DE29516754U1 - Solar energy roof - Google Patents

Description

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Solar energy roof

The invention relates to a solar energy roof in which the roof skin is formed by sheet metal strips which are connected to one another by means of folds and to which pipes for conducting a heat exchange medium are attached.

A solar energy roof of this type, which works as a heat collector, is known from EP-Al 32 965. With such a system, it is possible to prefabricate the sheet metal panels with attached pipes and deliver them to the construction site in this condition. Using a laying technique that is common for sheet metal roofs, the roof can then be provided with a closed sheet metal outer skin. The additional costs compared to a conventional sheet metal roof without a heat collector function are relatively low.

The object of the invention is to improve the functionality and efficiency of the solar roof known from EP-Al 32 965.

According to the invention, this is achieved in that the solar energy roof has a transparent cover that at least partially covers the pipes, the transparent cover being held at a distance from the sheet metal sheets forming the roof skin by a number of support elements attached to or formed on the sheet metal sheets.

Furthermore, it is advantageous that the pipes are attached to the outside of the sheet metal strips by means of a material connection, preferably by soldering or welding.

The greenhouse effect and the improved insulation, which are brought about by the transparent cover and the air cushion formed between the cover and the metal roof, increase the efficiency of the solar energy system according to the invention.

gy roof is significantly increased compared to the device known from EP-Al 32 965. A further improvement in the efficiency of the solar energy roof according to the invention is due to the lower heat transfer resistance between the sheet metal of the sheet metal strips and the pipes as a result of the material connection between them.

A solar energy roof according to the invention allows for simple production, cost-effective transport to the construction site and simple and quick assembly. For transport, the prefabricated sheet metal panels can be rolled up with the pipes attached to them, which is particularly advantageous for longer transport routes. It is then advantageous to cut them to the desired lengths at the construction site. After the closed sheet metal outer skin of the sheet metal roof has been produced, the transparent cover is installed by first attaching the support elements to the sheet metal panels, preferably to the folds of the sheet metal panels, and then placing the panels forming the transparent cover on the supports and attaching them to them.

Further advantages and details of the invention are explained in more detail below with reference to the accompanying drawing: In this drawing:

Fig. 1 is a section in a plane perpendicular to the roof surface and in the longitudinal direction of the roof of a solar energy roof according to the invention,

Fig. 2 is an enlargement of detail A from Fig. 1, and Fig. 3 is another embodiment of a support element.

A vapor barrier 12 and insulation 4 are applied to the roof sheathing 11, on which the copper sheeting 1 is laid. The sheeting 1 is connected by means of folds 3 and pipes 2 are welded to the sheeting 1

or soldered on, in which a heat transfer medium circulates. For this purpose, the pipes 2 are connected at the lower and upper ends of the roof by horizontally running collecting pipes 10. The pipes 2, 10 and the sheet metal strips 1 are advantageously made of copper. By means of support elements 6 attached to the folds 3, glass plates 9 are held at a defined distance from the sheet metal strips 1. The circulation of the heat transfer medium through the pipes 11, 2 is maintained by a known system using a circulation pump. The thermal energy of the liquid heated in the pipes 2 can be used for different purposes, for example for low-temperature heating or for hot water preparation.

The exact structure of the support elements 6 can be seen in Fig. 2. Two U-shaped profiles 15, 15' are located on both sides of the fold 3 and are fastened by screws 5, which pass through openings in the profiles 15, 15' and holes in the folds 3. In order to compensate for unevenness, and to take into account different temperatures and thermal expansion coefficients, compensating foils 7 can be provided. The glass panels 9 are fastened to the support elements 6 by means of double-sided adhesive glass strips 8. In addition, the glass panels 9 are fastened to the supports 6 at their corner points with screws. The space between the two glass panels 9, 9' is filled with silicone compound 16 after they have been laid.

Of course, other forms of the support elements 6 are also conceivable and possible. For example, as shown in Fig. 3, a support element 6' can be formed by a single U-shaped profile, one U-leg 6'a of which is soldered to the fold 3, the other U-leg 6'b of which is soldered to the copper sheet 1 and on whose base surface 6'c the two glass plates 9 rest. This form of the support elements 6 has the advantage that the sheet metal folds 3 do not have to be cut through.

have to be drilled so that the tightness of the sheet metal skin is not impaired. This is a particularly advantageous embodiment of the invention, especially for a flat roof, where water can always collect.

In order to be able to reliably absorb the downward forces of the glass plate 9, stops (not shown in the drawing) are provided on the lower edge of each glass plate 9 for roof inclinations. These can be implemented, for example, by bent-up parts of the support elements themselves or by L-shaped profile sheets attached to the support elements.

Compared to conventional sheet metal roofs, the solar energy roof according to the invention has other advantages in addition to energy generation: Due to the air cushion formed between sheet metal strips 1 and glass cover, the insulation properties are improved, so that low outside temperatures are better kept out. When the sun shines, the temperatures in the rooms under the solar energy roof do not rise as high as with a normal sheet metal roof, since heat is dissipated by the heat exchange medium circulating in the copper pipes 2. Furthermore, the noise caused by rain is significantly reduced by the glass cover 9. When it snows, the snow cover that forms normally flows evenly off the glass cover 9 during precipitation. Should wet snow nevertheless freeze onto the glass cover 9, the snow cover can be made to slide off by pumping water through the pipes 2. A partially transparent cover for the roof skin can also be provided. For example, a transparent cover can be provided in the area of the gable, which is usually snow-free first, while no cover is used in a lower part of the roof, which is equipped with the usual snow retention devices. A targeted

Melting of the thawed snow in this lower part of the roof is then made possible by energy exchange, for example by means of heat exchangers between these two areas.

Claims (11)

Protection claims: 1. Solar energy roof, in which the roof skin is formed by sheet metal strips which are connected to one another by means of folds and to which pipes for conducting a heat exchange medium are attached, characterized in that the solar energy roof has a transparent cover (9) which at least partially covers the pipes (2), the transparent cover (9) being held at a distance from the sheet metal strips (1) forming the roof skin by a number of support elements (6) which are attached or formed on the sheet metal strips (11). 2. Solar energy roof according to claim 1, characterized in that separate support elements (6) are provided from the sheet metal strips (11), preferably screwed or welded thereto. 3. Solar energy roof according to claim 1 or 2, characterized in that the support elements (6) for the transparent cover (9) are attached to the folds (3) of the sheet metal strips (1). 4. Solar energy roof according to claim 3, characterized in that the support elements (6) for the transparent cover (9) each have two U-shaped profiles (15, 15') which rest on the two sides of the folds (3) and are fastened to them by means of screws or rivets (5) which pass through openings in the profiles (15, 15') and folds (3). 5. Solar energy roof according to claim 3, characterized in that the support elements (6) for the transparent cover (9) each have a single U-profile, one U-leg of which is attached to the fold (3), preferably soldered or welded. 6. Solar energy roof according to one of claims 1 to 5, characterized in that self-adhesive strips (8) are provided for fastening the transparent cover (9) to the support elements (6). 7. Solar energy roof according to one of claims 1 to 6, characterized in that the width of the panels forming the transparent cover (9) corresponds to that of the sheet metal strips (1). 8. Solar energy roof according to one of claims 1 to 7, characterized in that the sheet metal strips (1) and the tubes (2) consist of copper. 9. Solar energy roof, in which the roof skin is formed by sheet metal strips which are connected to one another by means of folds and to which pipes for conducting a heat exchange medium are attached, in particular according to one of claims 1 to 8, characterized in that the pipes (2) are attached externally to the sheet metal strips (1) by means of a material connection, preferably by soldering or welding. 10. Solar energy roof according to claim 8, characterized in that the tubes (2) are attached to the sheet metal strips (1) by ultrasonic welding. 11. Solar energy roof according to one of claims 1 to 10, characterized in that stops for the lower edge of each panel of the transparent cover (9) are provided on the support elements (6).