JP6544611B2 - Frame and solar module - Google Patents

Description

  The present invention relates to a frame, and more particularly to a frame and a solar cell module attached to a solar cell panel.

  A module frame is disposed on each side of the solar cell module. Adjacent module frames are connected by joint members. Here, the joint member is fixed to the module frame by bolts (see, for example, Patent Document 1).

JP, 2014-45118, A

  The coupling member, which is a joint member for coupling the frame that is the module frame, is fixed to the frame by, for example, a joint member such as a bolt as described above. At this time, since the joining member is inserted from the outer surface of the frame, the head of the joining member is exposed to the outer surface. Thereby, the designability of a solar cell module falls.

  The present invention has been made in view of such a situation, and an object thereof is to provide a technique for suppressing a decrease in design of a solar cell module.

  In order to solve the above problems, a frame according to an aspect of the present invention includes a fitting portion to which an outer edge portion of a solar cell panel is fitted, a hollow support portion supporting the fitting portion from below, and a support portion And a bottom portion supporting the legs from below. The bottom portion is provided with a first through hole for inserting the joining member from below, and the support portion is provided with a second through hole for inserting the joining member from below following the first through hole. .

  Another aspect of the present invention is a solar cell module. The solar cell module includes a solar cell panel, a plurality of frames disposed on each side of the solar cell panel, a plurality of connection members for connecting adjacent frames among the plurality of frames, and a plurality of connections. And a plurality of joining members for joining each of the members to each frame. The frame supports a fitting portion to which the outer edge portion of the solar cell panel is fitted, supports the fitting portion from below, a hollow support portion, a leg portion provided downward from the support portion, and a leg And a bottom portion supporting the portion from below. The bottom portion is provided with a first through hole for inserting the joining member from below, and the support portion is provided with a second through hole for inserting the joining member from below following the first through hole. The connecting member is disposed inside the support portion, and has an inserted portion for inserting the joining member following the second through hole.

  ADVANTAGE OF THE INVENTION According to this invention, the fall of the designability of a solar cell module can be suppressed.

Fig.1 (a)-(b) is a figure which shows the structure of the solar cell module which concerns on the Example of this invention. 2 (a)-(b) are cross-sectional views showing the configuration of the solar cell module of FIG. FIGS. 3A to 3D are diagrams showing the configuration of the short frame of FIG.

  Before specifically explaining the present invention, an outline will be given. An embodiment of the present invention relates to a frame disposed on each side of a solar cell panel in a solar cell module. The frame has a hollow structure, and a connecting member for connecting adjacent frames is inserted into the frame. Also, a joining member is used to fix the connecting member and the frame. As described above, when the joining member is inserted from the outer surface of the frame, the design of the solar cell module is degraded by exposing the head of the joining member to the outer face. When the joining member is inserted from the lower surface of the frame in order to suppress the deterioration of the design, the head of the joining member is prevented from being exposed to the outer surface. However, since the head of the joint member comes out of the lower surface of the frame, when the solar cell module is fixed to the mount, the head of the joint member rides on the mount, and the mount fixation becomes unstable. Therefore, inserting the joining member from the lower surface of the frame is not generally adopted.

  In order to maintain the stability of fixation to a gantry while suppressing a decrease in design of the solar cell module, the frame according to the present embodiment is provided with a leg extending downward from a support having a hollow structure, The bottom is located below the legs. Here, the frame is supported by the bottom. Such a support, legs and bottom form a grooved structure recessed from the outer surface. Furthermore, the through-hole which penetrates a bottom part and a support part is provided, and a joining member is inserted in a through-hole from the downward direction. At that time, since the head of the joining member is fixed to the support portion, the head of the joining member does not come out of the lower surface of the bottom. In the following description, "parallel" includes not only perfect parallel but also cases of deviation from parallel in the range of errors. In addition, “approximately” means that they are the same within the approximate range.

  Fig.1 (a)-(b) is a figure which shows the structure of the solar cell module 100 which concerns on the Example of this invention. Fig.1 (a) shows the structure at the time of seeing the solar cell module 100 from the light-receiving surface side. The solar cell module 100 includes a first short frame 10a collectively referred to as a short frame 10, a second short frame 10b, a first long frame 12a collectively referred to as a long frame 12, a second long frame 12b, and a solar cell panel 110. .

  As shown in FIG. 1A, an orthogonal coordinate system including x-axis, y-axis and z-axis is defined. The x axis and the y axis are orthogonal to each other in the plane of the solar cell module 100. The z-axis is perpendicular to the x-axis and the y-axis, and extends in the thickness direction of the solar cell module 100. The positive direction of each of the x-axis, y-axis, and z-axis is defined in the direction of the arrow in FIG. 1A, and the negative direction is defined in the direction opposite to the arrow. Of the two main surfaces forming the solar cell module 100 and parallel to the xy plane, the main plane disposed on the positive direction side of the z axis is the light receiving surface 112, and z The main plane disposed on the negative direction side of the axis is the back surface 114. Hereinafter, the positive direction side of the z axis is referred to as “light receiving surface side”, and the negative direction side of the z axis is referred to as “rear surface side”.

  The solar cell panel 110 has a rectangular shape longer in the x-axis direction than in the y-axis direction, including the light receiving surface 112 and the back surface 114 that are opposite to each other in the z-axis direction. A translucent substrate is disposed on the light receiving surface 112 side of the solar cell panel 110, and a back sheet serving as a back surface protection member is disposed on the back surface 114 side. In addition, a sealing member is disposed between the light transmitting substrate and the back sheet, and the plurality of solar cells are sealed by the sealing member. For example, a glass substrate, a translucent plastic, etc. are used for a translucent substrate, and a resin film such as PET (polyethylene terephthalate) or a laminated film having a structure in which an Al foil is sandwiched between resin films is used for a back sheet. Is used. Further, as the sealing member, a thermoplastic resin such as a resin film such as polyolefin, EVA (ethylene vinyl acetate), PVB (polyvinyl butyral) or polyimide is used.

  Short frames 10 extending in the y-axis direction are disposed at both ends of the solar cell panel 110 in the x-axis direction, and long frames 12 extending in the x-axis direction are disposed at both ends of the solar cell panel 110 in the y-axis direction. . The adjacent short frame 10 and the long frame 12 are connected to each other, so that the two short frames 10 and the two long frames 12 are arranged in a frame shape surrounding the solar cell panel 110. Since the short frame 10 and the long frame 12 are formed by extrusion molding, they have the same cross section in the direction transverse to the extending direction. The short frame 10 and the long frame 12 are made of, for example, aluminum or an aluminum alloy in order to protect the solar cell panel 110.

  A terminal box not shown is attached to the back surface 114 of the solar cell panel 110. Further, one end of each of the two cables is connected to the terminal box, and a connector is connected to the other end of each of the two cables. The terminal box, the cable, and the connector are electrically connected to the solar cell panel 110 and draw power from the solar cell panel. Although the solar cell module 100 has the short frame 10, the long frame 12, the terminal box, the cable, and the connector attached to the solar cell panel 110, the description of the terminal box, the cable, and the connector will be omitted below.

  FIG. 1 (b) is an enlarged view of a portion where the first short frame 10a and the first long frame 12a are adjacent in FIG. 1 (a), and shows a configuration when viewed from the light receiving surface side. The first short frame 10a extending in the y-axis direction and the first long frame 12a extending in the x-axis direction are joined together substantially at right angles. Moreover, the 1st short frame 10a and the 1st long frame 12a are connected by making the connection member 200 insert in those inside. The connection member 200 is shown by a dotted line because it can not be seen from the light receiving surface side and the back surface side of the solar cell module 100.

  The connecting member 200 has an L shape in which a first connecting piece 210a extending in the x-axis direction and a second connecting piece 210b extending in the y-axis direction are joined at substantially right angles. In the connection member 200, the first connection piece 210a and the second connection piece 210b are integrally formed. By such a configuration, the first connection piece 210a is inserted into the inside of the first long frame 12a, and the second connection piece 210b is inserted into the inside of the first short frame 10a.

  At that time, in order to facilitate the insertion of the first connection piece 210a into the first long frame 12a, the first connection piece end 212a is disposed on the negative direction side of the x-axis of the first connection piece 210a. Here, the first connection piece end 212a is formed in an acute angle. In addition, the second connection piece end 212b is formed similarly in the second connection piece 210b. The connection member 200 connects adjacent frames by inserting the connection piece 210 into the frame. Furthermore, a circular first inserted portion 220a is provided in the first connection piece 210a, and a circular second inserted portion 220b is provided in the second connection piece 210b. Details of these will be described later.

  In FIG. 1A, between the first short frame 10a and the second long frame 12b, between the second long frame 12b and the second short frame 10b, and between the second short frame 10b and the first long frame 12a. The connecting member 200 is also inserted between them. Therefore, the solar cell module 100 includes four connection members 200.

  FIGS. 2A and 2B are cross-sectional views showing the configuration of the solar cell module 100. FIG. FIG. 2A is a cross-sectional view of the solar cell module 100 in FIG. 1A along the x-axis, specifically, the A-A ′ line. The solar cell panel 110 has a shape longer in the x-axis direction than the z-axis direction, and is disposed with the light receiving surface 112 facing the positive direction side of the z-axis and the back surface 114 facing the negative direction side of the z-axis. Further, each of the positive direction end of the x-axis of the solar cell panel 110 and the negative direction end of the x-axis is an outer edge portion 116.

  Although the first short frame 10a and the second short frame 10b are symmetrical although configured in the same manner, the following description will be made based on the first short frame 10a. The long frame 12 (not shown) may be configured similarly to the short frame 10. The short frame 10, which collectively refers to the first short frame 10a and the second short frame 10b, includes a fitting portion 20, a support portion 22, a leg portion 24, and a bottom portion 26. The support portion 22 has a top surface portion 28 and a first hollow portion. 30 includes a second hollow portion 32, a first partition piece 34 a collectively referred to as a partition piece 34, a second partition piece 34 b, and a bottom surface portion 40. Here, the fitting portion 20, the support portion 22, the leg portion 24, and the bottom portion 26 are integrally formed.

  The fitting portion 20 is disposed on the positive direction side of the z axis of the support portion 22 described later, and has a cross-section which is recessed on the negative direction side of the x axis by being combined with the top surface portion 28 of the support portion 22. With such a shape, the outer edge portion 222 of the solar cell panel 110 is fitted into the fitting portion 20 from the negative direction side of the x axis. The fitting portion 20 and the top surface portion 28 and the solar cell panel 110 are fixed by a butyl-based sealing material or a silicon-based adhesive.

  The support portion 22 supports the fitting portion 20 from the negative direction side of the z axis. The top surface portion 28 is disposed on the positive direction side of the z axis of the support portion 22 so as to face the fitting portion 20. Further, the support portion 22 has a substantially rectangular cross section, and is provided with the first partition piece 34 a and the second partition piece 34 b opposite to the inner wall of the hollow structure. The hollow structure is divided into a first hollow portion 30 and a second hollow portion 32 by the first partition piece 34 a and the second partition piece 34 b. At the bottom surface portion 40 on the negative direction side of the z axis of the support portion 22, the leg portion 24 is provided from the negative direction side of the x axis toward the negative direction of the z axis. The legs 24 may be connected to any part of the bottom 40. A bottom 26 is disposed on the negative side of the leg 24 in the z-axis direction. The bottom portion 26 has a cross section extending in the x-axis direction, and supports the bottom portion 26 from the negative direction side of the z-axis.

  FIG.2 (b) is sectional drawing in alignment with the x-axis of the solar cell module 100 in FIG.1 (b), specifically the B-B 'line | wire. This can be said to be a cross-sectional view including a portion where the second inserted portion 220 b is formed in the connecting member 200. In FIG. 2 (b), the bonding member 300 is shown. An example of the joining member 300 is a rivet. The rivet is a part which is plastically deformed and joined at the opposite end by inserting into a holed member and caulking with a dedicated tool, and includes a head 310 and a body 312. The head 310 may be either a hemispherical round head, a disc-like flat head, or a flat disc face with a flat surface side and a conical base, but it is assumed here that it is a round head. Also, the body portion 312 is formed in a cylindrical shape. Note that no screw is formed on the body 312. Here, since the diameter of the largest portion of the head 310 is larger than the diameter of the trunk portion 312, when the joint member 300 is inserted from the trunk portion 312, the head 310 advances the joint member 300. It is stopped. The joining member 300 may be a screw instead of a rivet. In that case, at least a part of the body portion 312 is formed with a threaded portion.

  The first short frame 10a is configured in the same manner as FIG. 2A, but the bottom 26 is provided with a first through hole 36 for inserting the bonding member 300 in the negative direction of the z-axis. Further, in the support portion 22, a second through hole 38 for inserting the bonding member 300 in the negative direction of the z-axis is provided following the first through hole 36. Furthermore, in the second hollow portion 32 of the first short frame 10a, the connecting member 200 is disposed, and in the connecting member 200, following the second through hole 38, the connecting member 300 is from the negative direction of the z axis. A second insertion portion 220b for insertion is provided. Here, the first through hole 36 penetrates the bottom portion 26 in the z-axis direction, the second through hole 38 penetrates the bottom surface portion 40 in the z-axis direction, and the second inserted portion 220 b connects the connecting member 200. It penetrates in the z-axis direction. Here, the diameter of the second through hole 38 is equal to the diameter of the second inserted portion 220 b, is larger than the diameter of the trunk portion 312, and smaller than the diameter of the largest portion of the head 310. On the other hand, the diameter of the first through hole 36 is larger than the diameter of the second through hole 38 and larger than the diameter of the largest portion of the head 310.

  In the joining member 300, the body portion 312 is directed to the positive direction side of the z axis, and the head 310 is directed to the negative direction side of the z axis. The trunk portion 312 is inserted into the first through hole 36 from the negative direction side of the z axis of the first through hole 36 in such a direction. The body portion 312 passes through the first through hole 36, the second through hole 38, and the second inserted portion 220b, and the tip end of the body portion 312 passes through the connecting member 200 and reaches the first hollow portion 30. On the other hand, following the body portion 312, the head 310 is also inserted into the second through hole 38 and passes through. However, since the diameter of the largest portion of the head 310 is larger than the diameter of the second through hole 38, the head 310 is stopped at the bottom 40. Thus, the head 310 is disposed on the positive direction side of the z axis with respect to the bottom portion 26. Therefore, although the joining member 300 is inserted from the back side of the short frame 10, the head 310 does not come out from the back side of the frame.

  Furthermore, each of the plurality of bonding members 300 is inserted into the first through hole 36 and the second through hole 38 provided in the short frame 10 and the long frame 12 and the inserted portion 220 provided in the connecting member 200. Therefore, the plurality of joint members 300 join the short frame 10 and the long frame 12 with each of the plurality of connection members 200.

  FIGS. 3A to 3D show the configuration of the short frame 10. Here, the configuration of the first short frame 10a is shown as an example, but the same applies to the second short frame 10b. Also, the long frame 12 may have the same configuration except for the length. FIG. 3A shows a configuration when the first short frame 10a is viewed from the light receiving surface side. As illustrated, it has a substantially trapezoidal shape. Further, the bottom portion 26 protrudes in the negative direction side of the x axis with respect to the fitting portion 20.

  FIG. 3B shows the configuration when the first short frame 10 a is viewed from the side, more specifically from the outer side of the solar cell module 100. From the positive direction of the z-axis to the negative direction, the fitting portion 20, the support portion 22, the leg portion 24, and the bottom portion 26 are arranged in order. FIG. 3C shows a configuration when the first short frame 10a is viewed from the back side. This has a substantially trapezoidal shape as in FIG. 3 (a). Further, the two first through holes 36 are provided in the bottom portion 26, and the second through holes 38 are disposed inside the respective first through holes 36. FIG. 3D shows another configuration when the first short frame 10a is viewed from the back side. Here, the shapes of the first through holes 36 and the second through holes 38 are different from those in FIG. The first through holes 36 have an elliptical shape that is longer in the y-axis direction than in the x-axis direction. The second through hole 38 has a concaved shape so as to open in the positive direction of the x axis. Similarly to the first through hole 36, the second through hole 38 may have an elliptical shape longer in the y axis direction than the x axis direction.

  According to the embodiment of the present invention, the support portion 22, the leg portion 24, and the bottom portion 26 are arranged in order, the bottom portion 26 is provided with the first through hole 36, and the support portion 22 is provided with the second through hole 38. Therefore, the joining member 300 can be inserted into the support 22 from the bottom 26 side. Further, since the joining member 300 is inserted into the support portion 22 from the bottom portion 26, the head 310 of the joining member 300 can be made inconspicuous. Moreover, since the head part 310 of the joining member 300 becomes inconspicuous, the fall of the designability of the solar cell module 100 can be suppressed. In addition, since the size of the first through hole 36 is larger than the size of the second through hole 38, the head 310 of the bonding member 300 can pass through only the first through hole 36 and can not pass through the second through hole 38 . Further, since the head portion 310 of the joining member 300 passes through only the first through hole 36 and does not pass through the second through hole 38, the head portion 310 can be prevented from coming out from the back surface side of the bottom portion 26. Moreover, since the head 310 does not come out from the back surface side of the bottom part 26, the riding on the mount can be prevented. Moreover, the solar cell module 100 which suppressed the fall of the designability can be provided.

  The outline of this embodiment is as follows. The short frame 10 and the long frame 12 according to an embodiment of the present invention include a fitting portion 20 to which the outer edge portion 116 of the solar cell panel 110 is fitted, and a hollow support 22 supporting the fitting portion 20 from below. , A leg 24 provided downward from the support 22 and a bottom 26 supporting the leg 24 from below. The bottom portion 26 is provided with a first through hole 36 for inserting the joining member 300 from below, and the support portion 22 is provided with a second through hole 36 for inserting the joining member 300 from below. Two through holes 38 are provided.

  The size of the first through hole 36 is larger than the size of the second through hole 38.

  Another aspect of the present invention is a solar cell module 100. The solar cell module 100 is adjacent to the solar cell panel 110 and a plurality of short frames 10 and long frames 12 arranged on each side of the solar cell panel 110 and a plurality of short frames 10 and long frames 12. A plurality of connecting members 200 for connecting the short frame 10 and the long frame 12 and a plurality of connecting members 300 for connecting each of the plurality of connecting members 200 to the respective short frames 10 and the long frame 12 are provided. The short frame 10 and the long frame 12 support a fitting portion 20 to which the outer edge portion 116 of the solar cell panel 110 is fitted, support the fitting portion 20 from below, and a hollow support 22 and a support 22. , And a bottom 26 supporting the leg 24 from below. The bottom portion 26 is provided with a first through hole 36 for inserting the joining member 300 from below, and the support portion 22 is provided with a second through hole 36 for inserting the joining member 300 from below. A through hole 38 is provided, and the connecting member 200 is disposed inside the support portion 22 and has an inserted portion 220 for inserting the joining member 300 following the second through hole 38.

  The present invention has been described above based on the embodiments. It is understood by those skilled in the art that this embodiment is an exemplification, and that various modifications can be made to their respective components or combinations of processing processes, and such modifications are also within the scope of the present invention. .

  In the present embodiment, the insertion portion 220 penetrates the connection member 200. However, not limited to this, for example, the insertion portion 220 may not penetrate the connection member 200. At this time, the tip of the body 312 is disposed in the connecting member 200. According to this modification, the degree of freedom of the configuration can be improved.

  Reference Signs List 10 short frame (frame), 12 long frame (frame), 20 fitting portion, 22 support portion, 24 leg portion, 26 bottom portion, 28 top surface portion, 30 first hollow portion, 32 second hollow portion, 34 partition piece, 36 first through hole, 38 second through hole, 40 bottom portion, 100 solar cell module, 110 solar cell panel, 112 light receiving surface, 114 back surface, 116 outer edge portion, 200 connecting member, 210 connecting piece, 212 connecting piece end, 220 inserted parts, 300 joining members, 310 heads, 312 trunks.

  ADVANTAGE OF THE INVENTION According to this invention, the fall of the designability of a solar cell module can be suppressed.

Claims (3)

A fitting portion to which the outer edge portion of the solar cell panel is fitted;
A hollow support portion for supporting the fitting portion from below;
A leg provided downward from the support;
And a bottom supporting the legs from below.
The bottom portion is provided with a first through hole for inserting the joining member from below,
The frame is characterized in that the support portion is provided with a second through hole for inserting the joining member from below following the first through hole.   The frame according to claim 1, wherein a size of the first through hole is larger than a size of the second through hole. With solar panels,
A plurality of frames disposed on each side of the solar cell panel;
A plurality of connecting members for connecting adjacent frames among the plurality of frames;
And a plurality of joining members for joining each of the plurality of connecting members to each frame,
The frame is
A fitting portion to which the outer edge portion of the solar cell panel is fitted;
While supporting the fitting portion from below, a hollow support portion;
A leg provided downward from the support;
And a bottom supporting the legs from below.
The bottom portion is provided with a first through hole for inserting the joining member from below;
The support portion is provided with a second through hole for inserting the joining member from below following the first through hole,
The solar cell module is characterized in that the connection member is disposed inside the support portion and has an insertion portion for inserting the bonding member following the second through hole.

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