AT509724A4 - FAÇADE ELEMENT FOR A SOLAR FAÇADE - Google Patents

Description

* · - 1 -14902

The present invention relates to a facade element for a solar façade with an absorber fin, a pipe for guiding a heat transfer medium and a heat transfer sheet, which is connected to the tube and at least partially rests flat against the absorber blade.

In order to use the solar radiation thermally, often covered solar panels are used. These have a high efficiency in selective coating, since the radiation losses due to the cover are relatively low. A disadvantage of this type of Sonnenkoilktoren that economically only rectangular single panels can be made, which are arranged for example on the roof of buildings. The architectural integration of such collectors is difficult in many cases. In addition, only a portion of the available space can always be usefully used, because given standard dimensions remains in peripheral areas unused parts of roofs or facades remain.

To avoid these disadvantages, so-called solar facades have been developed. These are building envelopes that are composed of façade elements that assume the function of a solar collector. As a rule, these are elongated elements which can be largely cut to length in the longitudinal direction and with which a suitable external building surface can be completely or largely completely covered.

Although a facade element in the sense of the present invention primarily means a cover for a vertical building wall, the facade element according to the invention is also fundamentally applicable to inclined surfaces such as roofs.

In DE 198 59 308 A a facade element is described, which has an absorber lamella, which represents the outer shell of the building. Inside is attached to this absorber lamella by gluing a heat transfer sheet to which a tube is welded, via which a heat transfer medium dissipates the heat. Balance as an adhesive a material with relatively good heat transfer behavior is used, the efficiency of such facade elements is very modest. In addition, due to the relatively strong temperature differences in different distribution points to very different thermal expansion of the individual components, so that the bonding over time at least partially dissolves, which has a further serious deterioration of heat transfer result. * «* *« ··· * * * ♦ * a «« * ι t m * * - 2 -

Another known solution with a very poor heat transfer behavior between the absorber blade and the tube is described in DE 196 15 228 C. The tube is only stored locally on brackets, so that only minimal contact between the components is given.

Object of the present invention is to avoid these disadvantages and to provide a facade element having a high efficiency, which comes close to the achievable with solar panels covered efficiencies. In any case, the efficiency should be well above the known absorber systems.

According to the invention it is provided that the heat transfer sheet is fastened by a clamping connection to the absorber blade.

It is essential to the present invention that the contact between absorber blade and heat transfer plate is maintained even with very different thermal expansions of the individual components. These two components can move in the longitudinal direction against each other so that impermissible stresses are avoided. The heat transfer sheet surrounds the pipe over a little more than half its circumference and holds this clamped with intimate contact. Away from the tube, two strip-like projections extend in opposite directions, which abut essentially on the entire surface of the absorber lamella. This ensures a large-scale efficient heat transfer.

It has been found that in the embodiment according to the invention optimum heat utilization is given when the heat transfer sheet is fixed in the lower region of the absorber lamella. The lower part of the absorber lamella in the installation position reaches in the meantime! the highest temperatures, so that here correspondingly high efficiencies can be achieved.

Furthermore, it is of particular advantage if the absorber lamella has a fastening portion which is intended to fix the absorber lamella to a substructure, above which has a downwardly open groove to hold a further absorber lamella arranged underneath, the groove pointing outwards is limited by a projection, which then merges into a visible surface, which has a retaining lug on its upper side. In this way, the assembly of the absorber blades can be done efficiently from top to bottom.

Be particularly favorable, it has been found when the heat transfer sheet of terminals between the projection of the absorber blade and a

Holding projection is held. The retaining projection protrudes from the inside of the absorber blade and limits the movement of the heat transfer sheet upwards. The projection may be formed for example by impressions of the absorber sheet, but it is also possible to apply the projection by gluing or welding.

Particularly preferably, the tube is arranged immediately above the projection forming the lower edge of the absorber lamella in order to optimally utilize the prevailing temperature here.

The clamping connection can be particularly favored in particular in that the tube is arranged directly in the region of an outwardly convex longitudinal bend of the absorber lamella.

A further increase in the efficiency is achieved in that the tube and at least a portion of the heat transfer sheet is surrounded by an insulating element received in the absorber blade. It is particularly advantageous subsequently when the heat transfer sheet rests over a portion of the absorber blade whose length I is between 20% and 40% of the total height h of the absorber blade. To reduce the radiation losses can also be provided a cover that covers the absorber blade at least partially. This cover may be formed, for example, as a perforated plate.

In further consequence, the present invention will be explained in more detail with reference to the embodiment variants which are shown in the figures. Show it:

Fig. 1 and Fig. 2 are each a section through an embodiment of the present invention.

Fig. 1 shows schematically the structure of a wall element attached to a facade element. On a masonry 1, an insulating layer 2 is attached, which is covered to the outside of the building by a ventilated cover 3. The facade element 4 consists of an absorber lamella 5 and of a heat transfer plate 6, which rests on the inner side of the absorber lamella 5 by clamping. The heat transfer plate 6 clampingly encloses a tube 7 which dissipates the heat via a heat transfer medium such as water. In the interior of the absorber blade 5, a formed as a molded part insulating 8 is arranged, which in particular the tube 7 umschießt.

The absorber blade 5 has a mounting portion 9, which represents the lowest part of the absorber blade 5 in the installed position. Here the absorber blade 5 is fastened with screws 10 on the substructure. Above is a downwardly open groove 11, which is intended to hold another absorber lamella 5 located underneath. On the outside, this groove 11 is delimited by a projection 12, which represents the lower section of the outer visible surface 13 of the absorber lamella 5. In its upper portion, the absorber blade 5 has a retaining lug 14 which is received in the groove 11 of the overlying Absorberlamelle 5, inside a heat transfer plate 6 is arranged clamping in the lower portion of the absorber blade 5, which is supported on the projection 12 and upwards is held by a retaining projection 15. The retaining projection 15 may be formed, for example, by stampings, which are impressed from the outside in the manufacture of the absorber blade 5 and project inwardly, as shown in Fig. 1. However, it is alternatively possible in the same way to produce this retaining projection 15 by gluing or welding a corresponding piece of sheet metal.

The heat transfer plate 6 consists of an upper rib 16 and a lower rib 17 and a Ω-shaped portion 18 which is arranged between these ribs 16, 17 and encloses the tube 7. The length 1 of the portion of the absorber blade 5 against which the heat transfer sheet 6 rests is about 30% of the total height h of the absorber blade 5, and may preferably be in a range between 20% and 40%.

The visible surface 13 of the absorber blade 5 has in the longitudinal direction an outwardly convex longitudinal crease 19 which is provided approximately in the region of the tube 7. In installation position this Längsknicks 19 limits an approximately vertical lower portion 20 of the visible surface 13 against an obliquely upwardly inclined upper portion 21 of the viewing surface 13. In correspondence to this obtuse angle between the sections 20 and 21 are also the ribs 16, 17 of the heat transfer sheet. 6 inclined to lie close to the absorber blade 5.

The absorber lamella 5 and the heat transfer plate 6 are made of aluminum, wherein the absorber lamella 5 has on the outside a selective coating, which is optimized in a manner known per se to absorb a maximum of radiation and at the same time to minimize the emission losses. Outside the absorber lamellae 5 are covered by a cover made of a perforated plate 22, which is attached on the one hand for aesthetic reasons and on the other hand additionally reduces the radiation losses. «I * *» i * * * * * • »t *» · · * »* · • | I · »> ·· ·· »- 5 -

The embodiment of Fig. 2 differs from that of Fig. 1 in that the perforated plate 22 is not carried out here and that the heat transfer plate 6 is clamped in projection 12.

The present invention makes it possible to represent solar façades, which have high efficiencies, are shapely and according to the architecture of the building are adaptable within wide limits.

Claims (10)

1. facade element for a solar façade with an absorber lamella (5), a pipe for guiding a heat transfer medium and with a heat transfer plate (6), 4 * * * * * * which is connected to the tube (7) and at least partially rests flat against the absorber blade (5), characterized in that the heat transfer plate (6) is clamped to the absorber blade (5). 2. Facade element according to claim 1, characterized in that the heat transfer plate (6) in a lower region of the absorber blade (5) is fixed. 3. Facade element according to one of claims 1 or 2, characterized in that the absorber lamella (5) has a fastening portion (9) which is intended to fasten the absorber lamella (5) to a substructure (3), about a downwards open groove (11) to hold a further absorber lamella (5) arranged therebelow, wherein the groove (11) is bounded outwardly by a projection (12), which subsequently merges into a visible surface (13) has a retaining lug (14) on its upper side. 4. Facade element according to claim 3, characterized in that the heat transfer sheet (6) is clamped between the projection (12) of the absorber blade (5) and a holding projection (15) is held. 5. Facade element according to one of claims 3 or 4, characterized in that the tube (7) is arranged directly above the projection (12). 6. Facade element according to one of claims 1 to 5, characterized in that the tube (7) is arranged directly in the region of an outwardly convex longitudinal nick of the absorber blade (5). 7. Facade element according to one of claims 1 to 6, characterized in that the tube (7) and at least a portion of the heat transfer sheet (6) by a in the absorber blade (5) accommodated insulating element (8) is surrounded. 8. façade element according to one of claims 1 to 7, characterized in that the heat transfer sheet (6) over a portion of the absorber blade (5) is applied, the length I between 20% and 40% of the total height h of the Absorberiamelle (5). 9. Facade element according to one of claims 1 to 8, characterized in that the absorber blade (5) is at least partially covered by a cover (22). 10. Facade element according to claim 9, characterized in that the cover element (22) is designed as a perforated plate. A-1150 Vienna. Mariahilfer Gäru * l 39/17 Tel .: < * 431) «* 2» 9 33-0 Fax; (+43 I) 892 89 333 2010 06 08 Ba / Ec