HU187183B - Flexible structural material of losse structure and method for producing same - Google Patents

Abstract

The present invention relates to a loose structure, a flexible structure material, and a method for producing such a product. The structural material according to the invention is composed of a fibrous material known per se, such as glass fiber, slag wool, natural or artificial textile material or a mixture thereof, and optionally having a topsheet, and the structural material being preferably a mesh or perforated film of thermoplastic polymerase. a set of elements is attached and, in addition to the mechanical bonding of the layers, are bonded by melting the polymer under heat transfer, and optionally, the product is provided with a protective coating as a third layer. The loose-structure, flexible structure material according to the invention can be used primarily for technical purposes, for example as an insulating material. -1-

Description

FIELD OF THE INVENTION The present invention relates to a loose structure, a flexible structural material consisting of natural and / or artificial fibers and having a uniform skeleton structure and a process for making such a product. The product according to the invention can be used primarily for technical purposes, for example as an insulating material for pipes and pipelines.

A solution is known in which an adhesive coating such as a polyethylene film is extruded onto a loose structure, such as a nonwoven material. In this case, the substrate structure of the material is formed by the connection of the filaments themselves. The strength of the structure is determined by the frictional force between the filaments, which depends on the fiber material used. This frictional force can be increased by known mechanical means. The strength of the structure can also be chemically secured or enhanced by the addition of an adhesive.

In another known embodiment, the surface of a loose structure material, such as a nonwoven fabric formed during a separate process operation, is sprayed with an adhesive polymeric powder, which is important in the after-treatment.

The known solutions have the disadvantage that the formation of the fibrous material and the formation of the adhesive layer on the material require a separate technological operation. The adhesive medium - polymer powder, adhesive film or adhesive film - is located on the surface and therefore the structures tend to separate the bonded layers. During use, the elastic properties of the structural layers vary, which is an undesirable phenomenon and can frustrate further use.

SUMMARY OF THE INVENTION The object of the present invention is to overcome the above-mentioned disadvantages and to provide a structural material of uniform structure, high strength and thus advantageous use.

It has now been found that this object is achieved by a loose, flexible structural material which is itself known from a fibrous material such as fiberglass, slag wool, natural or artificial textile raw material or a mixture thereof, optionally provided with a topcoat characterized by thermoplastic material. The polymer backbone, preferably mesh or perforated film, is located underneath and / or over a set of filaments and is bonded by mechanical bonding of the layers by melting the polymer under heat, optionally provided with a protective layer as the third layer.

The present invention is based on the discovery that the thermoplastic polymer backbone within the filament assembly, upon melting, simultaneously secures the product's skeletal structure and acts as an adhesive, virtually eliminating subsequent separation of the layers.

The thermoplastic polymer backbone of the present invention is preferably mesh and is preferably polyethylene and / or polypropylene.

Optional protective coatings may be, for example, leather, imitation leather, plastic or textile.

The loose structure flexible structure material of the present invention is prepared by the use of known fibrous materials such as fiberglass.

applying a thermoplastic polymer backbone to the fiber bundle layer of slag wool, natural or artificial fiber, or a mixture thereof, re-laying the fiber bundle layer, if desired, and then joining the layers with a needle felting; in a manner known per se, also provided with a topcoat.

The fiber set layer is formed in a manner known per se, for example by carding the filaments.

The thermoplastic polymer backbone and the fiber set layers are preferably bonded by needle felting.

According to the process of the present invention, the polymer backbone is bonded to one or two layers of fiber by needle felting. Needle felting causes holes or perforations in the polymer backbone to penetrate into the fiber bundle layer (s) to attach the polymer backbone to the fiber layer (s). The thermoplastic polymer backbone binds to the filaments after it has been melted and, after cooling, becomes inseparable from the weight of the filaments. In this way, the frame structure imparts very high strength to an otherwise loose material.

When melting the thermoplastic polymer backbone, pressure and temperature values depending on the type of polymer are used. The melting can be carried out, for example, on a hot air press or on a heated calendar.

The product thus obtained may optionally be provided with a protective cover. This can be achieved in a number of ways known per se, for example by gluing the topsheet or by spraying the surfaces with thermoplastic polymer particles such as powder and extruding the particles during heating. In the case where the polymer backbone is bonded to the filament layer only on one side, the other side can also be provided with a protective coating by applying heat and pressure, or the polymer backbone itself can be used to bond the third layer used as the protective coating.

The structural material according to the invention has a high strength, yet a flexible, loose structure. Even under significant stress, the individual interconnected layers do not separate. The polymer backbone in the fiber assembly does not form a closed film after melting, thus retaining the air permeability of the loose structure.

An advantage of the process according to the invention is the use of a solvent-free binder, a polymer skeleton. As a result, there is no need to impregnate or lubricate the feedstock with an adhesive dispersion, solution, or paste conventionally known in the art, thereby eliminating costly impregnating or lubricating lines and saving the heat needed to evaporate the solvents. The polymer backbone of the present invention may serve to attach a fiber layer of almost any fiber material.

The invention is illustrated by the following examples.

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Example 1

From 1.7 to 4.1 dtex / 38 to 65 mm of fine viscose staple fiber, a fiber having a specific gravity of 40 to 100 g / m ^{2 is} formed in a manner known per se and is stretched to a low density of 0.03 to 0.04 mm on a spinning machine. polyethylene / polypropylene polymer mesh. In this way, the weight of the fibrous material is applied to the polymeric mesh and thereafter acts as a support structure. The resulting semi-finished product is described below. It is passed through a heat calender heated to 120-130 ° C at a velocity of 0.16-0.2 m / s at a pressure of 25-30 N / cm. As a result of heat transfer, the polyethylene / polypropylene mesh softens, melts and binds to the filaments of the fibrous material; consequently, it improves the strength indexes of the fiber assembly.

The material thus obtained is pressed onto a third layer, which may be a fabric, on a press machine. The pressing is carried out at 160-170 ° C and 1.7 bar pressure for 15 seconds.

Example 2

A polyester staple of 1.5-6.7 dtex / 38-60 mm was prepared as described in Example 1 and passed through an infrared hot press at 400 ° C at 0.2 m / s using a cold pressure of 10-15 N / cm. . The products can be used as a shoe liner.

Claims (3)

Patent claims ). Loose-structured flexible structural material, known per se as fibrous material such as fiberglass, slag wool, natural or artificial textile raw materials or mixtures thereof, optionally with a cover layer characterized in that the thermoplastic polymer backbone is preferably mesh or perforated wood is a set of filaments. and are bonded by mechanical bonding of the layers by melting the polymer under heat, while. optionally, the product is provided with a protective layer as a third layer. 2. The l. The structural material according to claim 1, wherein the thermoplastic polymer backbone comprises polyethylene and / or polypropylene. 3. A process for the production of a loose structure, flexible structural material according to claim 1, characterized in that a fiber mat, preferably perforated, mesh or perforated is deposited on a fiber assembly formed from fibers known per se, such as fiberglass, slag wool, natural or artificial textile raw materials or mixtures thereof. optionally re-laying the fiber assembly layer, then mechanically joining the layers with a needle felting, then melting the thermoplastic polymer backbone to apply adhesive at the same time as applying heat and pressure, and optionally shielding said structural material in a manner known per se.