DE10160665A1 - Composite element used for indoor and outdoor facade linings comprises a stone plate and a support plate made from a material containing components contained in the stone material - Google Patents

Abstract

Composite element comprises a stone plate (1) and a support plate (2) made from a material containing components contained in the stone material. The components of the stone material occur by a chemical reaction with the components of the support to form a fixed bond. Preferred Features: The support plate is made from porous concrete and is joined to the stone plate by hardening the porous concrete in the liquid state. The stone plate is made from hard or soft natural stone. The material of the support plate has a bulk density of 300 to more than 800 kg/m<3>. An Independent claim is also included for a process for the production of the composite element.

Description

The invention relates to a composite element with a natural stone slab, in particular for Facade cladding can be used outdoors and indoors, as well as a Process for producing the composite element.

Composite elements with a natural stone slab are in different embodiments known, the natural stone slab is glued to a support plate, the for example from an aluminum honeycomb panel, an aluminum corrugated carrier plate or one Glass fiber mat can exist. Such composite elements have a relatively high weight and are not fully approved as exterior wall cladding.

The invention has for its object a composite element with a natural stone slab low weight so that it can be used in all areas, especially for Facade cladding, can be used.

According to the invention this is achieved by the features in claim 1. As a result of that a chemical to establish the connection between the stone slab and the support plate Reaction between components of the two elements takes place, you get a very solid one Connection between stone slab and base plate, which is also a relatively light material such as B. aerated concrete can be used so that there is a composite element of little Weight results that can also be used for facade cladding.

The aerated concrete is preferably applied to the stone slab in the liquid state, whereupon a firm connection with the stone slab is achieved by hardening.

The invention is explained in more detail for example with reference to the drawing. Show it

Fig. 1 shows a section through a composite element with a recess for an anchor, and

Fig. 2 shows schematically two further embodiments of an anchor for the composite element.

1 with a stone slab is called, which can consist of hard or soft natural stone such as granite, gabbro or marble, limestone and the like. The plate thickness can range from 3 mm to more than 40 mm. The natural stone slab is preferably sawn on both sides.

With the stone slab 1 , a support plate 2 is connected, which is preferably made of aerated concrete. This carrier plate can have a thickness of 5 mm to more than 120 mm, and the density of the cellular concrete can be 300 to more than 800 kg / m ³ . In a practical embodiment, a carrier plate made of aerated concrete with a layer thickness of 15 mm and a density of approx. 450 kg / m ^{3 can be} applied to a natural stone plate 1 with a layer thickness of 10 mm and a density of approx. 2,750 kg / m ³ .

Aerated concrete is understood to be a lightweight concrete with a porous structure and bulk densities of 0.35 to 1.0 kg / dm ³ , which is also referred to as gas concrete. AAC contains as its main component quartz-containing sand, lime, cement and possibly other additives and / or additives as well as aluminum powder or paste as a pore-forming additive. These ingredients are mixed and, if necessary, ground beforehand, whereupon they are pasted with water and poured into a mold. After solidification, the aerated concrete can be steamed in autoclaves at approx. 190 ° C. and cured about 12 bar in about 6 to 12 hours.

3 with a recess in the stone slab 1 and the support plate 2 is designated, in which an undercut anchor can be used for fastening the composite element consisting of the stone slab 1 and the support plate 2 . Other anchor elements can also be used, for example a blind hole anchor or pocket anchor.

Fig. 2 shows, for example, an anchor 4 , in which the inner end of the anchor is widened by a screw (wedge anchor). 5 denotes a further embodiment of an anchor, in which a clamping ring 6 is widened by a screw at the inner end of the anchor (Fischer anchor). In both anchors, a hexagon is shown at 7.

The reproduced in Fig. 1 and Fig. 2 anchors extend into the stone slab 1. This embodiment is preferred if the material of the carrier plate 2 is relatively light and porous. In a correspondingly solid embodiment of the carrier plate 2 , the anchor can also only extend into the carrier plate 2 .

The carrier plate 2 made of aerated concrete is preferably connected to the stone slab 1 by applying aerated concrete in liquid form to the stone slab and allowing the aerated concrete to harden under the action of heat. Here, the stone slab 1 is placed in a mold and aerated concrete, which contains quartz, lime, cement, diorite and aluminum powder as main components, is applied to the stone slab in liquid form. After a certain stiffening phase, the composite element becomes at approx. 200 ° C. and a relative humidity of 98% cured.

This creates a firm connection between the stone slab and the aerated concrete that calcium and / or silicon components of the two elements when exposed to heat form a chemical bond with each other and separate crystals or molecules the components of both plates are formed. For making the connection preferably a sawn surface of the stone slab is used.

After the production of the composite element, the natural stone slab can be calibrated or be surface coated. The surface or visible side of the stone slab can, for. B. polished, be sanded, sandblasted or flamed. The back of the carrier plate can also be calibrated to obtain a low thickness tolerance. The finished composite element can be cut to the desired size and anchor holes can be made become. An undercut technique is primarily used for anchoring. It is but a Dorn technique can also be used.

Due to the carrier plate made of aerated concrete with variable density, it is possible to use a to manufacture lightweight natural stone facade panels that comply with German and European standards can be used outdoors at any height. With a layer thickness of for example 25 mm of the composite element, the carrier plate 15 mm and the stone plate Is 10 mm thick, the composite element is thinner than a conventional natural stone facade panel, whose thickness is 30 mm.

With a weight of approx. 30 kg the composite element is much lighter than one Usual natural stone facade panel, which has a weight of 90 kg.

The composite element is non-flammable and consists of mineral material.

It is also possible to connect a carrier plate 2 made of aerated concrete to the stone plate 1 using an adhesive. Mineral adhesives or two-component adhesives (e.g. polyurethane or epoxy resin adhesives) are preferably used.

According to a modified embodiment, one can be between the stone slab and the support slab Adhesive bridge and / or barrier layer by means of an adhesive, primer or the like be provided. Especially with soft, highly water-absorbent materials, it can it may be necessary to apply an adhesive bridge and / or barrier to the stone before aerated concrete is applied in liquid form. An adhesive bridge is an advantage because it has soft rocks a diamond-sawn surface are relatively smooth. The barrier between Stone and aerated concrete is used to prevent components of the aerated concrete from blooming Avoid surface of the stone.

When applying an intermediate layer on the stone material, the material of the Intermediate layer penetrate into the stone surface, leaving the surface of the stone material remains open for a chemical connection with components of the carrier material.

Due to the low weight of the composite element is a much larger plate format possible than was previously the case with natural stone. In the case of interior wall cladding, the thickness of the Natural stone can be further reduced to get an even lighter product. Should be very low heights are required, so the density of the aerated concrete Carrier plate are increased to reduce the layer thickness. By increasing the density the aerated concrete has a higher bending tensile strength and a higher pressure stability of the carrier, so that one with a lower layer thickness and higher density comparable values can be obtained with a larger layer thickness and lower density.

Instead of aerated concrete, other types of lightweight concrete with preferably porous can also be used Structure, such as foam concrete or lightweight concrete with porous aggregates such. B. pumice, Expanded mica, clay, pearlite and foam plastics used as the material for the carrier plate be, the material of the carrier plate components such as calcium and / or silicon are added, which, when exposed to heat, with the corresponding components of the Stone material react in this way and establish a firm connection.

Instead of a porous carrier material, a dense carrier material can also be used be when the composite element is used for example as a floor covering. Also in In this case, the connection is achieved by joint molecular formation between the Components of the stone material and those of the carrier material are formed.

In addition to the anchor technology, the connection of the composite element to the substrate can be done and a substructure can also be produced using conventional powder adhesives.

In addition to exterior and interior cladding, a composite element of described type for wall coverings as well as ceiling and floor coverings in Indoor and outdoor use.

Instead of natural stone, an artificial stone or an agglomerate can also be used in conjunction with Aerated concrete can be used to design a composite element.

Claims (12)

1. Composite element made of a stone slab ( 1 ) and a carrier plate ( 2 ), the carrier plate ( 2 ) connected to the stone slab being made of a material that contains constituents contained in the stone material, and wherein the constituents of the stone material are produced by a chemical process react with the constituents of the carrier material and in this way establish a firm connection. 2. Composite element according to claim 1, wherein the carrier plate ( 2 ) is made of aerated concrete. 3. Composite element according to claim 2, wherein the carrier plate ( 2 ) is connected to the stone slab by curing the aerated concrete from the liquid state. 4. Composite element according to claim 2, wherein the carrier plate made of aerated concrete is connected to the stone slab by an adhesive. 5. Composite element according to the preceding claims 1, wherein the stone slab ( 1 ) consists of hard or soft natural stone. 6. Composite element according to the preceding claims, wherein the material of the carrier plate ( 2 ) has a density of 300 to more than 800 kg / m ³ . 7. Composite element according to the preceding claims, wherein the carrier plate ( 2 ) has a layer thickness of 5 mm to more than 120 mm and the stone plate has a layer thickness of 3 mm to more than 40 mm. 8. Composite element according to the preceding claims, wherein between the carrier plate an intermediate layer is provided from aerated concrete and stone slab, which as Adhesive bridge and / or serves as a barrier between aerated concrete and stone. 9. Composite element according to the preceding claims, wherein the stone slab on the Side of the support plate has a sawn surface. 10. A method for producing a composite element from a stone plate ( 1 ) and a carrier plate ( 2 ), wherein on the stone plate surrounded by a casting mold a constituent of the stone plate such as calcium and / or silicon-containing carrier material in a liquid state up to the desired layer thickness of the carrier plate is poured on, whereupon the carrier material is cured to produce a connection with the stone plate under the action of heat to form a chemical reaction between the constituents of the stone material and the carrier material. 11. The method according to claim 10, wherein liquid-applied aerated concrete after a Stiffening phase at approx. 200 ° C. is cured. 12. The method of claim 11, wherein the curing process at a relative Humidity of approximately 98% is executed.