DE202011000969U1 - solar module - Google Patents

Abstract

Solar module (1, 101) with: - a cover layer (2) made of glass; - A transparent melting film (3) adjoining the cover layer (2); - Solar cells (4) adjoining the melt film (3); - A rear lamination (5) adjoining the solar cells (4); and - at least one profile element (8) for fastening the solar element (1, 101) to a supporting structure, the profile element (8) being fixed on the side of the back lamination (5) opposite the solar cells (4) by means of an adhesive layer (9).

Description

The invention relates to a solar module.

Solar modules, also called photovoltaic modules or "modules" for short, are used to convert sunlight into electrical energy. Conventional solar modules in this case have the following layer structure, starting with the side facing the sun: a cover layer of glass, a melt film, solar cells, another melt film, a backsheet. For fixing the individual components and for attachment to a support structure, a frame comprising the solar module can be provided.

The invention has for its object to offer a particularly weather-resistant and / or long-term temperature-stable solar module.

This object is achieved by a solar module having the features of patent claim 1. Advantageous embodiments of the solar module are described in the subclaims.

In addition, the side of the solar module facing the sun during operation is also referred to as "front side" or "front side" and the side of the solar module facing away from the sun is referred to as "rear side" or "rear side".

According to the invention, the solar module has a covering layer made of glass, a transparent melt film adjoining the covering layer, solar cells adjoining the melting film, a back side lining adjoining the solar cells and at least one profile element for fastening the solar module to a supporting structure. The profile element is fixed on the side of the back side lining opposite the solar cells by means of an adhesive layer.

By gluing the profile element to the solar module back creates a surface connection between the profile element and the solar module, resulting in a torsion-resistant overall construction. In this way, the stability of the module is increased, which leads to an increased load capacity and weather resistance. In particular, the resistance to snow loads and storm is increased.

In an advantageous embodiment, the profile element - which is preferably made of aluminum or an aluminum alloy - projects beyond the lateral edge of the solar module with a certain supernatant. In this way, the edges of the module are protected from damage. In particular, the supernatant can be 1 to 5 mm. This range of values for the supernatant has proved to be advantageous since, although it is large enough to ensure reliable edge protection, it is at the same time small enough not to have to excessively increase the distance between individual modules arranged side by side.

Advantageously, a plurality of profile elements on the side opposite the solar cells of the back side lamination is fixed by means of an adhesive layer, so that they surround the solar module like a frame. In this way, the module is particularly torsionally rigid. Also, such an effective protection of all module edges by profile elements is possible.

In order to further increase the torsional stiffness of the module, in addition at least one profile element as a transverse strut can span the rear of the solar module, d. H. The frame-like construction can be further reinforced by introducing additional braces. In this way, the stability and snow reliability of the module can be further improved.

In a further advantageous embodiment, the cover layer is provided with an opaque coating in areas corresponding to those areas in which the profile element is fixed by means of the adhesive layer on the back side lamination. In this way, the adhesive layer can be effectively protected from sunlight, which increases the long-term stability and weather resistance of the module. Preferably, the opaque coating is a film strip, in particular a black film strip, or a color, in particular a black color.

In an advantageous embodiment, the back side lining has a melting film adjoining the solar cells and a glass adjoining the melting film. This construction of the backside lamination is particularly temperature stable. Thus, the module can be used up to a temperature of 135 ° C (continuous load) or 150 ° C (peak load).

Furthermore, the back side lining may have a potting compound, in particular a polyurethane potting compound (abbr .: PU), in which the solar cells are embedded. By embedding the solar cells in the potting compound can be dispensed with the conventional arranged on the back of the solar cell melt film and the backsheet. This reduces the temperature sensitivity of the solar module. The maximum operating temperature increases accordingly.

In addition, the potting compound increases the stability of the solar module. As a result, the thickness of the cover layer can be reduced accordingly. A reduction of the cover layer in turn increases the solar yield of the module. In particular, the conventional thickness of the cover layer can be reduced to about 50%. This increases the yield by about 5% compared to conventional modules. In particular, the conventional glass thickness can be reduced from 4-5 mm to about 2 mm.

In a further preferred embodiment, a metal foil, in particular a steel foil, is arranged on the rear side of the potting compound. This metal foil forms a good heat-conducting coating of the potting compound. Thus, the cooling of the solar module can be improved. In this way, the temperature resistance of the solar module can be over 100 ° C. Consequently, a long-term, trouble-free operation in hot areas (Italy, Africa, etc.) is possible.

The cooling can be further improved by applying a metal plate, possibly with heat sinks, to the metal foil or an integration of passive and / or active cooling elements in the metal foil.

In a further advantageous embodiment, the solar module further comprises a junction box made of aluminum. The design of the junction box as an aluminum component increases the weather resistance of the module and at the same time reduces the risk of fire.

Further important features and advantages of the invention emerge from the dependent claims, from the drawings and from the associated description of the figures. It is understood that the features mentioned above and the features to be explained below can be used not only in the respectively specified combination but also in other combinations or alone, without departing from the scope of the present invention.

The invention is further explained by means of embodiments in the drawing figures. They show, in each case schematically and fragmentarily,

1 a first embodiment of the solar module; and

2 a second embodiment of the solar module, wherein the back side lamination consists of a potting compound.

1 shows a first embodiment of the solar module 1 , The solar module 1 has a cover layer 2 , a melting film 3 , Solar cells 4 and a backside lamination 5 on. The backside lamination 5 consists of a melting foil 6 and a glass 7 ,

During operation of the solar module 1 is the topcoat 2 facing the sun. The subsequent to the deck view melt film 3 may be a film of ethylene vinyl acetate (EVA) or a silicone film. This film covers a layer of solar cells 4 , On the top layer 2 remote side of the solar cells 4 is also a melting film 6 appropriate. This melt film may also be a film of EVA or a silicone film. Be as melting films 3 . 6 Silicone-based films increase the temperature resistance compared to the use of EVA-based films. The back close of the solar module 1 forms a layer of glass 7 , This serves to stabilize the module and has a higher temperature stability than conventional backsheets.

At the side edge of the solar module 1 is a profile element 8th by means of an adhesive layer 9 at the back of the glass 7 fixed. The profile element 8th serves for fastening the solar module to a supporting structure. The profile element 8th surmounts the lateral edge of the solar module 1 with a supernatant A. This way is the edge of the solar module 1 effectively protected against damage. The profile element 8th is alone on the back of the glass 7 appropriate. Another attachment, for example, on the side edge or on the side facing the sun of the solar module 1 , can be omitted. On the top layer 2 is a coating 10 applied. This coating 10 is made of opaque material and can be designed as a dark film strip or dark color. The coating 10 is in those areas of the topcoat 2 applied, which correspond to those areas in which the adhesive layer 9 located. This way, the adhesive layer becomes 9 protected from sunlight.

2 shows a further embodiment of a solar module 101 , This in 2 illustrated solar module 101 points like the solar module 1 out 1 a cover layer 2 , a melting film 3 , Solar cells 4 and a profile element 8th by means of an adhesive layer 9 with the solar module 1 is connected. The solar module 101 out 2 differs from the solar module 1 out 1 only by a differently structured backside lamination 5 , In the solar module 101 is the backside lamination 5 through a potting compound 11 formed in which the solar cells 4 are embedded. The profile element 8th is through the adhesive layer 9 at the melt film 3 opposite side of the potting compound 11 fixed.

LIST OF REFERENCE NUMBERS

1, 101

solar module

2

topcoat

3

melting foil

4

solar cells

5

backsheet

6

melting foil

7

Glass

8th

profile element

9

adhesive layer

10

coating

11

potting compound

A

Got over

Claims (10)

Solar module ( 1 . 101 ) with: - a cover layer ( 2 ) of glass; - one on the top layer ( 2 ) subsequent transparent melt film ( 3 ); - on the molten foil ( 3 ) subsequent solar cells ( 4 ); - one to the solar cells ( 4 ) subsequent backside lamination ( 5 ); and - at least one profile element ( 8th ) for fixing the solar element ( 1 . 101 ) on a support structure, wherein the profile element ( 8th ) at the solar cells ( 4 ) opposite side of the back cover ( 5 ) by means of an adhesive layer ( 9 ) is fixed. Solar module ( 1 . 101 ) according to claim 1, wherein the profile element surmounted the lateral edge of the solar module with a supernatant (A), in particular with a supernatant (A) of 1 to 5 mm, preferably with a supernatant (A) of 1 to 2 mm. Solar module ( 1 . 101 ) according to one of the preceding claims, wherein a plurality of profile elements ( 8th ) on the solar cells ( 4 ) opposite side of the back cover ( 5 ) by means of an adhesive layer ( 9 ) Are fixed so that they surround the solar module like a frame. Solar module ( 1 . 101 ) according to claim 3, wherein additionally at least one profile element ( 8th ) as a cross strut the back of the solar module ( 1 . 101 ) spans. Solar module ( 1 . 101 ) according to one of the preceding claims, wherein the cover layer ( 2 ) in areas corresponding to the areas in which the profile element ( 8th ) by means of the adhesive layer ( 9 ) on the back cover ( 5 ) is fixed with an opaque coating ( 10 ) is provided. Solar module ( 1 . 101 ) according to claim 5, wherein the opaque coating ( 10 ) is a foil strip, in particular a black foil strip, or a color, in particular a black color. Solar module ( 1 . 101 ) according to one of the preceding claims, wherein the profile element consists of aluminum or an aluminum alloy. Solar module ( 1 ) according to any one of the preceding claims, wherein the backside lamination ( 5 ) one to the solar cells ( 4 ) subsequent melt film ( 6 ) and one to the melt film ( 6 ) subsequent glass ( 7 ) having. Solar module ( 101 ) according to one of claims 1 to 7, wherein the back side lining ( 5 ) a potting compound ( 11 ), in particular a potting compound ( 11 ) made of polyurethane, in which the solar cells ( 4 ) are embedded. Solar module ( 1 . 101 ) according to one of the preceding claims, wherein the solar module ( 1 . 101 ) further comprises a junction box made of aluminum.

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