JP2698200B2 - How to install rooftop solar cells - Google Patents

Description

The present invention relates to a method of installing a roof-mounted solar cell, and more particularly to a method of installing a solar cell that can be installed on an existing roof of a general house.

(B) Conventional technology Solar cells, which directly convert light energy into electric energy, use inexhaustible sunlight as a main energy source, and thus have been spotlighted in the face of the depletion of energy resources. When this solar cell is used as a household power source, if the conversion efficiency of the solar cell is 10%, a light receiving area of 30 m ² is sufficient if the power consumption is normal household use. The light-receiving area of this solar cell is an area that is sufficiently possible on the roof of an ordinary house or the like.

Therefore, a tile-shaped solar cell device has been proposed as disclosed in Japanese Patent Application Laid-Open No. 60-31259. This tile-shaped solar cell device only has to be laid in place of existing roof tiles, and has an advantage that laying equipment such as a gantry is not required.

(C) Problems to be Solved by the Invention However, when the above-mentioned tiled solar cell device is to be laid on an existing roof, the roof tile already laid is removed, and then the tiled solar cell device is removed. The laying work of the battery device must be performed. For this reason, the laying work took a lot of time and was not suitable for the existing roof.

Furthermore, since a glass substrate bent in a tile shape is used as a substrate of a solar cell, its manufacture is difficult, cost is increased, and the photovoltaic power fluctuates depending on the irradiation angle due to the curved surface shape. .

An object of the present invention is to provide a method of installing a roof-mounted solar cell that can be easily installed on an existing roof.

(D) Means for Solving the Problems The first method of installing a roof-mounted solar cell device of the present invention is to install a solar cell mounting wire vertically and horizontally on a roof, and to apply the solar cell to the solar cell mounting wire. A solar cell is installed on a roof by connecting a plurality of locations.

According to the second installation method of the roof-mounted solar cell device of the present invention, hooks are provided at a plurality of required positions on the periphery of the solar cell, a metal net is stretched on the roof along the roof upper surface, and A solar cell is mounted on a roof by mounting a solar cell on a net, attaching a solar cell hook to the net and attaching the solar cell to the net.

(E) Function In the first method of installing a roof-mounted solar cell of the present invention,
First, wires for mounting solar cells are stretched vertically and horizontally on the roof.

Then, a plurality of required solar cells are connected to the solar cell mounting wires.

In the second method for installing a roof-mounted solar cell of the present invention,
Hooks are provided in advance at a plurality of required locations on the periphery of the solar cell.

When installing a solar cell on a roof, first, a metal net is provided on the roof along the roof upper surface.

Next, the solar cell is placed on the net, and the solar cell is attached to the net by hooking the hook of the solar cell on the net.

(F) Example Hereinafter, an example of the present invention will be described with reference to the drawings.

1 to 4 show a first embodiment of the present invention.

 FIG. 4 shows a solar cell.

In FIG. 4, (1) is a substrate made of a transparent and insulating material such as tempered glass, and (2) is a photoelectric conversion region directly attached to the surface of the substrate (1) at regular intervals. . The photoelectric conversion region (2) includes, from the substrate (1) side, for example, a transparent conductive film (3) such as tin oxide or indium tin oxide, and a semiconductor film (4) made of amorphous silicon having a semiconductor junction therein. The semiconductor film (4) and the back electrode film (5) made of aluminum or the like that are in ohmic contact are sequentially laminated to form a micron-order film.

Each semiconductor film (4) has a P-type layer with a thickness of about 50 to 250 °, an I-type (intrinsic) layer with a thickness of about 4000 to 7000 °, and 30 to form a PIN junction parallel to the film surface, for example.
An N-type layer of about 0 to 600 ° is sequentially laminated and deposited, so that when light enters through the substrate (1) and the transparent conductive film (3), electrons and holes in the free state are mainly in the I-type layer. Are generated, and the electrons and holes are attracted by a PIN junction electric field formed by each of the above layers, so that each of the transparent conductive films (3) and the back electrode film (5) are generated.
And electric power that is electrically added by superimposition of the transparent conductive film (3) of the adjacent photoelectric conversion region (2) and the back electrode film (5) is extracted.

(6) is an outer frame made of aluminum or the like, and (7) is a resin layer covering the photoelectric conversion region (2).

FIGS. 1 to 3 show a state where the solar cell is installed on the roof of an existing house. In the following description, "before" refers to the solar cell (1) of the gable roof (11) shown in FIG.
The eaves side of the surface on which 0) is installed is referred to as the eaves side, and the rear is referred to as the ridge side.

1 to 3, the roof facing south (1
1) On top, solar cell mounting wires (12) and (13) are stretched vertically and horizontally. In this example, three solar cell mounting wires (12) extending in the left-right direction with an interval in the vertical direction
And five solar cell mounting wires (13) extending in the front-rear direction with an interval in the left-right direction.

Left and right solar cell mounting wires (1
2) is located on the front and rear center of the roof (11) facing south. And both ends of this wire (12)
As shown in the figure, it is attached via a turnbuckle (14) to a clamp member (15) attached to the purlin (19). The lower end of the clamp member (15) is the purlin (19)
It is inserted into a fixing bracket (16) fixed by bolts (17). In addition, a clamp member (1
A guide member (18) for holding the 5) in a vertical position is fixed, and a clamp member (15) is attached to the stabilizing member (18).
Is guided.

The solar cell mounting wire (1
2) is located on the roof (11). Both ends of the wire (12) are attached to a clamp member (15) attached to a purlin of the roof (11) via a turnbuckle (14). The attachment of the clamp member (15) to the purlin is the same as the attachment of the clamp member (15) to the purlin, and a description thereof will be omitted.

The lowermost horizontal solar cell mounting wire (1
2) is arranged on the eaves of the roof (11). Both ends of the wire (12) are attached to clamp members (15) attached to rafters located on the left and right sides of the roof (11) via turnbuckles (14). The attachment of the clamp member (15) to the rafter is the same as the attachment of the clamp member (15) to the purlin, and a description thereof will be omitted.

The front ends of the left and right outer two wires (13) of the five front-rear direction solar cell mounting wires (13) are clamp members (15) attached to rafters located on the left and right sides of the roof (11). It is attached via a turnbuckle (14). The rear ends of these two wires (13) are on the roof (11)
It is attached via a turnbuckle (14) to a clamp member (15) attached to the purlin.

The front ends of the three inner wires (13) of the five front-to-back solar cell mounting wires (13) are provided with turnbuckles (14) on clamp members (15) attached to rafters on the roof (11). Attached through. The rear ends of these three wires (13) are attached via a turnbuckle (14) to the uppermost left-right direction solar cell attachment wire (12).

The intersection of the left-right direction wire (12) and the front-back direction wire (13) is bound by a binding member (20) such as a wire.

Solar cell mounting wire (12) on roof (11)
A solar cell (10) is arranged in the area surrounded by (13). Although FIG. 1 shows only one solar cell (10), in this example, eight solar cells (10) can be installed. Solar cell mounting wire (12)
Solar cells (10) arranged in the area surrounded by (13)
Is connected to the solar cell mounting wires (12) and (13) located around it through turnbuckles (21) (see FIG. 3) through a plurality of required portions of the peripheral portion (outer frame (6)). As a result, it is attached to the wires (12) and (13).

Hooks (not shown) are provided at a plurality of required positions on the periphery of the solar cell (10), and the hooks are hooked on the solar cell mounting wires (12) (13) located around the solar cell (10). Alternatively, the solar cell (10) may be attached to the wires (12) and (13).

Lead wires (22) extending from the solar cell (10)
Is wound around the solar cell mounting wires (12) and (13), guided to the eaves, and drawn indoors.

Next, a method for installing a solar cell will be described with reference to FIG.

First, the solar cell mounting wire (12) on the roof (11)
Stretch (13) vertically and horizontally.

Next, the solar cell mounting wire (12) on the roof (11)
Place the solar cell in the area surrounded by (13).

Then, a plurality of required positions on the periphery of the solar cell (10) are turnbuckled (21) to the solar cell mounting wires (12) (13).
Connect using. As a result, the solar cell can be roofed (11)
Installed on top.

Thus, in this solar cell installation method, the roof (11)
Solar cell mounting wires stretched vertically and horizontally (12) (13)
Since the solar cell (10) is mounted on the vehicle, a frame for mounting the solar cell (10) is not required, so that the cost can be reduced and the installation operation can be simplified. Also, according to the size and quantity of the solar cell (10), the solar cell mounting wires (12) and (13) can be stretched.
The number of solar cells (10) can be easily installed on the roof (11).

FIG. 5 and FIG. 6 show a modification of the first embodiment. The lower surface of the rear edge of the solar cell (10) has a cross section U on the left side.
A negative electrode side connector / hook member (33) is attached to the right side, and a positive electrode side connector / hook member (34) having a U-shaped cross section is attached to the right side.

Although not shown, a pair of left and right U-shaped wire hooking members are attached to the lower surface of the front edge of the solar cell (10).

On the other hand, among the solar cell mounting wires (12) and (13) stretched vertically and horizontally on the roof (11), the wire (12) in the left-right direction is connected to the negative electrode side connector and hooking member of the solar cell (10). (33)
The annular negative terminal (31) is located at the position corresponding to
An annular positive terminal (32) is attached to a position corresponding to the positive connector / hook member (34) of (0).

The solar cell (10) is a negative electrode side connector and hooking member (33)
Is connected to the negative terminal (31) and the positive connector / hook (34)
Are fitted to the positive electrode terminals (32), respectively, and each wire hooking member is hooked on the wire (12),
Attached to wire (12).

The negative electrode terminal (31) and the positive electrode terminal (32) are connected to lead wires for guiding electric energy obtained by the solar cell (10) indoors. Multiple solar cells (10)
If a negative electrode terminal (31) provided for each solar cell (10) and a positive electrode terminal (32)
Comrades are connected by electric wire, one negative terminal (31)
And, a lead wire for guiding the electric energy obtained by all the solar cells (10) indoors is connected to one positive electrode terminal (32).

According to such a method, the solar cell (10) can be easily attached to the solar cell attachment wires (12, 13), and the electrical connection between the solar cells (10) can be easily achieved.

7 and 8 show a second embodiment of the present invention.

On the roof (11) facing the south side, a metal net (40) is stretched along the roof (11), and the solar cell (10) is attached to this net (40). I have.

The net (40) consists of a frame (41) made of large-diameter wire,
It consists of a number of small-diameter wires (42) stretched in a frame (41). The net (40) is attached to the roof (11) by being fixed to the purlin of the roof (11), rafters, etc. via the wire (43) for attaching the net at a plurality of places required for the frame (41). I have.

At several required locations on the lower surface of the peripheral portion of the solar cell (10), U
Shaped hooks (44) are attached to each. Each hook (44) is hung on the wire (42) of the net (40), so that the solar cell (10) is attached to the net (40).

The method of attaching the solar cell (10) to the roof (11) will be described. First, the net (40) is spread on the roof (11), and then placed on the net (40) using the net attachment wire (43).
To the roof (11).

Next, the solar cell (10) is placed on the net (40), and each hook (44) of the solar cell (10) is hung on the wire (42) of the net (40). Thereby, the solar cell (10) is installed on the roof (11).

In this way, according to this solar cell installation method, the hook (44) provided on the solar cell (10) is hung on the net (40) stretched on the roof (11), and the solar cell (10) is connected to the net ( 40)
As compared with the case where a gantry is used to mount the solar cell (10), the weight can be reduced and the installation work can be simplified. Also, solar cells (10) of any size and quantity can be easily installed on the roof (11). Further, once the solar cell (10) is installed, the solar cell (10) can be removed and replaced by loosening the wire (43) for the net and removing the hook (44) from the wire (42). Very easy to do.

(G) Effects of the Invention As described above, according to the first method of installing a roof-mounted solar cell of the present invention, a solar cell mounting wire is stretched vertically and horizontally on a roof, and the solar cell mounting wire is attached to the roof. Since the solar cell is mounted, a stand for mounting the solar cell is not required, so that the cost can be reduced and the installation operation can be simplified. Also, depending on the size and quantity of solar cells,
Since the solar cell mounting wire can be stretched, solar cells of any size and quantity can be easily installed on the roof.

According to the second method of installing a roof-mounted solar cell of the present invention, a net is placed on the roof, and a hook provided on the solar cell is hung on the net, and the solar cell is mounted on the net. Compared to the case where a gantry is used for mounting, the weight can be reduced and the installation work can be simplified.
Also, solar cells of any size and quantity can be easily installed on the roof. Furthermore, since the solar cell once installed can be removed by, for example, loosening the tension of the net and removing the hook from the net, the solar cell can be easily removed and replaced.

[Brief description of the drawings]

1 to 4 show a first embodiment of the present invention. FIG. 1 is a schematic perspective view showing a state where a solar cell is installed on the roof of an existing house. FIG. 2 is an enlarged perspective view showing a state where the solar cell mounting wire is mounted on a roof. FIG. 3 is an enlarged perspective view showing a mounting state of a solar cell to a solar cell mounting wire. FIG. 4 is an enlarged sectional view showing the solar cell. FIG. 5 and FIG. 6 show a modification of the first embodiment. FIG. 5 is a schematic partial perspective view showing a negative electrode side connector / hook member and a positive electrode side connector / hook member provided on a solar cell, and a negative electrode terminal and a positive electrode terminal provided on a solar cell mounting wire. . FIG. 6 is a side view of FIG. 7 and 8 show a second embodiment of the present invention. FIG. 7 is a schematic perspective view showing a state where a net is attached to a roof of an existing house. FIG. 8 is a sectional view showing a state where a solar cell is attached to a net stretched over a roof. 10… Solar cells, 11… Roof, 12, 13… Wires for mounting solar cells, 40… Nets, 44… Hooks.

Claims (2)

(57) [Claims] 1. A roof-mounted solar cell in which a solar cell is installed on a roof by attaching solar cell mounting wires vertically and horizontally on a roof and connecting a plurality of required positions of the solar cell to the solar cell mounting wire. Installation method. 2. A hook is provided at a plurality of required positions on a peripheral portion of the solar cell, a metal net is stretched on the roof along the roof upper surface, and the solar cell is mounted on the net. A method of installing a roof-mounted solar cell in which the solar cell is mounted on a roof by attaching the solar cell to the net by hanging the cable on the net.