DE29610225U1 - Plate absorber - Google Patents

Description

Plate absorber

The invention relates to plate absorbers, in particular for solar energy use via concrete components, with the features of the preamble of claim 1.

Solar energy can be used for hot water preparation and space heating using collectors. The collectors are arranged for this purpose on roofs, facades or walls. Direct sunlight, diffuse light, rain and wind bring heat into the collectors and this heat is then transferred to consumers via heat exchange devices using a liquid heat exchange medium.

It is known to use metal collectors covered with glass to heat domestic water. Such collectors are usually mounted on pitched roofs and have the disadvantage of being a foreign body that impairs the aesthetics of the entire building.

Collectors made of glass fiber reinforced concrete are also well known (see Civil Engineer 1995, Issue 10), which can be integrated into a building as a component without affecting the aesthetics as a foreign body. The collectors made of glass fiber reinforced concrete allow thin-walled constructions with high bending and impact strength and enable temperatures of the heat exchange medium of approx. 55* C without additional aids such as heat pumps. Since these collectors are also integrated into roof coverings, high requirements must be met with regard to tight installation.

The object of the invention is to create plate absorbers made of glass fiber concrete that can be reliably sealed against each other.

The problem is solved with plate absorbers with the features of claim 1. Advantageous embodiments of the invention are presented in the subclaims.

According to the invention, plate absorbers are provided with profile plates that are arranged sideways and lengthways. The profile plates are of course manufactured without asbestos. Corrugated profile plates of the plate absorbers according to the invention can, for example, be easily integrated into existing corrugated plate components for roofs or facades without affecting the aesthetics. The overlapping sides of the profile plates ensure absolute tightness with minimal assembly effort. The profile plates of the plate absorbers according to the invention have an upper side facing the environment, preferably in a way that allows optimal incidence of the sun's rays. Pipes for transporting a liquid heat exchange medium into a heat exchange system are provided in the plate absorbers according to the invention. The pipes are held by their casings on profile peaks or profile flanks of the profile plates. The plate absorbers according to the invention enable multifunctional applications as integrated components and fulfill the function of sealing and thermal insulation and, as absorbers, contribute to the conservation of resources and the reduction of CO ₂ emissions, since with the inventive plate absorbers, such high temperatures of the heat exchange medium can be achieved without any additional aids that, in favorable weather, service water can be made available or buildings can be heated, 5 so that the burden on the environment is reduced overall.

According to a preferred embodiment of the plate absorbers according to the invention, an underside of the profile plates is

a thermal insulation, which preferably contains mineral wool ■ and/or polystyrene. The profiled panels heat up considerably when exposed to sunlight due to the heat build-up resulting from the excellent thermal insulation. 5

According to a preferred embodiment of the plate absorbers according to the invention, the profile plates are arranged to form a roof covering, so that a roof covered in this way acts as a heat source for the building.

According to a further preferred embodiment of the plate absorbers according to the invention, glass fiber concrete is contained in the profile plates, which, as thin-walled constructions, have high bending and impact strength and enable heat exchange medium temperatures of approx. 55* C without additional aids, such as heat pumps. The profile plates are preferably approx. 6-12 mm thick and preferably have a dark coating on the surface. Such profile plates could be designed in accordance with the specifications of Euronorm 494.

The casings of the tubes of the plate absorbers according to the invention preferably contain glass fiber reinforced concrete like the profiled plates, so that the profiled plates and the casings have the same thermal expansion coefficients and the same dilatation behavior.

The tubes of the plate absorbers according to the invention have a 5 - 10 mm coating, so that there is a good flow of heat from the profile plates to the liquid heat exchange medium. The geometry of the tubes can be chosen as desired, for example the cross-section can be round or oval.

According to a further inventive design of the plate absorbers, the heat exchange system is provided with storage tanks and/or heat exchangers for the liquid heat exchange medium for domestic water heating.

According to a further inventive design of the plate absorbers, a heat pump is arranged in the heat exchange system for the mono-energetic heating of a building equipped with such plate absorbers. 5

The invention is illustrated below using exemplary embodiments. They show:

Fig. 1 is a schematic view of the plate absorbers according to the invention made of corrugated profile plates and with tubes in the profile mountains and

Fig. 2 is a schematic view of the plate absorbers according to the invention made of corrugated profile plates and with tubes on the profile flanks.

Fig. 1: A plate absorber 1 has corrugated profile plates 2. The corrugated profile plates 2 are made of asbestos-free glass fiber concrete, i.e. concrete that contains alkali-resistant glass fibers. The thickness of the corrugated profile plates 2 is approx. 6-12 mm. Pipes 5 are preferably non-positively attached to profile peaks 3 of the corrugated profile plates 2 by means of their casings 4 containing glass fiber concrete. The pipes 5 contain a liquid heat exchange medium and are connected to storage tanks and/or heat exchangers of a heat exchange system (not shown). The pipes 5 are made of plastic or metal and are approximately 5 - 10 mm thick with a sheath and are each mounted with the not yet fully cured sheath 4 made of glass fiber concrete to the profile mountains 3 of the wave-shaped profile plates 2, whereby the not yet fully cured sheath 4 made of glass fiber concrete acts like an adhesive and connects pipe 5 to the profile plate 2 in a force-fitting manner.

The wave-shaped profile plates 2 preferably lie on a thermal insulation made of mineral wool or polystyrene (not shown).

The plate absorbers 1 can be tightly connected to the sides and lengthways with similar plate absorbers 1 or with profile plates 2 without collector function. A falling profile flank 7 of a wave-shaped profile plate 2 is placed over a rising profile flank 8 of a wave-shaped profile plate 2 and the geometric conditions, in conjunction with gravity, ensure that the connection of the wave-shaped profile plates 2 is absolutely tight.

Fig. 2: Corresponding features are designated with the reference numerals from Fig. 1. On a plate absorber 1 with a wave-shaped profile plate 2 made of glass fiber reinforced concrete, pipes 5 are attached to profile flanks 7 of the wave-shaped profile plate 2 by means of their sheaths containing glass fiber reinforced concrete. The pipes 5 contain a liquid heat exchange medium.

No pipe 5 is arranged on sloping profile flanks 7 of a wave-shaped profile plate 2, which are placed over a rising profile flank 8 of a wave-shaped profile plate 2.

The heat exchange system can be equipped with a heat pump to increase the temperature of the liquid heat transport medium, so that the heat exchange system is suitable for mono-energetic heating of buildings.

Arranged on a foundation wall coated with bitumen, the plate absorber 1 according to the invention can, in addition to providing mechanical protection and a drainage effect, also take on the function of an absorber in the ground when properly designed in new buildings.

Claims (8)

Expectations 1. Plate absorber (1) with profile plates (2), which are arranged laterally and longitudinally, and pipes (5) for transporting a liquid Heat exchange medium in a heat exchange system, wherein the tubes (5) are held by means of their casing (4) on profile peaks (3) or flanks (7) of the profile plates (2).
10 2. Plate absorber (1) according to claim 1, characterized in that the profile plates (2) are equipped with thermal insulation. 3. Plate absorber (1) according to claim 1, characterized characterized in that the profile plates (2) are arranged to form a roof covering. 4. Plate absorber (1) according to claim 1, characterized in that the profile plates (2) Contains glass fibre reinforced concrete. 5. Plate absorber (1) according to claim 1, characterized in that the casings (4) contain glass fiber concrete. 6. Plate absorber (1) according to claim 1, characterized in that the tubes (5) have a casing (4) of 5-10 mm. 7. Plate absorber (1) according to claim 1, characterized in that the heat exchange system is provided with storage and/or heat exchangers for the liquid heat exchange medium. 8. Plate absorber (1) according to claim 7, characterized in that in the heat exchange system a heat pump is arranged.