EP0454800B1 - Process for fixing components on an external insulation layer - Google Patents

Abstract

The mounting assembly (1) of the invention comprises a backing plate (2) with a layer of insulation (3) on one side. Since the mounting assembly (1) is fitted with the backing plate (2) on the inerior side, thus ensuring that the backing plate (2) experiences virtually the same environmental conditions as the rest of the insulation, condensation in the area of the mounting assembly is avoided.

Description

The invention relates to a method for fastening components to external insulation according to the preamble of claim 1.

Methods of the type mentioned are known.

DE-OS 33 07 634 describes the milling of grooves into an external insulation, mounting slats being glued into the grooves, to which cladding panels are then attached. It is disadvantageous that the grooves have to be milled very carefully in order to obtain a straight and consistently deep groove, which enables the assembly batten to be inserted precisely with precise alignment with the surface of the external insulation. Subsequent adjustment of the surface of the mounting lath to the surface of the external insulation is not possible or at best with considerable effort. In addition, the mounting slats on the top of the outer insulation form thermal bridges, which have a disadvantageous effect on the cladding panels and lead to moisture precipitation there under certain atmospheric conditions. The latter in turn results in dirt and / or color changes in the cladding panels.

CH-PS 674 234 describes an analogous method, but instead of long grooves, limited recesses are created, which are also not milled out, but are formed by means of a heated resistance wire. In addition, mounting plates with high mechanical strength are glued in place of mounting slats. This method also has the disadvantages already described above, with an additional complication that the cutting out of the recess by means of the heated resistance wire leads to greater inaccuracies in terms of shape, dimensional accuracy and surface quality of the recess. In particular, arises from the fusion cutting an uneven surface layer in the recess, which at least significantly impedes firm and permanent adhesion of the mounting plate.

GB-A-2 126 619 describes a method for fastening components to external insulation, in which fastening laths are spaced directly at a component via glued-on insulation strips, i.e. to be attached to masonry. For this purpose, screws are used, which run through the mounting plates and are screwed into dowels, which are arranged in the masonry. Insulation plates are arranged between the fastening slats, which are held over covers which overlap the insulation plates and the fastening slats and are held by means of clips which are hammered into the fastening slats. This method of fastening is extremely complicated and in particular not suitable for fastening objects to the insulation layer, because on the contrary it serves to fasten the insulation layer to a component.

The object of the invention is to improve a method of the type mentioned in the introduction so that the disadvantages mentioned are avoided.

The object is achieved according to the invention by the characterizing features of claim 1.

The circular design of the assembly base has the significant advantage that the recess in the outer insulation can be made easily and with great accuracy using a circular milling cutter that can be fastened in any drilling machine by hand and at any location, especially on the fully assembled outer insulation . The milling surfaces also provide the best adhesive properties, so that such an assembly pad on everyone any point of the external insulation can be attached with high accuracy and optimal gluing. The arrangement of the mounting plate in the interior of the recess and the insulation layer on the outside results in the further advantages that the mounting base can be easily adapted to the surface of the outside insulation by grinding. The outer insulation layer avoids cold bridges and therefore does not interfere with the insulation properties of the outer insulation, as a result of which punctual deviations in the surface properties are avoided on an overlying cover.

Advantageous embodiments of the method are described in claims 2 to 7.

The mounting plate used can be made of any material that provides a secure hold for fasteners such as screws. For example, the mounting plate can consist of a hardboard. A mounting plate made of hard plastic is preferably used. However, it is even more advantageous according to claim 3 to use a metal mounting plate, aluminum being particularly preferred. An aluminum mounting plate not only has good strength properties, but is particularly suitable for self-tapping screws, for example. Otherwise, it is corrosion-resistant.

There are also a wide variety of design options for the insulation layer, an insulation layer made of foam plastic, in particular polystyrene foam, being preferred according to claim 4.

An assembly base is advantageously used in which the assembly plate and the insulation layer are bonded according to claim 5, a dispersion adhesive being preferred with regard to strength properties and aging resistance.

The mounting plate (s) used and / or the insulation layer can have different dimensions, but optimum values are given by claims 6 and / or 7.

• Figur 1 eine Montageunterlage in Seitenansicht; und
• Figur 2 eine in einer Aussenisolation angeordnete Montageunterlage mit einem daran befestigten Bauteil, im Querschnitt längst der Zentrumsachse der Montageunterlage.

An embodiment of the invention is described below with reference to the drawing, which show:

• Figure 1 is an assembly document in side view; and
• FIG. 2 shows an assembly pad arranged in an external insulation with a component attached to it, in cross section along the center axis of the assembly pad.

FIG. 1 shows a particularly advantageous mounting base 1 which has a mounting plate 2 which is made of aluminum and has a thickness of approximately 2 mm. This mounting plate is provided on one side with an insulation layer 3, which consists, for example, of polystyrene foam and has a thickness of approximately 10 mm. The mounting pad is designed as a circular disc and has a diameter of preferably 90 mm. The insulation layer 3 and the mounting plate 2 are connected to one another by means of an adhesive, preferably a dispersion adhesive. The insulation layer 3 can expand slightly conically outwards from the mounting plate 2, as a result of which the fit and centering of the mounting base in a recess can be improved.

FIG. 2 shows an assembly pad 1 arranged in an external insulation 4, for example of a building, and a component 5 fastened thereon, which can be designed, for example, as an angle iron. A self-tapping screw 6 is used to fasten the component 5 to the assembly base 1.

The assembly pad on or in the outer insulation 4 is arranged in a simple manner as follows. First, the intended assembly point, which is given by the axis 7, is marked on the outer insulation 4. Then, by means of a circular milling cutter, a recess 8 is made coaxially with the intended assembly point 7 in the outer insulation 4, the depth and diameter of which corresponds to the thickness and the diameter of the assembly base. Then the mounting pad 1 with the mounting plate 2 on the inside is glued into the recess 8, for which purpose a dispersion adhesive is preferably used. The assembly document is then located coaxially at the intended assembly point. The attachment point is prepared by pre-drilling through the assembly base so that component 5 can then be easily attached to the attachment point using screw 6.

Claims (7)

1. A process for fixing components to an external insulation layer of a structural body, Wherein a recess is made in the external insulation layer and a mounting assembly is glued into the recess, said mounting assembly being provided with a backing plate and an insulation layer glued thereto, a component being fixed to the structural body by mechanical means, characterized in milling a circular recess into the external insulation layer and gluing thereto a corresponding circular mounting assembly such that said backing plate is positioned interiorly and said insulation layer is oriented exteriorly.
2. A process according to claim 1 characterized in using a mounting assembly (1), the backing plate (2) of which consists of hard plastic.
3. A process according to claim 1 characterized in using a mounting assembly (1), the backing plate (2) of which consists of metal, preferably of aluminium.
4. A process according to one of the claims 1 to 3 characterized in using a mounting assembly (1), said insulation layer (3) of which consists of foamed plastic, preferably of polystyrene foam.
5. A process according to one of the claims 1 to 4 characterized in using a mounting assembly (1), the backing plate (2) of which is glue bonded to said insulation layer (3).
6. a process according to one of the claims 1 to 5 characterized in using a mounting assembly (1), wherein said backing plate (2) has a thickness of about 2 mm and said insulation layer (3) has a thickness of about 10 mm.
7. A process according to one of the claims 1 to 6 characterized in using a mounting assembly (1) having a diameter of about 90 mm.

Images