CH681053A5 - Energy recovery solar panel for water heating - has cells mounted on elastomer mat having formed channels through which liquid is circulated - Google Patents

Abstract

The solar energy panel has a matrix of cells (1) that are bonded onto an elastomer mat (3) located on top of the cells is a transparent plate (2) of glass or plastic that is bonded into position. Two such assemblies can be mounted side by side on a wooden base (5) and are held in position by bridging elements (10) with fixing screws (9). The elastomer mat is produced with a cross section that is formed with channels through which a fluid may be circulated. At the same time that the solar cells are cooled, the fluid is heated and this may be used for some form of external heating, i.e. a swimming bath. USE/ADVANTAGE - Allows recovery of additional energy. Can be used to heat water in swimming pool or as primary circuit of water heat pump.

Description

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description

Solar cells were originally developed to power satellites. Today, however, the technology for producing solar cells has progressed so far that such cells are also used on earth in many places where it is difficult to supply electrical current. Such solar cells usually consist of a light-sensitive layer which converts sunlight into electrical charge and which is placed on a metal plate, e.g. an aluminum plate and through a transparent pane, e.g. a sheet of natural or artificial glass, covered, i.e. is protected.

It has now been found that the yield of sunlight can be significantly improved by such a device for generating energy by providing the solar cells on the side facing away from the sun with a rubber mat which has channels for a cooling liquid. In this context, a rubber mat is understood to mean any structure made of rubber or a rubber substitute, i.e. an elastic plastic, which is provided with channels for a cooling liquid, e.g. ordinary water. It is expedient if the solar cells on the side facing the sun radiation with a transparent pane, i.e. e.g. a glass pane or a pane made of transparent plastic with which they are welded or to which they can be glued by means of a transparent adhesive.

An exemplary embodiment of the invention is described below with reference to the accompanying drawing. The single figure of the drawing shows a cross section through an inventive device for energy generation, which at the same time forms a roof skin of a building, the individual components of the device being shown on different scales for better clarity.

The solar cells 1 of known construction are protected on the side facing the sun by means of a transparent glass plate 2 or a transparent plate made of plastic against any mechanical damage. The solar cells can be welded to this plate or connected to it by means of a transparent adhesive, as is common in many applications. The new and inventive feature that is essential for increasing the energy yield is the fact that the solar rows 1 lie on the side facing away from the sun radiation on a rubber mat 3 which is provided with channels 4 for a cooling liquid. In the exemplary embodiment shown, the rubber mat consists of an upper layer 3a, a lower layer 3b and webs 3c, which keep the two layers at a constant distance and use these layers to delimit channels 4 for a cooling liquid. The wall thickness of these channels is preferably 1-2 mm, the total thickness of the mat is approximately 10 mm. The technical advantage that can be achieved by the rubber mat, which of course does not necessarily have to be rubber, but can be made of any rubber-like or plastic that serves as a rubber substitute, i.e. a so-called artificial rubber, is that it is possible on the one hand to dissipate the heat generated by the solar radiation by means of a coolant flowing through the channels, so that it can be used elsewhere, e.g. for direct heating of a swimming pool or as the primary circuit of a heat pump, and on the other hand because the heat is dissipated and the solar cell cools is kept, this works with a higher efficiency, ie emits more electricity per incident amount of light. The structure described above can now, as shown in the drawing, be used as a roof skin. In the drawing, 5 denotes an under-roof formed by a wooden underlay. This is, as usual, attached to rafters, one of which is shown in the drawing and designated 6. Of course, the sub-roof 5 can also be made from plastic parts or a hard or soft plastic insulation layer can be attached to the top or bottom of the boards.

The rubber mat 3, which is laid so that its channels run in the direction of the roof, has a channel-free longitudinal strip 7 on each of its two longitudinal edges. During assembly, two abutting strips 7 are held tightly and tightly together by a longitudinal rail 8 also running in the falling line. It is of course readily possible to use several rail sections, the ends of which overlap one another, instead of a single rail which extends over the entire length of the rubber track. Screws 9 and clamps 10 are used to fasten all the parts described above: The screws 9 serve to hold the longitudinal rail 8 or the rail sections forming them, while the clamps 10 press the glass plates 2 against the sub-roof. Of course, it is also possible, instead of tension clamps 10, which can be attached, for example, every 50 cm, to attach a cover plate extending over the entire length of the web or a plurality of cover plates covering one another in a shingle-like manner.

For the good circulation of the cooling water, one glues or welds to the lower and upper ends of each rubber mat 3 a cross-sectionally U-shaped or semicircular end piece connecting the channels 4 to each other, the end piece at the lower end with an inflow pipe and the end piece at the top End is provided with a drain pipe. Depending on the prevailing conditions, the flow generated by the heating of the water in the channels is sufficient, or a circulation pump can or must also be provided. With this arrangement it is therefore possible to operate the solar cell in a temperature range that is optimal for it, that is to say to obtain a higher output from it than in the

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previous operation, and additional heat energy.

Of course, the device according to the invention for generating energy can not only be used as a roof skin. It can also be attached somewhere to clad a wall or as an isolated energy recovery element.

Claims (12)

Claims 1. Device for generating energy with solar cells, characterized in that the solar cells (1) are provided on their surface facing away from the sun with a cooler which has an inflow connection and an outlet connection for a cooling liquid. 2. Device according to claim 1, characterized in that the solar cells (1) on their side facing the solar radiation are covered by a transparent pane (2). 3. Device according to claim 2, characterized in that the solar cells (1) are non-detachably connected to the transparent pane (2) by means of a transparent adhesive. 4. Device according to claim 2, characterized in that the solar cells (1) are welded onto the transparent pane (2). 5. Device according to one of claims 1 to 4, characterized in that the solar cells (1) rest on the cooler. 6. Device according to one of claims 1 to 4, characterized in that the solar cells (1) are detachably connected to the cooler. 7. Device according to one of claims 1 to 4, characterized in that the solar cells (1) are permanently welded or glued to the cooler. 8. Device according to one of claims 1 to 7, characterized in that the cooler is formed by two sheets connected to one another at its edges and at a plurality of further locations. 9. Device according to claim 8, characterized in that the points connecting the sheets from the inflow connection to the outlet connection lead channels. 10. Device according to one of claims 1 to 7, characterized in that the cooler is formed by a rubber mat provided with channels for the cooling liquid. 11. The device according to claim 10, characterized in that the rubber mat (3) is about 1 cm thick and is formed from an upper (3a) and a lower layer (3b) and the two layers at a constant spacing webs (3c) . 12. Device according to claim 11, characterized in that the two layers (3a, 3b) and the webs (3c) are each about 1-2 mm thick. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd