JPH1077719A - Wiring coupling sub-plate and facing structure attached with solar energy converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a facing structure as well as a coupling sub-plate making ridge directional connection of a facing material integrally equipped with a solar energy converter such as a solar battery on its surface side in the ridge direction. SOLUTION: The wiring coupling sub-plate 1 makes ridge directional connections of a facing material 2 attached with a solar energy converter integrally equipped with a solar energy converter 22 such as a solar battery on the face plate 21 and it is also used for wiring disposition of the solar energy converter 22. In such case, the plate 1 is provided, on the eaves side, with an eaves side end part 13 positioned on the ridge side fringe of the facing material 2 on the lower stage and, on the ridge side, with a ridge side end part 12 equipped with a flashing 121, while its breadth center is provided with a wiring groove 14 capable of storing connecting cables 221 for the solar energy converter 22.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wiring joint discarding plate for connecting in the direction of the order of girder an exterior material integrally provided with a solar energy conversion device such as a solar cell on the surface side, and an exterior with a solar energy conversion device. It is about structure.

[0002]

2. Description of the Related Art In recent years, many proposals have been made in which a solar energy conversion device is integrated with an existing roofing material. No. 7-297440)
Has been made. The solar cell module described in the above-mentioned Japanese Patent Application Laid-Open No. 7-297440 has had to obtain a roof material with a solar cell by integrating a solar cell with a face plate of an existing roof material by bonding or other means. Against
Since roll forming becomes possible, improvement in productivity as a roofing material is expected.

[0003]

However, when the wiring of the solar cell is considered, there are the following problems. Generally, the left and right ends in the longitudinal direction of the roof material to be roll-formed are processed portions, and the processed portions are naturally subjected to pressure by the rolls. Therefore, it is appropriate to provide the connection terminals of the solar cell near the processed portions. Not. A roofing material of a horizontal roofing type represented by a horizontal roofing metal roof is fixed in a state in which a ridge-side molded portion is grounded on or close to a base, so that it is difficult to perform an electrical wiring process in an eaves ridge direction. The roofing material for the connection in the left-right direction generally performs a raining by arranging a joint discard plate on the back surface of the connection portion, but does not have a sufficient space to allow the wiring for the solar cell.

[0004]

SUMMARY OF THE INVENTION The present invention has been proposed in view of the above-mentioned circumstances. The present invention relates to a method of connecting an exterior member integrally provided with a solar energy conversion device such as a solar cell to a face plate portion in the order of digits, and A wiring joint discarding plate used for wiring processing of a solar energy conversion device, which has an eaves end on the eaves side, located on the ridge edge of the lower exterior material, and a water return section on the ridge side. A wiring joint discarding plate having a side end portion and having a wiring groove portion capable of accommodating the connection cable of the solar energy conversion device in the center in the width direction,
And an exterior structure with a solar energy conversion device using the same.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION A wiring joint discarding plate (hereinafter simply referred to as a joint discarding plate) 1 according to the present invention is a ridge having an eave-side end portion 13 on the eave side and a water return portion 121 on the ridge side. It has a side end portion 12 and a wiring groove portion 14 at the center in the width direction. The connection is made in the row direction of the exterior material 2 with the solar energy conversion device described later, and the wiring of the solar energy conversion device 22 is performed. It is used for processing.

The above-mentioned joint discard plate 1 can be made of the same material as the base material of the exterior material 2 with a solar energy conversion device described later. When the material is a metal plate, roll forming (roll forming) or It is molded (molded) by press molding or a combination of both. The joint discard plate 1 shown in FIGS. 1 and 2 is produced by using both press molding and roll molding, and has water return pieces 111 which are folded inward on both side edges of the receiving plate portion 11. A plurality of (two on each side) protrusion ribs 112 are formed in the length direction, and the protrusion ribs 112 are respectively formed in the length direction as shown in FIG. It is inclined toward.
The ridge rib 112 has a water return structure when rainwater invades, like the water return piece 111. On the eave side of the receiving plate portion 11, an eave-side end portion 13 is formed by bending the eave end of the receiving plate portion 11 downward, and on the ridge side of the receiving plate portion 11, the ridge end of the receiving plate portion 11 is formed. The ridge side end portion 12 having the water return portion 121 formed by bending the upper part upward is formed. Further, a wiring groove 14 communicating with the eaves ridge direction is formed in the center of the receiving plate 11 in the width direction. The bottom portion of the wiring groove 14 is shown in FIG.
As shown in (c), it has a tapered shape that slopes upward from the ridge end 12 to the eaves end 13. Further, the ridge end of the wiring groove portion 14 bulges toward the ridge side from the water return portion 121 (bulge portion 141). The length in the length direction of the receiving plate 11 is substantially equal to or slightly larger than the width in the width of the face plate 11 of the exterior material 2 described later.

[0007] The exterior material 2 to be connected in the girder direction by the joint discard plate 1 is provided with a solar energy conversion device 22 such as a solar cell on the face plate portion 21 integrally. Any structure having a waterproof connection portion 23 and a waterproof connection receiving portion 24 that engage or overlap with each other may be used. The specific configuration (structure and shape) of each of the above-described portions is not particularly limited. It may be designed and implemented. The exterior material 2 is made of a rust-proofing steel sheet such as a hot-dip galvanized steel sheet or a galvalume steel sheet, a special steel and a non-ferrous metal, a stainless steel sheet,
A weather-resistant steel plate, a copper plate, an aluminum alloy plate, a lead plate, a zinc plate, a titanium plate, or the like may be used as a material, and may be appropriately formed by roll molding, press molding, or the like. In addition, the solar energy conversion device 22 is not particularly limited in its configuration, and any configuration can be applied. For example, using a flexible amorphous silicon solar cell recently proposed. Is also good. The amorphous silicon solar cell is lightweight and flexible by using a highly weather-resistant transparent film as a surface protection material, and does not break even when bent or walked on the surface. Also, the mode of combination with the exterior material 2 is not particularly limited. For example, the entire surface of the material constituting the exterior material 2 is coated in advance with a highly elastic filler in which the solar cell is embedded. At the same time, the surface may be protected by a highly weather-resistant transparent film, which may be appropriately molded, or the solar cell may be attached to the surface of an existing exterior material that has already been molded. In general, a solar cell is composed of a conductive substrate, a back reflection layer, a semiconductor layer as a photoelectric conversion member, and a transparent conductive layer. Examples of the conductive substrate include steel plates, copper, titanium, aluminum, stainless steel, and carbon sheets. In addition, a resin film such as polyester, polyimide, polyethylene naphthalide, or epoxy provided with a conductive layer, a ceramic, or the like can also be used. The semiconductor layer is not particularly limited, but a compound semiconductor such as an amorphous silicon semiconductor, a polycrystalline silicon semiconductor, a crystalline silicon semiconductor, and copper indium selenide can be used. As described above, the solar energy conversion device 22 can be configured in any manner, but in the illustrated embodiment, the solar energy conversion device
The second connection cable 221 was formed so as to be located.
Incidentally, the connection cable 221 and the like are subjected to a waterproof treatment without being described.

In the embodiment shown in FIGS. 1 and 3, the exterior material 2 is provided at the side edges in the longitudinal direction of the face plate portion 21, that is, at the eave edge and the ridge edge.
The waterproof connection portion 23 and the waterproof connection receiving portion 24 are formed by roll molding, and the waterproof connection portion 23 provided on the eave edge is bent so that the eave edge of the face plate portion 21 extends downward and continues to the ridge side. The waterproof connection receiving portion 24 provided at the ridge edge is bent so that the ridge edge of the face plate portion 21 extends upward toward the eaves and then downward toward the eaves. It is. The waterproof connection portion 23 and the waterproof connection receiving portion 24 are engaged with each other as shown in FIG. 3B, and have a structure in which rainwater or the like does not enter the back surface from the engagement portion. Incidentally, in FIG.
Is a suspender for holding the waterproof connection receiving portion 24 of the exterior material 2 from above.

As shown in FIG. 1, the exterior material 2 and the joint discard plate 1 are disposed on the back side of the end in the girder direction of the exterior material 2 along the almost entire length of the exterior material 2. 1 are connected. At this time, the connection cable 221 located at the edge in the girder direction of the exterior material 2 is accommodated in the wiring groove 14 of the joint discard plate 1. The connection cable 221 housed in the wiring groove 14 is laid toward the ridge side, and is taken out from the ridge end that protrudes toward the ridge side from the water return portion 121. After that, the cover member 4 is arranged so as to cover between the ends of the exterior member 2 in the girder direction. This cover material 4
Is usually made of the same material as the base material of the exterior material 2, but a decorative material different from the base material of the exterior material 2 may be used in consideration of design.

[0010] Along with the joint discard plate 1 and the exterior material 2 described above, FIG.
The base material 3 having the exterior structures of Nos. To 6 will be described. As the base material 3, a foamed resin material having a high heat insulating property such as polyurethane, polystyrene, phenol or the like is used, but a wood wool cement board or the like can be used in consideration of fire resistance. In the base material 3 of the illustrated embodiment, the grooves 31 for wiring and the grooves 32 for support members are alternately formed on the surface of the base material 3 at regular intervals in the order of shunting. Absent.

FIGS. 4 and 5 show the case 2 having the joint discarding plate 1 and the solar energy converter 22 integrally, and the case 20 having the same structure except that the solar energy converter 22 is not provided. This is an exterior structure laid on the base material 3. In FIG. 4A, reference numeral 5 denotes the exterior material 2 and the exterior material 2
A support member for fixing the base member 3, which is fixed to a frame below the base material 3, and on which a suspender 6 is fixed. At the time of the installation, the connecting cable 7 is previously arranged in the wiring groove 31 of the base material 3,
The joint discard plate 1 is disposed immediately above the joint disc 1. Therefore, FIG.
As shown in (a), on the ridge side, the wiring groove 14 of the joint discard plate 1 is loosely received in the wiring groove 31 of the base material 3, and the ridge-side back surface of the receiving plate part 11 is covered with the base material. 3, the joint discard plate 1 is stably disposed without rattling in the inclination (rotation) direction. Thereafter, the exterior material 2 is laid. However, as described above, the connection cable 221 is housed in the wiring groove 14 of the joint discard plate 1 and taken out from the ridge end, and is therefore housed in the wiring groove 31. Since it is located above and below the connecting cable 7, the connection of the solar energy converter 22 of the exterior material 2 in the eaves ridge direction can be extremely easily performed as shown in FIG. Although not shown, the same applies to the case where the connection is made in the horizontal direction. The connection cable 221 and / or the connection cable 7 may be connected in the wiring groove 14 and / or the back space of the exterior material 20 adjacent to the ridge side. good. In this manner, the wiring processing of the solar energy conversion device 22 can be easily performed, and there is no hindrance to the subsequent arrangement of the cover member 4. Further, in the wiring processing in the prior art, the connection of the exterior material in the same stage had to be performed simultaneously with the fixing of the exterior material, but according to the present invention, for example, some of the wiring processing shown in FIG. After the exterior material is fixed as in the aspect described above, the operations can be performed collectively on the upper side, so that the work cooperation and wiring confirmation between the exterior material installer and the electric construction worker are facilitated, and the workability is improved. In addition, as for the arrangement of the exterior material 20 adjacent to the ridge side, as described above, the waterproof connection receiving portion 24 provided on the ridge edge is used.
In this case, it is only necessary to engage with the waterproof connection portion 23 provided on the eaves edge of the upper exterior material 20.

In particular, in this exterior structure, the wiring groove 14 of the joint discard plate 1 has a tapered shape in which the bottom portion is inclined upward toward the eaves-side end 13, and the eaves-side end 13 is provided in the lower exterior material 20. Therefore, even if rainwater enters, it can be surely and smoothly guided to the lower exterior material 20 and drained. Further, in this exterior structure, since the connection cable 221 is taken out from the bulging portion 141 bulging toward the ridge side from the water return portion 121 of the wiring groove portion 14 as described above, the connecting cable 221 is taken out. At the end (small edge) of the joint discard plate 1 can be reduced.

In this exterior structure, the exterior material 2 integrally provided with the solar energy conversion device 22 and the exterior material 20 not provided with the solar energy conversion device 22 are alternately arranged in the eaves ridge direction. Is not particularly limited. For example, the roof may be constituted only by the former.

FIGS. 7 to 9 show another embodiment of the joint discard plate 1 of the present invention. In the following embodiments, portions having the same functions as those of the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted. Joint discarded plate 1 ₂ shown in FIG. 7 is created only by press molding, water flashing piece 111 to the standing piece shape, projecting ribs 112 are formed on a strip at a time Mikadoyama shape to the left and right. As described above, the water return pieces 111 and the ridge ribs 112 are not particularly limited in their shapes, and may be formed into any shape. In this embodiment, the bulging portion 141 is not provided on the ridge side of the wiring groove 14 as in the above-described embodiment.
As shown in FIG.
Is provided on the ridge side of the ridge of the exterior material 2 (waterproof connection receiving portion 24) at a distance of at least the amount of wiring processing, so that connection is made from the space between the water return portion 121 and the ridge of the exterior material 2. The cable 221 can be easily taken out.

[0015] Joint discarded plate 1 ₃ shown in FIG. 8, after the press molding, is created by sticking a strip of rubber foamed resin, the rubber resin foam is water flashing piece (portion) 111 and projecting ribs 1
12. Thus, the water return piece (part) 11
The protruding rib 112 may be formed of a separate member. In this case, the contact with the exterior member 2 is not made between metals, so that physical stability and durability stability are improved. Further, in this embodiment, the wiring groove 14 has a bottom portion extending from substantially the center in the longitudinal direction from the ridge side end portion 12 to the eave side end portion 13.
It has a tapered shape that slopes up toward.

[0016] Joint discarded plate 1 ₄ shown in FIG. 9 is created by press-molding, the type is not ledge of the wiring groove 14 on the back surface. In this embodiment, the water return piece 111 is formed in the shape of an upright piece, and the protruding ribs 112 are formed in the shape of a triangular mountain with two left and right sides.
2 ′ is formed high on the ridge side, and the wiring groove 14
Is formed. As shown in FIG. 3B, even the wiring groove 14 which is not depressed downward can be used as a space for accommodating the connection cable 221 as in the embodiment. In short, in this configuration, the position of the end portion in the row direction of the exterior material is regulated by the high ridge ribs 112 ′ and 112 ′ near the center, and the wiring groove 14 that can accommodate the connection cable is secured between the ribs. is there. According to this configuration, since the wiring groove 14 and the receiving plate 11 are on the same plane, there is no need to consider the return gradient of the wiring groove 14 as in the other embodiments. Further, in the case of the configuration in which the wiring process in the column direction is performed, the base material may have a flat shape,
Even in the case of performing the wiring processing in the direction of the eaves ridge, a shallow groove may be used as compared with the other embodiments.

Next, another embodiment of the base material 3 is shown in FIG.
11 is shown. Base material 3 ₂ shown in FIG. 10, the end portion of the girder direction, the ends of the eaves ridge direction respectively, a structure to be polymerized to each other in the figure, 33 is right overlapping portion, 34 and the right overlapping portion 33 Polymerization Left overlap section, 35 is a ridge overlap section, 36 is a ridge overlap section 35
This is the eaves polymerization section that polymerizes. And this base material 3 ₂
Can be connected in the eaves ridge direction to allow the wiring groove 31 to communicate in the eaves ridge direction as shown in FIG. In this case the peripheral shape may be formed so as to how not particularly limited, but which communicates the wiring grooves 31 as the base material 3 ₂ of this embodiment in Nokito direction, non When formed of a water-permeable material, the wiring groove 31 can also be used as a drain groove, and in this case, a secondary waterproof effect can be obtained.

The base material 3 ₃ shown in FIG. 11, the surface is not flat, stepped to back over the back surface of the receiving plate portion 11 and the outer cover 2 of the face plate portion 21 of the joint discard plate 1 in substantially the entire surface This is a configuration in which many raised portions 37 are formed. The outer shape as, but may be any form not particularly limited, the use of the base material 3 ₃ of this embodiment, the outer structure endurance strength during forward load is applied (hard-to-deform) Will be higher.

Although the present invention has been described with reference to the embodiments shown in the drawings, the present invention is not limited to the above-described embodiments, but may be modified in any way unless the structure described in the claims is changed. Can be implemented. For example, it is not limited that the water return portion 121 of the joint discard plate 1 is provided immediately after the ridge of the exterior material, and a configuration in which a fixed portion extending along the base from the water return portion 121 to the ridge side may be formed. .
In addition, in order to regulate the disposition position of the exterior material 2 with respect to the joint discard plate 1, a regulating portion for locking the end of the exterior material 2 in the row direction may be provided at an appropriate position of the joint discard plate 1. . Furthermore, in order to improve the mounting stability of the cover member 4, a means or a portion that physically engages with the joint discard plate 1 may be provided.

[0020]

In summary, the wiring joint discarding plate of the present invention has an eave-side end located on the eave side of the lower exterior material on the eave side and a water return portion on the ridge side. It has a ridge-side end and a wiring groove at the center in the width direction that can accommodate the connection cable of the solar energy conversion device. Therefore, a solar energy conversion device such as a solar cell is integrated with the face plate. And the wiring process of the solar energy converter can be easily performed in the wiring groove. In particular, wiring processing in the direction of the eaves wing becomes easy. According to the wiring processing of the prior art, connection of the exterior material in the same stage had to be performed simultaneously with fixing of the exterior material. Therefore, the work coordination and wiring confirmation between the exterior material installer and the electric construction operator are facilitated, and the workability is improved.

When the bottom portion of the wiring groove is formed in a tapered shape which is inclined upward at least from the center in the longitudinal direction to the eaves end, even if rainwater flows into the wiring groove,
It can be drained smoothly.

Further, when the water return portion is made substantially along the ridge edge of the exterior material and the ridge end of the wiring groove is bulged toward the ridge side from the water return portion, the wiring can be easily formed from the bulge portion. Can be taken out. Further, the possibility of damaging the wiring such as the connection cable at the end (small edge) of the joint can be reduced.

A base material having a wiring groove and a support member groove formed on the surface is laid on a surface to be roofed,
An exterior structure in which a joint discarding plate is disposed on the wiring groove,
Since the wiring groove in which the connecting cable and the like are provided and the wiring groove in which the connecting cable is provided are located vertically, the connection of the solar energy converter in the eaves ridge direction can be performed extremely easily. Furthermore, since the exterior material can be firmly fixed to the support member, it is possible to provide an exterior structure with a solar energy conversion device having excellent workability and strength performance.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view showing a connection structure between a joint discard plate and an exterior material according to one embodiment.

2A is a perspective view showing a joint discard plate used in the connection structure of FIG. 1, FIG. 2B is a sectional view thereof, and FIG. 2C is a side view thereof.

3A is a perspective view showing an exterior material used in the connection structure shown in FIG. 1, and FIG. 3B is a side sectional view showing a connection state in the eaves ridge direction.

4A is a longitudinal sectional view showing a part of an exterior structure using the connection structure of FIG. 1, and FIG. 4B is a side sectional view thereof.

5A is a perspective view showing an exterior structure using the connection structure of FIG. 1, and FIG. 5B is an enlarged plan view showing a part thereof.

6A is a plan view illustrating an example of a wiring process, FIG. 6B is a plan view illustrating another example, and FIG. 6C is a plan view illustrating another example.

7A is a perspective view showing a joint discard plate according to another embodiment, FIG. 7B is a sectional view thereof, and FIG. 7C is a side view thereof.

8A is a perspective view showing a joint discard plate according to another embodiment, FIG. 8B is a sectional view thereof, and FIG. 8C is a side view thereof.

9A is a perspective view illustrating a joint discard plate according to another embodiment, and FIG. 9B is a cross-sectional view illustrating a connection state in the row direction.

10A is a front view showing a base material according to another embodiment, and FIG. 10B is a side sectional view showing a connection state in the eaves ridge direction.

FIG. 11 is a perspective view showing a base material according to another embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1, 1 ₂ , 1 ₃ , 1 ₄ Joint discard plate 11 Receiving plate part 12 Building end 13 House end 14 Wiring groove 141 Swelling part 2 Exterior material with solar energy conversion device 21 Face plate part 22 Solar energy conversion Apparatus 221 Connection cable 23 Waterproof connection part 24 Waterproof connection receiving part 3 Base material 31 Wiring groove 32 Support member groove

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[Procedure amendment]

[Submission date] October 3, 1997

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0015

[Correction method] Change

[Correction contents]

[0015] Joint discarded plate 1 ₃ shown in FIG. 8, after the press molding, is created by sticking a strip of rubber foamed resin, the rubber resin foam is water flashing piece (portion) 111 and projecting ribs 1
12. Thus, the water return piece (part) 11
And the protruding rib 112 may be made of a separate member. In this case, the contact with the exterior material 2 is not made between metals.
Since, physical stability and running stability are improved. In this embodiment, the wiring groove 14 has a bottom portion extending horizontally from the ridge-side end portion 12 to substantially the center in the longitudinal direction.
It has a tapered shape that slopes upward from the center to the eaves side end 13.

Claims (5)

[Claims] 1. A wiring joint discard plate used for connecting in an order direction of an exterior member integrally provided with a solar energy conversion device such as a solar cell on a face plate portion and for wiring processing of the solar energy conversion device. The eave side has an eave-side end located on the ridge edge of the lower exterior material, the ridge side has a ridge-side end provided with a water return section, and the center in the width direction has the sun A wiring joint discarding plate having a wiring groove capable of accommodating a connection cable of an energy conversion device. 2. The wiring joint discarding plate according to claim 1, wherein a bottom portion of the wiring groove has a tapered shape which is inclined upward at least from a center in a longitudinal direction to an eave-side end. 3. The water return portion substantially along the ridge edge of the exterior material, and the ridge end of the wiring groove bulges toward the ridge side from the water return portion. Discard the wiring joints described. 4. A joint discarding plate for wiring is provided along the substantially entire length of the exterior material on the back surface side of the end in the girder direction of the exterior material integrally provided with a solar energy conversion device such as a solar cell on the face plate portion. In the exterior structure formed by arranging and connecting, the exterior material has a waterproof connection portion and a waterproof connection receiving portion that are engaged or superimposed on each other on the eaves edge and the ridge edge of the face plate portion. The edge has a connection cable of the solar energy conversion device, the wiring joint discarding plate, on the eaves side, the eaves end located on the ridge side edge of the lower exterior material, on the ridge side, An exterior structure with a solar energy conversion device, comprising: a ridge side end portion having a water return portion; and a wiring groove at a center in a width direction capable of accommodating a connection cable of the solar energy conversion device. 5. A concave groove for wiring for connecting solar cell energy devices of vertical packaging materials in series in a vertical direction and a groove for a supporting member for supporting the packaging material are respectively formed on the surface.
The underlaying material formed so as to communicate in the direction of the eaves ridge or more is laid on the roof construction target surface, and a wiring joint discard plate is disposed on the wiring groove. Exterior structure with solar energy converter.