JPS61101083A - Solar battery module - Google Patents

Abstract

PURPOSE:To realize a solar battery module with its characteristics not deteriorat ed under a high-temperature, high-moisture test by a method wherein the solar battery module is constituted of a thin-film solar battery element formed on a substrate and a protecting film of a dielectric resin containing perfluoroalky lene groups and active hydrogen. CONSTITUTION:A CdS film 2 is formed on the entire surface of a glass substrate 1 and, on top of the CdS film 2, a CdTe film 3, C film 4, Ag electrode 5 are formed, with a space reserved for an Ag-In electrode 6. Covering the entirety, a compound resin film 7 is formed containing perfluoroalkylene groups and active hydrogen. A solar battery module produced to this design is excellent in withstanding high temeratures and moisture and, when exposed to such adverse environmental conditions, suffer from so small a reduction in its photovoltaic capability as 3% which may be said to fall within the error allowance of measurement.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a solar cell module, and particularly to a solar cell module with excellent heat resistance, moisture resistance and weather resistance, and a good appearance.

Conventional configurations and their problems Recently, solar cells have been attracting attention as a means of energy supply. The reason for this is that electrical energy can be easily extracted directly from the almost infinite amount of clean solar energy. However, due to the high cost of producing the electrical energy, it has not yet reached a stage where it is fully widespread. However, solar cell modules that take advantage of the above advantages have begun to appear, and there are signs that they will gradually become popular.

In planning the practical use of solar cells, it is of course important to reduce the cost of the electricity produced by them, but it is also important to ensure that the usable life of the solar cell modules produced is as long as possible. It won't happen. That is, the product must have high long-term reliability, and for this reason, efforts have been made to improve the reliability and long-term life of solar cell modules, but there are still some points that cannot be said to be sufficient.

There are various methods to increase the reliability of solar cell modules, one of which is to coat the solar cell elements with a paint that has excellent heat resistance, moisture resistance, and weather resistance to block external influences. There is a way. Already from the present invention, Cd S /
We have discovered that coating a Cd Te solar cell element with an epoxy resin can improve the heat resistance and moisture resistance of the solar cell element, and have filed a patent application. However, although epoxy resin does not easily deteriorate element performance due to its weather resistance, it may yellow itself slightly and cause poor appearance.
It had the disadvantage of being unable to avoid deterioration in more severe high temperature and humidity resistance tests.

OBJECTS OF THE INVENTION The present invention aims to provide a solar cell module that does not have the above-mentioned drawbacks, such as coloring of the resin itself, such as yellowing, and does not deteriorate even in a more severe high temperature and humidity test.

1. Bright Structure The solar cell module of the present invention has a substrate made of glass, stainless steel, etc., and CdS/CdTe formed on the substrate.
< is composed of a thin film type solar cell element such as amorphous silicon (hereinafter abbreviated as a-8i) and a protective film containing a resin derivative containing a perfluoroalkylene group and active hydrogen. Resins containing a per70 alkylene group and active hydrogen are commercially available from Asahi Glass Co., Ltd. under the trademark Lumiflon, for example. Lumiflon has a per70-roargylene group and a pendant active hydrogen, more specifically an OH group, in its molecule, and is a fluorine-containing polymer with a number average molecular weight of 20,000 to 80,000, and is similar to compounds with melamine and isocyanate groups. The reaction produces a crosslinked polymer, referred to herein as a wipe derivative. The solar cell module of the present invention is characterized by being protected by this derivative.

Description of examples The present invention will be explained using examples.

(Example 1) The figure is a sectional view of a main part of a solar cell module for explaining the present invention in detail. In the figure, 1 is a glass substrate, on which a CdS film 2 is formed on the entire surface, and Ag-
Leave a space for the In electrode 6 and deposit the CdTe film 3. C film 4
．． An Ag electrode 5 is formed. The above CdTe film 3. C
Membrane 4. Ag on the CdS film 2 on which the Aq electrode 6 is not formed.
-In electrode 6 is formed. A resin 7 is formed to cover all of them. Resin 7 is a compound containing a perfluoroalkylene group and active hydrogen. “Lumiflon ■” LF302Ct7) manufactured by Asahi Glass Co., Ltd.
1007i and Hekiza 6, a trimer of methylene diinocyanate manufactured by Nippon Polyurethane Industries Co., Ltd., was formed by heating and curing between rollers.

The solar cell module formed as described above was heated to 80°C.
The solar cells were left under conditions of 95% relative humidity for 1000 hours, and then the characteristics and appearance of the solar cells were examined.

The results are shown in Table 1 along with reference data. In Table 1, solar cell module number 1 is that of this example, and numbers 2 to 8 are reference data for comparison.

As is clear from Table 1, the solar cell module of the present invention had good high-temperature heat resistance, and the photoelectric properties showed only a factor of 3 deterioration, which could be said to be within the measurement error.

(Example 2) A solar cell module was formed in the same manner as in Example 1. However, the conditions for forming resin 7 are: temperature 80°C for 60 minutes, temperature 1
The temperature was changed from 20 minutes to 80 minutes at 00°C and 20 minutes at 120°C. However, the obtained solar cell module showed almost the same reliability as Example 1 (module number 1), although none are shown.

(Example 3) 100 parts by weight of Lumiflon 302C and resol type phenolic resin CT1000010 manufactured by Matsushita Electric Works Co., Ltd.
A solar cell module was formed in the same manner as in Example 1, except that 0 parts by weight of the mixture was used. The results of the life test are listed as number 9 in Table 1.

As is clear from Table 1, the data for the solar cell module of the present invention is slightly inferior to that of 0 Coronate EH, which shows good high-temperature heat resistance, but the data is slightly inferior to that of 0 Coronate EH, which shows that the solar cell module of the present invention has good high-temperature heat resistance. Compared to the data of , this example is very superior.

Table 1 *1 Urethane resin manufactured by Nippon Oil & Fats Co., Ltd. *2 Dow・
Silicone resin manufactured by Corning Corporation *3 Silicone resin manufactured by Shin-Etsu Chemical Co., Ltd. *4 Epoxy resin manufactured by Izumi Kasei Co., Ltd. *5 Epoxy resin manufactured by Nippon Bellnox Co., Ltd. *6 Epoxy manufactured by Nitto Electric Industry Co., Ltd. Resin also *7 Effects of the resol type pheno resin invention manufactured by Matsushita Electric Works Co., Ltd. As already mentioned in the examples, a resin derivative containing a per-70 alkylene group and active hydrogen is used as the coating resin. The solar cell modules currently available are of excellent quality with extremely high reliability. Compared to epoxy resins, which have traditionally been said to be excellent, resin derivatives containing perfluoroalkylene groups and active hydrogen exhibit outstanding moisture resistance and are glossy, which is why they are the best choice for modules. High product value.

Furthermore, solar cell modules are often covered with a three-layer film of tetra-, aluminum foil, and tetra-layer to produce devices, but resin derivatives containing perfluoroalkylene groups and active hydrogen are - It has the characteristic that it is easy to attach fluorine-containing polymer films such as three-layer films.

Of course, this fluorine-containing polymer film must be brought into contact with the resin derivative containing perfluoroalkylene groups and active hydrogen before curing, and must be cured in that state. Since the above-mentioned tetra is a fluororesin film, it has good affinity with this resin derivative and has the effect of good adhesion.

Resins containing per-70 alkylene groups and active hydrogen are currently being released by Asahi Glass Co., Ltd. under the trademark Lumiflon, but there are various grades of resins with different molecular weights. Outside of LF302C KLF1ooC, LF20
0C, LF300C.

I got results.

1. As a thin film type solar cell element, there is an A-8T solar cell element, but as with the CdS/CdTd solar cell element, if it is covered with a resin derivative containing per70 alkylene group active hydrogen, It was found that the high temperature and humidity resistance was superior to those covered with other resins.

[Brief explanation of the drawing]

The figure is a sectional view of a main part of a solar cell module for which the present invention will not be explained in detail. DESCRIPTION OF SYMBOLS 1... Glass substrate, 2... CdS film, 3... CdTe film, 4... C film, 5
...Aq main electrode 6...Ag-In electrode, 7...Resin.

Claims (7)

[Claims] (1) A solar cell module comprising a substrate, a thin film solar cell element formed on the substrate, and a protective film containing a resin derivative containing a perfluoroalkylene group and active hydrogen. (2) The solar cell module according to claim 1, wherein the substrate is glass. (3) The solar cell module according to claim 1, wherein the thin film solar cell element is a CdS/CdTe type solar cell. (4) Claim 1, characterized in that the thin film solar cell element is an amorphous silicon solar cell element.
The solar cell module described in Section 1. (5) Claim 1, wherein the protective film contains a reaction product of a resin containing a perfluoroalkylene group and active hydrogen, and a compound containing an isocyanate group.
The solar cell module described in Section 1. (6) The solar cell module according to claim 1, wherein the protective film contains a reaction product of a resin containing a perfluoroalkylene group and active hydrogen, and a phenol resin. (7) A solar cell consisting of a substrate, a thin film solar cell element formed on the substrate, an adhesive containing a resin derivative containing a perfluoroalkylene group and active hydrogen, and a protective film containing an Al foil. battery module.