JP2001007358A5 - - Google Patents

Description

That is, the solar cell module of the present invention includes a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back surface cover material from at least the light receiving surface side. in the battery module, said non-light-receiving surface side filler resin comprises two different resin materials, resin materials in contact with the rear surface cover member of the non-light-receiving surface side filler resin is flame retardant than the light receiving surface side filler resin It is characterized by.
Further, the solar cell module of the present invention includes a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back surface covering material from at least the light receiving surface side. In the battery module, the back surface cover material has holes for electric output terminals, and among the non-light receiving surface side filling resins, the filling resin provided at least in the vicinity of the holes for the electric output terminals is filled on the light receiving surface side. It is characterized by being more flame-retardant than resin.

Further, the method for manufacturing a solar cell module of the present invention includes at least a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back surface cover material from the light receiving surface side. In the method for manufacturing a solar cell module, the non-light receiving surface side filling resin is composed of two different resin materials, and the portion of the non-light receiving surface side filling resin in contact with the back surface cover material is the light receiving surface side filling resin. It is characterized by using a resin material that is more flame-retardant.
Further, the method for manufacturing a solar cell module of the present invention includes at least a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back surface cover material from the light receiving surface side. In the method for manufacturing a solar cell module, the back surface cover material is provided with a hole for an electric output terminal, and the filling resin provided at least in the vicinity of the hole for the electric output terminal among the non-light receiving surface side filling resins It is characterized by using a resin that is more flame-retardant than the light-receiving surface side filling resin.

( Reference Example 1)
The feature of this reference embodiment is that a silicone resin is used for both the light-receiving surface side and the non-light-receiving surface side filling resin, but platinum is contained only in the non-light-receiving surface side filling resin. Other parts not otherwise specified are the same as those in the embodiment.

FIG. 4 is a cross-sectional view showing the configuration of the solar cell module of the present reference embodiment, and will be described with reference to this.

Since the silicone resin of this reference example has excellent adhesiveness as compared with the flame-retardant silicone resin used in the embodiment, it is not necessary to use another filling resin having excellent adhesiveness, and the silicone resin comes into contact with the photovoltaic element 2. It is used as such.

When a platinum complex is contained in a silicone resin, it may turn yellow. However, in this reference example, the filling resin 19 on the light receiving surface side does not contain platinum and there is no concern about yellowing. On the other hand, since the filling resin 20 on the non-light receiving surface side contains platinum, there is a concern about yellowing. However, even if the translucency is lowered due to yellowing due to the non-light receiving surface side, photoelectric conversion is performed. There is no need to worry about affecting your ability.

(Example 1 )
A feature of this embodiment is that a platinum-containing silicone resin is provided only in the vicinity of the holes for the electric output terminals. Other parts not otherwise specified are the same as those in Reference Example 1.

Reference numeral 20 denotes a silicone resin containing platinum, which is the same as that used in Reference Example 1, and is provided in the vicinity of the hole for the electric output terminal (up to 5 cm outside the peripheral edge of the hole). The other filling resin 19 is a platinum-free silicone resin similar to that used in Reference Example 1.

In this embodiment, the flame-retardant polyethylene foam 21 is attached to the back surface side of the metal reinforcing plate 7 with a thickness of 1.5 mm as shown in FIG. Due to the heat insulating effect of the flame-retardant polyethylene foam 21, heat transfer to the back surface side of the solar cell module is reduced in this example as compared with Reference Example 1. Therefore, by providing a flame-retardant resin containing platinum in the silicone resin only in the vicinity of the hole for the electric output terminal where heat conduction is easily performed or the flame may be extended, the amount is reduced. A great effect can be obtained by the amount of flame-retardant resin.

( Reference Example 2 )
This reference embodiment is characterized in that a vinyl chloride resin is used as the filling resin on the non-light receiving surface side, and other points not otherwise specified are the same as those of the embodiment.

The surface protective film and the surface side filling resin, which are combustible materials, were the same as those in the embodiment, except that the non-light receiving surface side filling resin of this reference example was provided with a vinyl chloride resin having a thickness of 550 μm.

( Reference Example 3 )
This reference example is characterized in that a vinyl chloride resin is used as the filling resin on the non-light receiving surface side, and aluminum hydroxide is added to the vinyl chloride resin in order to further improve the flame retardancy. The points are the same as in Reference Example 2 .

As a result, the flame retardancy of the filling resin on the non-light receiving surface side is further improved, and a solar cell module having further excellent fire protection performance can be obtained as compared with Reference Example 2.

[Simple explanation of drawings]
FIG. 1
The cross-sectional view which shows the structure of the solar cell module of the Embodiment Example of this invention.
FIG. 2
A perspective view of a roof showing a state in which the solar cell module of the present invention is installed and constructed as a building material.
FIG. 3
FIG. 2 is a cross-sectional view taken along the cutting line AA'in FIG. 2, showing a state in which the solar cell module of the present invention is installed and constructed on a roof.
FIG. 4
FIG. 5 is a cross-sectional view showing the configuration of the solar cell module of Reference Example 1.
FIG. 5
The cross-sectional view which shows the structure of the solar cell module of Example 1 of this invention.
[Explanation of symbols]
1 Solar cell module 2 Photovoltaic element 3 Light receiving surface side filling resin (EVA resin)
4 Fluororesin film 5 Non-light receiving surface side filling resin (EVA resin)
6 Non-light receiving surface side filling resin (flame-retardant silicone resin)
7 Metal reinforcing plate 8 Electric output terminal box 9 Adhesive 10 Output electric cable 11 Rising part 12 Field plate 13 Rafters 14 Rafters 15, 17 Drill screws 16 Fixing hardware 18 Decorative cover material 19 Light-receiving surface side filling resin (silicone resin)
20 Non-light receiving surface side filling resin (platinum-containing silicone resin)
21 Flame-retardant polyethylene foam

Claims (13)

At least from the light receiving surface side, in a solar cell module having a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back cover material,
The non-light-receiving surface side filling resin is made of two different resin materials, and the resin material in contact with the back cover material among the non-light- receiving surface side filling resin is more flame retardant than the light-receiving surface side filling resin. Solar cell module. At least from the light receiving surface side, in a solar cell module having a translucent surface cover material, a light receiving surface side filling resin, a photovoltaic element, a non-light receiving surface side filling resin, and a back cover material,
The back cover material has holes for electrical output terminals, and the filling resin provided at least in the vicinity of the holes for the electrical output terminals among the non-light receiving surface side filling resins is more incombustible than the light receiving surface side filling resin. A solar cell module characterized by being characterized. The back cover member is a solar cell module according to claim 1 or 2, characterized in that the incombustible material. The solar cell module according to claim 3 , wherein the non-combustible material is a metal plate. The solar cell module according to claim 1, wherein the light receiving surface side filling resin is an ethylene-vinyl acetate resin. At least from the light-receiving surface side, in the method for producing a solar cell module comprising a translucent surface cover material, a light-receiving surface-side filling resin, a photovoltaic element, a non-light-receiving surface-side filling resin, and a back cover material,
The non-light-receiving surface side filling resin is composed of two different resin materials, and a resin material that is more flame retardant than the light-receiving surface side filling resin is used for a portion of the non-light-receiving surface side filling resin that is in contact with the back cover material. A method for producing a solar cell module, comprising: At least from the light-receiving surface side, in the method for producing a solar cell module comprising a translucent surface cover material, a light-receiving surface-side filling resin, a photovoltaic element, a non-light-receiving surface-side filling resin, and a back cover material,
The back cover material is provided with holes for electrical output terminals, and at least the filling resin provided in the vicinity of the holes for electrical output terminals among the non-light receiving surface side filling resin is more flame retardant than the light receiving surface side filling resin. A method for manufacturing a solar cell module, characterized by using the following. The back cover material, a method for manufacturing a solar cell module according to claim 6 or 7, characterized in that a noncombustible. The method for manufacturing a solar cell module according to claim 8 , wherein the non-combustible material is a metal plate. The method for manufacturing a solar cell module according to claim 6, wherein the light receiving surface side filling resin is an ethylene-vinyl acetate resin.   A plurality of solar cell modules according to any one of claims 1 to 5 are fixed by a fixing member on the outside of a base material having a combustible material at least in part, and electricity of the plurality of solar cell modules is fixed. The envelope structure is characterized in that each output is electrically connected in parallel or in series.   The said base material is a wooden field board, The solar cell module several sheets in any one of the said Claims 1 thru | or 5 are used as a roofing material, It is fixing so that it may not leak rain water on the non-light-receiving surface side. The roof according to claim 11, wherein the roof is an enclosure structure.   6. A power generation device comprising the solar cell module according to claim 1 and a power conversion device connected to the solar cell module.