DE29810238U1 - Solar cell arrangement - Google Patents

Description

Fax/Telecopier (0561)780032

Autokühler GmbH & Co KG, 34369 Hofgeismar

Solar cell arrangement

The invention relates to a solar cell arrangement according to the type specified in the preamble of claim 1.

Solar cells are used to generate electrical energy using photovoltaics. The solar cells are usually arranged in a number of rows and columns to form what are known as solar cell modules and are embedded on all sides in a housing that has a transparent cover made of glass or similar on at least one broad side. Depending on the efficiency of the solar cells used, such solar cell modules convert only around 12% to 17% of the incident solar energy into electrical energy, while the majority is converted into heat. This means that modules can heat up to over 70° on hot days. The performance data given by the module manufacturers normally refers to a module temperature of 25 ⁰ C. However, the efficiency of a PV module decreases as the module temperature increases. If a power loss of approximately 0.45% per ¹⁰ C temperature increase (average value when using crystalline solar cells) is assumed, the power is reduced by approximately 20% compared to the manufacturer's specification at a module temperature of 70 ⁰ C.

To avoid this disadvantage, solar cell arrangements have become known in which the solar cell modules are provided with cooling devices on their backs in order to keep the solar cells at a favorable operating temperature even in strong sunlight.

temperature and thereby improve efficiency compared to uncooled solar cell arrangements.

A known solar cell arrangement of the type described at the beginning (DE 42 06 931 A1) contains a profiled sheet as a cooling device, on the front of which the solar cell modules are attached and on the back of which cooling pipes are attached by welding. Another known solar cell arrangement is constructed in a similar way (DE 91 04 211 U1), in which the solar cells are attached to a heat-conducting rear wall, which is in press contact with a plurality of cooling pipes on its other broad side. In another known solar cell arrangement (DE 296 05 277 U1), the solar cells are attached to a heat sink made of honeycomb aluminum by gluing, the heat sink serving as a spacer between the solar cells and a rear wall made of an insulating material (styrofoam). Finally, a solar cell arrangement of the type described at the beginning is known (DE 31 12 468 A1) which has a heat sink in the form of a flow channel through which the coolant flows. The flow channel has a translucent wall behind which the solar cells are arranged. The solar cells are therefore immersed at least with their rear sides in the cooling medium, which consists, for example, of an electrically non-conductive oil. In a similar arrangement, the solar cells form wall sections of a pipe through which the coolant flows (EP 0 789 405 A1).

The problem with the solar cell arrangements described is that they either enable good heat dissipation from the solar cells with a relatively high level of construction effort, or they only bring about a slight improvement in the efficiency of the solar cells with a simple construction. This is unsatisfactory because more frequent use of cooled photovoltaic systems can only be achieved if the achievable increase in performance is greater than the additional investment cost caused by the installation of cooling devices. This is particularly true for the usual applications on house roofs, building facades, etc.

No viable solutions seem to have been found yet, since solar cell arrangements equipped with cooling devices have not yet become established.

The invention is therefore based on the object of providing a solar cell arrangement of the

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which is easy to manufacture, provides a good cooling effect and, due to its dimensions and weight, allows for a wide range of applications.

The characterizing features of claim 1 serve to solve this problem.

The invention has several advantages. Due to the use of a wave-shaped heat sink, a high level of mechanical stability of the entire arrangement is made possible despite the fact that areas through which the coolant flows are at least partially directly adjacent to the solar cells to improve the heat exchange performance. Since the heat sink also has a large heat exchange surface, a comparatively flat and therefore light arrangement can be obtained despite achieving a good cooling effect. Finally, the entire arrangement can be manufactured from a few individual parts and using generally known techniques, e.g. lamination technology, so that low construction costs can be achieved in comparison to the increase in performance achieved.

Further advantageous features of the invention emerge from the subclaims.

The invention is explained in more detail below in conjunction with the accompanying drawings using exemplary embodiments. They show:

Fig. 1 is a schematic, partially broken-away plan view of the front side of a solar cell arrangement according to the invention;
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Fig. 2 is a section along the line Π-Π of Fig. 1;

Fig. 3 is an enlarged detail of Fig. 2; and

Fig. 4 and 5 show views corresponding to Fig. 3, two further embodiments of the invention.

According to Fig. 1 to 3, a solar cell arrangement according to the invention contains at least one

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Solar cell 1, which is manufactured using a technique commonly used today and consists of a substantially plane-parallel plate with a size of approximately 120 mm x 120 mm in plan view and a thickness of a few millimeters. In the exemplary embodiment, a solar cell arrangement with six solar cells 1 is shown, which can be electrically connected to one another in parallel and/or series. Between the individual solar cells 1, gaps 2 remain free.

On their upper or front broad side, the solar cells 1 are covered with a transparent cover 3, which consists, for example, of a plane-parallel glass plate and covers all solar cells 1 that may be present. Each solar cell 1 is attached to the cover 3, for example, by means of a layer 4 consisting of an elastic adhesive that compensates for the different thermal expansions of the solar cells 1 and the cover 3.

A heat sink 5 according to the invention is attached to the lower or rear broad sides of the solar cells 1, through which a coolant can flow, for example in the direction of the arrows shown in Fig. 1. As Figs. 1 and 3 show, the heat sink 5 contains a large number of individual strips 6a, 6b, which are arranged one behind the other and parallel in the direction of flow and extend transversely to the direction of flow. According to Fig. 3, the strips 6a, 6b are corrugated in a meandering shape transversely to the direction of flow, so that they have lower sections 7a and 7b, upper sections 8a and 8b and webs 9a and 9b lying between them. The rear sides of the sections 7a, 7b and the front sides of the sections 8a, 8b preferably lie essentially in planes that are arranged parallel to one another and at a distance from one another corresponding to the length of the webs 9a, 9b. As shown in particular in Figs. 1 and 3, the corrugations of successive strips 6a, 6b are also preferably offset from one another transversely to the flow direction.

The heat sink 5 is preferably manufactured in one piece, with the strips 6a, 6b being manufactured from a sheet by a rolling process using profile rollers or by a punching process. The sheet consists of a preferably thin, highly heat-conducting material, in particular metal sheets (e.g. copper, aluminum). The heat sink 5 expediently extends over all of the solar cells 1 present. However, several heat sinks 5 of the specified type arranged in parallel can also be used.

become.

The connection of the heat sink 5 to the solar cells 1 is expediently achieved by attaching the front sections 8a, 8b of the strips 6a, 6b to the latter by means of a layer 10 made of a preferably elastic and highly heat-conductive adhesive which compensates for the different thermal expansions of the heat sink 5 and the solar cells 1.

Due to the described design of the heat sink 5, the sections 7a, 7b, 8a, 8b and the webs 9a, 9b form a large number of passages or through-holes running in the direction of flow, which within the individual strips 6a, 6b alternately delimit areas 11 and 12 that are open to the front or top and to the back or bottom. The areas 11 that are open to the front are, as shown in Fig. 3, directly opposite the backs of the solar cells 1. In other words, the areas 11 border directly on the backs of the solar cells 1 with their open sides, so that a coolant flowing through these areas 11 comes into direct contact with the back walls of the solar cells 1 and causes intensive heat dissipation. Where there are gaps 2 (Fig. 1), coolant flowing in the areas 11 comes into direct contact with the back of the cover 3 and the side walls of the solar cells 1, which also results in a good cooling effect there.

The areas 12 are open at the bottom or rear, but their front sections 8a, 8b are adjacent to the rear sides of the solar cells 1, so that a coolant flowing through them is involved in the removal of heat via these sections 8a, 8b. Overall, the corrugations result in a very large heat exchange surface even with short webs 9a, 9b or flat heat sinks 5, and thus a good cooling effect, which is further increased by the offset of the strips 6a, 6b and the resulting intensive turbulence of the coolant flowing through the heat sink 5.

The sections 7a, 7b of the heat sink 5 can be exposed if, for example, air is to be used as a coolant and only rear ventilation of the solar cells 1 is intended. This effect can be improved by attaching a rear wall 14 to the rear of the heat sink 5 or to the sections 7a, 7b, which can be attached, for example, to

Building facades produce an improved flow in the manner of a chimney draft. According to a particularly preferred embodiment, however, the cover 3 and the rear wall 14 are connected to one another on the outer circumference by frame parts 15 as shown in Fig. 1 and 2, the frame parts 15 preferably consisting of U-profiles and, in the case of a square or rectangular basic shape of the entire solar cell arrangement (Fig. 1), being provided with miter cuts at the corners. The frame parts 15 or seals inserted into them also seal the space between the cover 3 and the rear wall 14, thus creating a housing which surrounds the cooling body 5 and is closed on all sides. In this case, the front and rear frame parts 15 in the direction of flow can each be provided with an inlet 16 and outlet 17 for the coolant as shown in Fig. 1. In addition, in this case the housing could be provided with sections free from the heat sink 5 in the area of the inlet 16 or outlet 17, which form collection chambers for the coolant and improve its distribution across the width of the heat sink 5. The frame parts 15 are preferably also made of metal, e.g. copper or aluminum, and can be connected to the heat sink 5 by soldering or the like to form a mechanically stable construction. Alternatively, it would also be possible to connect the various parts to one another using purely mechanical means, e.g. by using an upper and lower frame part each, which border one another along parting planes that are arranged parallel to the sections 7a, 7b or 8a, 8b. These frame parts 15 could then be connected to one another using screws, flanged edges, clamps or the like and, if necessary, with intermediate seals and, if necessary, pressed against one another with a preselected preload. In this case, adhesive layers 4 and/or 10 could be completely omitted.

In a further preferred embodiment, prefabricated assemblies are produced by, for example, connecting the lower frame parts and the rear wall 14 or the lower frame parts, the rear wall 14 and the cooling body 5 to form a first assembly by soldering or the like. The entire arrangement is then formed, for example, by placing a second assembly on top, which consists of the cover 3, which already has the solar cells 1 on its rear side, and an upper frame, which is mechanically connected to the lower frame formed from the frame parts 15. This makes it possible to connect the two assemblies in

different production sites and then later combined to form the final product.

In the embodiment according to Fig. 4, identical parts are provided with the same reference numerals. This embodiment differs from that according to Figs. 1 to 3 essentially only in that a layer 18 consisting of an electrical insulation film is arranged between the solar cells 1 and the cooling body 5. When using coolants such as normal water, which are not sufficiently electrically insulating, the layer 18 ensures that no voltage breakdowns occur or undesirable electrical current paths are formed.

Fig. 5 finally shows a further embodiment analogous to Figs. 1 to 3, so that identical parts are again provided with the same reference numerals. In contrast to Figs. 1 to 3, the corrugations consisting of the strips 6b or the sections 7b, 8b and 9b have been omitted and replaced by further corrugations consisting of the strips 6a or the sections 7a, 8a and 9a. In contrast to Figs. 1 to 4, this results in channels 19 and 20 which are closed in the direction of flow and which have no openings whatsoever due to the lack of lateral offset. The channels 19 are formed by the sections 7a and 8a, the webs 9a and the undersides of the solar cells 1 or the cover 34. The channels 20, on the other hand, are formed by the parts 7a, 8a, 9a and the rear wall 14. The advantage over the heat sink shape shown in Fig. 1 and 2 with the offset strips is the simpler structure and a lower pressure drop of the cooling medium when flowing through the channels. In addition, in Fig. 5, a layer 21 consisting of a laminating compound is provided between the cover 3 and the solar cells 1 on the one hand and between the solar cells 1 and the heat sink 5 on the other. This is intended to express that the cover 3, the solar cells 1, the heat sink 5 and possibly the rear wall 14 are connected to one another by lamination according to a particularly preferred embodiment in that the layers consisting of epoxy resins or the like are plasticized at an elevated temperature and thereby firmly connected to the parts 3, 1, 5 and possibly. At the same time, the solar cells 1 are firmly embedded in the layers. It is also clear that the layers 21, like an insulating layer 18 used if necessary according to Fig. 4, can be made comparatively thin so that they

Do not significantly affect heat dissipation.

In addition to air, water or water with antifreeze, electrically insulating coolants such as transformer oil can also be used as coolants. Furthermore, when using non-insulating coolants, provision can be made for the heat sink 5 to be made of anodized aluminum or to be anodized after its manufacture, in which case the anodized layer provides electrical insulation and therefore additional insulating means are not required.

In addition to the good cooling effect, the invention has the advantage that the solar cell arrangement can be made flat, light and, particularly when using the heat sinks according to Fig. 1 to 4, mechanically very stable using simple means. The height of the heat sinks 5 can be, for example, 3 mm to 20 mm depending on the length of the webs 9a, 9b. The width of the strips 6a, 6b measured in the direction of flow and the size and geometric shape of the waves (e.g. rectangular, trapezoidal, sinusoidal cross-section or the like) present transversely to the direction of flow can be selected depending on the individual case. In addition, it can be provided that different sizes and/or shapes of the corrugations and/or strips are provided in each heat sink in order to avoid resonance effects.

Furthermore, the coolant heated by the solar cell arrangement can be guided in a known manner with the help of a fan, a circulation pump or the like in a closed circuit and used, for example, with a heat pump to provide hot water. If the latter is not necessary, the coolant can also be guided in an open circuit, particularly when air is used. The solar cell arrangement as a whole is preferably designed in such a way that the increase in electrical energy achieved by the cooling effect is greater than the energy required to operate the fans, circulation pumps, etc.

The invention is not limited to the described embodiments, which can be modified in many ways. In particular, the layer sequences explained with reference to Figures 1 to 5 can be selected differently, and it can also be expedient to add thin layers between the sections 8a, 8b and the solar cells 1.

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made of a thermally conductive paste in order to improve the heat transfer even further. It would also be possible to provide the solar cells 1 with electrically insulating layers on their rear sides, which would make additional insulation measures unnecessary. Furthermore, the solar cell arrangement can have more or fewer than six solar cells 1, the advantages of the invention being retained even if only a single solar cell is present. In addition, it is not absolutely necessary, particularly in the embodiments according to Figs. 3 and 4, to use a heat sink made of a material that conducts heat well, since good cooling effects can also be achieved with less conductive materials due to the offset position described and the large number of areas 11 and 12. It is also possible to increase the specific power of the solar cell arrangement described by attaching the solar cells 1 to both broad sides of the heat sink 5 and covering each with a cover 3. In this case, the solar cell arrangements are arranged, for example, at preselected distances from reflective walls in such a way that they are also irradiated from the rear sides. Alternatively, the heat sink could also consist of two halves designed as shown in Fig. 3 to 5, which are arranged on the two sides of an intermediate plate and are covered on their outer sides with the solar cells 1. Finally, it is understood that the various features of the invention can also be used in combinations other than those described and shown.

Claims (18)

1. Solar cell arrangement with at least one solar cell ( 1 ), a transparent cover ( 3 ) attached to the front of the solar cell ( 1 ) and a cooling body ( 5 ) attached to the back of the solar cell ( 1 ) and through which a coolant flows, characterized in that the cooling body ( 5 ) consists of a lamella with a plurality of corrugations which form regions ( 11 , 12 ) or channels ( 19 , 20 ) through which the coolant flows, which are open on sides extending parallel to the flow direction of the coolant and with these open sides directly border the solar cells ( 1 ). 2. Solar cell arrangement according to claim 1, characterized in that the corrugations are meander-shaped, trapezoidal, sinusoidal or triangular. 3. Solar cell arrangement according to claim 1 or 2, characterized in that the corrugations are formed on a plurality of strips ( 61 , 6b ) extending transversely to the flow direction and arranged one behind the other in the flow direction, and the corrugations of successive strips ( 6a , 6b ) are offset from one another transversely to the flow direction. 4. Solar cell arrangement according to one of claims 1 to 3, characterized in that the heat sink consists of a material with good heat conduction. 5. Solar cell arrangement according to one of claims 1 to 4, characterized in that the heat sink ( 5 ) consists of aluminum. 6. Solar cell arrangement according to one of claims 1 to 5, characterized in that a rear wall ( 14 ) is arranged on the side of the cooling body ( 5 ) facing away from the solar cell ( 1 ). 7. Solar cell arrangement according to claim 6, characterized in that the cover ( 3 ), the solar cell ( 1 ), the cooling body ( 5 ) and the rear wall ( 14 ) are connected to one another by circumferential frame parts ( 15 ) to form a closed housing. 8. Solar cell arrangement according to claim 7, characterized in that the frame parts ( 15 ) each have at least one inlet and outlet ( 16 , 17 ) for the coolant. 9. Solar cell arrangement according to one of claims 1 to 8, characterized in that the solar cell ( 1 ) and the cover ( 3 ) are connected to one another by a layer ( 4 ) of an elastic adhesive. 10. Solar cell arrangement according to one of claims 1 to 9, characterized in that the solar cell ( 1 ) and the heat sink ( 5 ) are connected to one another by a layer ( 10 ) of a heat-conducting, elastic adhesive. 11. Solar cell arrangement according to one of claims 1 to 9, characterized in that a layer of a thermally conductive paste is arranged between the solar cell ( 1 ) and the heat sink ( 5 ). 12. Solar cell arrangement according to one of claims 1 to 11, characterized in that an electrically insulating layer ( 18 ) is provided between the solar cell ( 1 ) and the heat sink ( 5 ). 13. Solar cell arrangement according to claim 12, characterized in that the insulating layer ( 18 ) is an anodized layer. 14. Solar cell arrangement according to one of claims 1 to 13, characterized in that it is produced by lamination. 15. Solar cell arrangement according to one of claims 1 to 14, characterized in that it contains several heat sinks ( 5 ) according to one or more of claims 1 to 14. 16. Solar cell arrangement according to one of claims 1 to 15, characterized in that it has a plurality of solar cells ( 1 ) which are attached to two broad sides of the heat sink ( 5 ) facing away from one another. 17. Assembly for producing a solar cell arrangement according to one or more of claims 1 to 16, characterized in that it contains the rear wall ( 14 ) and/or the cooling body ( 5 ) and a lower frame part as a preassembled unit. 18. Assembly according to claim 17, characterized in that the cooling body ( 5 ) and/or the rear wall 14 and the lower frame part are connected to one another in a materially bonded manner, e.g. by soldering.