DE29517189U1 - Housing for solar collectors made of a porosified lightweight building material - Google Patents

Description

L. Voit, F. Warmuth: Solar collector housings - 2 -

Description

Housing for solar collectors made of a porous lightweight material molded body.

Solar collectors are used to use solar energy to heat buildings, to heat water and to generate electricity. Solar collectors of today's design essentially consist of an absorber for absorbing and converting solar energy, a transparent pane on the front, insulation on the back and a housing. The housing has the task of ensuring that the components are held together, in conjunction with the insulation, preventing the radiation of the absorbed energy and protecting the components from harmful external influences.

There are various designs known for solar collector housings:

• Deep-drawn metal housings made of aluminum or stainless steel. Aluminum should no longer be used in construction for ecological reasons. Stainless steel results in a high housing weight.

• Assembled housings made of aluminum, steel or plastic profiles with flat fillers such as aluminum sheet or plastic panels. The assembly of individual parts can be complex. A construction made up of many individual parts can be unstable. Aluminum and various types of plastic should no longer be used in construction for ecological reasons.

• Housing made of fiber-reinforced plastics. Fiber-reinforced plastics cannot be recycled and should therefore be avoided in construction.

• Various special solutions, which usually date back to the time of technology introduction and the prototype phase (wooden frames, steel frame constructions, etc.) as well as vacuum collectors for hot water production, which do not represent economical solutions in terms of their manufacturing and maintenance costs.

For the rear insulation, insulating materials from the construction industry are usually used, such as mineral fiber mats, foam plastics, cellulose and wool insulation materials. Mineral fiber mats are classified as carcinogenic. Foam plastics should be avoided in construction for ecological reasons. Cellulose and wool insulation materials can be attacked by moisture and animal or plant pests.

A housing design that also takes on the function of rear insulation is not known. The front panel is usually connected to the housing molding with metal, plastic or rubber profiles as well as with silicone adhesive beads.

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L. Voit, F. Warmuth: Solar collector housings - 3 -

The invention specified in claim 1 is based on the problem of creating a solar collector housing with a low weight, which consists of a material with good thermal insulation, the materials of which can be easily recycled and has integrated functional elements. In addition, the number of components required for solar collectors is to be reduced, thus reducing the manufacturing costs for solar collectors.

These problems are solved with the features listed in claim 1.

The invention ensures that the components of the solar collector are connected to one another and that the internal components, such as the absorber, are protected from external influences. The housing is advantageously made from porous lime silicate as described for example in DE 25 26 258 C2, DE 26 09 099 C2 and EP 0 038 552 Bl. It is also conceivable to use foam concrete as described for example in WO 82/03622 or other porous mineral lightweight building materials. The use of porous mineral building materials leads to a low housing weight, since a density of 130 kg/m ³ to 400 kg/m ³ is achieved for these building materials. The high air or gas content results in good thermal insulation. The integration of functional, connecting and handling elements by appropriate design of the mold reduces the number of required components. The high rigidity of the mineral building material prevents major deformations caused by the weight of the collector or external forces and reduces the risk of the front panel breaking due to deformations. Non-mineral functional elements such as crane hook eyes can be integrated as insert elements during the primary forming process. Furthermore, the use of mineral lightweight building materials enables the housing mold to be mortared and colored in almost any desired way. To achieve different strengths within the housing mold block, housing mold blocks can be made from raw material with different densities as described in WO 82/03622. Increased strength, which at the same time also brings with it a higher density and should therefore not be used where possible, can be advantageous for the connecting elements and the outer layer.

An embodiment of the invention with a different housing material is specified in claim 2.

Instead of the mineral lightweight material, it is also possible to use another porous lightweight material such as polymer foam or aluminum foam to manufacture the housing mold. This design can lead to a lower collector weight and higher energy efficiency.

L. Voit, F. Warmuth: Solar collector housings - 4 -

An advantageous embodiment of the invention is specified in claim 3.

The further development according to claim 3 enables the front glass pane to be attached simply, quickly, tightly and aesthetically by gluing the pane to the housing molding using a permanently elastic bonding system. The elasticity of the bond prevents the components from becoming distorted and thus potentially damaging the pane. The bonding can be carried out using the processes known from automotive production for bonding window panes.

A further advantageous embodiment of the invention is specified in claim 4.

The further development according to claim 4 enables an advantageous distribution of the joining and connection forces between the front pane and the housing molding. A rubber or plastic profile with a profiled cross-section, to which the front pane is glued, can thus be firmly anchored in the housing molding. It is advisable to integrate the profile as an insert element during the initial formation of the housing molding.

A further advantageous embodiment of the invention is specified in claim 5.

The further development according to claim 5 enables the solar collector to be integrated into the roof covering. The conventional effort for the sheet metal can be significantly reduced by the interlocking of the housing molding and roof tiles. It is also conceivable to connect several solar collectors to form a closed field using similarly designed connecting elements.

An embodiment of the invention is explained with reference to Figures 1 to 4. They show:

Fig. 1 the solar collector housing including the exemplary components absorber (2) and front panel (1),

Fig. 2 a section through the housing molding (3) with the fastening of the front panel (1) carried out as an adhesive (7),

Fig. 3 a section through the housing molding (3) with the fastening of the front panel (1) designed as a rubber or plastic profile (8),

Fig. 4 a section through the housing molding (3) with lateral connecting elements (9) and (10).

The figures show the solar collector housing with housing molding (3), front panel (1), and integrated exemplary connecting elements (4). The connection bushings (6) enable the connections (5) of the absorber (2) to be passed through. The front panel (1) is connected to the housing with the adhesive (7) or alternatively with the plastic/rubber profile (8).

L. Voit, F. Warmuth: Solar collector housings - 5 -

the housing molding (3). The design of the profile (8) is chosen here so that a uniform introduction of force into the housing molding is achieved. The sections through the housing molding shown in Fig. 2 and Fig. 3 show an exemplary, centrally mounted stiffening rib. The side connecting elements according to Fig. 4 enable the housing molding and the roof covering to engage in a positive fit. Different types of connecting elements are possible for different roof coverings. If the side connecting elements are designed so that they do not protrude beyond the actual housing molding, it is possible to connect several solar collectors to form a closed field.

Claims (5)

L. Voit, F. Warmuth: Solar collector housings -1 - Protection claims 1. Housing for solar collectors made of a porous lightweight material molded body for accommodating energy absorbers, in particular for hot water preparation and for generating electrical current, characterized, • that the housing molded body (3) consists of a molded body cast in a mold or of a machined molded body, • that the housing molding (3) is made of a mineral porous lightweight material , • that the housing molding (3) optionally contains an integrated reinforcement to increase strength, • that the housing body (3) integrates functional, connecting and handling elements (insulating effect, connection leadthrough (6), fastening connections (4), recessed grips, crane hook eyes, etc.). 2. Housing for solar collectors according to protection claim 1
characterized, • that instead of the mineral porous lightweight material, another porous material on a metallic or organic basis is used. 3. Housing for solar collectors according to protection claim 1 or 2
characterized, • that the front panel (1) is attached to the housing molding (3) with an elastic adhesive (7). 4. Housing for solar collectors according to protection claims 1 to 3
characterized, • that the front panel (1) is attached to the housing molding with a rubber or plastic profile (8) embedded in the housing molding. 5. Housing for solar collectors according to protection claims 1 to 4
characterized, • that the housing molding contains connecting elements on one or more outer sides for the positive connection with a roof covering or with other housing moldings.