion C is formed in the lower portion of the stepped portion 50c3. However, the angle θ according to this modification need not be a strict right angle (90°), and may be a slightly acute angle within the range where the desired space C is formed, that is, a substantially right angle. you can

-effect-
FIG. 7 shows an example of a state in which interlayer deformation has occurred in the frame 1 due to an earthquake or the like. FIG. 7 shows a case where the mount 1 is tilted about 8° with respect to the vertical direction. In FIG. 7, the dimension A of the space between the rail reinforcing members 30 that are vertically adjacent to each other is reduced by about 1% compared to before the inclination occurs. Therefore, if the value of dimension A before deformation is, for example, 400 mm, the reduced value of dimension A after deformation is approximately 4 mm.

However, in the present embodiment, as shown in FIGS. 4A or 4B and FIG. 6, even if the inter-layer Even if deformation occurs, contact between the lower solar cell module 10A and the fixed-portion-side connection portion 50c2 of the module installation tool 50 is prevented. Therefore, damage due to interlayer deformation of the solar cell module 10 can be prevented.

In addition, since the front side of the wall surface of the stepped portion 50c3 of the module installation tool 50 is lowered by the space portion C provided behind the fixed portion side connection portion 50c2, rainwater or the like from the upper solar cell module 10B stays there. do not do.

Further, in the solar cell module installation structure according to the present embodiment, after the first module installation tool 50 is installed on the lower stage of the frame 1, the first solar cell is mounted on the receiving part 50a of the first module installation tool 50. The bottom part of the module 10 is fitted. Subsequently, a second module installation tool 50 is attached to the upper stage adjacent to the lower stage of the gantry 1 . When the second module installation tool 50 is attached to the upper stage of the pedestal 1 , the upper side of the first solar cell module 10 is pressed against the pedestal 1 by the back surface of the connecting part 50 c of the second module installation tool 50 . . By repeating this operation for the third and subsequent tiers, a multi-tiered solar cell module installation structure is obtained. In this manner, the upper side portion of the first solar cell module 10 is pressed and fixed by the back surface of the module installation tool 50 in the second stage, so that the solar cell modules 10 in multiple stages can be installed efficiently. can.

(Other embodiments)
In the above embodiment, the receiving portion 50a of the module installation tool 50 is provided over the entire longitudinal direction of the module installation tool 50 corresponding to the rail reinforcing plate 30 . However, the present invention is not limited to this, and the receiving portions 50a may be intermittently provided at a plurality of locations along the longitudinal direction. This eliminates the need to provide the through holes 50a1 and 52a in the receiving portion 50a.

Further, the front cover portion 52 may also be partially provided with a plurality of fragment members instead of being a continuous integral body. The configuration in which the front cover portion 52 is partially provided may be performed independently of the front cover portion 52 or may be performed together with the receiving portion 50a.

Furthermore, the front cover portion 52 is not limited to being made of metal because the load is smaller than that of the receiving portion 50a, and may be made of resin that can withstand the load and is excellent in weather resistance.

Also, the front cover portion 52 may be configured to be integrally formed with the receiving portion 50 a of the module installation tool 50 .

1 Frames 10, 10A, 10B Solar cell module 20 Vertical shaft member 21 Wall projecting tool 22 Mounting rail 23 Bridge material 30 Rail reinforcing plate 50 Module installation tool 50a Receiving part 50b Fixing part 50c Connecting part 50c1 Receiving part side connecting part 50c2 Fixing part Side connection portion 50c3 Stepped portion 50c4 Receiving portion side facing surface 50c5 Fixed portion side facing surface 52 Front cover portions 60A and 60B Receiving portion cushioning material (gasket)
60C Joint cushioning material (gasket)
C space part (space)

Claims (7)

A module installation tool for solar cell modules that is attached to a frame that fixes a plurality of solar cell modules in parallel in one direction while aligning the back surfaces of the solar cell modules along the wall surface of the building,
a receiving portion for supporting the one side portion of one of the solar cell modules, where one side portion is the one side portion and the other is the other side portion of the facing side portions of the solar cell module;
a fixing part fixed to the pedestal;
a connecting portion that connects the receiving portion and the fixing portion and forms a stepped space that accommodates and holds the other side portion of the other solar cell module;
an obtuse angle or a right angle formed by a receiving side facing surface facing the light receiving surface of the other solar cell module and a fixing side facing surface facing the space in the connecting portion;
A connecting portion cushioning material is arranged in the connecting portion ,
The connection part cushioning material is an L-shaped gasket,
The module installation tool , wherein one side of the L-shape is fixed to the receiving portion side facing surface, and the other side of the L-shape is a free end . The module installation tool according to claim 1 ,
one side of the L-shaped cushioning material for the connecting portion is in contact with the light-receiving surface side of the other side of the other solar cell module;
The other L-shaped side of the module installation tool is in contact with the end surface of the other side portion of the other solar cell module. The module installation tool according to claim 1 or 2 ,
The module installation tool includes a portion in which the receiving portion protrudes away from a surface on the opposite side of the receiving portion side facing surface to form an L shape. In the module installation tool according to any one of claims 1 to 3 ,
The receiving part is a module installation tool having a U-shape by protruding from one side of the two sides of the L-shaped portion so as to face the other side. The module installation tool according to claim 4 ,
The module installation tool, wherein at least a front portion of the U-shaped portion of the receiving portion is separate from the receiving portion. A module installation tool for solar cell modules that is attached to a frame that fixes a plurality of solar cell modules in parallel in one direction while aligning the back surfaces of the solar cell modules along the wall surface of the building,
a receiving portion for supporting the one side portion of one of the solar cell modules, where one side portion is the one side portion and the other is the other side portion of the facing side portions of the solar cell module;
a fixing part fixed to the pedestal;
a connecting portion that connects the receiving portion and the fixing portion and forms a stepped space that accommodates and holds the other side portion of the other solar cell module;
an obtuse angle or a right angle formed by a receiving side facing surface facing the light receiving surface of the other solar cell module and a fixing side facing surface facing the space in the connecting portion;
A connecting portion cushioning material is arranged in the connecting portion,
The receiving portion cushioning material arranged in the receiving portion is an L-shaped gasket,
The module installation tool, wherein one side of the L-shape is fixed to a surface opposite to the receiving portion side facing surface, and the other side of the L-shape is a free end. A solar cell module installation structure in which a plurality of solar cell modules are installed on the wall surface of the outer wall,
a pedestal including a plurality of vertical shaft members each extending in the vertical direction and arranged at intervals in the horizontal direction; and a plurality of rail reinforcing plates for connecting and supporting the vertical shaft members in the horizontal direction;
A plurality of solar cell modules installed on the pedestal,
A solar cell module installation structure in which the module installation tool according to any one of claims 1 to 6 is attached to each of the rail reinforcing plates.

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