JP2020070677A - Solar cell module installation structure and its construction method, and cable mounting set used therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar cell module installation structure having excellent workability.
SOLUTION: In a solar cell module installation structure A, solar cell modules 10 each having an upper module connection cable 12 and a lower module connection cable 13 are installed in multiple stages along a vertical axis member 20. In any lower and upper solar cell modules 10, the upper module connecting cable 12 of the lower solar cell module 10 is electrically connected to the lower module connecting cable 13 of the upper solar cell module 10. The upper module connection cable 12 of the lower solar cell module 10 is attached to the vertical axis member 20 at a position corresponding to the installation of the upper solar cell module 10.
[Selection diagram] Fig. 9

Description

  The present invention relates to a solar cell module installation structure, a construction method thereof, and a cable mounting set used therein.

  Various studies have been made on the handling of the cable extending from the solar cell module from the viewpoint of landscape and maintenance. For example, in Patent Document 1, the long sides of the wall panel to which the solar cell module is attached are joined and arranged side by side, and a cable box is provided along the short sides thereof, and a cable extending from the solar cell module is provided. Housing in the cable box is disclosed.

JP, 2011-58261, A

  An object of the present invention is to provide a solar cell module installation structure having excellent workability.

  The present invention provides a solar cell module having an upper module connection cable and a lower module connection cable arranged in multiple stages along a vertical axis member, and in any adjacent lower and upper solar cell modules, the lower solar cell The upper module connection cable of the module is a solar cell module installation structure electrically connected to the lower module connection cable of the upper solar cell module, the upper module connection of the lower solar cell module A cable for use is attached to the position corresponding to the installation of the upper solar cell module on the vertical axis member.

  The present invention provides a solar cell module having an upper module connection cable and a lower module connection cable arranged in multiple stages along a vertical axis member, and in any adjacent lower and upper solar cell modules, the lower solar cell A method of constructing a solar cell module installation structure in which the upper module connection cable of the module is electrically connected to the lower module connection cable of the upper solar cell module, wherein the upper solar cell module is installed. At the time of installing the lower solar cell module in the front, the upper module connecting cable of the lower solar cell module is attached to the vertical axis member at a position corresponding to the installation of the upper solar cell module.

  The present invention is a cable mounting set used in the method for constructing a solar cell module installation structure of the present invention, wherein the cable mounting tool is attached to the upper module connecting cable of the lower solar cell module, and the vertical axis member. A vertical axis member constituting a part including a position corresponding to the installation of the upper solar cell module, and provided with a cable attachment part capable of attaching the cable attachment at the position corresponding to the installation of the upper solar cell module. Have and.

  According to the present invention, excellent workability can be obtained by attaching the upper module connecting cable of the lower solar cell module to the position corresponding to the installation of the upper solar cell module in the vertical axis member.

It is explanatory drawing of the 1st step of the construction method of the solar cell module installation structure which concerns on Embodiment 1. FIG. 3 is a cross-sectional view showing a structure for attaching a vertical axis member to an outer wall in the solar cell module installation structure according to the first embodiment. It is explanatory drawing of the 2nd step of the construction method of the solar cell module installation structure which concerns on Embodiment 1. FIG. 3 is a cross-sectional view showing the installation structure of the lower part of the first-stage solar cell module in the solar cell module installation structure according to Embodiment 1. FIG. 3 is an exploded perspective view showing a mounting structure of a cable for connecting an upper stage module to a mounting rail that constitutes a vertical axis member in the solar cell module installation structure according to the first embodiment. FIG. 3 is a perspective view showing a mounting structure of a cable for connecting an upper stage module to a mounting rail that constitutes a vertical axis member in the solar cell module installation structure according to the first embodiment. It is explanatory drawing of the 3rd step of the construction method of the solar cell module installation structure which concerns on Embodiment 1. FIG. 3 is a cross-sectional view showing the installation structure of the upper part of the first-stage solar cell module and the lower part of the second-stage solar cell module in the solar cell module installation structure according to Embodiment 1. FIG. 3 is a perspective view showing an attachment structure of a cable for connecting an upper stage module to a cross-linking material forming a vertical axis member in the solar cell module installation structure according to the first embodiment. It is explanatory drawing of the 4th and 5th step of the construction method of the solar cell module installation structure which concerns on Embodiment 1. FIG. 6 is an exploded perspective view showing a mounting structure of a cable for connecting an upper stage module to a vertical axis member in the solar cell module installation structure according to the second embodiment. FIG. 7 is a perspective view showing an attachment structure of a cable for connecting an upper stage module to a vertical axis member in the solar cell module installation structure according to the second embodiment. It is a 1st explanatory view which shows the attachment method to the vertical axis | shaft material of the cable for connecting an upper stage module in the construction method of the solar cell module installation structure which concerns on Embodiment 2 from the back surface side of a vertical axis | shaft material. It is a 2nd explanatory view which shows the attachment method to the vertical axis | shaft material of the cable for connecting an upper stage module in the construction method of the solar cell module installation structure which concerns on Embodiment 2 from the back surface side of a vertical axis | shaft material. It is a 1st explanatory view which shows the attachment method to the vertical axis | shaft material of the cable for connecting an upper stage module in the construction method of the solar cell module installation structure which concerns on Embodiment 2 by the cross section of a vertical axis | shaft material. It is a 2nd explanatory view which shows the attachment method to the vertical axis | shaft material of the cable for connecting an upper stage module in the construction method of the solar cell module installation structure which concerns on Embodiment 2 with the cross section of a vertical axis | shaft material.

  Hereinafter, embodiments will be described in detail with reference to the drawings.

(Embodiment 1)
A solar cell module installation structure A and a construction method thereof according to the first embodiment will be described based on FIGS. 1 to 9.

  Here, first, the "solar cell module" in the present application includes a plurality of electrically connected solar cells, which are protected by a sealing material such as a resin, against a solar panel, and a frame. It means a product with the attached items.

  Further, in the following description, the solar cell module 10 is attached to the outer wall W of a building such as a house, so that the direction facing the roof side of the building is “upper” or “upper” and the direction facing the ground side. May be referred to as "lower" or "lower side". When the outer wall W is viewed from the front, the front side may be referred to as “front side”, the opposite side to this front side may be referred to as “rear side”, and the direction connecting the front side and rear side may be referred to as “front-back direction”. The direction connecting the upper and lower sides is the "vertical direction", and the directions orthogonal to the vertical direction and the front-back direction are the "lateral direction", and one side of this lateral direction is the "right side" and the other side is the "left side". Sometimes called.

  In the case where a plurality of solar cell modules 10 are stacked from the ground side (lower side) to the roof side (upper side) and arranged in multiple stages, when comparing two arbitrary solar cell modules 10, the solar cells on the upper side are compared. The module 10 may be referred to as the “upper” solar cell module 10, and the lower solar cell module 10 may be referred to as the “lower” solar cell module 10. Each solar cell module 10 has two module connecting cables for electrically connecting the solar cell modules 10, but the module connecting cable for connecting to the upper solar cell module 10 is “upper The module connecting cable 12 "and the module connecting cable for connecting to the lower solar cell module 10 may be referred to as the" lower module connecting cable 13 ".

  In the solar cell module installation structure A according to the first embodiment, the 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 unit in the middle row will be described. However, the construction method of the units in each end row is basically the same.

<First step>
In the construction method of the solar cell module installation structure A according to the first embodiment, as a first step, as shown in FIG. 1, on the outer wall W of a building such as a house, a plurality of vertical axis members each extending in the vertical direction. 20 are mounted laterally spaced.

  Specifically, first, the wall surface projections 21 are arranged and fixed in the outer wall W at predetermined attachment positions of the longitudinal members 20 at predetermined intervals in the vertical direction. The wall surface jumper 21 is formed of, for example, a steel plate, and has a T-shaped cross-section member having a front plate 211 and a rear plate 212 that is connected to the center of the back surface thereof and extends rearward as shown in FIG. Is. In the wall surface ejector 21, the front plate 211 is arranged in parallel with the outer wall W, the rear plate 212 is inserted into the joint portion of the outer wall W, and is fastened to a structural member such as a steel frame (not shown) in the back. The wall surface ejector 21 is thus fixed to the outer wall W.

  Next, the mounting rails 22 are mounted at fixed intervals in the vertical direction on the wall surface ejector 21 fixed to the mounting position of the vertical axis member 20 on the outer wall W. This mounting of the mounting rail 22 is performed at two positions on both sides in the length direction. The mounting rail 22 is formed of, for example, a plated steel plate, and is an L-shaped member having a wide front portion 221 and a narrow side portion 222 as shown in FIG. As for the front plate 211 of the wall surface jumper 21, the left half is the rail mounting portion of the mounting rail 22 of the left unit, and the right half is the rail mounting portion of the mounting rail 22 of the right unit as viewed from the front. The front surface 221 of the mounting rail 22 is in contact with the corresponding rail mounting portion of the front plate 211, the side surface portion 222 extends toward the outer wall W, and the inner corners of the front surface portion 221 and the side surface portion 222 are the front plate. It is arranged so as to hit the side edge of 211. Then, the screw B1 is tightened from the mounting rail 22 side into screw holes 221a and 211a formed in the front portion 221 of the mounting rail 22 and the front plate 211. The mounting rail 22 is thus mounted on the wall surface jumper 21.

  Next, the mounting rails 22 that are adjacent to each other in the vertical direction are connected by the bridging material 23. The cross-linking material 23 is formed of, for example, a plated steel plate, and is a flat plate-shaped member having the same width as the side surface portion 222 of the mounting rail 22. The cross-linking material 23 is arranged such 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. .. Then, in each of them, screws (not shown) are tightened from the side of the cross-linking material 23 into the screw holes formed in the cross-linking material 23 and the side surface portion 222 of the mounting rail 22. The cross-linking material 23 is attached to the attachment rail 22 in this manner.

  In this manner, the mounting rails 22 attached to the outer wall W and the cross-linking material 23 are alternately coupled by the wall surface ejector 21, and thus the vertical axis member 20 attached to the outer wall W is configured. Therefore, the mounting rail 22 and the cross-linking material 23 are the vertical axis member constituting members that configure the vertical axis member 20. In this case, the vertical axis member forming member includes two kinds of members having different shapes, that is, the mounting rail 22 and the bridge member 23. The vertical axis member constituting member may include a plurality of types of members of three or more types having different shapes, may include only a single type of member, and may be one single member. ..

  When the front plate 211, the mounting rail 22, and the bridge material 23 of the wall surface jumper are made of metal, the wall surface jumper 21 mounts the mounting rail 22 on the outer wall W, and the mounting rails 22 are connected by the bridge material 23. In addition, the vertical axis member 20 constitutes a grounding body as a whole because it is electrically connected. Therefore, the vertical axis member 20 can be electrically connected to the grounding wire extending from various devices at arbitrary positions of the mounting rail 22 and the bridge member 23 which constitute the vertical axis member 20.

<Second step>
In the construction method of the solar cell module installation structure A according to the first embodiment, as the second step, as shown in FIG. 3, the solar cell module 10 in the lowermost first stage is installed.

  Specifically, first, the rail reinforcing plate 30 is attached between the lower ends of the pair of longitudinally adjacent longitudinal members 20 that are adjacent in the lateral direction so as to connect them. Also, another rail reinforcing plate 30 is attached between the pair of longitudinal members 20 so as to connect them in parallel with the vertical spacing with a distance slightly shorter than the height of the solar cell module 10. The rail reinforcing plate 30 is a flat plate-shaped member formed of, for example, a plated steel plate. The rail reinforcing plate 30 is arranged so that its left end contacts the left vertical axis member 20 and its right end contacts the right vertical axis member 20. Then, in each of them, screws (not shown) are tightened into the screw holes formed in the rail reinforcing plate 30 and the vertical axis member 20 from the rail reinforcing plate 30 side. The rail reinforcing plate 30 is thus attached to the vertical axis member 20.

  Next, the module installation member 40 is attached so as to overlap the lower rail reinforcing plate 30 attached between the lower ends of the vertical axis members 20. The module installation member 40 is formed of, for example, a plated steel plate, and as shown in FIG. 4, is a plate-shaped bending member, and is an upper flat plate portion 41 and a lower end after extending to the front side continuously from the lower end thereof. It has a step portion 42 that bends and extends, and a U-shaped groove portion 43 that continuously extends from the lower end to the front side and then bends and extends upward. A drain hole may be formed at the bottom of the U-shaped groove 43. Further, the U-shaped groove portion 43 is not limited to one integrally formed in the module installation member 40, and may be formed separately. Further, the bottom of the U-shaped groove portion 43 does not need to be formed over the entire length of the module installation member 40, and may be partially formed in the entire length of the module installation member 40. The flat plate portion 41 of the module installation member 40 is stacked on the lower rail reinforcing plate 30. Then, at each of the left end portion and the right end portion, the screw B2 is tightened from the module installation material 40 side into the flat plate portion 41 of the module installation material 40 and the screw holes 41a and 30a formed in the rail reinforcing plate 30. The module installation member 40 is thus attached to the rail reinforcing plate 30.

  Next, the first-stage solar cell module 10 is installed so as to close the opening of the horizontally long rectangular frame formed by the pair of vertical axis members 20, the rail reinforcing plate 30, and the module installation material 40. The solar cell module 10 has a horizontally long rectangular module body 11, and an upper-stage module connection cable 12 and a lower-stage module connection cable 13 that extend from the back surface of the module body 11. Each of the upper module connecting cable 12 and the lower module connecting 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 connecting cable 12 and the connector 132 of the lower module connecting cable 13 are connectable. From the viewpoint of preventing connection errors, it is preferable that the same type of connectors of the upper module connecting cable 12 and the lower module connecting cable 13 cannot be connected to each other, and the upper module connecting cable 12 and the lower module are connected. It is preferable that the connecting cable 13 is provided with a visual identification means such as color coding.

  In the solar cell module 10 of the first stage, the lower side portion of the module body 11 is fitted into the U-shaped groove portion 43 of the module installation member 40, and the both side portions of the back surface of the module body 11 are paired with the vertical axis members 20. The upper side portions of the rear surface and the rear surface are provided so as to contact the upper rail reinforcing plate 30, respectively, so that the vertical axis member 20, the rail reinforcing plate 30, and the module installation member 40 are installed in the frame. A gasket made of rubber or the like may be provided in at least one of the space between the module body 11 and the U-shaped groove portion 43 and between the module body 11 and the rail reinforcing plate 30.

  Further, when the solar cell module 10 of the first stage is installed, the upper module connecting cable 12 extending from the module main body 11 is passed through the rear side of the upper rail reinforcing plate 30, and as shown in FIGS. With the cable fixture 50 attached to the cable body 121 of the connecting cable 12, the upper side second-stage solar cell module 10 is installed at a position corresponding to the side portion 222 of the mounting rail 22 that constitutes the left vertical member 20. It is attached to the provided cable attachment portion 60. The cable fixture 50 has a band portion 51 having screw through holes 51a formed at both ends and a mounting screw 52. Examples of the material for forming the band portion 51 include metals such as stainless steel and resins. The cable attachment portion 60 is a screw hole. The upper module connecting cable 12 is wound around the band portion 51 of the cable fixture 50. Both ends of the band portion 51 are overlapped with each other, and the mounting screws 52 are passed through the screw insertion holes 51a at both ends thereof. Then, the mounting screw 52 is tightened by a screwdriver into the cable mounting portion 60 of the screw hole provided in the side surface portion 222 of the mounting rail 22 which constitutes the vertical axis member 20, and the screw head has the screw thread of the band portion 51. The hole 51a is prevented from coming off along the peripheral edge thereof. The upper module connecting cable 12 is thus attached to the side surface portion 222 of the attachment rail 22 that constitutes the vertical axis member 20.

<Third step>
In the construction method of the solar cell module installation structure A according to the first embodiment, as the third step, as shown in FIG. 6, the solar cell module in the upper second row adjacent to the solar cell module 10 in the first row in the lowermost row Install 10.

  Specifically, first, the module installation member 40 is attached so as to overlap the upper rail reinforcing plate 30 attached in the second step. As shown in FIG. 7, in the module installation member 40, the flat plate portion 41 is stacked on the rail reinforcing plate 30, and the step portion 42 is arranged so as to cover the upper side portion of the solar cell module 10 in the first stage. Then, at each of the left end portion and the right end portion, the screw B2 is tightened from the module installation material 40 side into the flat plate portion 41 of the module installation material 40 and the screw holes 41a and 30a formed in the rail reinforcing plate 30. As a result, in the first-stage solar cell module 10, the lower side portion is fitted into the U-shaped groove portion 43 of the lower module installation material 40, and the upper side portion is reinforced with the step portion 42 of the upper module installation material 40 and the rail reinforcement. Since it is fitted between the plate 30 and the plate 30, the displacement in the front-rear direction is restricted. A gasket made of rubber or the like may be provided between the module body 11 and the step portion 42 and the rail reinforcing plate 30.

  Further, they are connected to each other between the pair of longitudinal members 20 in parallel with each other at a distance slightly shorter than the height of the solar cell module 10 in the vertical direction from the upper rail reinforcing plate 30 attached in the second step. The rail reinforcing plate 30 is attached so that. The method of attaching the rail reinforcing plate 30 to the vertical axis member 20 is the same as in the second step.

  Next, the second-stage solar cell module 10 is installed so as to close the opening of the horizontally long rectangular frame formed by the pair of vertical axis members 20, the rail reinforcing plate 30, and the module installation member 40. As shown in FIG. 7, in the second-stage solar cell module 10, the lower side portion of the module body 11 is fitted into the U-shaped groove portion 43 of the module installation member 40, and both side portions of the back surface of the module body 11 are The pair of longitudinal members 20 and the upper side of the back surface are provided so as to contact the rail reinforcing plate 30, respectively, and thereby installed in the frames of the longitudinal member 20, the rail reinforcing plate 30, and the module installation member 40. ..

  In addition, when installing the second-stage solar cell module 10, in the second step, the upper-stage module connection of the first-stage solar cell module 10 attached to the position corresponding to the installation of the second-stage solar cell module 10 on the vertical axis member 20. The cable for use 12 is electrically connected to the cable for connecting lower modules 13 that extends from the module body 11 of the second-stage solar cell module 10.

  By the way, if the upper-stage module connecting cable 12 of the first-stage solar cell module 10 is not attached to the vertical axis member 20, the upper-stage module connecting cable 12 will be attached to the first-stage solar cell module during the third step. It is assumed that a situation will occur in which the rear surface of 10 is depressed. In that case, it is necessary to pull up the dropped upper module connection cable 12 by putting a hand on the back surface side of the solar cell module 10, which impairs the workability. In addition, when the upper module connecting cable 12 is pulled up excessively, or when the upper module connecting cable 12 has a free end, the upper module connecting cable 12 interferes with the solar cell module 10. Alternatively, the solar cell module 10 may be damaged.

However, according to the construction method of the solar cell module installation structure A according to the first embodiment,
At the time of installing the lower-stage first-stage solar cell module 10 before installing the upper-stage second-stage solar cell module 10, the upper-stage module connecting cable 12 of the first-stage solar cell module 10 It is attached to the position corresponding to the installation of the solar cell module 10 of the eye. In this case, it is sufficient to handle the portion of the cable 12 for connecting the upper module on the tip side from the mounting portion, whereby excellent workability can be obtained. Further, since this mounting position is mounted on the side surface portion 222 of the mounting rail 22 that constitutes the vertical axis member 20 and thus on the non-opposing surface of the rear surface of the second-stage solar cell module 10, Interference with the solar cell module 10 in the stage is avoided.

  Here, from the viewpoint of obtaining excellent workability, the cable attachment portion 60 has the installation position corresponding to the installation position of the second-stage solar cell module 10 on the side surface portion 222 of the attachment rail 22 that constitutes the vertical axis member 20 in the vertical direction. It is preferably provided in the middle part when divided into three equal parts. In addition, from the viewpoint that it is possible to adapt to the length of the upper module connecting cable 12 and from the viewpoint of increasing the flexibility of construction, installation of the second-stage solar cell module 10 on the side surface portion 222 of the mounting rail 22. It is preferable that a plurality of cable attachment portions 60 be provided at corresponding positions at intervals in the length direction.

  Further, when the second-stage solar cell module 10 is installed, as in the case of installing the first-stage solar cell module 10, the upper-stage module connecting cable 12 extending from the module body 11 is connected to the upper rail reinforcing plate 30. As shown in FIG. 8, through the rear side, the cable fixture 50 attached to the cable body 121 of the upper module connecting cable 12 allows the upper third stage of the cross-linking material 23 that constitutes the left vertical axis member 20. The solar cell module 10 is attached to the cable attachment portion 60 at a position corresponding to the installation. The upper module connecting cable 12 is wound around the band portion 51 of the cable fixture 50. Both ends of the band portion 51 are overlapped with each other, and the mounting screws 52 are passed through the screw passing holes of the both ends. Then, the mounting screw 52 is tightened by a screwdriver into the cable mounting portion 60 of the screw hole provided in the cross-linking material 23 forming the vertical axis member 20, and the screw head is located at the periphery of the screw through hole of the band portion 51. It is prevented from coming off. The upper module connecting cable 12 is thus attached to the bridging material 23 that constitutes the vertical axis member 20.

  Here, similarly to the above, from the viewpoint of obtaining excellent workability, the cable attachment part 60 has the cross-linking material 23 forming the vertical axis member 20 in the vertical direction at the corresponding installation position of the third-stage solar cell module 10. It is preferably provided in the middle part when divided into three equal parts. Further, from the viewpoint that it is possible to adapt to the length of the upper module connecting cable 12 and from the viewpoint of increasing the degree of freedom in construction, the position corresponding to the installation position of the third-stage solar cell module 10 of the cross-linking material 23. It is preferable that a plurality of cable attachment portions 60 are provided at intervals in the length direction.

<Fourth step>
In the construction method of the solar cell module installation structure A according to the first embodiment, as a fourth step, the second step solar cell module 10 including the attachment of the upper module connection cable 12 to the vertical axis member 20 is included. As shown in FIG. 9, the solar cell module 10 is installed up to the uppermost stage after the third stage, and finally the upper side of the solar cell module 10 is covered with the stepped portion 42 as shown in FIG. The installation material 40 is attached.

  At this time, when the solar cell module 10 of each stage is installed, the cable 12 for connecting the upper stage module is attached to the position corresponding to the installation of the solar cell module 10 of the upper stage on the vertical axis member 20, so that the solar cell module of the second stage is installed. Similar to the case of installing 10, excellent workability can be obtained.

<Fifth step>
In the construction method of the solar cell module installation structure A according to the first embodiment, as the fifth step, the lower module connection cable 13 of the lowermost solar cell module 10 of the first stage is used alone or in units of two or more rows. Are electrically coupled to the lead-in cable 70a that is pulled out from the inside to the outside through the outer wall W and extends. Similarly, the upper module connection cable 12 of the uppermost solar cell module 10 is used alone or by coupling two or more units of units, and the pull-in cable 70b is extended by being pulled out from the inside to the outside through the outer wall W. Electrically connect to. It should be noted that the electrical connection between the solar cell modules 10 is appropriately changed depending on the type of the solar cell module 10, the electrical design of the solar cell module 10, and the like, and thus is limited to the above electrical connection. It is not something that will be done.

  In the solar cell module installation structure A according to the first embodiment completed by the above construction, the solar cell modules 10 are installed in multiple stages on the outer wall W of the vertical wall along the vertical axis member 20, and any adjacent lower stage and In the upper solar cell module 10, the upper module connection cable 12 of the lower solar cell module 10 is electrically connected to the lower module connection cable 13 of the upper solar cell module 10. The upper module connection cable 12 of the lower solar cell module 10 is attached to the vertical axis member 20 at a position corresponding to the installation of the upper solar cell module 10.

  According to the solar cell module installation structure A according to Embodiment 1 as described above, the upper module connection cable 12 of the lower solar cell module 10 is attached to the vertical axis member 20 at a position corresponding to the installation of the upper solar cell module 10. And, since it is electrically connected to the lower module connecting cable 13 of the upper solar cell module 10, the upper module connecting cable 12 and the lower module connecting cable 13 are regularly arranged on the back side of the installation structure. Since the cables are arranged in an orderly manner, the cables can be easily identified, and therefore maintainability is excellent.

  In addition, in the construction of the solar cell module installation structure A according to the first embodiment, the upper module connection cable 12 of the lower solar cell module 10 is attached to a position corresponding to the installation of the upper solar cell module 10 on the vertical axis member 20. Is a cable attachment 50 to be attached to the upper module connection cable 12 of the lower solar cell module 10, and a vertical axis member that constitutes a part of the vertical axis member 20 that includes a corresponding position for installation of the upper solar cell module 10. A cable attachment having a mounting rail 22 and a cross-linking material 23, which are constituent members, each of which is provided with a cable attachment part 60 capable of attaching the cable attachment 50 at a position corresponding to the installation of the upper solar cell module 10. You can use a set.

(Embodiment 2)
The solar cell module installation structure A and the construction method thereof according to the second embodiment will be described based on FIGS. 10A and 10B to 12A and 12B. The parts having the same names as those in the first embodiment are indicated by the same reference numerals as those in the first embodiment. The direction defining method is also the same as in the first embodiment.

  In the solar cell module installation structure A according to the second embodiment, as shown in FIGS. 10A and 10B, in any adjacent lower and upper solar cell modules 10, the cable 12 for connecting the upper module of the lower solar cell module 10 is , Is attached to the cable attachment portion 60 at the position corresponding to the installation of the upper solar cell module 10 on the side surface portion 222 of the attachment rail 22 forming the vertical axis member 20 by the cable attachment tool 50 attached to the cable body 121. ..

  The cable attachment 50 has a band portion 51 having member through holes 51b formed at both ends and an attachment member 53. Examples of materials for forming the band portion 51 and the attachment member 53 include metals such as stainless steel and resins. The mounting member 53 has a large-diameter disc portion 531 at one end, a small-diameter disc portion 532 at the other end, and a columnar portion 533 connecting the centers thereof, and the outer diameter of the columnar portion 533 is the large-diameter disc portion 531. And a dumbbell-shaped member smaller than the outer diameter of the small-diameter disk portion 532. The outer diameter of the large diameter disc portion 531 is larger than the inner diameter of the member through hole 51b of the band portion 51, but the outer diameters of the small diameter disc portion 532 and the columnar portion 533 are smaller than that.

  The cable attachment portion 60 is a cable attachment hole having a large diameter round hole portion 60a in the upper part and a lower long diameter hole portion 60b continuously extending downward in the lower diameter part. The inner diameter of the round hole portion 60a is smaller than the outer diameter of the large diameter disc portion 531 of the cable attachment 50, the same as or larger than the outer diameter of the small diameter disc portion 532, and larger than the outer diameter of the column portion 533. .. The width of the long hole portion 60b is smaller than the outer diameters of the large-diameter disc portion 531 and the small-diameter disc portion 532, and is the same as or larger than the outer diameter of the columnar portion 533.

  In the construction of the solar cell module installation structure A according to the second embodiment, the band module 51 of the cable fixture 50 is wound around the upper module connecting cable 12. Both ends of the band portion 51 are overlapped with each other, and the small-diameter disk portion 532 and the columnar portion 533 of the mounting member 53 are passed through the member through holes 51b at both ends thereof. The small-diameter disk portion 532 and the cylindrical portion 533 are inserted into the round hole portion 60a of the cable attachment portion 60 provided on the vertical axis member 20, as shown in FIGS. 11A and 12A. Since the outer diameter of the large-diameter disc portion 531 is larger than the inner diameter of the round hole portion 60a, it is not inserted into the round hole portion 60a together with the band portion 51. Then, as shown in FIGS. 11B and 12B, they are guided by the long hole portion 60b and positioned at the lower end thereof, and the large-diameter disc portion 531 is attached to the peripheral edge of the member through hole 51b of the band portion 51 and is prevented from coming off. At the same time, the small-diameter disk portion 532 is retained by the edge of the long hole portion 60b of the cable attachment portion 60 of the vertical axis member 20. The upper module connecting cable 12 is thus attached to the side surface portion 222 of the attachment rail 22 that constitutes the vertical axis member 20.

  Also in the cross-linking material 23 that constitutes the vertical axis member 20, the upper module connecting cable 12 of the lower solar cell module 10 is attached to the installation corresponding position of the upper solar cell module 10 in the same manner.

  According to the solar cell module installation structure A according to the second embodiment, the upper module connecting cable 12 can be manually attached to the vertical member 20 without using a tool such as a driver, and the vertical member 20 Since the solar cell module 10 can be easily removed, the solar cell module 10 can be easily removed, and thus the maintainability is excellent. Other configurations and operational effects are the same as those of the first embodiment.

(Other embodiments)
Although the solar cell module installation structure A is arranged on the outer wall W in the first and second embodiments, the present invention is not particularly limited to this, and the solar cell module installation structure A may be an inclined surface such as a roof or It may be arranged on a horizontal plane such as the ground.

  In the first and second embodiments, the cable attachment 50 attached to the upper module connecting cable 12 is attached to the cable attachment portion 60 provided on the vertical axis member 20, but the present invention is not limited to this. For this attachment, for example, a cable attachment such as a clip member or a magnet member is attached to the upper module connection cable 12, and the upper module connection cable 12 is attached to an arbitrary position of the vertical axis member 20 using the same. May be

  Further, this attachment may be configured such that a cable attachment tool such as a clip member is fixed to a predetermined position of the vertical axis member 20 and the upper module connecting cable 12 is attached to the vertical axis member 20 using the same.

  Further, this attachment is made by attaching the upper module connecting cable 12 to the vertical member 20 by using a cable attaching tool such as a clip member which is separate from the upper module connecting cable 12 and the vertical member 20. Good.

  In addition, this attachment is carried out without using a cable attachment tool by hooking the upper module connecting cable 12 to the engagement portion formed of the hole formed in the vertical axis member 20 and the notch formed in the end portion. Alternatively, the cable 12 for connecting the upper stage module may be attached to the vertical axis member 20 with an adhesive.

A Solar cell module installation structure 10 Solar cell module 12 Upper-stage module connection cable 13 Lower-stage module connection cable 20 Vertical axis member 22 Mounting rail (vertical axis member constituent member)
23 Cross-linking material (vertical axis material component)
50 cable mount 60 cable mount

Claims (6)

Solar cell modules having an upper module connection cable and a lower module connection cable are installed in multiple stages along a vertical axis member, and in any adjacent lower and upper solar cell modules, the upper stage of the lower solar cell module. A module connection cable is a solar cell module installation structure electrically connected to the lower module connection cable of the upper solar cell module,
A solar cell module installation structure in which the upper module connection cable of the lower solar cell module is attached to the vertical axis member at a position corresponding to the installation of the upper solar cell module. In the solar cell module installation structure according to claim 1,
A solar cell module installation structure in which the cable for connecting the upper module of the lower solar cell module is attached to the vertical axis member by a cable attachment. The solar cell module installation structure according to claim 1 or 2,
The solar cell module installation structure in which the cable for connecting the upper module of the lower solar cell module can be manually removed from the vertical member without using a tool. Solar cell modules having an upper module connection cable and a lower module connection cable are installed in multiple stages along a vertical axis member, and in any adjacent lower and upper solar cell modules, the upper stage of the lower solar cell module. A module connection cable is a construction method of a solar cell module installation structure electrically connected to the lower module connection cable of the upper solar cell module,
When installing the lower solar cell module before installing the upper solar cell module, the upper module connecting cable of the lower solar cell module, the installation corresponding position of the upper solar cell module in the vertical axis material Construction method of solar cell module installation structure to be attached to. A cable mounting set used for the construction method of the solar cell module installation structure according to claim 4,
A cable fixture attached to the upper module connection cable of the lower solar cell module,
A vertical portion that constitutes a portion including the installation corresponding position of the upper solar cell module in the vertical axis member, and that is provided with a cable attachment part capable of attaching the cable attachment at the installation corresponding position of the upper solar cell module. A shaft member,
Cable mounting set with. The cable mounting set according to claim 5,
The vertical axis member constituting member is a cable attachment set including a plurality of types of members having different shapes.