JP2014080846A - Method for mounting corrugated plate-like galvanized plate, and processing method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for mounting a corrugated plate-like galvanized plate such as a house with a solar cell formed on the surface thereof, in which it can be easily mounted even by an amateur, plasterer, or carpenter in mounting work and the mounting cost is reduced.SOLUTION: First of all, a position of an interval and a dimension of a wooden purlin material 3 are determined, or positions of holes to be formed in a solar cell 1 are determined, and then positions of holes to be formed in a large-corrugated iron plate, a substrate bracket metallic material, and a steel frame are determined. The processing of holes in the surfaces of the large-corrugated iron plate is performed by a numerically-controlled machine tool in a factory in advance so that a large amount of holes are accurately processed, and a corrugated plate-like galvanized plate is mounted on the wooden purlin material 3 by using nails or wood screws as roof materials.

Description

The present invention provides a process for forming a thin-film solar cell (1) on the surface of a corrugated corrugated iron plate (2) (hereinafter simply referred to as a corrugated steel plate or a corrugated steel plate). It is about the method.

Further, the present invention relates to a rafter (3) or a wall constituting a roof of a house made of a corrugated corrugated steel plate or a corrugated corrugated steel plate (hereinafter referred to simply as a corrugated steel plate). The present invention relates to attaching a corrugated steel plate (2) or a steel plate (8) made of a flat plate to the rafter (3) that is constructed from the back side.

In order to install the solar cell (1), for example, a structure for installing the solar cell (1) on the surface of the roof of the house is formed, and the structure formed on the surface of the roof of the house is formed. The present condition is attaching the solar cell (1).

Moreover, after forming the solar cell (1) on the surface of the corrugated steel plate (2), the corrugated steel plate (2) is used as the rafter (3) constituting the roof of the house. The nail (4) is used to form the solar cell (1) on the surface of the rafter (3), and the corrugated steel plate (2) is attached to the rafter (3). When used and struck, rainwater enters from the portion where the rafter (3) is struck by the corrugated steel plate (2) using the nail (4), and the corrugated steel plate ( The solar cell (1) formed on the surface of 2) has a defect that the solar cell (1) is peeled off. The solar cell (1) is formed on the surface of the conventional corrugated iron plate (2). It is a solar cell.

Furthermore, when attaching the corrugated steel plate (2) to the rafter (3) constituting the roof of the house, the surface of the corrugated steel plate (2) using nails (4) Using a nail (4), a corrugated steel plate (2) is used to form a corrugated steel plate (2) on the rafter (3) of the roof constituting the house. Using the nail (4) from the surface of 2), the corrugated steel plate (2) using the nail (4) to the rafter (3) is hit against the rafter (3).

Problems to be solved by the invention

The rafter (3) constituting the roof of the house on the back surface of the corrugated iron plate (2) is attached to the nail (4), the bolt (5), the nut (6), the hook (7), or Pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) or UK turnbuckle (7) (hereinafter abbreviated as nut, hook or eye) )
Or, use other means to attach the rafter (3) to the back surface of the corrugated iron plate (2) and fix it on the surface of the corrugated steel plate (2). On the surface of the corrugated corrugated steel plate (2) by using the corrugated corrugated steel sheet (2) on which the battery (1) is formed as a roofing material for the house and directly as the roof of the house. The rainwater enters from the surface of the corrugated steel plate (2) formed by the solar cell (1), and the solar cell from the surface of the corrugated steel plate (2). The purpose is to prevent (1) from peeling off.

Moreover, when the corrugated iron plate (2) is used as a roof material constituting a house, the corrugated steel plate (2) is used as a rafter (3) constituting the house. When the nail (4) is used from the surface of the shaped tin plate (2) to the rafter (3) constituting the house, the corrugated tin plate (2) is turned into the rafter (3). Using the nail (4) to prevent the corrugated steel plate (2) from rusting due to rainwater entering from the hole where the nail (4) is struck against the rafter (3). With the goal.

After attaching the rafter (3) constituting the house to the back surface of the corrugated iron plate (2) and fixing the solar cell (1 The solution means is to use the corrugated iron plate (2) formed as a roofing material for a house.

Moreover, by attaching the rafter (3) constituting the roofing material of the house from the back side to the corrugated steel plate (2), the corrugated steel plate (2) is completely damaged on the surface. The solution means is to attach and fix the corrugated iron plate (2) to the rafter (3) constituting the roof material of the house without doing so.

The rafter (3) constituting the roof of the house on the back surface of the corrugated iron plate (2) is attached to the nail (4), the bolt (5), the nut (6), the hook (7), or Pad eye (7), or long eye (7), or open pad eye (7), or eye strap (7), or UK turnbuckle (7), or L bar with nut (hereinafter abbreviated as nut, or Corrugated steel plate after fixing rafter (3) to the back of corrugated steel plate (2) using hook or eye) or other means The corrugated iron plate (2) having the solar cell (1) formed on the surface of (2) is used as a roofing material for a house and directly as a roof for a house, thereby forming a corrugated sheet shape. Solar cell (1) formed on the surface of the tin plate (2) It is possible to prevent the rainwater from entering from the surface of the corrugated stainless steel plate (2) and the solar cell (1) from peeling off from the surface of the corrugated steel plate (2). There is an effect that can be done.

In addition, the corrugated plate shape described above for the spherical silicon solar cell module whose product name is manufactured and sold by Clean Venture 21 Co., Ltd., located in Kamikoba Taichocho 35, Minami-ku, Kyoto, Japan The solar cell (2) or the corrugated steel plate (2) having a higher power generation efficiency by forming on the surface of the flat plate (2) or the flat plate (8). Alternatively, there is an effect that it can be formed on the surface of the flat-plate-like tin plate (8).

Furthermore, the corrugated iron plate (2) described above, or the tin plate (8) made of a flat plate (hereinafter, abbreviated as a tin plate or an iron plate) is constructed. A tin plate which is an iron plate inside a plating tank in which a base material of an alloy of aluminum (Al) 55% + zinc (Zn) 43.4% + silicon (Si) 1.6% is melted on the surface of the iron plate Waves that have been soaked and plated, with the name galvalume-plated (hereinafter abbreviated as "galvastar" or "ZG" as the product name manufactured and sold by Galva Steel or Nisshin Steel) On the surface on which the solar cell (1) is formed on the surface of the tin plate, on which the solar cell (1) is formed on the surface of the platinum plate (2) having a plate shape or on the surface of the tin plate (8) made of a flat plate Using nails (4) to rafters (3) that make up the roof of the house from A corrugated steel plate (2) forming a solar cell (1) in contact, or a tin plate (8) made of a flat plate using a nail (4) to a rafter (3) Even if it is struck from above, the tin plate made of galva steel plate is highly corrosion resistant and resistant to corrosion, so the solar cell (1) formed on the surface of the tin plate made of galva steel plate and corrugated plate Since the progress of peeling from the shaped tin plate (2) or the tin plate (8) made of a flat plate can be most reduced, the corrugated tin plate made of galvanized steel plate (2 The solar cell (1) is formed on the surface of). Or, if the steel plate (1) is formed on the surface of the steel plate (8) made of a flat plate, the roof of the house is constructed from the surface of the steel plate using nails (4). The rafter (3) is effective in that the tin plate can be driven directly onto the rafter (3) using the nail (4) from the surface on the surface of the tin plate.

Also, corrugated tin plate (2) suitable for uses in poultry houses, pig houses, cattle houses, and compost houses, or a corrugated steel board (8) made of flat plates (hereinafter referred to as the tin plate). For example, Nisshin Steel Co., Ltd. manufactures and sells zinc (Zn) 91% + aluminum (Al) which is excellent in ammonia resistance and wet resistance. 6% + magnesium (Mg) 1% metal on the surface of a corrugated steel plate made of corrugated plate using ZAM steel plate that has been subjected to double-bake plating in the inside of the plating tank in which the metal is melted A solar cell (1) is formed. Alternatively, when the solar cell (1) is formed on the surface of the platinum plate (8) made of a flat plate, there is an effect excellent in ammonia resistance and wet resistance.

Further, the corrugated stainless steel plate (2) is replaced with a bolt (5), a nut (6), a hook (7), a pad eye (7), a long eye (7), or an open pad eye (7). ), Or eye strap (7), or UK turnbuckle (7), or L bar with nut (hereinafter abbreviated as nut, hook or eye), or other means, By attaching the rafter (3) to the rafter (3) from the back side of the corrugated steel plate (2) to the rafter (3) constituting the roof, a nail ( 4) From the back to the rafter (3), the corrugated iron plate (2) is formed on the rafter (3) of the roofing material that constitutes the house without damaging the wounds generated by hitting. Because it is installed and fixed, corrugated tin Since the corrugated stainless steel plate (2) can be used as a roofing material without generating any scratches on the surface of (2), for example, the product name described above is the Galvaster (ZG) Steel sheet or ZAM steel sheet is used to form corrugated stainless steel sheet (2), and the service life is Nisshin Steel Sheet Co., Ltd., which manufactures and sells Galvaster (ZG) steel sheet or ZAM steel sheet Is made of corrugated corrugated iron plate (2) and flat plate that does not corrode at all for 30 to 50 years, which is 3 to 5 times the warranty period of 10 years. There is an effect that the tin plate (8) can be formed.

Corrugated stainless steel plate (2) or flat steel plate (8) made of flat plate (hereinafter referred to as corrugated stainless steel plate, tin plate, slate roof, or folded plate roof for short) ) On the surface of the solar cell (1) and the corrugated iron plate (2), or between the slate roof (2) or the folded plate roof (2), the adhesive (10) is used. The adhesive layer (10) is formed, and the solar cell (1) and the corrugated iron plate (2), the slate roof (2), or the folded plate roof (2) are joined and integrated. The utilization effect of the solar cell (1) will be described in the following (1) to (21).

As a utilization effect of (1), if the solar cell (1) is bonded and integrated using the adhesive layer (10) on the surface of the corrugated iron plate (2), the house is When it is used as a roof of a roof material that is configured, there is an effect that there is no need to form any structure necessary to attach the solar cell (1).

As a utilization effect of (2), the solar cell (1) integrated with the adhesive layer (10) interposed on the surface of the corrugated iron plate (2) has a corrugated shape. The back surface of the tin plate (2) is an air layer, and the solar cell (1) can be cooled by circulating or connecting the air in the air layer to the outside air. There is a utilization effect capable of suppressing a decrease in electrical conversion rate due to an increase in surface temperature.

As a utilization effect of (3), a solar cell integrated with the corrugated steel plate (2) by interposing an adhesive layer (10) on the surface of the corrugated steel plate (2). If it is (1), anyone who has constructed a corrugated iron plate (2) having a conventional corrugated shape, for example, a carpenter or other experienced person, can attach the solar cell (1) to a house. There is a utilization effect that can be constructed as a roof that constitutes.

As a utilization effect of (4), a solar cell integrated with a corrugated steel plate (2) by interposing an adhesive layer (10) on the surface of the corrugated steel plate (2). In the case of (1), the solar cell (1) can be constructed as a roof of a house roof material without requiring any structure necessary for constructing the solar cell (1). Therefore, the solar battery (1) can be used as a roof of a house at a very low cost. In addition, there is a utilization effect that electrical wiring is easy.

As a utilization effect of (5), the solar cell integrated with the corrugated steel plate (2) by interposing the adhesive layer (10) on the surface of the corrugated steel plate (2). When (1) is used as a roof of a roof material constituting a house, the sun integrated on the surface of a corrugated iron plate (2), which is the main purpose of the present invention When the battery (1) is constructed as a roof of a roof material, for example, a solar cell (2) is formed on the back surface of the corrugated steel plate (2) and on the surface of the corrugated steel plate (2). 1) As a pre-process before joining and integrating with an adhesive layer (10), for example, a pad eye (7) or a nut ( 7), or bolts (7), hooks (7), etc. were made into corrugated plates using arc welding etc. For example, the corrugated iron plate (2) attached to the back surface of the tongue plate (2) using a pad eye (7) or the like is used as a rafter (3) of a member constituting the house. Since corrugated iron plate (2) is installed from the back side of corrugated steel plate (2), it is compared with the conventional corrugated steel plate (2). If this is done, the corrugated stainless steel plate (2) will not be damaged at all by using nails or the like on the surface of the corrugated steel plate (2). There is no use effect.

The effect of using (6) is, in particular, the corrugated plate shape made by using Nisshin Steel Co., Ltd., which is manufactured and sold by the company, and the product name is Galvaster or ZAM. If the corrugated iron plate (2) is installed without damaging the corrugated corrugated steel plate (2) using any nails, it will take 30 to 50 years. The corrugated stainless steel plate (2) has a utilization effect that does not corrode.

As a utilization effect of (7), a solar cell (1) having the same shape as the corrugated steel plate (2) is formed on the surface of the corrugated steel plate (2). Since (1) is pasted, the appearance is very glossy, and there is a use effect that can make a beautiful roof.

As an effect of using (8), the solar cell (1) is formed on the surface of the corrugated iron plate (2) by using the adhesive layer (10) or other joining means, thereby forming the corrugated plate shape. The corrugated steel plate (2) forming the solar cell (1) on the surface of the steel plate (2) is connected to the rafter (3), which is a member constituting the house, with the bolt (5), And the nut (6), it is a construction means that is attached from the back side of the corrugated stainless steel plate (2), so that it is more resistant to wind and snow than traditionally using nails. It can be used as a roof.

As a utilization effect of (9), for the purpose of attaching the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) formed an arc welded part (13) or a metal adhesive part (13), and a nut (6) was fixed on the surface of the corrugated iron plate (2) to form a corrugated sheet By forming the tin plate (2), for example, a spherical silicon solar cell module (output 115W) manufactured and sold by Clean Venture 21 Co., Ltd., located in Kagami Toba Daimoncho 35, Minami-ku, Kyoto, As shown in FIG. 37, a spherical silicon solar cell module (output 115W) is used by using a nut (6) that is fixed on the surface of a corrugated tin plate (2). Corrugated iron plate (2 It is the use effect of the on the surface easily firmly attached it is possible.

The effect of using (10) is that, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) Arc welding part (13) or metal adhesive part (13) is formed, and after fixing nut (6) on the surface of corrugated iron plate (2), corrugated sheet An arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the shaped tin plate (2), and a pad eye (7), a long eye (7), or an open pad eye ( 7), or eye strap (7) (hereinafter abbreviated as pad eye), and the rafter (3) constituting the house from the back surface of the corrugated steel plate (2), The solar cell (1) is formed on the surface of the corrugated iron plate (2). A solar cell is formed on the surface of the corrugated steel plate (2) by attaching it to the rafter (3) constituting the house from the back surface of the corrugated steel plate (2). Even if (1) is formed, there is no need to form a special structure for attaching the solar cell (1).

The effect of using (11) is that, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, Centered on the foamed polystyrene board, which is made of a foamed polystyrene board and aluminum, with an adhesive layer (10) formed on both side surfaces, in the middle between the stainless steel plate (2) and the solar cell (1). For example, products that are manufactured and sold by JSP Co., Ltd., whose location is in 3-4-2 Marunouchi (Nisseki Building), Chiyoda-ku, Tokyo. The name is Mirapane Ace (hereinafter abbreviated as Mirapane Ace) The plywood that is made of that), hereinafter referred to as Mirapaneesu plywood (20). A corrugated iron plate (2) and a solar cell (1) interposing adhesive layers (10) formed on both sides of a plywood (20) made of this Mirapane ace plywood (20) Laminated. Further, an arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated tin plate (2) to form a pad eye (7), a long eye (7), or an open. Corrugated tin with pad eye (7) or eye strap (7) (hereinafter abbreviated as pad eye) formed on the back surface of corrugated corrugated tin plate (2) With the formation of the plate (2), even if a human freely walks on the surface of the solar cell (1) formed on the surface of the corrugated iron plate (2), it can withstand the weight of the human. It becomes the structure of the solar cell (1) that can be used. It also has a soundproofing effect. Furthermore, the solar cell (1) is laid on the surface of the corrugated iron plate (2), which has a heat resistance effect. The solar cell (1) is laid on the corrugated steel plate (2). However, no special structure is required at all, and the solar cell (in the same work process as the work process of laying the corrugated iron plate (2) as the roof of the roofing material) 1) There is a utilization effect that can be laid.

As a utilization effect of (12), for the purpose of attaching the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, Adhesive layers (10) formed on both sides of a Mirapane Ace plywood (20) made of a polystyrene foam plate and an aluminum plate, between the made tin plate (2) and the solar cell (1). ) Interposing a corrugated steel plate (2) and a solar cell (1), and fixing the corrugated steel plate (2) with a nut (6) and a bolt ( 5) and corrugated tin plate (2) and Mirapane Ace plywood ( 0) and corrugated tin plate (2) are combined to form an arc welded portion (13) or metal adhesive portion (13) on the back surface of corrugated tin plate (2). Then, using a pad eye (7), a long eye (7), an open pad eye (7), or an eye strap (7) (hereinafter referred to as a pad eye for short), a corrugated plate shape was formed. Corrugated corrugated sheet (2) by forming corrugated corrugated sheet (2) that can be attached to rafters (3) constituting the house from the back of corrugated sheet (2) Even if a human walks freely on the surface of the solar cell (1) formed on the surface of the solar cell (1), the structure of the solar cell (1) can withstand the weight of the human. It also has a soundproofing effect. Further, the solar cell (1) is formed on the surface of the corrugated iron plate (2) having a heat resistance effect. The solar cell (1) is installed because it is the corrugated steel plate (2). However, there is no need for any special structure, and the solar cell (with the same work process as the work process of installing the corrugated iron plate (2) as the roof of the roofing material) 1) There is a utilization effect that can be laid.

As a utilization effect of (13), when the corrugated steel plate (2) is used as the roof of a house and the corrugated steel plate (2) is currently used, The corrugated steel plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2) described above is currently used as a roof of a house. A corrugated steel plate (2) is formed by forming a hole in the corrugated steel plate (2) constituting the roof of the house from the surface of the steel plate (2) having a plate shape. In order to firmly fix the corrugated iron plate (2) formed on the surface of the solar cell (1) to the rafter (3) constituting the house through the corrugated plate, Pad eye (7), long eye (7), or open pad attached to the back of the tin plate (2) Using the eye (7) or eye strap (7) (hereinafter abbreviated as pad eye), bolt (5), nut (6), or L rod with nut, When the corrugated steel plate (2) forming the solar cell (1) is overlapped and overlapped from the surface of the corrugated steel plate (2) used as a roof There is an effect that the solar cell (1) can be attached more easily.

The effect of (14) is conventionally made of a tile roof as a roof material of a house, a roof of a slate roof material made of cement, or a roof of a roof material made of other artificial thin plates. The roof of the house (hereinafter abbreviated as a tiled roof) has a corrugated shape in which the solar cell (1) is formed on the surface of the corrugated iron plate (2) described above. When installing the tin plate (2), similar to the contents explained above, a house is constructed by forming a hole in the tile roof tile that constitutes the roof of the house and penetrating the tile. In order to fix the corrugated steel plate (2) on which the solar cell (1) is formed on the surface of the rafter (3), the back surface of the corrugated steel plate (2) Pad eye (7), long eye (7), or open pad eye (7) , Or eye strap (7) (hereinafter abbreviated as pad eye), bolt (5), nut (6), or L rod with nut, etc. The tiled roof or slate currently used for the corrugated iron plate (2) forming the solar cell (1) from the surface used as the tiled roof or slate roof. When the installation is done by firmly overlapping and fixing on the roof surface made of the above, the corrugated steel plate (2) currently used as the roof of the house as described above ), The solar cell (1) is more easily arranged on the surface of the roof tile, similarly to the case where the corrugated iron plate (2) forming the solar cell (1) is installed on the surface of the roof tile, Or firmly fix it on the surface of the roof made of slate. It may use effect that can be.

The effect of using (15) is that, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap ( ) (Hereinafter abbreviated as pad eye), the roof of the house is attached to the rafter (3) constituting the house on the back surface of the corrugated steel board (2). A hole (22) is formed in the constituting roof tile (21), and a pad eye (7) attached on the back surface of the corrugated steel plate (2) and an n-shaped nut at the tip portion Using the L-shaped rod (14) with a nut having an n-shaped tip, the L-shaped rod (14) is passed through the hole (22) formed in the roof tile (21). The rafter (3) is composed of a solar cell (1) on the surface of the corrugated tin plate (2) and a soundproofing effect on the back surface of the corrugated tin plate (2). Or, for the purpose of improving the heat insulation effect or the adhesion to the roof tile (21), both sides are flat, or one side is flat. Corrugated steel board (2 The corrugated iron plate (2) forming the solar cell (1) on the surface of) is firmly attached to the rafters (3) constituting the house and is made of roof tiles (21). On the surface of the roof, there is a utilization effect capable of forming the corrugated steel plate (2) forming the solar cell (1) on the surface of the corrugated steel plate (2). .

The effect of using (16) is that, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap ( ) (Hereinafter abbreviated as pad eye), the roof of the house is attached to the rafter (3) constituting the house on the back surface of the corrugated steel board (2). A hole (22) is formed in the constituting roof tile (21), and a pad eye (7) attached on the back surface of the corrugated steel plate (2) and an n-shaped nut at the tip portion Using the L-shaped rod (14) with a nut having an n-shaped tip, the L-shaped rod (14) is passed through the hole (22) formed in the roof tile (21). The rafter (3) is composed of a solar cell (1) on the surface of the corrugated tin plate (2) and a soundproofing effect on the back surface of the corrugated tin plate (2). Or, for the purpose of improving the heat insulation effect or the adhesion to the roof tile (21), one side is corrugated and the other side is flat. Alternatively, the surface of the corrugated steel plate (2), which is used as a roof tile tile, with a sandwiched polystyrene foam plate (9) having a shape similar to that of the tile, intervening in the middle The surface of the roof made of tiles (21) with the corrugated iron plate (2) forming the solar cell (1) on it firmly attached to the rafters (3) constituting the house On top of this, there is a utilization effect capable of forming the corrugated tin plate (2) forming the solar cell (1) on the surface of the corrugated tin plate (2).

The effect of (17) is that, for the purpose of mounting the solar cell (1) on the surface of the flat plate (8) made of a flat plate, a nut ( 6) After forming the arc welding part (13) or metal adhesive part (13) and fixing the nut (6) on the surface of the flat plate (8) made of flat plate, A plywood plate (20) made of a polystyrene foam plate and a plate made of aluminum is formed between an aluminum plate (8) and a solar cell (1) with an adhesive layer (10) interposed therebetween. Then, after laminating, an arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the flat plate (8) made of a flat plate, and a pad eye (7), or Long eye (7) or open pad eye (7) or ice Using a wrap (7) (hereinafter abbreviated as pad eye), the rafter (3) constituting the house is mounted on the back surface of the flat board (8) made of flat plate. A hole (22) is formed in the tile (21) constituting the roof, and the pad eye (7) attached on the back surface of the flat plate (8) made of a flat plate and the tip portion are n-shaped. Using the L-shaped rod (14) with a nut, the inside of the hole (22) formed in the roof tile (21) is passed through the nut (14) with a nut, and the tip is n-shaped. The rafters (3) constituting the house, the solar cell (1) on the surface of the steel plate (8) made of a flat plate, and the back surface of the steel plate (8) made of a flat plate For the purpose of enhancing the soundproofing effect, the heat insulating effect, or the adhesion to the roof tile (21), both side surfaces are flat plate shapes or pieces Is a flat plate shape, and the other side is used as a roof tile tile. A styrofoam plate (11) having a shape similar to the tile shape is interposed in the middle of the sandwich shape, and the flat plate shape is changed. The tin plate (8) made of a flat plate, which forms the solar cell (1) on the surface of the made tin plate (8), is firmly attached to the rafter (3) constituting the house and the roof tile (21 ) On the surface of the roof made of flat plate, and on the surface of the steel plate made of flat plate (8) forming the solar cell (1) on the surface of the flat plate made of flat plate (8). There is an advantage that the tin plate (8) made of the flat plate forming the battery (1) can be formed.

As a utilization effect of (18), for the purpose of attaching the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A laminated board (20) made of a foamed polystyrene board and a board made of aluminum foil is interposed between the made tin plate (2) and the solar battery (1) with an adhesive layer (10) interposed. After forming and laminating, an arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7). , Or long eye (7), or open pad eye (7), or eye strap 7) The roof of the house is used to attach the rafters (3) constituting the house on the back surface of the corrugated steel board (2) using (hereinafter abbreviated as pad eye). A hole (22) is formed in the roof tile (21) forming the pad eye (7) attached to the back surface of the corrugated stainless steel plate (2) and the tip portion has an n-shape. By using the L rod (14) with a nut having an n-shaped tip, the L rod (14) with a nut is passed through the hole (22) formed in the roof tile (21). The rafter (3) constituting the corrugated iron plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2) is formed on the rafter (3). A corrugated plate is formed by penetrating the inside of the hole (22) formed in the roof tile (21) with the L-shaped rod with nut (14) having a shape. When the iron plate (2) is attached and fixed to the rafters (3) constituting the house, the rainwater leaks from the holes (22) formed in the roof tile (21), and rainwater enters the interior of the house. In order to prevent intrusion, the roof tile (21) is formed by combining a structure having a long cylindrical shape (23) of about 5 cm from the surface of the roof tile (21) with the roof tile (21). Is used to fix the corrugated iron plate (2) using an L-shaped rod (14) with a nut whose tip is n-shaped. Furthermore, the nut-attached L rod (14) whose tip portion penetrating the inside of the cylindrical shape (23) is an n-shape is a sealant (24) inside the cylindrical shape (23), for example, Using an adhesive made of silicone resin or the like, the inside of the cylindrical shape (23) formed on the roof tile (21) united with the roof tile (21) is sealed with the sealant (24). Is used to prevent rainwater from leaking into the house from the hole (22) formed in the roof tile (21). Alternatively, the packing (24) made of silicone resin or the like is inserted into the cylindrical shape (23) instead of the sealant (24), and the L-rod with nut (14) having an n-shaped tip portion. ) Is formed in the roof tile (21) by being sealed inside the cylindrical shape (23) formed in the roof tile (21) which is integrated with the roof tile (21). The roof tile (21) having a structure capable of preventing the rainwater from leaking into the house from the hole (22) and the cylindrical shape (23) are combined to form the roof tile (21) as an integral structure. There is a use effect that can be done.

As the utilization effect of (19), as shown in FIG. 73 and FIG. 74, the solar cell (1) manufacturing company is on the surface of the folded plate roof (2) or the slate roof (2). . For example, a solar cell (1) manufactured and sold by UNI-SOLAR, whose headquarters is located in the United States, is made of stainless steel with a thickness of 0.5 mm made of stainless steel on the base. It is a three-layer type composed of amorphous silicon and silicon germanium on the surface of the plate thickness. Moreover, the solar cell (1) of UNI-SOLA is a flexible type and flexible. Further, an adhesive layer (10) having a strong adhesive effect is formed on the back surface of the stainless steel plate as the base. The surface of the solar cell (1) manufactured by UNI-SOLAR, whose base is made of stainless steel plate, is a folded plate roof (2) or a slate roof (2) (hereinafter referred to as a folded plate roof). On the top, for example, a solar cell (1) manufactured by UNI-SOLAR is directly pasted in parallel to the ridge on the surface of the folded roof (2) parallel to the ridge which is the peak of the house. In addition, when the solar cell (1) made by UNI-SOLAR is directly pasted at a right angle in the vertical direction on the surface of the folded roof (2) at a right angle in the vertical direction with respect to the ridge which is the peak of the house, On the surface of the folded plate roof (2) using the adhesive layer (10) formed on the back surface of the stainless steel plate constituting the base of the solar cell (1) made by UNI-SOLA The solar cell (1) manufactured by UNI-SOLA can be bonded and bonded firmly.

As the utilization effect of (20), as shown in FIG. 73 and FIG. 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter referred to as the folded plate roof). Furthermore, the base made by UNI-SOLA is made of a stainless steel plate with a thickness of 0.5 mm made of stainless steel. The width is about 1 m and the length direction can be cut freely. A long solar cell (1) made by UNI-SOLA on the surface of the folded roof (2) or slate roof (2), and the back of the base of the solar cell (1) made by UNI-SOLAR On the surface of the folded roof (2) or the slate roof (2) with the adhesive layer (10) formed on the surface, a solar cell (1) manufactured by UNI-SOLAR Co., Ltd. 1) Folding plate shop with an adhesive layer (10) formed on the back surface of the base When directly sticking on the surface of the root (2) or the slate roof (2), the solar cell (1) made by UNI-SOLAR is a long solar cell (1). Since the solar cell (1) is directly pasted and the surface tension becomes strong, the surface of the solar cell (1) manufactured by UNI-SOLAR is the folded plate roof (2) or the slate roof (2). There is a utilization effect that can withstand a heavy load that allows a human to walk freely on the surface directly pasted on.

As the utilization effect of (21), as shown in FIGS. 73 and 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter referred to as folded plate roof). In addition, a UNI-SOLA solar cell (1) made of stainless steel with a thickness of 0.5 mm and made of stainless steel is folded on the roof. (2) Or on the surface of the slate roof (2), an adhesive layer (10) formed on the back surface of the base of the solar cell (1) manufactured by UNI-SOLAR is interposed, and the folded plate roof ( 2) When a solar cell (1) made by UNI-SOLAR is directly pasted on the surface of the slate roof (2), there is no need for any structure necessary for installing the solar cell (1). Because there is no, the solar cell (1), the house is constructed at an extremely low cost Effect of installing a solar cell (1) made by UNI-SOLAR at a very low cost on the surface of the folded roof (2) or the slate roof (2), which is a roofing material. There is.

In addition, after decades of asbestos slate 26, the conventional strength has become extremely weak for the purpose of repairing work by reinforcing the strength of asbestos slate 26, which becomes fragile and becomes dangerous. Walking with asbestos slate 26, for example using asbestos slate 26, over asbestos slate 26 on the surface of a factory or warehouse roof that is decades old, Since the strength of the asbestos slate 26 after 10 years has become weak, first, it is very dangerous to walk on the old asbestos slate 26. Secondly, when asbestos slate 26 made of the main raw material of asbestos is disassembled, asbestos with carcinogenic properties is scattered, and asbestos slate 26 that has become old easily can be easily disassembled. The current situation is not possible. However, polystyrene is the main raw material used for the construction method to reinforce the strength of the roofs of factories or warehouses that are made of asbestos slate 26 that leaks rain and becomes safe. The foam ratio is low, and the foam polystyrene is very low, for example, the expansion ratio is 10 times or less, or the expansion ratio is 20 times or less, or the expansion ratio is 25 times or less, or the expansion ratio is 30 times or less, or the expansion ratio Is made of a polystyrene foam having a foaming ratio of 35 times or less, or a foaming ratio of 50 times or less (hereinafter abbreviated to be a foaming ratio of 25 times or less). One side of the foamed polystyrene 27, or both sides of the polystyrene foam 28, or one side of the asbestos slate 26 shaped foam. An old asbestos that forms a roof of a factory or warehouse that has been leaking for several decades, using a foamed polystyrene 29 having the shape of a slate roof 25 on the other side of the roll. A construction method for reinforcing the strength of the slate 26 and performing repair work safely will be described in the following (1) to (9).

(1) As shown in FIG. 76, the asbestos slate 26 has been used for repair work by reinforcing the strength of the dangerous asbestos slate 26 that has become fragile and old after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene plate made of a foamed polystyrene plate having a width of 685 mm. The foamed polystyrene plate 27 is a foamed polystyrene 27 in which the shape of one side is the shape of an asbestos slate 26 and the shape of the other side is a flat plate shape. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a human can freely walk on the surface of the asbestos slate 26. The asbestos slate 26 has a load that can withstand the load of human beings, exceeding the limit that it can withstand.

(2) As shown in FIG. 77, the asbestos slate 26 has been used for repair work by strengthening the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene board made of a foamed polystyrene board with a width of 685 mm, and a foamed polystyrene board 28 having a flat plate shape on both sides, is spread on the surface of the asbestos slate 26 and laminated on the surface of the asbestos slate 26. Thus, the load of the asbestos slate 26 can withstand the human load, for example, the load of the asbestos slate 26 that exceeds the limit that the human can freely walk on the surface of the asbestos slate 26. There exists an effect which can be set as a structure.

(3) As shown in FIG. 78, the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes obsolete after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene board made of foamed polystyrene board with a width of 685 mm, the foamed polystyrene board having the shape of asbestos slate 26 on one side and the foamed polystyrene 29 having the slate roof shape on the other side, The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. However, there is an effect that the load of the asbestos slate 26 exceeding the limit that can be endured can be a structure that can withstand the human load.

As for (4), as shown in FIG. 79, the asbestos slate 26 has been used for repair work by strengthening the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene board made of foamed polystyrene board with a width of 685 mm, the foamed polystyrene board having the shape of asbestos slate 26 on one side and the foamed polystyrene 29 having the slate roof shape on the other side, The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure that can withstand the load of human beings, the load of the asbestos slate 26 is over the surface of the polystyrene foam 29, and the slate roof 25 is stacked on top of each other to form a rafter 3, asbestos. Four types of panels, slate 26, styrofoam 29, and slate roof 25, are constructed using bolts 5 and nuts 6. Slate roof 25 a slate roof 25 to rafter 3 is a roofing material attached to the laminate from above and below by and, consequently, with intervening expanded polystyrene 29, the effect of that can be fixed to the asbestos slate 26.

(5) As shown in FIG. 80, the asbestos slate 26 has been used for repair work by strengthening the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene plate made of a foamed polystyrene plate having a width of 685 mm, a foamed polystyrene plate 29 having one side of the shape of asbestos slate 26, and the other side of the foamed polystyrene 29 having a slate roof shape, The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure that can withstand the load of human beings, the load of the asbestos slate 26 is over the surface of the polystyrene foam 29, and the slate roof 25 is stacked on top of each other to form a rafter 3, asbestos. Four types of panels, a slate 26, a polystyrene foam 29, and a slate roof 25, are provided with a pad eye 7 and an n-shaped naval tip. As a result, the slate roof 25 attached by laminating the slate roof 25 from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material constituting the house, using the L-shaped rod 14 There is an effect that the styrofoam 29 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26.

(6) As shown in FIG. 81, the asbestos slate 26 has been used for repair work by strengthening the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. On the surface of the asbestos slate 26, the foamed polystyrene plate made of a polystyrene foam plate having a width of 685 mm is laminated on the surface of the asbestos slate 26 by laminating and laminating the polystyrene foam 28 having both sides flat. For example, the polystyrene foam after the asbestos slate 26 has a structure capable of withstanding the load of the asbestos slate 26, which is more than the limit that the human can freely walk on the surface of the asbestos slate 26. On the surface of 28, the slate roof 25 is stacked and laminated, and four types of panels of rafters 3, asbestos slate 26, styrofoam 28, and slate roof 25 are formed, pad eye 7 and the tip part are n-shaped. The slate roof 25 is stacked from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material constituting the house, using the L bar 14 with a nut. As a result, the slate roof 25 attached in a laminated manner is placed on the surface of the slate roof 25 after the foamed polystyrene 28 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26. There is an effect that the solar cell 1 can be fixed on the surface of the slate roof 25 by using the nut 6, the pad eye 7, and the bolt 5.

As for (7), as shown in FIG. 82, the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene plate made of a foamed polystyrene plate having a width of 685 mm. The foamed polystyrene plate 27 is a foamed polystyrene 27 in which the shape of one side is the shape of an asbestos slate 26 and the shape of the other side is a flat plate shape. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a human can freely walk on the surface of the asbestos slate 26. The asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, and the slate roof 25 is stacked on the surface of the polystyrene foam 27, and the rafter 3, Four types of panels, asbestos slate 26, styrofoam 27, and slate roof 25, are provided with pad eyes 7 and naps that have an n-shaped tip. Using the attached L bar 14, the slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 which is the roof material constituting the house from above and below, and as a result, the polystyrene foam 27 is replaced with the asbestos slate 26. And the slate roof 25, and the solar cell 1 is attached to the slate roof using the nut 6, the pad eye 7 and the bolt 5 on the surface of the slate roof 25 after being fixed to the asbestos slate 26. There exists an effect which can be attached and fixed on the surface of 25.

As for (8), what is shown in FIG. 83 is that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes older after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. The shape of the slate roof 25 is made of a polystyrene foam plate having a width of 685 mm. The styrofoam 29 having the above structure is laid and stacked on the surface of the asbestos slate 26, and a load that can be sustained on the surface of the asbestos slate 26 is applied, for example, on the surface of the asbestos slate 26. The slate roof 25 is placed on the surface of the polystyrene foam 29 after the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the weight of the human being, which is more than the limit that a human can walk freely. Laminated, four types of panels, rafter 3, asbestos slate 26, styrofoam 29, and slate roof 25, are pad eye 7 And using the L rod 14 with a nut whose tip portion is n-shaped, the slate roof 25 is stacked from above and below from the lower surface which is the back surface of the rafter 3 which is the roof material constituting the house. As a result, the slate roof 25 is fixed to the asbestos slate 26 by interposing the polystyrene foam 29 between the asbestos slate 26 and the slate roof 25, and the nut 6 on the surface of the slate roof 25. There is an effect that the solar cell 1 can be fixed on the surface of the slate roof 25 by using the pad eye 7 and the bolt 5.

As for (9), what is shown in FIG. 84 is the purpose of repairing the asbestos slate 26 by strengthening the strength of the dangerous asbestos slate 26 that has become old and brittle after several decades. The asbestos slate 26 described above with reference to FIG. 75, which is an asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by solidifying asbestos with cement, is used as a roofing material for a house. On the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface of the rafter 3 constituting, for example, a thickness of about 10 cm, When using iron plate small waves as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using iron plate large waves as the roofing material, the working width is 685 mm. A foamed polystyrene plate having the shape of a slate roof 25 in which the shape of a foamed polystyrene plate made of a foamed polystyrene plate having a width of 685 mm is a foamed polystyrene 30 having a flat shape on one side and a slate roof 25 on the other side. 30 is laid on the surface of the asbestos slate 26 and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26 is applied, for example, on the surface of the asbestos slate 26. The asbestos slate 26 has a structure that can withstand the weight of human beings, and the slate roof 25 is stacked on the surface of the polystyrene foam 30 after the asbestos slate 26 has a structure that can withstand the load of human weight. 4 types of panels, rafter 3, asbestos slate 26, polystyrene foam 30 and slate roof 25, pad eye 7 and tip portion A slate that is attached by stacking slate roofs 25 from above and below from the bottom surface of the rafter 3 that is the roof material constituting the house, using an L-shaped nut 14 with an n-shape. After the roof 25 is fixed to the asbestos slate 26 by interposing the polystyrene foam 30 between the asbestos slate 26 and the slate roof 25, the nut 6 and the pad eye 7, In addition, the solar battery 1 can be mounted and fixed on the surface of the slate roof 25 using the bolts 5 and bolts 5.

FIG. 85 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the dangerous asbestos slate 26 after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. The foamed polystyrene plate is made of a foamed polystyrene plate of 685 mm. The foamed polystyrene plate 27 is a foamed polystyrene 27 having a flat shape on one side and the slate roof 25 on the other side. On the surface of the asbestos slate 26, the layers are laid and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, is free After assembling a structure in which the load of the asbestos slate 26 that can withstand the load of human weight is more than the limit that can be tolerated by walking, the slate roof 25 is stacked on the surface of the polystyrene foam 27, and laminated. Four types of panels, rafters 3, asbestos slate 26, polystyrene foam 27, and slate roof 25, are used with bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roof material constituting the house and stacked, and as a result, the polystyrene foam 27 is placed between the asbestos slate 26 and the slate roof 25. The solar cell 1 is fixed on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. There is an effect that can be done.

FIG. 86 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. On the surface of the asbestos slate 26, the layers are laid and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, can be freely After assembling a structure in which the load of the asbestos slate 26 that can withstand the load of human weight is more than the limit that can be tolerated by walking, the slate roof 25 is stacked on the surface of the polystyrene foam 30 and laminated. Four types of panels, rafter 3, asbestos slate 26, styrofoam 30 and slate roof 25, are used with bolt 5 and nut 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 which is the roof material constituting the house is stacked, and as a result, the polystyrene foam 30 is placed between the asbestos slate 26 and the slate roof 25. The solar cell 1 is fixed on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. There is an effect that can be done.

FIG. 87 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. The foamed polystyrene plate has a foamed polystyrene 27 in which one side has the shape of asbestos slate 26 and the other one side has a flat plate shape. The surface of the asbestos slate 26 is laid on top of the surface of the asbestos slate 26 and laminated to withstand the load that can be withstood on the surface of the asbestos slate 26, for example, even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 that can exceed the maximum possible load can withstand the weight of human beings is formed, and the slate roof 25 is stacked on the surface of the polystyrene foam 27, and the rafter 3 and asbestos slate are stacked. 26, styrofoam 27, and slate roof 25 are used to construct a house using bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 that is the roof material is stacked, and as a result, the polystyrene foam 27 is interposed between the asbestos slate 26 and the slate roof 25, and the asbestos slate. 26, on the surface of the slate roof 25, and further on the surface of the expanded polystyrene 28 after laminating the expanded polystyrene 28 having a flat plate shape on both sides. In the upper Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) is manufactured and sold. The solar cell (1) is placed on the surface of the polystyrene foam 28 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the polystyrene foam 28. There is an effect that can be attached and fixed.

FIG. 88 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by strengthening the strength of the asbestos slate 26 which has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a foamed polystyrene board of 685 mm, and the foamed polystyrene board is laminated on the surface of the asbestos slate 26 by laminating and stacking the foamed polystyrene 28 having both sides flat on the surface of the asbestos slate 26. Of the expanded polystyrene 28 after the load of the asbestos slate 26 is made a structure that can withstand the load of human beings, for example, exceeding the limit that a human can freely walk on the surface of the asbestos slate 26. A slate roof 25 is stacked on the surface and laminated, and four types of panels, rafters 3, asbestos slate 26, polystyrene foam 28, and slate roof 25, are constructed using bolts 5 and nuts 6. As a result, the slate roof 25 in which the slate roof 25 is attached to the rafter 3 which is the roofing material by overlapping the layers from above and below is laminated. After the roll 28 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26, a foamed polystyrene 28 having a flat plate shape on both sides is further formed on the surface of the slate roof 25. After the lamination, on the surface of the polystyrene foam 28, for example, the location is Kami Toba Taichocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21), and manufactures and sells it. The solar cell (1) having the product name spherical silicon solar cell lightweight module is placed on the surface of the foamed polystyrene 28 using the nut 6, the pad eye 7 and the bolt 5 on the surface of the foamed polystyrene 28. There is an effect that can be attached and fixed.

FIG. 89 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape, and the other side has a slate roof 25 with the shape of the slate roof 25. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. , Asbestos slate 26, styrofoam 30, and slate roof 25, using bolts 5 and nuts 6 to construct the house. The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 which is the roofing material being stacked, and as a result, the polystyrene foam 30 is interposed between the asbestos slate 26 and the slate roof 25. On the surface of the slate roof 25 after being fixed to the asbestos slate 26, the shape of the slate roof 25 is a foamed polystyrene 30 having a flat shape on one side and the slate roof 25 on the other side. On the surface of the expanded polystyrene 30, for example, the location is Kamitoba Daichocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21), which manufactures and sells. A solar cell (1) having a product name of a spherical silicon solar cell light-weight module, a nut 6, a pad eye 7, and There exists an effect which can attach and fix a solar cell (1) on the surface of the polystyrene foam 30 using the volt | bolt 5. FIG.

FIG. 90 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 which has become fragile and becomes obsolete after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape, and the other side has a slate roof 25 with the shape of the slate roof 25. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. , Asbestos slate 26, styrofoam 30, and slate roof 25, using bolts 5 and nuts 6 to construct the house. The slate roof 25 in which the slate roof 25 is stacked from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material, is attached, and as a result, the polystyrene foam 30 is replaced with the asbestos slate 26 and the slate roof 25. On the surface of the slate roof 25 after being fixed to the asbestos slate 26, and further on the surface of the polystyrene foam 28 having a flat plate shape on both sides. In the city of Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) manufactures and sells, and the product name is a spherical silicon solar cell lightweight module solar cell (1). The solar cell (1) is mounted on the surface of the foamed polystyrene 28 using the nut 6, the pad eye 7 and the bolt 5 on the surface of the foamed polystyrene 28. There is an effect that can be fixed.

FIG. 91 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes fragile after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. The shape of the expanded polystyrene plate is made of a expanded polystyrene plate of 685 mm. The expanded polystyrene plate 29 has the shape of asbestos slate 26 on one side and the slate roof 25 in the shape of the other side. Styrofoam 29 is laid on the surface of the asbestos slate 26 and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, Laminate the slate roof 25 on the surface of the polystyrene foam 29 after the asbestos slate 26 has a structure capable of withstanding the load of human weight, which is more than the limit that a human can withstand walking freely. The four types of panels, rafter 3, asbestos slate 26, styrene foam 29, and slate roof 25, are connected to bolt 5 and The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roofing material constituting the house from the top and bottom, and as a result, the polystyrene foam 29 is replaced with the asbestos slate 26 and the slate. On the surface of the slate roof 25 after interposing it in the middle with the roof 25 and fixing it to the asbestos slate 26, a foamed polystyrene 30 having a flat plate shape on one side, and the shape on the other side is On the surface of the foamed polystyrene 30 in the shape of the slate roof 25 of the slate roof 25, for example, the location is Kami Toba Daimonocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21). The solar cell (1) having a product name of a spherical silicon solar cell lightweight module is manufactured and sold on the surface of the polystyrene foam 30. There is an effect that the solar cell (1) can be attached and fixed on the surface of the polystyrene foam 30 using the pad 6, the pad eye 7, and the bolt 5.

FIG. 92 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. The polystyrene foam plate 29 is made of foamed polystyrene 29 having one side of the shape of asbestos slate 26 and the other side of the polystyrene foam 29 having a corrugated plate shape. On the surface of the asbestos slate 26, it is laid down and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26 can be applied. A structure in which the load of the asbestos slate 26 that can withstand the weight of the human being exceeds the limit that can be withstood by the weight of human beings is formed, and the slate roof 25 is stacked on the surface of the polystyrene foam 29 to laminate the rafter 3, asbestos. Four types of panels, slate 26, styrofoam 27, and slate roof 25, are configured using bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 that is the roof material is stacked, and as a result, the polystyrene foam 27 is interposed between the asbestos slate 26 and the slate roof 25, and the asbestos slate. 26, on the surface of the slate roof 25, and further on the surface of the expanded polystyrene 28 after laminating the expanded polystyrene 28 having a flat plate shape on both sides. In the upper Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) is manufactured and sold. The solar cell (1) is placed on the surface of the polystyrene foam 28 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the polystyrene foam 28. There is an effect that can be attached and fixed.

93 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25 and the steel plate large wave 25 in which the nut 6 is attached on the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 4, after fixing the iron plate large wave 25 to the rafter 3, on the surface of the iron plate large wave 25, one side of the shape is a polystyrene foam 27 having the shape of the iron plate large wave 25. After the laminated polystyrene 27 having a flat plate shape is stacked and laminated, the solar cell 1 manufactured and sold by the company name CV21 is further laminated and laminated on the surface of the foamed polystyrene 27. Solid on the surface of Using the nut 6, the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 panel 3 using the bolt 5 and the nut 6, the solar cell 1 is attached to the rafter 3 as a result. ing. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

94 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25 and the steel plate large wave 25 in which the nut 6 is attached on the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 The surface of the foamed polystyrene 28 after laminating and stacking the foamed polystyrene 28 having a flat plate shape on both sides of the surface of the steel plate large wave 25 after the steel plate large wave 25 is fixed to the rafters 3 Further, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the nut 6 is fixed on the surface of the iron plate large wave 25 and the solar cell is used. 1, polystyrene foam 28, and Bolt 5 3 panels plate billows 25, and using a nut 6, as a result, have installed a solar cell 1 to the rafters 3. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 28, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

95 shows, for example, that the welded portion 13 of the nut 6 is formed on the surface of the iron plate large wave 25, and the iron plate large wave 25 attached to the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 4, after fixing the iron plate large wave 25 to the rafter 3, on the surface of the iron plate large wave 25, one side of the shape is a polystyrene foam 27 having the shape of the iron plate large wave 25. After the laminated polystyrene 27 having a flat plate shape is stacked and laminated, the solar cell 1 manufactured and sold by the company name CV21 is further laminated and laminated on the surface of the expanded polystyrene 27, and then the iron plate large wave 25 Solid on the surface of Using the nut 6, the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 panel 3 using the bolt 5 and the nut 6, the solar cell 1 is attached to the rafter 3 as a result. ing. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

FIG. 96 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25, and the iron plate large wave 25 attached to the nut 6 on the surface of the iron plate large wave 25 is the C steel 3. Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 The surface of the foamed polystyrene 28 after laminating and stacking the foamed polystyrene 28 having a flat plate shape on both sides of the surface of the steel plate large wave 25 after the steel plate large wave 25 is fixed to the rafters 3 Further, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the nut 6 is fixed on the surface of the iron plate large wave 25 and the solar cell is used. 1, polystyrene foam 28, and Bolt 5 3 panels plate billows 25, and using a nut 6, as a result, have installed a solar cell 1 to the rafters 3. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 28, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

What is shown in FIG. 97 is, for example, for the purpose of attaching to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as rafter) from the back surface of the iron plate large wave 25,
The pad eye 7 is formed on the back surface of the iron plate large wave 25, the welded portion 13 is formed, the pad eye 7 is attached on the back surface of the iron plate large wave 25, and further on the surface of the iron plate large wave 25 that fixes the pad eye 7. The welded portion 13 is formed on the surface of the iron plate large wave 25 and the bolt 5 is attached and fixed on the surface of the iron plate large wave 25. The shape of one side is an iron plate on the surface of the iron plate large wave 25. After the expanded polystyrene 27 having the shape of a large wave 25 and the other side of the expanded polystyrene 27 having a flat plate shape laminated on the surface of the large steel plate 25, for example, the company name CV21 is manufactured and sold. After stacking the solar cells 1, the three panels of the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 are attached using the bolts 5 fixed on the surface of the iron plate large wave 25. Belt 5, and the lamination by pressure bonding using a nut 6. As a result, the pad eye 7 is attached on the back surface of the iron plate large wave 25 with the iron plate large wave 25 attached with the solar cell 1 and fixed by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1. , A roof material that constitutes a roof by attaching to C steel 3, wood purlin 3, or rafter 3 (hereinafter, abbreviated as rafter), and iron plate large wave 25 that is a roof material and solar cell 1 It is an extremely light composite roofing material 32 in which the two are integrated. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

What is shown in FIG. 98 is, for example, for the purpose of attaching to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as rafter) from the back side of the iron plate large wave 25,
The weld 6 is formed on the back surface of the iron plate large wave 25, the nut 6 is attached to the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 fixing the nut 6. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the bolt 5 is attached and fixed on the surface of the iron plate large wave 25. After the foamed polystyrene 27 having the shape of the other side is stacked on the surface of the iron plate large wave 25, the other one side of the foamed polystyrene 27 is laminated, and then, for example, the company name CV21 is manufactured and sold After stacking the batteries 1, the bolts 5 fixed on the surface of the iron plate large wave 25 are used to connect the three panels of the solar cell 1, the polystyrene 27 and the iron plate large wave 25 to the bolt 5, and so on. It is crimped by using the nut 6 to a stacked. As a result, the nut 6 which attached the iron plate large wave 25 which has fixed and fixed the solar cell 1 by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1 on the back surface of the iron plate large wave 25 is provided. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

99, for example, for the purpose of attaching to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as rafter) from the back side of the iron plate large wave 25,
The weld 6 is formed on the back surface of the iron plate large wave 25, the nut 6 is attached to the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 fixing the nut 6. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the bolt 5 is attached to the surface of the iron plate large wave 25 to fix the Mirapane Ace 20 on the surface of the iron plate large wave 25. After stacking on top of each other, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the bolt 5 fixed on the surface of the iron plate large wave 25 is used. Then, the three panels of the solar cell 1, the mirror panel ace 20, and the iron plate large wave 25 are bonded using the bolts 5 and the nuts 6 and laminated. As a result, the iron plate large wave 25 attached with the solar cell 1 is fixed with the Mirapane Ace 20 interposed between the iron plate large wave 25 and the solar cell 1, and the nut 6 attached on the back surface of the iron plate large wave 25 is attached. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1, and the iron plate large wave 25, the mirror panel ace 20, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

FIG. 100 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back side of the iron plate large wave 25. The pad eye 7 is formed on the back surface of the steel plate, the welded portion 13 is formed, the pad eye 7 is mounted on the back surface of the iron plate large wave 25, and the nut 6 is further formed on the surface of the iron plate large wave 25 fixing the pad eye 7. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the nut 6 is attached and fixed on the surface of the iron plate large wave 25. After the foamed polystyrene 27 having the shape of the other side is stacked on the surface of the iron plate large wave 25, the other one side of the foamed polystyrene 27 is laminated, and then, for example, the company name CV21 is manufactured and sold Electric After stacking 1 and laminating, using the nut 6 fixed on the surface of the iron plate large wave 25, the three panels of the solar cell 1, the polystyrene 27 and the iron plate large wave 25 are connected to the bolt 5 and the nut. 6 is used for pressure bonding. As a result, the pad eye 7 is attached on the back surface of the iron plate large wave 25 with the iron plate large wave 25 attached with the solar cell 1 and fixed by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1. , A roof material that constitutes a roof by attaching to C steel 3, wood purlin 3, or rafter 3 (hereinafter, abbreviated as rafter), and iron plate large wave 25 that is a roof material and solar cell 1 It is an extremely light composite roofing material 32 in which the two are integrated. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

101 shows, for example, an iron plate large wave 25 for the purpose of attaching to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back side of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is mounted on the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. A welded portion 13 is formed on the surface of the steel plate 25, and bolts 5 are attached and fixed on the surface of the steel plate large wave 25. On the surface of the steel plate large wave 25, a polystyrene foam 28 having a flat plate shape on both sides is provided. After stacking, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the bolt 5 fixed on the surface of the iron plate large wave 25 is used. , Solar cell 1, Foam The three panels of the roll 28, and the iron plate billows 25 bolt 5, and the lamination by pressure bonding using a nut 6. As a result, the nut 6 which attached the iron plate large wave 25 which has fixed the solar cell 1 by interposing the polystyrene foam 28 between the iron plate large wave 25 and the solar cell 1 is attached on the back surface of the iron plate large wave 25. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 28, and the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

102 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, the wood purlin 3, or the rafter 3 (hereinafter, abbreviated as a rafter) from the back surface of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is attached to the back surface of the iron plate large wave 25, and the nut 6 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the nut 6 is attached and fixed on the surface of the iron plate large wave 25, and the Mirapane Ace 20 is overlaid on the surface of the iron plate large wave 25. Further, for example, after stacking the solar cells 1 manufactured and sold by the company name CV21, using the nut 6 fixed on the surface of the iron plate large wave 25, Solar cell 1, Mirapane Scan 20, and the three panels of the iron plate billows 25 bolt 5, and the lamination by pressure bonding using a nut 6. As a result, the iron plate large wave 25 attached with the solar cell 1 is fixed with the Mirapane Ace 20 interposed between the iron plate large wave 25 and the solar cell 1, and the nut 6 attached on the back surface of the iron plate large wave 25 is attached. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1. There is an effect that the composite roofing material 32 can be formed by integrating the panels.

1) At present, a contractor who manufactures the solar cell (1) and a contractor who installs the solar cell (1) on a structure such as a house (hereinafter abbreviated as a house). Is different.

2) The reason is that a solar cell manufactured by a manufacturer that manufactures the solar cell (1) cannot be directly attached to a house.

3) To install the solar cell (1) manufactured by the manufacturer that manufactures the solar cell (1) in a house, a professional contractor who installs the solar cell (1) installs the solar cell (1). The present condition is that the solar cell (1) is attached to the house by forming a structure intended to be attached to the house.

4) The solar cell (1) can be attached by developing the solar cell (1), which is a unitary structure by combining the necessary structure for installing the solar cell (1) in the house. For example, if an amateur can easily attach the solar cell (1) and the installation cost of the solar cell (1) is reduced, the solar cell (1) will be further spread.
The target effect explained above will be explained in the following (1) to (13).

Target effect (1)
A corrugated tin plate (2) is formed by laminating and laminating a solar cell (1) on the surface of a corrugated tin plate (2), and the corrugated tin plate (2 ) Is attached to the rafters (3) constituting the roof material of the house from the back side of the house, so that the corrugated plate shape can be obtained without damaging the surface of the corrugated iron board (2). The effect which aims at attaching and fixing to the rafter (3) which comprises the roof board | plate material of a house is made into (1).

Target effect (2)
For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). And forming a corrugated steel plate (2) in which a nut (6) is fixed on the surface of a corrugated steel plate (2). As shown in FIGS. 102, 44 and 50, a spherical silicon solar cell module (output 98W) manufactured and sold by Clean Venture Co., Ltd. Use the nut (6) attached and fixed on the surface of the shaped tin plate (2), or form an adhesive layer (10) to attach the spherical silicon solar cell module (output 98W) to the nut (6) Use or adhesive layer (1 ) To form, to the effect that the purpose of easily firmly attached to be able on the surface of the galvanized iron plate and the corrugated plate shape (2) and (2).

(3) of target effect
For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). After fixing the nut (6) on the surface of the corrugated tin plate (2), foaming is performed between the corrugated tin plate (2) and the solar cell (1). A plate made of polystyrene foil and aluminum foil but having an adhesive layer (10) formed on both sides thereof, and a plate made of aluminum foil on both sides with a foamed polystyrene plate as the center, for example, Plywood made by Mirapane Ace with the name of the company that JSP Co., Ltd. manufactures and sells in 3-4-2 Marunouchi (Nipponishi Building), Chiyoda-ku, Tokyo. Mirapane Ace Plywood (20)). A corrugated iron plate (2) and a solar cell (1) interposing adhesive layers (10) formed on both sides of a plywood (20) made of this Mirapane ace plywood (20) Bonded and stacked. Further, an arc welded portion (13) is formed on the back surface of the corrugated tin plate (2) to form a pad eye (7), a long eye (7), an open pad eye (7), or an eye strap. (7) By forming the corrugated steel plate (2) (hereinafter abbreviated as pad eye for short) formed on the back surface of the corrugated steel plate (2). The solar cell (1) is capable of withstanding the weight of a human even when the human walks freely on the surface of the solar cell (1) formed on the corrugated iron plate (2). It becomes a structure. It also has a soundproofing effect. Further, the solar cell (1) is formed on the surface of the corrugated iron plate (2) having a heat resistance effect. The solar cell (1) is installed because it is the corrugated steel plate (2). However, no special structure is required at all, and the solar cell (with the same work process as the work process of constructing the corrugated iron plate (2) as the roof of the roofing material) The effect for the purpose of being able to install 1) shall be (3).

(4) of target effect
For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). After fixing the nut (6) on the surface of the corrugated tin plate (2), foaming is performed between the corrugated tin plate (2) and the solar cell (1). After forming and joining the Mirapane Ace plywood (20) made of polystyrene and aluminum foil with the adhesive layer (10) interposed, and then laminating, An arc welded portion (13) is formed on the back surface of the shaped tin plate (2) to form a pad eye (7), a long eye (7), an open pad eye (7), or an eye strap (7) ( (Hereinafter referred to as pad eye for short) To attach the corrugated iron plate (2) to the rafter (3) constituting the house on the back surface of the iron plate (2), the tile (21) constituting the roof of the house, or A corrugated plate is formed by forming a hole (22) in a corrugated iron plate (21) (hereinafter abbreviated to be abbreviated as a tile) that is used as a slate (21) or a roofing material. The inside of the hole (22) in which the pad eye (7) attached on the back surface of the tin plate (2) and the L-rod (14) with nut whose tip is n-shaped are formed in the roof tile (21) On the surface of the corrugated steel plate (2) on the rafter (3) constituting the house, using an L-rod (14) with a nut whose tip is n-shaped. Furthermore, on the back surface of the solar cell (1) and the corrugated iron plate (2), a soundproofing effect or a heat insulating effect Or, for the purpose of improving the adhesion to the roof tile (21), one side is corrugated and the other side is a flat plate, or a shape similar to the shape of a roof tile is used as a roof tile. Corrugated stainless steel plate (1) is formed on the surface of corrugated steel plate (2) with sandwiched polystyrene foam plate (9) interposed in the middle of the sandwich shape. (2) is firmly attached to the rafters (3) constituting the house, on the surface of the roof made of tiles (21), and on the surface of the corrugated tin plate (2), solar cells ( The effect intended to form the corrugated iron plate (2) forming 1) is defined as (4).

Target effect (5)

FIG. 102 shows a corrugated steel plate (for the purpose of mounting the solar cell (1) on the surface of the corrugated steel plate (2) using bolts (5)). After forming the arc welded part (13) on the surface of 25) and fixing the nut (6) on the surface of the corrugated iron plate (25), the corrugated plate was formed. In the middle of the tin plate (25) and the solar cell (1), a Mirapane Ace plywood (20) made of a polystyrene foam plate and a plate made of aluminum foil is interposed with an adhesive layer (10). After forming and laminating, an arc welded portion (13) is further formed on the back surface of the corrugated iron plate (25) to form a pad eye (7), or a long eye (7), or Open pad eye (7) or eye strap (7) And, a pad eye) to the effect that it is intended to be formed on the back surface of the galvanized iron plate and the corrugated plate shape (25) and (5).

(6) of target effect
FIG. 44 shows a corrugated steel plate for the purpose of attaching the solar cell (1) by forming an adhesive layer (10) on the surface of the corrugated steel plate (2). Between the solar cell (1) and the solar cell (1), an adhesive layer (10) is attached between the Mirapane Ace plywood (20) and the solar cell (1) made of a foamed polystyrene plate and a plate made of aluminum foil. ), And one side is corrugated and the other side is intermediate between the Mirapane Ace (20) and the corrugated iron plate (2) and the Mirapane Ace (20). After the laminated polystyrene plate (9) is bonded to the corrugated stainless steel plate (2) with the adhesive layer (10) interposed on both sides of the flat polystyrene foam plate (9). In addition, the back side of corrugated iron plate (2) An arc welded portion (13) is formed on the nut (7), or the pad eye (7), or the long eye (7), or the open pad eye (7), or the eye strap (7) (hereinafter abbreviated, In order to attach the corrugated steel plate (2) to the rafter (3) constituting the house on the back surface of the corrugated steel plate (2) using the pad eye) Tile (21) or slate (21) constituting the roof of a house, or a corrugated corrugated steel plate (21), or an ordinary flat plate (21) (hereinafter abbreviated) L) with a pad eye (7) attached on the back surface of the corrugated stainless steel plate (2) and an n-shaped nut at the tip. The rod (14) penetrates the inside of the hole (22) forming the roof tile (21). Then, using an L-shaped rod (14) with a nut having an n-shaped tip, the rafter (3) constituting the house is placed on the surface of the corrugated iron plate (2). For the purpose of improving the soundproofing effect, the heat insulating effect, or the adhesiveness to the roof tile (21) on the back surface of the battery (1) and the corrugated iron plate (2), one side is corrugated. The solar cell (1) is formed on the surface of the corrugated steel plate (2) by interposing a polystyrene foam plate (9) having a flat plate shape on the other side in the middle of the sandwich shape. The corrugated steel plate (2) is firmly attached to the rafter (3) constituting the house, and the corrugated steel plate (2) is formed on the roof surface made of tiles (21). The corrugated iron plate (2) forming the solar cell (1) on the surface of 2) is formed. The effect for the purpose is (6).

(7) of target effect
FIG. 50 shows a corrugated tin plate (for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2) using bolts (5)). After forming the arc welded part (13) on the surface of 2), the nut (6) was fixed on the surface of the corrugated iron plate (2), and then the corrugated plate was formed. In the middle of the tin plate (2) and the solar cell (1), a Mirapane Ace plywood (20) made of a polystyrene foam plate and an aluminum foil plate is interposed with an adhesive layer (10). After forming and laminating, an arc welded portion (13) is further formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7), or a long eye (7), or Open pad eye (7) or eye strap (7) (hereinafter abbreviated The roof tile of the house (21) is attached to the rafter (3) constituting the house on the back surface of the corrugated iron board (2) using A hole (22) is formed in the pad, and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are tiled. Rafters (3) that make up the house using an L-shaped rod (14) with a nut that penetrates the inside of the hole (22) formed in (21) and has an n-shaped tip. The corrugated steel plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2), and the nut-attached L rod (14) having an n-shaped tip. ) Through the inside of the hole (22) formed in the roof tile (21), and the corrugated steel plate (2) is housed. To prevent rainwater from leaking through the holes (22) formed in the roof tile (21) and entering the interior of the house when fixed to the rafters (3) constituting the roof In addition, from the surface of the roof tile (21), a structure in which a long cylindrical shape (23) of about 5 cm is formed and the roof tile (21) is combined with the roof tile (21), and the tip portion is used. A corrugated tin plate (2) is fixed using an n-shaped L rod with nut (14). Furthermore, the nut-attached L rod (14) whose tip portion penetrating the inside of the cylindrical shape (23) is an n-shape is a sealant (24) inside the cylindrical shape (23), for example, Using an adhesive made of silicone resin or the like, the inside of the cylindrical shape (23) formed on the roof tile (21) united with the roof tile (21) is sealed with the sealant (24). Is used to prevent rainwater from leaking into the house from the hole (22) formed in the roof tile (21). Alternatively, the packing (24) made of silicone resin or the like is inserted into the cylindrical shape (23) instead of the sealant (24), and the L-rod with nut (14) having an n-shaped tip portion. ) Is formed in the roof tile (21) by being sealed inside the cylindrical shape (23) formed in the roof tile (21) which is integrated with the roof tile (21). Forming a roof tile (21) in which the roof tile (21) and the cylindrical shape (23) are combined to form a unitary structure by preventing rainwater from leaking into the house from the hole (22). The intended effect is (7).

(8) of target effect
FIG. 51 shows an enlarged view of the drawing shown in FIG. 50. The shaded portion uses a sealant (24) or packing (24), and rainwater leaks and enters the interior of the house. (8) is an effect intended to form a roof tile (21) having a structure in which the roof tile (21) and the cylindrical shape (23) are combined to form an integral structure.

(9) of target effect
A corrugated sheet of the same shape has been conventionally formed by forming a corrugated corrugated sheet (2) obtained by laminating and bonding the solar cell (1) on the corrugated corrugated sheet (2). By using a shaped steel plate (21), for example, replacing it with a corrugated steel plate that has the same vertical and horizontal dimensions but is used as a roofing material for chicken sheds, A structure for attaching a solar cell is obtained by replacing the corrugated steel plate (2) having a power generation function with the solar cell (1) formed on the surface of the steel plate (2) having a plate shape. Let (9) be the effect intended to be able to easily replace the corrugated plate (2) having a power generation function without forming it.

(10) of target effect
In Japan, corrugated tin plates are used only on the roof of chicken huts. However, in Southeast Asia, the equatorial zone of the hottest and the poorest countries in the world, Southeast Asia, sub-Saharan Africa, southern China, and Central and South America sub-Mexico, the main house roofing material. Is a corrugated iron plate (21). There are also many homes living without electricity infrastructure. The main roofing material of the houses inhabited by people who have no electrical infrastructure is also corrugated tin plate (21). Corrugated steel plate (21), which is the roof material of houses where people without this infrastructure live, and corrugated steel plate (2), which has the same shape and size as the power generation function (10) is an effect intended to facilitate the supply of electricity by replacing the above.

(11) of target effect
Corrugated stainless steel plate (2) is bolt (5), nut (6), hook (7), pad eye (7), long eye (7), or open pad eye (7), Or use the eye strap (7), or the UK turnbuckle (7), or the L bar with nut (hereinafter abbreviated as pad eye), or other means to form the roof of the house. Corrugated steel plate (2) by attaching corrugated steel plate (2) to rafter (3) from the back side of corrugated steel plate (2) to rafter (3) The corrugated steel plate (2) is applied to the rafter (3) of the roofing material that constitutes the house, without damaging the wound generated by hitting the nail (4) on the surface of the back surface. Since it is attached and fixed to the rafter (3) from above, the corrugated plate shape Since the corrugated steel plate (2) can be used as a roofing material without generating any scratches on the surface of the steel plate (2), Nisshin Steel Sheet Co., Ltd. manufactures and sells it. When the product name is Galvanstar (ZG) steel sheet or ZAM steel sheet, and the corrugated iron plate (2) is formed, the service life becomes Galvastar (ZG) steel sheet or ZAM steel sheet. Corrugated iron plate that is not corroded at all for 30 to 50 years, which is 3 to 5 times the warranty period of 10 years, which is guaranteed by Nisshin Steel Co., Ltd. Let (11) be the effect intended to be able to form the solar cell (1) on the surface of the tin plate (8) made of (2) or a flat plate.

(12) of target effect
Solar cell (1) shown in FIGS. 102, 44, and 50 and a structure necessary for constructing and mounting the solar cell (1) are combined to form an integrated structure. By developing (1), there is an effect for the purpose described in the following (1) to (5).

(1) Even an amateur can easily be made of, for example, a tile (21) or a slate (21) constituting a roof of a house, a corrugated iron plate (21), or an ordinary flat plate. The solar cell (1) can be attached to the surface of the iron plate (21) (hereinafter abbreviated as a roof tile).

(2) The solar cell (1) can be easily installed and installed on the roof surface of an old house or on the roof surface of a newly built house.

(3) In addition, if there is a vacant land that is a space other than the roof of the house, even an amateur can easily install and install the solar cell (1) to perform power generation business (1) A solar cell (1) that can be provided can be provided.

(4) The solar cell (1) can be attached and installed at an extremely cheap price, and the solar cell (1) will be further spread.

(5) As a result, the solar cell (1) described above is widely used, and the solar power (1) that can drastically change the world power situation and energy situation is provided. I can do it.

(13) of target effect
1) The price of the solar cell (1) shown in FIGS. 102, 44, and 50 is the power generation function at a very low price of + α (alpha) in addition to the price of the main body of the solar cell (1). A solar cell (1) is completed.

2) For example, the standard of corrugated iron plate (2) has a width of 90 cm and a vertical length of 180 cm. The power that can be generated in this 90 cm × 180 cm area is about 98 W. The amount of electricity used per day in a general home is set to 3 KW to 4 KW. Then, about 30 solar cells (1) (hereinafter abbreviated as solar cells (1)) in which the solar cells (1) are formed on the surface of the corrugated iron plate (2). If it is 40 sheets from, it will be the calculation which can cover the general household electricity consumption.

3) The standard of corrugated iron plate (2) is 90 cm in width and 180 cm in length. When the solar cell (1) is formed on the surface of the area of 90 cm × 180 cm, a structure that can be attached to the solar cell (1) for about 15,000 yen is completed. Since approximately 30 solar cells (1) are required to cover the cost, the cost of 30 sheets x 15000 yen → approximately 450,000 yen, the equipment that converts direct current to alternating current, and the lead battery is approximately If 150,000 yen, you will be able to cover electricity for one household.

4) In industrialized countries, this low-cost solar battery (1) that can be easily installed on the surface of a roof such as a house by an amateur, carpenter, or plasterer is profitable by selling it. increase. In the poorly developed countries, which are poor countries, each household needs to be free of charge to the people in the poorly developed countries by using the profits obtained by selling solar cells (1) in the developed countries. We will start a business to provide solar cells (1) necessary to cover the electricity to be used.

5) In developed countries, sell solar cells (1) at an extremely cheap price to increase profits. By providing this solar cell free of charge (1) that can cover the power required by people in low-developed countries by applying this profit, most of the energy required on this planet is solar cell. (1) can be covered. As the solar cell (1) is gradually spread, an energy revolution will occur on the earth.

6) In addition, we will provide solar cells (1) free of charge necessary to cover the power required by people in underdeveloped countries. Instead, each household will be provided with a solar cell (1) that can generate more electricity than the household needs.

7) Using the solar cell (1) provided free of charge, the power generated by each household will be sold or converted to hydrogen. Then, it will be sold to developed countries as energy that developed countries need.

8) Furthermore, in poor underdeveloped countries, there is cheap and wide land. By making effective use of this cheap and wide land, power is generated by solar power generation using inexhaustible solar rays. Can be a country that can As a result, the possibility of becoming an energy producing country from a poorly underdeveloped country and being able to escape from a poorly underdeveloped country is the corrugated tin plate (2 ) On the surface of the solar cell (1).

9) In addition, the land of the vast area owned by the poor underdeveloped countries and the land owned by the poor underdeveloped countries due to inexhaustible solar rays are most necessary in the developed countries and on the earth. It is also a land that has the potential to cover the energy that it says.

10) In particular, 36 sub-Saharan countries are the poorest and poorest countries in the world. The reason for this is that catfish and horses, which are livestock necessary for farming work, are infected with Nagana disease and die, because the fly flies that are infected with Trypanosoma protozoa are intensifying. The high mortality rate of cattle and horses essential for this farming work is the reason why the 36 sub-Saharan countries are the poorest and poorest countries in the world.

11) The total area of the farmland where 36 countries in the sub-Saharan Desert cannot perform farming work due to the fertility of the fly fly is called the fly fly belt zone. The fly flies that carry this trypanosoma protozoa inhabit in a relationship of mutual prosperity with wild animals over 10 million square kilometers. Since the area of the United States is 96.22 million square kilometers, almost the same area is called the Tsuetsue fly belt zone, and it is a barren land that cannot be farmed. If solar power is generated on farmland that cannot be cultivated in the Tweed fly belt belt, and the power is transmitted to the consuming countries, the world energy situation will change drastically, and at the same time The south 36 countries have the effect (13) aimed at becoming the richest country in the world.

Moreover, what is shown in FIG. 103 aims at attaching the solar cell 1 directly on the surface of the folded-plate roof 25 as the 1st objective. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the nut 6 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, in order to attach the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is used. There is also an effect that the solar cell 1 can be directly attached and fixed on the surface of the folded plate roof 25 on which the nut 6 is attached by forming the arc welded portion 13 on the back surface of the steel plate.

Further, the first object shown in FIG. 111 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the nut 6 is attached to the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. In addition, there is an effect that the solar cell 1 can be directly attached and fixed on the surface of the slate roof 25 to which the nut 6 is attached by forming the arc welded portion 13.

FIG. 121 shows a processing means for joining the two large iron plate waves 25 of the present invention by pressure bonding. First, a nut 6 or other mounting bracket 6 (hereinafter abbreviated as nut 6) is placed on the back surface of the iron plate large wave 33 on the back surface of the iron plate large wave 33 located at the upper portion. An iron plate large wave 33 to which the nut 6 is attached by forming a welded portion 13 is formed. Secondly, the bolt 5 passing through the inside of the hole portion 36 formed in the large iron plate wave 34 located in the lower portion, the washer 35 larger than the inner diameter of the hole portion 36, and the nut 6 is used to overlap the iron plate large wave 33 located in the upper part and the iron plate large wave 34 located in the lower part in an overlapping manner, and the two nuts located vertically 6 is effective in that two large iron plate waves 25 can be pressure-bonded from above and below.

The iron plate large wave 34 is extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. There is an effect that it is possible to form the solar cell 1 in which the band-shaped iron plate 37 is attached on both side surfaces of the large wave 34 and the large iron plate 34 and the band-shaped iron plate 37 are firmly bonded.

For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). For example, even for an amateur, a plasterer, or a carpenter, the solar cell 1 and the solar cell 1 are integrated as a structure that can attach the solar cell 1 very easily. Solar power united with It has the effect of capable of forming a solar cell 1 for the purpose of which individually produce and sell one.

For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). The solar cell 1 for the purpose of individually manufacturing and selling the solar cell 1 combined with the roofing material, which has a structure in which the solar cell 1 can be attached very easily. C steel 3 or wood constituting The solar cell 1 which is made by combining the roof material with the roof 3 or the rafter 3 (hereinafter referred to as the rafter 3) is integrated with the roof material from the back surface of the roof material constituting the house. When the solar cell 1 is attached to the rafter 3 constituting the house from the back side, and the iron plate large wave 34 serving as the roof constituting the house is attached to the roof, the solar cell 1 is simultaneously formed on the roof constituting the house. There is an effect that the solar cell 1 can be attached to the roof which is a material.

Conventionally, when the solar cell 1 is installed on the surface of the iron plate small wave 25, the iron plate large wave 25, or the folded plate roof 25 (hereinafter referred to as iron plate large wave), the surface of the wood purlin 3 Attach a large iron plate wave using a nail 4, wood screw, stainless steel screw, or Namiji hex (hereinafter abbreviated as a nail) to the wood purlin 3 ing. As shown in FIG. 126 and FIG. 131, when attaching one piece of the iron plate large wave 25 to the wood purlin material 3 using the nail 4, the hole diameter of about 50 places is 6 mm, or the hole diameter is 7 mm. Alternatively, it is necessary to form a hole having a hole diameter of 8 mm on the surface of the iron plate large wave 25. Further, a base metal receiver (hereinafter abbreviated as a bracket) 42 used to firmly fix the solar cell 1 on the surface of the iron plate large wave 25, the solar cell 1 as one solar cell 1. For mounting on the surface of one large iron plate wave 25, four base metal receiving pieces 42 are used. In order to attach the base metal receiving material 42 on the surface of the iron plate large wave 25 using four sheets, 16 holes having a diameter of 8 mm are formed on the surface of the iron plate large wave 25 and the surface of the iron plate large wave 25 is formed. A base metal receiver 42 is attached to the base plate. In order to attach the steel plate large wave 25 to the wood purlin 3 as described above, about 50 holes are formed and 16 pieces are used to attach the base metal receiving material 42 on the surface of the steel plate large wave 25. Since a hole is formed, a total of about 66 holes are formed on a roof where the working environment is severe to attach and fix one solar cell 1 on the surface of one large iron plate wave 25. The current situation is that it cannot be done without processing. The following (1) to (5) will be described to simplify the work performed on the rooftop on the roof where the working environment is severe as described above.

As (1), first, as shown in FIGS. 125 and 130, the position and size of the interval of the wood purlin 3 are determined. Second, as shown in FIGS. 126 and 131, the position of the hole formed in the iron plate large wave 25 is determined. Third, as shown in FIGS. 127 and 132, the positions of the holes to be formed in the base metal receiver 42 are determined. Fourth, as shown in FIGS. 128 and 133, the positions of the holes formed in the steel frame 43 are determined. Fifth, as shown in FIGS. 129 and 134, the position of the hole to be formed in the solar cell 1 is determined.

As (2), first, as shown in FIGS. 129 and 134, the position of the hole to be formed in the solar cell 1 is determined. Second, as shown in FIGS. 128 and 133, the positions of the holes formed in the steel frame 43 are determined. Third, as shown in FIGS. 127 and 132, the positions of the holes to be formed in the base metal receiver 42 are determined. Fourth, as shown in FIGS. 126 and 131, the position of the hole formed in the iron plate large wave 25 is determined. Fifth, as shown in FIGS. 125 and 130, the position and size of the interval of the wood purlin material 3 are determined.

As (3), as the conclusion (1), as explained in the above (1) and (2), first, the position and size of the interval of the wood purlin 3 are first determined, Or if the position of the hole formed in the solar cell 1 is determined, the position of the hole formed in the iron plate large wave 25, the base metal receiving member 42, and the steel frame 43 is determined. This means that, for example, 66 holes are drilled on the surface of the iron plate large wave 25 using a drill on the rooftop of the roof where the working environment is severe, and holes are formed on the surface of the iron plate large wave 25. When the drilling work to be performed is performed inside the factory, holes to be formed on the surface of the iron plate large wave 25 are attached with NC, for example, a plurality of 20 to 30 iron plate large waves 25 together. Using a machine tool, there is an effect that a large amount of holes can be precisely machined at an extremely low cost without an error of ± 1 mm.

As (4), as conclusion (2), the iron plate large wave 25, the folded plate roof 25, or the roofing material 25 (hereinafter abbreviated as the iron plate large wave) made of metal having other shapes, When a large number of several tens of sheets are manufactured and sold one by one with a large plate of iron plate 25 drilled using NC machine tools, the nail 4 or wood screw is used as a roofing material. There is an effect of using 4 and attaching it to the wood purlin 3 that easily constitutes the roof.

As (5), as conclusion (3), the steel plate large wave 25 that has been drilled, the base metal 42 that has been drilled, the steel frame 43 that has been drilled, and the solar cell 1 that has been drilled, and FIG. To attach the solar cell panel 1 to the iron plate large wave 25, which is an accessory shown in Fig. 1, attach the solar cell panel 1, pack together the set of one panel, and manufacture and sell it as a kit or set The operation of attaching the solar cell 1 to the roof purlin 3 and the iron plate large wave 25 has the effect that even an amateur, carpenter or plasterer can easily attach it.

For the purpose of mounting the solar cell 1 on the surface of the iron plate large wave 25, the roof material 25 made of iron plate large wave 25, folded plate roof 25, or other shaped metal (hereinafter abbreviated as iron plate large wave 25). On the surface of the rafter 3 constituting the roof material, or the C steel 3, or the wooden purlin 3 or the skeleton 3 constituting the roof of the house (hereinafter abbreviated as rafter). For the purpose of attaching and fixing a single iron plate large wave 25 to the rafter 3 using the nail 4, the wood screw 4, or the screw hex 4 (hereinafter abbreviated as a nail). The total number of holes to be formed on the surface of one large iron plate wave 25 needs to form approximately 66 holes. The total position of forming approximately 66 holes constitutes the roof of the house with the steel plate large wave 25, the base metal receiver 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25 for short). Since the purpose is to attach and fix to the central part of the rafter 3, the total number of holes formed in the iron plate large wave 25, all the positions of about 66 holes, are shown in FIGS. 125 and 130, for example. As shown in the figure, the iron plate at a position corresponding to a portion directly above the central portion of the rafter 3 which is the purlin 3 constituting the roof of the house, and the rafters 3 are attached at intervals of 428.5 mm. In the processing factory that has already produced the iron plate large wave 25 in the large wave 25, a hole is formed on the surface of the iron plate large wave 25 using the NC machine tool on the surface of the top of the mountain where the uneven portion of the iron plate large wave 25 is present. The surface of the iron plate large wave 25 Since holes can be formed at positions where there is no error of ± 1 mm, for example, as shown in FIGS. 125 and 130, the interval between the rafters 3 is first set to 428.5 mm, and the positions of the rafters 3 are If accurately determined, the iron plate large wave 25 in which holes are formed on the surface of the iron plate large wave 25 at intervals of 428.6 mm in the iron plate large wave 25 shown in FIGS. 126 and 131 is a rafter. If the iron plate large wave 25 is attached to the rafter 3 using the nail 4 and installed from right above the iron plate 3, the iron plate large wave 25 can be easily attached to the rafter 3 without dividing the size of the iron plate large wave 25. . To install the solar panel 1 on the surface of the iron plate large wave 25, the installation of the solar cell panel 1 is completed on the surface of the iron plate large wave 25 just by assembling the kit as a set of the solar cell panel 1 on the surface. In order to install the solar cell panel 1 on the surface of the iron plate large wave 25, there is no need to divide the dimensions on the roof of the work site and to match the actual product on the site. It is easy to attach and fix to the rafter 3, and the kit that is a set of solar panel 1 can be mass-produced at the processing factory, so the cost is low, the delivery time is fast, and the installation work is simple. Even an amateur, carpenter, or plasterer can perform installation work, so the solar cell panel 1 is attached to the iron plate large wave 25 and the rafter 3, and the solar cell panel 1 is attached to the iron plate large wave 25. Is mounted on the surface there is an effect that construction period required is an overwhelming shortened to complete the roof.

In addition, as described above, the steel plate 1 is made of the iron plate large wave 25 by using the iron plate large wave 25, the base metal receiving member 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25). FIG. 135 shows one solar cell panel, one steel plate large wave 25, four base plates 42, two steel frames 43, which are mounted on the surface and fixed. A box in which a set of one set of panels of solar cells 1 is packed together in one box (hereinafter, abbreviated, set, or kit, or solar cell set, or solar cell kit) The solar cell 1 is attached on the surface of the iron plate large wave 25 using the above. However, the processing means for attaching the solar cell 1 to the surface of the iron plate large wave 25 is used to attach the roof to the rafter 3, which is the roof constituting the roof of the house, using only the iron plate large wave 25 alone. As a processing means for attaching the iron plate large wave 25 as a roof material for the purpose of constructing only a roof, for example, as shown in FIGS. 125 and 130, when a roof of a house is first constructed, a rafter is constructed. If the position of the rafter 3 is determined at an interval of 428.5 mm, the iron plate large wave 25 and the hole interval of the iron plate large wave 25 shown in FIGS. 126 and 131 are 428.5 mm. It is possible to attach the iron plate large wave 25 to the rafter 3 by using the nail 4 by installing the iron plate large wave 25 having a hole formed on the surface thereof from right above the rafter 3. In this way, when the roof is configured using the iron plate large wave 25 in which a hole is formed in the iron plate large wave 25 using the NC machine tool, the rafter 3 constituting the roof of the house is configured as described above. As in the case of attaching the solar cell 1 to the iron plate large wave 25 as described, if the position of the rafter 3 is determined, the error of the hole formed in the iron plate large wave 25 is no error of ± 1 mm, so it is a work site. Since it is not necessary to divide the size of the iron plate large wave 25 on the surface of the roof, it is easy to attach and fix the iron plate large wave 25 to the rafter 3. Since it is a simple operation, the cost is low, and the construction period required to complete the roof by attaching the iron plate large wave 25 to the rafter 3 is overwhelmingly shortened.

Furthermore, before the formation of the iron plate large wave (25), the pre-process processing is completed, for example, Nisshin Steel Co., Ltd. manufactures and sells, the product name is the Galvaster (ZG) steel plate, or ZAM steel plate A flat steel plate coated with a paint on the surface of a flat steel plate, a flat steel plate coated with urethane paint, a flat steel plate that has just been rolled, or a steel coil wound around a round roll, or a strip steel flat plate, or a flat plate Or a decorative plate made of plywood, a plywood plate, a flat plate made of plastic, or a flat plate made of other materials, or an external flat plate material, or an internal flat plate material (hereinafter, a plastic flat plate, or For example, a thin film quantum dot PV solar on which the research and development by Solterra in the United States has succeeded in research and development on a surface such as a decorative plate, a flat plate, or a flat steel plate) The quantum dot solar cell (51) is rolled onto the surface of the flat steel plate (44) using a manufacturing technique of the battery (51) (hereinafter, abbreviated as a quantum dot solar cell (51)). A flat plate steel plate (44) having a quantum dot type solar cell (51) directly formed on the surface of the flat plate steel plate (44) by using roll printing technology, ink jet printing technology, or screen printing technology. Alternatively, there is an effect that the flat steel plate (44) in which the quantum dot solar cell (51) is formed can be formed on the surface of the strip steel flat steel plate (44) wound in round and round.

Further, on the surface of the flat steel plate (44), using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique, a quantum dot type For the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which the solar cell (51) is formed, the solar cell (51) is made of a resin having good sunlight transmittance. A flat steel plate (44) on which a quantum dot solar cell (51) is formed using a film made of polycarbonate resin or the like, or a film made of other resin (hereinafter abbreviated as a protective film (45)). ) On the surface of the flat steel plate (44) in which the quantum dot solar cell (51) is formed on the surface of the flat steel plate (44) as the protective film (45). The flat steel plate (44) bonded on the surface of the flat steel plate (44) is used as the protective film (45) protecting the surface of 51), or the quantum dot solar cell (51) is used as the flat steel plate (44). The protective film (45) is formed on the surface of the flat steel plate (44), which is formed on the surface of the quantum dot solar cell (51), which is still formed on the surface of A flat plate steel plate (44) forming a quantum dot solar cell (51), which is a building material constituting a house or a building (hereinafter abbreviated as a house). It is used as the outer wall plate of the wall material constituting the outer periphery of the outer wall or the exterior material. For example, a quantum dot type solar cell (51) is formed on the surface of a flat steel plate (44) on the surface of a flat steel plate (44) having a width of 90 cm and a vertical width of 180 cm. Using the solar cell (51), electric power is generated using the energy of solar rays. Moreover, the quantum dot type solar cell (51) which has formed the quantum dot type solar cell (51) on the surface of a flat steel plate (44) as an interior material for the room | chamber interior currently used in the house interior. ) Using the energy of light generated from incandescent lamps or fluorescent lamps that are used inside houses or buildings, and using quantum dot solar cells (51 ) Is formed on the surface of the flat steel plate (44), the quantum dot solar cell (51) is used to generate power using the quantum dot solar cell (51). There exists an effect which can form the flat steel plate (44) which forms the battery (51).

Furthermore, a quantum dot type using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). For the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which the solar cell (51) is formed, the solar cell (51) is made of a resin having good sunlight transmittance. A flat steel plate (44) on which a quantum dot solar cell (51) is formed using a film made of polycarbonate resin or the like, or a film made of other resin (hereinafter abbreviated as a protective film (45)). ) As a protective film (45) on the surface of the flat steel plate (44) in which a quantum dot solar cell (51) is formed on the surface of the flat steel plate (44). As the protective film (45) for protecting the surface of (51), a flat steel plate (44) bonded on the surface of the flat steel plate (44) is used, or the quantum dot solar cell (51) is used as a flat steel plate. A protective film (45) is formed on the surface of the flat steel plate (44), which is formed on the surface of the quantum dot solar cell (51), as it is formed on the surface of (44). The flat plate steel plate (44) forming the quantum dot solar cell (51), which is not formed, is directly molded into the iron plate large wave (46) for the purpose of forming the iron plate large wave (46). Using a machine, forming the quantum dot solar cell (51) on the surface of the flat steel plate (44), molding the flat steel plate (44), on the surface of the iron plate large wave (25), Directly a large iron plate (4) forming a quantum dot solar cell (51) ) There is an effect that can be formed.

Further, the plate steel plate (44) forming the quantum dot solar cell (51) is directly formed on the surface of the plate steel plate (44) with the shape of the iron plate large wave (25) or the folded plate roof (25). A quantum dot solar cell (51) is formed directly on the surface of the iron plate large wave (25) by molding using a molding machine for forming into a shape (hereinafter referred to as iron plate large wave (25)). ) Forming a rafter (3), a purlin (3), or a skeleton (3) (hereinafter abbreviated as a rafter (abbreviated) 3)), using a stainless steel screw (4), a hole (47) for attaching the steel plate large wave (25) to the rafter (3), for example, a hole diameter of 9 mm. An iron plate large wave (46) in which a hole (47) is formed on the surface of the iron plate large wave (46), for example, an iron plate large wave (4 ) Are stacked together by laminating 10 to 20 sheets together, and using a machine tool with NC, make holes (47) from 40 to 60 with an error within ± 1 mm. On the surface of the large wave (46), an iron plate large wave (46) having a hole (47) can be formed at the same time.

Furthermore, using the printing technology such as roll-to-roll printing technology, ink jet printing technology, or screen printing technology on the surface of the steel plate big wave (25) or the flat steel plate (44), the iron plate big wave (25), Alternatively, the quantum dot solar cell (51) can be formed uniformly along the curved surface on the surface of the folded plate roof (25). Moreover, there exists an effect which can form a quantum dot type solar cell (51) on the surface of a flat steel plate (44).

In addition, the rafter (3) or C on the surface of the iron plate large wave (25) is used for the purpose of performing surface processing so that the iron plate large wave (25) does not rust for several tens of years to 100 years. Stainless steel screws (4) are used for the steel (3), the wooden purlin (3), or the skeleton (3) (hereinafter abbreviated as rafter (3)) constituting the roof of the house. , A hole (47) for attaching the iron plate large wave (25) to the rafter (3), for example, a hole (47) having a hole diameter of 9 mm on the surface of the iron plate large wave (25), NC Using a machine tool, an extremely thin primer as a first layer on the surface of the iron plate wave (25) in which a hole (47) is formed on the surface of the iron plate wave (25) with an error within ± 1 mm Form a layer. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. Urethane on the surface of the iron plate large wave (25) which forms the hole (47) for attaching to the rafter (3) which comprises a house on the surface of the iron plate large wave (25) demonstrated above. For the purpose of forming the coating film (48) and attaching the iron plate large wave (25) formed with the urethane coating film (48) to the rafter (3) using the stainless steel screw (4), Whether it is an amateur, carpenter, plasterer, or electrician, drilling holes (47) on the surface of the iron plate large wave (25) for the purpose of easily attaching the iron plate large wave (25) to the rafter (3), and There exists an effect which can form the iron plate large wave (50) with a urethane coating film which forms the urethane coating film (48).

Furthermore, for the purpose of performing surface processing for which the iron plate large wave (25) does not rust for several tens of years to 100 years, the first layer on the surface of the iron plate large wave (25) is extremely used. Form a thin primer layer. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. In the convex part on the surface of the iron plate large wave (25) after the urethane coating film (48) is formed on the surface of the iron plate large wave (25) described above, for example, the diameter of the hole diameter is 9 mm. Hole (47) with a hole diameter on the surface of the iron plate large wave (25) using an NC machine tool with an error within ± 1 mm, the urethane coating (48) on the surface of the iron plate large wave (25) A hole (47) for attaching to the rafter (3) constituting the house is formed on the surface of the iron plate large wave (25), and the iron plate large wave (25) is made of stainless steel into the rafter (3). For the purpose of being able to attach using a wooden screw (4), even an amateur, carpenter, plasterer, electrician, etc., to easily attach a large iron plate (25) to a rafter (3), Drilling holes (47) on the surface of the iron plate large wave (25), and urethane There is an effect that it is possible to form a urethane coating with iron large wave that forms a film (48) (50).

In addition, as a first layer on the surface of the iron plate large wave (25), the iron plate large wave (25) is extremely formed as a first layer on the surface of the iron plate large wave (25) for the purpose of performing surface processing so that the iron plate large wave (25) does not rust. Form a thin primer layer. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. Using the flat steel plate (44) formed on the surface of the flat steel plate (44) as described above and using the flat steel plate (44) as a raw material, the flat steel plate (49) with a urethane coating is used directly. The urethane coating film is formed on the surface of the flat steel plate (44) by using a molding machine for forming the iron plate big wave (25) for the purpose of forming the iron plate big wave (25). Effect of forming a steel plate large wave (50) with a urethane coating film by forming a flat steel plate (49) with a coating film to form a urethane coating film (48) on the surface of the iron plate large wave (25) There is.

FIG. 1 shows that a corrugated tin plate (2) having a solar cell (1) directly attached is formed on the surface of a corrugated tin plate (2) to form a solar plate. The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly The rafters (3) and nails (4) are used on the corrugated tin plate (2) for the purpose of directly using the solar cell (1) as the roof constituting the house. After attaching rafters (3) using nails (4) to the back of corrugated steel plates, corrugated steel plates On the surface of the corrugated plate (2), a solar cell (1) having the same shape as the corrugated tin plate (2) is bonded to the surface of the corrugated tin plate (2) with an adhesive ( 10) is used for pasting and joining, or the solar cell (1) is joined on the surface of the corrugated iron plate (2) using other means, and then the house is constructed again. FIG. 1 shows a longitudinal sectional view in which a rafter (3) is attached to a corrugated tin plate (2) for the purpose of reattaching to the rafter (3) of the roofing material. FIG. 2 shows that a corrugated tin plate (2) having a solar cell (1) directly attached is formed on the surface of a corrugated corrugated tin plate (2). The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly The rafters (3) are bolts (5) and nuts to the corrugated steel plate (2) for the purpose of directly using the solar cell (1) as the roof constituting the house. Using (6), use the bolt (5) and nut (6) on the back of the corrugated tin plate After attaching the tree (3), on the surface of the corrugated tin plate (2), the solar cell (1) having the same shape as the corrugated tin plate (2) Attached to the surface of the galvanized steel plate (2) by using an adhesive (10) or bonded to the surface of the corrugated steel plate (2) using other means. After joining the battery (1), the rafter (3) is attached to the corrugated iron plate (2) for the purpose of reattaching it to the rafter (3) of the roof material constituting the house. A longitudinal sectional view is shown in FIG. FIG. 3 shows that a corrugated tin plate (2) in which a solar cell (1) is directly attached is formed on the surface of a corrugated tin plate (2) to form a solar plate. The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly The rafters (3) and nails (4) are used on the corrugated tin plate (2) for the purpose of directly using the solar cell (1) as the roof constituting the house. After attaching the rafter (3) using the nail (4) to the back of the corrugated tin plate, On the surface of the corrugated plate (2), a solar cell (1) having the same shape as the corrugated tin plate (2) is bonded to the surface of the corrugated tin plate (2) with an adhesive ( 10) is used for pasting and joining, or the solar cell (1) is joined on the surface of the corrugated iron plate (2) using other means, and then the house is constructed again. FIG. 3 shows a longitudinal sectional view of the rafter (3) attached to the corrugated tin plate (2) for the purpose of reattaching to the rafter (3) of the roofing material. FIG. 4 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated corrugated tin plate (2), The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly The rafters (3) are bolts (5) and nuts to the corrugated steel plate (2) for the purpose of directly using the solar cell (1) as the roof constituting the house. Using (6), use the bolt (5) and nut (6) on the back of the corrugated tin plate After attaching the tree (3), on the surface of the corrugated tin plate (2), the solar cell (1) having the same shape as the corrugated tin plate (2) Attached to the surface of the galvanized steel plate (2) by using an adhesive (10) or bonded to the surface of the corrugated steel plate (2) using other means. After joining the battery (1), the rafter (3) is attached to the corrugated iron plate (2) for the purpose of reattaching it to the rafter (3) of the roof material constituting the house. FIG. 4 shows a vertical sectional view. FIG. 5 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated tin plate (2) to form a solar plate The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly The rafters (3) are bolts (5) and nuts to the corrugated steel plate (2) for the purpose of directly using the solar cell (1) as the roof constituting the house. Using (6), use the bolt (5) and nut (6) on the back of the corrugated tin plate After attaching the tree (3), on the surface of the corrugated tin plate (2), the solar cell (1) having the same shape as the corrugated tin plate (2) Attached to the surface of the galvanized steel plate (2) by using an adhesive (10) or bonded to the surface of the corrugated steel plate (2) using other means. After joining the battery (1), the rafter (3) is attached to the corrugated iron plate (2) for the purpose of reattaching it to the rafter (3) of the roof material constituting the house. FIG. 5 shows a longitudinal sectional view. FIG. 6 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated tin plate (2) to form a solar plate. The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the corrugated corrugated tin plate (2) is formed on the corrugated corrugated corrugated sheet (2). 2) The solar cell (1) having the same shape as that of the adhesive (1 ), Or after joining the solar cell (1) on the corrugated iron plate (2) surface using other means, the house is constructed again. Corrugated tin for the purpose of attaching corrugated corrugated steel plate (2) from the back using bolts (5) and nuts (6) on rafters (3) of the roofing material FIG. 6 shows a longitudinal sectional view of the bolt (5) attached to the back surface of the plate (2). FIG. 7 shows that a corrugated tin plate (2) in which a solar cell (1) is directly attached is formed on the surface of a corrugated tin plate (2) to form a solar plate. The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the corrugated corrugated tin plate (2) is formed on the corrugated corrugated corrugated sheet (2). The solar cell (1) having the same shape as 2) is bonded to the surface of the corrugated iron plate (2) with an adhesive (1 ), Or after joining the solar cell (1) on the corrugated iron plate (2) surface using other means, the house is constructed again. Corrugated tin for the purpose of attaching corrugated corrugated steel plate (2) from the back using bolts (5) and nuts (6) on rafters (3) of the roofing material FIG. 7 shows a longitudinal sectional view of the nut (6) attached to the back surface of the plate (2). FIG. 8 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated corrugated tin plate (2). The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the corrugated corrugated tin plate (2) is formed on the corrugated corrugated corrugated sheet (2). The solar cell (1) having the same shape as 2) is bonded to the surface of the corrugated iron plate (2) with an adhesive (1 ), Or after joining the solar cell (1) on the corrugated iron plate (2) surface using other means, the house is constructed again. Back surface of corrugated steel plate (2) for the purpose of attaching corrugated steel plate (2) from the back surface using hook (7) to rafters (3) of the roofing material FIG. 8 shows a longitudinal sectional view of the hook (7) attached to the hook. FIG. 9 shows that a corrugated tin plate (2) with a solar cell (1) attached directly on the surface of a corrugated corrugated tin plate (2), The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the flat plate made of a flat plate (8) on the surface of the flat plate (8) made of a flat plate ( The solar cell (1) having the same shape as 8) is bonded to the surface of the flat plate (8) made of flat plate. Use (10) to attach and join, or use other means to join the solar cell (1) on the surface of the flat plate (8) made of flat plate, It is made of a flat plate for the purpose of attaching a steel plate (8) made of a flat plate from the back using bolts (5) and nuts (6) on a rafter (3) of the constituting roofing material. The longitudinal cross-sectional view which has attached the volt | bolt (5) to the back surface of the iron plate (8) which is installed is shown in FIG. FIG. 10 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated corrugated tin plate (2), The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the flat plate made of a flat plate (8) on the surface of the flat plate (8) made of a flat plate ( A solar cell (1) having the same shape as 8) is placed on the surface of a flat plate (8) made of flat plate. After bonding the solar cell (1) on the surface of the tin plate (8) made of a flat plate using other means, or pasting using the agent (10), the house is again formed. It is made of a flat plate for the purpose of attaching a flat plate made of flat plate (8) from the back using bolts (5) and nuts (6) on the rafters (3) of the roofing material comprising The longitudinal cross-sectional view which has attached the nut (6) to the back surface of the iron plate (8) which is attached is shown in FIG. FIG. 11 shows that a corrugated tin plate (2) with a solar cell (1) directly attached is formed on the surface of a corrugated corrugated tin plate (2). The surface of the corrugated steel plate (2) again for the purpose of attaching the solar cell (1) directly to the rafters (3) of the roof material that constitutes the roof of the house. Above, corrugated iron plate (2) directly forming solar cell (1), solar cell (1) directly on rafters (3) constituting the roofing material of the house directly In order to use the solar cell (1) directly as the roof constituting the house, the flat plate made of a flat plate (8) on the surface of the flat plate (8) made of a flat plate ( A solar cell (1) having the same shape as 8) is placed on the surface of a flat plate (8) made of flat plate. After bonding the solar cell (1) on the surface of the tin plate (8) made of a flat plate using other means, or pasting using the agent (10), the house is again formed. For the purpose of attaching the steel plate (8) made of a flat plate from the back using a hook (7) to the rafter (3) of the roof material constituting the steel plate (8) 11 is a longitudinal sectional view of the hook (7) attached to the back surface of FIG. FIG. 12 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). Corrugated steel plate (2) using nails (4) and corrugated steel plate (2) using rafters (3) and nails (4) on the back of corrugated steel plate (2) After fixing the rafter (3) to the back surface of the corrugated sheet, the corrugated sheet shape is exactly the same as the corrugated corrugated sheet board (2) on the corrugated corrugated sheet board (2). The adhesive layer (9) between the plate (9) (hereinafter abbreviated as foamed polystyrene plate for short) and the corrugated tin plate (2) made of a polystyrene foam plate on the other side. 10) to form an adhesive layer (10) on the surface of the polystyrene foam plate (9) on the surface of the corrugated stainless steel plate (2) Interposed therebetween, a longitudinal cross-sectional view forming a solar cell (1) adhered by bonding a solar cell (1), is shown in FIG. 12. FIG. 13 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), the back surface of corrugated stainless steel plate (2) with bolt (5) welded or using metal adhesive to fix bolt (5) After the rafter (3) is fixed to the back surface of the corrugated steel plate (2) using the nut (6), the rafter (3) is fixed to the corrugated steel plate (2). A plate (9) (hereinafter abbreviated as a corrugated sheet having the same shape as the corrugated iron plate (2) on one side and a flat plate on the other side (9) An adhesive layer (10) is formed between the corrugated steel plate (2) and the corrugated stainless steel plate (2). An adhesive layer (10) is interposed on the surface of the polystyrene foam plate (9) on the surface of the shaped tin plate (2), and the solar cell (1) is joined and bonded to form the solar cell (1). FIG. 13 shows a longitudinal sectional view formed. FIG. 14 shows the formation of irregularities on the corrugated tin plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2). The rafter (3) is attached to the back surface of the corrugated steel plate (2) by using the nail (4) with the rafter (3) in the parallel direction along the direction of the convex shape. Corrugated sheet with exactly the same shape as corrugated sheet (2) on the surface of corrugated corrugated sheet (2) after fixing rafter (3) Adhesion between the plate (9) (hereinafter abbreviated as a polystyrene foam plate) and a corrugated tin plate (2) made of foamed polystyrene with the other side having a flat plate shape. A layer (10) is formed on the surface of a corrugated steel plate (2) and on the surface of a polystyrene foam plate (9). Adhesive layer (10) interposed therebetween, and the longitudinal cross-sectional view of forming a solar cell (1) adhered by bonding a solar cell (1), is shown in FIG. 14. FIG. 15 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), the bolt (5) is welded, or the bolt (5) is attached to the back surface of the corrugated stainless steel plate (2) using a metal adhesive. Using a rafter (3) and a bolt (5) and a nut (6) in a parallel direction along the concave shape on the concave back surface forming the irregularities, a corrugated steel plate ( After attaching rafters (3) to the back of 2) and fixing them, the corrugated steel plate (2) has the same shape as the corrugated steel plate (2) on the surface of the corrugated steel plate (2). Corrugated plate (9) (hereinafter abbreviated as Styrofoam) made of Styrofoam with a corrugated plate and the other side of a flat plate An adhesive layer (10) is formed between the corrugated steel plate (2) and the corrugated steel plate (2), and a polystyrene foam plate (2) is formed on the corrugated steel plate (2). FIG. 15 shows a longitudinal sectional view of the solar cell (1) formed by bonding and bonding the solar cell (1) with the adhesive layer (10) interposed on the surface of 9). FIG. 16 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), the nut (6) is welded to the back surface of the corrugated iron plate (2), or the nut (6) is fixed using a metal adhesive. The rafter (3) was fixed to the back surface of the corrugated steel plate (2) by using the bolt (5) on the back surface of the corrugated steel plate (2). Styrofoam with a corrugated plate shape that is exactly the same as the corrugated steel plate (2) on the surface of the corrugated steel plate (2), and the flat plate shape on the other side (9) (hereinafter abbreviated as polystyrene foam plate) and corrugated steel plate (2) An adhesive layer (10) is formed in the middle of the sheet, and an adhesive layer (10) is interposed on the surface of the polystyrene foam plate (9) on the surface of the corrugated stainless steel plate (2). FIG. 16 shows a longitudinal sectional view of the solar cell (1) formed by bonding and bonding 1). FIG. 17 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), after welding bolt (5) or using metal adhesive to fix bolt (5) to the back of corrugated stainless steel plate (2) The corrugated steel plate (2) has a corrugated plate shape that is exactly the same as the corrugated steel plate (2) on the surface of the corrugated steel plate (2), and the other surface is a styrofoam made of a flat plate. An adhesive layer (10) is formed between the finished plate (9) (hereinafter, abbreviated as a polystyrene foam plate) and a corrugated tin plate (2) to form a corrugated plate. An adhesive layer (10) is interposed on the surface of the polystyrene foam plate (9) on the surface of the tin plate (2), The longitudinal cross-sectional view forming a solar cell (1) adhered by bonding solar cell of (1), it is shown in Figure 17. FIG. 18 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), the nut (6) is welded to the back surface of the corrugated iron plate (2), or the nut (6) is corrugated using a metal adhesive. FIG. 18 shows a longitudinal sectional view of the solar cell (1) formed on the surface of the corrugated iron plate (2) after being fixed to the back surface of the iron plate (2). . FIG. 19 shows a rafter on the back surface of the corrugated steel plate (2) for the purpose of forming the solar cell (1) on the surface of the corrugated steel plate (2). For the purpose of fixing (3), the hook (7) is welded to the back surface of the corrugated steel plate (2) or the hook (7) is corrugated using a metal adhesive. Corrugated plate with exactly the same shape as the corrugated corrugated steel plate (2) on the surface of the corrugated corrugated steel plate (2) after fixing to the back surface of the corrugated corrugated steel plate (2) In the middle of the plate (9) (hereinafter abbreviated as a foamed polystyrene plate for short) made of foamed polystyrene having the other side of the other side and the corrugated stainless steel plate (2). (10) is formed on the surface of the corrugated stainless steel plate (2) of the polystyrene foam plate (9). Adhesive layer (10) is interposed on the surface, a longitudinal cross-sectional view forming a solar cell (1) adhered by bonding a solar cell (1), is shown in Figure 19. FIG. 20 shows a rafter on the back surface of the flat plate (8) made of flat plate for the purpose of forming the solar cell (1) on the surface of the flat plate (8) made of flat plate. (3) For the purpose of attaching etc., the surface of the tin plate (8) made of flat plate after the bolt (5) is welded or the bolt (5) is fixed using a metal adhesive A plate (9) (hereinafter abbreviated as polystyrene foam) made of foamed polystyrene having the same shape as the corrugated stainless steel plate (2) having the same shape on one side and the flat plate on the other side. An adhesive layer (10) is formed between the corrugated steel plate (2) and the corrugated steel plate (2), and a polystyrene foam plate (9) is formed on the corrugated steel plate (2). The solar cell (1) is bonded and pasted with the adhesive layer (10) interposed on the surface of The longitudinal cross-sectional view forming a solar cell (1) combined, is shown in Figure 20. FIG. 21 shows a rafter on the back surface of the steel plate (8) made of flat plate for the purpose of forming the solar cell (1) on the surface of the flat plate (8) made of flat plate. (3) The surface of the steel plate (8) made of a flat plate after the nut (6) is welded or the nut (6) is fixed using a metal adhesive for the purpose of attaching etc. A plate (11) made of foamed polystyrene having both flat sides on the upper side (hereinafter abbreviated as foamed polystyrene plate), a tin plate (8) made of flat plate, and a solar cell (1). On the surface of the flat plate (8) made of a flat plate by attaching and bonding the solar cell (1) to the flat plate (8) made of a flat plate with an adhesive layer (10) interposed therebetween. FIG. 21 shows a longitudinal sectional view forming the solar cell (1). For the purpose of forming the solar cell (1) on the surface of the steel plate (8) made of flat plate, FIG. 22 shows a rafter on the back surface of the steel plate (8) made of flat plate. (3) For the purpose of attaching etc., the surface of the steel plate (8) made of flat plate after the hook (7) is welded or the hook (7) is fixed using a metal adhesive A plate (11) (hereinafter abbreviated as a foamed polystyrene plate for short) made of foamed polystyrene having both sides flat on the upper side, a steel plate (8) made of a flat plate, and a solar cell (1). On the surface of the flat plate (8) made of a flat plate by attaching and bonding the solar cell (1) to the flat plate (8) made of a flat plate with an adhesive layer (10) interposed therebetween. FIG. 22 shows a longitudinal sectional view forming the solar cell (1). FIG. 23 shows a corrugated tin plate (2) and a solar cell for the purpose of directly attaching the solar cell (1) onto the surface of the corrugated tin plate (2). Packing for preventing penetration of rainwater and leakage of solar cell (1) on the surface of corrugated iron plate (2) by forming through holes in module forming battery (1) (12) is interposed, the corrugated iron plate (2) and the solar cell (1) are joined using bolts (5) and nuts (6) to further constitute a house. Using rafters (3), which are roofing materials, using bolts (5) and nuts (6), the corrugated stainless steel plate (2) and solar cell (1) are joined together. The corrugated iron plate (2) and the solar cell (1) are housed in the rafter (3) constituting the house. Configured and have bolts from the back side of the roof (5), and a longitudinal cross-sectional view is attached using nut (6), shown in Figure 23 has the. FIG. 24 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ) Between the foamed polystyrene plate (9) made of foamed polystyrene plate (9) with one side made of corrugated plate and the other side made of flat plate shape. 2) and a solar cell (1) between the solar cell (1), a through hole is formed in the module, and the solar cell (1) enters the rainwater on the surface of the corrugated iron plate (2), and The corrugated stainless steel plate (2) and the solar cell (1) are joined using the bolt (5) and the nut (6) with the packing (12) for preventing water leakage interposed. In addition, the rafter (3), which is the roofing material constituting the house, is bolted (5) and nuts. (6) is used to join the corrugated steel plate (2) and the solar cell (1) to form a corrugated steel plate (2), and the solar cell (1). FIG. 24 shows a longitudinal cross-sectional view in which the rafter (3) constituting the house is attached from the back surface of the roof constituting the house using the bolt (5) and the nut (6). Yes. FIG. 25 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ), A foamed polystyrene plate (11) made of a foamed polystyrene plate (11) on both sides is formed into a flat plate shape, a corrugated tin plate (2) and a solar cell (1). A through hole is formed in the module interposed between the solar cell (1) and the solar cell (1) on the surface of the corrugated steel plate (2) to prevent rainwater from entering and leakage (12) ), The corrugated iron plate (2) and the solar cell (1) are joined using bolts (5) and nuts (6), and the house is further constructed. Using bolts (5) and nuts (6) on the rafters (3), which is the roofing material, A rafter (2) constituting a corrugated steel plate (2) and a solar cell (1) in which a corrugated steel plate (2) and a solar cell (1) are joined to form a house. FIG. 25 shows a longitudinal sectional view in which the bolt (5) and the nut (6) are attached from the back of the roof constituting the house in 3). FIG. 26 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ), A foamed polystyrene plate (11) made of a foamed polystyrene plate (11) on both sides in a flat plate shape, a corrugated tin plate (2) and a solar cell (1) Bolts (5) and nuts (6) that are welded on the surface of corrugated stainless steel plate (2) or joined using metal adhesive are used. Then, a foamed polystyrene plate (11) having both sides made of a polystyrene foam plate (11) is formed in the middle, and a solar cell (11) is placed on the surface of the polystyrene foam plate (11). 1) After bonding the adhesive layer (10) The corrugated steel plate (2) and the solar cell (1), which are formed by joining the corrugated steel plate (2) and the solar cell (1) together, constitute a house. FIG. 26 shows a longitudinal sectional view in which the hook (7) is attached to the rafter (3) from the back surface of the roof constituting the house. FIG. 27 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ), A foamed polystyrene plate (11) made of a foamed polystyrene plate (11) on both sides in a flat plate shape, a corrugated tin plate (2) and a solar cell (1) Bolt (5) in which a module interposed in between is joined on the surface of corrugated iron plate (2) using welded part (13) or metal adhesive part (13) , And a nut (6), and a polystyrene foam plate (11) having both sides made of a polystyrene foam plate (11) having a flat plate shape is interposed in between. The solar cell (1) and the adhesive layer (10) on the surface of Then, after attaching the solar cell (1) to the corrugated iron plate (2) using the bolt (5) and the nut (6), the corrugated plate shape is The pad eye (7) is formed on the back surface of the iron plate (2), and the welded portion (13) or the metal adhesive portion (13) is formed on the back surface of the corrugated steel plate (2). FIG. 27 shows a longitudinal sectional view to which 7) is attached. FIG. 28 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ), A foamed polystyrene plate (11) made of a foamed polystyrene plate (11) on both sides in a flat plate shape, a corrugated tin plate (2) and a solar cell (1) Bolt (5) in which a module interposed in between is joined on the surface of corrugated iron plate (2) using welded part (13) or metal adhesive part (13) , And a nut (6), and a polystyrene foam plate (11) having both sides made of a polystyrene foam plate (11) in the form of a flat plate is interposed in between. The solar cell (1) and the adhesive layer (10) on the surface of Then, after attaching the solar cell (1) to the corrugated iron plate (2) using the bolt (5) and the nut (6), the corrugated plate shape is The pad eye (7) is formed on the back surface of the iron plate (2), and the welded portion (13) or the metal adhesive portion (13) is formed on the back surface of the corrugated steel plate (2). 7) After attaching the pad eye (7) to the rafter (3) constituting the house, using the L rod (14) with an n-shaped nut (6) at the tip of the pad eye (7) A corrugated plate shape is formed on a rafter (3) constituting a house by using a module formed with a solar cell (1) joined with a shaped tin plate (2) and a polystyrene foam plate (11) interposed therebetween. The rafters (3) that make up the house from the back of the iron plate (2) The longitudinal cross-sectional view is installed using Jo was nuts (6) with L rod (14) is shown in Figure 28. FIG. 29 shows a hook (7), a pad eye (7), a long eye (7), an open pad eye (7) on the back surface of a corrugated iron plate (2), or Eye strap (7), UK turnbuckle (7), or L bar with nut (hereinafter abbreviated to pad eye), pad eye (7) is welded part (13), or metal adhesive part FIG. 29 shows a longitudinal sectional view in which (13) is formed and the pad eye (7) is attached to the back surface of the corrugated iron plate (2). FIG. 30 shows a hook plate (7), a pad eye (7), a long eye (7), an open pad eye (7) on the back surface of a corrugated iron plate (2), or Eye strap (7), UK turnbuckle (7), or L bar with nut (hereinafter abbreviated to pad eye), pad eye (7) is welded part (13), or metal adhesive part An L-rod (14) with a nut (6) having a tip-shaped n-shape is formed on the pad eye (7) attached to the back surface of the corrugated iron plate (2). Using the corrugated iron plate (2) to the rafters (3) of the roof material constituting the house, the corrugated iron plate (2) from the back of the corrugated steel plate (2) to the rafters (3) A corrugated L-plate with nuts with an n-shaped tip and a corrugated steel plate (2) Using the pad eye (7) attached to the shaped tin plate (2), the longitudinal sectional view attached to the rafter (3) from the back surface of the corrugated tin plate (2) 30. FIG. 31 shows a hook plate (7), a pad eye (7), a long eye (7), an open pad eye (7) on the back surface of a corrugated tin plate (2), or Eye strap (7), UK turnbuckle (7), or L rod with nut (hereinafter abbreviated as pad eye), using paddle (15), pad eye (7), corrugated plate FIG. 31 shows a longitudinal sectional view attached to the shaped tin plate (2). FIG. 32 shows a hook plate (7), a pad eye (7), a long eye (7), an open pad eye (7) on the back surface of the corrugated iron plate (2), or Eye strap (7), UK turnbuckle (7), or L rod with nut (hereinafter abbreviated as pad eye), using paddle (15), pad eye (7), corrugated plate After attaching to the shaped tin plate (2), the pad eye (7) attached to the back surface of the corrugated tin plate (2) uses an L rod with a nut whose tip is n-shaped. Then, the corrugated iron plate (2) is applied to the rafters (3) of the roof material constituting the house, and the corrugated plate (2) from the back surface of the corrugated steel plate (2) to the rafters (3). Shaped iron plate (2) with an N-shaped L-bar with a tip and a corrugated plate FIG. 32 is a longitudinal sectional view attached to the rafter (3) from the back surface of the corrugated iron plate (2) using the pad eye (7) attached to the iron plate (2). It shows. FIG. 33 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). ), A foamed polystyrene plate (11) made of a foamed polystyrene plate (11) on both sides in a flat plate shape, a corrugated tin plate (2) and a solar cell (1) Bolt (5) in which a module interposed in between is joined on the surface of corrugated iron plate (2) using welded part (13) or metal adhesive part (13) , And a nut (6), and a polystyrene foam plate (11) having both sides made of a polystyrene foam plate (11) having a flat plate shape is interposed in between. The solar cell (1) and the adhesive layer (10) on the surface of Then, after attaching the solar cell (1) to the corrugated iron plate (2) using the bolt (5) and the nut (6), the corrugated plate shape is Hook (7), pad eye (7), long eye (7), open pad eye (7), eye strap (7), or UK turnbuckle (7) Or after attaching the pad eye (7) to the corrugated stainless steel plate (2) using a hook (15), an L rod with a nut (hereinafter referred to as pad eye for short) Corrugated steel plate (2) using an L-shaped rod with a nut whose tip is n-shaped on the pad eye (7) attached to the back surface of the corrugated steel plate (2) The corrugated sheet of rafter (3) of the roofing material that makes up the house A corrugated tin plate (2) is attached to the rafter (3) from the back surface of the plate (2) to an L rod with a nut having an n-shaped tip and a corrugated tin plate (2). FIG. 33 shows a longitudinal sectional view attached to the rafter (3) from the back surface of the corrugated iron plate (2) using the pad eye (7). FIG. 34 shows a corrugated corrugated steel plate (2), for example, a corrugated corrugated steel plate manufactured by Nisshin Steel Co., Ltd. using a ZAM steel plate. On the surface of (2), a concentrating solar cell (1) consisting of approximately 1 mm spherical solar cell surface (16), tempered glass (18) and reflecting mirror (17) is installed, and the solar cell is overheated. In order to suppress, the concentrating solar cell (1) characterized in that the lower portion (19) of the solar cell is brought into close contact with the peak portion of the corrugated iron plate (2) to dissipate heat from the tin plate (2). FIG. 34 shows a longitudinal sectional view of the iron plate (2). FIG. 35 shows a corrugated corrugated steel plate (2), for example, a corrugated corrugated steel plate manufactured by Nisshin Steel Co., Ltd. using a ZAM steel plate. Concentrating solar cell (1) consisting of approximately 1 cm cylindrical solar cell surface (16) pn junction, tempered glass (18) and reflecting mirror (17) negative electrode with (2) as reflector (17) In order to suppress the temperature overheating of the solar cell, the solar cell (1) and the corrugated plate shape with the solar cell lower part (19) as a negative electrode FIG. 35 shows a longitudinal cross-sectional view in which the galvanized iron plates are integrated. FIG. 36 shows a corrugated corrugated steel plate (2), for example, a corrugated corrugated steel plate manufactured by Nisshin Steel Co., Ltd. using a ZAM steel plate. (2) is a reflecting mirror (17), and the corrugated iron plate (2) is made of a copper pipe of about 1 cm at the top of the convex shape that is the concave and convex shape, about 1 cm Cylindrical solar cell surface (16) pn junction (hereinafter abbreviated as solar cell (1) or concentrating solar cell (1)), convex portion of corrugated iron plate (2) In order to suppress the overheating of the solar cell by integrally forming the solar cell (1) attached to the apex of the solar cell, the reflecting mirror (17), and the concentrating solar cell (1) composed of the negative electrode, A solar cell having a negative electrode at the lower part (19) of the solar cell (19) ) And a longitudinal section that integrates galvanized iron plate having a corrugated plate shape, is shown in Figure 36. FIG. 37 shows a nut (2) on the surface of the corrugated steel plate (2) for the purpose of mounting the solar cell (1) on the corrugated steel plate (2). 6) formed an arc welded part (13) or a metal adhesive part (13), and a nut (6) was fixed on the surface of the corrugated iron plate (2) to form a corrugated sheet A longitudinal sectional view of the tin plate (2) is shown in FIG. FIG. 38 shows a nut on the surface of the corrugated tin plate (2) for the purpose of mounting the solar cell (1) on the corrugated tin plate (2). 6) Arc welding part (13) or metal adhesive part (13) is formed, and after fixing nut (6) on the surface of corrugated iron plate (2), corrugated sheet An arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the shaped tin plate (2), and a pad eye (7), a long eye (7), or an open pad eye ( 7), or eye strap (7) (hereinafter abbreviated as pad eye), and the rafter (3) constituting the house from the back surface of the corrugated steel plate (2), The wave forming the solar cell (1) on the surface of the corrugated iron plate (2) The longitudinal cross-sectional view that tin plate having a corrugated plate shape rafter (3) constituting the house (2) attached from the back surface of the galvanized iron plate in the form (2), is shown in Figure 38. FIG. 39 shows a nut (on the surface of the corrugated steel plate (2) for the purpose of mounting the solar cell (1) on the corrugated steel plate (2). 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap (7) Hereinafter, short, pad eye to), the longitudinal cross-sectional view, a back surface on the formation of the tin plate having a corrugated shape (2), it is shown in Figure 39. FIG. 40 shows a nut (on the surface of the corrugated steel plate (2) for the purpose of mounting the solar cell (1) on the corrugated steel plate (2). 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap (7) Hereinafter, the corrugated tin is attached to the rafter (3) constituting the house on the back surface of the corrugated corrugated steel plate (2) using a pad eye for short. A longitudinal sectional view of the plate (2) is shown in FIG. In FIG. 41, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap (7) The roof of the house is constructed to attach the rafters (3) constituting the house on the back surface of the corrugated steel board (2) using a pad eye). A hole (22) is formed in the roof tile (21), and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and a nut with a nut whose tip is n-shaped. The bar (14) is made to penetrate the inside of the hole (22) formed in the roof tile (21), and the house is constructed using the L rod (14) with a nut having an n-shaped tip. The rafter (3), the solar cell (1) on the surface of the corrugated tin plate (2), and the sound insulation effect or heat insulation on the back surface of the corrugated tin plate (2). For the purpose of improving the effect or the adhesion to the roof tile (21), the polystyrene foam plate (11 The house is made of corrugated corrugated steel plate (2), with solar cell (1) formed on the surface of corrugated corrugated corrugated sheet (2), with a sandwich in the middle. The solar cell (1) is formed on the surface of the corrugated iron plate (2) on the surface of the roof made of tiles (21) that are firmly attached to the rafters (3). FIG. 41 shows a longitudinal sectional view of the corrugated tin plate (2). FIG. 42 shows a nut (on the surface of the corrugated tin plate (2) for the purpose of mounting the solar cell (1) on the corrugated tin plate (2). 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A plywood (20) made of a polystyrene foam plate and a plate made of aluminum is formed between the made tin plate (2) and the solar cell (1) with an adhesive layer (10) interposed. Then, after the lamination, an arc welded portion (13) or a metal adhesive portion (13) is further formed on the back surface of the corrugated iron plate (2) to form a pad eye (7), or Long eye (7) or open pad eye (7) or eye strap (7) The roof of the house is constructed to attach the rafters (3) constituting the house on the back surface of the corrugated steel board (2) using a pad eye). A hole (22) is formed in the roof tile (21), and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and a nut with a nut whose tip is n-shaped. The bar (14) is made to penetrate the inside of the hole (22) formed in the roof tile (21), and the house is constructed using the L rod (14) with a nut having an n-shaped tip. The rafter (3), the solar cell (1) on the surface of the corrugated tin plate (2), and the sound insulation effect or heat insulation on the back surface of the corrugated tin plate (2). For the purpose of improving the effect or adhesion to the roof tile (21), one side is corrugated and the other side is flat. Corrugated corrugated steel plate (9) having a solar cell (1) formed on the surface of corrugated corrugated steel plate (2) with a polystyrene foam plate (9) interposed in the middle. 2) is firmly attached to the rafter (3) constituting the house, and the solar cell (1) is formed on the surface of the corrugated iron plate (2) on the surface of the roof made of tiles (21). FIG. 42 shows a longitudinal sectional view of the corrugated tin plate (2) forming a). In FIG. 43, for the purpose of attaching the solar cell (1) on the surface of the flat plate (8) made of a flat plate, a nut ( 6) Form the arc welded part (13) or metal adhesive part (13) and fix the nut (6) on the surface of the corrugated stainless steel plate (2). A plywood plate (20) made of a polystyrene foam plate and a plate made of aluminum is formed between an aluminum plate (8) and a solar cell (1) with an adhesive layer (10) interposed therebetween. Then, after laminating, an arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the flat plate (8) made of a flat plate, and a pad eye (7), or Long eye (7), or open pad eye (7), or ice trap (7) To attach the rafters (3) constituting the house on the back surface of the steel plate (8) made of a flat plate (hereinafter referred to as pad eye for short) A hole (22) is formed in the tile (21) constituting the roof, and the pad eye (7) attached on the back surface of the flat plate (8) made of a flat plate and the tip portion are n-shaped. The L-shaped rod with nut (14) is made to pass through the inside of the hole (22) formed in the roof tile (21), and the L-shaped rod with nut (14) whose tip portion is n-shaped is used. The rafters (3) that make up the house, the solar cell (1) on the surface of the steel plate (8) made of flat plate, and the soundproofing on the back surface of the steel plate (8) made of flat plate For the purpose of improving the effect, the heat insulation effect, or the adhesion to the roof tile (21), both sides have a flat plate shape. A steel plate (11) made of a flat plate (11) is formed on the surface of a flat plate-like tin plate (8) with a steel plate (11) interposed in the middle. 8) is firmly attached to the rafters (3) constituting the house, on the surface of the roof made of tiles (21), on the surface of the tin plate (8) made of flat plates (1) 43 is a longitudinal sectional view of the tin plate (8) made of a flat plate forming the solar cell (1) on the surface of the flat plate (8) made of a flat plate forming a). ing. FIG. 44 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a plywood (20) (hereinafter abbreviated as Mirapane Ace 20) and a solar cell (1) made of a polystyrene foam plate and a plate made of aluminum, and an adhesive layer (10) In addition, the one side is corrugated and the other side is flat between the Mirapane Ace (20) and the corrugated iron plate (2) and the Mirapane Ace (20). After bonding the laminated polystyrene sheet (9) to the corrugated steel plate (2) with the adhesive layer (10) interposed, the corrugated steel plate (2) ) Arc welded part (13) or gold on the back Nut (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut) by forming an adhesive part (13) The roof tile of the house is attached to the rafter (3) constituting the house on the back surface of the corrugated iron plate (2) using the pad eye) A hole (22) is formed in (21), and a pad eye (7) attached on the back surface of the corrugated stainless steel plate (2) and an L rod with nut (14) having an n-shaped tip. ) Through the inside of the hole (22) formed in the roof tile (21) and using an L-shaped rod (14) with a nut having an n-shaped tip, the rafter constituting the house In (3), on the surface of the corrugated iron plate (2), the solar cell (1) and For the purpose of improving the soundproofing effect, the heat insulating effect, or the adhesion to the roof tile (21) on the back surface of the corrugated iron plate (2), one side is corrugated and the other side is flat. The shaped polystyrene foam plate (9) is sandwiched in the middle to form a solar cell (1) on the surface of the corrugated iron plate (2). The tin plate (2) is firmly attached to the rafter (3) constituting the house, and the sun is placed on the surface of the corrugated tin plate (2) on the surface of the roof made of tiles (21). FIG. 44 shows a longitudinal sectional view of a corrugated iron plate (2) forming the battery (1). FIG. 45 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a polystyrene foam plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is joined to a corrugated steel plate (2) with an adhesive layer (10) interposed therebetween. After the lamination, the arc welded portion (13) or the metal adhesive portion (13) is further formed on the back surface of the corrugated tin plate (2) to form the nut (7) or the pad eye. (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter, abbreviated as nut or pad eye) Attach the rafters (3) that make up the house on the back of the board (2) In addition, a hole (22) is formed in the tile (21) constituting the roof of the house, and the pad eye (7) attached to the back surface of the corrugated iron plate (2) and the tip portion are An L-shaped rod with nut (14) having an n-shape is passed through a hole (22) formed in the roof tile (21), and an L-shaped rod with nut (14) having an n-shaped tip is formed. Using the rafters (3) constituting the house, the solar cell (1) on the surface of the corrugated steel plate (2), and the corrugated steel plate (2) For the purpose of enhancing the soundproofing effect, the heat insulating effect, or the adhesion to the roof tile (21) on the back surface, a polystyrene foam plate (9) having a corrugated shape on one side and a flat shape on the other side is sandwiched. The solar cell (1) is formed on the surface of the corrugated iron plate (2) with the intervening in the middle The corrugated corrugated steel plate (2) is firmly attached to the rafter (3) constituting the house, and the corrugated corrugated corrugated steel plate is formed on the roof surface made of tiles (21). The longitudinal cross-sectional view of the corrugated iron plate (2) which forms the solar cell (1) on the surface of (2) is shown in FIG. FIG. 46 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a plywood (20) (hereinafter abbreviated as Mirapane Ace 20) and a solar cell (1) made of a polystyrene foam plate and a plate made of aluminum, and an adhesive layer (10) In addition, the one side is corrugated and the other side is flat between the Mirapane Ace (20) and the corrugated iron plate (2) and the Mirapane Ace (20). Surface of corrugated corrugated steel plate (2) in which a styrofoam sheet (9) shaped is joined and laminated to corrugated corrugated steel sheet (2) with adhesive layer (10) interposed Corrugated sheet with solar cell (1) on top An arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the plate (2) to form a nut (7), a pad eye (7), a long eye (7), or an open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut or pad eye) attached on the back surface of corrugated corrugated steel plate (2), corrugated corrugated steel plate FIG. 46 shows a longitudinal sectional view of a corrugated iron plate (2) in which a solar cell (1) is formed on the surface of (2). FIG. 47 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a polystyrene foam plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is joined to a corrugated steel plate (2) with an adhesive layer (10) interposed therebetween. After the lamination, the arc welded portion (13) or the metal adhesive portion (13) is further formed on the back surface of the corrugated tin plate (2) to form the nut (7) or the pad eye. (7), or long eye (7), or open pad eye (7), or eye strap (7) (hereinafter, abbreviated as a nut or pad eye) attached corrugated steel plate A corrugated plate with a solar cell (1) formed on the surface of (2) A longitudinal section of the end plate (2), is shown in Figure 47. FIG. 48 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a plywood (20) (hereinafter abbreviated as Mirapane Ace 20) and a solar cell (1) made of a polystyrene foam plate and a plate made of aluminum, and an adhesive layer (10) In addition, the one side is corrugated and the other side is flat between the Mirapane Ace (20) and the corrugated iron plate (2) and the Mirapane Ace (20). After bonding the laminated polystyrene sheet (9) to the corrugated steel plate (2) with the adhesive layer (10) interposed, the corrugated steel plate (2) ) Arc welded part (13) or gold on the back Nut (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut) by forming an adhesive part (13) In addition, for the purpose of enhancing the soundproofing effect, the heat insulating effect, or the adhesion with the roof tile (21) on the back surface of the corrugated stainless steel plate (2) after attaching the pad eye) Surface of corrugated corrugated steel plate (2) by sandwiching a foamed polystyrene plate (9) with a corrugated plate on one side and a flat plate on the other surface with an adhesive layer (10) in the middle FIG. 48 shows a longitudinal sectional view on which the solar cell (1) is formed. FIG. 49 shows a corrugated tin plate (2) and a solar cell (1) for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2). In between, a polystyrene foam plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is joined to a corrugated steel plate (2) with an adhesive layer (10) interposed therebetween. After the lamination, the arc welded portion (13) or the metal adhesive portion (13) is further formed on the back surface of the corrugated tin plate (2) to form the nut (7) or the pad eye. (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut or pad eye) The soundproofing effect or heat insulation effect on the back side For the purpose of improving the adhesion to the roof tile (21), a styrofoam plate (9) having a corrugated shape on one side and a flat shape on the other side is sandwiched with an adhesive layer (10) in the middle. FIG. 49 shows a longitudinal sectional view in which the solar cell (1) is formed on the surface of the corrugated iron plate (2). In FIG. 50, for the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a nut ( 6) After forming the arc welding part (13) or the metal adhesive part (13) and fixing the nut (6) on the corrugated iron plate (2) surface, A laminated board (20) made of a foamed polystyrene board and a board made of aluminum foil is interposed between the made tin plate (2) and the solar battery (1) with an adhesive layer (10) interposed. After forming and laminating, an arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7). Or long eye (7) or open pad eye (7) or eye strap (7 (Hereafter, abbreviated as pad eye), the roof of the house is constructed to attach the rafter (3) constituting the house on the back surface of the corrugated iron board (2). A hole (22) is formed in the roofing tile (21), with a pad eye (7) attached on the back surface of the corrugated stainless steel plate (2) and a nut having a n-shaped tip. The L bar (14) is made to penetrate the inside of the hole (22) formed in the roof tile (21), and the house is constructed using the L bar (14) with a nut having an n-shaped tip. The corrugated iron plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2) on the rafter (3), and the tip portion has an n-shape. The L-shaped rod with nut (14) is passed through the hole (22) formed in the roof tile (21) to form a corrugated plate. When the tin plate (2) is attached and fixed to the rafters (3) constituting the house, rainwater leaks from the holes (22) formed in the roof tile (21), and rainwater enters the house. In order to prevent the roof tile (21) from being integrated, the structure having a long cylindrical shape (23) of about 5 cm is combined with the roof tile (21) from the surface of the roof tile (21). The corrugated tin plate (2) is fixed by using an L-shaped rod (14) with a nut whose tip is n-shaped. Furthermore, the nut-attached L rod (14) whose tip portion penetrating the inside of the cylindrical shape (23) is an n-shape is a sealant (24) inside the cylindrical shape (23), for example, Using an adhesive made of silicone resin or the like, the inside of the cylindrical shape (23) formed on the roof tile (21) united with the roof tile (21) is sealed with the sealant (24). Is used to prevent rainwater from leaking into the house from the hole (22) formed in the roof tile (21). Alternatively, the packing (24) made of silicone resin or the like is inserted into the cylindrical shape (23) instead of the sealant (24), and the L-rod with nut (14) having an n-shaped tip portion. ) Is formed in the roof tile (21) by being sealed inside the cylindrical shape (23) formed in the roof tile (21) which is integrated with the roof tile (21). The longitudinal cross-sectional view of the roof tile (21) united with the roof tile (21) and the cylindrical shape (23), which has a structure capable of preventing rainwater from leaking into the house from the hole (22). This is shown in FIG. FIG. 51 shows an enlarged view of the drawing shown in FIG. 50. The hatched portion injects sealant (24) or packing, and rainwater leaks and cannot enter the house. FIG. 51 shows a longitudinal cross-sectional view of the roof tile (21) having a structure in which the roof tile (21) and the cylindrical shape (23) are united. FIG. 52 shows a corrugated iron plate (2) having a corrugated iron plate (8) made of a flat plate with an adhesive layer (10) or a double-sided tape (10) (hereinafter abbreviated). The surface of the steel plate (8) made of a flat plate after bonding and bonding on the surface of the corrugated steel plate (2) using the adhesive layer (10)) FIG. 52 shows a longitudinal sectional view in which the solar cell (1) is bonded to the adhesive layer (10) formed thereon. As shown in FIG. 53, FIG. 53 shows that the iron plate (8) made of a flat plate is formed on the surface of the corrugated steel plate (2) in the same manner as the content shown in FIG. 53. Or a flat plate after bonding and bonding on the surface of a corrugated iron plate (2) using a double-sided tape (10) (hereinafter abbreviated as an adhesive layer (10)) FIG. 53 shows a longitudinal cross-sectional view in which the solar cell (1) is bonded on the surface of the tin plate (8) made of the above by forming the adhesive layer (10). 53 is different from FIG. 52 in that the corrugated steel plate (2) is attached to a rafter (3) which is a roof material constituting a house. FIG. 54 shows a tin plate made of a flat plate by forming an adhesive layer (10) on a surface of a corrugated tin plate (2) and forming an adhesive plate (8) on the surface of the corrugated steel plate (2). FIG. 54 shows a longitudinal sectional view in which the plate (8) is bonded and bonded to the surface of the corrugated iron plate (2). As shown in FIG. 55, as in the case of the contents shown in FIGS. 52 and 53, the flat plate (8) made of a flat plate is bonded onto the surface of the corrugated stainless steel plate (2). Using a layer (10) or a double-sided tape (10) (hereinafter, abbreviated as an adhesive layer (10)), bonding was performed on the surface of a corrugated stainless steel plate (2). FIG. 55 shows a longitudinal sectional view in which the solar cell (1) is bonded to the surface of the platinum plate (8) made of a flat plate by forming the adhesive layer (10) on the surface. Also, FIG. 55 is different from FIGS. 52 and 53 in that the corrugated iron plate (2) is attached to a rafter (3) which is a roof material constituting the house. FIG. 56 shows a corrugated iron plate (2) made of corrugated iron plate (2) by using nails (4) on the rafters (3) of the roof material constituting the roof of the house. After attaching the tin plate to the rafter (3) using the nail (4) on the rafter (3) or the like, the tin plate (8) made of a flat plate on the surface of the corrugated tin plate (2) ) To form a bonding layer (10) and then bond them together to form a solar cell (1) on the surface of a platinum plate (8) made of a flat plate. FIG. 56 shows a longitudinal cross-sectional view in which bonding is performed by bonding. As shown in FIG. 56, FIG. 57 shows that the corrugated steel plate (2) is bolted to the rafters (3) of the roof material constituting the roof of the house (5). ), And the nut (6), the corrugated iron plate is attached to the rafter (3) etc. by using the bolt (5) and the nut (6) to attach the rafter (3), After the corrugated iron plate (2) is made of a flat plate on the surface of the corrugated steel plate (2), the adhesive layer (10) is formed and bonded to form a flat plate. FIG. 57 shows a longitudinal sectional view in which the solar cell (1) is bonded to the surface of the metallic plate (8) by forming the adhesive layer (10) and bonding them. Also, FIG. 57 differs from FIG. 56 in that the corrugated iron plate (2) is attached to a rafter (3) which is a roof material constituting the house. FIG. 58 shows a corrugated tin plate (1) formed directly on the surface of a corrugated tin plate (2) by forming an adhesive layer (10) on the surface of the corrugated tin plate (2). The bolt (5) and the nut (6) attached to the back surface of the corrugated iron plate (2) after the solar cell (1) is bonded to the surface of 2) and bonded. FIG. 58 shows a longitudinal sectional view of the corrugated iron plate (2) attached to the rafter (3), which is a roof material constituting the house, from the back surface. As shown in FIG. 59, the steel plate (8) made of a flat plate is bonded on the surface of the corrugated steel plate (2) in the same manner as shown in FIGS. After the layer (10) is formed and bonded, the solar cell (1) is further bonded to the surface of the platinum plate (8) made of a flat plate. FIG. 59 shows a longitudinal sectional view in which the bonding is performed. 59 differs from FIGS. 57 and 58 in the means for attaching the corrugated iron plate (2) to the rafter (3), which is a roof material constituting the house. As shown in FIG. 59, FIG. 60 shows a corrugated tongue in which a pad eye (7) is attached on the back surface of the corrugated tongue plate (2). The solar cell (1) is formed on the surface of the plate (2) to form the adhesive layer (10), and the solar cell (1) is directly adhered to the surface of the corrugated iron plate (2). The solar cell (1) is formed on the surface of the corrugated stainless steel plate (2) joined together, and the house is further formed on the back surface of the corrugated steel plate (2). FIG. 60 shows a longitudinal cross-sectional view in which a pad eye (7), which is a metal fitting for attaching a corrugated steel plate (2), is attached to a rafter (3), which is a roof material, or the like. ing. FIG. 61 shows a longitudinal sectional view of an enlarged view of the drawing shown in FIG. FIG. 62 shows from the back surface the tin plate (8) made of flat plate on the roof material or wall material constituting the house on the back surface of the flat plate (8) made of flat plate. For the purpose of mounting, the solar cell (1) is bonded onto the surface of the tin plate (8) made of flat plate after attaching the nut (6) to the back surface of the flat plate (8) made of flat plate. FIG. 62 shows a longitudinal cross-sectional view of a flat plate (8) made of a flat plate on which the layer (10) is formed and attached. In FIG. 63, the steel plate (8) made of a flat plate on the back surface of the steel plate (8) made of a flat plate or the roof material constituting the house or the wall material is shown from the back surface. For the purpose of mounting, the solar cell (1) is bonded on the surface of the flat plate (8) made of flat plate after the bolt (5) is attached to the back surface of the flat plate (8) made of flat plate. FIG. 63 shows a longitudinal cross-sectional view of a flat plate (8) made of a flat plate on which the layer (10) is formed and attached. FIG. 64 shows the back of the steel plate (8) made of a flat plate, the roof plate constituting the house, or the steel plate (8) made of a flat plate on the wall material from the back side. For the purpose of attachment, the solar cell (1) is bonded onto the surface of the flat plate (8) made of flat plate after the hook (7) is attached to the back surface of the flat plate (8) made of flat plate. FIG. 64 shows a longitudinal cross-sectional view of a flat plate (8) made of a flat plate on which the layer (10) is formed and attached. In FIG. 65, the steel plate (8) made of a flat plate is formed on the back surface of the steel plate (8) made of a flat plate from the back surface. For the purpose of attachment, the solar cell (1) is placed on the surface of the flat plate (8) made of flat plate after the pad eye (7) is attached to the back surface of the flat plate (8) made of flat plate. FIG. 65 shows a longitudinal cross-sectional view of a flat plate (8) made of a flat plate to which an adhesive layer (10) is formed and attached. FIG. 66 shows a roof that constitutes a house with a folded-plate-shaped iron plate (hereinafter abbreviated as a folded-plate roof) made of an iron plate that forms the folded-plate roof (25). For the purpose of attaching the folded-plate roof (25) to the rafter (3) or the like from the back surface to the rafter (3), which is a material, a nut ( FIG. 66 shows a longitudinal sectional view of the folded plate roof (25) to which a metal fitting such as 6) is attached. FIG. 67 shows a roof that constitutes a house made of a folded-plate-shaped iron plate (hereinafter abbreviated as a folded-plate roof) made of an iron plate that forms a folded-plate roof (25). For the purpose of attaching the folded-plate roof (25) to the rafter (3) or the like from the back surface to the rafter (3), which is a material, bolts ( FIG. 67 shows a longitudinal sectional view of the folded plate roof (25) to which a metal fitting such as 5) is attached. FIG. 68 shows a roof that constitutes a house from a folded-plate-shaped iron plate (hereinafter abbreviated as a folded-plate roof) made of an iron plate that forms the folded-plate roof (25). For the purpose of attaching the folded-plate roof (25) to the rafter (3) or the like from the back surface to the rafter (3), which is a material, pad eye on the back surface of the folded-plate roof (25) FIG. 68 shows a longitudinal sectional view of the folded plate roof (25) to which a metal fitting such as (7) is attached. As shown in FIGS. 66, 67, and 68, FIG. 69 shows a rafter (3) that constitutes the roofing material of the house on the back surface of the folded plate roof (25). In addition, for the purpose of attaching the folded plate roof (25) from the back side to the rafter (3) or the like, a pad eye (7) or the like is connected on the back surface of the folded plate roof (25). After attaching the metal fittings, an adhesive layer (10) is formed on the surface of the folded plate roof (25), and an adhesive layer (10) is formed on the surface of the folded plate roof (25). Let them join. Further, the solar cell (1) is bonded to the surface of the tin plate (8) made of a flat plate bonded and bonded to the surface of the folded plate roof (25) by forming an adhesive layer (10). FIG. 69 shows a longitudinal cross-sectional view of the folded plate roof (25) joined together. As shown in FIGS. 66, 67, 68 and 69, FIG. 70 shows a rafter (3) constituting the roof material of a house on the back surface of the folded plate roof (25). ), And the plate-shaped foamed polystyrene plate (11), the folded plate roof (25) is attached to the folded plate roof (25) from the rear surface to the rafter (3), and the plate-shaped foamed polystyrene plate (11). For this purpose, a metal plate (8) made of a flat plate on the surface of the folded plate roof (25) after attaching fittings such as pad eyes (7) on the back surface of the folded plate roof (25) A bonding layer (10) is formed and bonded onto the surface of the folded plate roof (25) for bonding. Further, the solar cell (1) is bonded to the surface of the tin plate (8) made of a flat plate bonded and bonded to the surface of the folded plate roof (25) by forming an adhesive layer (10). FIG. 70 shows a longitudinal cross-sectional view of the folded plate roof (25) joined together. FIG. 71 shows a folded plate roof (25) from the back surface to the rafter (3) constituting the roof material of the house on the back surface of the folded plate roof (25). ) On the surface of the folded plate roof (25) after attaching a fitting for connection such as a pad eye (7) on the back surface of the folded plate roof (25) for the purpose of attaching to the rafter (3), etc. FIG. 71 shows a longitudinal sectional view of a folded plate roof (25) in which the solar cell (1) is bonded by forming an adhesive layer (10). FIG. 72 shows a folded plate roof on the back surface of the folded plate roof (25), a rafter (3) constituting the roof material of the house, and a flat polystyrene foam plate (11). For the purpose of attaching (25) the folded plate roof (25) to the rafter (3) and the flat polystyrene foam plate (11) from the back side, pad eyes (7 ) And the like, and the folded plate roof (10) is formed by bonding the solar cell (1) on the surface of the folded plate roof (25) after attaching the connecting metal fittings. FIG. 72 shows a longitudinal sectional view of 25). FIG. 73 shows the folded plate roof (25) on the back surface of the folded plate roof (25), the rafter (3) that is a roof material constituting the house, and the like. ) Is attached to the rafter (3) from the back surface of the folded plate roof (25) by attaching a metal fitting such as a pad eye (7) to the double-sided tape (13), the adhesive layer (13), or the welded portion (13). ) (Hereinafter abbreviated as double-sided tape), the solar cell (1) is directly mounted on the surface of the folded plate roof (25) after being mounted on the back surface of the folded plate roof (25). FIG. 73 shows a longitudinal sectional view in which the adhesive layer (10) is formed on the surface of the folded plate roof (25) and the solar cell (1) is attached on the surface of the folded plate roof (25). FIG. 74 shows a corrugated iron plate (2) or a slate roof (2) (hereinafter referred to as corrugated steel plate or slate roof for short). Pads for the purpose of attaching the slate roof (2) to the rafters (3), which is the roofing material constituting the house, and the slate roof (2) from the back of the slate roof (2) to the rafters (3), etc. On the back surface of the slate roof (2) using a double-sided tape (13), an adhesive layer (13), or a welded part (13) (hereinafter abbreviated as double-sided tape) with a metal fitting such as eye (7) On the surface of the slate roof (2), the solar cell (1) is formed on the surface of the slate roof (2) and the adhesive layer (10) is directly formed on the surface of the slate roof (2). 74 is a longitudinal sectional view of the solar cell (1) attached to FIG. It is. FIG. 75 shows the conventional asbestos slate for the purpose of performing repair work by reinforcing the strength of the asbestos slate 26, which has become fragile and becomes dangerous after several decades. Asbestos forming plate 26 (hereinafter abbreviated as asbestos slate) 26, which is formed by cementing asbestos with cement, is bolted from the back surface of the rafter 3 constituting the roof material of the house. 5 and a longitudinal sectional view attached to the rafter 3 using the nut 6 are shown in FIG. FIG. 76 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since the old asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. On the surface of the asbestos slate 26, the foamed polystyrene plate is made of a foamed polystyrene 27 having one side shaped as an asbestos slate 26 and the other side shaped as a flat plate. In addition, the load that can be withstood on the surface of the asbestos slate 26 is laid down on the surface of the asbestos slate 26 and stacked, for example, the limit that a human can withstand on the surface of the asbestos slate 26. FIG. 76 shows a longitudinal sectional view of the structure in which the load of the asbestos slate 26 can withstand a human load. FIG. 77 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. Asbestos slate is formed by laying and stacking foamed polystyrene 28 having a flat plate shape on both sides of the asbestos slate 26 on the surface of the asbestos slate 26. For example, a structure in which the load of the asbestos slate 26 can withstand the load of the human being is more than the limit that the human can freely walk on the surface of the asbestos slate 26. A longitudinal sectional view is shown in FIG. FIG. 78 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed and the strength of the asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having one side of the shape of the asbestos slate 26 and the other side having the slate roof shape. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. FIG. 78 shows a longitudinal sectional view showing a structure in which the load of the asbestos slate 26 exceeding the limit can withstand a human load. FIG. 79 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since the old asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having one side of the shape of the asbestos slate 26 and the other side having the slate roof shape. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 exceeding the limit is able to withstand human loads, and the slate roof 25 is stacked and laminated on the surface of the polystyrene foam 29, and the rafter 3, asbestos slate 26, polystyrene foam are laminated. 29, and the four types of panels of the slate roof 25 using the bolts 5 and nuts 6 and the roofing material constituting the house. FIG. 79 shows a longitudinal sectional view of the slate roof 25 in which the slate roof 25 is attached to the rafter 3 by laminating from above and below, and as a result, the polystyrene foam 29 is interposed and the asbestos slate 26 is fixed. Yes. FIG. 80 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26, which has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roof material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having a shape of the asbestos slate 26 on one side and a polystyrene 29 having a slate roof on the other side. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 exceeding the limit is able to withstand human loads, and the slate roof 25 is stacked and laminated on the surface of the polystyrene foam 29, and the rafter 3, asbestos slate 26, polystyrene foam are laminated. 29, and four types of panels of the slate roof 25, the pad eye 7, and the L-rod 14 with a nut whose tip is an n-shape. Thus, the slate roof 25 in which the slate roof 25 is stacked and attached from the lower surface which is the back surface of the rafter 3 which is the roof material constituting the house, and as a result, the polystyrene foam 29 is replaced with the asbestos slate 26. FIG. 80 shows a longitudinal sectional view in which the asbestos slate 26 is interposed between the slate roof 25 and the asbestos slate 26. FIG. 81 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since it became old and becomes brittle and dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene board made of the above-mentioned foamed polystyrene board has a flat-faced foamed polystyrene 28 that is laid on the surface of the asbestos slate 26 and stacked to form a load that can be withstood on the surface of the asbestos slate 26. For example, on the surface of the polystyrene foam 28 after the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human beings, which is more than the limit that a human can withstand walking freely. In addition, the slate roof 25 is stacked and laminated, and four types of panels, a rafter 3, an asbestos slate 26, a polystyrene foam 28, and a slate roof 25, are formed with a pad eye 7 and a nut L with a n-shaped tip. Using the bar 14, the slate roof 25 is piled up and down from the lower surface which is the back surface of the rafter 3 which is the roof material constituting the house. As a result, the slate roof 25 is fixed to the asbestos slate 26 by interposing the polystyrene foam 28 between the asbestos slate 26 and the slate roof 25, and the nut 6 and the pad eye on the surface of the slate roof 25. FIG. 81 shows a longitudinal sectional view in which the solar cell 1 is mounted and fixed on the surface of the slate roof 25 using the bolts 7 and 5. FIG. 82 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes fragile after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. On the surface of the asbestos slate 26, the foamed polystyrene plate is made of a polystyrene foam 27 having one side of the shape of the asbestos slate 26, and the other side of the polystyrene foam 27 having a flat plate shape. In addition, the load that can be withstood on the surface of the asbestos slate 26 is laid down on the surface of the asbestos slate 26 and stacked, for example, the limit that a human can withstand on the surface of the asbestos slate 26. After the above-described structure in which the load of the asbestos slate 26 can withstand the load of human weight is formed, the slate roof 25 is stacked on the surface of the polystyrene foam 27, and the rafter 3, the asbestos slate 26, Using four types of panels, polystyrene foam 27 and slate roof 25, pad eye 7, and L-rod 14 with nut whose tip is n-shaped. Then, the slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roof material constituting the house from the top and bottom, and as a result, the polystyrene foam 27 is connected to the asbestos slate 26 and the slate roof 25. The solar cell 1 is mounted on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. FIG. 82 shows a vertical cross-sectional view of the fixed parts. FIG. 83 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes obsolete after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate is made of a foamed polystyrene plate 29. The foamed polystyrene plate 29 has the shape of an asbestos slate 26 on one side and the slate roof 25 on the other side. Are placed on the surface of the asbestos slate 26 and stacked on top of the surface of the asbestos slate 26 so that a load that can be tolerated on the surface of the asbestos slate 26 is applied by, for example, a person on the surface of the asbestos slate 26. The asbestos slate 26 has a structure that can withstand the weight of human beings, and the slate roof 25 is laminated on the surface of the foamed polystyrene 29 after the load of the asbestos slate 26 exceeds the limit that can withstand walking freely. , Rafter 3, asbestos slate 26, styrofoam 29, and slate roof 25, four types of panels, pad eye 7 and tip portion A slate roof that is attached by stacking slate roofs 25 from above and below from the bottom surface of the rafter 3 that is the roofing material that constitutes the house, using the L-shaped nut-attached L bar 14 25. As a result, after the foamed polystyrene 29 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26, the nut 6, the pad eye 7, and FIG. 83 shows a longitudinal sectional view in which the solar cell 1 is mounted and fixed on the surface of the slate roof 25 using the bolts 5. FIG. 84 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape and the other side with a slate roof 25, and the foamed polystyrene 30 having the shape of the slate roof 25 is replaced with asbestos. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. Asbestos slate 26, Styrofoam 30 and slate roof 25, four types of panels, pad eye 7 and the tip portion was n-shaped The slate roof 25 attached by stacking the slate roof 25 from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material constituting the house, using the L bar 14 with a tut, As a result, the nut 6, the pad eye 7, and the bolt 5 are placed on the surface of the slate roof 25 after the polystyrene foam 30 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26. FIG. 84 shows a longitudinal sectional view in which the solar cell 1 is attached and fixed on the surface of the slate roof 25 by using it. FIG. 85 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the dangerous asbestos slate 26 after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. The foamed polystyrene plate is made of a foamed polystyrene plate of 685 mm. The foamed polystyrene plate 27 is a foamed polystyrene 27 having a flat shape on one side and the slate roof 25 on the other side. On the surface of the asbestos slate 26, the layers are laid and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, is free After assembling a structure in which the load of the asbestos slate 26 that can withstand the load of human weight is more than the limit that can be tolerated by walking, the slate roof 25 is stacked on the surface of the polystyrene foam 27, and laminated. Four types of panels, rafters 3, asbestos slate 26, polystyrene foam 27, and slate roof 25, are used with bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roof material constituting the house and stacked, and as a result, the polystyrene foam 27 is placed between the asbestos slate 26 and the slate roof 25. The solar cell 1 is fixed on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. FIG. 85 shows a longitudinal sectional view. FIG. 86 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. On the surface of the asbestos slate 26, the layers are laid and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, can be freely After assembling a structure in which the load of the asbestos slate 26 that can withstand the load of human weight is more than the limit that can be tolerated by walking, the slate roof 25 is stacked on the surface of the polystyrene foam 30 and laminated. Four types of panels, rafter 3, asbestos slate 26, styrofoam 30 and slate roof 25, are used with bolt 5 and nut 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 which is the roof material constituting the house is stacked, and as a result, the polystyrene foam 30 is placed between the asbestos slate 26 and the slate roof 25. The solar cell 1 is fixed on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. FIG. 86 shows a longitudinal sectional view. FIG. 87 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. The foamed polystyrene plate has a foamed polystyrene 27 in which one side has the shape of asbestos slate 26 and the other one side has a flat plate shape. The surface of the asbestos slate 26 is laid on top of the surface of the asbestos slate 26 and laminated to withstand the load that can be withstood on the surface of the asbestos slate 26, for example, even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 that can exceed the maximum possible load can withstand the weight of human beings is formed, and the slate roof 25 is stacked on the surface of the polystyrene foam 27, and the rafter 3 and asbestos slate are stacked. 26, styrofoam 27, and slate roof 25 are used to construct a house using bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 that is the roof material is stacked, and as a result, the polystyrene foam 27 is interposed between the asbestos slate 26 and the slate roof 25, and the asbestos slate. 26, on the surface of the slate roof 25, and further on the surface of the expanded polystyrene 28 after laminating the expanded polystyrene 28 having a flat plate shape on both sides. In the upper Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) is manufactured and sold. The solar cell (1) is placed on the surface of the polystyrene foam 28 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the polystyrene foam 28. FIG. 87 shows a longitudinal sectional view attached and fixed. FIG. 88 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by strengthening the strength of the asbestos slate 26 which has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a foamed polystyrene board of 685 mm, and the foamed polystyrene board is laminated on the surface of the asbestos slate 26 by laminating and stacking the foamed polystyrene 28 having both sides flat on the surface of the asbestos slate 26. Of the expanded polystyrene 28 after the load of the asbestos slate 26 is made a structure that can withstand the load of human beings, for example, exceeding the limit that a human can freely walk on the surface of the asbestos slate 26. A slate roof 25 is stacked on the surface and laminated, and four types of panels, rafters 3, asbestos slate 26, polystyrene foam 28, and slate roof 25, are constructed using bolts 5 and nuts 6. As a result, the slate roof 25 in which the slate roof 25 is attached to the rafter 3 which is the roofing material by overlapping the layers from above and below is laminated. After the roll 28 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26, a foamed polystyrene 28 having a flat plate shape on both sides is further formed on the surface of the slate roof 25. After the lamination, on the surface of the polystyrene foam 28, for example, the location is Kami Toba Taichocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21), and manufactures and sells it. The solar cell (1) having the product name spherical silicon solar cell lightweight module is placed on the surface of the foamed polystyrene 28 using the nut 6, the pad eye 7 and the bolt 5 on the surface of the foamed polystyrene 28. FIG. 88 shows a longitudinal sectional view attached and fixed. FIG. 89 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape, and the other side has a slate roof 25 with the shape of the slate roof 25. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. , Asbestos slate 26, styrofoam 30, and slate roof 25, using bolts 5 and nuts 6 to construct the house. The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 which is the roofing material being stacked, and as a result, the polystyrene foam 30 is interposed between the asbestos slate 26 and the slate roof 25. On the surface of the slate roof 25 after being fixed to the asbestos slate 26, the shape of the slate roof 25 is a foamed polystyrene 30 having a flat shape on one side and the slate roof 25 on the other side. On the surface of the expanded polystyrene 30, for example, the location is Kamitoba Daichocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21), which manufactures and sells. A solar cell (1) having a product name of a spherical silicon solar cell light-weight module, a nut 6, a pad eye 7, and FIG. 89 shows a longitudinal sectional view in which the solar cell (1) is attached and fixed on the surface of the foamed polystyrene 30 using the bolt 5. FIG. 90 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 which has become fragile and becomes obsolete after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape, and the other side has a slate roof 25 with the shape of the slate roof 25. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. , Asbestos slate 26, styrofoam 30, and slate roof 25, using bolts 5 and nuts 6 to construct the house. The slate roof 25 in which the slate roof 25 is stacked from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material, is attached, and as a result, the polystyrene foam 30 is replaced with the asbestos slate 26 and the slate roof 25. On the surface of the slate roof 25 after being fixed to the asbestos slate 26, and further on the surface of the polystyrene foam 28 having a flat plate shape on both sides. In the city of Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) manufactures and sells, and the product name is a spherical silicon solar cell lightweight module solar cell (1). The solar cell (1) is mounted on the surface of the foamed polystyrene 28 using the nut 6, the pad eye 7 and the bolt 5 on the surface of the foamed polystyrene 28. A fixed longitudinal sectional view is shown in FIG. FIG. 91 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes fragile after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. The shape of the expanded polystyrene plate is made of a expanded polystyrene plate of 685 mm. The expanded polystyrene plate 29 has the shape of asbestos slate 26 on one side and the slate roof 25 in the shape of the other side. Styrofoam 29 is laid on the surface of the asbestos slate 26 and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, on the surface of the asbestos slate 26, Laminate the slate roof 25 on the surface of the polystyrene foam 29 after the asbestos slate 26 has a structure capable of withstanding the load of human weight, which is more than the limit that a human can withstand walking freely. The four types of panels, rafter 3, asbestos slate 26, styrene foam 29, and slate roof 25, are connected to bolt 5 and The slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roofing material constituting the house from the top and bottom, and as a result, the polystyrene foam 29 is replaced with the asbestos slate 26 and the slate. On the surface of the slate roof 25 after interposing it in the middle with the roof 25 and fixing it to the asbestos slate 26, a foamed polystyrene 30 having a flat plate shape on one side, and the shape on the other side is On the surface of the foamed polystyrene 30 in the shape of the slate roof 25 of the slate roof 25, for example, the location is Kami Toba Daimonocho 35, Minami-ku, Kyoto, and the company name is Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21). The solar cell (1) having a product name of a spherical silicon solar cell lightweight module is manufactured and sold on the surface of the polystyrene foam 30. FIG. 91 shows a longitudinal sectional view in which the solar cell (1) is attached and fixed on the surface of the polystyrene foam 30 using the pad 6, the pad eye 7, and the bolt 5. FIG. 92 shows that the asbestos slate 26 has been used for repair work by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafter 3 using the bolt 5 and the nut 6 from the back surface or the top surface of the steel plate, for example, with a thickness of about 10 cm, When using as a roofing material, the working width is 695 mm, so the width is 695 mm, and when using a large iron plate as the roofing material, the working width is 685 mm. Is made of a polystyrene foam plate of 685 mm. The polystyrene foam plate 29 is made of foamed polystyrene 29 having one side of the shape of asbestos slate 26 and the other side of the polystyrene foam 29 having a corrugated plate shape. On the surface of the asbestos slate 26, it is laid down and stacked on the surface of the asbestos slate 26, so that a load that can be tolerated on the surface of the asbestos slate 26 can be applied. A structure in which the load of the asbestos slate 26 that can withstand the weight of the human being exceeds the limit that can be withstood by the weight of human beings is formed, and the slate roof 25 is stacked on the surface of the polystyrene foam 29 to laminate the rafter 3, asbestos. Four types of panels, slate 26, styrofoam 27, and slate roof 25, are configured using bolts 5 and nuts 6. The slate roof 25 in which the slate roof 25 is stacked and stacked on the rafter 3 that is the roof material is stacked, and as a result, the polystyrene foam 27 is interposed between the asbestos slate 26 and the slate roof 25, and the asbestos slate. 26, on the surface of the slate roof 25, and further on the surface of the expanded polystyrene 28 after laminating the expanded polystyrene 28 having a flat plate shape on both sides. In the upper Toba Daimonocho 35, the company name Clean Venture 21 Co., Ltd. (hereinafter abbreviated as CV21) is manufactured and sold. The solar cell (1) is placed on the surface of the polystyrene foam 28 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the polystyrene foam 28. FIG. 92 shows a longitudinal sectional view attached and fixed. 93 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25 and the steel plate large wave 25 in which the nut 6 is attached on the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 4, after fixing the iron plate large wave 25 to the rafter 3, on the surface of the iron plate large wave 25, one side of the shape is a polystyrene foam 27 having the shape of the iron plate large wave 25. After the laminated polystyrene 27 having a flat plate shape is stacked and laminated, the solar cell 1 manufactured and sold by the company name CV21 is further laminated and laminated on the surface of the foamed polystyrene 27. Solid on the surface of Using the nut 6, the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 panel 3 using the bolt 5 and the nut 6, the solar cell 1 is attached to the rafter 3 as a result. ing. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1. FIG. 93 shows a longitudinal cross-sectional view of the composite roofing material 32 formed by integrating the panels. 94 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25 and the steel plate large wave 25 in which the nut 6 is attached on the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 The surface of the foamed polystyrene 28 after laminating and stacking the foamed polystyrene 28 having a flat plate shape on both sides of the surface of the steel plate large wave 25 after the steel plate large wave 25 is fixed to the rafters 3 Further, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the nut 6 is fixed on the surface of the iron plate large wave 25 and the solar cell is used. 1, polystyrene foam 28, and Bolt 5 3 panels plate billows 25, and using a nut 6, as a result, have installed a solar cell 1 to the rafters 3. Further, a junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 28, and the solar cell 1 are three pieces. FIG. 94 shows a longitudinal sectional view of the composite roofing material 32 in which the panels are integrated and combined. 95 shows, for example, that the welded portion 13 of the nut 6 is formed on the surface of the iron plate large wave 25, and the iron plate large wave 25 attached to the surface of the iron plate large wave 25 is the C steel 3, Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 4, after fixing the iron plate large wave 25 to the rafter 3, on the surface of the iron plate large wave 25, one side of the shape is a polystyrene foam 27 having the shape of the iron plate large wave 25. After the laminated polystyrene 27 having a flat plate shape is stacked and laminated, the solar cell 1 manufactured and sold by the company name CV21 is further laminated and laminated on the surface of the expanded polystyrene 27, and then the iron plate large wave 25 Solid on the surface of Using the nut 6, the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 panel 3 using the bolt 5 and the nut 6, the solar cell 1 is attached to the rafter 3 as a result. ing. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. FIG. 95 shows a longitudinal sectional view of the composite roofing material 32 in which the panels are integrated and combined. FIG. 96 shows, for example, that the welded portion 13 is formed on the surface of the iron plate large wave 25, and the iron plate large wave 25 attached to the nut 6 on the surface of the iron plate large wave 25 is the C steel 3. Or, using a nail 4 or a Namijime hex (hereinafter abbreviated as a nail) for the purlin 3 or rafter 3 (hereinafter abbreviated as a rafter), a large iron plate 25 is nailed into the rafter 3 as a rafter 3 The surface of the foamed polystyrene 28 after laminating and stacking the foamed polystyrene 28 having a flat plate shape on both sides of the surface of the steel plate large wave 25 after the steel plate large wave 25 is fixed to the rafters 3 Further, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the nut 6 is fixed on the surface of the iron plate large wave 25 and the solar cell is used. 1, polystyrene foam 28, and Bolt 5 3 panels plate billows 25, and using a nut 6, as a result, have installed a solar cell 1 to the rafters 3. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1. FIG. 96 shows a longitudinal cross-sectional view of the composite roofing material 32 formed by integrating the panels. 97 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back surface of the iron plate large wave 25. The pad eye 7 is formed on the back surface of the steel plate, the welded portion 13 is formed, the pad eye 7 is mounted on the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 fixing the pad eye 7. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the bolt 5 is attached and fixed on the surface of the iron plate large wave 25. After the foamed polystyrene 27 having the shape of the other side is laminated on the surface of the iron plate large wave 25, the other one side of the foamed polystyrene 27 is laminated, and then, for example, the company name CV21 is manufactured and sold battery After stacking, the bolts 5 fixed on the surface of the iron plate large wave 25 are used to connect the three panels of the solar cell 1, the polystyrene 27, and the iron plate large wave 25 to the bolts 5 and nuts 6. Is laminated using pressure bonding. As a result, the pad eye 7 is attached on the back surface of the iron plate large wave 25 with the iron plate large wave 25 attached with the solar cell 1 and fixed by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1. , A roof material that constitutes a roof by attaching to C steel 3, wood purlin 3, or rafter 3 (hereinafter, abbreviated as rafter), and iron plate large wave 25 that is a roof material and solar cell 1 It is an extremely light composite roofing material 32 in which the two are integrated. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. FIG. 97 shows a longitudinal cross-sectional view of the composite roofing material 32 formed by integrating these panels and combining them. 98 shows, for example, the iron plate large wave 25 for the purpose of being attached to the C steel 3, the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as a rafter) from the back surface of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is mounted on the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. The welded portion 13 is formed on the surface of the steel plate 25, and the bolts 5 are attached and fixed on the surface of the iron plate large wave 25. On the surface of the iron plate large wave 25, the shape of one side is the shape of the iron plate large wave 25. After the foamed polystyrene 27 is laminated on the surface of the iron plate large wave 25, the solar cell 1 whose company name is manufactured and sold by CV21 is further laminated. Pile up product After using the bolt 5 that is fixed on the surface of the iron plate large wave 25, the three panels of the solar cell 1, the polystyrene foam 27, and the iron plate large wave 25 are used with the bolt 5 and the nut 6. Laminate by pressing. As a result, the nut 6 which attached the iron plate large wave 25 which has fixed and fixed the solar cell 1 by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1 on the back surface of the iron plate large wave 25 is provided. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. FIG. 98 shows a longitudinal sectional view of the composite roofing material 32 in which the panels are integrated and combined. 99 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back surface of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is mounted on the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the bolt 5 is attached to the surface of the iron plate large wave 25, and the mirror panel ace 20 is superimposed on the surface of the iron plate large wave 25 on the surface of the iron plate large wave 25 Then, for example, after stacking the solar cells 1 manufactured and sold by the company name CV21, using the bolts 5 fixed on the surface of the iron plate large wave 25, Solar cell 1, Mirapane 20, and the three panels of the iron plate billows 25 bolt 5, and the lamination by pressure bonding using a nut 6. As a result, the iron plate large wave 25 attached with the solar cell 1 is fixed with the Mirapane Ace 20 interposed between the iron plate large wave 25 and the solar cell 1, and the nut 6 attached on the back surface of the iron plate large wave 25 is attached. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1. FIG. 99 shows a longitudinal sectional view of the composite roofing material 32 in which the panels are integrated and combined. FIG. 100 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back side of the iron plate large wave 25. The pad eye 7 is formed on the back surface of the steel plate, the welded portion 13 is formed, the pad eye 7 is mounted on the back surface of the iron plate large wave 25, and the nut 6 is further formed on the surface of the iron plate large wave 25 fixing the pad eye 7. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the nut 6 is attached and fixed on the surface of the iron plate large wave 25. After the foamed polystyrene 27 having the shape of the other side is stacked on the surface of the iron plate large wave 25, the other one side of the foamed polystyrene 27 is laminated, and then, for example, the company name CV21 is manufactured and sold Electric After stacking 1 and laminating, using the nut 6 fixed on the surface of the iron plate large wave 25, the three panels of the solar cell 1, the polystyrene 27 and the iron plate large wave 25 are connected to the bolt 5 and the nut. 6 is used for pressure bonding. As a result, the pad eye 7 is attached on the back surface of the iron plate large wave 25 with the iron plate large wave 25 attached with the solar cell 1 and fixed by interposing the polystyrene foam 27 between the iron plate large wave 25 and the solar cell 1. , A roof material that constitutes a roof by attaching to C steel 3, wood purlin 3, or rafter 3 (hereinafter, abbreviated as rafter), and iron plate large wave 25 that is a roof material and solar cell 1 It is an extremely light composite roofing material 32 in which the two are integrated. A junction box 31 (hereinafter abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1 on the back surface of the solar cell 1, and the iron plate large wave 25, the polystyrene foam 27, and the solar cell 1. FIG. 100 shows a longitudinal cross-sectional view of the composite roofing material 32 formed by integrating the panels. 101 shows, for example, an iron plate large wave 25 for the purpose of attaching to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter abbreviated as a rafter) from the back side of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is mounted on the back surface of the iron plate large wave 25, and the bolt 5 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. A welded portion 13 is formed on the surface of the steel plate 25, and bolts 5 are attached and fixed on the surface of the steel plate large wave 25. On the surface of the steel plate large wave 25, a polystyrene foam 28 having a flat plate shape on both sides is provided. After stacking, for example, the solar cell 1 manufactured and sold by the company name CV21 is stacked and stacked, and then the bolt 5 fixed on the surface of the iron plate large wave 25 is used. , Solar cell 1, Foam The three panels of the roll 28, and the iron plate billows 25 bolt 5, and the lamination by pressure bonding using a nut 6. As a result, the nut 6 which attached the iron plate large wave 25 which has fixed the solar cell 1 by interposing the polystyrene foam 28 between the iron plate large wave 25 and the solar cell 1 is attached on the back surface of the iron plate large wave 25. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter, abbreviated as FA2 terminal box) is attached on the back surface of the solar cell 1, and is mounted on the back surface of the solar cell 1. FIG. 101 shows a longitudinal sectional view in which a composite roof material 32 is formed by integrating the panels of the above and combined. 102 shows, for example, an iron plate large wave 25 for the purpose of being attached to the C steel 3, the wood purlin 3, or the rafter 3 (hereinafter, abbreviated as a rafter) from the back surface of the iron plate large wave 25. The weld 6 is formed on the back surface of the nut 6, the nut 6 is attached to the back surface of the iron plate large wave 25, and the nut 6 is further mounted on the surface of the iron plate large wave 25 to which the nut 6 is fixed. The welded portion 13 is formed on the surface of the iron plate large wave 25, and the nut 6 is attached and fixed on the surface of the iron plate large wave 25, and the Mirapane Ace 20 is overlaid on the surface of the iron plate large wave 25. Further, for example, after stacking the solar cells 1 manufactured and sold by the company name CV21, using the nut 6 fixed on the surface of the iron plate large wave 25, Solar cell 1, Mirapane Scan 20, and the three panels of the iron plate billows 25 bolt 5, and the lamination by pressure bonding using a nut 6. As a result, the iron plate large wave 25 attached with the solar cell 1 is fixed with the Mirapane Ace 20 interposed between the iron plate large wave 25 and the solar cell 1, and the nut 6 attached on the back surface of the iron plate large wave 25 is attached. The roof material that is attached to the C steel 3, or the wooden purlin 3, or the rafter 3 (hereinafter, abbreviated as rafter) and constitutes the roof, and the iron plate large wave 25 that is the roof material and the solar cell 1 It is an extremely light composite roofing material 32 that is integrated and united. Further, a junction box 31 (hereinafter abbreviated as an FA2 terminal box) is attached on the back surface of the solar cell 1, and is attached to the back surface of the solar cell 1. FIG. 102 shows a longitudinal sectional view in which a composite roof material 32 is formed by integrating the panels. The first purpose shown in FIG. 103 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the nut 6 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, for the purpose of attaching the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is provided. FIG. 103 shows a longitudinal sectional view of a folded plate roof 25 in which the nut 6 is attached to the back surface of the metal plate by forming the arc welded portion 13. The first object shown in FIG. 104 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the nut 6 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, in order to attach the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is used. FIG. 104 shows a longitudinal cross-sectional view of the folded plate roof 25 in which the bolt 5 is attached to the back surface of the steel plate by forming the arc welded portion 13. The first object shown in FIG. 105 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the bolt 5 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, in order to attach the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is used. FIG. 105 shows a longitudinal sectional view of a folded plate roof 25 in which the nut 6 is attached to the back surface of the steel plate by forming the arc welded portion 13. The first purpose shown in FIG. 106 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the bolt 5 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, for the purpose of attaching the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is provided. FIG. 106 shows a longitudinal sectional view of the folded plate roof 25 in which the bolt 5 is attached to the back surface of the steel plate by forming the arc welded portion 13. The first object shown in FIG. 107 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the pad eye 7 is attached on the surface of the folded plate roof 25 by forming the arc welding portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, for the purpose of attaching the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is provided. FIG. 107 shows a longitudinal sectional view of a folded plate roof 25 in which the pad eye 7 is attached to the back surface of the metal plate by forming the arc welded portion 13. The first purpose shown in FIG. 108 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the nut 6 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, for the purpose of attaching the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is provided. FIG. 108 shows a longitudinal sectional view of a folded plate roof 25 in which the pad eye 7 is attached to the back surface of the plate by forming the arc welded portion 13. The first purpose shown in FIG. 109 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the pad eye 7 is attached on the surface of the folded plate roof 25 by forming the arc welding portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, in order to attach the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is used. FIG. 109 shows a longitudinal sectional view of a folded plate roof 25 in which the bolt 5 is attached to the back surface of the steel plate by forming the arc welded portion 13. The first object shown in FIG. 110 is to attach the solar cell 1 directly on the surface of the folded plate roof 25. As the second purpose, the folded plate roof 25 is attached to the rafter 3 constituting the roof of the house, the folded plate roof 25 is attached to the rafter 3 from the back side of the folded plate roof 25, and the folded plate roof 25 is placed on the back side. It aims at attaching to the rafter 3 and fixing. In order to solve the above problem, the bolt 5 is attached to the surface of the folded plate roof 25 by forming the arc welded portion 13 on the surface of the folded plate roof 25. Moreover, on the back surface of the folded-plate roof 25 as well as the content demonstrated above, for the purpose of attaching the folded-plate roof 25 to the rafter 3 which comprises the house from the back surface, the folded-plate roof 25 is provided. FIG. 110 shows a longitudinal sectional view of a folded plate roof 25 in which the pad eye 7 is attached to the back surface of the plate by forming the arc welded portion 13. The first object shown in FIG. 111 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the nut 6 is attached to the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 111 shows a longitudinal sectional view of the slate roof 25 to which the nut 6 is attached by forming the arc welded portion 13. The first purpose shown in FIG. 112 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the nut 6 is attached to the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 112 shows a longitudinal sectional view of the slate roof 25 to which the bolt 5 is attached by forming the arc welded portion 13. The first purpose shown in FIG. 113 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the bolt 5 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 113 shows a longitudinal sectional view of a slate roof 25 to which the nut 6 is attached by forming the arc welded portion 13. The first purpose shown in FIG. 114 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the bolt 5 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. In addition, on the back surface of the slate roof 25, as in the case described above, for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface, FIG. 114 shows a longitudinal sectional view of the slate roof 25 to which the bolt 5 is attached by forming the arc welded portion 13. FIG. 115 shows that the first object is to directly attach the solar cell 1 on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above-mentioned problem, the pad eye 7 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 115 shows a longitudinal sectional view of the slate roof 25 to which the pad eye 7 is attached by forming the arc welded portion 13. The first object shown in FIG. 116 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the nut 6 is attached to the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. In addition, on the back surface of the slate roof 25, as in the case described above, for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface, FIG. 116 shows a longitudinal sectional view of the slate roof 25 to which the pad eye 7 is attached by forming the arc welded portion 13. The first purpose shown in FIG. 117 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above-mentioned problem, the pad eye 7 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 117 shows a longitudinal sectional view of the slate roof 25 to which the nut 6 is attached by forming the arc welded portion 13. The first purpose shown in FIG. 118 is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above-mentioned problem, the pad eye 7 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. In addition, on the back surface of the slate roof 25, as in the case described above, for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface, FIG. 118 shows a longitudinal sectional view of the slate roof 25 to which the bolt 5 is attached by forming the arc welded portion 13. FIG. 119 shows that the first purpose is to attach the solar cell 1 directly on the surface of the slate roof 25. As a second purpose, the slate roof 25 is attached to the rafter 3 constituting the roof of the house, the slate roof 25 is attached to the rafter 3 from the back side of the slate roof 25, and the slate roof 25 is changed to the rafter 3 from the back side. The purpose is to attach and fix. In order to solve the above problem, the bolt 5 is attached on the surface of the slate roof 25 by forming the arc welded portion 13 on the surface of the slate roof 25. Further, on the back surface of the slate roof 25, as in the case described above, on the back surface of the slate roof 25 for the purpose of attaching the slate roof 25 to the rafter 3 constituting the house from the back surface. FIG. 119 shows a longitudinal sectional view of the slate roof 25 to which the pad eye 7 is attached by forming the arc welded portion 13. In FIG. 120, a conventional iron plate large wave 25 is overlapped on the lower portion for the purpose of attaching to the C steel 3, the wooden purlin 3, or the rafter 3 (hereinafter, referred to as rafter). Using the nail 4 or the namime hex 4 (hereinafter, abbreviated as najime hex), the position of the telecommunications plate wave 34 and the telecommunications plate wave 33 located in the upper part are positioned in the lower part. The large iron plate 34 and the large iron plate 33 located in the upper part are attached to the rafter 3 using the Namijime hex 4, and the conventional two large iron plates 25 are bonded together by pressure bonding. FIG. 120 shows a longitudinal sectional view of the means for attaching. FIG. 121 shows a processing means for joining the two large iron plate waves 25 of the present invention by pressure bonding. First, a nut 6 or other mounting bracket 6 (hereinafter abbreviated as nut 6) is placed on the back surface of the iron plate large wave 33 on the back surface of the iron plate large wave 33 located at the upper portion. An iron plate large wave 33 to which the nut 6 is attached by forming a welded portion 13 is formed. Secondly, the bolt 5 passing through the inside of the hole portion 36 formed in the large iron plate wave 34 located in the lower portion, the washer 35 larger than the inner diameter of the hole portion 36, and the nut 6 is used to overlap the iron plate large wave 33 located in the upper part and the iron plate large wave 34 located in the lower part in an overlapping manner, and the two nuts located vertically FIG. 121 shows a longitudinal cross-sectional view in which two large iron plate waves 25 are bonded from above and below using 6. FIG. 122 shows that the large iron plate wave 34 is usually extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) using bolts 5 and nuts 6 by attaching them from both sides of the iron plate large wave 34 by pressure bonding, and spreading the wind pressure received at one point as widely as possible. Without causing deformation of the iron plate large wave 34 For the purpose of preventing damage to the iron plate large wave 34 even under strong wind pressure, a band-shaped iron plate 37 is attached on both sides of the iron plate large wave 34 to firmly bond the iron plate large wave 34 and the band-shaped iron plate 37. FIG. 122 shows a vertical cross-sectional view attached by attaching the same. FIG. 123 shows the iron plate large wave 34 that is a roofing material and the solar cell 1 to unite the solar cell 1 to form an integrated structure. No. 34 is extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) using bolts 5 and nuts 6 by attaching them from both sides of the iron plate large wave 34 by pressure bonding, and spreading the wind pressure received at one point as widely as possible. Without causing deformation of the iron plate large wave 34 For the purpose of preventing damage to the iron plate large wave 34 even under strong wind pressure, a band-shaped iron plate 37 is attached on both sides of the iron plate large wave 34 to firmly bond the iron plate large wave 34 and the band-shaped iron plate 37. The solar cell 1 is mounted on the surface of the iron plate large wave 34 after mounting by using bolts 5 and nuts 6, and the iron plate large wave 34 that is a roof material and the solar cell 1 are combined to form an integrated structure. The solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material) is formed, and the roof material and the combined material are structured so that the solar cell 1 can be attached very easily. FIG. 123 shows a vertical cross-sectional view of the solar cell 1 for the purpose of individually manufacturing and selling the solar cell 1 that has been made. FIG. 124 shows an iron plate large wave as described above for the purpose of forming the solar cell 1 having a unitary structure by combining the iron plate large wave 34 that is a roofing material and the solar cell 1. No. 34 is extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) using bolts 5 and nuts 6 by attaching them from both sides of the iron plate large wave 34 by pressure bonding, and spreading the wind pressure received at one point as widely as possible. Without causing deformation of the iron plate large wave 34 For the purpose of preventing damage to the iron plate large wave 34 even under strong wind pressure, a band-shaped iron plate 37 is attached on both sides of the iron plate large wave 34 to firmly bond the iron plate large wave 34 and the band-shaped iron plate 37. The solar cell 1 is mounted on the surface of the iron plate large wave 34 after mounting by using bolts 5 and nuts 6, and the iron plate large wave 34 that is a roof material and the solar cell 1 are combined to form an integrated structure. The solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material) is formed, and the roof material and the combined material are structured so that the solar cell 1 can be attached very easily. The solar cell 1 for the purpose of individually manufacturing and selling the solar cell 1 is used as the C steel 3, the purlin 3 or the rafter 3 (hereinafter, the rafter 3 for short) constituting the house. ) To take the solar cell 1 combined with the roofing material Only, when mounting the roof constituting the house, at the same time, the longitudinal cross-sectional view that attach the solar cell 1 on the surface of the roof, are shown in Figure 124. FIG. 125 shows, for the purpose of simplifying solar power generation equipment construction and enabling installation work even for an amateur, FIG. 125 shows a schematic diagram of the plan A wood purlin material installation plan for assembling the solar power generation equipment kit, in which three points are the main members of the solar power generation equipment kit. 126 is a schematic diagram for the purpose of assembling a plan A of a photovoltaic power generation equipment kit, in which 3 is a wood purlin material, 25 is a large iron plate wave, 41 is a wave ridge, It is shown in FIG. FIG. 127 is a schematic diagram for the purpose of assembling a plan A of the photovoltaic power generation equipment kit. After attaching the iron plate large wave 25 on the surface of the wood purlin 3, the surface of the iron plate large wave 25 is shown. FIG. 127 shows a schematic view in which a base metal receiving member (hereinafter, abbreviated as a bracket) 42 is attached to the substrate. FIG. 128 is a schematic diagram for the purpose of assembling a plan A of the photovoltaic power generation equipment kit. After attaching the iron plate large wave 25 on the surface of the wood purlin 3, the surface of the iron plate large wave 25 is shown. FIG. 128 shows a schematic diagram in which a base metal receiver (hereinafter abbreviated as a bracket) 42 is attached to the base frame 42 and a steel frame 43 is attached on the surface of the base metal receiver 42. FIG. 129 shows a schematic diagram for the purpose of assembling a plan A of the photovoltaic power generation equipment kit. After attaching the iron plate large wave 25 on the surface of the wooden purlin 3, the surface of the iron plate large wave 25 is shown. A base metal receiver (hereinafter abbreviated as a bracket) 42 is attached to the steel frame 43, and the steel frame 43 is attached to the surface of the base metal receiver 42, and then the solar cell 1 is attached to the surface of the steel frame 43. A schematic diagram is shown in FIG. FIG. 130 shows, for the purpose of simplifying the solar power generation equipment construction and enabling the installation work even for an amateur, for example, the iron plate large wave 25, the base metal receiver 42, and the steel frame 43. FIG. 130 shows a schematic diagram of the plan B wood purlin material installation diagram for assembling the solar power generation equipment kit, in which three points are the main members of the solar power generation equipment kit. 131 is a schematic diagram for the purpose of assembling a plan B of a photovoltaic power generation equipment kit, in which 3 is a wood purlin material, 25 is a large iron plate wave, 41 is a wave ridge, It is shown in FIG. FIG. 132 is a schematic diagram for the purpose of assembling the plan B of the photovoltaic power generation equipment kit. After attaching the iron plate large wave 25 on the surface of the wood purlin 3, the surface of the iron plate large wave 25 is shown. FIG. 132 is a schematic diagram in which a base metal receiving member (hereinafter, abbreviated as a bracket) 42 is attached to FIG. FIG. 133 shows a schematic diagram for the purpose of assembling a plan B of the photovoltaic power generation equipment kit. FIG. 133 shows a schematic view in which a steel frame 43 is attached on the back surface of the solar cell 1 after attaching a base metal receiver (hereinafter abbreviated as a bracket) 42 on the surface. FIG. 134 is a schematic diagram for the purpose of assembling a plan B of the photovoltaic power generation equipment kit. After attaching the iron plate large wave 25 on the surface of the wood purlin 3, the surface of the iron plate large wave 25 is shown. A base metal receiver (hereinafter abbreviated as a bracket) 42 is attached to the surface of the solar battery 1, and a steel frame 43 is attached to the back surface of the solar cell 1 on the surface of the base metal receiver 42. A schematic diagram of the attachment on the surface of the receiver 42 is shown in FIG. FIG. 135 shows a solar cell (hereinafter abbreviated as a panel or a solar cell panel) 1 in detail of components necessary for attaching one solar cell panel 1 to FIG. Show. FIG. 136 shows that the pre-process processing is completed before forming the iron plate large wave (25), for example, Nisshin Steel Co., Ltd. manufactures and sells the product name is Galbuster (ZG). A steel plate, a ZAM steel plate, a flat steel plate coated with a paint on the surface of a flat steel plate, a flat steel plate coated with a urethane paint, a flat steel plate just rolled, or a steel coil wound around a circle, Or a strip steel flat plate, or a decorative plate made of a flat plate or a veneer plate, or a veneer plate, a flat plate made of plastic, or a flat plate made of other materials, an outer flat plate material, or an inner flat plate material (hereinafter, For example, the amount of the thin film that Solterra in the United States has succeeded in research and development on a surface such as a plastic flat plate, a decorative plate, a flat plate, or a flat steel plate). Using the manufacturing technology of the child dot type PV solar cell (51) (hereinafter abbreviated as the quantum dot type solar cell (51)), on the surface of the flat steel plate (44), the quantum dot type solar cell ( 51) Using a roll-to-roll printing technique, an ink jet printing technique, or a screen printing technique, a flat plate shape in which a quantum dot solar cell (51) was formed directly on the surface of a flat steel sheet (44) was formed. A side view of the flat steel plate (44) in which the quantum dot solar cell (51) is formed on the surface of the flat steel plate (44) or the strip steel flat steel plate (44) wound in round winding is shown in FIG. Yes. FIG. 137 shows a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). For the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which the quantum dot solar cell (51) is formed, the transmittance of solar rays is A film made of a good resin, a polycarbonate resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is used as a quantum dot solar cell (51). As a protective film (45) on the surface of the flat steel plate (44) formed with a quantum dot solar cell (51) on the surface of the flat steel plate (44) formed on the surface of the flat steel plate (44), A flat steel plate (44) bonded on the surface of the flat steel plate (44) is used as a protective film (45) for protecting the surface of the child dot solar cell (51), or a quantum dot solar cell (51 ) On the surface of the flat steel plate (44), which is in a state of being formed on the surface of the flat steel plate (44), on the surface of the flat steel plate (44). 45), a flat steel plate (44) forming a quantum dot solar cell (51) is formed to constitute a house or a building (hereinafter abbreviated as a house). The building material is used as an outer wall plate of the wall material constituting the outer periphery of the house, or as an exterior material. For example, a quantum dot type solar cell (51) is formed on the surface of a flat steel plate (44) on the surface of a flat steel plate (44) having a width of 90 cm and a vertical width of 180 cm. Using the solar cell (51), electric power is generated using the energy of solar rays. Moreover, the quantum dot type solar cell (51) which has formed the quantum dot type solar cell (51) on the surface of a flat steel plate (44) as an interior material for the room | chamber interior currently used in the house interior. ) Using the energy of light generated from incandescent lamps or fluorescent lamps that are used inside houses or buildings, and using quantum dot solar cells (51 ) Is formed on the surface of the flat steel plate (44), the quantum dot solar cell (51) is used to generate power using the quantum dot solar cell (51). A plan view of the flat steel plate (44) forming the battery (51) is shown in FIG. FIG. 138 shows a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an ink jet printing technique, or a screen printing technique on the surface of the flat steel plate (44). For the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which the quantum dot solar cell (51) is formed, the transmittance of solar rays is A film made of a good resin, a polycarbonate resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is used as a quantum dot solar cell (51). As a protective film (45) on the surface of the flat steel plate (44) formed with a quantum dot solar cell (51) on the surface of the flat steel plate (44) formed on the surface of the flat steel plate (44), As the protective film (45) for protecting the surface of the child dot solar cell (51), a flat steel plate (44) bonded on the surface of the flat steel plate (44) is used, or a quantum dot solar cell ( 51) is formed on the surface of the quantum dot solar cell (51) in a state where it is formed on the surface of the flat steel plate (44), and a protective film is formed on the surface of the flat steel plate (44). For the purpose of directly forming the iron plate large wave (46), the plate steel plate (44) forming the quantum dot solar cell (51) not forming (45) is directly used to form the iron plate large wave (46). ) Is used to form the quantum dot solar cell (51) on the surface of the flat steel plate (44), the flat steel plate (44) is formed, and the iron plate large wave (25) A quantum dot solar cell (51) is directly formed on the surface of A longitudinal section of the iron plate billows (46) that are, are shown in Figure 138. FIG. 139 shows that the flat steel plate (44) forming the quantum dot solar cell (51) is directly formed on the surface of the flat steel plate (44), or the shape of the iron plate large wave (25), or Formed using a molding machine that molds into the shape of the folded plate roof (25) (hereinafter abbreviated as iron plate large wave (25)), directly on the surface of the iron plate large wave (25), On the surface of the convex part of the iron plate large wave (25) forming the quantum dot solar cell (51), the rafter (3), the purlin (3), or the skeleton (3) constituting the roof of the house (3) ( Hereinafter, a stainless steel screw (4) is used for the rafter (3), and a hole (47) for attaching the iron plate large wave (25) to the rafter (3) is formed, for example, with a hole diameter. An iron plate large wave (46) in which a hole (47) having a diameter of 9 mm is formed on the surface of the iron plate large wave (46), For example, a large plate of iron plates (46) are stacked together and laminated together, and 10 to 20 holes are stacked together, and 40 to 60 holes (47) are made within ± 1 mm using a machine tool with NC. FIG. 139 shows a longitudinal cross-sectional view of the iron plate large wave (46) in which a hole (47) is simultaneously formed on the surface of the iron plate large wave (46) with the above error. FIG. 140 shows directly on the surface of a steel plate (25) or flat steel plate (44) using a printing technique such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique. FIG. 140 shows a longitudinal sectional view in which the quantum dot solar cell (51) is formed on the surface of the iron plate large wave (25) or the flat steel plate (44). FIG. 141 shows the surface of the iron plate large wave (25) for the purpose of performing surface processing so that the iron plate large wave (25) does not rust for several tens of years to 100 years. Stainless steel screws for rafters (3), C steel (3), wooden purlin (3), or skeleton (3) (hereinafter abbreviated as rafters (3)) constituting the roof of the house The hole (47) for attaching the iron plate large wave (25) to the rafter (3) using (4), for example, the hole (47) having a hole diameter of 9 mm, and the iron plate large wave (25 1) on the surface of the iron plate large wave (25) in which a hole (47) is formed on the surface of the iron plate large wave (25) with an error within ± 1 mm using an NC machine tool. As a layer, a very thin primer layer is formed. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. Urethane on the surface of the iron plate large wave (25) which forms the hole (47) for attaching to the rafter (3) which comprises a house on the surface of the iron plate large wave (25) demonstrated above. For the purpose of forming the coating film (48) and attaching the iron plate large wave (25) formed with the urethane coating film (48) to the rafter (3) using the stainless steel screw (4), Whether it is an amateur, carpenter, plasterer or electrician, drilling holes (47) on the surface of the iron plate large wave (25) for the purpose of easily attaching the iron plate large wave (25) to the rafter (3) FIG. 141 shows a longitudinal sectional view of a large iron plate wave (50) with a urethane coating film forming the urethane coating film (48). FIG. 142 shows the surface of the iron plate large wave (25) for the purpose of performing surface processing so that the iron plate large wave (25) does not rust for several tens of years to 100 years. An extremely thin primer layer is formed as the first layer. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. In the convex part on the surface of the iron plate large wave (25) after the urethane coating film (48) is formed on the surface of the iron plate large wave (25) described above, for example, the diameter of the hole diameter is 9 mm. Hole (47) with a hole diameter on the surface of the iron plate large wave (25) using an NC machine tool with an error within ± 1 mm, the urethane coating (48) on the surface of the iron plate large wave (25) A hole (47) for attaching to the rafter (3) constituting the house is formed on the surface of the iron plate large wave (25), and the iron plate large wave (25) is made of stainless steel into the rafter (3). For the purpose of being able to attach using a wooden screw (4), even an amateur, carpenter, plasterer, electrician, etc., to easily attach a large iron plate (25) to a rafter (3), Drilling holes (47) on the surface of the iron plate large wave (25), and urethane A longitudinal section of a urethane coating with iron large wave that forms a film (48) (50), is shown in Figure 142. FIG. 143 shows the surface of the iron plate large wave (25) for the purpose of performing surface processing in which the iron plate large wave (25) does not rust for several tens of years to 100 years. An extremely thin primer layer is formed as the first layer. Next, as the second layer, on the surface of the primer layer formed by the first layer, the ultra-high speed curing urethane spraying method (hereinafter abbreviated as JetSpray method), the ultra-high speed curing type A polyurethane resin (hereinafter abbreviated as urethane paint) is applied, for example, a urethane paint having a thickness of about 2 mm is applied to form a urethane coating (48). Furthermore, as the third layer, an extremely thin color elastic fluorine coat is applied on the surface on which the urethane coating film (48) having a thickness of about 2 mm is formed, so that the color can be freely set. Using the flat steel plate (44) formed on the surface of the flat steel plate (44) as described above and using the flat steel plate (44) as a raw material, the flat steel plate (49) with a urethane coating is used directly. The urethane coating film is formed on the surface of the flat steel plate (44) by using a molding machine for forming the iron plate big wave (25) for the purpose of forming the iron plate big wave (25). The longitudinal cross-sectional view of the iron plate large wave (50) with a urethane coating which forms the flat steel plate (49) with a coating film and forms the urethane coating (48) on the surface of the iron plate large wave (25) 143.

The solar cell (1) is formed on the surface of the corrugated iron plate (2), and the solar cell (1) is formed as a roofing material for a house without damaging the surface of the solar cell (1). The rafter (3) on the back surface of the corrugated corrugated iron plate (2), the nail (4), the bolt (5), the nut (6), the hook (7), or the pad eye (7 ), Or long eye (7), or open pad eye (7), or eye strap (7), or UK turnbuckle (7), or L-rod with nut (hereinafter abbreviated as nut or hook, or By attaching to the rafters (3) from the back of the corrugated steel plate (2) using the rafters (3) constituting the roof of the house using other means, Solar cell formed on the surface of a plate-shaped platinum plate (2) 1) The without damaging any, since the solar cell (1) can be attached as a roof material of a house, it can be use as a roofing material of a house without any damage to the solar cells (1).

Corrugated stainless steel plate (2) is bolt (5), nut (6), hook (7), pad eye (7), long eye (7), or open pad eye (7), Or the roof of a house using an eye strap (7), or a UK turnbuckle (7), or an L-bar with a nut (hereinafter abbreviated as nut, hook or eye), or other means The nail (4) on the surface of the corrugated steel plate (2) by attaching it to the rafter (3) from the back surface of the corrugated steel plate (2) Attach the corrugated iron plate (2) to the rafters (3) from the back side without damaging the wounds generated by hitting the Because it is fixed, corrugated tin plate (2) Tin plate having a corrugated shape without causing the wound at all on the surface (2) can be used as a roofing material.

For the purpose of forming the solar cell (1) on the corrugated steel plate (2), the rafter (3) and the nail (4) are attached to the back surface of the corrugated steel plate (2). Use rafters (3) on the back of corrugated tin plate (2) and nail (4) to fix rafters (3) on the back of corrugated tin plate (2) After that, the iron plate (2) in which the solar cell (1) is formed on the surface of the corrugated iron plate (2) is referred to as Example 1.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The rafters (3) are nuts (6) on the back surface of the corrugated steel plate (2) to which the bolts (5) are welded or the bolts (5) are fixed using a metal adhesive. ) Is used to form the solar cell (1) on the corrugated steel plate (2) surface after the rafter (3) is fixed to the back surface of the corrugated steel plate (2). The obtained tin plate (2) is referred to as Example 2.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2), the concave shape or the convex shape forming irregularities on the corrugated tin plate (2) The rafters (3) are attached to the back surface of the corrugated steel plate (2) by using the nails (4) with the rafters (3) in the direction parallel to the concave or convex direction. Example 3 is a tin plate (2) in which a solar cell (1) is formed on the surface of a corrugated tin plate (2) after the rafter (3) is fixed by nailing.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). In addition, the concave shape forming the corrugations of the corrugated plate on the back surface of the corrugated steel plate (2) which is welded with the bolt (5) or using a metal adhesive to form the corrugated bolt (5), Alternatively, a corrugated tin plate using a rafter (3) and a bolt (5) and a nut (6) in a parallel direction along the concave or convex direction on the back surface of the convex shape ( After the rafter (3) was attached to the back surface of 2) and fixed, the tin plate (2) in which the solar cell (1) was formed on the surface of the corrugated tin plate (2) was formed as in Example 4. To do.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The corrugated steel plate (2) is welded with a nut (6) to the back surface of the corrugated steel plate (2), or the nut (6) is fixed using a metal adhesive ( Corrugated iron after fixing rafter (3) to the back of corrugated steel plate (2) using rafter (3) bolt (5) on the back of 2) A tin plate (2) in which the solar cell (1) is formed on the surface of the plate (2) is referred to as Example 5.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). Next, the corrugated steel plate after the bolt (5) is welded or the bolt (5) is fixed to the back surface of the corrugated steel plate (2) using a metal adhesive. A tin plate (2) in which the solar cell (1) is formed on the surface of (2) is referred to as Example 6.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). Next, the nut (6) is welded to the back surface of the corrugated steel plate (2), or the nut (6) is welded to the back surface of the corrugated steel plate (2) using a metal adhesive. Example 7 is a tin plate (2) in which a solar cell (1) is formed on the surface of a corrugated tin plate (2) after fixing.

For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The hook (7) is welded to the back surface of the corrugated steel plate (2), or the hook (7) is attached to the back surface of the corrugated steel plate (2) using a metal adhesive. Example 8 is a tin plate (2) in which a solar cell (1) is formed on the surface of a corrugated tin plate (2) after being fixed.

For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the steel plate (8) made of a flat plate after the bolt (5) is welded or the bolt (5) is fixed using a metal adhesive. The obtained tin plate (8) is referred to as Example 9.

For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the flat plate (8) after welding the nut (6) or fixing the nut (6) using a metal adhesive. The obtained tin plate (8) is referred to as Example 10.

For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the flat plate (8) made of a flat plate after the hook (7) is welded or the hook (7) is fixed using a metal adhesive. The obtained tin plate (8) is referred to as Example 11.

A hook plate (7), a pad eye (7), a long eye (7), or an open pad eye (7) on the back surface of a corrugated tin plate (2) or a flat plate (8) made of a flat plate ), Or eye strap (7), or UK turnbuckle (7), or L rod with nut (hereinafter abbreviated as nut, hook, or eye), or rafter (3) A spherical silicon solar cell with higher power generation efficiency that can collect sunlight from many directions on the surface of the corrugated iron plate (2) or the flat plate (8) made of a flat plate. A corrugated iron plate (2) having a module formed thereon, or a tin plate (8) formed of a flat plate on the surface of the steel plate (1) to constitute the roof of the house. Rafters (3) or wall To the rafters (3), from the back of the roof of the house, or from the back of the wall constituting the house, the corrugated steel plate (2), or the steel plate (8) made of flat plate A solar cell (1) forming the solar cell (3) on the surface is attached and fixed as Example 12.

Aluminum (Al) on the surface of the iron plate constituting the corrugated tin plate (2) or the tin plate (8) made of a flat plate (hereinafter referred to simply as the tin plate or iron plate). 55% + zinc (Zn) 43.4% + silicon (Si) 1.6% alloy base metal is melted in the plating tank, and the iron plate is immersed in the plating plate. Corrugated tin plate (2) subjected to galvalume plating (hereinafter, abbreviated as Galva Steel, or Nisshin Steel Co., Ltd., the product name of which is manufactured and sold by Galbuster or ZG) The solar cell (1) is formed on the surface of the tin plate (8) made of a flat plate, and the roof of the house is constructed from the surface on which the solar cell (1) is formed on the surface of the tin plate. Using the nail (4) to the rafter (3), directly form the solar cell (1) Even if the corrugated steel plate (2) or the steel plate (8) made of flat plate is nailed from the top of the steel plate to the rafter (3) using the nail (4), it can be made of galva steel plate. Since the corrugated iron plate is highly corrosion resistant and resistant to corrosion, the solar cell (1) formed on the surface of the corrugated steel plate made of galva steel plate and the corrugated tin plate (2), or Since the progress of peeling with the flat plate made of flat plate (8) can be most reduced, the solar cell (1) is formed on the surface of the corrugated plate made of galvanized steel plate (2). Form. Or, if the steel plate (1) is formed on the surface of the steel plate (8) made of a flat plate, the roof of the house is constructed from the surface of the steel plate using nails (4). It is assumed in Example 13 that the tin plate can be applied to the rafter (3) directly from the surface on the surface of the tin plate using the nail (4).

Corrugated corrugated steel plate (2) suitable for uses in poultry houses, pig houses, cattle houses, and compost houses, or the surface of the corrugated steel board (8), which is made of flat plate For example, zinc (Zn) 91% + aluminum (Al) 6%, which is excellent in ammonia resistance and wet resistance manufactured and sold by Nisshin Steel Co., Ltd. + A solar cell on the surface of a corrugated tin plate using ZAM steel plate, which has been subjected to double-bake plating in a plating tank in which a metal made of 1% magnesium (Mg) is melting Form (1). Alternatively, Example 14 is to form the solar cell (1) on the surface of the flat plate (8) made of a flat plate.

The solar cell (1) is formed on the surface of the corrugated iron plate (2), and the solar cell (1) is formed as a roofing material for a house without damaging the surface of the solar cell (1). The rafter (3) on the back surface of the corrugated corrugated iron plate (2), the nail (4), the bolt (5), the nut (6), the hook (7), or the pad eye (7 ), Or long eye (7), or open pad eye (7), or eye strap (7), or UK turnbuckle (7), or L-rod with nut (hereinafter abbreviated as nut or hook, or By attaching to the rafters (3) from the back of the corrugated steel plate (2) using the rafters (3) constituting the roof of the house using other means, Solar cell formed on the surface of a plate-shaped platinum plate (2) Since the solar cell (1) can be attached as a roof material of a house without damaging 1) at all, it is used as a roof material of a house without damaging the solar cell (1) at all. And

For the purpose of attaching the solar cell (1) on the surface of the corrugated tin plate (2), a polystyrene foam plate is placed between the corrugated tin plate (2) and the solar cell (1). A module in which a foamed polystyrene plate (11) made of (11) on both sides is formed in a flat plate shape is interposed between a corrugated steel plate (2) and a solar cell (1). Using bolts (5) and nuts (6) joined on the surface of corrugated stainless steel plate (2) using welded part (13) or metal adhesive part (13) Then, a foamed polystyrene plate (11) having both sides made of a polystyrene foam plate (11) is formed in the middle, and a solar cell (1) is placed on the surface of the foamed polystyrene plate (11). After forming the adhesive layer (10) and bonding Furthermore, after attaching the solar cell (1) to the corrugated steel plate (2) using the bolt (5) and the nut (6), on the back surface of the corrugated steel plate (2) Hook (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) or UK turnbuckle (7) or L rod with nut , Abbreviated as pad eye) is attached to the corrugated tin plate (2), and then the tip of the pad eye (7) attached to the back surface of the corrugated tin plate (2) Corrugated iron plate (2) using corrugated iron plate (2) using r-bar with nut with n-shaped part on roof rafter (3) constituting the house 2) From the back side of rafter (3) to corrugated sheet (2) The corrugated tongue plate (2) is formed by using an L rod with a nut having an n-shaped end and a pad eye (7) attached to the corrugated tongue plate (2). Attaching to the rafter (3) from the back side is referred to as Example 16.

On the surface of corrugated stainless steel plate (2), for example, the name of a product manufactured and sold by Nisshin Steel Co., Ltd. 1 mm spherical silicon pn junction solar cell surface (16) of Clean Venture 21, Inc., tempered glass with a conductive antireflection film (18) Concentrating solar cell (1) comprising negative electrode and reflector (17) In order to suppress overheating of the solar cell, the lower part (19) of the positive electrode is brought into close contact with the peak portion of the corrugated steel plate (2), and the tin plate (2) It is assumed that Example 17 is attached to a corrugated stainless steel plate on which a solar cell (1) characterized in that it also dissipates heat.

Corrugated steel plate (2), for example, Nisshin Steel Co., Ltd. manufactured and sold a corrugated steel plate using a ZAM steel plate as a reflector (17), A concentrating solar cell (1) composed of a cylindrical silicon pn-junction solar cell surface (16) having an outer diameter of 1 cm, a tempered glass (18), and a reflecting mirror (17) positive electrode is formed integrally. In order to suppress temperature overheating, heat is dissipated from the tin plate (2), and the solar cell (1) having the solar cell lower part (19) as a positive electrode and the corrugated tin plate are integrated. Example 18 was carried out. Example 18 shows that hot water is also obtained when water is allowed to flow inside the cylindrical solar cell surface (16) or heat is dissipated as a heat pipe.

For the purpose of mounting the solar cell (1) on the corrugated tin plate (2) surface,
A hook (7), a pad eye (7), a long eye (7), an open pad eye (7), an eye strap (7), or a UK turn After attaching a buckle (7) or an L bar with a nut (hereinafter abbreviated as pad eye) to the back surface of the corrugated steel plate (2), the corrugated steel plate (2 After the solar cell (1) is bonded on the surface of the adhesive plate (10) with the adhesive layer (10) interposed, the tip portion is attached to the pad eye (7) attached to the back surface of the corrugated iron plate (2). The corrugated iron plate (2) using the n-shaped L-rod with a nut, and the corrugated steel plate (2) to the rafter (3) of the roof material constituting the house (2) ) To the rafter (3) from the back side of the corrugated steel plate (2) Using the L-shaped nut-attached L bar and the pad eye (7) attached to the corrugated tin plate (2), the rafters (from the back of the corrugated tin plate (2) ( The solution is to attach to 3).
In addition, by attaching the corrugated iron plate (2) to the rafter (3) constituting the roofing material of the house from the back, the corrugated corrugated steel plate (2) is completely damaged. It is assumed that the corrugated iron plate (2) is attached to the rafter (3) constituting the roofing material of the house and fixed, without fixing.

For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Alternatively, a metal adhesive portion (13) is formed and a nut (6) is fixed on the surface of the corrugated stainless steel plate (2), and then the corrugated steel plate (2) and solar cell After forming and laminating a plywood (20) made of a foam polystyrene plate and a plate made of aluminum foil with an adhesive layer (10) interposed between the plate made of polystyrene and (1) Furthermore, an arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7), or a long eye (7), or Open pad eye (7) or eye strap (7) (hereinafter abbreviated as pad The roof tile of the house (21) to attach the rafter (3) constituting the house on the back surface of the corrugated iron board (2) A hole (22) is formed in the pad, and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are tiled. Rafters (3) that make up the house using an L-shaped rod (14) with a nut that penetrates the inside of the hole (22) formed in (21) and has an n-shaped tip. The corrugated steel plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2), and the nut-attached L rod (14) having an n-shaped tip. ) Through the inside of the hole (22) formed in the roof tile (21), the corrugated steel plate (2) In order to prevent rainwater from leaking through the holes (22) formed in the roof tile (21) when it is attached and fixed to the rafters (3), the rainwater enters the house. From the surface of the roof tile (21), a structure having a long cylindrical shape (23) of about 5 cm is combined with the roof tile (21), and the roof tile (21) is used to form an integral structure. A corrugated steel plate (2) is fixed using an L-shaped rod (14) with a nut. Furthermore, the nut-attached L rod (14) whose tip portion penetrating the inside of the cylindrical shape (23) is an n-shape is a sealant (24) inside the cylindrical shape (23), for example, Using an adhesive made of silicone resin or the like, the inside of the cylindrical shape (23) formed on the roof tile (21) united with the roof tile (21) is sealed with the sealant (24). Is used to prevent rainwater from leaking into the house from the hole (22) formed in the roof tile (21). Alternatively, the packing (24) made of silicone resin or the like is inserted into the cylindrical shape (23) instead of the sealant (24), and the L-rod with nut (14) having an n-shaped tip portion. ) Is formed in the roof tile (21) by being sealed inside the cylindrical shape (23) formed in the roof tile (21) which is integrated with the roof tile (21). A roof tile (21) having a structure capable of preventing rainwater from leaking into the house from the hole (22) and combining the roof tile (21) and the cylindrical shape (23) into an integrated structure is as in Example 20. To do.

As shown in FIG. 73 and FIG. 74, it is a manufacturing company of a solar cell (1) on the surface of a folded-plate roof (2) or a slate roof (2). For example, a solar cell (1) manufactured and sold by UNI-SOLAR, whose headquarters is located in the United States, is made of stainless steel with a thickness of 0.5 mm made of stainless steel on the base. It is a three-layer type composed of amorphous silicon and silicon germanium on the surface of the plate thickness. Moreover, the solar cell (1) of UNI-SOLA is a flexible type and flexible. Further, an adhesive layer (10) having a strong adhesive effect is formed on the back surface of the stainless steel plate as the base. The surface of the solar cell (1) manufactured by UNI-SOLAR, whose base is made of stainless steel plate, is a folded plate roof (2) or a slate roof (2) (hereinafter referred to as a folded plate roof). On the top, for example, a solar cell (1) manufactured by UNI-SOLAR is directly pasted in parallel to the ridge on the surface of the folded roof (2) parallel to the ridge which is the peak of the house. Or, when the solar cell (1) made by UNI-SOLAR is directly pasted at a right angle in the vertical direction on the surface of the folded roof (2) at a right angle in the vertical direction with respect to the ridge which is the peak of the house, On the surface of the folded plate roof (2) using the adhesive layer (10) formed on the back surface of the stainless steel plate constituting the base of the solar cell (1) made by UNI-SOLA Example 21 shows that a solar cell (1) manufactured by UNI-SOLA can be bonded firmly and bonded.

73 and 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter abbreviated as the folded plate roof), a base made by UNI-SOLA. Is made of a stainless steel plate base with a thickness of 0.5 mm and is about 1 m wide and can be cut freely in the length direction. Adhesive layer formed on the back surface of the base of the solar cell (1) manufactured by UNI-SOLAR on the surface of the folded plate roof (2) or the slate roof (2) A solar cell (1) manufactured by UNI-SOLAR is formed on the back surface of the base of the solar cell (1) on the surface of the folded roof (2) or the slate roof (2) with (10) interposed. Folded plate roof (2) or slate roof (with a bonding layer (10) When directly pasting on the surface of 2), the solar cell (1) manufactured by UNI-SOLAR is a long solar cell (1). As a result, the long solar cell (1) is directly pasted. Since the surface tension becomes strong, the solar cell (1) manufactured by UNI-SOLAR is directly attached on the surface of the folded roof (2) or the slate roof (2). In the twenty-second embodiment, the human body can withstand a load that is heavy enough for a human to walk freely.

73 and 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter abbreviated as the folded plate roof), a base made by UNI-SOLA. The solar cell (1) made by UNI-SOLAR, which is made of a stainless steel plate base having a thickness of 0.5 mm made of stainless steel, is a folded plate roof (2) or a slate roof (2 ), A folded roof (2), or a slate roof (2) with an adhesive layer (10) formed on the back surface of the base of the solar cell (1) made by UNI-SOLA. If a solar cell (1) made by UNI-SOLA is directly pasted on the surface of the battery, there is no need for any structure necessary for installing the solar cell (1), so it is extremely inexpensive. The solar cell (1) is folded roof (which is the roof material that constitutes the house) Example 23 is that a solar cell (1) manufactured by UNI-SOLAR can be installed on the surface of 2) or the slate roof (2) at a very low cost.

FIG. 83 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes obsolete after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate is made of a foamed polystyrene plate 29. The foamed polystyrene plate 29 has the shape of an asbestos slate 26 on one side and the slate roof 25 on the other side. Are placed on the surface of the asbestos slate 26 and stacked on top of the surface of the asbestos slate 26 so that a load that can be tolerated on the surface of the asbestos slate 26 is applied by, for example, a person on the surface of the asbestos slate 26. The asbestos slate 26 has a structure that can withstand the weight of human beings, and the slate roof 25 is laminated on the surface of the foamed polystyrene 29 after the load of the asbestos slate 26 exceeds the limit that can withstand walking freely. , Rafter 3, asbestos slate 26, styrofoam 29, and slate roof 25, four types of panels, pad eye 7 and tip portion A slate roof that is attached by stacking slate roofs 25 from above and below from the bottom surface of the rafter 3 that is the roofing material that constitutes the house, using the L-shaped nut-attached L bar 14 25. As a result, after the foamed polystyrene 29 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26, the nut 6, the pad eye 7, and Example 24 shows that the solar cell 1 can be mounted on the surface of the slate roof 25 and fixed using the bolt 5.

The iron plate large wave 34 is extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing damage to the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure pressure as widely as possible. In Example 25, a belt-shaped iron plate 37 is attached on both side surfaces of the large wave 34, and the steel plate large wave 34 and the belt-shaped iron plate 37 are firmly joined.

For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). For example, even for an amateur, a plasterer, or a carpenter, the solar cell 1 and the solar cell 1 are integrated as a structure that can attach the solar cell 1 very easily. Solar power united with Forming a solar cell 1 intended to individually manufacture and sell 1 and Example 26.

For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). The solar cell 1 for the purpose of individually manufacturing and selling the solar cell 1 combined with the roofing material, which has a structure in which the solar cell 1 can be attached very easily. C steel 3 or wood constituting The solar cell 1 which is made by combining the roof material with the roof 3 or the rafter 3 (hereinafter referred to as the rafter 3) is integrated with the roof material from the back surface of the roof material constituting the house. When the solar cell 1 is attached to the rafter 3 constituting the house from the back side, and the iron plate large wave 34 serving as the roof constituting the house is attached to the roof, the solar cell 1 is simultaneously formed on the roof constituting the house. Example 27 is to attach the solar cell 1 to the roof, which is a material.

First, if the position and size of the gap between the wood purlins 3 are determined, or the positions of the holes to be formed in the solar cell 1 are determined, the iron plate large wave 25, the base metal receiving member 42, and the steel frame 43 are formed. The position of the hole to be determined is determined. This means that, for example, 66 holes are drilled on the surface of the iron plate large wave 25 using a drill on the rooftop of the roof where the working environment is severe, and holes are formed on the surface of the iron plate large wave 25. When the drilling work to be performed is performed inside the factory, holes to be formed on the surface of the iron plate large wave 25 are attached with NC, for example, a plurality of 20 to 30 iron plate large waves 25 together. Example 28 is that a machine tool can be used to precisely and accurately drill a large number of holes at an extremely low cost without an error of ± 1 mm.

Machine tools with NC for several tens of roof materials 25 made of iron plate large waves 25, folded plate roofs 25, or other shapes of metal (hereinafter, abbreviated as iron plate large waves). If the iron plate large wave 25 which carried out the hole processing using one is manufactured and sold one by one, the roof is easily constituted by using the nail 4 or the wood screw 4 as the roof material. Attaching to the existing wood purlin 3 is referred to as Example 29.

Iron plate large wave 25 that has been subjected to hole processing, base metal receiving material 42 that has been subjected to hole processing, steel frame 43 that has been subjected to hole processing, solar cell 1 that has been subjected to hole processing, and solar cell panel 1 that is an accessory shown in FIG. When the solar cell panel 1 is attached to the iron plate large wave 25, and a panel set is packed together and manufactured and sold as a kit or set, the solar cell 1 is used as a roofing material 3 In addition, it is assumed that the work to be attached to the iron plate large wave 25 can be easily attached by an amateur, a carpenter or a plasterer as Example 30.

For the purpose of mounting the solar cell 1 on the surface of the iron plate large wave 25, the roof material 25 made of iron plate large wave 25, folded plate roof 25, or other shaped metal (hereinafter abbreviated as iron plate large wave 25). On the surface of the rafter 3 constituting the roof material, or the C steel 3, or the wooden purlin 3 or the skeleton 3 constituting the roof of the house (hereinafter abbreviated as rafter). For the purpose of attaching and fixing a single iron plate large wave 25 to the rafter 3 using the nail 4, the wood screw 4, or the screw hex 4 (hereinafter abbreviated as a nail). The total number of holes to be formed on the surface of one large iron plate wave 25 needs to form approximately 66 holes. The total position of forming approximately 66 holes constitutes the roof of the house with the steel plate large wave 25, the base metal receiver 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25 for short). Since the purpose is to attach and fix to the central part of the rafter 3, the total number of holes formed in the iron plate large wave 25, all the positions of about 66 holes, are shown in FIGS. 125 and 130, for example. As shown in the figure, the iron plate at a position corresponding to a portion directly above the central portion of the rafter 3 which is the purlin 3 constituting the roof of the house, and the rafters 3 are attached at intervals of 428.5 mm. In the processing factory that has already produced the iron plate large wave 25 in the large wave 25, a hole is formed on the surface of the iron plate large wave 25 using the NC machine tool on the surface of the top of the mountain where the uneven portion of the iron plate large wave 25 is present. The surface of the iron plate large wave 25 Since holes can be formed at positions where there is no error of ± 1 mm, for example, as shown in FIGS. 125 and 130, the interval between the rafters 3 is first set to 428.5 mm, and the positions of the rafters 3 are If accurately determined, the iron plate large wave 25 in which holes are formed on the surface of the iron plate large wave 25 at intervals of 428.6 mm in the iron plate large wave 25 shown in FIGS. 126 and 131 is a rafter. If the iron plate large wave 25 is attached to the rafter 3 using the nail 4 and installed from right above the iron plate 3, the iron plate large wave 25 can be easily attached to the rafter 3 without dividing the size of the iron plate large wave 25. . To install the solar panel 1 on the surface of the iron plate large wave 25, the installation of the solar cell panel 1 is completed on the surface of the iron plate large wave 25 just by assembling the kit as a set of the solar cell panel 1 on the surface. In order to install the solar cell panel 1 on the surface of the iron plate large wave 25, there is no need to divide the dimensions on the roof of the work site and to match the actual product on the site. It is easy to attach and fix to the rafter 3, and the kit that is a set of solar panel 1 can be mass-produced at the processing factory, so the cost is low, the delivery time is fast, and the installation work is simple. Even an amateur, carpenter, or plasterer can perform installation work, so the solar cell panel 1 is attached to the iron plate large wave 25 and the rafter 3, and the solar cell panel 1 is attached to the iron plate large wave 25. Construction period necessary to complete the roof mounted on the surface is as in Example 31 to be overwhelmingly reduced.

For attaching and fixing the solar cell 1 on the surface of the iron plate large wave 25 using the iron plate large wave 25, the base metal receiver 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25). Panel 1 of solar cell 1, which is a metal panel shown in FIG. 135, including one solar cell panel, one steel plate large wave 25, four base metal pieces 42, two steel frames 43. Large iron plate using a box (hereinafter abbreviated as a set, a kit, or a solar cell set, or a solar cell kit) in which a set of metal fittings are packed together in one box The explanation about attaching the solar cell 1 on the surface of 25 was given. However, the processing means for attaching the solar cell 1 to the surface of the iron plate large wave 25 is used to attach the roof to the rafter 3, which is the roof constituting the roof of the house, using only the iron plate large wave 25 alone. As a processing means for attaching the iron plate large wave 25 as a roof material for the purpose of constructing only a roof, for example, as shown in FIGS. 125 and 130, when a roof of a house is first constructed, a rafter is constructed. If the position of the rafter 3 is determined at an interval of 428.5 mm, the iron plate large wave 25 and the hole interval of the iron plate large wave 25 shown in FIGS. 126 and 131 are 428.5 mm. It is possible to attach the iron plate large wave 25 to the rafter 3 by using the nail 4 by installing the iron plate large wave 25 having a hole formed on the surface thereof from right above the rafter 3. In this way, when the roof is configured using the iron plate large wave 25 in which a hole is formed in the iron plate large wave 25 using the NC machine tool, the rafter 3 constituting the roof of the house is configured as described above. As in the case of attaching the solar cell 1 to the iron plate large wave 25 as described, if the position of the rafter 3 is determined, the error of the hole formed in the iron plate large wave 25 is no error of ± 1 mm, so it is a work site. Since it is not necessary to divide the size of the iron plate large wave 25 on the surface of the roof, it is easy to attach and fix the iron plate large wave 25 to the rafter 3. Since the operation is simple, the cost is low, and the construction period required to complete the roof by attaching the iron plate large wave 25 to the rafter 3 is overwhelmingly shortened as Example 32.

The pre-process processing before forming the iron plate large wave (25) is completed, for example, Nisshin Steel Co., Ltd. manufactures and sells, and the trade name is a galvastar (ZG) steel plate, or a ZAM steel plate, or a flat steel plate A flat steel plate coated with paint on the surface of the steel plate, a flat steel plate coated with urethane paint, a flat steel plate that has been rolled, or a steel coil wound around crawling, or a strip steel flat plate, or flat plate, or A decorative plate made of plywood, a plywood plate, a flat plate made of plastic, or a flat plate made of other materials, an exterior flat plate material, or an internal flat plate material (hereinafter abbreviated as a plastic flat plate or a decorative plate) Thin film quantum dot PV solar cell (5), for example, which was successfully researched and developed by Solterra in the United States. 1) Roll-to-roll printing of a quantum dot solar cell (51) on the surface of a flat steel plate (44) using a manufacturing technique (hereinafter referred to as quantum dot solar cell (51) for short) Flat plate steel plate (44) having a quantum dot type solar cell (51) directly formed on the surface of the flat plate steel plate (44) by using a technology, ink jet printing technology, or screen printing technology, or Example 33 is that a flat steel plate (44) on which quantum dot solar cells (51) are formed can be formed on the surface of a strip steel flat steel plate (44) wound in round and round.

A quantum dot solar cell using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). Polycarbonate, which is made of a resin having good sunlight transmittance for the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which (51) is formed. A film made of a resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is made of a flat steel plate (44) on which a quantum dot solar cell (51) is formed. As a protective film (45) on the surface, a quantum dot solar cell (51) is formed on the surface of a flat steel plate (44) in which a quantum dot solar cell (51) is formed on the surface of the flat steel plate (44). The flat steel plate (44) bonded on the surface of the flat steel plate (44) is used as the protective film (45) for protecting the surface of the steel plate, or the quantum dot solar cell (51) of the flat steel plate (44) is used. The protective film (45) is not formed on the surface of the flat steel plate (44), which is formed on the surface of the quantum dot solar cell (51), which is in a state of being formed on the surface, The outer periphery of a house, which is a building material that forms a flat steel plate (44) forming a quantum dot solar cell (51) and constitutes a house or a building (hereinafter abbreviated as a house). It is used as an outer wall plate of the wall material constituting the, or as an exterior material. For example, a quantum dot type solar cell (51) is formed on the surface of a flat steel plate (44) on the surface of a flat steel plate (44) having a width of 90 cm and a vertical width of 180 cm. Using the solar cell (51), electric power is generated using the energy of solar rays. Moreover, the quantum dot type solar cell (51) which has formed the quantum dot type solar cell (51) on the surface of a flat steel plate (44) as an interior material for the room | chamber interior currently used in the house interior. ) Using the energy of light generated from incandescent lamps or fluorescent lamps that are used inside houses or buildings, and using quantum dot solar cells (51 ) Is formed on the surface of the flat steel plate (44), the quantum dot solar cell (51) is used to generate power using the quantum dot solar cell (51). Example 34 shows that a flat steel plate (44) forming the battery (51) can be formed.

A quantum dot solar cell using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). Polycarbonate, which is made of a resin having good sunlight transmittance for the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which (51) is formed. A film made of a resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is made of a flat steel plate (44) on which a quantum dot solar cell (51) is formed. As a protective film (45) on the surface, a quantum dot solar cell (51) is formed on the surface of a flat steel plate (44) in which a quantum dot solar cell (51) is formed on the surface of the flat steel plate (44). As the protective film (45) for protecting the surface of the steel plate, the flat steel plate (44) bonded on the surface of the flat steel plate (44) is used, or the quantum dot solar cell (51) is used as the flat steel plate (44). The protective film (45) is not formed on the surface of the flat steel plate (44) which is formed on the surface of the quantum dot solar cell (51) which is in a state of being formed on the surface of The plate steel plate (44) forming the quantum dot solar cell (51) is directly used to form the iron plate large wave (46) for the purpose of forming the iron plate large wave (46). Then, the quantum dot solar cell (51) is formed on the surface of the flat steel plate (44), the flat steel plate (44) is molded, and directly on the surface of the iron plate large wave (25), Forming a large iron plate wave (46) forming a quantum dot solar cell (51) It is as in Example 35 to be able to.

The plate steel plate (44) forming the quantum dot solar cell (51) is directly formed on the surface of the plate steel plate (44) by the shape of the iron plate large wave (25) or the shape of the folded plate roof (25) ( Hereinafter, the quantum dot solar cell (51) is directly formed on the surface of the iron plate large wave (25) by molding using a molding machine for forming the iron plate large wave (25). The rafter (3), the purlin (3), or the skeleton (3 for short) constituting the roof of the house (hereinafter abbreviated as rafter (3) And a hole (47) for attaching the steel plate large wave (25) to the rafter (3) using a stainless steel screw (4), for example, a hole having a hole diameter of 9 mm ( 47), an iron plate large wave (46) formed on the surface of the iron plate large wave (46), for example, an iron plate large wave (46) Laminate 0 to 20 sheets together and stack them, and use a machine tool with NC to drill holes (47) from 40 to 60 places with an error of within ± 1 mm. In Example 36, it is possible to form a large iron plate wave (46) in which a hole (47) is simultaneously formed on the surface of 46).

Using a printing technology such as roll-to-roll printing technology, ink jet printing technology, or screen printing technology on the surface of the steel plate big wave (25) or flat steel plate (44), The quantum dot solar cell (51) can be formed uniformly along the curved surface on the surface of the plate roof (25). Example 37 shows that a quantum dot solar cell (51) can be formed on the surface of a flat steel plate (44).

Conventionally, a corrugated steel plate (2) having the same shape is used by forming the solar cell (1) on the surface of the corrugated steel plate (2). For example, a chicken hut Solar cell (1) on the surface of corrugated corrugated steel plate (2) by replacing it with corrugated corrugated steel plate that has the same vertical and horizontal dimensions. The corrugated steel plate having the power generation function can be easily replaced without forming a structure for attaching the solar cell by replacing the corrugated steel plate with the power generation function (2). (2) can be replaced.

In Japan, the corrugated tin plate described above is used only on the roof of a chicken hut. But in Southeast Asia, the equatorial zone of the hottest and the poorest countries in the world, Southeast Asia, sub-Saharan Africa, southern China, and Central and South America sub-Mexico, main house roofing materials Is a corrugated tin plate. There are also many homes living without electricity infrastructure. The main roofing material of the houses inhabited by people who have no electrical infrastructure is corrugated corrugated tin. Replacing corrugated corrugated steel plate, which is the roofing material of houses inhabited by people without this infrastructure, with corrugated corrugated steel plate (2) that has the same power generation function and dimensions. Thus, electricity can be easily supplied.

Further, the corrugated stainless steel plate (2) is replaced with a bolt (5), a nut (6), a hook (7), a pad eye (7), a long eye (7), or an open pad eye (7). ), Or eye strap (7), or UK turnbuckle (7), or L bar with nut (hereinafter abbreviated as nut, hook or eye), or other means, A rafter (3) is attached to the rafters (3) constituting the roof of the corrugated iron plate (2) from the back surface of the corrugated steel plate (2), so that a nail ( 4) From the back to the rafter (3), the corrugated iron plate (2) is formed on the rafter (3) of the roofing material that constitutes the house without damaging the wounds generated by hitting. Because it is installed and fixed, corrugated tin Since the corrugated stainless steel plate (2) can be used as a roofing material without generating any scratches on the surface of (2), for example, the product name described above is the Galvaster (ZG) Steel sheet or ZAM steel sheet is used to form corrugated stainless steel sheet (2), and the service life is Nisshin Steel Sheet Co., Ltd., which manufactures and sells Galvaster (ZG) steel sheet or ZAM steel sheet Is made of corrugated corrugated iron plate (2) and flat plate that does not corrode at all for 30 to 50 years, which is 3 to 5 times the warranty period of 10 years. A tin plate (8) can be formed.

1. A solar cell (hereinafter abbreviated as a solar cell) is formed on the surface of a corrugated iron plate or a slate corrugated plate (hereinafter abbreviated as a tin plate) made of cement. ing.
2. A corrugated steel plate or slate roof (hereinafter abbreviated as a steel plate or slate roof)
3 Rafters, or C steel, or a wooden purlin, or a skeleton that constitutes the roof of a house (hereinafter abbreviated as rafters)
4 nails, sword hexes, wood screws, or stainless steel screws (hereinafter abbreviated as nails)
5 bolts, complete hook bolts, pipe hook bolts, channel hook bolts, or other fittings (hereinafter abbreviated as hooks or bolts)
6 Nut 7 Nut, or hook, or pad eye, or long eye, or open pad eye, or eye strap, UK turnbuckle, L rod with nut, complete hook bolt, pipe hook bolt, or channel hook bolt Or other mounting brackets (hereinafter abbreviated as nuts, hooks, eyes, or pad eyes)
8 Steel plate made of flat plate 9 One side made of foamed polystyrene, foamed polystyrene, foamed urethane, or other foamed object is corrugated, and the other side is flat, or used as roof tile tile A foamed object made of a shape similar to the shape of a roof tile (hereinafter abbreviated foamed polystyrene board)
10 Adhesive, or adhesive layer, or double-sided tape (hereinafter abbreviated as adhesive layer or double-sided tape)
11 Tile that is made of expanded polystyrene, expanded polystyrene, expanded urethane, or other foamed objects, both sides are flat, or one side is flat, and the other is used as a roof tile Foamed object made of a shape similar to the shape (hereinafter abbreviated as a flat polystyrene foam plate)
12 Packing for the purpose of preventing rainwater from entering and leaking (hereinafter abbreviated as packing)
13 Parts where bolts (5) and pad eyes are joined using welding, or metal adhesive, or double-sided tape (hereinafter abbreviated as welded parts, metal adhesive parts, or double-sided tape)
14 L-shaped rod with nut 15 whose tip is n-shaped 15 A part where two steel plates are joined using a rivet (rivet) or an eyelet (hereinafter abbreviated as heel) 16 Copper pipe Solar cell surface (hereinafter abbreviated as solar cell surface)
17 Reflective mirror 18 Tempered glass 19 Lower part of solar cell 20 Foamed object in which both side surfaces made of expanded polystyrene, expanded polystyrene, expanded urethane, or other expanded objects are formed in a flat plate shape (hereinafter abbreviated as a flat plate shape) The thickness of the sheet made of expanded polystyrene or expanded polystyrene is, for example, expanded polystyrene or expanded polystyrene having a thickness of about 5 mm. For example, a plate made of aluminum having a thickness of about 0.01 mm is formed on both sides of the plate, and a polystyrene foam is used by using an adhesive on both sides of the plate made of polystyrene foam or polystyrene. Or stick the plate made of aluminum on both sides with the plate made of polystyrene foam as the center Plywood made of polystyrene foam and aluminum (hereinafter abbreviated as Mirapane Ace (20))
21 Roofing material made of roof tile made of roof tile, slate, or corrugated iron plate, or steel plate made of ordinary flat plate, or other thin plate (hereinafter referred to as tile)
22 A hole (hereinafter abbreviated as a roof tile) formed in roofing material made of roof tiles made of roof tiles made of roof tiles made of roof tiles made of roof tiles, slate, normal corrugated plate, or normal flat plates, or other flat plates A hole formed in
23 Roofing material (hereinafter abbreviated as tile) made of roof tile made of roof tiles, slate, corrugated corrugated sheet, corrugated corrugated sheet, corrugated sheet, or other thin sheet (hereinafter referred to as roof tile) A long cylindrical shape (hereinafter abbreviated as a cylindrical shape) formed on a surface of a roof that is similar to a chimney and has a long cylindrical shape with a hollow inside of the roof tile. To do)
24 The hatched portion formed on the roof tile (21) passes through the inside of the cylindrical shape, and for the purpose of sealing the L-rod (14) with nut whose tip portion is n-shaped, silicone resin Sealing agent that seals the adhesive made of, etc., or packing made of silicone resin or silicone rubber (hereinafter abbreviated as sealing agent or packing)
25 Iron roof made of corrugated sheet, or corrugated sheet roof, or slate roof, or steel sheet small wave, or iron sheet large wave, or square wave, or roof, or mated flat roof tile, or side roof, or folded Plate roof (hereinafter abbreviated to be a tin plate, a slate roof, a square wave, a roof, a mated flat roof tile, a horizontal roof, or a folded plate roof)
26 Asbestos slate 27 Styrofoam with one side shaped asbestos slate 26, slate roof 25, or iron plate large wave 25 and the other one side with flat plate shape 28 Styrofoam with both sides shaped flat plate 29 One side is foamed polystyrene with the shape of asbestos slate 26, the other side is corrugated steel plate, or slate roof, or iron plate small wave, or iron plate large wave, or square wave, or roof, or mated flat tile Rod, or horizontal roof, or folded-plate roof (hereinafter abbreviated as steel plate, slate roof, square wave, roof, or mated flat tile rod, horizontal roof, or folded-plate roof) ) In the form of polystyrene foam 30 on one side, a foamed polystyrene on the other side, and a corrugated stainless steel plate on the other side, or Rate roof, or iron plate small wave, or iron plate large wave, or square wave, or roof, or mated flat roof tile, or horizontal roof, or folded plate roof (hereinafter, abbreviated as a steel plate, slate roof, or corner) Styrofoam 31 junction box (hereinafter abbreviated as FA2 terminal box) in the shape of wave, roof, mated flat roof tile, side roof, or folded roof
32 The composite roofing material 33 which united the iron plate large wave 25 and the solar cell 1 and united them 33 The iron plate large wave 25 located in the upper part
34 Large iron plate 25 located in the lower part
35 Washer, nut, or other metal fitting larger than the hole portion 36 formed in the iron plate large wave 25 (hereinafter abbreviated as a washer)
36 Hole portion 37 formed in the iron plate large wave 25 A strip-shaped iron plate, for example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate)
38 Through-hole formed in the belt-shaped iron plate 37, or through-hole formed with, for example, a millimeter screw or an inch screw (hereinafter abbreviated as a millimeter screw) in the through-hole 39 A cylindrical washer (hereinafter abbreviated) A cylindrical washer)
40 Although not shown in the drawings, for the purpose of preventing the leakage of rainwater, several asbestos packings are used to prevent water leakage (hereinafter abbreviated as asbestos packing). To do)
41 Wave ridge 42 Underlying metal receiving object 43 Steel frame 44 Flat steel plate, steel coil wound around round, strip steel flat plate, flat plate, decorative plate made of veneer plate, veneer plate, flat plate made of plastic An exterior flat plate material or an internal flat plate material (hereinafter abbreviated as a plastic flat plate, a decorative plate, a flat plate, or a flat steel plate) that is a flat plate made of other materials.
45 Protective film 46 Solar cell 47 forming solar cell (1) directly on the surface of iron plate large wave (25) or folded plate roof (25) 47 Stainless steel forming iron plate large wave (46) Hole for attaching to rafter (3) using wooden screw (4) (hereinafter abbreviated as hole)
48 Urethane coating 49 Flat steel plate with urethane coating formed on the surface of the flat steel plate (44) (hereinafter abbreviated as flat steel plate with urethane coating)
50 Iron plate large wave with urethane coating 51 Quantum dot type solar cell, silicon type solar cell (1), or other compound type solar cell (1) (hereinafter, abbreviated as quantum dot type solar cell (51))

Claims (62)

For the purpose of forming the solar cell (1) on the corrugated steel plate (2), the rafter (3) and the nail (4) are attached to the back surface of the corrugated steel plate (2). Use rafters (3) on the back of corrugated tin plate (2) and nail (4) to fix rafters (3) on the back of corrugated tin plate (2) After that, the solar cell (1) is formed on the surface of the tin plate (2), which is characterized in that the solar cell (1) is formed on the surface of the corrugated tin plate (2). A tin plate and its processing method. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The rafters (3) are nuts (6) on the back surface of the corrugated steel plate (2) to which the bolts (5) are welded or the bolts (5) are fixed using a metal adhesive. ) Is used to form the solar cell (1) on the corrugated steel plate (2) surface after the rafter (3) is fixed to the back surface of the corrugated steel plate (2). The tin plate which has formed the solar cell (1) on the surface of the tin plate (2) characterized by having performed, and its processing method. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2), the concave shape or the convex shape forming irregularities on the corrugated tin plate (2) The rafters (3) are attached to the back surface of the corrugated steel plate (2) by using the nails (4) with the rafters (3) in the direction parallel to the concave or convex direction. On the surface of the tin plate (2), wherein the solar cell (1) is formed on the surface of the corrugated steel plate (2) after the rafter (3) is fixed by nailing A tin plate forming the solar cell (1) and a processing method thereof. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). In addition, the concave shape forming the corrugations of the corrugated plate on the back surface of the corrugated steel plate (2) which is welded with the bolt (5) or using a metal adhesive to form the corrugated bolt (5), Alternatively, a corrugated steel plate (2) using a rafter (3) and bolts (5) and nuts (6) in parallel with the concave or convex direction on the convex back surface (2) Of the tin plate (2) characterized in that the solar cell (1) is formed on the surface of the corrugated tin plate (2) after the rafter (3) is attached and fixed to the back surface of A tin plate on which the solar cell (1) is formed on the surface, and a processing method thereof. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The corrugated steel plate (2) is welded with a nut (6) to the back surface of the corrugated steel plate (2), or the nut (6) is fixed using a metal adhesive ( Corrugated iron after fixing rafter (3) to the back of corrugated steel plate (2) using rafter (3) bolt (5) on the back of 2) A tin plate characterized in that a solar cell (1) is formed on the surface of a tin plate (2), wherein the solar cell (1) is formed on the surface of the plate (2), and a processing method thereof . For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). Next, the corrugated steel plate after the bolt (5) is welded or the bolt (5) is fixed to the back surface of the corrugated steel plate (2) using a metal adhesive. A tin plate in which the solar cell (1) is formed on the surface of the tin plate (2), wherein the solar cell (1) is formed on the surface of (2), and a processing method thereof. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). Next, the nut (6) is welded to the back surface of the corrugated steel plate (2), or the nut (6) is welded to the back surface of the corrugated steel plate (2) using a metal adhesive. The solar cell (1) is formed on the surface of the tin plate (2), wherein the solar cell (1) is formed on the surface of the corrugated tin plate (2) after being fixed. Iron plate and processing method thereof. For the purpose of forming the solar cell (1) on the surface of the corrugated tin plate (2) and for the purpose of fixing the rafter (3) to the back surface of the corrugated tin plate (2). The hook (7) is welded to the back surface of the corrugated steel plate (2), or the hook (7) is attached to the back surface of the corrugated steel plate (2) using a metal adhesive. The solar cell (1) is formed on the surface of the tin plate (2), wherein the solar cell (1) is formed on the surface of the corrugated tin plate (2) after being fixed. Iron plate and processing method thereof. For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the steel plate (8) made of a flat plate after the bolt (5) is welded or the bolt (5) is fixed using a metal adhesive. The tin plate which has formed the solar cell (1) on the surface of the tin plate (2) characterized by having performed, and its processing method. For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the flat plate (8) after welding the nut (6) or fixing the nut (6) using a metal adhesive. The tin plate which has formed the solar cell (1) on the surface of the tin plate (2) characterized by having performed, and its processing method. For the purpose of forming solar cells (1) on the surface of a tin plate (8) made of flat plate, for the purpose of attaching rafters (3) etc. to the back surface of the tin plate (8) made of flat plate Next, the solar cell (1) is formed on the surface of the flat plate (8) made of a flat plate after the hook (7) is welded or the hook (7) is fixed using a metal adhesive. The tin plate which has formed the solar cell (1) on the surface of the tin plate (2) characterized by having performed, and its processing method. A hook plate (7), a pad eye (7), a long eye (7), or an open pad eye (7) on the back surface of a corrugated tin plate (2) or a flat plate (8) made of a flat plate ), Or eye strap (7), or UK turnbuckle (7) (hereinafter abbreviated as a nut, hook, or eye) or a rafter (3) The wave which formed the spherical silicon solar cell module which can condense a solar ray from many directions and has much higher electric power generation efficiency on the surface of the made tin plate (2) or the tin plate (8) made of a flat plate A rafter (3) that constitutes a roof of a house made of a steel plate (2), or a steel plate (8) that forms a solar cell (1) on the surface of a steel plate (8) made of a flat plate Or rafters that make up the wall ( ) From the back surface of the roof of the house or the back surface of the wall constituting the house, the solar cell (2), or the surface of the tin plate (8) made of a flat plate (8) 1), a corrugated iron plate (2) or solar cell (1) having a solar cell (1) formed by attaching and fixing the solar cell (1). A tin plate (8) made of the formed flat plate and a processing method thereof. Aluminum (Al) on the surface of the iron plate constituting the corrugated tin plate (2) or the tin plate (8) made of a flat plate (hereinafter referred to simply as the tin plate or iron plate). 55% + zinc (Zn) 43.4% + silicon (Si) 1.6% alloy base metal is melted in the plating tank, and the iron plate is immersed in the plating plate. Corrugated tin plate (2) subjected to galvalume plating (hereinafter, abbreviated as Galva Steel, or Nisshin Steel Co., Ltd., the product name of which is manufactured and sold by Galbuster or ZG) The solar cell (1) is formed on the surface of the tin plate (8) made of a flat plate, and the roof of the house is constructed from the surface on which the solar cell (1) is formed on the surface of the tin plate. Using the nail (4) to the rafter (3), directly form the solar cell (1) Even if the corrugated steel plate (2) or the steel plate (8) made of flat plate is nailed from the top of the steel plate to the rafter (3) using the nail (4), it can be made of galva steel plate. Since the corrugated iron plate is highly corrosion resistant and resistant to corrosion, the solar cell (1) formed on the surface of the corrugated steel plate made of galva steel plate and the corrugated tin plate (2), or Since the progress of peeling with the flat plate made of flat plate (8) can be most reduced, the solar cell (1) is formed on the surface of the corrugated plate made of galvanized steel plate (2). Form. Or, if the steel plate (1) is formed on the surface of the steel plate (8) made of a flat plate, the roof of the house is constructed from the surface of the steel plate using nails (4). The solar cell (1) characterized in that the rafter (3) can be directly struck onto the rafter (3) using the nail (4) from the surface on the surface of the tin plate. A corrugated iron plate (2), or a tin plate (8) made of a flat plate on which a solar cell (1) is formed, and a processing method thereof. Plated on the surface of a corrugated steel plate (2) suitable for use in cattle barns and compost houses, or a steel plate (8) made of flat plate (hereinafter abbreviated as a steel plate). For processing, for example, zinc (Zn) 91% + aluminum (Al) 6% + magnesium (Nisshin Steel Co., Ltd.) manufactured and sold with excellent ammonia resistance and wet resistance. (Mg) 1% solar cell on the surface of corrugated tin plate using ZAM steel plate, which has been subjected to double-bake plating inside the plating tank in which the metal made of 1% is melting Form. Alternatively, a corrugated tin plate (2) formed with a solar cell (1), wherein the solar cell (1) is formed on the surface of a flat plate (8) made of a flat plate, or the sun A tin plate (8) made of a flat plate on which the battery (1) is formed, and a processing method thereof. Corrugated corrugated iron plate (2) is damaged from the corrugated corrugated steel plate (2) by attaching rafters (3) constituting the roofing material of the house from the back side. Corrugated iron plate (2) or flat plate characterized by attaching and fixing corrugated steel plate (2) to rafter (3) constituting the roofing material of the house A tin plate (8) made of the above and its processing method. For the purpose of attaching the solar cell (1) on the surface of the corrugated tin plate (2), a polystyrene foam plate is placed between the corrugated tin plate (2) and the solar cell (1). A module in which a foamed polystyrene plate (11) made of (11) on both sides is formed in a flat plate shape is interposed between a corrugated steel plate (2) and a solar cell (1). Using bolts (5) and nuts (6) joined on the surface of corrugated stainless steel plate (2) using welded part (13) or metal adhesive part (13) Then, a foamed polystyrene plate (11) having both sides made of a polystyrene foam plate (11) is formed in the middle, and a solar cell (1) is placed on the surface of the foamed polystyrene plate (11). After forming the adhesive layer (10) and bonding Furthermore, after attaching the solar cell (1) to the corrugated steel plate (2) using the bolt (5) and the nut (6), on the back surface of the corrugated steel plate (2) Hook (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) or UK turnbuckle (7) or L rod with nut , Abbreviated as pad eye) is attached to the corrugated tin plate (2), and then the tip of the pad eye (7) attached to the back surface of the corrugated tin plate (2) Corrugated iron plate (2) using corrugated iron plate (2) using r-bar with nut with n-shaped part on roof rafter (3) constituting the house 2) From the back side of rafter (3) to corrugated sheet (2) The corrugated tongue plate (2) is formed by using an L rod with a nut having an n-shaped end and a pad eye (7) attached to the corrugated tongue plate (2). A corrugated tin plate (2) or a tin plate (8) made of a flat plate, characterized by being attached to the rafter (3) from the back, and a processing method thereof. On the surface of corrugated stainless steel plate (2), for example, the product name manufactured and sold by Nisshin Steel Co., Ltd. is spherical on the surface of corrugated steel plate (2) using ZAM steel plate. A solar cell surface (16), a concentrating solar cell (1) composed of tempered glass (18) and a reflecting mirror (17) is installed, and the solar cell lower portion (19 ) In close contact with the peak portion of the corrugated iron plate (2) and dissipating heat from the corrugated steel plate (2). 2) and its processing method. The upper surface of the corrugated stainless steel plate (2) is used as a reflecting mirror (17), and a concentrating solar comprising a cylindrical solar cell surface (16), a tempered glass with a conductive thin film (18), and a reflecting mirror (17). The cylindrical solar cell surface (1) is characterized by radiating heat from the tin plate (2) in order to integrally form the battery (1) and suppress temperature overheating of the solar cell surface (16). A corrugated stainless steel plate (2) formed thereon and a processing method thereof. For the purpose of mounting the solar cell (1) on the corrugated tin plate (2) surface,
A hook (7), a pad eye (7), a long eye (7), an open pad eye (7), an eye strap (7), or a UK turn After attaching a buckle (7) or an L bar with a nut (hereinafter abbreviated as pad eye) to the back surface of the corrugated steel plate (2), the corrugated steel plate (2 After the solar cell (1) is bonded on the surface of the adhesive plate (10) with the adhesive layer (10) interposed, the tip portion is attached to the pad eye (7) attached to the back surface of the corrugated iron plate (2). The corrugated iron plate (2) using the n-shaped L-rod with a nut, and the corrugated steel plate (2) to the rafter (3) of the roof material constituting the house (2) ) To the rafter (3) from the back side of the corrugated steel plate (2) Using the L-shaped nut-attached L bar and the pad eye (7) attached to the corrugated tin plate (2), the rafters (from the back of the corrugated tin plate (2) ( 3) A corrugated iron plate (2) having a solar cell (1) formed on the surface thereof, and a processing method thereof. For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Or forming a corrugated tin plate (2) by forming a metal adhesive portion (13) and fixing a nut (6) on the surface of the corrugated corrugated steel plate (2). Thus, for example, as shown in FIG. 37, a spherical silicon solar cell module (output 115W) manufactured and sold by Clean Venture 21 Co., Ltd., located at Kamitoba Daichocho 35, Minami-ku, Kyoto, Using a spherical silicon solar cell module (output 115W) using a nut (6) attached and fixed on the surface of a corrugated tin plate (2), the corrugated tin Easily and firmly mounted on the surface of the plate (2) Galvanized iron plate has a corrugated shape which is formed on the surface and the solar cell (1), characterized in that it can be attached (2), and its processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Alternatively, a metal adhesive portion (13) is formed and a nut (6) is fixed on the surface of the corrugated stainless steel plate (2), and then the corrugated steel plate (2) and solar cell In the middle of (1), although it is a board made of foamed polystyrene and aluminum, an adhesive layer (10) is formed on both sides, and on both sides of the foamed polystyrene board, both sides are made of aluminum. For example, the name of the company that is located in 3-4-2 Marunouchi, Chiyoda-ku, Tokyo (Nipponishi Building), and the name of the product that JSP Co., Ltd. manufactures and sells is Mirapane Ace (hereinafter abbreviated, Plywood made of Mirapane Ace) , And Mirapaneesu plywood (20). A corrugated iron plate (2) and a solar cell (1) interposing adhesive layers (10) formed on both sides of a plywood (20) made of this Mirapane ace plywood (20) Laminated. Further, an arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated tin plate (2) to form a pad eye (7), a long eye (7), or an open. Corrugated tin with pad eye (7) or eye strap (7) (hereinafter abbreviated as pad eye) formed on the back surface of corrugated corrugated tin plate (2) With the formation of the plate (2), even if a human freely walks on the surface of the solar cell (1) formed on the surface of the corrugated iron plate (2), it can withstand the weight of the human. It becomes the structure of the solar cell (1) that can be used. It also has a soundproofing effect. Furthermore, the solar cell (1) is laid on the surface of the corrugated iron plate (2), which has a heat resistance effect. The solar cell (1) is laid on the corrugated steel plate (2). However, no special structure is required at all, and the solar cell (in the same work process as the work process of laying the corrugated iron plate (2) as the roof of the roofing material) 1) A corrugated iron plate (2) having a solar cell (1) formed on the surface thereof, and a processing method thereof. Conventionally, when the corrugated steel plate (2) is used as the roof of a house and the corrugated steel plate (2) is currently used, the corrugated plate shape described above is used. The corrugated steel plate (2) which uses the corrugated steel plate (2) having the solar cell (1) formed on the surface of the corrugated steel plate (2) as a roof of a house at present (2) A hole is formed in the corrugated steel plate (2) constituting the roof of the house from above the surface, and the corrugated steel plate (2) is penetrated to constitute the house. In order to firmly fix the corrugated steel plate (2) formed on the surface of the solar cell (1) to the rafter (3), the back surface of the corrugated steel plate (2) Pad eye (7), long eye (7), or open pad eye (7), or ice tiger (7) (hereinafter abbreviated as pad eye), bolt (5), nut (6), or L rod with nut, etc. If the corrugated iron plate (2) forming the solar cell (1) is overlapped and overlapped from the surface of the plate-shaped tin plate (2), the solar cell will be more simplified. (1) A corrugated iron plate (2) having a solar cell (1) formed on the surface thereof, and a processing method thereof. Conventionally, a roof of a house made of a tile roof as a roof material of a house, a roof of a slate roof material made of cement, or a roof of a roof material made of other artificial thin plate (hereinafter abbreviated, When installing the corrugated steel plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2) described above. In the same manner as described above, a hole is formed in the tile roof tile that constitutes the roof of the house, and the roof tile is penetrated to the rafter (3) constituting the house. A pad eye (7) attached to the back surface of the corrugated steel plate (2) for fixing the corrugated steel plate (2) on which the battery (1) is formed. Or long eye (7) or open pad eye (7) or eye strap (7) Hereinafter, abbreviated pad eye), or a tile roof or slate roof currently used as a roof of a house using a bolt (5), a nut (6), or an L bar with a nut, etc. On the surface of the roof made of slate or the tile roof that is currently using the corrugated iron plate (2) forming the solar cell (1) from the surface used as When the solar cell is placed on the surface of the corrugated iron plate (2), which is currently used as a roof of a house, as described above, when it is installed firmly and overlapped with each other and fixed. Similar to the case where the corrugated iron plate (2) forming (1) is installed, the solar cell (1) is more easily arranged on the surface of the roof tile or on the roof made of slate. It can be firmly fixed on the surface. Solar cell (1) galvanized iron plate having a corrugated shape which is formed on the surface (2), and its processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Alternatively, a metal adhesive portion (13) is formed and a nut (6) is fixed on the surface of the corrugated stainless steel plate (2), and then the corrugated steel plate (2) and solar cell In the middle of (1), a plywood plate (20) made of a polystyrene foam plate and a plate made of aluminum is formed with an adhesive layer (10) interposed, and then laminated. An arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7), a long eye (7), or an open pad Eye (7) or eye strap (7) (hereinafter abbreviated as pad To the roof tiles (21) constituting the roof of the house to attach the rafters (3) constituting the house on the back surface of the corrugated iron plate (2). A hole (22) is formed, and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are tiled ( 21) Use the L-shaped bar with nut (14) that penetrates the inside of the hole (22) formed in 21) and the tip part is n-shaped, to the rafter (3) that constitutes the house The solar cell (1) on the surface of the corrugated iron plate (2), and further, the soundproofing effect, the heat insulating effect, or the roof tile (21) on the back surface of the corrugated steel plate (2). For the purpose of improving the adhesion to the inside, the polystyrene foam plate (11) with both side surfaces in a flat plate shape is sandwiched The rafters constituting the house with the corrugated steel plate (2) forming the solar cell (1) on the surface of the corrugated steel plate (2) 3) A corrugated plate forming a solar cell (1) on the surface of a corrugated iron plate (2) on the surface of a roof made of tiles (21) firmly attached to 3) A corrugated tin plate (2) in which a solar cell (1) is formed on the surface, and a processing method thereof. For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Alternatively, a metal adhesive portion (13) is formed and a nut (6) is fixed on the surface of the corrugated stainless steel plate (2), and then the corrugated steel plate (2) and solar cell In the middle of (1), a plywood plate (20) made of a polystyrene foam plate and a plate made of aluminum is formed with an adhesive layer (10) interposed, and then laminated. An arc welded part (13) or a metal adhesive part (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7), a long eye (7), or an open pad Eye (7) or eye strap (7) (hereinafter abbreviated as pad To the roof tiles (21) constituting the roof of the house to attach the rafters (3) constituting the house on the back surface of the corrugated iron plate (2). A hole (22) is formed, and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are tiled ( 21) Use the L-shaped bar with nut (14) that penetrates the inside of the hole (22) formed in 21) and the tip part is n-shaped, to the rafter (3) that constitutes the house The solar cell (1) on the surface of the corrugated iron plate (2), and further, the soundproofing effect, the heat insulating effect, or the roof tile (21) on the back surface of the corrugated steel plate (2). For the purpose of improving the adhesion with the other side, use one side as a corrugated plate and the other side as a flat plate or roof tile. The solar cell (1) is formed on the surface of the corrugated iron plate (2) by interposing a polystyrene foam plate (9) having a shape similar to the shape of the tile in the middle of the sandwich shape. The corrugated iron plate (2) is firmly attached to the rafter (3) constituting the house, and the corrugated corrugated steel plate (2) is formed on the roof surface made of tiles (21). The solar cell (1) is formed on the surface of the plate (2), and the corrugated iron plate (2) forming the solar cell (1) can be formed on the surface of the plate (2). Corrugated stainless steel plate (2) and its processing method. For the purpose of attaching the solar cell (1) on the surface of the flat plate (8) made of flat plate, the nut (6) is arc-welded (13) on the surface of the flat plate (8) made of flat plate. Or a metal adhesive portion (13), and after fixing a nut (6) on the surface of a flat plate (8) made of a flat plate, the flat plate (8) made of a flat plate and a solar cell In the middle of (1), a plywood plate (20) made of a polystyrene foam plate and a plate made of aluminum is formed with an adhesive layer (10) interposed, and then laminated. A pad eye (7), a long eye (7), or an open pad by forming an arc welded part (13) or a metal adhesive part (13) on the back surface of a flat plate (8) made of a flat plate Eye (7) or eye strap (7) (hereinafter abbreviated The roof tile of the house (21) is used to attach the rafter (3) constituting the house on the back surface of the steel plate (8) made of flat plate using the pad eye) ) With a hole (22) and a pad eye (7) attached on the back side of the flat plate (8) made of a flat plate and an L rod (14) with a nut having an n-shaped tip. The rafters (3) that make up the house using an L-shaped rod (14) with a nut that penetrates the inside of the hole (22) formed in the roof tile (21) and has an n-shaped tip. ), The solar cell (1) on the surface of the flat plate (8) made of a flat plate, and the soundproofing effect, the heat insulating effect, or the roof tile (8) on the back surface of the flat plate (8) made of a flat plate. 21) For the purpose of improving the adhesion with 21), both sides are flat or one side is flat and the other piece On the surface of a flat steel plate (8) that is used as a roof tile, with a polystyrene foam plate (11) having a shape similar to that of the tile in the middle of the sandwich shape. On the surface of the roof made of tiles (21) by firmly attaching the flat plate (8) made of flat plate to the rafter (3) constituting the house In addition, a solar cell (8) made of a flat plate forming a solar cell (1) on the surface of a flat plate (8) made of a flat plate can be formed. Corrugated iron plate (2) formed on the surface of 1) and a processing method thereof. There are two types of dimensions of the corrugated tin plate (2): a small wave and a large wave. The dimensions of the small wave are 0.35 × 793 × 1800 (thickness × width × length), the unit is mm, the weight is 2.69 kg, the distance between the peaks is 31 mm, and the working width is 695 mm. The dimensions of the large wave are 0.4 × 914 × 1800 (thickness × width × length), the weight is 3.5 kg, the distance between the peaks is 63.6 mm, and the working width is 685 mm. The standard product of the two corrugated stainless steel plates (2) is the global standard for corrugated steel plates (2). In order to reinforce the strength of the corrugated steel plate (2) by attaching the solar cell (1) on the surface of the corrugated steel plate (2), the corrugated steel plate On the back surface of the plate (2), for the purpose of reinforcing the strength of the corrugated tin plate (2), the Mirapane Ace (20), or a corrugated polystyrene foam plate (9), or a flat plate shape was used. A corrugated stainless steel plate (2) characterized in that a foamed polystyrene plate is bonded and bonded with an adhesive layer (10) interposed therebetween, and a processing method thereof. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a polystyrene foam plate is placed between the corrugated tin plate (2) and the solar cell (1). After joining a plywood plate (20) (hereinafter abbreviated as Mirapane Ace 20) made of aluminum and a solar cell (1) with an adhesive layer (10) interposed therebetween. In addition, a foamed polystyrene plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is disposed between the Mirapane Ace 20 and the corrugated stainless steel plate (2) and the Mirapane Ace 20 with an adhesive layer (9). 10) is interposed and laminated on the corrugated stainless steel plate (2) and laminated, and then the arc welded portion (13) on the back surface of the corrugated steel plate (2), or Form metal adhesive part (13) (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut or pad eye) In order to attach the rafters (3) constituting the house on the back surface of the corrugated iron plate (2), a hole (22) is formed in the tile (21) constituting the roof of the house. Then, a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are formed on the roof tile (21). The rafter (3) constituting the house was made into a corrugated plate shape using an L-shaped rod (14) with a nut having an n-shaped tip, penetrating the inside of the hole (22). A solar cell (1) on the surface of the tin plate (2), and a corrugated tin plate (2) For the purpose of enhancing the soundproofing effect, the heat insulating effect, or the adhesion to the roof tile (21) on the back side, a polystyrene foam plate (9) having a corrugated shape on one side and a flat shape on the other side is sandwiched. In the middle, the solar cell (1) is formed on the surface of the corrugated steel plate (2), and the corrugated steel plate (2) constitutes the house. A corrugated shape in which a solar cell (1) is formed on the surface of a corrugated iron plate (2) on the surface of a roof made of tiles (21) firmly attached to a rafter (3) A corrugated iron plate (2) having a solar cell (1) formed on the surface thereof, and a processing method thereof. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), one side is corrugated between the corrugated tin plate (2) and the solar cell (1). After forming and laminating a foamed polystyrene plate (9) having a flat plate shape on the other side by joining the corrugated steel plate (2) with an adhesive layer (10) interposed therebetween, An arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a nut (7), a pad eye (7), or a long eye (7 ), Or an open pad eye (7) or eye strap (7) (hereinafter abbreviated as a nut or pad eye), and a house on the back surface of the corrugated steel plate (2). The roof of the house is constructed to attach the rafters (3) A hole (22) is formed in the roof tile (21), and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod with a nut whose tip is n-shaped. (14) is made to penetrate the inside of the hole (22) formed in the roof tile (21), and the L-shaped rod (14) with a nut whose tip portion is n-shaped is used to configure the house. The rafter (3) has a solar cell (1) on the surface of the corrugated iron plate (2) and a soundproofing effect or a heat insulating effect on the back surface of the corrugated steel plate (2). For the purpose of improving the adhesion to the roof tile (21), a foamed polystyrene plate (9) having a corrugated plate shape on one side and a flat plate on the other surface is interposed in the middle of the sandwich shape. The solar cell (1) is formed on the surface of the plate-shaped tin plate (2), and the corrugated plate shape is formed. The tongue plate (2) is firmly attached to the rafter (3) constituting the house, and the sun is placed on the surface of the corrugated tongue plate (2) on the surface of the roof made of tiles (21). Corrugated iron plate (1) formed on the surface of the solar cell (1), characterized in that the corrugated steel plate (2) forming the battery (1) can be formed. 2) and its processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a polystyrene foam plate is placed between the corrugated tin plate (2) and the solar cell (1). After joining a plywood plate (20) (hereinafter abbreviated as Mirapane Ace 20) made of aluminum and a solar cell (1) with an adhesive layer (10) interposed therebetween. In addition, a foamed polystyrene plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is disposed between the Mirapane Ace 20 and the corrugated stainless steel plate (2) and the Mirapane Ace 20 with an adhesive layer (9). The corrugated plate shape in which the solar cell (1) is formed on the surface of the corrugated corrugated steel plate (2), which is bonded to the corrugated corrugated steel plate (2) and laminated. Arc welded part on the back of the stainless steel plate (2) (13), or a metal adhesive portion (13) to form a nut (7), or a pad eye (7), or a long eye (7), or an open pad eye (7), or an eye strap (7) ( In the following, abbreviated as a nut or pad eye) is attached to the back surface of the corrugated stainless steel plate (2), and the solar cell (1 A corrugated tin plate (2) formed on the surface of a solar cell (1), characterized by being capable of forming a corrugated tin plate (2) formed with Processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), one side is corrugated between the corrugated tin plate (2) and the solar cell (1). After forming and laminating a foamed polystyrene plate (9) having a flat plate shape on the other side by joining the corrugated steel plate (2) with an adhesive layer (10) interposed therebetween, An arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a nut (7), a pad eye (7), or a long eye (7 ), Or an open pad eye (7) or an eye strap (7) (hereinafter abbreviated as a nut or a pad eye), and a solar cell on the surface of a corrugated iron plate (2). A corrugated iron plate (2) formed with (1) is formed. DOO solar cell characterized in that it (1) galvanized iron plate having a corrugated shape which is formed on the surface (2), and its processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), a polystyrene foam plate is placed between the corrugated tin plate (2) and the solar cell (1). After joining a plywood plate (20) (hereinafter abbreviated as Mirapane Ace 20) made of aluminum and a solar cell (1) with an adhesive layer (10) interposed therebetween. In addition, a foamed polystyrene plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface is disposed between the Mirapane Ace 20 and the corrugated stainless steel plate (2) and the Mirapane Ace 20 with an adhesive layer (9). 10) is interposed and laminated on the corrugated stainless steel plate (2) and laminated, and then the arc welded portion (13) on the back surface of the corrugated steel plate (2), or Form metal adhesive part (13) (7) or pad eye (7) or long eye (7) or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut or pad eye) Furthermore, for the purpose of improving the soundproofing effect, the heat insulating effect, or the adhesiveness with the roof tile (21) on the back surface of the corrugated iron plate (2), one side is corrugated and the other side A solar cell (1) is formed on the surface of a corrugated steel plate (2) by interposing an adhesive layer (10) in the middle of a sandwiched polystyrene foam plate (9) having a flat plate shape on one side. Corrugated iron plate (2) characterized by being capable of being processed and its processing method. For the purpose of mounting the solar cell (1) on the surface of the corrugated tin plate (2), one side is corrugated between the corrugated tin plate (2) and the solar cell (1). After forming and laminating a foamed polystyrene plate (9) having a flat plate shape on the other side by joining the corrugated steel plate (2) with an adhesive layer (10) interposed therebetween, An arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a nut (7), a pad eye (7), or a long eye (7 ), Or open pad eye (7) or eye strap (7) (hereinafter abbreviated as nut or pad eye), and then on the back of corrugated tin plate (2) Soundproofing effect, heat insulation effect, or adhesion to roof tile (21) For this purpose, a corrugated sheet made of a polystyrene foam plate (9) having a corrugated plate shape on one side and a flat plate shape on the other surface with an adhesive layer (10) interposed in the middle of the sandwich shape. A corrugated iron plate (2) characterized in that a solar cell (1) can be formed on the surface of the plate (2), and a processing method thereof. For the purpose of mounting the solar cell (1) on the surface of the corrugated stainless steel plate (2), the nut (6) is arc welded on the surface of the corrugated steel plate (2) (13). Alternatively, a metal adhesive portion (13) is formed and a nut (6) is fixed on the surface of the corrugated stainless steel plate (2), and then the corrugated steel plate (2) and solar cell After forming and laminating a plywood (20) made of a foam polystyrene plate and a plate made of aluminum foil with an adhesive layer (10) interposed between the plate made of polystyrene and (1) Furthermore, an arc welded portion (13) or a metal adhesive portion (13) is formed on the back surface of the corrugated stainless steel plate (2) to form a pad eye (7), or a long eye (7), or Open pad eye (7) or eye strap (7) (hereinafter abbreviated as pad The roof tile of the house (21) to attach the rafter (3) constituting the house on the back surface of the corrugated iron board (2) A hole (22) is formed in the pad, and a pad eye (7) attached on the back surface of the corrugated iron plate (2) and an L rod (14) with a nut having an n-shaped tip are tiled. Rafters (3) that make up the house using an L-shaped rod (14) with a nut that penetrates the inside of the hole (22) formed in (21) and has an n-shaped tip. The corrugated steel plate (2) in which the solar cell (1) is formed on the surface of the corrugated steel plate (2), and the nut-attached L rod (14) having an n-shaped tip. ) Through the inside of the hole (22) formed in the roof tile (21), the corrugated steel plate (2) In order to prevent rainwater from leaking through the holes (22) formed in the roof tile (21) when it is attached and fixed to the rafters (3), the rainwater enters the house. From the surface of the roof tile (21), a structure having a long cylindrical shape (23) of about 5 cm is combined with the roof tile (21), and the roof tile (21) is used to form an integral structure. A corrugated steel plate (2) is fixed using an L-shaped rod (14) with a nut. Furthermore, the nut-attached L rod (14) whose tip portion penetrating the inside of the cylindrical shape (23) is an n-shape is a sealant (24) inside the cylindrical shape (23), for example, Using an adhesive made of silicone resin or the like, the inside of the cylindrical shape (23) formed on the roof tile (21) united with the roof tile (21) is sealed with the sealant (24). Is used to prevent rainwater from leaking into the house from the hole (22) formed in the roof tile (21). Alternatively, the packing (24) made of silicone resin or the like is inserted into the cylindrical shape (23) instead of the sealant (24), and the L-rod with nut (14) having an n-shaped tip portion. ) Is formed in the roof tile (21) by being sealed inside the cylindrical shape (23) formed in the roof tile (21) which is integrated with the roof tile (21). The roof tile (21) that has a structure that can prevent rainwater from leaking into the house from the hole (22) and the roof tile (21) and the cylindrical shape (23) are combined to form an integral structure. A corrugated corrugated iron plate (2) and a processing method thereof. As shown in FIG. 73 and FIG. 74, it is a manufacturing company of a solar cell (1) on the surface of a folded-plate roof (2) or a slate roof (2). For example, a solar cell (1) manufactured and sold by UNI-SOLAR, whose headquarters is located in the United States, is made of stainless steel with a thickness of 0.5 mm made of stainless steel on the base. It is a three-layer type composed of amorphous silicon and silicon germanium on the surface of the plate thickness. Moreover, the solar cell (1) of UNI-SOLA is a flexible type and flexible. Further, an adhesive layer (10) having a strong adhesive effect is formed on the back surface of the stainless steel plate as the base. The surface of the solar cell (1) manufactured by UNI-SOLAR, whose base is made of stainless steel plate, is a folded plate roof (2) or a slate roof (2) (hereinafter referred to as a folded plate roof). On the top, for example, a solar cell (1) manufactured by UNI-SOLAR is directly pasted in parallel to the ridge on the surface of the folded roof (2) parallel to the ridge which is the peak of the house. Or, when the solar cell (1) made by UNI-SOLAR is directly pasted at a right angle in the vertical direction on the surface of the folded roof (2) at a right angle in the vertical direction with respect to the ridge which is the peak of the house, On the surface of the folded plate roof (2) using the adhesive layer (10) formed on the back surface of the stainless steel plate constituting the base of the solar cell (1) made by UNI-SOLA A folded-plate roof, a slate roof, and a method for attaching the same, characterized in that a solar cell (1) manufactured by UNI-SOLA can be bonded firmly and bonded. 73 and 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter abbreviated as the folded plate roof), a base made by UNI-SOLA. Is made of a stainless steel plate base with a thickness of 0.5 mm and is about 1 m wide and can be cut freely in the length direction. Adhesive layer formed on the back surface of the base of the solar cell (1) manufactured by UNI-SOLAR on the surface of the folded plate roof (2) or the slate roof (2) A solar cell (1) manufactured by UNI-SOLAR is formed on the back surface of the base of the solar cell (1) on the surface of the folded roof (2) or the slate roof (2) with (10) interposed. Folded plate roof (2) or slate roof (with a bonding layer (10) When directly pasting on the surface of 2), the solar cell (1) manufactured by UNI-SOLAR is a long solar cell (1). As a result, the long solar cell (1) is directly pasted. Since the surface tension becomes strong, the solar cell (1) manufactured by UNI-SOLAR is directly attached on the surface of the folded roof (2) or the slate roof (2). A folded-plate roof, a slate roof, and a method for attaching the same, characterized by being able to withstand a load that is heavy enough for a human to walk freely. 73 and 74, on the surface of the folded plate roof (2) or the slate roof (2) (hereinafter abbreviated as the folded plate roof), a base made by UNI-SOLA. The solar cell (1) made by UNI-SOLAR, which is made of a stainless steel plate base having a thickness of 0.5 mm made of stainless steel, is a folded plate roof (2) or a slate roof (2 ), A folded roof (2), or a slate roof (2) with an adhesive layer (10) formed on the back surface of the base of the solar cell (1) made by UNI-SOLA. If a solar cell (1) made by UNI-SOLA is directly pasted on the surface of the battery, there is no need for any structure necessary for installing the solar cell (1), so it is extremely inexpensive. The solar cell (1) is folded roof (which is the roof material that constitutes the house) 2) or a folded plate roof, a slate roof, characterized in that a solar cell (1) manufactured by UNI-SOLAR can be installed on the surface of the slate roof (2) at a very low cost, And its mounting method. Asbestos slate 26 has been extremely weak for the purpose of repairing the asbestos slate 26 after several decades. For example, using asbestos slate 26, walking on asbestos slate 26, which is on the surface of a factory or warehouse roof that has been decades old, is decades old. Since the strength of the asbestos slate 26 is weak, it is very dangerous to walk on the old asbestos slate 26 first. Secondly, when asbestos slate 26 made of the main raw material of asbestos is disassembled, asbestos with carcinogenic properties is scattered, and asbestos slate 26 that has become old easily can be easily disassembled. The current situation is not possible. However, the asbestos slate 26 is characterized by a construction method aimed at performing repair work safely by reinforcing the strength of the roof of a factory or warehouse that is made of asbestos slate 26 that leaks old and leaks. Repair method. Polystyrene is the main raw material made of polystyrene and has a low expansion ratio and a very low expansion polystyrene, for example, a expansion ratio of 10 times or less, or a expansion ratio of 20 times or less, or a expansion ratio of 25 times or less, or a expansion ratio of 30 Or less, or the expansion ratio is 35 times or less, or the expansion ratio is 50 times or less (hereinafter abbreviated, the expansion ratio is 25 times or less). The polystyrene foam 27, the other side of which has a flat plate shape, the polystyrene foam 28 of which both sides have a flat plate shape, or the one side of a polystyrene foam 26 having the shape of an asbestos slate 26, and the other side of the slate roof 25. Using foamed polystyrene 29 in the shape of a roof of a factory or warehouse that has been leaking for decades. And that, old method of repairing work method asbestos slate, wherein the strength of the asbestos slate 26 to reinforce safely perform repair work. FIG. 76 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since the old asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. On the surface of the asbestos slate 26, the foamed polystyrene plate is made of a foamed polystyrene 27 having one side shaped as an asbestos slate 26 and the other side shaped as a flat plate. In addition, the load that can be withstood on the surface of the asbestos slate 26 is laid down on the surface of the asbestos slate 26 and stacked, for example, the limit that a human can withstand on the surface of the asbestos slate 26. A method for repairing asbestos slate, characterized in that the asbestos slate 26 can be structured to withstand the load of human beings. FIG. 77 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. Asbestos slate is formed by laying and stacking foamed polystyrene 28 having a flat plate shape on both sides of the asbestos slate 26 on the surface of the asbestos slate 26. For example, a structure in which the load of the asbestos slate 26 withstands the load of the asbestos slate 26 is more than the limit that a human can withstand even when walking freely on the surface of the asbestos slate 26. Asbestos slate repair method characterized by being able to. FIG. 78 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed and the strength of the asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having a shape of the asbestos slate 26 on one side and a polystyrene 29 having a slate roof on the other side. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. A method for repairing asbestos slate, characterized in that the asbestos slate 26 has a structure that can withstand the load of human beings, exceeding the limit. FIG. 79 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since the old asbestos slate 26 becomes fragile and becomes dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having one side of the shape of the asbestos slate 26 and the other side having the slate roof shape. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 exceeding the limit is able to withstand human loads, and the slate roof 25 is stacked and laminated on the surface of the polystyrene foam 29, and the rafter 3, asbestos slate 26, polystyrene foam are laminated. 29, and the four types of panels of the slate roof 25 using the bolts 5 and nuts 6 and the roofing material constituting the house. Asbestos slate repair, characterized in that the slate roof 25 in which the slate roof 25 is attached to the rafter 3 by laminating from above and below can be fixed to the asbestos slate 26 with the foamed polystyrene 29 interposed therebetween. Method. FIG. 80 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26, which has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roof material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The surface of the asbestos slate 26 is made of a polystyrene foam 29 having a shape of the asbestos slate 26 on one side and a polystyrene 29 having a slate roof on the other side. On the surface of the asbestos slate 26, the layers are stacked and stacked, so that a load that can be withstood on the surface of the asbestos slate 26 can be endured even if a human walks freely on the surface of the asbestos slate 26. A structure in which the load of asbestos slate 26 exceeding the limit is able to withstand human loads, and the slate roof 25 is stacked and laminated on the surface of the polystyrene foam 29, and the rafter 3, asbestos slate 26, polystyrene foam are laminated. 29, and four types of panels of the slate roof 25, the pad eye 7, and the L-rod 14 with a nut whose tip is an n-shape. Thus, the slate roof 25 in which the slate roof 25 is stacked and attached from the lower surface which is the back surface of the rafter 3 which is the roof material constituting the house, and as a result, the polystyrene foam 29 is replaced with the asbestos slate 26. A method for repairing asbestos slate, characterized in that the asbestos slate 26 can be fixed by being interposed between the slate roof 25 and the slate roof 25. FIG. 81 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 after the decades have passed since it became old and becomes brittle and dangerous. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene board made of the above-mentioned foamed polystyrene board has a flat-faced foamed polystyrene 28 that is laid on the surface of the asbestos slate 26 and stacked to form a load that can be withstood on the surface of the asbestos slate 26. For example, on the surface of the polystyrene foam 28 after the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human beings, which is more than the limit that a human can withstand walking freely. In addition, the slate roof 25 is stacked and laminated, and four types of panels, a rafter 3, an asbestos slate 26, a polystyrene foam 28, and a slate roof 25, are formed with a pad eye 7 and a nut L with a n-shaped tip. Using the bar 14, the slate roof 25 is piled up and down from the lower surface which is the back surface of the rafter 3 which is the roof material constituting the house. As a result, the slate roof 25 is fixed to the asbestos slate 26 by interposing the polystyrene foam 28 between the asbestos slate 26 and the slate roof 25, and the nut 6 and the pad eye on the surface of the slate roof 25. 7 and a method for repairing asbestos slate, wherein the solar cell 1 can be attached and fixed onto the surface of the slate roof 25 using bolts 5. FIG. 82 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes fragile after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. On the surface of the asbestos slate 26, the foamed polystyrene plate is made of a polystyrene foam 27 having one side of the shape of the asbestos slate 26, and the other side of the polystyrene foam 27 having a flat plate shape. In addition, the load that can be withstood on the surface of the asbestos slate 26 is laid down on the surface of the asbestos slate 26 and stacked, for example, the limit that a human can withstand on the surface of the asbestos slate 26. After the above-described structure in which the load of the asbestos slate 26 can withstand the load of human weight is formed, the slate roof 25 is stacked on the surface of the polystyrene foam 27, and the rafter 3, the asbestos slate 26, Using four types of panels, polystyrene foam 27 and slate roof 25, pad eye 7, and L-rod 14 with nut whose tip is n-shaped. Then, the slate roof 25 in which the slate roof 25 is stacked and attached to the rafter 3 that is the roof material constituting the house from the top and bottom, and as a result, the polystyrene foam 27 is connected to the asbestos slate 26 and the slate roof 25. The solar cell 1 is mounted on the surface of the slate roof 25 using the nut 6, the pad eye 7, and the bolt 5 on the surface of the slate roof 25 after being interposed and fixed to the asbestos slate 26. Asbestos slate repair method, characterized by being able to be fixed. FIG. 83 shows the above-described FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes obsolete after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate is made of a foamed polystyrene plate 29. The foamed polystyrene plate 29 has the shape of an asbestos slate 26 on one side and the slate roof 25 on the other side. Are placed on the surface of the asbestos slate 26 and stacked on top of the surface of the asbestos slate 26 so that a load that can be tolerated on the surface of the asbestos slate 26 is applied by, for example, a person on the surface of the asbestos slate 26. The asbestos slate 26 has a structure that can withstand the weight of human beings, and the slate roof 25 is laminated on the surface of the foamed polystyrene 29 after the load of the asbestos slate 26 exceeds the limit that can withstand walking freely. , Rafter 3, asbestos slate 26, styrofoam 29, and slate roof 25, four types of panels, pad eye 7 and tip portion A slate roof that is attached by stacking slate roofs 25 from above and below from the bottom surface of the rafter 3 that is the roofing material that constitutes the house, using the L-shaped nut-attached L bar 14 25. As a result, after the foamed polystyrene 29 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26, the nut 6, the pad eye 7, and A method for repairing asbestos slate, wherein the solar cell 1 can be fixed on the surface of the slate roof 25 using bolts 5. FIG. 84 shows the above-mentioned FIG. 75 for the purpose of repairing the asbestos slate 26 by reinforcing the strength of the asbestos slate 26 that has become fragile and becomes dangerous after several decades. The asbestos slate 26, which is a conventional asbestos slate 26, asbestos-forming plate (hereinafter abbreviated as asbestos slate) 26 formed by cementing asbestos with cement, is a rafter that constitutes the roofing material of the house. 3 on the surface of the asbestos slate 26 after the asbestos slate 26 is attached to the rafters 3 using the bolts 5 and nuts 6, for example, with a thickness of about 10 cm and a small iron plate wave as a roofing material When used, since the working width is 695 mm, the width is 695 mm, and when using a large iron plate as a roofing material, the working width is 685 mm, so the width is 685 m. The foamed polystyrene plate made of the above-mentioned foamed polystyrene plate is a foamed polystyrene 30 with one side having a flat plate shape and the other side with a slate roof 25, and the foamed polystyrene 30 having the shape of the slate roof 25 is replaced with asbestos. The surface of the asbestos slate 26 is laid and stacked on the surface of the asbestos slate 26, and a load that can be withstood on the surface of the asbestos slate 26, for example, a person freely walks on the surface of the asbestos slate 26. Even if the asbestos slate 26 has a structure in which the load of the asbestos slate 26 can withstand the load of human weight, the slate roof 25 is stacked on the surface of the foamed polystyrene 30, and the rafter 3 is laminated. Asbestos slate 26, Styrofoam 30 and slate roof 25, four types of panels, pad eye 7 and the tip portion was n-shaped The slate roof 25 attached by stacking the slate roof 25 from above and below from the lower surface, which is the back surface of the rafter 3 that is the roof material constituting the house, using the L bar 14 with a tut, As a result, the nut 6, the pad eye 7, and the bolt 5 are placed on the surface of the slate roof 25 after the polystyrene foam 30 is interposed between the asbestos slate 26 and the slate roof 25 and fixed to the asbestos slate 26. A method for repairing asbestos slate, characterized in that the solar cell 1 can be used and fixed on the surface of the slate roof 25. FIG. 121 shows a processing means for joining the two large iron plate waves 25 of the present invention by pressure bonding. First, a nut 6 or other mounting bracket 6 (hereinafter abbreviated as nut 6) is placed on the back surface of the iron plate large wave 33 on the back surface of the iron plate large wave 33 located at the upper portion. An iron plate large wave 33 to which the nut 6 is attached by forming a welded portion 13 is formed. Secondly, the bolt 5 passing through the inside of the hole portion 36 formed in the large iron plate wave 34 located in the lower portion, the washer 35 larger than the inner diameter of the hole portion 36, and the nut 6 is used to overlap the iron plate large wave 33 located in the upper part and the iron plate large wave 34 located in the lower part in an overlapping manner, and the two nuts located vertically 6 is a method of attaching two iron plate large waves 25 in an overlapping manner and attaching them to the rafter 3 by bonding the two iron plate large waves 25 from above and below. The iron plate large wave 34 is extremely thin and weak with a thickness of 0.3 mm to 0.8 mm. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. A belt-shaped iron plate 37 is attached to both sides of the large wave 34, and the steel plate large wave 34 and the belt-shaped iron plate 37 are firmly joined to each other. The iron plate large wave 34 for the purpose of attaching the solar cell 1 that has been bonded and crimped, and a processing method thereof. For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). For example, even for an amateur, a plasterer, or a carpenter, the solar cell 1 and the solar cell 1 are integrated as a structure that can attach the solar cell 1 very easily. Solar power united with Solar cell 1, wherein the solar cell 1 intended to individually manufacture and sell 1, and the mounting method thereof. For the purpose of forming the solar cell 1 having a monolithic structure by combining the iron plate large wave 34 and the solar cell 1 which are roof materials, the iron plate large wave 34 described above is usually 0.3 mm in thickness. To 0.8mm, very thin and weak. For this reason, if a pressure with a change in which pressurization and depressurization are repeatedly applied to the roof receiving wind pressure is received at one point, the force may be concentrated and the one part may be easily damaged. In the present invention, the large steel plate wave 34 is protected by spreading the wind pressure pressure in a wide area, so that the large iron plate wave 34 is not deformed, and even if it receives a strong wind pressure pressure. For example, a strip-shaped iron plate having a thickness of about 5 mm and a width of about 3 cm (hereinafter abbreviated as a strip-shaped iron plate) 37) with a cylindrical washer 39 as a stopper, and asphalt packing 40 in the middle, using bolts 5 and nuts 6, and crimping from both sides of the steel plate large wave 34. And receive at one point For the purpose of preventing breakage of the iron plate large wave 34 even if it receives a strong wind pressure pressure without causing the deformation of the iron plate large wave 34 by dispersing the wind pressure as widely as possible. After the strip-shaped iron plate 37 is attached on both sides of the large wave 34 and the large plate 34 and the strip-shaped iron plate 37 are firmly joined and attached, the solar cell 1 is mounted on the surface of the large plate 34 with the bolt 5, and The solar cell 1 attached by using the nut 6 and united with the iron plate large wave 34 as the roof material and the solar cell 1 (hereinafter, abbreviated as the solar cell 1 combined with the roof material). The solar cell 1 for the purpose of individually manufacturing and selling the solar cell 1 combined with the roofing material, which has a structure in which the solar cell 1 can be attached very easily. C steel 3 or wood constituting The solar cell 1 which is made by combining the roof material with the roof 3 or the rafter 3 (hereinafter referred to as the rafter 3) is integrated with the roof material from the back surface of the roof material constituting the house. When the solar cell 1 is attached to the rafter 3 constituting the house from the back side, and the iron plate large wave 34 serving as the roof constituting the house is attached to the roof, the solar cell 1 is simultaneously formed on the roof constituting the house. A solar cell 1 and a method of attaching the solar cell 1, wherein the solar cell 1 is attached to a roof which is a material. First, if the position and size of the gap between the wood purlins 3 are determined, or the positions of the holes to be formed in the solar cell 1 are determined, the iron plate large wave 25, the base metal receiving member 42, and the steel frame 43 are formed. The position of the hole to be determined is determined. This means that, for example, 66 holes are drilled on the surface of the iron plate large wave 25 using a drill on the rooftop of the roof where the working environment is severe, and holes are formed on the surface of the iron plate large wave 25. When the drilling work to be performed is performed inside the factory, holes to be formed on the surface of the iron plate large wave 25 are attached with NC, for example, a plurality of 20 to 30 iron plate large waves 25 together. A large iron plate wave 25 and a machining method thereof, characterized in that a machine tool can be used to precisely and accurately produce a large number of holes at an extremely low cost without an error of ± 1 mm. Machine tools with NC for several tens of roof materials 25 made of iron plate large waves 25, folded plate roofs 25, or other shapes of metal (hereinafter, abbreviated as iron plate large waves). If the iron plate large wave 25 which carried out the hole processing using one is manufactured and sold one by one, the roof is easily constituted by using the nail 4 or the wood screw 4 as the roof material. An iron plate large wave 25, which is attached to the existing wood purlin 3 and a processing method thereof. Iron plate large wave 25 that has been subjected to hole processing, base metal receiving material 42 that has been subjected to hole processing, steel frame 43 that has been subjected to hole processing, solar cell 1 that has been subjected to hole processing, and solar cell panel 1 that is an accessory shown in FIG. When the solar cell panel 1 is attached to the iron plate large wave 25, and a panel set is packed together and manufactured and sold as a kit or set, the solar cell 1 is used as a roofing material 3 The solar battery panel 1 and the processing method thereof are characterized in that the work attached to the iron plate large wave 25 can be easily attached by an amateur, a carpenter or a plasterer. For the purpose of mounting the solar cell 1 on the surface of the iron plate large wave 25, the roof material 25 made of iron plate large wave 25, folded plate roof 25, or other shaped metal (hereinafter abbreviated as iron plate large wave 25). On the surface of the rafter 3 constituting the roof material, or the C steel 3, or the wooden purlin 3 or the skeleton 3 constituting the roof of the house (hereinafter abbreviated as rafter). For the purpose of attaching and fixing a single iron plate large wave 25 to the rafter 3 using the nail 4, the wood screw 4, or the screw hex 4 (hereinafter abbreviated as a nail). The total number of holes to be formed on the surface of one large iron plate wave 25 needs to form approximately 66 holes. The total position of forming approximately 66 holes constitutes the roof of the house with the steel plate large wave 25, the base metal receiver 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25 for short). Since the purpose is to attach and fix to the central part of the rafter 3, the total number of holes formed in the iron plate large wave 25, all the positions of about 66 holes, are shown in FIGS. 125 and 130, for example. As shown in the figure, the iron plate at a position corresponding to a portion directly above the central portion of the rafter 3 which is the purlin 3 constituting the roof of the house, and the rafters 3 are attached at intervals of 428.5 mm. In the processing factory that has already produced the iron plate large wave 25 in the large wave 25, a hole is formed on the surface of the iron plate large wave 25 using the NC machine tool on the surface of the top of the mountain where the uneven portion of the iron plate large wave 25 is present. The surface of the iron plate large wave 25 Since holes can be formed at positions where there is no error of ± 1 mm, for example, as shown in FIGS. 125 and 130, the interval between the rafters 3 is first set to 428.5 mm, and the positions of the rafters 3 are If accurately determined, the iron plate large wave 25 in which holes are formed on the surface of the iron plate large wave 25 at intervals of 428.6 mm in the iron plate large wave 25 shown in FIGS. 126 and 131 is a rafter. If the iron plate large wave 25 is attached to the rafter 3 using the nail 4 and installed from right above the iron plate 3, the iron plate large wave 25 can be easily attached to the rafter 3 without dividing the size of the iron plate large wave 25. . To install the solar panel 1 on the surface of the iron plate large wave 25, the installation of the solar cell panel 1 is completed on the surface of the iron plate large wave 25 just by assembling the kit as a set of the solar cell panel 1 on the surface. In order to install the solar cell panel 1 on the surface of the iron plate large wave 25, there is no need to divide the dimensions on the roof of the work site and to match the actual product on the site. It is easy to attach and fix to the rafter 3, and the kit that is a set of solar panel 1 can be mass-produced at the processing factory, so the cost is low, the delivery time is fast, and the installation work is simple. Even an amateur, carpenter, or plasterer can perform installation work, so the solar cell panel 1 is attached to the iron plate large wave 25 and the rafter 3, and the solar cell panel 1 is attached to the iron plate large wave 25. Solar panel 1 construction period necessary to complete a roof mounted on the surface, characterized in that it is overwhelmingly shorter, and its processing method. For attaching and fixing the solar cell 1 on the surface of the iron plate large wave 25 using the iron plate large wave 25, the base metal receiver 42, or the steel frame 43 (hereinafter referred to as the iron plate large wave 25). Panel 1 of solar cell 1, which is a metal panel shown in FIG. 135, including one solar cell panel, one steel plate large wave 25, four base metal pieces 42, two steel frames 43. Large iron plate using a box (hereinafter abbreviated as a set, a kit, or a solar cell set, or a solar cell kit) in which a set of metal fittings are packed together in one box The explanation about attaching the solar cell 1 on the surface of 25 was given. However, the processing means for attaching the solar cell 1 to the surface of the iron plate large wave 25 is used to attach the roof to the rafter 3, which is the roof constituting the roof of the house, using only the iron plate large wave 25 alone. As a processing means for attaching the iron plate large wave 25 as a roof material for the purpose of constructing only a roof, for example, as shown in FIGS. 125 and 130, when a roof of a house is first constructed, a rafter is constructed. If the position of the rafter 3 is determined at an interval of 428.5 mm, the iron plate large wave 25 and the hole interval of the iron plate large wave 25 shown in FIGS. 126 and 131 are 428.5 mm. It is possible to attach the iron plate large wave 25 to the rafter 3 by using the nail 4 by installing the iron plate large wave 25 having a hole formed on the surface thereof from right above the rafter 3. In this way, when the roof is configured using the iron plate large wave 25 in which a hole is formed in the iron plate large wave 25 using the NC machine tool, the rafter 3 constituting the roof of the house is configured as described above. As in the case of attaching the solar cell 1 to the iron plate large wave 25 as described, if the position of the rafter 3 is determined, the error of the hole formed in the iron plate large wave 25 is no error of ± 1 mm, so it is a work site. Since it is not necessary to divide the size of the iron plate large wave 25 on the surface of the roof, it is easy to attach and fix the iron plate large wave 25 to the rafter 3. Since it is a simple operation, the cost is low, and the construction period necessary for completing the roof by attaching the iron plate large wave 25 to the rafter 3 is overwhelmingly shortened, and its processing Method. The pre-process processing before forming the iron plate large wave (25) is completed, for example, Nisshin Steel Co., Ltd. manufactures and sells, and the trade name is a galvastar (ZG) steel plate, or a ZAM steel plate, or a flat steel plate A flat steel plate coated with paint on the surface of the steel plate, a flat steel plate coated with urethane paint, a flat steel plate that has been rolled, or a steel coil wound around crawling, or a strip steel flat plate, or flat plate, or A decorative plate made of plywood, a plywood plate, a flat plate made of plastic, or a flat plate made of other materials, an exterior flat plate material, or an internal flat plate material (hereinafter abbreviated as a plastic flat plate or a decorative plate) Thin film quantum dot PV solar cell (5), for example, which was successfully researched and developed by Solterra in the United States. 1) Roll-to-roll printing of a quantum dot solar cell (51) on the surface of a flat steel plate (44) using a manufacturing technique (hereinafter referred to as quantum dot solar cell (51) for short) Flat plate steel plate (44) having a quantum dot type solar cell (51) directly formed on the surface of the flat plate steel plate (44) by using a technology, ink jet printing technology, or screen printing technology, or A quantum dot solar cell characterized in that a flat plate steel plate (44) on which a quantum dot solar cell (51) is formed can be formed on the surface of a strip steel flat plate steel plate (44) wound in a round; And its processing method. A quantum dot solar cell using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). Polycarbonate, which is made of a resin having good sunlight transmittance for the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which (51) is formed. A film made of a resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is made of a flat steel plate (44) on which a quantum dot solar cell (51) is formed. As a protective film (45) on the surface, a quantum dot solar cell (51) is formed on the surface of a flat steel plate (44) in which a quantum dot solar cell (51) is formed on the surface of the flat steel plate (44). The flat steel plate (44) bonded on the surface of the flat steel plate (44) is used as the protective film (45) for protecting the surface of the steel plate, or the quantum dot solar cell (51) of the flat steel plate (44) is used. The protective film (45) is not formed on the surface of the flat steel plate (44), which is formed on the surface of the quantum dot solar cell (51), which is in a state of being formed on the surface, The outer periphery of a house, which is a building material that forms a flat steel plate (44) forming a quantum dot solar cell (51) and constitutes a house or a building (hereinafter abbreviated as a house). It is used as an outer wall plate of the wall material constituting the, or as an exterior material. For example, a quantum dot type solar cell (51) is formed on the surface of a flat steel plate (44) on the surface of a flat steel plate (44) having a width of 90 cm and a vertical width of 180 cm. Using the solar cell (51), electric power is generated using the energy of solar rays. Moreover, the quantum dot type solar cell (51) which has formed the quantum dot type solar cell (51) on the surface of a flat steel plate (44) as an interior material for the room | chamber interior currently used in the house interior. ) Using the energy of light generated from incandescent lamps or fluorescent lamps that are used inside houses or buildings, and using quantum dot solar cells (51 ) Is formed on the surface of the flat steel plate (44), the quantum dot solar cell (51) is used to generate power using the quantum dot solar cell (51). The quantum dot type solar cell characterized by being able to form the flat steel plate (44) which forms the battery (51), and its processing method. A quantum dot solar cell using a printing technique (hereinafter abbreviated as a screen printing technique) such as a roll-to-roll printing technique, an inkjet printing technique, or a screen printing technique on the surface of the flat steel plate (44). Polycarbonate, which is made of a resin having good sunlight transmittance for the purpose of protecting the surface of the quantum dot solar cell (51) on the surface of the flat steel plate (44) on which (51) is formed. A film made of a resin or the like, or a film made of another resin (hereinafter abbreviated as a protective film (45)) is made of a flat steel plate (44) on which a quantum dot solar cell (51) is formed. As a protective film (45) on the surface, a quantum dot solar cell (51) is formed on the surface of a flat steel plate (44) in which a quantum dot solar cell (51) is formed on the surface of the flat steel plate (44). As the protective film (45) for protecting the surface of the steel plate, the flat steel plate (44) bonded on the surface of the flat steel plate (44) is used, or the quantum dot solar cell (51) is used as the flat steel plate (44). The protective film (45) is not formed on the surface of the flat steel plate (44) which is formed on the surface of the quantum dot solar cell (51) which is in a state of being formed on the surface of The plate steel plate (44) forming the quantum dot solar cell (51) is directly used to form the iron plate large wave (46) for the purpose of forming the iron plate large wave (46). Then, the quantum dot solar cell (51) is formed on the surface of the flat steel plate (44), the flat steel plate (44) is molded, and directly on the surface of the iron plate large wave (25), Forming a large iron plate wave (46) forming a quantum dot solar cell (51) Quantum dot solar cell, characterized in that the can be, and its processing method. The plate steel plate (44) forming the quantum dot solar cell (51) is directly formed on the surface of the plate steel plate (44) by the shape of the iron plate large wave (25) or the shape of the folded plate roof (25) ( Hereinafter, the quantum dot solar cell (51) is directly formed on the surface of the iron plate large wave (25) by molding using a molding machine for forming the iron plate large wave (25). The rafter (3), the purlin (3), or the skeleton (3 for short) constituting the roof of the house (hereinafter abbreviated as rafter (3) And a hole (47) for attaching the steel plate large wave (25) to the rafter (3) using a stainless steel screw (4), for example, a hole having a hole diameter of 9 mm ( 47), an iron plate large wave (46) formed on the surface of the iron plate large wave (46), for example, an iron plate large wave (46) Laminate 0 to 20 sheets together and stack them, and use a machine tool with NC to drill holes (47) from 40 to 60 places with an error of within ± 1 mm. 46. A quantum dot solar cell and a processing method thereof, characterized in that an iron plate large wave (46) having a hole (47) formed at the same time can be formed on the surface of 46). Using a printing technology such as roll-to-roll printing technology, ink jet printing technology, or screen printing technology on the surface of the steel plate big wave (25) or flat steel plate (44), The quantum dot solar cell (51) can be formed uniformly along the curved surface on the surface of the plate roof (25). Moreover, the quantum dot type solar cell (51) which can form a quantum dot type solar cell (51) on the surface of a flat steel plate (44), and its processing method.

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