DE8329884U1 - Large-area solar panel with semiconductor photoelements - Google Patents

Description

COHAUSZ & FLORACK

PATENT LAWYER OFFICE SCHUMANNSTR. &bgr;&Tgr; O*4000D0seBLDORPl

Tel: (0211)683346 &Tgr;·!·»: 0888 6513 cop d

PATENT ATTORNEYS:
Dipl.lng. W. COHAUSZ · Dipl.Hng. R. KNAUF · DlpHng. HB COHAUSZ - OfUn ₉ . O. H WERNER

' 14.10.83 - 5 -

BM -Chemie Kunststoff GmbH Adolf-Floring-Str. 22

5678 Weriaelsklrchen

Large-area solar plate with semiconductor photoelements

The invention relates to a large-area solar panel with semiconductor photoelements for the direct photovoltaic conversion of solar radiation energy into electrical energy, whereby the semiconductor photoelements are mounted between an upper light-transmissive cover plate and further layers and all layers are surrounded by a rectangular frame, of which, in the installed state, lying at an angle to the horizontal, two frame parts lie approximately horizontally and the other two frame parts, which are parallel to one another, are inclined approximately in the fall line.

In order to attach these solar panels at an angle to a roof surface or a frame, it is common to use fittings such as angle irons that clamp around the profiles of the frame. Such an attachment is labor-intensive and visually unattractive. In addition, additional

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¹ It must be ensured that a waterproofing membrane is attached underneath the solar panels if watertightness is to be achieved. The waterproofing membrane, in particular a ToILm, must be separated from the fastening means^

⁵ in particular nails or screws, are penetrated, so j that the security of a high level of tightness is reduced.

&iacgr; The object of the invention is to provide a solar panel of the type

j mentioned type in such a way that they can be used with little

I ^1O labor can be fixed and an additional sealing

§ < ) protection against water is not required.

&rgr; This object is achieved according to the invention in that one

I of the inclined frame parts on the semiconductor photoelement

i ¹⁵ elements has at least one upwardly directed rib, which is used to form a standing pallet.

i zes in a downwardly open groove of the second inclined

:' frame part of the adjacent solar panel.

&idigr; 20 These solar panels can be easily attached to a substructure, especially a batten, using nails or screws, without requiring any additional mounting parts.

&igr; are robust and highly impermeable, and

: in addition, they form with other solar panels of the same

&xgr; ²⁵ construction a surface that is absolutely waterproof.

\ From DE-OS 1 9OO O69 it is known that

L· Edges of components containing semiconductor photoelements

■ to be provided with ribs and grooves that fit into each other

*i ^ lying down to form folds. But this is roofing

I bricks or roof tiles of the usual shape, which are not only used in

their size is much smaller than solar panels, but also only has a very limited area for semiconductor

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photo elements are free. Frame parts are not present and the grooves and ribs require a lot of space in relation to the size of the panel.

Advantageous embodiments of the invention are described in the

The features listed therein not only reduce the assembly work involved in producing the plate and attaching it to a substructure, but also increase the tightness of the plate itself, so that the semiconductor photoelements are protected against environmental influences even over a long period of time. In addition,

High water vapor impermeability and high protection against mechanical damage are also achieved.

It is particularly advantageous if the frame is made of an elastomer, in particular a two-component silicone rubber or a two-component acrylic elastomer. Such a frame made of an elastomer is not only extremely simple and quick and can therefore be attached in large quantities using an automatic production process, but in addition, the laterally protruding edges of the frame can be penetrated directly by fastening devices such as nails or screws without having to drill holes first. The panels can therefore be extremely

They can be nailed or screwed onto a substructure quickly and inexpensively and can be produced in large quantities. The elastomer frame safely absorbs expansion movements of the layers surrounded by the frame, so that a particularly high level of tightness is achieved.

The frame also absorbs mechanical shocks, making the entire panel particularly robust.

An example of the invention is shown in the drawings and is described in more detail below. There are»

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Fig. 1 is a perspective view of four solar panels mounted on a batten;

Fig. 2 a section through two adjacent solar panels, with the inclined

ten frame parts are cut;

Fig. 3 a section through the profile of the upper horizontal frame part.
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Γ) Semiconductor photoelements 1 are located between two hot-melt adhesive films 2, 3, which consist of acrylic or ethyl vinyl acetate and which, after the air in between has been sucked out and melted together, hold the semiconductor photoelements securely. Above the layer 2 there is a cover plate 4 made of hardened silicate glass, which adheres with its underside to the hot-melt adhesive film 2. Below the hot-melt adhesive films there are two films 5, 6 made of fluorinated hydrocarbons (tetra film), between which an aluminum film 7 of 5Oy* is placed as a water vapor barrier. These layers 1-7 form a plate of rectangular format, with the semiconductor photoelements reaching close to the edges and being electrically connected to one another.

V Each plate contains 20 or more semiconductor photoelements of

10x10 cm arranged close together in four rows of 5 each.

This multi-layered plate is surrounded on its four edges by a frame made of aluminum profiles that enclose the edges in a U-shape. Since the plates are facing the sun at an angle and thus form an angle of 30 to 45° with the horizontal, two frame parts 8, 9 are inclined at the same angle according to the inclination of the plate and

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opposite each other, parallel to each other and two frame parts 10, 11 horizontal. While the semiconductor photoelements 1 reach close to the frame parts 8 to 10, they are arranged at a greater distance of approx. 4 to 10 cm, in particular 7 cm, from the upper horizontal frame part 11, since this area is covered by the solar plate located above it.

The first inclined side frame part 8 is, as shown in Fig. 2, formed by an aluminum profile which is U-shaped and whose legs 8a, 8b lie parallel to the cover plate 4. The vertical base 8c located between the legs 8a, 8b is extended vertically downwards and is angled at the end outwards, i.e. away from the semiconductor photoelements, by 90° in order to form a laterally projecting edge region 8d which is parallel to the plate and is covered by the adjacent plate. This region 8d, which lies lower than the underside of the adjacent plate, has two vertically projecting ribs 8e, 8f on the top side. Furthermore, the edge region 8d has, next to the ribs 8e, 8f on the side facing away from the plate, an outer area forming a surface 14 through which screws or nails can be driven into the substructure. For this purpose, this surface can have 14 openings.

In order to securely fasten the plate consisting of layers 1 to 7 in the profile 8 as well as in the second frame part 9 within the U-section, both the legs and the base have ribs 4 running lengthways to the profile as spacers, which ensure that there is always space between the plate 1 to 7 and the inner walls of the profile Gin. This space is filled by a

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Plastic sealing material that reacts chemically with both the silicate glass and the tetla film and especially with the aluminum profile.

The aluminum profile of the second inclined frame part 9 has, in the same way as the frame part 8, a U-shaped area in cross section in which the plate with the semiconductor photo elements is located and which has two legs 9a, 9b. The lower leg 9b is extended inwards and has two grooves 12, 13 on the underside which are open towards the bottom and run parallel to the profile. The ribs 8e, 8f lie in these grooves. The grooves and ribs are thus located below the ^U -shaped frame part and the plate with the semiconductor photo elements, whereby the total area of the solar plate can be optimally used by semiconductor photo elements and the frame itself only takes up a small area.

The profiles of the frame parts 8, 9 have screw channels 15, 16 on the underside in the corner area, into which screws are screwed that hold the horizontal frame parts 10, 11. The lower frame part 10 can essentially only be U-shaped and have a web pointing downwards at the end. The upper horizontal

The frame part 11, on the other hand, is formed by the profile shown in Fig. 3, which in turn has a U-shaped cross-section with legs 11a, 11b parallel to the plate surface and a vertical base 11c, which is extended downwards and bent at a right angle at the lower end to form a surface 11d parallel to the plate surface. This outwardly projecting and lower surface 11d is used for the upper fastening of the solar plate by means of fastening means such as nails or screws. For this purpose, holes can be provided in this surface 11d .

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The solar panels are attached one above the other in such a way that the inclined frame parts 8 of the panels lying one above the other lie on top of the other in the overlapping area. The same applies to the frame parts 9. The frame parts 8 are with their surfaces 14 on the falling direction Laths 16 are nailed or screwed, between which air ducts 17 are formed, running continuously from bottom to top, beneath the panels. These air ducts are not interrupted by components, since the laths 16 are on the lower, underlying horizontal slats 18. The air flowing through the channels 17 cools the solar panels on the backs.

In a second embodiment, the profiles of all frame parts are not made of aluminum, but of an elastomer, in particular a two-component silicone rubber or a two-component acrylic elastomer. This elastomer reacts chemically with the silicate glass and/or the Tetla or Teflon film, either directly or via an adhesion promoter , so that an absolutely tight connection is created. In the area of the surfaces 11d and 14, this material can be pierced by nails or screws without having to drill holes, so that a particularly easy method of fastening is possible. The openings created by these fastening elements remain absolutely tight, since the material displaced there presses against these fastening means.

The four frame parts 8 to 11 can be molded in one piece from elastomer. This is done particularly easily in an injection molding machine, which casts a frame made of elastomer around layers 1 to 7. This enables particularly automatic mass production.

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An easily removable connection of the profiles to the substructure can be created by having openings in the surfaces 11d and 14, the diameter of which in a first area is that of the head of a nail or screw and in a second area the diameter decreases, so that a positive connection is created, similar to a bayonet connection. Moving the solar panel downwards locks it and moving it upwards releases it.

Claims (4)

COHAUSZ & FLORACK patent attorney's office schumannstr. st d-4ooo düsseldorf 1 TaMm: (0211)683348 Taten: 0858 6513 cop d PATENT ATTORNEYS: DipUng. W. COHAUSZ · ttpl-tng. R. KNAUF · OipHng. H. a COHAUSZ · Oqpl-tng. &agr; H. WERNER 14.10.83 Claims 1. Large-area solar panel with semiconductor photoelements (1) for the direct photovoltaic conversion of solar radiation energy into electrical energy, the semiconductor photoelements being fastened between an upper transparent cover plate and further layers and all layers being surrounded by a rectangular frame, of which, in the installed state lying at an angle to the horizontal, two frame parts lie approximately horizontally and the two other frame parts parallel to one another are inclined approximately in the fall line, characterized in that one of the inclined frame parts (8) has at least one upwardly directed rib (8e, 8f) on the side facing away from the semiconductor photoelements, which lies in a downwardly open groove (12, 13) of the second inclined frame part (9) of the adjacent solar panel to form a standing fold. 2. Solar panel according to claim 1, characterized in that the groove(s) (12, 13) of the second inclined frame part are located at least in part below the semiconductor photoelements (1). V1 ₃₇ 290
HC/Be \ 1 3. Solar panel according to claim 1 or 2, characterized £ characterized in that the first, at least I" frame part (8) having at least one rib (8e, 8f) j next to the rib(s) on which the semiconductor photo- i" 5 elements (1) facing away from a surface (14)j, through which fastening means, in particular i Screws or nails can be driven. e 4. Solar panel according to one of claims 1 to 3, d a - [ "&Oacgr; characterized in that the ^ j &Lgr; upper horizontal frame part (11) on which the semi-conductor I terphotoelements (1) facing away a surface &bull; (11d), through which fastening means, in particular - special screws or nails can be driven, I 15 5. Solar panel according to one of claims 1 to 4, characterized in that the - lower edge of the solar panel overlaps the upper edge of the adjacent solar panel. 20 6. Solar panel according to one of claims 1 to 5, characterized in that the translucent upper cover plate (4) is made of hardened t ) tem silicate glass. 25 7. Solar panel according to one of claims 1 to 6, characterized in that the semiconductor photoelements (1) are sandwiched between two hot-melt adhesive films (2, 3), in particular made of ethyl vinyl acetate 30 or acrylic. 8. Solar panel according to one of claims 1 to 7, characterized in that 35 at least one U foil (S, 6) made of a fluorinated hydrocarbon (polytetrafluoroethylene) is attached between the semiconductor photoelements (1). 9. Solar panel according to one of claims 1 to 8, characterized in that two films (S, 6) made of a fluorinated hydrocarbon (polytetrafluoroethylene) are attached below the semiconductor photoelements.
I 10. Solar panel according to claim 9, characterized in ^that between the two Foils (S, 6) a metal foil (7) in particular made of ] Aluminum. \ I 11. Solar panel according to one of claims 8 to 10, characterized in that the frames (8-11) surround the layers carrying the semiconductor photoelements (1) in a U-shape and in particular |> by sealing material with the edges of the layers are connected. f 12. Solar panel according to claim 11, characterized in that the sealing material (1) reacts chemically with the silicate glass (4) and the film (5) made of fluorinated hydrocarbon. 13. Solar panel according to one of claims 1 to 12, characterized in that the Frames of metal profiles (8-11), in particular
Aluminum is formed. 14. Solar panel according to claim 13, characterized in that characterized in that the inclined profiles (8, 9) have screw channels (15, 16). 15. Large-area solar panel with semiconductor photoelements for the direct photovoltaic conversion of solar radiation energy into electrical energy, whereby the semiconductor photoelements are mounted between an upper translucent cover plate and further layers and all layers are surrounded by a rectangular frame, of which two frame parts are arranged in the installed state inclined to the horizontal approximately horizontally and the two other frame parts parallel to each other are inclined approximately in the palline, in particular according to one of claims 1 to 12, characterized by/ in that the Frame (8-11) consists of an elastomer, in particular a two-component silicone rubber or a two-component acrylic elastomer. 16. Solar panel according to claim 15, characterized in that the elastomer reacts chemically with the layers (4, 5) directly or via adhesion promoters. 1e Claim 15 or 16, characterized in that all the layers (1) including the semiconductor photo elements (1) are placed in an injection molding die which is wrapped around the layers a. 35