DE202009018432U1 - solar collector - Google Patents

Abstract

Solar collector, in particular flat solar collector, comprising a glass cover (1), a foamed housing (2) in particular, an absorber (3) arranged therein, through which a solar fluid can flow, and insulation (4) on the side of the absorber facing away from the glass cover (1) (3), characterized in that the housing (2) and at least part of the absorber (3) is produced as an integrated component by shaping and / or primary shaping, and in that the absorber (3) is a prefabricated component when the foamed housing (2 ) is surrounded by the housing material.

Description

The innovation relates to a solar collector with a housing and disposed therein, can be traversed by a solar fluid absorber according to the preamble of the protection claim. 1

Solar collectors, in particular solar flat collectors are well known. Such solar collectors essentially consist of a glass cover, arranged therein, by a solar fluid permeable absorber and insulation on the side facing away from the glass cover side of the absorber. In this case, the absorber is designed as a channel through which the fluid can flow or as a fluid channel system. The fluid channel system in conventional embodiments comprises one or more tubes attached to respective brackets, for example, coated copper or aluminum sheets. The separately designed absorber is inserted into the solar collector housing, which also forms a separate assembly, and attached thereto. The absorber forms a separate unit. The cost of producing such a solar collector is considerable and therefore relatively expensive. In particular, the cost of materials and production times are high.

Also known are foamed housings, which are manufactured, for example, in a first manufacturing step and may even include preformed channels and structuring hydraulics, insulation, hydraulic connections, etc. In a second step, an absorber plate is then glued into the housing, for example, resulting in cavities in which the solar fluid can flow.

For reasons of robustness, especially because of the thermal expansion, the housing and the absorber are made of the same material. With other material combinations, there is otherwise a risk that leaks and thus leakage of the solar fluid may occur. In order to obtain a tightly sealed fluid space, the materials of the housing, the absorber plate and the adhesive must be precisely matched to one another with this concept. These include chemical resistance, thermal and mechanical properties, etc. This presents a challenge in development and manufacturing.

The innovation is based on the object to provide a solar collector to overcome the disadvantages of the prior art. In particular, it is an object of the innovation to provide a solar collector, which require a lower cost of materials and lower production times than before and also allow robustness and good flexibility.

According to the innovation this is solved by the objects with the features of the claims 1 and 8. Advantageous developments can be found in the dependent claims. The solar collector according to the invention is characterized in that the housing and at least a part of the absorber is produced by forming and / or prototyping as an integrated component and that the absorber is enclosed as a prefabricated, fluid-carrying component in the manufacture of the foamed housing from the housing material.

For this purpose, the absorber is selected in its embodiment as a prefabricated component from the group of heat exchangers, namely parallel or structured sheets or plates and / or films in the form of Plattenwärmeübertragern, individual, serially or parallel interconnected pipes in the form of tube bundle, harp and meander absorbers or flat-flow absorber. The material of the absorber as a prefabricated component is in its embodiment selected from the group of large-pore and open-cell foams and the plastic, rubber and / or ceramic materials and / or metals.

As a prefabricated component, the absorber has inherent stability. This is designed for the required pressure resistance during a foaming process in the manufacture of the housing so that it is not compressed. Alternatively, a waiver of the inherent stability is possible. Then the components can be subjected to water or air pressure which is as great as the pressure which builds up within the tool and the foaming process. For this purpose, the pressure during the foaming process is determined at a time or over the entire production process.

In a further embodiment, the absorber has openings spaced apart from one another, through which the foam material flows during a foaming process during production of the housing in order to form connecting webs for increasing the stability and to completely foam and encase the absorber. These additional connecting webs increase the stability of the structure in relation to the internal pressure prevailing in the hollow body during later operation.

In a preferred embodiment, an insulation is provided on the side facing away from the glass cover side of the absorber. In this case, the insulation is arranged at a distance below the absorber, so that flows during a foaming process in the manufacture of the housing of the foam material, at least in the peripheral edge region, between the absorber and insulation. In an additional, alternative Embodiment thereto, an insulation on the side facing away from the glass cover side of the absorber can be fixed thereto or adjacent thereto. The insulation with the absorber then forms a foamable unit.

The inventive method for producing a solar collector, in particular solar flat collector, is characterized in that the housing and at least a part of the absorber are produced by forming and / or prototyping as an integrated component and that the forming with a foaming process, in particular with a spray process for the manufacture of long or continuous fiber reinforced sandwich components in the manner of a composite spray molding process (CSM) is performed.

The foam method is carried out with at least one to be introduced into the open mold release agent for better demolding, wherein the release agent forms the weather protection on the component to be produced and wherein the coating within the mold, a so-called in-mold coating, in particular based on polyurethane (PUR ) is sprayed on the entire surface of the tool.

In a preferred embodiment, the foaming comprises the steps of introducing at least one release agent into at least one mold, then introducing at least one liquid foaming material, which is optionally provided with reinforcing materials such as glass fibers and / or gas-fiber mats, into the mold, then inserting the absorber, the insulation and / or other components to be foamed in the mold, and optionally the introduction of further layers of foaming material and reinforcing materials. Finally follows the shaping of the foam material as a finished component.

In a preferred embodiment, the foaming comprises the steps of introducing at least one release agent into at least one mold, then introducing at least one liquid foaming material, which is optionally provided with reinforcing materials such as glass fibers and / or gas-fiber mats, into the mold and then inserting one before a rigid foam processing method manufactured composite component of absorber and insulation. The absorber is at least partially enclosed by hard foam. If necessary, other components to be foamed can be inserted into the mold. In the same way, optionally further layers of foaming material and reinforcing materials can be introduced before, after curing, the last step is the opening of the molding tool for shaping the foaming material as a finished component.

In yet another embodiment of the method according to the invention, the foaming is carried out by a reaction injection molding method (RIM), wherein first the absorber, the insulation and / or other components to be foamed are inserted into the mold and then subsequently the foaming material in the closed tool is sprayed under pressure.

With the solar collector according to the invention and the process for its production, disadvantages according to the prior art are avoided and the robustness is increased. In addition to a lower cost of materials, the invention has a positive effect on the production since lower production times are necessary and a good flexibility in terms of structure and material properties is possible.

Due to the integrated construction, a compact construction is possible, which enables the production of very flat collectors, that is to say of flat collectors with a low collector height. Furthermore, can be saved by the integrated design up to 50% of the required in the prior art absorber material, usually the expensive material copper.

The sealing of the foam material against the solar fluid to corresponding absorber surfaces or inner surfaces is relatively simple and thus in a further step in the absorber prefabrication by infiltration, pouring or coating. In order for the plastic used to remain solar-fluid-resistant over the entire service life, for example water-resistant, all solar fluid-contacting surfaces in the absorber can preferably be infiltrated and / or coated with a protective coating, a so-called liner, or the like. The liner or a comparable substance can, for example, be sprayed on, dosed or applied in a dipping process.

Eliminated, however, due to the measures according to the invention, the application of an adhesive agent, such as an adhesive to connect items. Herin is a significant advantage, since no longer must be carefully applied or dosed on all bearing surfaces between the absorber parts and the housing adhesive to close fluid channels tight and form a functioning absorber. For this purpose, the production concept according to the invention provides prefabricated fluid-carrying elements or hollow bodies.

The drawings illustrate an embodiment of the innovation and its production and show in the figures:

1 FIG. 2 shows schematically a cross section through a solar collector according to the invention with insulation spaced from the absorber, FIG.

2 schematically a cross section through a solar collector according to the invention with an absorber fixed insulation and

3 schematically three different embodiments for an absorber in plan view and in section along the line SS, namely
3a as a porous foam body
3b as a combination of absorber tubes with at least one absorber plate
3c as a flat hollow body

The solar collector, in particular solar flat collector, consists essentially of a glass cover 1 , a foamed housing 2 , An arranged therein, can be traversed by a solar fluid absorber 3 and an insulation 4 on the from the glass cover 1 opposite side of the absorber 3 ,

The housing 2 and at least part of the absorber 3 are produced by forming and / or prototyping as an integrated component, wherein the absorber 3 as a prefabricated component in the manufacture of the foamed housing 2 is enclosed by the housing material, at least in the edge areas.

The absorber 3 can according to 3 be designed in various embodiments. As a porous foam body 31 according to , as a combination of absorber tubes 32 with at least one absorber sheet 33 according to or as a flat hollow body 34 according to ,

There are spaced breakthroughs 5 in the absorber 3 provided by the during a foaming process in the manufacture of the housing 2 the foam material flows to form connecting webs to increase stability and the absorber 3 enclose.

The insulation 4 is on the from the glass cover 1 opposite side of the absorber 3 intended. According to 1 this is at a distance below the absorber 3 so that during a foaming process in the manufacture of the housing 2 the foam material also between absorber 3 and insulation 4 flows. In contrast, according to 2 the insulation on the from the glass cover 1 opposite side of the absorber 3 fixed to this or arranged directly adjacent to this, so that the insulation 4 and absorbers 3 form a foamable unit.

Claims (7)

Solar collector, in particular solar flat collector, comprising a glass cover ( 1 ), a particular foamed housing ( 2 ), arranged therein, by a solar fluid permeable absorber ( 3 ) and an insulation ( 4 ) on the glass cover ( 1 ) facing away from the absorber ( 3 ), characterized in that the housing ( 2 ) and at least part of the absorber ( 3 ) is produced by forming and / or prototyping as an integrated component and that the absorber ( 3 ) as a prefabricated component in the manufacture of the foamed housing ( 2 ) is enclosed by the housing material. Solar collector according to claim 1, characterized in that the absorber ( 3 ) is selected as a prefabricated component in its embodiment from the group of heat exchangers, namely parallel or structured sheets or plates and / or foils in the form of Plattenwärmeübertragern, individual, serially or parallel interconnected tubes in the form of tube bundle, harp and meander absorbers or flat flowed through absorbers. Solar collector according to claim 1 or 2, characterized in that the material of the absorber ( 3 ) is selected as a prefabricated component in its embodiment from the group of large-pore and open-cell foams and the plastic, rubber and / or ceramic materials and / or metals. Solar collector according to one of claims 1 to 3, characterized in that the absorber ( 3 ) has an intrinsic stability as a prefabricated component, which has the required pressure resistance during a foaming process during manufacture of the housing ( 2 ) is designed. Solar collector according to one of claims 1 to 4, characterized in that the absorber ( 3 ) spaced-apart openings ( 5 ) during a foaming process in the manufacture of the housing ( 2 ) the foam material flows to form connecting webs to increase stability and the absorber ( 3 ). Solar collector according to one of claims 1 to 5, characterized in that an insulation ( 4 ) on the glass cover ( 1 ) facing away from the absorber ( 3 ) and that the insulation ( 4 ) at a distance below the absorber ( 3 ) is arranged so that during a foaming process in the manufacture of the housing ( 2 ) the foam material between absorber ( 3 ) and insulation ( 4 ) flows. Solar collector according to one of claims 1 to 6, characterized in that an insulation ( 4 ) on the glass cover ( 1 ) facing away from the absorber ( 3 ) is fixed to this or is arranged adjacent thereto, so that the insulation ( 4 ) with the absorber ( 3 ) forms a foamable unit.

Images