JP7498024B2 - Fixture for photovoltaic conversion module - Google Patents

Description

The present invention relates to a fixture for a photoelectric conversion module.

Photoelectric conversion modules, such as solar cell modules, are known that are installed on the roofs of buildings such as houses. Such photoelectric conversion modules are fixed to the installation surface by suitable fasteners according to the type of roof on which they are installed.

Patent Document 1 discloses that a solar cell module is installed using a fixture attached to a protruding portion such as a roof rafter. This fixture has a pair of base parts that sandwich the protruding portion formed on the installation surface, and a support part that supports one end of a columnar member that holds a panel-like member. The pair of base parts are fastened to each other with a fastening member such as a bolt, thereby tightly sandwiching the protruding portion of the installation surface. In this way, the fixture is fixed onto the installation surface.

JP 2018-105109 A

When attaching the fixing device described in Patent Document 1 to a convex portion of the installation surface, the user must loosen the fastening member fastening the pair of base parts together, and while manually increasing the distance between the pair of base parts, position the fixing device so that the convex portion of the installation surface is located between the pair of base parts.

The installation of the fixtures is carried out on unstable surfaces such as roofs. Therefore, fixtures that can be installed more easily are desired.

The fixture for a photoelectric conversion module according to one embodiment has a pair of legs that can clamp a protrusion formed on the installation surface and can move between an open state and a closed state, an elastic member that biases the pair of legs toward the open state, and a fastening member that can fasten the pair of legs toward the closed state.

The above aspect makes it easier to install the fixture.

1 is a schematic perspective view showing a photoelectric conversion module structure according to a first embodiment. FIG. 2 is an enlarged perspective view of region 2R of FIG. 1. 1 is a perspective view of the fixture and its vicinity in a closed state with one photoelectric conversion module removed. FIG. 4 is a side view of the fixture and its vicinity in a closed state as viewed from a direction 4A in FIG. 3 . 11 is a side view of the fixture and its vicinity in an open state with one photoelectric conversion module removed. FIG. FIG. 2 is a side view of a fastener constituting the fixing device as viewed from the vertical direction. FIG. 11 is a side view of the fixing device and its vicinity in a closed state in the second embodiment. FIG. 11 is a side view of the fixing device and its vicinity in an open state in the second embodiment. FIG. 13 is a perspective view of a columnar member provided on a second leg of a fixture in a second embodiment. FIG. 2 is a side view of a photoelectric conversion module structure in a state where four modules are stacked. FIG. 2 is a top view of four photoelectric conversion module structures stacked together.

The following describes the embodiments with reference to the drawings. In the following drawings, identical or similar parts are given identical or similar reference symbols. However, it should be noted that the drawings are schematic and the ratios of dimensions may differ from the actual ones.

[First embodiment]
Fig. 1 is a schematic perspective view showing a photovoltaic conversion module structure in a first embodiment. Fig. 2 is an enlarged perspective view of a region 2R in Fig. 1. The photovoltaic conversion module structure includes a fixture 100 for mounting a photovoltaic conversion module 10 to an installation surface, and the photovoltaic conversion module 10 mounted on the fixture 100.

The photovoltaic conversion module 10 may be, for example, a solar cell module that converts light energy into electrical energy. The photovoltaic conversion module 10 may have a photovoltaic conversion panel 12 and a frame 14. The frame 14 is provided around the photovoltaic conversion panel 12.

In the following, the X direction in the figure may be referred to as the horizontal direction, and the Y direction in the figure may be referred to as the vertical direction. The Z direction in the figure corresponds to a direction roughly perpendicular to the installation surface 50 or the photoelectric conversion panel 12. In the following, the Z direction in the figure may be referred to as the height direction.

The photovoltaic conversion module 10 may be installed on an outdoor installation surface 50 such as the roof of a building. In this embodiment, the installation surface 50 has multiple protrusions 52 extending in the vertical direction, and the multiple protrusions 52 are arranged side by side at intervals in the horizontal direction. An example of such an installation surface 50 is a folded-plate roof with vertical beams. In this case, the protrusions 52 correspond to the vertical beams.

In FIG. 1, multiple photoelectric conversion modules 10 are arranged side by side in the horizontal direction. This is not limited to the example shown in FIG. 1, and the photoelectric conversion modules 10 may be arranged side by side in the vertical direction. Also, only one photoelectric conversion module 10 may be installed on the installation surface 50.

Each of the fixing devices 100 supports an end of the photoelectric conversion module 10, specifically the frame 14. Some of the fixing devices 100 may be located between adjacent photoelectric conversion modules 10 and support both photoelectric conversion modules 10. Each of the photoelectric conversion modules 10 may be fixed to the installation surface 50 by a plurality of fixing devices 100 provided on one side and a plurality of fixing devices 100 provided on a side opposite the one side.

Next, details of each fixture 100 and the support structure of the photoelectric conversion module 10 by the fixture will be described. Figure 3 is a perspective view of the fixture and its vicinity in a closed state in which one photoelectric conversion module has been removed from the state shown in Figure 2. Figure 4 is a side view of the fixture and its vicinity in a closed state as viewed from direction 4A in Figure 3. Figure 5 is a side view of the fixture and its vicinity in an open state in which one photoelectric conversion module has been removed.

The fixing device 100 has a pair of legs 110, 120, an elastic member 200, and a fastening member 250. The pair of legs 110, 120 are configured to be able to clamp a protrusion 52 formed on the installation surface 50.

The first leg 110 of the pair of legs may have a first bottom 112 that abuts against the installation surface 50 and a first side 114 that extends in the height direction from the first bottom 112 (see Figures 3 to 5). The first bottom 112 may extend from the lower end of the first side 114 toward the convex portion 52 of the installation surface.

The second leg 120 of the pair of legs may have a second bottom 122 that abuts against the installation surface 50 and a second side 124 that extends in the height direction from the second bottom 122 (see Figures 3 to 5). The second bottom 122 may extend from the lower end of the second side 124 toward the convex portion 52 of the installation surface.

The first bottom 112 of the first leg 110 and the second bottom 122 of the second leg 120 face each other via the convex portion 52 of the installation surface 50. Specifically, the first bottom 112 of the first leg 110 and the second bottom 122 of the second leg 120 sandwich the convex portion 52 of the installation surface 50 when the fixture 100 is in the closed state (see FIG. 4).

The pair of legs 110, 120 are configured to be able to transition between an open state and a closed state. The open state means that the distance between the first leg 110 and the second leg 120 is relatively wide, and the convex portion 52 of the installation surface 50 can be inserted or removed between the first leg 110 and the second leg 120. In this embodiment, Figure 5 shows the open state.

The closed state means that the distance between the first leg 110 and the second leg 120 is relatively narrow, and the convex portion 52 of the installation surface 50 cannot be inserted or removed between the first leg 110 and the second leg 120. Therefore, if the first leg 110 and the second leg 120 are sandwiching the convex portion 52 in the closed state, the fixing device 100 is fixed to the installation surface 50 and cannot be removed. In this embodiment, Figures 3 and 4 show the closed state.

The elastic member 200 is configured to bias the pair of legs 110, 120 toward the open state. In this embodiment, the elastic member 200 biases the second bottom 122 of the second leg 120 in a direction away from the first bottom 112 of the first leg 110. The elastic member 200 may be a member having spring elasticity, such as a helical spring.

The fastening member 250 is configured to be capable of fastening the pair of legs 110, 120 toward the closed state. The first leg 110 has a first through hole 115 through which the fastening member 250 passes. The second leg 120 has a second through hole 125 through which the fastening member 250 passes in a wall portion facing the wall portion in which the first through hole 115 of the first leg 110 is formed.

When the fastening member 250 is tightly fastened, the second bottom 122 of the second leg 120 moves toward the first bottom 112 of the first leg 110, and the pair of legs 110, 120 is in a closed state. When the fastening member 250 is loosened, the biasing force of the elastic member 200 causes the second bottom 122 of the second leg 120 to move away from the first bottom 112 of the first leg 110, and the pair of legs 110, 120 is in an open state.

In this embodiment, the pair of legs 110, 120 maintain an open state with the fastening member 250 loosened. Therefore, the user does not need to spread the pair of legs 110, 120 with his or her own hands when inserting the protrusion 52 between the pair of legs 110, 120. This makes it easier to install the fixture 100 on the protrusion 52 of the installation surface 50.

Next, an example of a more specific structure for opening and closing the pair of legs 110, 120 will be described. In this embodiment, the second leg 120 may have a protrusion 126 extending toward the first leg 110 and a wall 128 extending upward from the protrusion 126. The wall 128 faces the first side 114 of the first leg 110.

The first through hole 115 is provided in the first side 114 of the first leg 110, and the second through hole 125 is provided in the wall 128 of the second leg 120. The fastener 250 may include, for example, a bolt 252 and a nut 254. In the illustrated embodiment, the head of the bolt 252 is located on the side of the first leg 110 opposite the second leg 120, and the nut 254 is located on the side of the wall 128 of the second leg 120 opposite the first leg 110. Alternatively, the positions of the head of the bolt 252 and the nut 254 may be reversed from the illustrated embodiment.

The fixture 100 may also have a hinge portion 130 that allows the second leg portion 120 to rotate around a rotation axis 132 positioned relative to the first leg portion 110 (FIGS. 4 and 5). Specifically, the hinge portion 130 may have a first plate portion 134, a second plate portion 136, and a rotation axis 132 that rotatably connects the first plate portion 134 and the second plate portion 136. The rotation axis 132 may extend along the vertical direction.

The first plate portion 134 is fixed to the upper portion 116 of the first leg portion 110, which extends from the upper end of the first side portion 114 in a direction approximately parallel to the photoelectric conversion panel 12. On the other hand, the second plate portion 136 is fixed to the second leg portion 120. In the illustrated example, the second plate portion 136 is fixed to the connecting portion 127 of the second leg portion 120. The connecting portion 127 is fixed to the protruding portion 126 of the second leg portion 120, and extends from the protruding portion 126 toward the upper portion 116 of the first leg portion 110. The second plate portion 136 of the hinge portion 130 is fixed to the portion of the connecting portion 127 that extends from the protruding portion 126 toward the upper portion 116 of the first leg portion 110.

With the above structure, the rotation axis 132 of the hinge portion 130 is positioned relative to the first leg portion 110. The second plate portion 136 rotates relative to the first plate portion 134 around the rotation axis 132 of the hinge portion 130, causing the second leg portion 120 to move closer to or farther away from the first leg portion 110.

The elastic member 200 biases the hinge portion 130 to rotate in one direction. In this embodiment, the elastic member 200 may be provided on the opposite side of the second leg 120 to the first leg 110 in the rotation direction around the rotation axis 132 of the hinge portion 130. In the illustrated embodiment, the elastic member 200 is stretched between a portion of the upper portion 116 of the first leg 110 that extends above the second leg 120 and the second side portion 124 of the second leg 120. Furthermore, in the closed state, the elastic member 200 is in a state in which it is stretched more than its natural length. As a result, the second leg 120 is biased toward the opposite side to the first leg 110 by the contraction force of the elastic member 200.

In this embodiment, the elastic member 200 biases the hinge portion 130 in a direction in which the second bottom portion 122 of the second leg portion 120 moves away from the first bottom portion 112 of the first leg portion 110. On the other hand, by tightening the fastening member 250, the second bottom portion 122 of the second leg portion 120 moves in a direction toward the first bottom portion 112 of the first leg portion 110 against the biasing force of the elastic member 200.

In this way, the user can transition the pair of legs 110, 120 between the open and closed states simply by tightening and loosening the fastening member 250.

At least one of the first through hole 115 and the second through hole 125 is preferably larger than the diameter of the fastening member 250 in a direction perpendicular to the rotation axis 132 of the hinge portion 130. In the illustrated embodiment, the length of the second through hole 125 in the height direction is longer than the diameter of the core of the bolt 252 of the fastening member 250. This makes it easier for the wall portion 128 of the second leg portion 120 to move downward in the open state. Therefore, in the open state, the second bottom portion 122 of the second leg portion 120 is easier to move due to elastic force in a direction away from the first bottom portion 112 of the first leg portion 110.

In this embodiment, the upper portion of the first leg 110 extends in a direction generally parallel to the photovoltaic conversion panel 12 and may form a pair of loading sections 310 on which the photovoltaic conversion modules 10 can be loaded. The frames 14 of the photovoltaic conversion modules 10 adjacent to each other in the horizontal direction are placed on the pair of loading sections 310 aligned in the horizontal direction.

The fixing device 100 may have a fastener 400 that presses the end of the photoelectric conversion module 10 loaded on the loading section 310, specifically the frame 14, toward the loading section 310. The fastener 400 may have a bottom 410 that abuts against the upper part of the first leg 110, a pair of erected portions 420 that stand upright in the height direction from the bottom 410, and flange portions 430, 432 that protrude laterally from the erected portions 420.

The flange portions 430, 432 face the loading portion 310. The end of the photoelectric conversion module 10, specifically the frame 14, is sandwiched between the loading portion 310 and the flange portions 430, 432. Thus, in this embodiment, the pair of loading portions 310 and the fasteners 400 form a pair of mounting portions to which the photoelectric conversion module 10 is attached.

The fastener 400 may be fastened to the top of the first leg 110 by, for example, a fastening member 440. The bottom 410 of the fastener 400 may have a through hole (not shown) through which the fastening member 440 passes. This through hole may be longer than the diameter of the fastening member 440 in the lateral direction. In this case, the position of the fastener 400 in the lateral direction can be finely adjusted.

Figure 6 is a side view of the fastener 400 constituting the fixing device 100, viewed from the vertical direction. As described above, the fastener 400 has a pair of flange portions 430, 432. The first flange portion 430 of the pair of flange portions may be located above the second bottom portion 122 of the second leg portion 120. The second flange portion 432 of the pair of flange portions may be located above the first bottom portion 112 of the first leg portion 110.

It is preferable that the height H1 from the underside of the bottom 410 of the fastener 400 to the underside of the first flange portion 430 is smaller than the height of the frame 14 of the photoelectric conversion module 10. Here, the height of the frame 14 corresponds to the height from the lower end to the upper end of the frame 14 in a state in which the frame 14 is not pressed by the fastener 400 (the same applies below). As a result, when the fastener 400 is fastened to the upper part of the first leg portion 110, the frame 14 of the photoelectric conversion module 10 is tightly sandwiched between the first flange portion 430 and the loading portion 310. For example, the height H1 from the underside of the bottom 410 of the fastener 400 to the underside of the first flange portion 430 may be smaller than the height of the frame 14 by, for example, about 0.5 mm to 5 mm.

On the other hand, it is preferable that the height H2 from the underside of the bottom 410 of the fastener 400 to the underside of the second flange portion 432 is greater than the height of the frame 14 of the photovoltaic conversion module 10. This allows the frame 14 of the photovoltaic conversion module 10 to be inserted between the second flange portion 432 and the loading portion 310 after the fastener 400 is fastened to the upper portion of the first leg portion 110. For example, the height H2 from the underside of the bottom 410 of the fastener 400 to the underside of the second flange portion 432 may be greater than the height of the frame 14 by, for example, about 0.5 mm to 5 mm.

In the case of the fastener 400 described above, the photoelectric conversion module 10 is attached between the first flange portion 430 and the loading portion 310, and the fixing device 100 can be attached to the convex portion 52 of the installation surface 50 in a state where the photoelectric conversion module 10 is not attached between the second flange portion 432 and the loading portion 310. Then, after attaching the fixing device 100 to the convex portion 52 of the installation surface 50, an end portion of another photoelectric conversion module 10 can be inserted between the second flange portion 432 and the loading portion 310 as necessary. By repeating this operation, multiple photoelectric conversion modules 10 can be installed side by side in the horizontal direction.

The fastening member 250 described above is preferably configured to be operable from one side of the pair of mounting portions, i.e., the loading portion 430. In this embodiment, the head of the bolt 252 of the fastening member 250 is located on the outside of the first leg 110. Therefore, even when the photovoltaic conversion module 10 is attached between the first flange portion 430 and the loading portion 310, the user can easily operate the fastening member 250.

[Second embodiment]
Next, a photovoltaic conversion module structure and a fixture according to a second embodiment will be described. Fig. 7 is a side view of the fixture and its vicinity in a closed state in the second embodiment. Fig. 8 is a side view of the fixture and its vicinity in an open state in the second embodiment. Fig. 9 is a perspective view of a columnar member provided on a second leg of the fixture in the second embodiment.

Please note that in the second embodiment, components that are the same as or similar to those in the first embodiment are given the same reference numerals. Also, please note that descriptions of components that are the same as or similar to those in the first embodiment may be omitted.

In the second embodiment, the configuration of the first leg 110 and the second leg 120 is generally similar to that in the first embodiment. In the second embodiment, the shape of the first side portion 114 of the first leg 110 is different from that in the first embodiment.

Specifically, when viewed vertically, the first side portion 114 has a first portion 114a standing upright from the first bottom portion 112, a second portion 114b extending from the first portion 114a toward the second leg portion 120, and a third portion 114c standing upright from the end of the second portion 114b facing the second leg portion 120. The first through hole 115 is formed in the third portion 114c of the first side portion 114.

Also, similar to the first embodiment, the second leg 120 is connected to the upper portion 116 of the first leg 110 via a hinge portion 130 having a rotation axis 132 positioned relative to the first leg 110. The specific structure of the hinge portion 130 may be the same as or different from that of the first embodiment.

In this embodiment, the fixing device 100 may have a columnar member 280 attached to the second leg 120. The columnar member 280 may have a generally columnar shape and may have a third through hole 282 through which the fastening member 250 passes. When the fastening member 250 is a bolt 252, the columnar member 280 corresponds to a nut that is coupled to the bolt 252.

In this embodiment, the elastic member 200 is provided between the first leg 110 and the second leg 120 in the rotation direction around the rotation axis 132 of the hinge part 130. More specifically, the elastic member 200 may be located between the first side part 114 of the first leg 110 and a columnar member 280 attached to the second leg 120.

Preferably, the elastic member 200 is provided around the core of the fastening member 250. For example, if the elastic member 200 is a helical spring, the elastic member 200 can be easily installed around the core of the fastening member 250.

The elastic member 200 is compressed beyond its natural length in the closed state. As a result, the second leg 120 is biased toward the opposite side to the first leg 110 by the extension force of the elastic member 200.

In this embodiment, the elastic member 200 biases the hinge portion 130 in a direction in which the second bottom portion 122 of the second leg portion 120 moves away from the first bottom portion 112 of the first leg portion 110. Meanwhile, by tightening the fastening member 250, the second bottom portion 122 of the second leg portion 120 moves in a direction toward the first bottom portion 112 of the first leg portion 110 against the biasing force of the elastic member 200. In this way, the pair of legs 110, 120 are configured to be able to transition between an open state and a closed state by the fastening member 250, similar to the first embodiment.

The columnar member 280 having the third through hole 282 is preferably configured to be rotatable with respect to the second leg 120 around an axis along the rotation axis 132 of the hinge section 130. In the illustrated embodiment, the columnar member 280 has an approximately cylindrical outer shape. The second leg 120 may have a C-shaped wall 129 that forms an approximately cylindrical cavity that receives the columnar member 280 having an approximately cylindrical shape. As a result, the columnar member 280 is attached within the C-shaped wall 129 and is configured to be rotatable with respect to the second leg 120 around an axis along the rotation axis 132.

The third through hole 282 of the columnar member 280 penetrates the columnar member 280 in a direction perpendicular to the axis along the rotation axis 132 of the hinge portion 130. In addition, a second through hole 125 is formed in the C-shaped wall portion 129. As a result, the fastening member 250 penetrates the first through hole 115 of the first leg portion 110, the second through hole 125 of the second leg portion 120, and the third through hole 282 of the columnar member 280.

Here, as described above, it is preferable that the columnar member 280 having the third through hole 282 is configured to be rotatable with respect to the second leg 120 around an axis along the rotation axis 132 of the hinge section 130. As a result, even if the second leg 120 rotates around the rotation axis 132 of the hinge section 130, the third through hole 282 through which the fastening member 250 passes is maintained in the lateral direction due to the rotation of the columnar member 280 with respect to the second leg 120. Therefore, it is possible to easily rotate the second leg 120 smoothly around the rotation axis 132.

In addition, to facilitate smooth rotation of the second leg 120 around the rotation axis 132, it is preferable that the second through hole 125 is larger in diameter than the fastening member 250 in a direction perpendicular to the rotation axis 132 of the hinge portion 130, as in the first embodiment.

In the second embodiment, the fixture 100 has a pair of mounting portions 300 to which adjacent photovoltaic conversion modules 10 can be attached. The first mounting portion 320 of the pair of mounting portions 300 is configured to be attached to the frame 14 of the photovoltaic conversion module 10 by a fastening member 322 such as a screw.

In one specific example, the frame 14 of the photoelectric conversion module 10 has a generally S-shaped configuration when viewed vertically, and the end of the photoelectric conversion panel 12 is received in a panel receiving portion 14a at the top of the frame 14. In addition, the bottom of the frame 14 forms a generally C-shaped receiving portion 14b that can receive a portion of the fixture 100 from the side opposite the photoelectric conversion panel 12.

A portion of the fixture 100, specifically, one end 116e of the upper portion 116 of the first leg 110, is received in the receiving portion 14b of the frame 14. The one end 116e of the upper portion 116 of the first leg 110 is attached to the frame 14 by a fastening member 322 at the receiving portion 14b.

The second mounting portion 330 of the pair of mounting portions 300 may be configured as an inseparable unit with the first leg portion 110 as part of the first leg portion 110. Specifically, a pair of protrusions 332, 334 protrude laterally from the second portion 114b of the first side portion 114 of the first leg portion 110.

The pair of protrusions 332, 334 form a receiving portion that receives the frame 14 of the photoelectric conversion module 10. Specifically, the first protrusion 332 of the pair of protrusions supports the frame 14 of the photoelectric conversion module 10 from below. The second protrusion 334 of the pair of protrusions covers the upper part of the frame 14 of the photoelectric conversion module 10 placed on the first protrusion 332. The frame 14 of the photoelectric conversion module 10 may be configured to be able to be fitted into the receiving portion formed by the pair of protrusions 332, 334.

The fastener 100 in the second embodiment does not require the fastener 400 described in the first embodiment.

Next, an example of a method for storing the photoelectric conversion module structure in the second embodiment before installation will be described. From the viewpoint of storage space, it is preferable that the photoelectric conversion module structures are stacked on top of each other during storage. FIG. 10 is a side view of four photoelectric conversion module structures stacked on top of each other. FIG. 11 is a top view of four photoelectric conversion module structures stacked on top of each other.

Each photovoltaic conversion module structure may have one photovoltaic conversion module 10 and the aforementioned fixing device 100 attached to only one side of the photovoltaic conversion module 10. Specifically, in each photovoltaic conversion module structure in storage, the fixing device 100 is attached to the frame 14 of the photovoltaic conversion module 10 at the aforementioned first mounting portion 320 by a fastening member 322, such as a screw.

The fixture 100 is preferably configured to be positioned outside the photoelectric conversion module 10, except for the first attachment portion 320 with the frame 14, when viewed from a direction perpendicular to the photoelectric conversion panel 12. This makes it possible to prevent the fixture 100 from interfering with another photoelectric conversion module 10 when multiple photoelectric conversion module structures are stacked.

Figures 10 and 11 show four photoelectric conversion module structures stacked on top of each other. Here, for convenience, in Figures 10 and 11, the fastener for the topmost photoelectric conversion module structure is given the reference symbol "100a". Similarly, the fastener for the second photoelectric conversion module structure from the top is given the reference symbol "100b". Furthermore, the fastener for the third photoelectric conversion module structure is given the reference symbol "100c". Furthermore, the fastener for the fourth photoelectric conversion module structure is given the reference symbol "100d". Below, the reference symbols 100a to 100d may be used to identify the fasteners for the photoelectric conversion module structures of each stage.

In the example shown in Figures 10 and 11, the top photoelectric conversion module structure has two fixtures 100a attached to the frame 14 on the left side of the page. The second photoelectric conversion module structure from the top has two fixtures 100b attached to the frame 14 on the right side of the page. Here, the fixtures 100a provided on the top photoelectric conversion module structure do not abut the second photoelectric conversion module 10 as described above. Therefore, the top photoelectric conversion module structure is placed on the frame 14 of the photoelectric conversion module 10 of the second photoelectric conversion module structure.

Similarly, the third-stage photoelectric conversion module structure has two fixtures 100c attached to the frame 14 on the left side of the page. However, the fixtures 100c of the third-stage photoelectric conversion module structure are positioned offset from the fixtures 100a of the top-stage photoelectric conversion module structure when viewed from a direction perpendicular to the photoelectric conversion panel 12. This prevents the fixtures 100c of the third-stage photoelectric conversion module structure from interfering with the fixtures 100a of the top-stage photoelectric conversion module structure.

The fourth-stage photoelectric conversion module structure has two fixtures 100d attached to the frame 14 on the right side of the page. However, the fixtures 100d of the fourth-stage photoelectric conversion module structure are positioned offset from the fixtures 100b of the second-stage photoelectric conversion module structure when viewed from a direction perpendicular to the photoelectric conversion panel 12. This prevents the fixtures 100d of the fourth-stage photoelectric conversion module structure from interfering with the fixtures 100b of the second-stage photoelectric conversion module structure.

As described above, by changing the position of the fasteners 100 attached to each photoelectric conversion module 10, multiple photoelectric conversion module structures can be stacked without the fasteners 100 of the different photoelectric conversion modules 10 interfering with each other. This allows the photoelectric conversion module structures to be densely stacked in the height direction.

In the example shown in Figures 10 and 11, when a further photoelectric conversion module structure is stacked on top of the top photoelectric conversion module structure, the fixture 100 provided on the further photoelectric conversion module structure may be disposed at the same position as the fixture 100d of the fourth photoelectric conversion module structure when viewed from a direction perpendicular to the photoelectric conversion panel 12. If the height of the fixture 100 is within four times the height of the frame 14, the fixture 100 of the further photoelectric conversion module structure does not interfere with the fixture 100d of the fourth photoelectric conversion module structure. In this way, the position of the fixture 100 of the photoelectric conversion module structure may overlap with the position of the fixture 100 of the photoelectric conversion module structure of another stage, depending on the size of the fixture 100 in the height direction.

When mounting the above-mentioned photoelectric conversion module structure on an installation surface, first, the fixing device 100 that has been previously attached to the photoelectric conversion module 10 at the first mounting portion 320 is attached to the convex portion 52 of the installation surface 50. Then, the frame 14 of the photoelectric conversion module 10 of another photoelectric conversion module structure is fitted into the second mounting portion 330 of the fixing device 100. Then, the fixing device 100 that has been previously attached to the photoelectric conversion module 10 of the other photoelectric conversion module structure is attached to the convex portion 52 of the installation surface 50. By repeating this operation, multiple photoelectric conversion modules 10 can be installed side by side in the horizontal direction.

As described above, the contents of the present invention have been disclosed through the embodiments, but the descriptions and drawings forming part of this disclosure should not be understood as limiting the present invention. From this disclosure, various alternative embodiments, examples and operating techniques will become apparent to those skilled in the art. Therefore, the technical scope of the present invention is determined only by the invention-specific matters relating to the scope of the claims that are appropriate from the above explanation.

For example, each structure or feature described in the above-mentioned embodiments can be applied to other embodiments or can be replaced with each structure or feature described in other embodiments, to the extent possible.

In the above embodiment, the pair of legs 110, 120 are configured to be able to transition between an open state and a closed state by rotating the second leg 120 around the rotation axis 132 of the hinge section 130. Alternatively, if possible, the pair of legs 110, 120 may be configured to be able to transition between an open state and a closed state by rotating the first leg 110 around the rotation axis. Furthermore, the pair of legs 110, 120 may be configured to be able to transition between an open state and a closed state by sliding the first leg 110 or the second leg 120 instead of rotating. Such a sliding movement can be realized, for example, by installing a rail at the upper end of the second leg 120 shown in FIG. 4 that allows the second leg 120 to slide laterally against the lower surface of the upper part of the first leg 110.

In addition, in the second embodiment, a method for stacking and storing photoelectric conversion module structures without interfering with the fixture 100 has been described. It should be noted that this method can also be applied to the photoelectric conversion module structure equipped with the fixture in the first embodiment.

In the first embodiment, the position of the elastic member 200 can also be changed around the fastening member 250. In this case, the elastic member 200 may be compressed beyond its natural length in the closed state.

REFERENCE SIGNS LIST 10 photoelectric conversion module 50 installation surface 52 protrusion 100 fixing device 110 first leg 115 first through hole 120 second leg 125 second through hole 130 hinge 132 rotating shaft 200 elastic member 250 fastening member 280 columnar member 282 third through hole 400 fastener

Claims (5)

A pair of legs capable of clamping a protrusion formed on an installation surface and capable of moving between an open state and a closed state;
an elastic member that biases the pair of legs toward the open state;
A fastening member capable of fastening the pair of legs toward the closed state;
a hinge portion that allows a second leg of the pair of legs to rotate about a rotation axis that is positioned with respect to a first leg of the pair of legs;
a columnar member attached to the second leg portion and configured to be rotatable with respect to the second leg portion around an axis along the rotation axis of the hinge portion;
The elastic member biases the hinge portion to rotate in one direction,
The columnar member has a third through hole through which the fastening member passes,
The third through hole penetrates the columnar member in a direction perpendicular to the axis, A pair of legs capable of clamping a protrusion formed on an installation surface and capable of moving between an open state and a closed state;
an elastic member that biases the pair of legs toward the open state;
A fastening member capable of fastening the pair of legs toward the closed state;
a hinge portion that allows a second leg of the pair of legs to rotate about a rotation axis that is positioned with respect to a first leg of the pair of legs,
The elastic member biases the hinge portion to rotate in one direction,
the elastic member is provided on an opposite side of the second leg to the first leg in a rotation direction about the rotation axis of the hinge portion,
The second leg is biased toward an opposite side to the first leg by a contraction force of the elastic member. The fastening member passes through a first through hole provided in the first leg portion and a second through hole provided in the second leg portion,
The fixture according to claim 1 , wherein at least one of the first through hole and the second through hole has a diameter larger than a diameter of the fastening member in a direction perpendicular to the rotation axis of the hinge portion. the elastic member is provided between the first leg and the second leg in a rotation direction around the rotation axis of the hinge portion,
The fastener according to claim 1 , wherein the second leg is biased in a direction opposite to the first leg by the extension force of the elastic member. The fastener according to claim 4, wherein the elastic member is provided around the core of the fastening member.

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