DE102017119048A1 - Composite covering, process for its production and use - Google Patents

Abstract

The invention relates to a Kompositbelag based on an aggregate, with layer thicknesses up to 5 millimeters for the usual processing of such coverings in the construction industry, for. B. as wall or ceiling cover or floor covering, suitable and this is deformable without cracking. The composite coating comprises an aggregate layer applied to a substrate with a aggregate size of up to 0.5 millimeters, the aggregates being bound by means of a homogeneously dispersed elastomer-based binder, the proportion of which is one to five percent of the mass of the aggregate layer. It is particularly suitable for use in the construction industry, namely as a floor covering or for covering ceilings, walls or facades, but also for doors and windows. Further fields of application are interior decorations in vehicles as well as ballistic protective coverings.

Description

The invention relates to a Kompositbelag based on an aggregate, a process for its preparation and the use of Kompositbelages for coverings and coverings, especially in construction.

The interior design or cladding of facades in stone look with tiles and tiles is known. Alternatively, have for years plastic-based coverings with a variety of well-known decors, u. a. also in stone look, established. These plastic-based imitation stone coverings are usually sold in thicknesses in the range of approximately 1 to 5 millimeters, are flexible and easy to process.

In contrast to natural stone or artificial stone, such as concrete, plastic coverings have a different feel and a lower resistance to environmental influences. With stone-clad ceilings and walls, the indoor climate is also often more pleasant than when using plastic panels.

Stone coverings that combine the advantages of the plastic coverings, in particular their simple processing, and the natural stone look and feel, are known in the form of rigid plates, thin stone veneers or very thin laminates with applied aggregates.

Stone veneers on support materials are described in, inter alia WO 2014/108500 A1 or DE 20 2006 000 130 U1 , Also known, for example DE 195 22 875 A1 or DE 10 2015 122 418 A1 , are flexible laminates where thin natural stones or artificial stones are applied to flexible substrates.

In GB 1 162 991 A a stone covering is described which is made of an artificial slip (containing an aggregate) and applied to a rigid plate. EP 2 360 025 A2 discloses a rock-based coating whose surface layer consists of finely-granulated, melt-mixed natural stone and is thermally applied to a carrier web. A method based on a putty for producing a plate with stone structure is in DE 103 40 238 A1 described.

The known stone coverings have the disadvantages that they either to ensure flexibility and deformability, are made very thin or rigid in the thicker versions and thus susceptible to cracking during processing, for example, in adaptation work on curved surfaces.

The object of the invention is to provide a flexible Kompositbelag stone optics based on an aggregate, with layer thicknesses up to 5 millimeters for the usual processing of such coverings in the construction industry, eg. B. as wall or ceiling cover or floor covering, suitable and this is deformable without cracking.

The object is achieved by the Kompositbelag based on an aggregate with the characterizing features of claim 1 and the method according to claim 7; expedient developments of the invention are in the dependent claims 2 to 6 such as 8th described. Advantageous uses emerge from claim 10.

According to the invention, the composite coating comprises an aggregate layer applied to a flexible carrier material known per se, the aggregate granules having a grain size of up to 0.5 millimeters being bonded by means of a homogeneously distributed elastomer-based binder in the aggregate layer. The proportion of the binder in the aggregate layer is one to five percent of the mass of the aggregate layer.

The aggregate may consist of any natural or artificial aggregate; the aggregates may be round or broken. Suitable aggregates are, for example, sands, natural stone granules (made of marble, basalt, granite, etc.) or artificial stone granules, made of cement or concrete. The selection of the type of rock depends on the desired appearance: Sandstone imitations can be produced by using sand as aggregate. Composite coverings with concrete look can be made with aggregates of sand and cement.

Due to the homogeneous distribution of the elastomer binder individual rock grains are evenly bonded rubber-elastic to their adjacent rock grains.

Suitable binders are artificial elastomers, for example butadiene or silicone elastomers, as well as natural rubber.

The amount of binder in the aggregate layer according to the invention ensures that unbound regions remain between adjacent rock grains. As a result, the overall composite in the aggregate layer is significantly more flexible than when all intermediate spaces with binder are completely filled, since the elastic extensibility of the individual binder bridges is higher than the extensibility of a compact, complete binder filling.

Due to the high proportion of aggregate aggregate, the special advantage of the composite coating is that the appearance, feel and many of the macroscopic material properties largely correspond to those of compact stone material.

At the same time, the composite covering has the desired flexibility and, owing to its good deformability, can be applied in a crack-free manner to curved surfaces in thicknesses of up to 5 millimeters.

Another advantage is that the components contained in the composite coating are predominantly based on natural or natural products. When using natural sands in combination with natural rubber as a binder and a cotton fleece as a carrier material, this is almost completely achievable.

In addition, the fire protection properties of Kompositbelages are particularly favorable.

In one embodiment of the Kompositbelages the aggregate has two sand fractions, the grain size of the first sand fraction in the range of 0.1 millimeters to 0.5 millimeters and the grain size of the second sand fraction in the range up to 0.1 millimeters. The proportion of the first sand fraction is 55 to 80 percent of the mass of the aggregate layer. The second sand fraction, alone or in combination with other aggregates, forms the remainder of the aggregate layer.

The aggregate layer of these sand fractions is particularly homogeneous in optical appearance and shows excellent flexibility, since the arranged between the larger rock grains and connected to these via the binder, smaller rock grains act like an articulation.

It can be provided that the aggregate consists of sand and cement stone fractions, wherein the proportion of the cement stone fraction in the aggregate layer is four to ten percent of the mass of the aggregate layer. The rest is sand. Cement stone and sand can be connected to concrete agglomerates. Composite coverings based on this aggregate have the appearance of concrete components.

Advantageously, the composite coating has a porosity in the range of 10 to 30 percent. The porosity increases the flexibility of the composite covering and improves its acoustic properties, for example in terms of sound insulation.

The aggregate layer may be sealed with a plastic; For this purpose, especially plastics based on polyurethane are suitable. The advantage of sealing is when using the Kompositbelages in the outdoor area, since the resistance to weathering, in particular against the ingress of water, is increased, or when used as a floor covering, since the sealing counteracts contamination and the abrasion resistance of Kompositbelages is increased.

The flexible carrier material is preferably a fleece or fabric. These are suitable in terms of a good connection of the carrier material to the aggregate layer and at the same time ensure the deformability of the Kompositbelages. In addition, fleeces or fabrics provide the basis for a good connection of the composite covering when gluing on the support surfaces.

According to the invention, the preparation of the aggregate-based composite coating with the aggregate coating applied to a flexible carrier material takes place in accordance with the process steps described below.

First, the aggregate is mixed with an aqueous dispersion of a rubber-based binder, for example by means of an agitator, until a lump-free, homogeneous aggregate paste is formed. Suitable binder dispersions are aqueous emulsions or suspensions of synthetic rubbers, such as butadiene or silicone rubber, as well as natural rubbers. In order to establish a suitable processing consistency or viscosity, water is used as an adjusting and dispersing agent.

The rockgrain paste is then evenly spread onto a production underlay, for example a wood or plastic panel, and the flexible support material of a water-permeable non-woven or fabric applied to the painted-on aggregate paste. This is done for example by placing and pressing the fleece or fabric.

The aggregate paste covered with the carrier material is rolled or pressed into a green coating of homogeneous thickness and subsequently dried. Drying can be carried out by venting in static or moving ambient air, by means of hot air blowers or by means of radiation.

During the drying step, the composite coating forms by, on the one hand, the liquid escapes from the layer of grain through the fleece or fabric and, on the other hand, the rubbers are vulcanized to form elastomers, resulting in the binder bridges between the grains.

Finally, the composite covering is deducted from the production document. He can now be made up as needed.

Preferably, the composite coating is abraded after removal from the production substrate on the opposite surface of the substrate. Since the layer of rock granules molds the surface of the production base, this specific surface appearance can be used for further use. To achieve a particularly uniform, typical stone appearance, it is advantageous to abrade the Kompositbelag, whereby, for example, the porosity is visible in the Gestarkkörnungsschicht.

In one embodiment of the process for producing the composite coating, the aggregate paste contains cement, the proportion of which amounts to one to seven percent of the mass of the aggregate paste. During the drying process, in addition to the elastomer binder bridges, cement paste or - in combination with sand - concrete is formed. As a result of the small amount of cement surcharge according to the invention, only individual agglomerates of mineral aggregated aggregates are formed. Macroscopically, the flexibility of the composite coating remains intact.

The Kompositbelag according to the invention is particularly suitable for use in the construction industry, namely as a floor covering or for covering ceilings, walls or facades. It is also possible to blind doors or windows with the Kompositbelag. The use of composite flooring is not limited to the construction industry; For example, it is also suitable for the interior decoration of vehicles or for ballistic protective coverings.

The invention is explained in more detail below with reference to an embodiment and with reference to the schematic drawings. For this purpose, the figure shows the aggregate-based Kompositbelag in plate form in the perspective view.

The aggregate layer 1 with a layer thickness of 2.5 millimeters is on the substrate 2 applied from a synthetic fiber fleece.

It consists of 65% by mass of a first sand fraction having a grain size in the range of 0.1 mm to 0.5 mm, 26% by mass of a second sand fraction having a grain size of up to 0.1 mm, and 7% by mass of a cement stone fraction and 2% by weight of natural rubber. The porosity of the aggregate layer 1 is 25% by volume.

To prepare the composite coating, an aqueous dispersion based on a natural rubber binder is mixed with the aggregate of the first and second sand fraction with the addition of cement in a stirred pot until a lump-free, homogeneous aggregate paste is formed. This is spread on a plastic plate (production document), the synthetic fiber fleece placed on it and pressed.

Subsequently, the green covering with homogeneous layer thickness is produced therefrom by means of a roller press. The green coating dries to form a Kompositbelages of still air.

After the composite covering has been removed from the production base, the composite covering is finely ground on the side opposite the nonwoven.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2014/108500 A1 [0005]
• DE 202006000130 U1 [0005]
• DE 19522875 A1 [0005]
• DE 102015122418 A1 [0005]
• GB 1162991 A [0006]
• EP 2360025 A2
• DE 10340238 A1 [0006]

Claims (10)

Composite covering based on an aggregate aggregate, comprising an aggregate layer (1) applied to a flexible support material (2), characterized in that the aggregates having a particle size of up to 0.5 millimeter are combined in the aggregate layer (1) by means of a homogeneously distributed elastomer-based binder are, wherein the proportion of the binder in the aggregate layer (1) is one to five percent of the mass of the aggregate layer (1). Composite coating after Claim 1 , characterized in that the aggregate has two sand fractions, wherein - the grain size of the rock grains of the first sand fraction in the range of 0.1 millimeters to 0.5 millimeters and the proportion of the first sand fraction in the aggregate layer (1) 55 to 80 percent of Mass of the aggregate layer (1) is, and - the grain size of the aggregates of the second sand fraction is up to 0.1 millimeter. Composite coating after Claim 1 or 2 , characterized in that the aggregate of sand and cement stone fractions, wherein the proportion of the cement stone fraction in the aggregate layer (1) is four to ten percent of the mass of the aggregate layer (1) and the remaining portion is formed by sand. Composite coating after one of the Claims 1 to 3 , characterized in that the aggregate layer (1) has a porosity in the range of 10 to 30 percent by volume. Composite coating after one of the Claims 1 to 4 , characterized in that the aggregate layer (1) is sealed with a polyurethane-based plastic. Composite coating after one of the Claims 1 to 5 , characterized in that the flexible carrier material is a fleece or fabric. A method of producing a composite coating based on an aggregate comprising an aggregate layer (1) applied to a flexible substrate (2) characterized by the steps of: a) mixing the aggregate with a water-based dispersion of a rubber based binder to form a lump-free homogeneous aggregate paste; b) applying the aggregate paste to a production base, c) applying the flexible substrate (2) of a water-permeable non-woven or fabric to the spread aggregate paste, d) pressing or rolling the aggregate paste covered with the substrate (2) into a green covering of homogenous thickness, e) drying the green coating to form the Kompositbelages, and f) peeling the Kompositbelages of the production document. Process for the preparation of a Kompositbelages after Claim 7 , characterized in that the composite coating is abraded after the removal of the production base on the surface opposite the substrate. Process for the preparation of a Kompositbelages after Claim 7 or 8th , characterized in that the aggregate paste contains cement at a level of one to seven percent of the mass of aggregate paste. Use of the composite covering according to one of Claims 1 to 6 or manufactured according to the method of one of Claims 7 to 9 as a covering for ceilings, walls or facades, as a floor covering, as interior decoration of vehicles and as a ballistic protective covering.

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