JP2021090244A - Solar panel frame - Google Patents

Abstract

To provide a solar panel frame that has a simple structure but does not fall off even when a supporting solar panel is impacted.SOLUTION: A solar panel frame 100 that holds a solar panel 200 includes a first frame 110 having a first contact portion 111 that comes into contact with one side of a solar panel 200, a second frame 120 having a second contact portion 121 that comes into contact with the other side opposite to one side of the solar panel 200, and a third frame 130 that connects the first frame 110 and the second frame 120 across the end of the solar panel 200, and the solar panel 200 is sandwiched between the first contact portion 111 and the second contact portion 121, and the rigidity of the third frame 130 is lower than the rigidity of each of the first frame 110 and the second frame 120.SELECTED DRAWING: Figure 2

Description

The present invention relates to a frame for a solar panel.

Various frame structures for supporting solar panels have been proposed (see, for example, Patent Documents 1 and 2).

Japanese Unexamined Patent Publication No. 2013-174091 Japanese Unexamined Patent Publication No. 2014-777290

The frame structure disclosed in the above patent document is heavy and costly due to the large number of members. In addition, the durability of the adhesive used and the workability in the field may be a problem.

The present invention has been made to solve such a problem, and provides a frame for a solar panel having a simple structure so that the supporting solar panel does not fall off even when it receives an impact. Is.

The frame for a solar panel in a specific embodiment of the present invention is a frame for a solar panel that sandwiches the solar panel, and has a first frame having a first contact portion that comes into contact with one side of the solar panel. A second frame body having a second contact portion that contacts on the other side opposite to one side of the solar panel, and a first frame body and a second frame body that are connected across the end portion of the solar panel. The solar panel is sandwiched between the first contact portion and the second contact portion, and the rigidity of the third frame body is lower than the rigidity of each of the first frame body and the second frame body.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a frame for a solar panel which has a simple structure but does not fall off even when the supporting solar panel receives an impact.

It is an external perspective view for demonstrating the use state of the frame for a solar panel which concerns on this embodiment. It is a partial cross-sectional view in a state where a frame supports a solar panel. It is a partial cross-sectional view in the state after the solar panel is impacted.

Hereinafter, the present invention will be described through embodiments of the invention, but the invention according to the claims is not limited to the following embodiments. Moreover, not all of the configurations described in the embodiments are indispensable as means for solving the problem.

FIG. 1 is an external perspective view for explaining a usage state of a solar panel frame (hereinafter referred to as “frame 100”) according to the present embodiment. As shown, the frame 100 supports the solar panel 200 and is supported by the structure 300 which is a part of the gantry. For example, the four corners of the frame 100 are fixed to the structure 300 by screws 310. The gantry is installed at a position where the solar panel 200 supported via the frame 100 can receive sunlight. The solar panel 200 receives sunlight, generates electric power, and transmits the generated electric power to an external device. The structure 300 in the drawing shows a part that supports the frame 100.

FIG. 2 is a partial cross-sectional view in a state where the frame 100 supports the solar panel 200. Specifically, it is a figure which shows the upper part of the cross section of the solar panel 200 in the installed state, which cut in the vertical direction near the center with respect to the longitudinal direction. The frame 100 is a cross section of an upper portion that functions to hold the solar panel 200 against gravity.

The frame 100 includes a first frame body 110, a second frame body 120, and a third frame body 130 as main structures. The first frame 110 is arranged on the first surface side of the solar panel 200, and has a contact rail 111 that comes into contact with the solar panel 200 on the first surface side. The contact rail 111 has a plane extending along the longitudinal direction of the solar panel 200 and in contact with the first surface. The contact rail 111 has an L-shaped cross section as shown in the figure, and is erected from the first frame body 110 toward the first surface. The contact rail 111 may be formed integrally with the first frame body 110 or may be formed as a separate body. Further, the contact rail 111 may have a non-slip surface on the contact surface with the first surface. As the non-slip, for example, a rubber sheet that can be attached can be considered.

The first frame body 110 is made of, for example, an aluminum material, and has a tubular shape with a rectangular cross section. Such a hollow shape contributes to weight reduction of the first frame body 110. Further, when the solar panel 200 receives an impact force from the outside, the hollow shape is deformed, so that the impact force can be absorbed.

The second frame body 120 has a contact elastomer 121 that is arranged on the second surface side of the solar panel 200 and comes into contact with the solar panel 200 on the second surface side. The second surface is the opposite surface to the first surface, as shown in the figure. The contact elastomer 121 has a plane that extends along the longitudinal direction of the solar panel 200 and contacts the first surface. The elastomer 121 has, for example, a trapezoidal cross section as shown and is fixed to the second frame 120.

The second frame body 120 is made of, for example, an aluminum material, and has a cylindrical cross section having a rectangular cross section like the first frame body 110. Such a hollow shape contributes to weight reduction of the second frame body 120. Further, when the solar panel 200 receives an impact force from the outside, the hollow shape is deformed, so that the impact force can be absorbed.

The third frame body 130 has a function of connecting the first frame body 110 and the second frame body 120 across the end portion of the solar panel 200. The third frame body 130 is, like the first frame body 110 and the second frame body 120, a rigid body made of, for example, an aluminum material. Specifically, as will be described later, the rigidity of the third frame body 130 is designed to be lower than the rigidity of each of the first frame body 110 and the second frame body 120.

When the solar panel 200 is inserted from the opening side opposite to the bridged side of the third frame body 130 and sandwiched between the contact rail 111 and the contact elastomer 121, the elastic force of the contact elastomer 121 causes the frame 100 to be inserted. Is fixed to. In other words, the solar panel 200 is sandwiched and fixed between the contact rail 111 and the contact elastomer 121. The operator only needs to insert the end portion of the solar panel 200 between the first frame body 110 and the second frame body 120.

By the nature of the solar panel 200, the solar panel 200 is generally installed outdoors. The solar panel 200 installed outdoors has a risk of collision with various flying objects. For example, the solar panel 200 installed in a vacant lot beside a highway may collide with pebbles wound up by a truck. Birds may collide with the solar panel 200 installed in the mountainous area. If a flying object collides with the solar panel 200 and the solar panel 200 falls off the frame, the fragments may be scattered to people around the frame, or the solar panel 200 may be damaged to the extent that it cannot be repaired. Therefore, it is desirable that the solar panel 200 does not fall off from the frame even when a flying object collides with it.

FIG. 3 is a partial cross-sectional view similar to that of FIG. 2 when the solar panel 200 is impacted by the collision of a flying object. Specifically, the state when a flying object collides with the second surface of the solar panel 200 and an impact force is generated in the direction of the dotted arrow is shown.

The contact rail 111 and the contact elastomer 121 are deformed along the respective surfaces of the solar panel 200 that is displaced by the impact force. The impact force is transmitted to the first frame body 110 and the second frame body 120 via the contact rail 111 and the contact elastomer 121, and reaches the third frame body 130 from the first frame body 110 and the second frame body 120. As described above, the rigidity of the third frame body 130 is designed to be lower than the rigidity of each of the first frame body 110 and the second frame body 120, so that the rigidity of the third frame body 130 is lower than that of the first frame body 110 and the second frame body 120. The third frame body 130 is greatly deformed. That is, it is deformed so that the distance between the first frame body 110 and the second frame body 120 to be bridged is shortened. As a result, the contact rail 111 and the contact elastomer 121 more firmly sandwich the end portion of the solar panel 200. That is, when a flying object collides, the end portion is sandwiched more firmly than in the normal case, so that the solar panel 200 does not fall off from the frame 100 in most situations.

The rigidity of the third frame 130 is lower than the rigidity of the first frame 110 and the second frame 120, respectively, when the third frame 130 bridges the first frame 110 and the second frame 120. In the structure, it means that the third frame body 130 is most easily deformed so as to shorten the bridging interval at the time of shock absorption. In order to realize such deformation, the third frame body 130 may be formed into a thin plate shape bent into a chevron shape as shown in the figure, or may be a lightened plate material or a mesh material. Further, the material of the third frame body 130 may be different from the materials of the first frame body 110 and the second frame body 120, and a material that is easily deformed may be adopted.

The frame 100 of the present embodiment described above adopts a structure in which the end portion of the solar panel 200 is sandwiched between the contact rail 111 and the contact elastomer 121 even in the normal state, but the structure in which the solar panel 200 is sandwiched in the normal time. Is not limited to this. For example, the contact rail 111 is normally separated from the first surface of the solar panel 200, and instead, a protruding portion protruding from the contact rail 111 comes into contact with the first surface to bring the solar panel 200. You may support it. In this case, the contact rail 111 and the first surface come into contact with each other due to the displacement of the solar panel 200 due to the collision of flying objects. If the contact area of the contact rail 111 is larger than the contact area of the protruding portion, it can be expected that the solar panel 200 is more firmly sandwiched in the event of a collision of a flying object.

100 frame, 110 1st frame, 111 contact rail, 120 2nd frame, 121 contact elastomer, 130 3rd frame, 200 solar panel, 300 structure, 310 screws

Claims (1)

A frame for solar panels that sandwiches solar panels.
A first frame having a first contact portion that comes into contact with one side of the solar panel,
A second frame having a second contact portion that comes into contact with the other side of the solar panel, which is opposite to the one side.
A third frame body that connects the first frame body and the second frame body across the end portion of the solar panel is provided.
The solar panel is sandwiched between the first contact portion and the second contact portion.
A frame for a solar panel in which the rigidity of the third frame is lower than the rigidity of each of the first frame and the second frame.

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