DE19653672A1 - Anchor attaching rear-ventilated outer wall cladding to structural support wall - Google Patents

Abstract

The device attaches a rear-ventilated outer wall cladding onto a structural wall. The anchors (18) interlock on one side with the structural wall (10) and on the other with the cladding. They are thermally insulated from the structural wall. Preferably low-conductivity plastic is used in the construction of the anchors, e.g. polyurethane or polyvinyl chloride. A component of the anchors comprises silicone rubber, or it is used in a casing. The anchor is made of stainless steel.

Description

The invention relates to a device for fastening against a ventilated outer wall covering, with the features mentioned in the preamble of claim 1.

Devices of the generic type are known. These have a substructure that one on the one hand non-positively with the outer wall covering and on the other hand, with a load-bearing wall connected is. The substructure itself exists usually from anchor profiles attached to the load-bearing Wall are non-positively attached and by means of which the outer wall cladding directly or via further con structural elements is held. This will ge ensures that the outer wall cladding on the tra wall is attached and everyone acts on it the forces, especially the dead weight and wind forces, worn out through the anchor into the load-bearing wall can be tet. Due to the substructure also a space between the outer wall dung and the load-bearing wall, which up to  an external ventilation gap with a heat insulation is provided. This leads to the end formation of a thermally insulated outer wall. With the be Known devices is disadvantageous that the the insulation penetrating anchors a heat bridge from the outer wall covering to the load-bearing wall is created. As a result, the desired thermal insulation Mungseffekt partially canceled, so that un desired heat losses occur.

The invention is therefore based on the object To create device of the generic type that is simply constructed and by means of which the heat losses are reduced.

According to the invention, this object is achieved with a Vorrich tion with the features mentioned in claim 1 ge solves. Because the anchor from the load-bearing wall is thermally separated, is used in the construction additional thermal resistance integrated a heat flow from the supporting wall to the outer wall clothing or the ventilation gap or vice versa about the anchor through the thermal insulation he significantly reduced. Due to the thermal separation a significant reduction in thermal conductivity and thus the heat loss of the whole invented outside device according to the invention structure possible.

In a preferred embodiment of the invention is provided see the anchor on its the supporting wall too facing an element from a thermal  Insulation material (material with low thermal conductivity ability). This element prevents one direct contact of the anchor with the load-bearing Wall so that a heat flow over the thermal isola tion material is significantly reduced. Especially is preferred if this element from a thermi insulation material firmly connected to the anchor is so that when assembling the outside wallcovering does not result in any additional effort. It is however also in the sense of the invention if that Element as a single part during assembly between the anchor and the load-bearing wall is inserted. Of course, the elements have for the Be any necessary breakthroughs.

Furthermore, in a preferred embodiment of the invention provided that the at least one anchor with a Material with low thermal conductivity is encased. This advantageously ensures that result in at least two sections representing the heat forward resistance between the supporting wall and the outer wall covering or the air gap increase per anchor. The effectiveness of thermal This further increases separation.

In addition, in a preferred embodiment Invention provided that the element or order sheathing from a low thermal conductivity having plastic, preferably polyurethane or polyvinyl chloride. This will make it in possible in a simple manner by means of suitable generally known and easy to do  Plastic injection processes the at least one anchor to be provided with the element or the casing.

In a further advantageous embodiment of the invention it is provided that the element or the casing has a minimum thermal resistance depending on the thickness and the thermal conductivity of ≧ 0.2 (m ² K) / W. With an element or a casing with such a minimum thermal resistance, it is possible to significantly reduce the additional heat losses caused by the substructure.

Finally, in a preferred embodiment, the Er provided that the surface of the at least refer to an anchor profile in the area of the element a profile in the area of the casing tion. As a result, the bond between the element and the sheathing and the anchor profile improved so that on the one hand an effective thermal separation results and this on the other hand adhere firmly to the at least one anchor profile.

He further preferred embodiments of the invention give up from the rest, in the subclaims mentioned features.

The invention is described in the following play closer with the accompanying drawings explained. Show it:

Figure 1 is a perspective view of a thermally insulated, ventilated outer wall construction in a partial view.

Figure 2 is a sectional view of the device according erfindungsge in a first embodiment.

Fig. 3 is a sectional view of the device according to the invention in a second exemplary embodiment and

Fig. 4 is a sectional view of the device according to the invention in a third exemplary embodiment.

In Fig. 1 is a perspective partial view of a load-bearing wall 10 is shown, to which an outer wall covering 14 is fastened by means of a substructure generally designated 12. The sub construction 12 consists of holding profiles 16 and anchor profiles 18th The holding profile 16 is designed as a continuous square profile, left representation in Fig. 1, or continuous hat profile, right representation in Fig. 1. The anchor profiles 18 are formed by substantially U-shaped profiles, the position either as a fixed point anchor, in Fig. 1 upper Dar position, or floating point anchors, in Fig. 2 bottom view. The holding profiles and anchor profiles 16 and 18 are non-positively connected to one another via the rivets 20 indicated here.

The holding profile 16 carries the outer wall cladding 14 , which can consist, for example, of individual facade elements. The outer wall cladding 14 is also non-positively connected to the holding profile 16 by means of suitable rivets 20 . The anchor profiles 18 are non-positively connected to the load-bearing wall via fastening means 22 . The fastening means 22 are formed, for example, by screws which are screwed into corresponding dowels introduced into the supporting wall.

The remaining space 24 between the outer wall cladding 14 and the wall 10 , the depth of which results from the dimensions of the holding profiles and anchor profiles 16 and 18 , is partially filled with a thermal insulation material, not shown in FIG. 1. This heat insulating material is attached to the tra constricting wall 10 in a suitable manner, so that a space between the clothing and the thermal insulating Außenwandbe 14 25 (ventilation gap) remains ver serving a rear ventilation. Overall, a rear-ventilated, heat-insulated outer wall is thus implemented. The anchor profiles 18 penetrate the thermal insulation material.

The illustration in Fig. 1 is only intended to serve as a general explanation. According to further exemplary embodiments, a different design of the substructure 12 is conceivable. This can also be formed in one piece, for example, the holding profiles and anchor profiles 16 and 18 have other profile cross sections. Instead of the fastening means 22 designed as screws, other suitable fastening means can also be provided. The same applies to the rivets 20 . It is crucial that the outer wall cladding 14 is connected via the substructure 12 in a force-locking manner to the wall 10 .

In Figs. 2 to 4 are each a cross section in the region of a retaining profile 16 and anchor profile shows 18 ge. Figs. 2 to 4 illustrate the configuration of the anchor profile 18 according to the invention. The same parts as in FIG. 1 are each provided with the same reference numerals and are not explained again. For reasons of clarity, the rivets 20 and the fastening means 22 have not been shown in FIGS. 2 to 4.

In Figs. 2 to 4 it is clear that the anchor section 18, the thermal insulation penetrating 26th Between the anchor profile 18 and the load-bearing wall 10 , an intermediate layer 28 made of a material with a low thermal conductivity and sufficient strength for structural purposes is arranged. The intermediate layer 28 is formed over the entire height and width of the anchor profile 18 . The intermediate layer 28 sits a thickness d1.

The arrangement of the intermediate layer 28 , it is sufficient that a total thermal resistance between the load-bearing wall 10 and the Außenwandbeklei extension 14 from a series circuit of a thermal resistance through resistance of the anchor profile 18 and the thermal resistance of the intermediate layer 28 is formed. Since the thermal resistance of the intermediate layer 28 is very high, the overall thermal resistance of the armature 18 was also very high, so that the outer wall cladding 14 is thermally separated from the load-bearing wall 10 . A heat flow through the substructure 12 , that is to say in particular through the anchor profiles 18 , from the load-bearing wall 10 to the outer wall covering 14 or vice versa is thus considerably reduced. Thus, a heat bridging, which would partially cancel the function of the thermal insulation 26 again, almost prevented via the Ankerpro file 18 .

The intermediate layer 28 can for example consist of polyurethane or polyvinyl chloride. To improve the adhesion of the intermediate layer 28 to the anchor profile 18 , the latter, on its leg facing the intermediate layer 28 , profiles not shown in detail here, for example ribs or the like, aufwei sen, which allow an intimate bond. The inter mediate layer 28 is dimensioned such that it clearly has a minimum thermal resistance depending on its thickness d1 and its thermal conductivity λ of 1 / λ ≧ 0.20 (m ² K) / W with regard to its thermal effectiveness. If, for example, an intermediate layer 28 made of polyurethane is used, which has a thermal conductivity of λ = 0.07 to 0.08 W / (mK), the thickness d1 is, for example, 20 to 30 mm.

The fastening means 22 , not shown in Fig. 2 are arranged such that there is no direct thermally conductive connection between the anchor profile 18 and the load-bearing wall 10 . This is achieved, for example, by the fastening means 22 engaging in a dowel consisting of a material with a low thermal conductivity. Furthermore, a thermal insulating bush can be seen easily, which prevents direct contact between the fastening means 22 and the anchor profile 18 .

In Fig. 3 a further embodiment variant is shown ge. Here, the anchor profile 18 is provided with a sheath 30 , which quasi includes the anchor profile 18 like a core. The casing 30 be a thickness d2. On the leg facing the supporting wall 10 , the casing 30 can form the intermediate layer 28 shown in FIG. 2 with the thickness d1. A casing 30 with an integrated intermediate layer 28 is thus created. The arrangement shown in Fig. 3 shows that the heat resistance between the supporting wall. 10 and the outer wall covering 14 is further enlarged. This results from the sum of the Wärmedurchlaßwi resistances of the holding profile 16 , the casing 30 , the anchor profile 18 and the intermediate layer 28 . Since the casing 30 and the intermediate layer 28 have a high thermal resistance, the arrangement in FIG. 3 results in an effective thermal decoupling of the outer wall covering 14 from the load-bearing wall 10 . The casing 30 can in turn consist of polyurethane or poly vinyl chloride, for example.

In order to achieve a sufficient thermal insulation effect, the casing 30 consisting, for example, of polyurethane with a thermal conductivity of λ = 0.07 to 0.08 W / (mK), the casing 30 has a thickness d2 of approximately 5 mm and a thickness d1 from 20-30 mm.

According to a further embodiment, it can be hen that, in the case of sheathing the Ankerpro fils 18, it consists of stainless steel. As a result, a further increase in the thermal resistance is achieved compared to the usual use of aluminum for the anchor profiles 18 . Due to the Ummante development 30 at the point of contact of the holding profiles 16 with the anchor profiles 18, the occurrence of a gal vanic element is prevented.

In Fig. 4 a further embodiment is shown ge, which corresponds essentially to the embodiment shown in Fig. 2. Here, the inter mediate 28 is made of a fiber-reinforced silicate. This silicate intermediate layer 28 has a thermal conductivity of λ = 0.08 to 0.09 W / (mK), so that a thickness d1 of 20-30 mm is selected to achieve a sufficient thermal insulation effect. Since silicate is known to have a relatively high water absorption capacity, an all-round thin, hydrophobic and / or water vapor-tight coating of the intermediate layer 28 made of fiber-reinforced silicate is to be provided, for example. The formation of the intermediate layer 28 from a fiber-reinforced silicate sits over the formation of the intermediate layer 28 from polyurethane or polyvinyl chloride, the advantage that the fiber-reinforced silicate, for example calcium silicate, is a non-combustible material.

Claims (10)

1.Device for fastening a ventilated outer wall cladding to a load-bearing wall, with at least one anchor, which on the one hand is non-positively connected to the load-bearing wall and on the other hand is non-positively connected to the outer wall cladding and which penetrates thermal insulation, characterized in that the anchor ( 18 ) is thermally decoupled from the supporting wall ( 10 ). 2. Device according to claim 1, characterized in that the armature ( 18 ) on its side facing the supporting wall ( 10 ) has an element ( 28 ) made of a material with low thermal conductivity. 3. Device according to one of the preceding Ansprü surface, characterized in that the armature ( 18 ) has a casing ( 30 ) made of a material of low thermal conductivity. 4. Device according to one of the preceding Ansprü surface, characterized in that the element ( 28 ) or the casing ( 30 ) consists of a low thermal conductivity plastic. 5. The device according to claim 4, characterized net that the plastic polyurethane or polyvinyl is chloride. 6. The device according to claim 1 to 3, characterized in that the element ( 28 ) or the casing ( 30 ) consists of a low thermal conductivity pointing, fiber-reinforced silicate. 7. Device according to one of the preceding claims, characterized in that the element ( 28 ) or the casing ( 30 ) has a minimum heat transmission resistance depending on the thickness (d1) and the thermal conductivity (X) of 1 / λ ≧ 0.2 (m ² K) / W on. 8. Device according to one of the preceding Ansprü surface, characterized in that the armature ( 18 ) in the region of the element ( 28 ) or the casing ( 30 ) has a profile. 9. Device according to one of the preceding Ansprü surface, characterized in that the armature ( 18 ) consists of stainless steel. 10. Device according to one of the preceding Ansprü surface, characterized in that the Befestigungsmit tel ( 22 ) of the armature ( 18 ) on the supporting wall ( 10 ) has no direct thermally conductive connection between the armature ( 18 ) and the wall ( 10 ) .