JP5611062B2 - Wire-shaping device and wire-wiring structure for wire-wiring the device - Google Patents

Description

  The present invention provides wiring of various cables (linear members) such as an electric cable for transmitting generated electric power when installing a solar energy utilization device such as a solar battery panel installed on a roof of a building. It is related to the technology to prepare.

  Conventionally, in solar energy utilization devices such as solar battery panels installed on the roof of a building, various cables such as electric cables are used, and these cables are wired on the roof. ing. For example, Patent Document 1 discloses that connection cables drawn out from a plurality of arranged solar cell panels are bundled by using a binding band. By using the binding band in this manner, the wiring is arranged, that is, the wires are arranged so that the cables are not complicated on the roof.

  Further, as disclosed in Patent Document 2, a structure in which a solar cell panel is installed on a crosspiece member is also known. In such a structure, a binding band is tied to the crosspiece member. Thus, fixing the cables to the crosspiece member is also performed.

Japanese Patent No. 4476071 JP 2010-261257 A

  In the above-described alignment on the roof, the binding band is used when bundling different types of cables, and may be used for applications such as bending and bundling cables that are slack due to excessive length. This is because if the cable is left loose on the roof, there is a concern that problems such as electric leakage and poor contact, and problems such as rain leakage due to accumulation of dust on the cable may occur.

  However, since the wire-straightening operation using the binding band is a fine manual operation such as tying the binding band, it has been desired to omit it. In particular, when carrying out fine manual work in a high working environment on the roof, it is necessary to be more careful, such as paying attention not to drop parts, and it imposes a heavy burden on the operator, It takes a lot of work time. There is also a concern that variations in construction by the operator may occur.

  Therefore, in view of the above problems, the present invention proposes a new technique for arranging cables for a device such as a solar energy utilization device installed on the roof of a building.

  In addition, it is considered that the degree of slack (sag) of the cables is determined after the solar cell panel is arranged. In other words, "If you do not install the solar panel on the mount, you will not know if the cable will loosen" or "You will know the degree of looseness only after installing the solar panel on the mount" .

  However, since the cables are arranged so as to be hidden behind the solar cell panel, it is difficult to tie the cable with a binding band after squeezing and bending the cable after installing the solar cell panel. Will be the ultimate. That is, it is necessary to grope while working on the back side of the solar cell panel while the cable is not visible, and improvement in workability is desired.

  Therefore, another object of the present invention is to propose a novel technique in which the workability of the wire-sharing work is improved.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, as described in claim 1, a solar cell panel mounting method for a gantry constituted by a long member, wherein a cable extending from a base point at a position away from the long member in each solar cell panel, The step of connecting the cables of the adjacent solar cell panels through the wire-shaping member provided in the long member, the solar cell panel being installed on a gantry, and the wire-shaping member being the long member Slid with respect to the longitudinal direction of the wire to change the position and adjust the line;
It is set as the attachment method of the solar cell panel containing.

In addition, as described in claim 2, at least two of the wire-shaping members are provided for the solar cell panel.

In addition, as described in claim 3, the position change by sliding the wire-shaping member with respect to the long member causes the wire-shaping member to be repositioned in a gap formed below the long member. It is assumed that it is performed by inserting means for the purpose.

In addition, as described in claim 4, it is a straight line structure of a cable of a solar cell panel installed on a gantry constituted by a long member, and is in a position away from the long member in each solar cell panel. The solar cell panel includes a linear member extending from a base point and through which cables connected to each other are passed. The linear member is slidable in the longitudinal direction of the long member. It shall be a cable wiring structure.

In addition, as described in claim 5, at least two of the straightening members are provided for the solar cell panel.

Moreover, as described in claim 6,
Each wire-shaping member is
Provided on the long member constituting the gantry,
It is assumed that a gap that allows the means for changing the position of the wire-straightening member to be inserted is secured below the long member.

  As effects of the present invention, the following effects can be obtained.

That is, in the invention according to claim 1,
By changing the position of the straightening member, it is possible to lengthen the path (path) connecting the base points transmitted by the cable with a straight line, thereby eliminating the slack of the cable. In addition, it is possible to improve workability as compared with the conventional form using a binding band.

In the invention according to claim 2,
By simply sliding the wire-shaping member, the wire-wiring operation can be performed, and workability can be improved.

Further, in the invention according to claim 3 , the linear adjustment member is moved after the device such as the solar cell panel is installed, that is, the final fixing position of the solar cell panel is determined. Therefore, it becomes possible to perform the line adjustment, and it is possible to surely eliminate the slack of the cable. Moreover, it becomes possible to perform the line adjustment without moving the apparatus such as the solar battery panel after the installation, and a configuration excellent in workability can be obtained.

Further, in the invention described in claim 4, by changing the position of the wire-straightening member, it is possible to lengthen the path (path) connecting the base points transmitted by the cable with a straight line. Can be resolved. In addition, it is possible to improve workability as compared with the conventional form using a binding band.

Further, in the invention described in claim 5, it is possible to perform the wire-straightening work simply by sliding the wire-shaping member, and the workability can be improved.

Further, in the invention according to claim 6 , the linear adjustment member is moved after the device such as the solar cell panel is installed, that is, the final fixing position of the solar cell panel is determined. Therefore, it becomes possible to perform the line adjustment, and it is possible to surely eliminate the slack of the cable. Moreover, it becomes possible to perform the line adjustment without moving the apparatus such as the solar battery panel after the installation, and a configuration excellent in workability can be obtained.

The figure which shows the whole outline | summary of one Embodiment of this invention. The figure shown about the state of the support member after installation, a vertical beam member, and a horizontal beam member. (A) is a figure shown about the accommodation of the solar cell panel in the eaves side. (B) is a figure shown about the accommodation of the solar cell panel in the ridge side. (A) is a figure shown about the state where the cable slackened. (B) is a figure shown about the state which arranged the cable. The figure explaining one form of construction of a solar cell panel. The figure shown about the structure of the member for wire-shaping. (A) is a figure explaining attachment of the member for wire-shaping. (B) is a figure explaining the removal and movement of the member for wire-shaping. The figure explaining the clearance gap formed between a crosspiece member and a roof material.

FIG. 1 shows an overall outline of an embodiment of the present invention.
As shown in FIG. 1, the present invention is applied to a solar energy utilization device 2 installed on a roof 1. As an embodiment, a plurality of solar cell panels 3, 3. It is supposed to be arranged.
Further, the gantry 4 is composed of a vertical beam member 10 arranged with the depth direction toward the roof 1 as a longitudinal direction, and a horizontal beam member 20 arranged with the horizontal direction as a longitudinal direction toward the roof 1. 4, solar cell panels 3, 3... Are mounted and fixed.
In addition, as a solar energy utilization apparatus installed on a roof, various apparatuses (for example, a solar water heater etc.) which utilize sunlight and solar heat other than a solar cell panel are assumed.

  As shown in FIG. 1, a plurality of vertical beam members 10, 10 are arranged at intervals, and a plurality of horizontal beam members 20, 20 are also arranged at intervals. And each vertical beam member 10 and the horizontal beam member 20 are arrange | positioned so that it may mutually orthogonally cross, and the cross-beam-like mount frame 4 is comprised. Further, support members 30 and 30 are installed at a plurality of locations of the roof material of the roof 1, and the vertical beam member 10 is fixed to the support members 30 and 30, and the horizontal beam member 20 is mounted on the vertical beam member 10. Is supposed to be fixed.

  Moreover, FIG. 2 shows the state of the support member 30, the vertical beam member 10, and the horizontal beam member 20 after installation. A support member 30 is fixed on the roofing material 1A by a fastening member such as a bolt. Further, the vertical beam member 10 is fixed to the support member 30 by a fastening member such as a bolt. The horizontal beam member 20 is placed on the upper surface of the vertical beam member 10, and the horizontal beam member 20 is fixed to the vertical beam member 10 by fixing members 71 and 72. Further, the lower side of the end portions of the solar cell panels 3 and 3 are placed on the horizontal beam member 20. A cap member 80 is attached to the upper part of the crosspiece member 20, and the upper end portion of the left solar cell panel 3 in the drawing is pressed by the cap member 80. Further, the upper end portion of the right solar cell panel 3 in the drawing is pressed by a pressing piece portion 81 provided on the crosspiece member 20. As described above, the solar cell panels 3 and 3 are fixed to the crosspiece member 20.

  Further, as shown in FIG. 2, the horizontal rail member 20 is formed with a groove portion 25 into which an end portion of the solar cell panel 3 can be inserted, and a substantially U-shaped groove portion 25 that is open to the side. It has become. Thereby, when installing the solar cell panel 3, while inserting the edge part of the solar cell panel 3 in the groove part 25 in the state which inclined the solar cell panel 3, and temporarily setting in the horizontal surface part 20e, a solar cell panel It is possible to install the solar cell panel 3 by defeating 3. In this embodiment, the groove portion 25 is formed between the pressing piece portion 81 and the lateral surface portion 20e.

  In addition to the embodiment shown in FIGS. 1 and 2, the horizontal beam member 20 may be fixed to the support members 30 and 30, and the vertical beam member 10 may be fixed on the horizontal beam member 20. In the description of the embodiments, the terms “vertical” and “horizontal” are used for convenience in understanding the positional relationship, and do not limit the scope of the invention. In addition, the roof 1 is assumed to be a sloped roof having a slope, a roof having any form, such as a flat roof having no slope and a roof having an arc shape. In addition to being fixed on the roofing material 1A, the support member 30 is also assumed to be fixed to other parts such as other metal fittings, mounts, and concrete surfaces.

  FIG. 2 shows the part of the cross beam member 20 in the middle part of the vertical beam member 10 in the longitudinal direction. However, as shown in FIG. 2) By using the horizontal beam member 91 having the same configuration as that of the horizontal beam member 20 shown in FIG. 2, the solar cell panel 3 can be fixed on the eaves side. The crosspiece member 91 is configured to have an inclined surface 91a to facilitate draining. Similarly, as shown in FIG. 3 (b), on the ridge side (in the case of an inclined roof), the same material as the crosspiece member 20 shown in FIG. 2 is used, and the decorative material 92 is used in combination. Thereby, fixation of the solar cell panel 3 in the ridge side is realizable. Thus, in each part in the longitudinal direction of the vertical beam member 10, an embodiment of a horizontal beam member suitable for each part can be obtained.

Next, a structure for arranging cables will be described.
FIGS. 4 (a) and 4 (b) show an outline of a line-aligning structure for eliminating the slack (sag) of the cables 5a and 5b and performing line alignment.
First, as shown in FIG. 4A, from the solar cell panels 3 and 3 adjacent in the lateral direction, the anode-side cables 5a and 5a and the cathode-side cables 5b and 5b are drawn out, respectively. By connecting the cables 5a and 5b of the matching solar cell panels 3 and 3, the solar cell panels 3 and 3 are electrically connected in series so that the electric power generated through the cables 5a and 5b is output. It has become.

  Further, in the state of FIG. 4A, the cables 5a and 5b are in a relaxed state, and the cables 5a and 5b in the relaxed state are connected to the wire-straightening device 50 as shown in FIG. 4B. So that the line can be adjusted. This line adjusting device 50 has at least two line adjusting members 51 and 52 that engage with a cable, and at least one line adjusting member (two line adjusting members 51 and 52 in this embodiment) The crosspiece member (horizontal crosspiece member 20) is provided so as to be movable in the longitudinal direction.

  In addition, with respect to the wire-straightening members 51 and 52, “acting with the cable” means that “the wire-shaping member and a part of the cable are in contact with each other and a load for pulling the cable can be applied”. . For example, in FIG. 4B, when the wire-straightening member 51 is moved to the left side in the drawing, a situation where the cable 5a is pulled by the wire-shaping member 51 can be created. In addition, in FIG. 4B, it is also possible to adopt a configuration in which the wire-straightening member 52 is fixed without being moved with respect to the horizontal beam member 20. Even in this case, as the wire-straightening member 51 moves and the cable 5a is pulled, the wire-shaping member 52 pulls the cable 5b, and the wire-shaping member 52 is associated with the cable 5b. It is.

  Further, as shown in FIG. 4A, the path along which the cables 5a and 5b are transmitted includes a base point 3ak that is the position of the panel side end portion of the cable 5a, a base point 51k that is the position of the wire-straightening member 51, This is a path connecting the base point 52k of the position of the member 52 and the base point 3bk which is the position of the end of the other cable 5b on the panel side. The distance of the path connecting these base points with a straight line is shown in FIG. In this state, the distance is L1 (the sum of La, Lb, and Lc).

  On the other hand, the base points 51k and 52k can be changed to the base points 51n and 52n, respectively, by separating the straightening members 51 and 52 as shown in FIG. 4B, and the distance L2 (Ld) longer than the distance L1. (Sum of Le and Lf)) can be realized. The reason why the distance L2 is longer than the distance L1 is that the route connecting the base point 3ak, the base point 51n, and the base point 51k with a straight line is longer than the route connecting the base point 3ak and the base point 51k with a straight line. Similarly, the route connecting the base point 3ak, the base point 51n, and the base point 51k is longer than the route connecting the base point 3ak and the base point 51k with a straight line.

  As described above, as shown in FIG. 4B, by separating the distance between the two wire adjusting members 51 and 52, the base point through which the series of connected cables 5a and 5b are transmitted is a straight line. It is possible to lengthen the route (path) to be connected, thereby eliminating the slack of the cables 5a and 5b, and making it possible to adjust the cables 5a and 5b on the roof.

  In the present embodiment, the two line-adjusting members 51 and 52 are both movable. However, if at least one of the line-adjusting members is movable, the above-described distance L2 (FIG. 4 ( Since it is possible to enlarge b)), an embodiment is also conceivable in which one of the wire-shaping members is fixed and the other wire-shaping member is movable.

  Moreover, in embodiment of Fig.4 (a) (b), since it is the structure which connects the solar cell panels 3 * 3 adjacent in a horizontal direction in series with the cables 5a * 5b, it is with respect to the crosspiece member 20. Although the arrangement device 50 is arranged, when the solar cell panels adjacent to each other in the vertical direction are connected by a cable, the arrangement apparatus is arranged with respect to the vertical beam member. Can be considered. In this case, the vertical beam member is installed on the horizontal beam member.

  Further, as shown in FIG. 5, in the construction work mode, one end side of the solar cell panel 3 is placed on the horizontal beam member 20 and is inclined (opened), and is on the back side of the solar cell panel 3. In the case of carrying out the operation of performing wiring and line adjustment of the cable 5a, in the case of the example of FIG. 5, it is assumed that the cable 5a has a margin of length proportional to the distance L3. When the device 50 for use (FIG. 4B) is not provided, it is assumed that the cable 5a is slackened by a length proportional to the distance L3. Therefore, even when the construction work mode shown in FIG. 5 is adopted, it is effective to provide the above-described line-straightening device 50 (FIG. 4B) in order to straighten the slack cable 5a. It will be something.

Next, an example of a specific structure of the wire-straightening device will be described.
FIG. 6 is a view showing the structure of the wire-straightening member 51.
As shown in FIG. 6, the wire-straightening member 51 includes a substantially U-shaped cable passage portion 53 whose upper side is opened in a cross-sectional view, and an engagement portion 54 that is attached to the horizontal rail member 20. It is configured as a tray-like member that is long in the same direction as the longitudinal direction of the crosspiece member 20. It should be noted that an embodiment other than the tray-like member as shown in FIG. 6 is also conceivable. For example, a ring-like member, a C-shaped (hook-like) member, etc. can be used in connection with the cable. If it exists, it does not specifically limit about the structure of the member for wire-shaping.

  Further, as shown in FIG. 6, the cable passing portion 53 includes a bottom surface portion 53a, vertical surface portions 53b and 53c rising from both side end portions of the bottom surface portion 53a, and an upper end portion of one vertical surface portion 53b to the other vertical surface portion 53c. A space 53e through which the cable 5a is passed is formed by a space surrounded by these portions. Further, a gap 53f is secured between the upper surface portion 53d and the vertical surface portion 53c, and the cable 5a can be inserted from the gap 53f. The gap 53f and the space 53e are preferably large enough to allow the connector portions 6a and 6b of the cables 5a and 5b shown in FIG.

  Moreover, as shown in FIG. 6, the engaging part 54 is the upper part of the vertical surface part 53c similarly to the lower side engaging piece part 54a which protrudes in the lower part of the vertical surface part 53c of the cable passage part 53 to the horizontal rail member 20 side. And an upper engaging piece portion 54b protruding to the side rail member 20 side. Each of the engaging pieces 54a and 54b is a mounting groove 21 provided on a side portion of the crosspiece member 20, and is inserted into and attached to a substantially U-shaped mounting groove 21 opened on the side. It has become.

  Further, as shown in FIG. 6, the mounting groove portion 21 of the horizontal beam member 20 has a lower side surface portion 21a and an upper side surface portion 21b from the lower end and the upper end of the vertical surface portion 20b of the side portion of the horizontal beam member 20, respectively. Is made to protrude. Further, the end portions of the lower side surface portion 21a and the upper side surface portion 21b are provided with ridge portions 22a and 22b, respectively, and each engagement piece of the wire-straightening member 51 is connected to the ridge portions 22a and 22b. The protruding portions 54c and 54d provided at the ends of the portions 54a and 54b are engaged.

FIGS. 7A and 7B are views for explaining attachment and detachment of the wire adjusting member 51. FIG.
As shown in FIG. 7A, it is preferable that the wire-straightening member 51 is detachably attached to the horizontal beam member 20. That is, as described above, the engaging portion 54 of the straightening member 51 is inserted into the mounting groove portion 21 of the horizontal beam member 20, and in this embodiment, when mounting, The protrusion 54c of the lower engagement piece 54a is put on the protrusion 22a of the lower side face 21a, and the adjustment member 51 is rotated to rotate the upper engagement piece 54b to the mounting groove. 21 and the protrusion 54d at the tip is engaged with the protrusion 22b of the upper side surface 21b.

  And, as shown in FIG. 6, the wire-straightening member 51 attached to the attachment groove portion 21 of the crosspiece member 20 is in a state where the engagement piece portions 54 a and 54 b are sandwiched between the attachment groove portions 21. As long as a force for intentionally moving the wire-shaping member 51 is not applied, the mounting position with respect to the crosspiece member 20 can be maintained. On the other hand, when the wire-shaping member 51 is intentionally moved, the wire-shaping member 51 can be moved by applying a force. In addition, since it is considered that a large force for moving the cable does not act after finishing the wire-shaping work, the wire-shaping member 51 needs to be firmly fixed to the horizontal beam member 20. However, it is preferable that the straightening member 51 is provided on the crosspiece member 20 to such an extent that the straightening member 51 can be moved when an operator applies force. In addition, means for fixing and releasing the fixing at an arbitrary position of the wire-shaping member 51 may be provided separately.

  Further, as shown in FIG. 7B, the wire-shaping member 51 is configured to be detachable / attachable (detachable) from the crosspiece member 20. As a result, when the wire-straightening member 51 is moved relative to the horizontal beam member 20, the movement of the wire-straightening member 51 hits another member such as the vertical beam member 10, and the movement is restricted. In such a case, the wire-straightening member 51 is once removed from the horizontal beam member 20 and mounted again at a position straddling the vertical beam member 10 and the like, and then the wire alignment can be performed. The straightening member 51 is removed by pressing and bending the upper engagement piece 54b in FIG. 7A from above, and the protrusion 54d at the tip is engaged with the protrusion 22b of the mounting groove 21. Can be performed by rotating the member 51 for straightening.

  Further, as shown in FIG. 8, a gap that allows a means for moving (sliding) the wire-straightening member 51 to be inserted between the crosspiece member 20 to which the wire-shaping member 51 is attached and the roofing material 1 </ b> A. 7 is preferably secured. In this embodiment, since the horizontal beam member 20 is installed on the vertical beam member 10, the gap 7 having a width corresponding to the height dimension H1 from the roof material 1A to the horizontal beam member 20 is formed. Thus, by inserting the hand 8 into the gap 7, it is possible to directly touch the line shaping member 51 and move the line shaping member 51.

  Then, as shown in FIG. 8, by securing such a gap 7, the solar cell panel 3 is installed, that is, the final fixing position of the solar cell panel 3 is determined. Thus, it becomes possible to move the wire-straightening member 51 and perform wire-shaping, and it is possible to reliably eliminate the slack of the cable. This is because there is a concern that if the line is adjusted before the final fixing position of the solar cell panel 3 is determined, the cable is slack again due to the position of the solar cell panel 3 being shifted. This is because such a concern will be eliminated if the straightening is performed after the final fixing position of the solar cell panel 3 is determined.

  In addition, when the gap 7 is small and it is difficult to put a hand, it may be possible to move the straightening member 51 by appropriately using a tool or the like. In addition to this, an embodiment in which the operation part is extended from the wire-straightening member 51 through the gap 7 and the wire-shaping member 51 is moved by picking the operation part is also conceivable.

The above is the embodiment of the present invention, and the present invention can have the following contents.
That is, as shown in FIGS. 1 and 4 (a) and 4 (b),
A device 50 for straightening cables 5a and 5b provided in devices such as solar cell panels 3 and 3;
Having at least two wire-shaping members 51 and 52 that engage with the cables 5a and 5b,
Of the wire-shaping members 51 and 52,
The position of at least one of the line shaping members 51 relative to the other line shaping member 52 is configured to be changeable.
It is something to do.

  As a result, as shown in FIGS. 4 (a) and 4 (b), by changing the positions of the wire-straightening members 51 and 52, it is possible to lengthen the path (path) connecting the base points transmitted by the cables 5a and 5b with a straight line. Thus, the slack of the cables 5a and 5b can be eliminated. In addition, workability can be improved as compared with the conventional form using a binding band.

Also, as shown in FIG.
The wire-straightening member 51 is provided on the cross beam member 20 as a long member constituting the gantry 4 for installing the devices such as the solar cell panels 3 and 3;
The wire-straightening member 51 can be changed in position with respect to the horizontal beam member 20 by sliding with respect to the horizontal beam member 20.
It is something to do.

  As a result, it is possible to perform the line adjustment work by simply sliding the line adjustment member 51, and the workability can be improved.

Moreover, as shown in FIG.
The wire-straightening member 51 includes:
Provided in the crosspiece member 20 as a long member constituting the gantry 4 for installing devices such as the solar cell panels 3 and 3;
It is something to do.

  As a result, when the movement is restricted due to the straightening member 51 hitting another member (vertical beam member 10), the straightening member 51 is once removed from the other member. It becomes possible to perform the line adjustment after re-attaching to a position straddling another member.

Also, as shown in FIG.
Below the horizontal beam member 20 as the long member to which the wire-straightening member 51 is attached,
A clearance 7 is provided to allow insertion of a means for changing the position of the wire-straightening member 51.

  As a result, after the apparatus such as the solar cell panel 3 is installed, that is, the final fixing position of the solar cell panel 3 is determined, the line adjusting member 51 is moved to perform line adjustment. It becomes possible to eliminate the slack of the cable with certainty. Moreover, it becomes possible to perform a line adjustment without moving apparatuses, such as the solar cell panel 3 after installation, and it can be set as the structure excellent in workability | operativity.

As shown in FIGS. 1 and 4 (a) and 4 (b),
The gantry 4 for installing devices such as the solar battery panels 3 and 3 provided with the wire alignment unit device 50 is used.

  Thereby, it becomes possible to wire the cables 5a and 5b for the devices such as the solar battery panels 3 and 3 installed on the gantry 4.

As shown in FIGS. 1 and 4 (a) and 4 (b),
A straightening structure for straightening the cables 5a and 5b of the solar energy utilization device 2 installed on the gantry 4,
Having at least two wire-shaping members 51 and 52 that engage with the cables 5a and 5b,
Of the wire-shaping members 51 and 52,
The position of at least one of the line shaping members 51 with respect to the other line shaping member 52 is configured to be changeable,
Each of the wire adjusting members 51 and 52 is provided on the frame 4 side.
It is something to do.

  As a result, as shown in FIGS. 4 (a) and 4 (b), by changing the positions of the wire-straightening members 51 and 52, it is possible to lengthen the path (path) connecting the base points transmitted by the cables 5a and 5b with a straight line. Thus, the slack of the cables 5a and 5b can be eliminated. In addition, workability can be improved as compared with the conventional form using a binding band.

As shown in FIGS. 1 and 4 (a) and 4 (b),
Each of the wire-straightening members 51 and 52 is provided on the cross beam member 20 which is a long member constituting the gantry 4,
Below the crosspiece member 20 as the long member,
A clearance 7 is provided to allow insertion of a means for changing the position of the wire-straightening member 51.

  As a result, after the apparatus such as the solar cell panel 3 is installed, that is, the final fixing position of the solar cell panel 3 is determined, the line adjusting member 51 is moved to perform line adjustment. It becomes possible to eliminate the slack of the cable with certainty. Moreover, it becomes possible to perform a line adjustment without moving apparatuses, such as the solar cell panel 3 after installation, and it can be set as the structure excellent in workability | operativity.

  The configuration of the present invention can be widely applied as means for arranging cables in a solar energy utilization device such as a solar battery panel installed on the roof of a building.

DESCRIPTION OF SYMBOLS 1 Roof 1A Roof material 2 Solar energy utilization apparatus 3 Solar cell panel 4 Mount 5a Cable 5b Cable 7 Gap 10 Vertical beam member 20 Horizontal beam member 21 Mounting groove part 30 Support member 50 Line adjustment device 51 Line adjustment member 52 Line adjustment Materials

Claims (6)

  A method for attaching a solar cell panel to a gantry composed of long members,
  In each solar cell panel, a cable extending from a base point located at a position distant from the long member is passed through a wire adjusting member provided in the long member, and the cables of adjacent solar cell panels are connected to each other;
  Installing the solar cell panel on a gantry, and sliding the wire-shaping member with respect to the longitudinal direction of the long member to change the position;
  A method for mounting a solar cell panel including: At least two of the wire-shaping members are provided for the solar cell panel,
The method for mounting a solar cell panel according to claim 1. The position change by the slide with respect to the long member of each of the wire-shaping members,
In the gap formed below the long member,
It is performed by inserting means for changing the position of the wire-shaping member,
The method for attaching a solar cell panel according to claim 1 or 2, wherein the solar cell panel is attached.   It is a straight line structure of a solar cell panel cable installed on a gantry composed of long members,
  Each solar cell panel has a wire-shaping member that is extended from a base point located at a position away from the long member and through which cables connected to each other pass.
  The wire-shaping member is provided so as to be slidable with respect to the longitudinal direction of the long member.
  Lined structure of solar panel cable. At least two of the wire-shaping members are provided for the solar cell panel,
The straightening structure of the cable of the solar cell panel according to claim 4. Each wire-shaping member is
  Provided on the long member constituting the gantry,
   Below the elongate member, a gap is secured so that a means for changing the position of the wire-shaping member can be inserted.
The straightening structure of the cable of the solar cell panel according to claim 4 or 5, characterized by the above.

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