CH682831A5 - Roof tile with at least one integrated solar cell - has current conducting end elements, e.g. pins, connected by electric conducting cable with other such tiles so that power obtained is accumulated and fed to mains - Google Patents

Abstract

The roof tile (1) can be made of clay or another natural material, or from synthetic material. One solar cell (3) at least is connected securely to the roof tile. At least one solar cell is mounted so that it is mobile. The solar cell can be aligned manually or automatically on a roof tile, e.g. by a small electric motor or electromagnets and controlled individually or from a central control station. One solar cell has at least one plane different from that of the tile. The tile has at least one semi-spherically shaped solar cell. The entire tile consists of at least one solar cell. ADVANTAGE - Provides source of electrical power. Roof tile is constructed without further edging being needed. Parts including cable connections can be prefabricated.

Description

1

CH 682 831 A5

2nd

description

The manufacture of a roof tile is known. The present invention relates to an energy roof tile according to the preamble of patent claim 1.

The energy roof tile has a recess in which a solar cell (2) is mounted.

The recess can consist in the fact that it is a mere depression or in a continuous recess (4). With the continuous recess (4), the brick would have the function of a stable frame around the solar cell.

One difficulty is that the energy obtained with the solar cell has to be conducted outside the brick. This is done by providing recesses (4) in the form of holes or channels in the brick (1). These recesses (4) can already be provided in the pressing tool when the bricks are pressed, so that the recesses (4) are formed simultaneously when the bricks are pressed. They can also be created retrospectively as long as the bricks are still “wet”, ie before they are burned in.

One possible embodiment is for the current-carrying elements (9), which are connected to the solar cell, to exit through recesses (4) which are guided downwards. The recesses (4) are designed so that they come to rest on the roof batten (7), which is used to hold the tiles.

At the ends of the current-carrying elements (9) thus positioned there are conductive bodies (5), e.g. Pins mounted.

The recesses (4) are perfectly sealed with a silicone or rubber-based sealing compound (3) that does not fully harden.

A tape (6) is attached above the roof batten (7) and has at least one conductive track on the inside, which is insulated from one another on all sides and in the case of several tracks.

When laying the tiles, the pins are now driven into the conductive “core” of the band (6), which is located on the roof batten (7). The electricity generated by the solar cell can thus be dissipated and recovered. (Fig. 6)

Another version is that the recesses (4) are guided to the rear, where the anchoring feet are attached. The current-carrying elements (9) are inserted into the recesses (4) and cast in a waterproof and insulating manner as described above.

The current-carrying elements (9) are dimensioned such that they protrude from the rear and can be effortlessly connected with a prefabricated power cable. The power cable has plug-in elements, the spacing of which is dimensioned such that they extend from brick to brick. The electricity generated by the solar cell can thus be dissipated and recovered. (Fig. 7)

1-7 show some embodiments.

1 shows a schematic partial representation of an energy roof tile with an integrated solar cell,

where 1 represents the energy roof tile, 2 the solar cell and 3 the sealing compound.

Fig. 2 shows a schematic section of an energy roof tile with an integrated solar cell, the tile having an edge over which the housing of the solar cell is placed and held and sealed in the rebate, with 1 the energy roof tile, 2 the solar cell and 3 the sealing compound represent.

Fig. 3 shows a schematic section of an energy roof tile with an integrated solar cell, the tile having an edge over which the housing of the solar cell is placed and held and sealed in the rebate. The tile has a continuous recess under the solar cell, 1 representing the energy roof tile, 2 the solar cell, 3 the sealing compound and 4 the recess.

4 shows a schematic section of an energy roof tile with an integrated solar cell, the housing of the solar cell being shaped in such a way that it is pressed directly into the tile, 1 representing the energy roof tile and 2 the solar cell.

5 shows a schematic section of an energy roof tile with an integrated solar cell, the solar cell being mounted “floating”. I.e. the solar cell is only held and sealed on two sides, preferably right and left. There is a cavity under the solar cell through which rainwater can drain, 1 representing the energy roof tile, 2 the solar cell, 3 the sealing compound and 8 the cavity.

6 shows a schematic partial cross section of an energy roof tile with an integrated solar cell, the current-carrying elements being arranged facing downward, 1 the energy roof tile, 2 the solar cell, 3 the sealing compound, 4 the cutouts, 5 and 9 the current-carrying elements , 6 represent the tape and 7 the roof batten.

7 shows a schematic partial cross section of an energy roof tile with an integrated solar cell, the current-carrying elements being guided to the rear, 1 the energy roof tile, 2 the solar cell, 3 the sealing compound, 4 the recesses, 9 the current-carrying elements, and 7 represent the roof batten.

By means of suitable processes, the solar cell (2) can be shaped in such a way that, in addition to the properties of energy generation, it also meets the properties of a roof tile and thus forms the roof tile itself without the need for a further border.

The solar cell (2) can also be shaped like a hemisphere, which is mounted on the brick (1) so that the drainage of the rainwater is not hindered. This version has the advantage that one segment of the solar cell hemisphere is always directed against the main solar radiation.

The solar cell (2) can be built on the roof tile (1) with the help of a mechanism so that it e.g. according to the direction of the main sun

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

2nd

3rd

CH 682 831 A5

radiation can be turned. Straightening is done manually or automatically e.g. through small electric motors or electromagnets, which are controlled individually or from a control center.

Claims (8)

Claims 1. Energy roof tile, characterized in that the tile has at least one solar cell. 2. Energy roof tile according to claim 1, characterized in that the tile consists of clay or other natural substances. 3. Energy roof tile according to claim 1, characterized in that the tile consists of artificial materials. 4. Energy roof tile according to claims 1 to 3, characterized in that at least one solar cell is firmly connected to the tile. 5. Energy roof tile according to claims 1 to 3, characterized in that at least one solar cell is mounted mobile. 6. Energy roof tile according to claims 1 to 3, characterized in that at least one solar cell has at least one other level than the tile. 7. Energy roof tile according to claims 1 to 3, characterized in that the tile has at least one hemispherical solar cell. 8. Energy roof tile according to claims 1 to 3, characterized in that the whole tile consists of at least one solar cell. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd