WO2009086803A2

WO2009086803A2 - Photovoltaic element, carrier structure, method for assembling a carrier structure and power plant therefor

Info

Publication number: WO2009086803A2
Application number: PCT/DE2008/002130
Authority: WO
Inventors: Christof Lagaly; Matthias Nitzko
Original assignee: Rev Renewable Energy Ventures, Inc.
Priority date: 2008-01-05
Filing date: 2008-12-18
Publication date: 2009-07-16
Also published as: WO2009086803A3; DE102008003286A1

Abstract

A photovoltaic element, particularly a thin-layer module (4) comprising an electrically contacted laminate (5), is fixed with the back thereof to a carrier body (6). The carrier body (6) at the side edges (7) thereof has means for the non-positive or positive fixation on a carrier structure.

Description

10.12.2008

Photovoltaic element, support structure, method for mounting a support structure and power plant thereto

description

The invention relates to a photovoltaic element, in particular a thin-film module comprising an electrically contacted laminate, which is fixed with its back on a support body, a support structure with parallel aligned profiles for at least one photovoltaic element with a rear support body, in particular a thin film module , A method for mounting a support structure comprising a plurality of parallel aligned profiles for several photovoltaic elements, in particular thin-film modules, wherein the profiles are aligned parallel to each other at least two perpendicular thereto arranged support profiles, and a power plant to do so.

Thin-film cells differ from crystalline solar cells based on silicon wafers on the one hand by their respective production processes and the layer thicknesses of the materials used and on the other by the physical properties of the amorphous material used in the thin-film cells, the properties crystalline silicon are different. Compared to crystalline solar cells made of silicon wafers, thin-film cells made of amorphous silicon (a-Si: H) are often about 100 times thinner. The thin-film cells are usually applied by deposition of the material from the gas phase directly onto a support material, which may be, for example, glass, sheet metal or plastic. Possible further materials for the production of thin-film cells are microcrystalline silicon (μc-Si: H), gallium arsenide (GaAs), cadmium telluride (CdTe) or copper indium (gallium) sulfur selenium compounds CIS cells or CIGS cells.

For the production of electricity, a high degree of efficiency is desired, which is also partially exhibited by thin-film modules. However, the efficiency is not the sole criterion in the selection of solar cells, as often the cost at which electricity from the solar cells can be produced, a decisive factor, the production methods used, the cost of the materials used, the cost of the complete Modules and their installation costs are not insignificant. In this context, the cost-effective and large-scale production of thin-film modules is advantageous.

DE 20 2006 008 614 U1 discloses a carrier assembly group for a solar cell unit comprising crystalline solar cells. On the back of the web-shaped carrier assembly group, ie on the side facing away from the sunlight side, is a solar cell embedding

Plastic compound with a galvanized sheet steel connected support body whose thickness is about 0.5 mm to 1 mm. On the edge side, the carrier assembly group is provided with mounting strips for connection to adjacent carrier assembly groups without adapter elements. If the carrier assembly group is to have a relatively high rigidity, the carrier body comprises a lavishly designed plastic base body with an embedded metal reinforcement.

Furthermore, DE 699 30 588 T2 shows a frame system for photovoltaic modules, which have a composite of several rails frame for mechanical stabilization and attachment.

The known solutions for mounting thin-film photovoltaic modules are disadvantageous in that the thin-film photovoltaic modules always have a multi-part frame which both stabilizes the thin-film photovoltaic modules and also serves for their attachment. The frame, which is usually made of aluminum profiles, incurs costs associated with the investment costs of a

Photovoltaic system must be taken into account and partially offset the cost advantage by the relatively cheap production of the thin-film photovoltaic modules. Furthermore, the frame has a negative effect on the weight of the thin-film photovoltaic module, which in particular makes it difficult to handle during assembly of the photovoltaic system.

It is an object of the invention, a photovoltaic element, a support structure, a method for mounting a support structure and a power plant of the type mentioned create, which is or manufacture cost-effective or realize.

According to the invention the object is achieved in a photovoltaic element in that the support body has at its side edges means for non-positive or positive fixing to a support structure.

Accordingly, it is not necessary for the photovoltaic element to be assembled and stabilized in a separate

Frame. To be particularly advantageous has been found to claim the photovoltaic element via its attached via the means side edges to train. As a result, a thin-film module is also protected against environmental damage, which can be caused, for example, by wind or changing temperatures.

The means are preferably designed as bores in the support body and plug pins or suspensions. By means of the plug-in pins, which usually have a head and a shaft and can also be designed as a rivet or screw, rapid assembly of the photovoltaic element is possible. Of course, structure-side suspensions, which engage in the holes conceivable. As an alternative, the means are designed as bends. The bends can serve as mounting fixtures during assembly and at the same time stabilize the photovoltaic element.

the supporting body is angled at its side edges projecting beyond the laminate such that it is resistant to deformation is stabilized in a direction offset to the side edges.

In an embodiment, the support body is angled at its on the lamina projecting side edges such that it is stabilized against deformation in a direction offset to the side edges direction. Thus, it is not necessary to enclose the photovoltaic element in a separate frame to stabilize it. Simple and cost-effective folding of opposite side edges that protrude beyond the laminate counteracts undesirable deformation and possibly resulting damage. If the support body is rectangular in shape and fixed to a support structure, it is sufficient to reshape the longitudinal side edges accordingly, so that during assembly of the photovoltaic element using appropriate support devices, the laminate is not damaged by deformation of the support body. After assembly, the photovoltaic element can be stabilized by further measures for its use.

Preferably, at least one of the parallel aligned side edges L-shaped folded. The L-shaped bevel initially stabilizes the photovoltaic element so that it can be handled without destruction. In addition, the L-shaped fold serves to hang in an associated profile of a support structure and can serve for secure attachment after further forming processes, such as rolling or crimping. Alternatively, the mutually parallel side edges are bent in a U-shape, wherein the free leg of the fold below the back of the laminate is parallel and spaced aligned with the support body. In addition to the stabilization of the photovoltaic element, the U-shape of the side edges also offers the possibility of being hooked into a correspondingly shaped profile of a support structure.

Thus, the support body does not affect the total weight of the Photovoltaikele- ment not too negative, the support body is advantageously made of a reinforced plastic. The reinforcement is designed as a wire mesh. For relatively easy manufacture of the support body of the plastic is a thermoplastic, which can be subjected to, for example, a hot forming, and the reinforcement is encapsulated. Of course, the reinforcement can also be formed by a fiber reinforcement.

Preferably, the support body is made of a thin sheet. For the purposes of the invention, a thin sheet means a hot or cold rolled sheet having a thickness of up to 3 mm, preferably between 0.4 mm and 1 mm. Preferably, the support body consists of a stainless sheet, in particular a galvanized sheet steel, an aluminum sheet or a stainless steel sheet. The thin sheet is easy to work on a construction site during assembly of the support structure with manual means.

According to the invention the object is achieved in a support structure with parallel aligned profiles for at least least a thin film photovoltaic module solved in that the profile has means for non-positive or positive fixing of the support body.

A photovoltaic system can be manufactured quickly and inexpensively using such a carrier structure with positively or positively fixed photovoltaic elements.

For secure attachment, the photovoltaic element is held under tensile stress between the profiles. The minimum tensile stress is in particular 0.02 kN / cm ² , preferably 0.2 kN / cm ² and preferably 2 kN / cm ² . In a further development, the means comprise bores for receiving plug-in pins protruding from the support body. Thus, a structurally simple attachment is realized. Alternatively, the means comprise at least one extension for suspending the angled side edges of the support body of the photovoltaic element. The profiles can be moved and fixed to the support structure in such a way that the support bodies suspended in the extensions or fixed by means of the plug-in pins are subjected to tension and thus have a relatively small deformation. The preload counteracts deformation caused by wind or snow and possibly resulting damage. Due to the tensile load, it is possible to make the support body thin and therefore cost-effective, since the stiffness increases with the stretching and with the same stability, a weight saving compared to a non-prestressed supporting body can be achieved. To provide a secure hold the extension of the profile is angular or T-shaped and a leg of the extension of the U-shaped folded side edge of the support body overlapped. In particular, a T-shaped configuration of the extension has a relatively large support surface for the support body, whereby the assembly of the photovoltaic element is simplified. The U-shaped fold of the side edge can for example be made by crimping a preformed side edge on the construction site, wherein the fold is bent directly around the leg of the extension.

In an embodiment, the profile has two parallel and zuein ^¬ other spaced projections for suspending the angled side edges of two adjacent support bodies. Such a profile is suitable for use in large-scale photovoltaic systems with a multiplicity of photovoltaic elements.

In order to ensure a secure fit both during assembly and thermally induced changes in length, the support body is advantageously held by means of at least one clamping element on the profile. A typical support body with a length of for example 10 to 1 m, in particular 8 to 4 m, preferably 5.6 m and a width of in particular 2 to 0.1 m, preferably 1 to 0.2 m and advantageously about 0.4 m can be held by, for example, 4 to 8 evenly distributed over the length rectangular clamping elements.

Conveniently, the clamping element of an upper part and an associated lower part composed. The clamping element preferably has indentations on opposite sides for the clamping engagement of legs of adjacent extensions of the profile with the bevelled side edge of the carrier body fixed thereto. For ease of assembly, a groove for slidingly receiving a nut or a head of a screw for screw fastening the clamping element is formed between the extensions of the profile. For example, at least one screw can be rotatably held in the groove slidably and the upper part and the lower part of the clamping element are attached to the screw and bolted to a nut. Thus, both the attachment of the clamping element and the exercise of a clamping force is ensured on the support body.

In order to provide a large-area photovoltaic system, a plurality of profiles aligned parallel to one another are fixed to support profiles arranged perpendicular thereto, wherein in each case a rectangular-shaped photovoltaic element is arranged between two adjacent profiles. Conveniently, the support profiles are connected to a frame for inclined arrangement of the photovoltaic elements. According to a development, the profile and / or the supporting profile is a drawn aluminum box profile. By appropriate cavities of the profile and / or the support profile can be laid e- lectric lines for contacting the photovoltaic elements.

The object is achieved by a method for mounting a support structure comprising a plurality of parallel aligned profiles for a plurality of photovoltaic elements, in particular thin-film modules, wherein the profiles are aligned parallel to each other at least two perpendicular thereto arranged support profiles. The first profile is determined on the two support profiles and the second profile at a distance which corresponds approximately to the width of the photovoltaic element, slidably mounted on the support profiles. Subsequently, the photovoltaic element is connected to the profiles in a positive or positive fit. Thereafter, the second profile is displaced such that the photovoltaic element is held under tensile load between the two adjacent profiles and then the second profile is fixed to the support profiles.

Due to this procedure, rapid assembly of a large-area photovoltaic system, as is present, for example, in a so-called solar power plant, is possible by using relatively inexpensive photovoltaic elements.

Preferably, the photovoltaic element is attached by means of pins or fittings on the profiles. Alternatively, the photovoltaic element is hung with its angled side edges in the extensions of the profiles.

According to a development, the angled side edges of the photovoltaic element are crimped around the extensions of the profiles. Thus, the photovoltaic element is reliably held on the associated profiles. For example, to replace a photovoltaic element with inadequate efficiency or other damage, the flanged side edges of the support body of the photovoltaic element can either be separated or bent. After placing a new photovoltaic element on the adjacent profiles, its pre-formed side edges can simply be crimped around the extensions of the profiles.

In order to simplify the handling of the relatively large and unstable photovoltaic elements during assembly, it is preferred to transport stacked photovoltaic elements on a carriage which is capable of rolling on the support profiles. The photovoltaic elements are delivered to the construction site by a vehicle and are lifted by means of a crane in packages onto the carriage, which is stored on the supporting profiles. Two technicians first attach the first two profiles in front of the car, pull a photovoltaic element from the stack and place it on the profiles whose further assembly is carried out as already described, then the carriage is moved with photovoltaic elements and pre-assembled the next profile. Thereafter, a photovoltaic element is again fixed on the existing profiles and attached the pre-assembled profile to the support profiles, that the photovoltaic element is held under tension.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively indicated combination but also in other combinations. The scope of the invention is defined only by the claims. The invention will be explained in more detail below with reference to an exemplary embodiment with reference to the accompanying drawings. It shows:

FIG. 1 shows a partial perspective view of a carrier structure according to the invention with photovoltaic elements according to the invention, FIG.

2 is a front view of the illustration of FIG. 1,

3 is a plan view of the illustration of FIG. 1,

4 is an enlarged view of the detail IV of FIG. 2,

FIG. 5 is a perspective view of a carriage for photovoltaic elements and supporting carriage of the support structure

6 is an enlarged view of a detail of the support structure with photovoltaic elements of FIG. 1 in an alternative embodiment.

The support structure comprises a plurality of supporting profiles 2 fastened to a frame 1 and supporting the profiles 3 running perpendicular thereto, wherein a rectangular photovoltaic element 16 designed as a thin-film photovoltaic module 4 is arranged between two mutually parallel profiles 3.

Each thin-film photovoltaic module 4 comprises an electrically contacted laminate 5, which is fixed with its back on a support body 6 of a metal sheet. The above the laminate protruding, parallel to each other Side edges 7 of the support body 6 are bent, that the free leg 8 of the fold below the back of the laminate 5 parallel and spaced from the support body 6 extends.

The photovoltaic element 16 designed as a thin-film photovoltaic module 4 is fixed by means for positive or positive fixing to a support structure.

For attachment of the thin-film photovoltaic module 4, two T-shaped extensions 9 are provided as a means for fixing to the profile 3, wherein a leg 10 of the extension 9 is overlapped by the U-shaped folded side edge 7 of the support body 6. Between the mutually spaced extensions 9 of the executed as a drawn aluminum box section profile 3, a groove 15 is formed.

In order to reliably support the thin-film photovoltaic modules 4 to the extensions 9 of the profile 3, 12 further consisting of an upper part 11 and an associated lower part 12 existing clamping elements 13 are arranged on opposite sides indentations 14 for clamping overlapping Legs 10 adjacent extensions 9 of the profile 3 with the side edge 7 of the support body 6 fixed thereto. The upper part 11 is screwed to the lower part 12, wherein a screw head of a screw of the screw connection in the groove 11 of the profile 3 is guided in a rotationally fixed sliding manner.

For mounting the support structure is after setting up the Frames 1 with the support profiles 2 first set a marginal first profile 3 on the support profiles 2 and a second profile 3 in a about the width of a thin-film photovoltaic module 4 corresponding distance to the edge profile 3 slidably supported on the support profiles 2.

To provide the thin-film photovoltaic modules 4 for mounting a carriage 17 is provided, which consists essentially of two longitudinal beams 18 with edge stops 19 and frontally attached thereto crossbars 20. The transverse beams 20 store rollers 21, which are supported on the support profiles 2. Thus, the carriage 17 does not slip off of the inclined arranged support profiles 2, 20 also rollers having support bars 22 are provided parallel to the cross members, which bear laterally against the support profiles 2. Between the edge stops 19 of the longitudinal bars 18, a plurality of thin-film photovoltaic modules 4 can be stacked.

After attaching the second profile 3, a thin-film photovoltaic module 4 is pulled by the carriage 17 and placed on the profiles 3, so that the lateral folds between the legs 10 of the extensions 9 of the profiles 3 are. Subsequently, the still movable profile 3 is displaced such that the thin-film photovoltaic module 4 is loaded over its width to train. After attachment of the profile 3, the side edges 7 of the support body 6 of the thin-film photovoltaic module 4 are crimped, so that the above-mentioned U-shaped fold arises, namely the free leg 8 of the fold below the back of the laminate 5 parallel and spaced from the Support body 6 runs.

Accordingly, the carriage 17 is displaced and the third profile 3 is displaceably mounted on the support profiles 2 and the second thin-film photovoltaic module 4 on the profiles 3, as explained above. After securing the third profile 3, the clamping elements 13 are arranged between the first and the second thin-film photovoltaic module 4. Following this procedure, a large-area photovoltaic system with a large number of thin-film

Install photovoltaic modules 4 quickly and therefore cost-effectively.

Alternatively, as a means for fixing the formed as a thin-film photovoltaic module 4 Photovoltaikele- element 16 holes 23 for receiving pins 24 in its side edges 7 of the support body 6 is inserted. For mounting the support structure, the edge-side first profile 3 is fixed to the support profiles 2 and a second profile 3 in an approximately the width of a thin-film photovoltaic module 4 corresponding distance to the edge-side profile 3 slidably after setting up the frame 1 with the support profiles 2 first the support profiles 2 are supported, wherein the profiles have 3 holes 25 for receiving the plug pins 24, whose distances correspond to the distances between the holes 23 in the support bodies 6. After the thin-film photovoltaic module 4 is fastened to the profiles 3 by means of the plug-in pins 24, the second profile 3 is displaced in a direction opposite to the first profile 3 and fixed in a position biasing the thin-film photovoltaic module 4. At- closing the next thin-film photovoltaic module 4 is fixed as described. Of course, it is also possible to provide a longitudinal groove in the profile 3 instead of holes 25 for receiving the plug pins 24.

Claims

claims

1. photovoltaic element, in particular an electrically contacted laminate (5) comprehensive thin-film module (4), which is fixed with its back on a support body (6), characterized in that the supporting body (6) at its side edges (7) means For force or positive locking on a support structure.

2. Photovoltaic element according to claim 1, characterized in that the means are formed as bores (23) in the support body (6) and plug pins (24) or suspensions.

3. Photovoltaic element according to claim 1, characterized in that the means are formed as angled portions.

4. Photovoltaic element according to one of claims 1 to 3, characterized in that the support body (6) is angled at its over the laminate (5) projecting side edges (7) such that it against deformation in one of the side edges (7) offset Direction is stabilized.

5. photovoltaic element according to claim 4, characterized in that at least one of the mutually parallel side edges (7) is L-shaped folded.

6. photovoltaic element according to claim 4, characterized in that the mutually parallel side edges (7) are U-shaped folded, wherein the free leg (8) of the fold below the rear side of the laminate (5) parallel and spaced from the support body (6) is aligned.

7. photovoltaic element according to one of claims 1 to 6, characterized in that the supporting body (6) is made of a reinforced plastic.

8. Photovoltaic element according to claim 7, characterized in that the reinforcement is designed as a wire grid.

9. Photovoltaic element according to one of claims 1 to 6, characterized in that the supporting body (6) is made of a thin sheet.

10. Photovoltaic element according to one of claims 1 to 9, characterized in that the supporting body (5) consists of a stainless sheet, in particular a galvanized sheet steel, an aluminum sheet or a stainless steel sheet.

11 carrier structure with parallel aligned profiles (3) for at least one photovoltaic element (16) with a rear support body (6), in particular a thin-film module (4) according to any one of claims 1 to 10, characterized in that the profile (3) means for non-positive or positive fixing of the support body (6).

12. support structure according to claim 11, characterized net, that the photovoltaic element (16) is held under a tensile stress between the profiles (3).

13. A support structure according to claim 12, characterized marked, that the minimum tensile stress in particular

0.02 kN / cm ² , preferably 0.2 kN / cm ² and preferably 2 kN / cm ² .

14. A support structure according to claim 11, characterized in that the means comprise bores (23) for receiving the support body (6) by projecting plug pins (24).

15. A support structure according to claim 11, characterized in that the means comprise at least one extension (9) for suspending the angled side edges (7) of the supporting body (6) of the photovoltaic element (16).

16. A support structure according to claim 15, characterized in that the extension (9) of the profile (3) angular- o- the T-shaped and a leg (10) of the extension (9) of the U-shaped folded side edge (7). of the supporting body (6) is overlapped.

17. Carrier structure according to one of claims 15 or 16, characterized in that the profile (3) has two parallel and mutually spaced extensions (9) for hooking the angled side edges (7) of two adjacent support bodies (6).

18. Support structure according to claim 11 or 12, characterized in that the support body (6) by means of at least one clamping element (13) on the profile (3) is held.

19. A support structure according to claim 18, characterized in that the clamping element (13) consists of an upper part

(11) and an associated lower part (12) is composed.

20. Carrier structure according to claim 18 or 19, characterized in that the clamping element (13) on opposite sides indentations (14) for clamping overlapping legs (10) of adjacent extensions (9) of the profile (3) with the beveled side edge fixed thereto ( 7) of the supporting body (6).

21. Carrier structure according to one of claims 15 to 20, characterized in that between the extensions (9) of the profile (3) has a groove (15) for slidably receiving a nut or a head of a screw to

Screw fastening of the clamping element (13) is formed.

22. A support structure according to any one of claims 15 to 21, characterized in that a plurality of profiles (3) are arranged parallel to each other aligned on perpendicular thereto arranged support profiles (2), wherein between two adjacent profiles (3) each have a rectangular-shaped photovoltaic element (16) is arranged.

23, support structure according to one of claims 15 to 22, character- ized in that the support profiles (2) with a frame (1) for the inclined arrangement of the photovoltaic elements (16) are connected.

24. Carrier structure according to one of claims 15 to 23, characterized in that the profile (3) and / or the support profile (2) is a drawn aluminum box section.

25. A method for mounting a support structure, in particular according to one of claims 11 to 24, comprising a plurality of mutually parallel profiles (3) for a plurality of photovoltaic elements (16), in particular thin-film modules (4) according to one of claims 1 to 10, wherein the profiles (3) are aligned parallel to each other at at least two support profiles (2) arranged perpendicular thereto, characterized in that

- fixed the first profile (3) on the two support profiles (2) and the second profile (3) at a distance which corresponds approximately to the width of the Photovoltaikelemen- tes (16), slidably mounted on the support profiles (2) .

- The photovoltaic element (16) positively or positively connected to the profiles (3), - The second profile (3) is moved so that the photovoltaic element (16) under tensile load between the two adjacent profiles (3) is held and then the second profile (2) is fixed to the support profiles (2).

26. The method according to claim 25, characterized in that the photovoltaic element (16) by means of plug pins (23) is attached to the profiles (3).

27. The method according to claim 26, characterized in that the photovoltaic element (16) with its angled side edges (7) in the extensions (9) of the Pro file (3) is mounted.

28. The method according to claim 27, characterized in that the angled side edges (7) of the Photovol- taikelementes (16) are crimped around the extensions (9) of the profiles (3).

29. The method according to claim 27 or 28, characterized in that stacked photovoltaic elements (16) are transported on a carriage (17) which is on the support profiles (2) rollingly displaceable.

30. Power plant with at least one photovoltaic element

(16) according to one of claims 1 to 10 and / or a support structure according to one of claims 11 to 24.