DE2310970A1 - Loose laid textile floor covering - has heavy filled plastics underside to hold down on floor - Google Patents

Abstract

A heavy coating for textile and similar flexible structures, espl intended for the underfacing of flexible but non-stick tiles or floor covering which are designed to remain in position without adhesive by their own wt. and low centre of gravity, is as follows: as plastics coating material, e.g., PVC, polyurethane, atactic polypropylene, polyethylene etc., is mixed with a filler of heavy specific gravity, esp. powdered Fe or Fe alloys of particle size 0.1-250 mu; the powdered/plastics wt. ratio is 20-95/80-5; the mixt. is applied as a paste, soln. hot melt, sheet, powder etc., onto the face of the textile and then gelled, sintered, age hardened, pressed or rolled to bonded to the textile.

Description

Heavy coating for textile and other flexible flat structures The subject matter of the invention preferably provides a plastic coating a textile fabric, which is due to its high filling with iron powder characterized by a high density, which is desirable and has the consequence that, for. B. a floor covering, especially if it is used in the form of self-laying tiles becomes firmly on the ground due to the heavily shifted center of gravity lies.

Laying out the floor in living rooms and other rooms with carpets and floor coverings to achieve greater heat and sound insulation, step elasticity, Aesthetics and thus greater comfort are being practiced to an ever greater extent. Within The so-called self-laying enjoy the various types of floor coverings and lying tiles are very popular. Because the tiles are only one size 40 x 40 cm or 50 x 50 cm, the problem occurs relatively often that To make tiles non-slip in order to protect those walking them from the risk of slipping or stumble and thus prevent harm.

So far, you have simply helped yourself to the fact that you are on the underside The tiles use an adhesive or pressure sensitive adhesive that is up right before laying is covered with a film or paper layer or when laying on the The underside of the floor covering or painted on the floor to be covered is applied to the tile provides the necessary firm hold. However, when removing the tiles from the subfloor, undesirable blemishes arose a, such as B. the soiling of the floor with glue residue or such a good adhesion between the adhesive and the subfloor, that when the tiles are removed, parts of the subfloor, such as B. PVC, parquet, felt, cork, screed, etc. were torn out. the end For this reason one leaves the gluing process again and goes over to what is known as to use self-laying tiles.

The self-laying tiles should now be constructed in such a way that you The center of gravity is as close as possible to the floor, i.e.

their lower layer must consist of a so-called heavy coating, which should not be particularly thick, in order not to affect the textile character of the floor covering to be detrimental, yet must be heavy. The ones that have been used so far Coatings using e.g. B. of chalk, limestone powder and barite as common and cheap fillers do not meet this requirement; above all because they are in the plastics used as eppich back coatings cannot be filled in too high without the properties being considerable deteriorated, i.e. the plastics become brittle if the filling is too high, crumbly and rotten.

The task was therefore to develop a heavy coating, which remedies the existing deficiency. According to the invention, the procedure is as follows: In the plastic material commonly used for carpet backing, e.g. B. plasticizer-containing Polyvinyl chloride, hereinafter referred to as PVC for short, is fisen powder with a grain size from 0.1 to 250 microns mixed in. Serve as mixing tools mainly Dissolver, planetary mixer or other compulsory mixers. There is a wish here to mix in the filler as much as possible in order to achieve the heavy coating according to the invention with high density.

The amount of embedding depends primarily on the type of Plastic and, secondly, the mean grain size and the grain size distribution of the filler.

In the case of the PVC mentioned, using iron powder as a filler one finds the following dependency on the mean grain size of the iron powder: parts by weight as a mixture PVC 20 20 20 20 plasticizer (DOP) 20 20 20 20 iron powder 80 100 120 140 avg. Grain size in microns 25 50 100 150 Make the listed mixtures are easily spreadable pastes with a viscosity of 5000 to 10,000 cP, 2 can be gelled quickly and in thick layers of up to 8 kg / m2 and have after excellent flexibility to gelation. The dependency of the degree of filling of the plastic type is compared to the dependence on the mean grain size much more serious, like the following list of some distinctive plastics when using iron powder with an average grain size of 25 microns at a grain size distribution between 1 and 50 microns shows: Parts by weight in the mixture plastic iron powder low pressure polyethylene 90 10 high pressure polyethylene 70 30 rigid PVC (100 PVC: 30 DOP) 50 50 soft PVC (60PVC: 40 DOP) 30 atactic polypropylene 15 85 Polystyrene butadiene 5 95 With a higher filling the plastics lose so strongly their original properties that either their processing is not is more possible or its serviceability decreases so much that a large-scale Use can no longer be thought of.

When using iron powder as a filler according to the invention can offer the following advantages in comparison to conventional fillers the following can be identified: 1. high density of over 7, 2. high bulk density of 2.5 kg / l and thus less space required, 3. blown and thus transportable in dust carts, 4. low oil number and thus low plastic and plasticizer binding, which is a little impairment of the flexibility and the other properties of the plastic has the consequence, 5. excellent weather and aging resistance, 6. optimal Anti-droning and sound-absorbing effect, 7. Accelerated gelation and sintering of the plastic and shortening the cooling time and zone after leaving the hot channel or after application of the melt due to the high specific thermal conductivity, 8th. antistatic effect if the filling level is sufficiently high, 9. low wear of the stirring tools, Extruder, doctor blade, etc. because of the amorphous structure of the filler, 10th layers up to 8 kg / m2 can be applied and gelled in a single coat, 11. the abrasion resistance is higher than with other heavy fillers and therefore no crumbling der Kunststoffschicht1 12. Plasticizer migration is due to the possible high Degree of filling held back, 13. cold flow, e.g. in atactic polypropylene, is reduced, 14. flame-retardant effect is achieved, 15. high degree of filling is possible; Depending on the type of plastic, the ratio is 90 parts by weight of iron powder to 10 parts by weight of plastic can be achieved (see also the table above); in order to the finished mixture is significantly cheaper because the iron powder is incomparably cheaper than any common plastic including regrind, 16. Stabilizer effect e.g. in PVC.

Is used as a plastic in the heavy coating according to the invention PVC, you no longer need to use a stabilizer, because the elementary iron the acids formed during thermal or photochemical decomposition, such as e.g. hydrochloric acid or oxygen-containing chloric acids, chemically binds and thus one put a stop to further decomposition.

In addition, due to the dark color of the heavy coating, it penetrates Only little light, especially during exposure, and little due to the high packing density Oxygen into the heavy coating according to the invention, so that this causes degradation is held back.

Because of the excellent stability of the heavy coating Weathering and the associated decomposition, it offers itself as a roof tarpaulin for covering flat and other roofs and as a tarpaulin for trucks, Rail vehicles or stored goods and can be used successfully in these sectors can be used. Compared to conventional tarpaulins, e.g. made of PVC-coated Fabrics have a higher weight due to the heavy coating, which the self lying Xeppich fleece is round, does not interfere especially with the roof tarpaulin, as these are mostly free on the flat roof, i.e.

without it being glued on, is laid, so that the increased weight a fixed position of the tarpaulin results in what is desired.

The density of the heavy coating according to the invention is for example with a mixture of 30 parts by weight of soft PVO and 70 parts by weight of iron powder purely arithmetically over 5. In practice, however, only values between 2 and 2.5 are used found. This is due to the fact that the iron powder entrained air into the plastic which escapes very slowly due to the high viscosity of the paste. There the paste tends to sediment due to the high density of the iron powder and the iron powder turns into a very hard, cement-like powder that cannot be stirred up Form settles, the paste must be painted and gelled as soon as possible after preparation will. This has the consequence that the air in it is preserved in a mixture remains and thereby the density in the gelled, which does not correspond to the theory State results, which has already been mentioned above.

Nevertheless, the achieved density of about 2.5 is sufficient, the self-lying Plates to provide the quiet location due to their name, which is the real thing The object of the invention is. In some cases there is even a desire available, to achieve greater heat and sound insulation as well as greater elasticity to transform the heavy coating according to the invention into a heavy foam, i. e. the air content should be artificially increased. This desire seems to be the real one Objective to contradict the subject matter of the invention, However, this contradiction can be refuted by the following example: When coating tufted carpets one mainly uses mechanically whipped foam z. B.

made of styrene butadiene latex in a layer thickness of about 3 mm. This has proven itself for years, is relatively light with a liter weight of approx. 350 g and still gives the tufted carpet, which is very limp without this coating, a certain, desired stand without the total weight of the carpet being excessive to complicate. This type of coating is ideal for sheet goods. Not against but for the more and more demanded self-laying and self-laying tiles. These stand out slightly from the ground, undulate and are therefore unsatisfactory. In addition to the reasons listed above, there is no need for glue to be applied due to the fact that the foam is relatively unstable and not a great mechanical one Has strength. As a result, parts of the foam come off when it is lifted off the back of the tile can be torn out and the tile is seriously damaged can become what stands in the way of their further use.

In this case, the real desire for a heavy coating lies which is designed as a foam before. According to the invention one proceeds here so that the latex iron powder is mixed in as high a concentration as possible and the mixture It foams just as mechanically as if there were no iron powder, but no or it only contains common fillers. The resulting foam possesses with a correspondingly high filling with iron powder an approx. three times higher liter weight than the common foam. The weights are compared in the following table: Layer thickness Weight per square meter normal foam 3 mm 1050 g heavy foam 3 mm 2700 g In this case it is also a heavy coating, albeit in foam form.

The shear coating is applied to the textile carrier in many cases in paste form. This is for example described in detail PVC, as is the case with polyurethane, styrene butadiene, natural latex, acrylate, etc. However, there are also a number of application methods which, for. T. considerably from differ from the cold-coated paste.

PVC in particular can also be used as a non-paste-like type in the form of a hot, thick film are applied, as z. B.

is always the case with atactic polypropylene. Also can the plastic as a prefabricated film laminated with an adhesive or by melting it onto the carrier will.

It is also possible to have the heavy coating in the form of a powder or to sprinkle or squeegee pourable fine granules onto the textile material, whereby mostly by a subsequent thermal treatment that Powder or fine granulate sintered and sometimes then mechanically pressed to give the heavy coating better adhesion to the textile carrier.

Of course, you can also use other flexible fabrics such. B. Films made of plastic, cellulose, metal, etc., fleeces and fabrics made of metal wires and chips, paper, cardboard, flat structures made of split foils, etc. as a carrier for the Use heavy coating. Especially the coating of steel fiber fleeces with Heavy-duty coating containing iron powder makes sense, as this results in excellent flexibility Magnetic boards result.

The described subject matter of the invention is a Up to now not yet known and described innovation. For the heavy coating according to the invention the property right is sought.

Claims (5)

Claims 1.) Heavy coating for textile and other flexible flat structures, characterized in that it consists of a textile fabric coating, preferably floor coverings, common plastic, such as. 3. PVC, polyurethane, atactic polypropylene, polyethylene, polyacrylate, polystyrene butadiene, chlorinated rubber, Nitrile rubber, natural latex, silicone rubber, unsaturated polyester resins, epoxy resins, Rubber, bitumen, polyvinyl alcohol, polyvinyl acetate, etc. as well as mixtures and copolymers of those mentioned and the like Plastics, with a specific heavy filler, preferably of iron and its alloys, in a grain size of 0.1 to 250 microns such is filled that there is 20 to 95 percent by weight of metal powder in the finished mixture and 80 to 5 percent by weight of plastic are in the form of a paste, solution, hot melt, foil, powder, fine or free-flowing granulate, etc. on the textile fabric for the purpose of weighting and covering the same applied and on this by means of gelation, sintering, pouring, curing, pressing, Reverse process, dipping, gluing, flame lamination, etc. made to adhere will. 2.) Heavy coating for textile and other flexible flat structures according to claim 1, characterized in that in addition to or instead of preferably used Iron powder other metal powder, e.g. Zinc, aluminum, lead, titanium, chromium, molybdenum, copper, manganese, etc. or their alloys, such as. B. bronze, brass, etc., or mixtures thereof as well as other fillers, such as. B. barite, fluorspar, aluminum oxide, quartz flour, '' Glirnmermehl, slate flour, limestone flour, chalk, graphite, antimony trioxide, asbestos flour, Titanium dioxide, etc. used to increase the density of the heavy coat can be. 3.) Heavy coating for textile and other flexible flat structures according to claim 1 and 2, characterized in that they are for the purpose of better Heat and sound insulation as well as the greater elasticity than coarse or fine-pored Foam by means of chemical or mechanical foaming during or before application is applied to the textile fabric, with the character of a Heavy coating is retained, as other comparable plastic foams are consistently used has a density two to three times smaller. 4.) Heavy coating for textile and other flexible flat structures according to claim 1 to 3, characterized in that in addition to or instead of preferably used textile fabrics also other flexible fabrics such. B. Films made of plastic, cellulose, acetate, metal, rubber, etc., metal mesh and fiber fleece, Paper, cardboard, fabric and fleece made from cut or split foils, foam etc. can serve as a carrier for the heavy coating. 5.) Heavy coating for textile and other flexible flat structures according to claim 1 to 4, characterized in that the coating is on both Sides of the carrier can be located or that they are above and below the textile fabric is covered or'd that it is in the form of a composite body of several layers of support and coating compound is present or that there is practically only a single layer represents when z. B. as a carrier a large-pore fleece, a mesh fabric, a scrim etc. is used.