JP2006241761A - Solar cell module-mounting roof structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solar cell module-mounting roof structure of high safety also in strength without being deformed by looseness or distortion even if mounted to a lightweight structure such as a sheet-like roof or wall using a woven fabric or polymeric material used for a lightweight roof of a foldable or demountable tent or a dome. <P>SOLUTION: A lightweight flexible type solar cell module 6 with silicon crystal or amorphous silicon formed in a film state on a polymeric film material such as plastic is used as a solar cell module bonded onto the polymeric sheet 5 of the dome-type lightweight roof. The respective flexible type solar cell modules 6 are joined and wired in series and wired as a power supply for a driving motor of the dome-type lightweight roof. The flexible type solar cell module 6 is covered with a polymeric material such as a polyethylene sheet to prevent an electric leakage to the dome-type lightweight roof itself. A polymeric material with heat insulating property is used as the polymeric material 5. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a solar cell module mounting roof structure in which a solar cell module is mounted on a roof.

  Conventionally, a solar cell has been used as a power source for an opening / closing mechanism such as opening / closing of a daylighting skylight installed on a roof of a building or opening / closing of an openable / closable roof. For example, Patent Document 1 describes an open / close-type lighting skylight device that is installed and used in an opening of a building, and shows an example in which a solar cell is installed outside an opening frame. Patent Document 2 describes a solar cell panel-integrated openable / closable roof that can obtain electrical energy in a structure. This solar cell panel-integrated open / close roof has a large number of vanes, and each vane is composed of a vane body and an amorphous solar panel attached to the surface of the vane body facing the sun. Has been. Patent Document 3 describes an open / close type skylight device that also serves as a solar cell panel in which a window body that opens and closes a daylight or ventilation skylight opening provided on a roof surface of a building also functions as a solar cell panel. ing. Solar cells are attached to the surface of the window. In both cases, electrical energy is taken out from the solar panel mounted on the roof or wall of the building, and the electrical energy generated by direct current through the inverter is converted into alternating current as the primary power source for lighting, ventilation, or air conditioning in the building. It is converted and used.

  FIG. 3 is a diagram for explaining the outline of opening and closing of the daylighting skylight and the like in the above-described prior art. In FIG. 3, reference numeral 10 denotes a building, 11 denotes a roof of the building 10, 1 denotes a solar cell panel installed on the roof 11, and 2 denotes an openable skylight for daylighting etc. installed on the roof 11. A structure such as the openable skylight 2 shown in FIG. 3 is provided with a driving device or an opening / closing mechanism (not shown) for opening and closing the structure, and a solar cell used as a power source for driving the structure. The panel 1 itself is also directly attached to a structure such as the roof 11. Thus, the structure to which the solar cell panel 1 is attached in the prior art is limited to a structure such as a strong roof 11 that does not change its shape even when the solar cell panel 1 is directly attached.

JP 60-258360 A JP 7-139112 A Japanese Patent Laid-Open No. 9-53309

  Since the solar cell itself has a panel shape with respect to the structure such as the strong roof 11 described above, the solar cell panel 1 can be attached and mounted only by matching the solar cell panel 1 to the size of the structure such as the roof 11. It can be used. However, for lightweight structures such as foldable or disassembleable tents, woven fabrics used for lightweight roofs such as domes, or sheet-like roofs or walls using polymeric materials, solar cells Not only the lightweight structure is deformed by the slack or distortion caused by the mounting of the panel 1, but also there is a problem in safety in terms of its strength. That is, there is a problem that it is impossible to directly install the conventional solar cell panel 1 on a lightweight roof such as a tent, a dome, or a sheet due to a limitation in weight.

  Accordingly, an object of the present invention is to solve the above-mentioned problems, and a sheet using a woven fabric used for a lightweight roof such as a tent or a dome that can be folded or disassembled, or a polymer material. It is to provide a solar cell module mounting roof structure that is highly safe in terms of strength without being deformed by slack or distortion even when mounted on a lightweight structure such as a roof or wall. .

  The solar cell module-attached roof structure of the present invention is a solar cell module-attached roof structure in which the solar cell modules are attached to the roof, and the roof is constituted by a sheet material stretched on pillars installed at predetermined intervals. The solar cell module is a flexible type solar cell module fixed on the sheet material.

  Here, in the solar cell module mounting roof structure of the present invention, the flexible solar cell module can be used as a power source for opening and closing the roof and / or for charging a power source for opening and closing.

Here, in the solar cell module mounting roof structure according to the present invention, the opening and closing of the roof can be performed by folding or sliding the roof.

  Here, in the solar cell module mounting roof structure of the present invention, the sheet material may be a polymer sheet using a polymer material.

  Here, in the solar cell module mounting roof structure of the present invention, the flexible type solar cell module is formed by forming a silicon crystal or amorphous silicon on a polymer film material, and both sides of the flexible type solar cell module are covered with an insulating sheet. It may be provided with a different structure.

  Here, in the solar cell module mounting roof structure according to the present invention, the roof may have a dome shape or a tent shape.

According to the solar cell module mounting roof structure of the present invention, a silicon crystal or amorphous silicon film is formed on a polymer film material such as plastic as a solar cell module to be bonded onto a polymer sheet of a dome-shaped lightweight roof, and an electrode is formed. The taken out flexible type solar cell module is used. Although deformation such as slack may occur in the polymer sheet between the columns of the dome-shaped lightweight roof, the flexible solar cell module can be deformed together with the deformation. For this reason, it becomes possible to utilize a flexible type solar cell module for a sheet-like dome-shaped lightweight roof. Each flexible type solar cell module is joined and wired in series, and is wired as a power source for the drive motor of the dome-shaped lightweight roof. Since the flexible type solar cell module is covered with a polymer material such as a polyethylene sheet, electricity generated from both ends of the flexible type solar cell module does not leak to the dome-shaped lightweight roof itself. Even if the insulation property of the flexible solar cell module is lowered, an insulating polymer material may be used as the polymer sheet (roof material) so that electricity does not flow through the polymer sheet itself. By the above, even if attached to a lightweight structure such as a foldable or disassembleable tent, a woven fabric used for a lightweight roof such as a dome, or a sheet-like roof or wall using a polymer material, There is an effect that it is possible to provide a solar cell module mounting roof structure that is highly safe in terms of strength without deformation caused by slack or distortion.

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

  FIG. 1: shows sectional drawing of the sheet-like dome shape lightweight roof structure which is an example of the solar cell module attachment roof structure in Example 1 of this invention. In FIG. 1, reference numeral 15 is a building, 16 is a sheet-like dome-shaped light roof provided in the building 15, 5 is a polymer sheet using a polymer material used for the dome-shaped light roof 16, and 4 is a dome-shaped light weight. A column 3 that supports the roof 16 is a moving rail (or slide rail) on which a plurality of columns 4 are installed. As shown in FIG. 1, a plurality of support columns 4 are installed at predetermined intervals on a moving rail 3 provided at a lower portion of a dome-shaped lightweight roof 16, and a polymer sheet 5 is placed on the support columns 4. The roof structure has a dome-shaped lightweight roof 16 attached thereto by stretching.

  FIG. 2 shows an enlarged perspective view of the dome-shaped lightweight roof 16. In FIG. 2, the same reference numerals as those in FIG. In FIG. 2, reference numeral 6 denotes a flexible solar cell module in which a silicon crystal or amorphous silicon film is formed on a polymer film material such as plastic and electrodes are taken out. The structure is covered with a polymer material (insulating sheet, not shown). As shown in FIG. 2, the lightweight flexible type solar cell module 6 is attached to the polymer sheet 5 by adhesion (adhering). Subsequently, reference numeral 7 denotes a moving wheel installed at the lower portion of the column 4 in order to move the entire dome-shaped lightweight roof 16 on the moving rail 3. In FIG. 2, the column 4 is indicated by a broken line because it is the back side of the polymer sheet 5.

  As described above, since the flexible solar cell module 6 is covered with a polymer material such as a polyethylene sheet, electricity generated from both ends of the flexible solar cell module 6 leaks to the dome-shaped lightweight roof 16 itself. There is no. Each flexible type solar cell module 6 is joined and wired in series, and is wired as a power source for the driving device of the dome-shaped lightweight roof 16.

  As the polymer sheet 5 (roofing material), the flexible solar cell module 6 can be bonded, and even if the insulation of the flexible solar cell module 6 falls, the polymer sheet 5 itself does not flow electricity. A high molecular weight material is used. For example, as the polymer sheet 5, a polymer sheet such as a fluororesin or polyethylene is suitable.

  The struts 4 of the dome-shaped lightweight roof 16 are made of steel pipes or the like in order to increase the strength of the entire dome-shaped lightweight roof 16 and to reduce the distortion or deformation of the polymer sheet 5. Install. The dome-shaped lightweight roof 16 moves on a moving rail 3 provided at a lower portion thereof by a drive motor (not shown). At that time, the polymer sheet 5 is folded to achieve a lightweight roof structure that enables opening and closing of the sheet-like dome-shaped lightweight roof 16. Alternatively, a lightweight roof structure that enables opening and closing of the sheet-shaped dome-shaped lightweight roof 16 can be achieved by sliding the entire dome-shaped lightweight roof 16 when moving on the moving rail 3 by the drive motor. . The predetermined interval for installing the support columns 4 may be an interval that is loosened appropriately when the flexible solar cell module 6 is fixed to the polymer sheet 5.

  The drive motor can directly use electricity generated by the flexible solar cell module 6. However, when the dome-shaped lightweight roof 16 is opened and closed at night, the solar battery energy cannot be obtained. Therefore, the battery (secondary battery) is charged in advance during the day, and the drive motor is operated using the secondary battery. It only needs to be able to operate. That is, the flexible solar cell module 6 can be used directly as a power source for opening and closing the dome-shaped lightweight roof 16, or can be used indirectly for charging a power source for opening and closing (secondary battery). Of course, it may be used directly as an open / close power source for the dome-shaped lightweight roof 16 and indirectly used for charging the open / close power source.

  The polymer sheet 5 between the columns 4 of the dome-shaped lightweight roof 16 may be deformed such as slack. However, the film-shaped flexible solar cell module 6 used in the sheet-like dome-shaped lightweight roof structure of the present invention can be deformed together with the above deformation. For this reason, the flexible solar cell module 6 can be used for the sheet-like dome-shaped lightweight roof 16. Similarly, a flexible solar cell module 6 may be bonded to the surface portion of a sheet-like lightweight roof such as a tent that can be folded or disassembled.

  As mentioned above, according to Example 1 of this invention, as a solar cell module adhere | attached on the polymer sheet 5 of the dome shape lightweight roof 16, a silicon crystal or amorphous silicon is formed into a polymer film material, such as a plastic, The flexible solar cell module 6 from which the electrode is taken out is used. The polymer sheet 5 between the columns 4 of the dome-shaped lightweight roof 16 can be deformed such as slack, but the flexible solar cell module 6 can be deformed together with the deformation. For this reason, the flexible solar cell module 6 can be used for the sheet-like dome-shaped lightweight roof 16. Each flexible type solar cell module 6 is joined and wired in series, and is wired as a power source for the drive motor of the dome-shaped lightweight roof 16. Since the flexible type solar cell module 6 is covered with a polymer material such as a polyethylene sheet, electricity generated from both ends of the flexible type solar cell module 6 does not leak to the dome-shaped lightweight roof 16 itself. Even if the insulation property of the flexible solar cell module 6 is lowered, an insulating polymer material may be used as the polymer sheet 5 (roof material) so that electricity does not flow through the polymer sheet 5 itself. By the above, even if attached to a lightweight structure such as a foldable or disassembleable tent, a woven fabric used for a lightweight roof such as a dome, or a sheet-like roof or wall using a polymer material, It is possible to provide a solar cell module mounting roof structure that is highly safe in terms of strength without causing deformation due to slack or distortion.

  Examples of applications of the present invention include a lightweight roof structure, for example, a foldable or disassembleable tent, a woven fabric used for a lightweight roof such as a dome, or a sheet-like roof or wall using a polymer material. A lightweight roof structure can be cited as an application target. That is, it can be applied to a roof structure having a wider application range than before.

It is sectional drawing of the sheet-like dome shape lightweight roof structure which is an example of the solar cell module attachment roof structure in Example 1 of this invention. It is the perspective view which expanded the dome shape lightweight roof 16. FIG. It is a figure for demonstrating the outline of opening and closing of the skylight for lighting in a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell panel, 2 Open / close-type skylight, 3 Moving rail, 4 Support column, 5 Polymer sheet, 6 Flexible type solar cell module, 7 Moving wheel, 10, 15 Building, 11 Roof, 16 Dome type lightweight roof.

Claims (6)

A solar cell module mounting roof structure in which the solar cell module is mounted on a roof,
The roof is a lightweight roof made of a sheet material stretched on pillars installed at a predetermined interval, and the solar cell module is a flexible type solar cell module fixed on the sheet material. Solar cell module mounting roof structure.   The solar cell module-mounted roof structure according to claim 1, wherein the flexible solar cell module is used as a power source for opening and closing the roof and / or for charging a power source for switching. 3. The solar cell module-attached roof structure according to claim 1, wherein the roof is opened and closed by folding or sliding the roof.   The solar cell module mounting roof structure according to any one of claims 1 to 3, wherein the sheet material is a polymer sheet using a polymer material.   The solar cell module mounting roof structure according to any one of claims 1 to 4, wherein the flexible type solar cell module is formed by forming a silicon crystal or amorphous silicon on a polymer film material, and both sides of the flexible type solar cell module are A solar cell module mounting roof structure comprising a structure covered with an insulating sheet. 6. The solar cell module mounting roof structure according to claim 1, wherein the roof has a dome shape or a tent shape.

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