DE29703315U1 - Ventilated facade system - Google Patents

Description

Patent attorneys

g Dipl.-Ing.M.Bartels

Authorized representatives Patent attorneys ■ Lange Straße 51 · D-70174 Stuttgart at the European Patent Office

128 238

Thomas Ehret, Robert-Koch-Str. 28

71640 Ludwigsburg

Wolfgang Pusch

Hischstrasse 2
71254 Ditzingen

Ventilated facade system

The invention relates to thermal insulation panels and a thermal insulation composite system produced using such thermal insulation panels for attachment to masonry.

When attaching a thermal insulation composite system with thermal insulation panels to masonry, it is usual in the state of the art for a base batten or a base metal rail to be anchored vertically to the masonry to be clad. This base batten or base metal rail forms a profile onto which thermal insulation panels are anchored. Battens or metal profiles are screwed onto this crosswise in the form of a "counter batten". The top cladding is screwed onto these profiles as a final coating.

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The well-known thermal insulation composite system is relatively expensive both in terms of the material required and the processing time. This disadvantage is further exacerbated by the fact that not all masonry is vertical. Then the installation of leveling washers becomes necessary, which represents a great deal of additional effort.

Based on this state of the art, the present invention was therefore based on the object of providing thermal insulation panels that make it possible to create a thermal insulation composite system whose installation is less complex and therefore less expensive, yet effectively prevents the formation of thermal bridges.

This object is achieved by thermal insulation panels according to the features of claim 1 and a thermal insulation composite system according to the features of claim 3. Further preferred embodiments are specified in the subclaims.

The thermal insulation board according to the invention has at least one groove extending over the entire length or width of the insulation board. This at least one groove serves as a ventilation duct and preferably has a cross-section of approximately 50 - 300, preferably 50 - 200 cm ² /m. A cross-section of the grooves of approximately 50 cm ² /m preferably serves to form a lower air supply opening at the bottom of the masonry to which the thermal insulation boards are to be attached, and to form upper exhaust air openings. A cross-section of approximately 200 cm ² /m is otherwise preferred.

If a thermal insulation composite system is attached to a masonry using the thermal insulation panels according to the invention, this is done in such a way that the grooves are arranged on the side of the insulation panels facing away from the masonry. The thermal insulation panels are also attached to the

Masonry is arranged in such a way that the grooves of the insulation panels complement each other to form continuous grooves extending vertically along the masonry, thus forming complete ventilation ducts.

Such a thermal insulation composite system advantageously represents a thermal bridge-free fastening. There is no need to use profiles, which means that the material used and therefore the processing time required are much lower than with the systems known in the prior art. A further advantage is that in the case of non-vertical masonry, no complex compensation with washers is required, because with the system according to the invention, unevenness in the raw masonry can be compensated for by bead-edge bonding of the insulation panels.

In a further embodiment, it is possible for mats containing capillary tubes to be applied in the grooves of the insulating panels. If these capillary tubes arranged on the mats are filled with a liquid, in particular water containing an antifreeze, and are connected to collection and distribution lines, for example for supply to a low-temperature heating system or underfloor heating, then the capillary tube mats serve as a solar energy absorber system that is implemented in the ventilation ducts of the thermal insulation panels according to the invention. Such a solar energy absorber system is described for floors in the utility model application file no. 296 20 230.4 of Loba Bautenschutz GmbH & Co. KG. The application of the solar energy absorber system disclosed therein to the thermal insulation composite system according to the invention claimed here is analogous. Reference is made in full to the utility model application mentioned.

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The invention is explained in more detail below using exemplary embodiments. The single figure shows an incomplete view of a ventilated thermal insulation composite system according to the invention.

In the thermal insulation composite system shown in the single figure, a brickwork is designated 1. An adhesive 3 is applied to this brickwork, which serves to attach the thermal insulation panels 5 according to the invention. These thermal insulation panels 5 have several grooves 7 at defined intervals, each of which extends over the entire width of the insulation panel. The thermal insulation panels 5 are attached in such a way that the grooves 7 are aligned vertically on the brickwork 1, with the grooves 7 of insulation panels placed one above the other each adding up to form a continuous groove 7. This arrangement creates vertically arranged ventilation ducts across the entire width and height of the brickwork 1. In order to create functional ventilation, it is necessary that the ventilation ducts in the form of the grooves 7 have a cross-section of at least 200 cmVm. It has been found that a significant increase in the ventilation cross-sections beyond 200 cmVm does not bring any significant ventilation advantages. On the other hand, however, smaller cross-sections are ineffective in terms of ventilation and flow. For a functional ventilation system, it is also necessary that there is both a lower air supply opening on the floor and an upper air exhaust opening. These are not shown in the figure. They can have smaller ventilation cross-sections than within the thermal insulation composite system. However, the cross-section should be at least 50cm ² /m.

When the insulation panels 5 have been attached to the masonry 1 by gluing, a layer of shock-resistant and non-flammable mineral panels 9 follows. A filler 11 is applied to this, which has a glass side fabric insert, which can either be arranged only in the joint area.

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net, or depending on the binding agent base, applied over the entire surface. Finally, a finishing plaster 13 is applied.

If the masonry 1 to which the thermal insulation composite system is to be attached has unevenness and is therefore not vertical, the thermal insulation panels 5 are attached by means of bead edge bonding using the adhesive 3, thus compensating for the unevenness. Furthermore, it is possible to dowel the grooves 7, which serve as ventilation ducts, on non-load-bearing masonry 1 to ensure the stability of the thermal insulation composite system.

Basically, the influence of the wind through the joints can result in moisture in the thermal insulation composite system construction. The ventilated thermal insulation composite system according to the invention represents the best possible rain protection. It is important to note the driving rain protection of the building equipped with the thermal insulation composite system, which must also be guaranteed at the joint connections. This driving rain protection is regulated in DiN 4108, Part 3, whereby the thermal insulation composite system according to the invention fully guarantees the standardized driving rain protection required there.

DIN 18516 defines the impact load that a building can absorb and the minimum is specified as 6N/m. The thermal insulation system according to the invention can also absorb this force.

In a modified embodiment, it is also possible to supply the thermal insulation panels 5 according to the invention as a system unit. In this case, these thermal insulation panels 5 already have the impact-resistant mineral panels 9 glued to them. The filler 11 with or without a glass silk fabric insert can also already be present. Then, by attaching the

The thermal insulation composite system is already complete as a whole by means of the thermal insulation panels 5 delivered ready for use by the Kieber 3.

In a further modification of the thermal insulation composite system according to the invention, not shown in the single figure, it is also possible to attach mats with capillary tubes in the grooves 7. These are filled with a liquid, preferably with water containing antifreeze. The mats provided with the capillary tubes can be used as a solar energy absorber system. This is based on the principle that the heating of the masonry 1 containing the thermal insulation composite system caused by solar radiation is used to heat the water in the capillary tubes. The capillary tubes themselves are in turn connected to collecting lines, and the water can be fed to lines of a heat exchanger of a low-temperature heating system or, for example, an underfloor heating system by a pump driven by an electric motor. The capillary tube system is also provided with return and distribution lines.

Details are set out in the utility model application file no. 296 20 230.4 of Loba Bautenschutz GmbH & Co. KG. Although this application concerns a solar energy absorber system for floors, it can be implemented analogously here. Reference is made to the utility model application in full.

Claims (5)

-01 - Protection claims 1. Thermal insulation board which has at least one groove (7) extending over the entire length or width of the insulation board (5). 2. Thermal insulation panel according to claim 1, characterized in that the groove (7) has a cross section of approximately 50 - 300, preferably 50 - 200 cm². 3. Thermal insulation composite system for attachment to a masonry (1), which has thermal insulation panels (5) according to claim 1 or 2, wherein the grooves (7) are arranged on the side of the insulation panels (5) facing away from the masonry (1). 4. Thermal insulation composite system according to claim 3, characterized in that the thermal insulation panels (5) are arranged on the masonry (1) in such a way that the grooves (7) of the insulation panels (5) each complement each other to form continuous grooves (7) extending vertically on the masonry (1). 5. Thermal insulation composite system according to claim 3 or 4, characterized in that mats having capillary tubes in the form of a solar energy absorber system are installed in the grooves (7).