DE3601689A1 - Heat-insulating, non-combustible facade cladding - Google Patents

Abstract

A description is given of a non-combustible, heat-insulating facade cladding, in which, between mineral-fibre panels (11) and finish-coat plaster (14), there is arranged a light undercoat plaster (17) without additional plaster carriers. <IMAGE>

Description

The invention relates to a heat-insulating, non-flammable Facade cladding of building material class A using of mineral fiber boards according to the preamble of claim 1.

Such a facade cladding is basically already out DE-OS 34 09 644 known. There is a heat-insulating facade cladding of building material class A, which are essentially made of mineral fiber boards, insulating plaster and mineral external plaster consists. On the building side, the mineral fiber boards are included arranged and fastened so that this about 70 to 95% cover the building area to be insulated. Not from them Building surfaces covered with mineral fiber panels are possible equally distributed. There is an insulating plaster over the mineral fiber boards and a mineral exterior plaster is arranged above this. Due to the areas not covered with mineral fiber boards will have better adhesion of the over the mineral fiber boards lying insulation plaster achieved. However, since the insulation plaster is less Thermal insulation has emerged as the mineral fiber boards partial areas with reduced thermal insulation. The backfilling of the building surfaces not covered by the mineral fiber mats requires an additional operation. Because of the different Heat conduction also results from temperature differences Thermal stresses that may lead to cracks.

Most thermal insulation for external walls currently have insulation boards made of foam plastics.

DE-OS 24 51 805 describes an insulation board made of polystyrene, Reinforcement applied directly to their surface and over which a plaster is applied. The reinforcement  is therefore arranged between the thermal insulation board and the plaster. Here too, cracks can occur when there are large temperature fluctuations occur. The reinforcement has therefore already been proposed to embed in the plaster layer. A crack on one This can prevent plaster on thermal insulation be that a very thin filler layer on the insulation board is applied with reinforcement. However, this is mechanical stress not grown. Even a leaned bike can lead to damage and indentation.

Reinforcement is therefore provided in DE-OS 31 04 084, in which both layers of plaster are applied separately, the Reinforcing filler layer are connected. Doing so the mineral insulation board initially with a relatively thick Intermediate plaster layer, then with a layer containing the reinforcement insert Filler and finally with a finishing coat. In total there are three plaster layers made of mortar with the usual ones Bulk densities and correspondingly high grammages, which overstress the mineral insulation board (adhesive pull and adhesive shear strength). Every plaster layer must be ordered harden completely or at least partially in the next layer. Economically undesirable, long downtimes occur to complete the entire facade.

In EP-OS 01 44 965 a light concealed installation with foam glass Insert described. Foam glass has a pretty good one Thermal insulation, but works because of its brittleness like a foreign body in the plaster and therefore leads to larger temperature fluctuations easy to crack.

DE-OS 34 07 459 describes a method for coating Walls and ceilings with heat-insulating material known with the a layer of polyurethane applied between metal pull-off strips whose distance from the wall is the thickness of the to be applied Layer determined. That after the order first over the Pulling strips protruding thermal insulation material is then  removed with a suitable tool. Serve the puller strips as a guide for the tool. The one in the facade cladding remaining pull-off strips made of metal however as thermal bridges and because of the lead to the surrounding Material different coefficients of expansion easy to crack in the coating.

A facade cladding is known from EP-OS 00 19 892, where a metal plate is fastened in front of a building wall is. This is done for example by screwing. The resulting space between the building wall and the metal plate is filled with urea-formaldehyde foam. The metal plate has protrusions with holes. The one on the metal plate Plaster applied is through the protrusions and holes anchored to the metal plate. This heat insulating outer cladding for building walls the attachment of one does not allow adhesive insulation on a building wall, the plaster not from the insulation material, but via the screw connection from the building wall will be carried. The insulation material is therefore not of any weight exposed to plastering forces. Here is, however disadvantageous that the metal plate as a foreign body with different Thermal expansion coefficient easily the cause of cracks. Also attaching the metal plates a labor-intensive process on the building wall.

From EP-OS 00 59 466 is finally a plaster base for Insulating plaster in the form of a wave-shaped grid intersecting steel wires known that by means of fasteners, that attack the wave valleys, anchored to the outer wall and with its protruding wave crests Insulating plaster carries. Can between the plaster base and the outer wall another insulation layer, e.g. B. made of mineral wool be attached to the outer wall with the plaster base becomes. Due to the undulating deformation of the support grid the thermal stresses in the insulation plaster are reduced and the danger of cracking is reduced. Because of the strangeness of the  wave-shaped mesh made of intersecting steel wires However, crack formation cannot be completely ruled out.

The invention has for its object a heat-insulating, to create non-flammable facade cladding that with optimal Thermal insulation and low manufacturing costs a good mechanical Has strength, without the risk of Cracking.

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

Advantageous further developments result from the subclaims.

The invention is described below with reference to the drawing figure for example explained.

The figure shows the structure of the heat-insulating facade cladding schematically. A layer of mineral fiber plates 11 is arranged on the building wall 10 in a manner known per se. The mineral fiber plates 11 are fastened in a known manner. On the mineral fiber boards 11 a light concealed plaster 12 with a mortar density between 600 and 1400 kg / cbm is applied without additional plaster base. A so-called reinforcement 13 made of glass silk fabric with a tensile strength in warp and weft of more than 2000 N / 5 cm can be arranged in the plaster 12 . As a result, the strength of the plaster 12 is significantly increased, and that without negative properties on the thermal insulation and without the risk of cracking. The plaster 12 can have a thickness of 10 to 20 mm, preferably that of 15 mm. It can be applied by machine or by hand. The solid mortar density should - as already mentioned - be between 600 and 1400 kg / cbm, but preferably between 800 and 1200 kg / cbm. This is considerably lower than the bulk density of common mortar, which is 1700 to 2000 kg / cbm.

In addition, the flush-mounted 12 may contain inorganic or organic light aggregates. Foamed organic aggregates have particular advantages, such as expanded polystyrene (EPS) with a bulk density of less than 20 kg / cbm. If such supplements are in spherical form, the elasticity is increased considerably as a result and an extremely soft temperature transition between the mineral fiber board 11 , the plaster 12 and the plaster 14 is ensured. The thermal conductivities are about 0.03 to 0.045 W / mk for the mineral fiber boards 11 , about 0.3 for the plaster 12 and about 0.8 to 0.9 for the top plaster 14 . This results in a low temperature build-up, which further reduces the susceptibility to cracking. The entire processing of the thermal insulation cladding described above is easy. It can be done with customary tools according to the craft.

A mineral, diffusion-open, non-combustible water-repellent plaster is used as the top plaster 14 , namely in a thickness of 3 to 12 mm.

Overall, this results in a cleaning system that is not flammable (Building material class A), is purely mineral and open to diffusion. Because of the extensive homogeneity of the building materials used a risk of cracking is practically excluded.

Overall, it can be said that with the system described found a solution for the required thermal insulation of facades was the facade

• a. is not flammable (even the concealed installation is despite the Addition of expanded polystyrene - EPS - non-flammable)
• b. no plaster base required (there is no time-consuming dowelling, different coefficients of expansion are avoided),
• c. only two layers of plaster needed and still mechanical loads  has grown in the usual way,
• d. does not require any downtimes that go beyond normal
• e. uniform thermal insulation over the entire facade having
• f. due to the elastic behavior and the given Layer thickness of the plaster is not prone to cracking and
• G. because of the adapted thermal conductivities a smooth temperature transition results in a temperature build-up and possibly still arising tensions due to the relatively large Layer thickness in the flush-mounted coped easily.

These advantages are achieved essentially by the special Design of the plaster, including the layer thickness the flush-mounted is of considerable importance.

Claims (7)

1. Thermally insulating, non-combustible facade cladding of building material class A using mineral fiber boards ( 11 ), on which the further plaster is applied, and with a mineral, diffusion-open, non-combustible mineral finishing plaster ( 14 ), characterized in that between mineral fiber boards ( 11 ) and top plaster ( 14 ) a light flush ( 12 ) is arranged without additional plaster base. 2. facade cladding according to claim 1, characterized in that the plaster ( 12 ) has a thickness of about 10 to 20 mm, preferably of 15 mm. 3. Facade cladding according to one of claims 1 or 2, characterized in that the plaster ( 12 ) has a solid mortar density of 600 to 1400 kg / cbm, preferably from 800 to 1200 kg / cbm. 4. facade cladding according to one of claims 1 to 3, characterized in that the plaster ( 12 ) contains inorganic or organic light aggregates, preferably foamed organic aggregates with a bulk density of less than 20 kg / cbm. 5. facade cladding according to claim 4, characterized in that the light supplements are expanded Polystyrene (EPS). 6. facade cladding according to claim 5, characterized in that it is expanded polystyrene in spherical form acts.   7. Facade cladding according to one of claims 1 to 6, characterized in that the plaster ( 12 ) contains a serving as reinforcement ( 13 ) embedded glass silk fabric.