WO2016170129A1 - Use of fibre-composites for producing technical textiles - Google Patents

Abstract

The invention relates to the use of a thermoplastic fibre-composite, containing: a) at least one thermoplastic moulding compound (A) as a matrix, b) at least one layer made of reinforcing fibres (B), and c) optionally at least one additive (C), which is particularly suitable for producing technical textiles. The at least one layer of the reinforcing fibres (B) is embedded in the matrix and the thermoplastic moulding compound (A) has elastomer characteristics and at least one chemically reactive functionality, which reacts with chemical groups of the surface of the reinforcing fibres (B) during the production process of the fibre composite.

Description

 Use of fiber composite materials for the production of technical textiles

The present invention relates to the use of a fiber composite material (also called organic sheet) for the production of technical textiles, the fiber composite material comprising a thermoplastic molding material A, which has elastomeric properties, and at least one layer of the reinforcing fibers B. The at least one layer of the reinforcing fibers B is embedded in the matrix of the thermoplastic molding compound A, the thermoplastic molding compound A having at least one chemically reactive functionality during the production of the material.

Fiber composite materials or organic sheets usually consist of a multiplicity of reinforcing fibers which are embedded in a polymer matrix. The fields of application of fiber composite materials are manifold. For example, fiber composite materials are used in the vehicle and aviation sectors. Here, fiber composite materials are to prevent the occurrence of total failure (such as tearing or other fragmentation) in order to reduce the risk of accidents through distributed component networks. Many fiber composite materials are able to absorb relatively high forces under load before it comes to a total failure. At the same time, fiber composite materials are distinguished by high strength and rigidity, combined with low density and other advantageous properties such as, for example, good aging and corrosion resistance, compared to conventional, non-reinforced materials.

Strength and rigidity are adaptable to the load direction and load type. Here, the fibers are primarily responsible for the strength and rigidity of the fiber composite material. In addition, their arrangement determines the mechanical properties of the respective fiber composite material. On the other hand, the matrix mostly serves primarily for introducing the forces to be absorbed into the individual fibers and for maintaining the spatial arrangement of the fibers in the desired orientation. Since both the fibers and the matrix materials are variable, numerous combinations of fibers and matrix materials come into consideration.

In the production of fiber composite materials, the connection of fibers and matrix to one another plays an essential role. The strength of the embedding of the fibers in the polymer matrix (fiber-matrix adhesion) can also have a considerable influence on the properties of the fiber composite material. To optimize fiber-matrix adhesion and to compensate for "low chemical similarity" between the fiber surfaces and the surrounding polymer matrix, reinforcing fibers are regularly pretreated. For this purpose, so-called sizing agents (sizing agents) are regularly added to adhesion promoters. Such sizing is applied regularly to the fiber during manufacture in order to improve the further processibility of the fibers (such as weaving, laying, sewing). If the sizing is undesirable for subsequent processing, it must first be removed in an additional process step, such as by burning down. In some cases, glass fibers are also processed without sizing. Then, a further adhesion promoter is applied in an additional process step for the production of the fiber composite material. Sizing and / or adhesion promoters form on the surface of the fibers a layer which can substantially determine the interaction of the fibers with the environment. Today, a variety of different adhesion agents are available. Depending on the field of application, the matrix to be used and the fibers to be used, the person skilled in the art can select a suitable adhesion promoter which is compatible with the matrix and with the fibers.

A technical challenge is that if the total failure occurs, the fiber composite material may suffer a brittle fracture. Consequently, for example, in the manufacture of technical textiles, which are regularly exposed to high stress, pose a significant risk of accident of torn fibers.

Therefore, it is desirable to provide fiber composite materials with a wide load range where total failure is unlikely. Desirable are also good optical properties, as well as the ability to produce by means of fiber composite materials components with smooth surfaces.

WO 2008/058971 describes molding compositions which use two groups of reinforcing fibers. The groups of reinforcing fibers are each provided with different adhesion promoter components which effect the different fiber matrix adhesions. The second fiber-matrix adhesion is less than the first fiber-matrix adhesion, and the near-surface layers of reinforcing fibers of reinforcing fibers of the first group are formed with greater fiber matrix adhesion. The matrix materials proposed are thermosetting plastics such as polyester and the thermoplastics polyamide and polypropylene.

WO 2008/1 19678 describes a glass-fiber-reinforced styrene-acrylonitrile copolymer (SAN) which is obtained by using maleic anhydride group-containing styrene Copolymer and cut glass fibers in its mechanical properties is improved. It is therefore taught the use of short fibers. It is therefore taught the use of short fibers. However, there is no indication of fiber composite materials.

CN 102924857 Blends of styrene-maleic anhydride copolymers which are blended with chopped glass and then show relatively high strengths.

However, the stress cracking resistance of such a material to solvents is too low. The strength compared to fiber optic connections is clearly too low.

CN 101555341 describes mixtures of acrylonitrile-butadiene-styrene (ABS), glass fibers, maleic anhydride-containing polymers and epoxy resins. In the manufacture of ABS and the maleic anhydride-containing polymer are initially charged to add the epoxy resin and then the glass fibers. The fluidity of such a mixture containing a (thermoset) epoxy resin is very limited.

KR 100376049 teaches mixtures of SAN, maleic anhydride and N-phenyl maleimide-containing copolymer, chopped glass fibers and an aminosilane-based coupling agent. The use of such a coupling agent leads to additional processing steps and thus increases the production costs.

US 201 1/0020572 describes organic sheet components having a hybrid design of, for example, a high flow polycarbonate component. In this process, polycarbonate (PC) is rendered flowable by suitable additives, such as hyperbranched polyesters, ethylene / (meth) acrylate copolymers or low molecular weight polyalkylene glycol esters.

EP-A 2 251 377 describes organo-sheets treated with an aminosilane size. It is not taught to use organic sheets for the production of technical textiles.

(Glass) fibers are often treated in the prior art with a sizing, which protect each other especially the fibers. Mutual damage due to abrasion should be prevented. When mutual mechanical action should not come to the transverse fragmentation (fracture).

Furthermore, by means of the sizing, the cutting process of the fiber can be facilitated in order to obtain, above all, an identical staple length. In addition, the size can be used to avoid agglomeration of the fibers. The dispersibility of short fibers Water in water can be improved. Thus, it is possible to obtain uniform sheets by the wet laying method.

A sizing may help to produce improved cohesion between the glass fibers and the polymer matrix in which the glass fibers act as reinforcing fibers. This principle is mainly used in glass fiber reinforced plastics (GRP).

So far, the glass fiber sizes generally contain a large number of constituents, such as film formers, lubricants, wetting agents and adhesion promoters.

A film former protects the glass filaments from mutual friction and, in addition, can enhance affinity for synthetic resins, thus promoting the strength and integrity of a composite. Starch derivatives, polymers and copolymers of vinyl acetate and acrylic esters, epoxy resin emulsions, polyurethane resins and polyamides in a proportion of 0.5 to 12 wt .-%, based on the total size, are mentioned.

A lubricant gives the glass fibers and their products suppleness and reduces the mutual friction of the glass fibers, as well as during manufacture. Often, however, the adhesion between glass and resin is compromised by the use of lubricants. Fats, oils and polyalkyleneamines in an amount of 0.01 to 1 wt .-%, based on the total size, are mentioned.

A wetting agent causes a lowering of the surface tension and an improved wetting of the filaments with the size. For aqueous sizes, for example, polyfatty acid amides in an amount of 0.1 to 1, 5 wt .-%, based on the total size to name.

Often there is no suitable affinity between the polymer matrix and the glass fibers. This bridging can take over adhesion promoters, which increase the adhesion of polymers to the fiber surface. Most organo-functional silanes, such as aminopropyltriethoxysilane, methacryloxypropyltrimethoxysilane, glycidyloxypropyltrimethoxysilane and the like can be mentioned.

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Silanes which are added to an aqueous sizing are usually hydrolyzed to silanols. These silanols can then react with reactive (glass) fiber surfaces and thus form an adhesive layer (with a thickness of about 3 nm). As a result, low molecular weight functional agents can react with silanol groups on the glass surface, with these low molecular weight agents subsequently reacting further (for example, in epoxy resins), thereby providing chemical bonding of the glass fiber to the polymer matrix. However, such a preparation is time-consuming and lasts until complete curing of the polymers (for example the abovementioned epoxy resins) approximately between 30 minutes to more than one hour.

It therefore appears desirable to bring already polymerized melts in conjunction with glass fibers or other reinforcing fibers in an improved process.

A functionalization by reaction with polymers is also known. Thus, by using low-molecular-weight polycarbonate types, it is possible to impregnate the glass fiber fabric and to perform a "grafting" by reacting functional groups on the glass fiber surface with the polycarbonate, which increases the compatibility with the polymer the disadvantage that polycarbonate (PC) has a very high viscosity and for this impregnation step low molecular weight, ie low viscosity PC must be used, which has an extremely poor usability, such as a low resistance to stress cracking agents, such as polar solvents has.

A technical object of the invention is to produce a fiber composite material (organogelc) which has suitable properties for the production of technical textiles. The fiber composite material should be based on an easy-to-process, highly solvent-resistant, high stress-crack resistant, solid composite material and have a smooth surface. Ideally, the fiber composite material comes without adhesion promoter.

It has surprisingly been found that a fiber composite material comprising at least one thermoplastic molding composition A, which has elastomeric properties, as a matrix, at least one layers of reinforcing fibers B, and optionally at least one additive C, wherein the at least one layer of the reinforcing fibers B in the matrix is embedded, and the thermoplastic molding compound A has at least one chemically reactive functionality, which reacts with chemical groups of the surface of the reinforcing fibers B during the manufacturing process of the fiber composite material, is particularly suitable for the production of technical textiles. The resulting fiber composite material has good strength and is tearing and solvent resistant.

One aspect of the present invention relates to the use of a thermoplastic fiber composite material comprising (or consisting of)

a) at least one thermoplastic molding compound A as matrix,

b) at least one layer of reinforcing fibers B, and

c) optionally at least one additive C, wherein the at least one layer of reinforcing fibers B is embedded in the matrix and wherein the thermoplastic molding composition A has elastomeric properties and at least one chemically reactive functionality during the manufacturing process of the thermoplastic fiber composite material, which in the manufacturing process of the fiber composite Material with chemical groups of the surface of reinforcing fibers B reacts for the production of technical textiles.

In other words, the present invention also relates, in other words, to a process for producing technical textiles comprising the following steps: (i) providing

 a) at least one thermoplastic molding compound A as matrix,

 b) at least one layer of reinforcing fibers B, and

 c) optionally at least one additive C,

wherein the at least one layer of the reinforcing fibers B is embedded in the matrix of the thermoplastic molding composition and the thermoplastic molding compound A has at least one chemically reactive functionality which reacts with chemical groups of the surface of component B during the manufacturing process of the fiber composite material; (ii) contacting the components A and B, and optionally C, with each other, in particular by loading or coating the component B with a (preferably obtained by heating) viscous or liquid thermoplastic molding compound A, optionally further containing at least one additive C; and (iii) reacting the at least one chemically reactive functionality of component A with chemical groups of the surface of component B. Optionally, a received textile part (such as a fabric) can be sewn subsequently with one or more other textile parts according to the invention and / or one or more other textile parts according to the invention. The fiber composite materials according to the invention can be designed so that they are printable and / or partially translucent. As a result of the partial translucency and printability, the fiber composite materials according to the invention can be used to produce a variety of technical textiles which are particularly readily dyeable. The invention particularly relates to the use of a thermoplastic fiber composite material as described above, containing (or consisting of) a) 30 to 95, in particular 45 to 80 wt .-%, particularly preferably 38 to 70 wt .-%, of the thermoplastic molding composition A. with elastomeric properties,

b) 5 to 70 wt .-%, in particular 10 to 54.9 wt .-%, particularly preferably 29.9 to 61, 9 wt .-%, of the reinforcing fibers B, and

c) 0 to 40, in particular 0.1 to 10 wt .-%, of at least one additive C.

The person skilled in the art will understand that the thermoplastic molding composition A according to the invention comprises at least one (co) polymer having at least one chemically reactive functionality which reacts with chemical groups on the surface of the reinforcing fiber component B during the manufacturing process of the fiber composite material , Such a (co) polymer comprises at least one functional monomer A-1 whose functionality reacts with chemical groups on the surface of the reinforcing fiber component B during the production process of the fiber composite material. The (co) polymer comprising monomer A-1 is also referred to herein as polymer component (A-a).

Optionally, the thermoplastic molding composition A may contain one or more (co) polymers which are optionally also free of such a chemically reactive functionality (therefore contain no functional monomer Al) and thus not with chemical groups on the surface during the manufacturing process of the fiber composite material the reinforcing fiber component B react. Such a (co) polymer is also referred to herein as polymer component (A-b).

The invention particularly relates to the use of a thermoplastic fiber composite material as described above, wherein the thermoplastic molding material A is amorphous. In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the thermoplastic molding material A is amorphous and is based on an impact-modified styrene copolymer which has at least one chemically reactive functionality. Often, A is a SAN copolymer modified by monomers having a chemically reactive functionality.

Such a styrene copolymer, when used as the polymer component (A-a), may be about a M-1-containing styrene copolymer (exemplified by a maleic anhydride-containing styrene copolymer). "Based thereon" is to be understood in the broadest sense as containing said component (s), preferably the said component (s) being greater than 50% by weight, more preferably greater than 75% by weight. even more preferably more than 90% by weight, even more preferably more than 95% by weight, or (largely) consisting of said component (s).

In a further embodiment, the invention particularly relates to the use of a thermoplastic fiber composite material as described above, wherein the matrix is based on a molding compound A which has at least one chemically reactive functionality, wherein the molding compound A is selected from the group consisting of: Styrene-based elastomers (S-TPE), hydrogenated or partially hydrogenated styrene-butadiene (block) copolymers, polyolefin-based thermoplastic elastomers, thermoplastic polyurethanes, and elastomeric polyether / esters (eg, polyester-based elastomer (e.g., of the HYTREL® type), if necessary; in mixture with polymers such as: polystyrene (transparent or impact-resistant), styrene-acrylonitrile polymers, acrylonitrile-butadiene-styrene copolymers, styrene-methyl methacrylate copolymers (SMMA), methacrylate-acrylonitrile-butadiene-styrene copolymers (MABS) or acrylic ester-styrene-acrylonitrile copolymers (ASA).

It will be understood that according to the invention at least one of the (co) polymer components of the thermoplastic molding material A is a (co) polymer having at least one chemically reactive functionality as described herein (polymer component (A-a)). Each of the copolymer components mentioned in the preceding paragraph can accordingly also have, in addition to the explicitly mentioned monomers, a reactive functionality which can react with the surface of the fibers B during the production of the fiber composite material. Thus, each of the above-mentioned (co) polymers may also be a polymer component (A-a).

Accordingly, the above-mentioned polymer components in their use as polymer component (Aa) usually also at least one monomer Al, which mediates the chemically reactive functionality (hence the reaction with fibers B). Optionally, the polymer components mentioned above in their use as polymer component (Aa) may also additionally comprise a second monomer (or even a third monomer) which mediates the chemically reactive functionality.

Optionally, one or more of any other (co) polymers without such functionality (as polymer component (A-b)) may be used in addition to the one or more polymer component (s) (A-a). Here too, by way of example, the abovementioned (co) polymers can be used, but then without the functionality (therefore without reactive monomer A-1).

Particularly preferably, the polymer component (A-a) of the thermoplastic molding composition A is based on a SAN copolymer. The person skilled in the art will recognize that the SAN copolymer then additionally comprises a monomer A-1 which reacts with the surface of the fibers B during the production process. Accordingly, the SAN copolymer in its use as polymer component (Aa) may also be a SAN (MI) copolymer (= SAN (MI) terpolymer), for example a SAN-MA copolymer (= SAN-MA copolymer). terpolymer).

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the chemically reactive functionality of the thermoplastic molding composition A based on components selected from the group consisting of maleic anhydride, N-phenylmaleimide, tert-butyl (meth ) acrylate and glycidyl (meth) acrylate function, preferably selected from the group consisting of maleic anhydride, N-phenylmaleimide and glycidyl (meth) acrylate function.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the thermoplastic molding material A 0.1 to 10 wt .-%, often 0.15 to 3 wt .-%, of monomers Al, based on contains the amount of component A, which have a chemically reactive functionality. In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the reinforcing fibers B consist of glass fibers which preferably contain as chemical-reactive functionality silane groups on the surface. In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the surface of the reinforcing fibers B contain one or more of the chemically reactive functionalities from the group: hydroxyl, ester and amino groups.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the reinforcing fibers B consist of glass fibers which contain (preferably) as chemically reactive functionality silanol groups on the surface.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the reinforcing fibers B are used in the form of a mat, a fabric, a mat, a nonwoven or a knitted fabric.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the fiber composite material has a thickness of <10 mm, preferably of <2 mm, in particular of <1 mm.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, wherein the fiber composite material is layered and contains more than two layers. By way of example, the other layers may be the same or different in construction from those described above.

In a further embodiment, the invention particularly relates to the use of a thermoplastic fiber composite material as described above, for the production of surface materials for sports, leisure and safety shoes.

In a further embodiment, the invention relates to the use of a thermoplastic fiber composite material as described above, for the production of covers for high mechanical loads, in particular for sails.

In a further embodiment, the invention relates to a method for producing a thermoplastic fiber composite material as described above, comprising the steps: (i) providing:

 (A) a matrix of at least one thermoplastic molding material A having elastomeric properties, comprising a copolymer A-1 containing monomers A-1 having a chemically reactive functionality;

 (B) at least one reinforcing fiber B, the surface of which has a chemically reactive functionality B-1 capable of forming a covalent bond with the monomers A-1;

 (ii) melting the thermoplastic molding material A and adding this molding compound A to the reinforcing fiber B from step (i); and

(iii) reacting the monomers A-1 of the copolymer A-1 with the chemically reactive functionality B-1 of the reinforcing fibers B from step (ii) to form covalent bonds.

In a further embodiment, the invention relates to technical textiles, produced from a fiber composite material as described above, which was produced as described above after the steps (i) to (iii).

 In a further embodiment, the invention relates to textiles produced from a thermoplastic fiber composite material as described above containing (or consisting of) the components A to C.

Component A

The fiber composite material contains at least 20 wt .-%, usually at least 30 wt .-%, based on the total weight of the fiber composite material, the thermoplastic matrix M or the thermoplastic molding composition A, which has elastomeric properties (molding material A). The thermoplastic molding compound A can also be referred to as a thermoplastic or (partially) crosslinked elastomer molding compound A. The thermoplastic matrix (M) containing the molding compound A is in the fiber composite material preferably from 30 to 95 wt .-%, particularly preferably from 35 to 90 wt .-%, often from 35 to 75 wt .-% and in particular from 38 to 70% by weight, based on the fiber composite material, available. The thermoplastic matrix M preferably corresponds to the thermoplastic molding compound A.

Preferably, the molding material A consists mainly (more than 50%, in particular more than 90%) of a copolymer (A-1). According to one embodiment, the molding material A is at least 75 wt .-%, preferably at least 90 wt .-% of the copolymer A-1. The thermoplastic molding compound A can also consist only of copolymer A-1. For a fiber composite material according to the invention, although any thermoplastics having elastomeric properties are suitable as molding material A, in particular styrene-based elastomers (S-TPE), hydrogenated or partially hydrogenated styrene-butadiene (block) copolymers, thermoplastic elastomers on polyols fin-base, thermoplastic polyurethanes and elastomeric polyether / esters of HYTREL® type used, if appropriate mixed with non-impact modified or impact-modified styrene copolymers, preferably acrylonitrile-butadiene-styrene copolymers (ABS), Methacrylate-acrylonitrile-butadiene-styrene copolymers (MABS) and acrylic ester-styrene-acrylonitrile copolymers (ASA).

As already explained above, the skilled person will understand that according to the invention at least one of the (co) polymer components of the thermoplastic molding composition A is a (co) polymer having at least one chemically reactive functionality as described herein (polymer component (Aa)) , Accordingly, it is preferred that at least one of the abovementioned polymer components (therefore at least one (optionally modified) polystyrene and / or at least one copolymer A-1 comprises at least one monomer A-1.

By way of example, in the case of using maleic anhydride (MA) as monomer A-1, the polystyrene may therefore be a polystyrene-maleic anhydride copolymer.

Optionally, in addition to the at least one polymer component (A-a), one or more further optional (co) polymers without such functionality (as polymer component (A-b)) can be used. It will be understood that this may optionally also be polystyrene and / or a copolymer A-1 (each comprising no monomer A-1).

The thermoplastic molding compound A (component A) is preferably an amorphous molding compound, wherein amorphous state of the thermoplastic molding compound (thermoplastic) means that the macromolecules without regular arrangement and orientation, i. without constant distance, are arranged completely statistically.

Preferably, the entire component A has amorphous, thermoplastic properties, is therefore fusible and (largely) non-crystalline. As a result, the shrinkage of the component A, and therefore also of the entire fiber composite material, is comparatively low. Especially smooth surfaces can be obtained with the technical textiles. Alternatively, the component A contains a partially crystalline fraction of less than 50 wt .-%, preferably less than 40 wt .-%, based on the total weight of component A. Semi-crystalline thermoplastics form both chemically regular, as well as geometric areas, ie there are areas, in which crystallites form. Crystallites are parallel bundles of molecular segments or folds of molecular chains. Individual chain molecules can partially pass through the crystalline or the amorphous region. Sometimes they can even belong to several crystallites at the same time. The thermoplastic molding compound A can also be a blend of amorphous thermoplastic polymers and semicrystalline polymers. Component A may be, for example, a blend of an impact-modified styrene-acrylonitrile copolymer with one or more polycarbonate (s) and / or one or more partially crystalline polymers (such as polyamide), the proportion of partially crystalline mixed components in the entire component A being less than 50% by weight .-%, preferably less than 40 wt .-%, often less than 25 wt .-% should be.

According to the invention, the component A used comprises at least one copolymer A-1 which comprises monomers A-1 which form covalent or non-covalent bonds with the functional groups B-1 of the embedded reinforcing fibers B.

The proportion of monomers Al in the component A can be chosen variable. The higher the proportion of monomers Al and the functional groups (B1), the stronger the bond between the molding compound A and the reinforcing fibers B can be. Monomers Al may still be present as monomers in copolymer A-1 or may be incorporated into copolymer A-1. Preferably, the monomers Al are incorporated in the copolymer A-1. According to a preferred embodiment, the copolymer A-1 is constructed with a proportion of monomers A1 of at least 0.1% by weight, for example from 0.1 to 10% by weight, preferably of at least 0.5% by weight, in particular of at least 1 wt .-%, z. B. from 1 to 3 wt .-%, based on A-1. As monomers Al, which can form covalent bonds with the functional groups Bl of the fibers B, all monomers are suitable which have such properties. As monomers A1, preference is given to those which can form covalent bonds by reaction with hydroxyl or amino groups. Preferably, the monomers Al have:

(a) at least one functionality capable of entering into covalent bonds with the functional groups B-1 of the surface of the fibers B (such as by reaction with hydroxy and / or amino groups); and

(B) at least one second functionality which is capable of being incorporated into the copolymer A-1, for example a double bond, preferably a terminal double bond, which is incorporated by means of radical polymerization in the copolymer A-1.

Optionally, copolymer A-1 or other (co) polymer contained in component A may contain one or more other monomers capable of covalent or noncovalent bonding with fibers B.

According to a preferred embodiment, the monomers A-I are selected from the group consisting of:

Maleic anhydride (MA),

 N-phenylmaleimide (PM),

 tert-butyl (meth) acrylate and

 Glycidyl (meth) acrylate (GM).

According to a more preferred embodiment, the monomers A-1 are selected from the group consisting of maleic anhydride (MA), N-phenylmaleimide (PM) and glycidyl (meth) acrylate (GM).

Also, two of these monomers A-1 may be contained in the copolymer A-1. The copolymer A-1 of the molding compound A may optionally contain further functional monomers A-II.

The matrix component M contains at least one thermoplastic molding compound A, in particular one suitable for the production of fiber composite materials. For the molding compound A, amorphous thermoplastics having elastomeric properties are preferably used. For example, impact-modified styrene-acrylonitrile copolymers, such as acrylonitrile-butadiene-styrene copolymers (ABS), styrene-methyl methacrylate copolymers (SMMA), methacrylate-acrylonitrile-butadiene-styrene copolymers (MABS) or acrylic ester-styrene-acrylonitrile Copolymers (ASA), wherein the impact-modified styrene-acrylonitrile copolymers with monomers (Al) are modified.

It will be understood that in this case at least one of the polymer components in the thermoplastic molding composition A is modified with monomer A-1 (polymer component (A-a)), preferably one or more of the abovementioned styrene copolymers is modified with monomer A-1. Any other polymer components (for example styrene copolymers, preferably those as mentioned above) may optionally be additionally present in the thermoplastic molding composition A, which are not optionally modified with monomer A-1 (polymer component (A-b)).

Blends of the abovementioned copolymers (one or more polymer components (Aa) and optionally (Ab)) with polycarbonate or partially crystalline polymers such as polyamide are also suitable, provided that the proportion of partially crystalline mixed components in component A is less than 50% by weight .%. Very particular preference is given to using SAN (M-1) copolymers (with modification by monomers A-1) as component of the thermoplastic molding composition A (optionally also as sole polymeric constituent). Blends of the abovementioned styrene copolymers with polycarbonate or partially crystalline polymers such as polyamide are also suitable, provided that the proportion of partially crystalline mixed components in component A is less than 50% by weight. Preference is given to using ABS copolymers (with modification by monomers A-1) as component A.

An inventive (a-methyl) styrene-methyl methacrylate copolymer (as polymer component (Aa)) as molding compound A is prepared from, based on the (o-methyl) styrene-methyl methacrylate copolymer, at least 50 wt .-%, preferably 55 to 95 wt .-%, particularly preferably 60 to 85 wt .-%, (a-methyl) styrene, and 4.9 to 45 wt .-%, preferably 14.9 to 40 wt%, methyl methacrylate and 0.1 to 5% by weight, preferably 0.1 to 3% by weight, of a monomer Al, such as maleic anhydride. The (a-methyl) styrene-methyl methacrylate copolymer may be random or a block polymer. Component A can also be prepared from, based on component A, at least 50% by weight, preferably 55 to 95% by weight, particularly preferably 60 to 85% by weight, of vinylaromatic monomer, 4.9 to 45% by weight. %, preferably 14.9 to 40% by weight, methyl methacrylate and 0.1 to 5 wt .-%, preferably 0.1 to 3 wt .-%, of a monomer Al, such as maleic anhydride. An inventive acrylonitrile-butadiene-styrene copolymer as component A is prepared by known methods from styrene, acrylonitrile, butadiene and a functional further monomer Al, such as. For example, methyl methacrylate. The modified ABS copolymer may, for. For example, up to 70% by weight (about 35 to 70% by weight) of butadiene, up to 99.9% by weight (about 20 to 50% by weight) of styrene and up to 38% by weight. % (about 9 to 38 wt%) of acrylonitrile and 0.1 to 20 wt%, preferably 0.1 to 10, more preferably 0.1 to 5, especially 0.1 to 3 wt% of a monomer A- I, such as maleic anhydride. Component A can also be prepared from 3 up to 70% by weight (about 35 to 70% by weight) of at least one conjugated diene, up to 99.9% by weight (about 20 to 50% by weight) of at least one vinyl aromatic monomer and up to 38 wt .-% (about 9 to 38 wt .-%) of acrylonitrile and 0.1 to 20 wt .-%, preferably

0.1 to 10, more preferably 0.1 to 5, especially 0.1 to 3 wt .-%, of a monomer A-l, such as maleic anhydride.

According to a preferred embodiment, the modified ABS copolymer (as polymer component (Aa)) may contain: 35 to 70% by weight of butadiene, 20 to 50% by weight of styrene and 9.9 to 38% by weight of acrylonitrile, and 0.1 to 5 wt .-%, preferably 0.1 to 3 wt .-%, of a monomer Al, such as maleic anhydride. Component A can also be prepared from 35 to 70% by weight of at least one conjugated diene, 20 to 50% by weight of at least one vinylaromatic monomer and 9.9 to 38% by weight of acrylonitrile and 0.1 to 5% by weight. %, preferably 0.1 to 3 wt .-%, of a monomer A-

1, such as maleic anhydride. In a further preferred embodiment, the inventive component A is a styrene / butadiene copolymer such as impact polystyrene, a styrene-butadiene block copolymer such as Styrolux®, Styroflex®, K-Resin, Clearen, Asaprene, a polycarbonate, an amorphous polyester or an amorphous polyamide. The person skilled in the art will understand that according to the invention at least one of the (co) polymer components of the thermoplastic molding composition A is a (co) polymer which has at least one chemically reactive functionality as described herein (polymer component (Aa)). This may also be a polymer component as described above, which contains at least one functional monomer A1 in said molding composition. Optionally, one or more other (co) polymers without such functionality (as the polymer component (Ab)) can be used. Further preferred matrix materials as component A are styrene-based elastomers ("S-TPE"), which are known, inter alia, as Kraton® or Asaflex, which are preferably materials comprising linear, branched or star-shaped styrene-butadiene Hydrogenated or partially hydrogenated styrene-butadiene (block) copolymers may also be used, as are polyolefin-based thermoplastic elastomers, so-called TPOs, which may include polyethylene and / or polypropylene (block) copolymers, Likewise, thermoplastic polyurethanes ("U-TPE") are among the possible matrix materials as component A, as well as technical elastomers (such as, for example, polyether / ester elastomers of the HY-type polyether / ethylene-propylene-diene PP / EPDM). TREL® type). Particularly preferred are thermoplastically processable elastomers.

It will be understood that in this case at least one of the polymer components in the thermoplastic molding composition A is modified with monomer A-1 (polymer component (A-a)), preferably one or more of the abovementioned styrene-based elastomers is modified with monomer A-1. Optionally, one or more other (co) polymers without such functionality (as polymer component (A-b)) can be used. In a further embodiment, the matrix M can consist of at least two mutually different molding compositions A. For example, these various molding compound types may have a different melt flow index (MFI), and / or other co-monomers or additives. According to the invention, the term molecular weight (Mw) in the broadest sense can be understood as the mass of a molecule or a region of a molecule (eg a polymer strand, a block polymer or a small molecule) which is in g / mol (Da) and kg / mol (kDa) can be specified. Preferably, the molecular weight (Mw) is the weight average which can be determined by the methods known in the art.

The molding compositions A preferably have a molecular weight Mw of from 60,000 to 400,000 g / mol, often from 80,000 to 350,000 g / mol, where Mw can be determined by light scattering in tetrahydrofuran (GPC with UV detector). The molecular weight Mw of component A can vary within a range of +/- 20%.

Component A preferably contains a styrene copolymer modified by a chemically reactive functionality, which, apart from the addition of the monomers A1, is composed essentially of the same monomers as the "normal styrene copolymer". Copolymer ", wherein the monomer content +/- 5%, the molecular weight +/- 20% and the melt flow index (determined at a temperature of 220 ° C and a load of 10 kg according to the ISO method 1 133) +/- 20% ISO Method 1 133 will preferably be understood as meaning DIN EN ISO 1 133-1: 2012-03.

According to a preferred embodiment, the melt flow rate (melt volume rate MVR), the thermoplastic polymer composition used as the polymer matrix A 10 to 70 cm ^3/10 min, preferably 12 to 70 cm ^3/10 min, particularly 15 to 55 cm ^3/10 min at 220 ° C / 10kg (measured according to IS01 133).

According to a particularly preferred embodiment, the melt flow rate is (Melt Volume rate, MVR) of the thermoplastic polymer composition used as the polymer matrix A 10 to 35 cm ^3/10 min, preferably 12 to 30 cm ^3/10 min, particularly 15 to 25 cm ^3/10 min at 220 ° C / 10kg (measured according to IS01 133).

Alternatively, the melt flow rate (melt volume rate MVR) of the thermoplastic polymer composition used as the polymer matrix A 35 to 70 cm ^3/10 min, preferably 40 to 60 cm ^3/10 min, in particular 45 to 55 cm ^3/10 min at 220 ° C / 10kg (measured according to IS01 133).

Alternatively or additionally, the viscosity number (J = (η / η ₀ -1) ^■ 1 / c) of the thermoplastic polymer composition A used as polymer matrix, measured at room temperature (20 ° C.) for granules dissolved in dimethylformamide, can be determined by means of a capillary viscometer. 50 to 100 ml / g, preferably 55 to 85 ml / g. According to a preferred embodiment, the viscosity number is 55 to 75 ml / g, preferably 60 to 70 ml / g, in particular 61 to 67 ml / g. According to an alternative preferred embodiment, the viscosity number is 60 to 90 ml / g, preferably 65 to 85 ml / g, in particular 75 to 85 ml / g. Suitable preparation methods for component A are emulsion, solution, bulk or suspension polymerization, preference being given to solution polymerization (see GB 1472195). In a preferred embodiment of the invention, component A is isolated after the preparation by processes known to those skilled in the art, and preferably processed into granules. Thereafter, the production of the fiber composite materials can take place.

Component B The fiber composite material (organic sheet) contains at least 5 wt .-%, based on the fiber composite material, the reinforcing fiber B (component B). The reinforcing fiber B in the fiber composite material is preferably from 5 to 70% by weight, particularly preferably from 10 to 65% by weight, often from 25 to 65% by weight and in particular from 29.9 to 61, 9 wt .-%, based on the fiber composite material included.

The reinforcing fiber B is preferably used as the sheet F. The reinforcing fiber B can be any fiber whose surface has functional groups which can form a covalent bond with the monomers A-1 of the component A, which have a chemically reactive functionality.

According to a preferred embodiment, the fabrics F fabrics, mats, nonwovens, scrims or knitted fabrics. Also, additionally or alternatively, continuous fibers (including fibers which are the product of a single fiber twist) may be employed as the reinforcing fibers B in the fiber composite material. The reinforcing fibers B are therefore preferably not short fibers ("chopped fibers") and the fiber composite material is preferably not a short glass fiber reinforced material At least 50% of the reinforcing fibers B preferably have a length of at least 5 mm, more preferably at least 10 mm or more than 100 The length of the reinforcing fibers B also depends on the size of the fabric made from the fiber composite material.

It is known to the person skilled in the art that a fabric, fabric or knitted fabric differs from short fibers, since in the former, coherent, larger fabrics F are produced, which as a rule will be longer than 5 mm. The person skilled in the art knows that in this case the fabrics, scrims, knitted fabrics, etc. are preferably present in such a way that they pass (largely) through the fiber composite material. Therefore, the fabrics or scrims are preferably such that they (substantially) pull through the existing of the fiber composite material textile. Pull through extensively here means that the fabric or scrim or continuous fibers pull through more than 50%, preferably at least 70%, in particular at least 90%, of the length of the textile. The length of the textile is the largest extent of this in one of the three spatial directions. More preferably, the fabrics or scrims or continuous fibers pass through more than 50%, preferably at least 70%, in particular at least 90%, of the surface of the textile. The area of the textile here is the area of the largest extent of the textile in two of the three spatial directions. The textile is preferably (largely) flat. In a preferred embodiment, the functional groups Bl on the surface of the reinforcing fiber B are selected from hydroxy, ester and amino groups. Particularly preferred are hydroxy groups. According to a more preferred embodiment, the reinforcing fibers B are glass fibers which have hydroxyl groups in the form of silanol groups as chemically reactive functionality Bl on the surface.

The reinforcing fibers B may be embedded in the fiber composite material in any orientation and arrangement. The reinforcing fibers B are present in the fiber composite material is not statistically uniformly distributed, but in levels with higher and those with lower proportion (therefore as more or less separate layers). Preferably, it is assumed that a laminate-like or laminar structure of the fiber composite material.

The reinforcing fibers B may be present, for example, as fabrics, mats, nonwovens, scrims or knitted fabrics. Laminated laminates formed in this way contain laminations of sheet-like reinforcing layers (of reinforcing fibers B) and layers of the polymer matrix wetting and holding them, containing at least one component A. According to a preferred embodiment, the reinforcing fibers B are embedded in layers in the fiber composite material , Preferably, the reinforcing fibers B are present as a flat structure F.

In a clutch, the fibers are ideally parallel and stretched. There are usually used endless fibers. Tissues are created by the interweaving of continuous fibers, such as rovings. The interweaving of fibers inevitably involves an ondulation of the fibers. The ondulation causes in particular a reduction of the fiber-parallel compressive strength. Mats are usually made of short and long fibers, which are loosely connected by a binder. Through the use of short and long fibers, the mechanical properties of components made of mats are inferior to those of fabrics. Nonwovens are structures of limited length fibers, filaments or cut yarns of any kind and of any origin which have been somehow joined together to form a nonwoven and joined together in some manner. Knitted fabrics are thread systems through machine formation.

The fabric F is preferably a scrim, a fabric, a mat, a nonwoven or a knitted fabric. Particularly preferred as a fabric F is a scrim or a fabric. Component C

As a further component C, the fiber composite material used optionally contains 0 to 40% by weight, preferably 0 to 30% by weight, particularly preferably 0.1 to 10% by weight, based on the buffers of components A to C, at least one of the components A and B different additive (auxiliaries and additives).

Particulate mineral fillers, processing aids, stabilizers, oxidation retarders, agents against heat decomposition and decomposition by ultraviolet light, lubricants and mold release agents, flame retardants, dyes and pigments and plasticizers are to be mentioned. Also esters as low molecular weight compounds are mentioned. Also, according to the present invention, two or more of these compounds can be used. In general, the compounds are present with a molecular weight of less than 3000 g / mol, preferably less than 150 g / mol.

Particulate mineral fillers may be, for example, amorphous silica, carbonates such as magnesium carbonate, calcium carbonate (chalk), powdered quartz, mica, various silicates such as clays, muscovite, biotite, suzoite, tin malite, talc, chlorite, phlogopite, feldspar, calcium silicates such as wollastonite or kaolin, especially calcined kaolin.

UV stabilizers include, for example, various substituted resorcinols, salicylates, benzotriazoles and benzophenones, which can generally be used in amounts of up to 2% by weight.

According to the invention, oxidation inhibitors and heat stabilizers may be added to the thermoplastic molding compound. Sterically hindered phenols, hydroquinones, substituted representatives of this group, secondary aromatic amines, if appropriate in conjunction with phosphorus-containing acids or their salts, and mixtures of these compounds, preferably in concentrations of up to 1% by weight, based on the weight the mixture, can be used.

Furthermore, according to the invention lubricants and mold release agents, which are usually added in amounts of up to 1 wt .-% of the thermoplastic composition. These include stearic acid, stearyl alcohol, stearic acid alkyl esters and amides, preferably Irganox®, and esters of pentaerythritol with long-chain fatty acids. It is possible to use the calcium, zinc or aluminum salts of stearic acid and also dialkyl ketones, for example distearyl ketone. Furthermore, ethylene oxide Propylene oxide copolymers can be used as lubricants and mold release agents. Furthermore, natural and synthetic waxes can be used. These include PP waxes, PE waxes, PA waxes, grafted PO waxes, HDPE waxes, PTFE waxes, EBS waxes, montan wax, carnauba and beeswaxes.

Flame retardants can be both halogen-containing and halogen-free compounds. Suitable halogen compounds, with brominated compounds being preferred over the chlorinated ones, remain stable in the preparation and processing of the molding composition of this invention so that no corrosive gases are released and efficacy is not thereby compromised. Preference is given to using halogen-free compounds, for example phosphorus compounds, in particular phosphine oxides and derivatives of acids of phosphorus and salts of acids and acid derivatives of phosphorus. Phosphorus compounds particularly preferably contain ester, alkyl, cycloalkyl and / or aryl groups. Likewise suitable are oligomeric phosphorus compounds having a molecular weight of less than 2000 g / mol, as described, for example, in EP-A 0 363 608.

Furthermore, pigments and dyes may be included. These are generally in amounts of 0 to 15, preferably 0.1 to 10 and in particular 0.5 to 8 wt .-%, based on the buzzer of components A to C, included. The pigments for coloring thermoplastics are generally known, see, for example, R. Gächter and H. Müller, Taschenbuch der Kunststoffadditive, Carl Hanser Verlag, 1983, pp. 494 to 510. As the first preferred group of pigments, white pigments such as zinc oxide, Zinc sulfide, lead white (2 PbC03.Pb (OH) 2), lithopone, antimony white and titanium dioxide. Of the two most common crystal modifications (rutile and anatase-type) of titanium dioxide, in particular the rutile form is used for the whitening of the molding compositions according to the invention.

Black color pigments which can be used according to the invention are iron oxide black (Fe304), spinel black (Cu (Cr, Fe) 204), manganese black (mixture of manganese dioxide, silicon oxide and iron oxide), cobalt black and antimony black, and particularly preferably carbon black, which is usually present in Form of Furnace- or gas black is used (see G. Benzing, Pigments for paints, Expert-Verlag (1988), p. 78ff). Of course, inorganic color pigments such as chromium oxide green or organic colored pigments such as azo pigments and phthalocyanines can be used according to the invention to adjust certain hues. Such pigments are generally available commercially. Furthermore, it may be advantageous to use said pigments or dyes in a mixture, for example, carbon black with Kupferphtha- locyaninen, since in general the color dispersion in the thermoplastics is facilitated. Production and Use of the Fiber Composite Materials (Organo Sheet) Organic sheets are preferably processed by injection molding or pressing. Thus, a further cost advantage can be generated by a functional integration, for example by the injection-molding or pressing of functional elements, since further assembly steps, for example the welding of functional elements, can be dispensed with.

The process for producing a fiber composite material includes the steps:

Deploy from:

 (A) a matrix of at least one thermoplastic molding composition A having elastomeric properties, comprising a copolymer A-1 containing monomers Al, which have a chemically reactive functionality (and optionally one or more further (co) polymers (Aa) and / or (From));

 (B) at least one reinforcing fiber B, the surface of which has a chemically reactive functionality B-1 capable of forming a covalent bond with the monomers A-1;

Melting the thermoplastic molding compound A and displacing (or bringing into contact) this molding compound A with the reinforcing fiber B from step (i); and

(iii) reacting the monomers A-1 of the copolymer A-1 with the chemically reactive functionality B-1 of the reinforcing fibers B of step (ii) to form covalent bonds.

The manufacturing process may include the phases of impregnation, consolidation and solidification (consolidation) common in the manufacture of composites, which process may be influenced by the choice of temperature, pressure and times employed.

According to a preferred embodiment contains (or consists of) the fiber composite material: a) 30 to 95 wt .-% of at least one thermoplastic molding composition A with elastomeric properties,

 5 to 70 wt .-% of at least one reinforcing fiber B, and

 0 to 40 wt .-% of at least one additive C. Step (ii) of the process, the melting of the component A and the placing (contacting) of this melt with the reinforcing fibers B, can be carried out in any suitable manner. In such an impregnation, the matrix M can be converted into a flowable state and the reinforcing fibers B are wetted to form a boundary layer.

Alternatively, steps (ii) and (iii) may be performed simultaneously. Then, immediately upon the addition of the component A to the reinforcing fibers B, a chemical reaction takes place in which the monomers A-1 form a covalent bond with the surface of the reinforcing fibers B (usually via a bond to the functional groups B-1). This may exemplify esterification (e.g., esterification of maleic anhydride monomers with silanol groups of a glass fiber). Alternatively, the formation of a covalent bond may also be initiated in a separate step (e.g., by temperature elevation, radical starter, and / or photo-initiation). This can be done at any suitable temperature.

The steps (ii) and / or (iii) are carried out at a temperature of at least 200 ° C, preferably at least 250 ° C, more preferably at least 300 ° C, especially at 300 ° C-340 ° C. In this case, it should preferably be ensured that as far as possible no pyrolysis occurs and that the components used are thermally not decomposed (or only slightly (therefore <50%)). An exception may be: a composition which releases reactive groups by thermal cleavage, such as tert-butyl (meth) acrylate, isobutene is released by thermal elimination at temperatures of about 200 ° C and the remaining functional group (essentially an acid function) can then react with the fiber surface.

According to a preferred embodiment, therefore, when carrying out steps (ii) and / or (iii), the residence time at temperatures of> 200 ° C. is not more than 10 minutes, preferably not more than 5 minutes, more preferably not more than 2 minutes, in particular not more than 1 min. Often 10 to 60 seconds are sufficient for the thermal treatment. The process, in particular the steps (ii) and (iii), can in principle be carried out at any pressure (preferably atmospheric pressure or overpressure), with and without pressing of the components. When pressed with overpressure, the properties of the fiber composite material can be improved.

According to a preferred embodiment, therefore, the steps (ii) and / or (iii) at a pressure of 5-100 bar and a pressing time of 10-60 s, preferably at a compression pressure of 10-30 bar and a pressing time of 15-40 s, performed. Preferably, at least one chemically reactive functionality (A-l) provided, impact-modified styrene-acrylonitrile copolymers, ie, amorphous thermoplastic matrices, used as component A. Thus, for the applications described below, the surface quality can be substantially increased compared to the semicrystalline thermoplastics for such textiles, since the lower shrinkage of the amorphous thermoplastics, the surface topology, due to the fiber-rich (intersection point in tissues) and fiber-poor regions, essential is improved.

During consolidation, air pockets in the fiber composite material are reduced and a good bond is made between component A and reinforcing fibers B (particularly if fibers B are stratified reinforcing fibers). It is preferred, after impregnation and consolidation to obtain a (as far as possible) non-porous composite material. Alternatively, said steps (i) to (iii) may be carried out in separate sequence. For example, first layers of reinforcing fibers B can be prepared with differently prepared reinforcing fibers B, wherein an impregnation of the reinforcing fibers B takes place with the matrix of component A. Thereafter, impregnated layers with reinforcing fibers B with different fiber-matrix adhesion can be present, which can be consolidated in a further working step to form a composite material as fiber composite material.

Before the layers of reinforcing fibers B are laminated with the matrix of component A, at least a part of the reinforcing fibers B can be subjected to a pretreatment in the course of which the subsequent fiber-matrix adhesion is influenced. The pretreatment may include, for example, a coating step, an etching step, a heat treatment step or a mechanical surface treatment step. In particular, for example, by heating a part of Reinforcing fibers B an already applied adhesion promoter are partially removed.

A particularly preferred embodiment relates to the use of a thermoplastic fiber composite material according to the invention for producing coverings for high mechanical loads,

wherein the reinforcing fibers B are used in the form of a mat, a fabric, a mat, a fleece or a knitted fabric, the fiber composite material is layered and contains more than two layers.

Another particularly preferred embodiment relates to the use of a thermoplastic fiber composite material according to the invention for producing coverings for high mechanical loads,

wherein the reinforcing fibers B in the form of a gel, a fabric, a mat, a nonwoven or a knitted fabric are used and

wherein the fiber composite material has a thickness of <2 mm, preferably <1 mm.

Such a thickness of <2 mm may provide a (partially) elastic / flexible fiber composite material.

A particularly preferred embodiment relates to the use of a thermoplastic fiber composite material according to the invention for the production of covers for high mechanical loads,

wherein the reinforcing fibers B are used in the form of a mat, a fabric, a mat, a fleece or a knitted fabric, the fiber composite material is layered and contains more than two layers,

wherein the fiber composite material has a thickness of <2 mm. According to an optional embodiment, no adhesion promoter, in particular no adhesion promoter from the group consisting of aminosilanes and epoxy compounds, is used in the production of the fiber composite material.

According to a particularly preferred embodiment, the present invention relates to the use of a thermoplastic fiber composite material having a thickness of <10 mm, comprising:

a) 30 to 95, in particular 38 to 70 wt .-%, of the thermoplastic, amorphous molding material A having elastomeric properties, which is based on an impact-modified styrene copolymer, comprising 0.1 to 10 wt .-% of monomers Al, based to the amount of component A, which have a chemically reactive functionality. b) 5 to 70 wt .-%, in particular 29.9 to 61, 9 wt .-%, of the reinforcing fibers B, wherein the surface of the reinforcing fibers B one or more of the chemically reactive functionalities from the group: hydroxy, ester and Amino groups, wherein the reinforcing fibers B are preferably used in the form of a gel, a fabric, a mat, a nonwoven or a knitted fabric, and c) 0 to 40, in particular 0.1 to 10 wt .-%, of at least one additive C, wherein the at least one layer of the reinforcing fibers B is embedded in the matrix and wherein the thermoplastic molding composition A has elastomeric properties and in the manufacturing process of the thermoplastic fiber composite material having at least one chemically reactive functionality, which in the manufacturing process of the fiber composite material with chemical groups of Surface of the reinforcing fibers B reacts, for the production of technical textiles, in particular for the production of covers for high mechanical loads. wherein the fiber composite material is preferably layered and contains more than two layers.

Even more preferably, the fiber composite material has other properties as described herein.

The reinforcement layers can be completely interconnected during the manufacturing process (laminating). Such fiber composite material mats offer optimized strength and rigidity in the fiber direction and can be processed particularly advantageously.

The method can also include the production of a molded part T. According to a preferred embodiment, the method comprises, as a further step (iv), a three-dimensional shaping into a molded part T. This can take place in any manner, for example by mechanical shaping through a shaping body, which can also be an embossed roll. Preferably, the still mouldable fiber composite material in which the thermoplastic molding compound A is still (partially) melted present. Alternatively or additionally, a cured fiber composite material can also be cold formed. In a further embodiment, at the end of the process, a (substantially) solid molding T is obtained. Thus, optionally as a further step (v), the process comprises curing the product obtained from one of the steps (iii) or (iv). This step can also be called solidification. The solidification, which generally takes place with removal of heat, can then lead to a ready-to-use molded part T. Optionally, the molded part T can still be finished (eg deburred, polished, dyed, etc.). The process can be carried out continuously, semicontinuously or discontinuously. According to a preferred embodiment, the process is carried out as a continuous process, in particular as a continuous process for the production of smooth or three-dimensionally embossed films. Alternatively, it is also possible to produce shaped parts T semi-discontinuously or discontinuously.

The reinforcing fibers B may be layer-wise impregnated and consolidated as layers of (or as sheets of F) reinforcing fibers B in a single processing step with the matrix M containing component A.

The production of the fiber composite material can be carried out in this way in a particularly efficient manner.

In a further embodiment, it is provided that further groups of reinforcing fibers B are coupled to the matrix M via further, differing fiber matrix adhesions.

If three or more groups of reinforcing fibers B with different fiber matrix adhesions are used, the behavior of the fiber composite material can be specifically and highly individually influenced. In each case different types of fibers or the same types of fibers can be used.

For example, groups of reinforcing fibers B may each be provided with different adhesion promoter compositions effecting the different fiber matrix adhesions. The different compositions may differ only in the concentrations or have other compositions. It is essential that significantly different fiber-matrix adhesions are set by the different adhesion promoter compositions.

Already in the production of the reinforcing fibers of the primer can be applied as part of the size. However, it can also be an additional process of thermal desizing or other desizing can be provided which destroys or removes the already applied sizing. Subsequently, the reinforcing fiber can then be coated with a finish containing the coupling agent and adapted to the particular matrix and the desired fiber-matrix adhesion.

By using, for example, Styroflex®, a styrene block copolymer (S-TPE, manufacturer Styrolution, Germany), as matrix M of the organic sheet, very flexible materials with high strength in the fiber direction can be obtained. These high-strength, flexible materials have great advantages in uppers for sports, leisure and safety footwear, for upholstery in public transport or as heavy-duty fabric (e.g., sails).

The organic sheets can simultaneously take on functional properties through the use of different fibers (e.g., metal or aramid fibers). Leather-like technical textiles can also be produced. Here are some concrete examples: Upper for sports, leisure and safety shoes:

As uppers for sports and leisure shoes, heavy-duty materials such as genuine leather, imitation leather (PU), PVC, PET or natural fibers and nylon (polyamide) in fabric form are often used due to the high stress in everyday life and sports. These used uppers have the disadvantage that they have a lower strength with increasing flexibility and thus fail after some time in use or overuse. Through the use of an endless fiber and the very flexible matrix M (eg Styrolux®) in the organic sheet, a high degree of flexibility can be achieved with high strength, ie a property pattern that could not be achieved with other materials. These organic sheets can therefore be used as very hard-wearing, strong, flexible uppers. In addition to the improved properties, an aesthetic advantage can also be created at the same time by coloring the fiber and / or matrix. The use as a transparent material is conceivable. This can be used to visualize underlying layers, thus creating a depth effect. Even in safety shoes, this material can have advantages due to the high strength. Through the use of glass, aramid and / or steel fibers, the upper material can be fitted so that it is puncture- and cut-resistant, so that the foot is protected by the upper material. Textiles for covers

Seat covers in public transport are usually very heavily loaded due to high usage and vandalism and therefore have to be replaced after a short time. By using these flexible, high-strength organic sheets as a substitute for the currently used substances, the service life can be increased many times, because the higher strength of the glass fibers abrasion and destruction can be prevented by piercing sharp objects during vandalism. Large-area textiles

Sails are made of woven polyester threads. The disadvantage of the polyester fiber is the lower strength compared to the glass fiber in the organic sheet, so that with the same load capacity a smaller weight of the glass fabric can be selected in the organic sheet. Thus, thinner material can be used, which can lead to a cost and weight reduction. In addition, the permeability through the complete impregnation of the fabric with, for example, Styroflex® much lower, which can be further increased the efficiency of the sail.

characters

FIG. 1 shows the fiber composite materials which have been tested according to test no. 1 were obtained. FIG. 1A shows the visual documentation. FIG. 1B shows the microscopic appearance of a section through the laminar fiber composite material arranged in a horizontal orientation (left: 25-fold magnification, right: 50-fold magnification), wherein the fibers clearly show horizontally extending dark layer between the light layers of thermoplastic molding material can be seen. Figure 1 C shows the 200-fold magnification, it can be seen that the impregnation is not completed in some places.

FIG. 2 shows the fiber composite materials, which according to test no. 2 were obtained. FIG. 2A shows the visual documentation. FIG. 2B shows the microscopic view of a section through the laminar fiber composite material arranged in a horizontal orientation (left: 25-fold magnification, right: 50-fold magnification), the fibers clearly being in the form of a running dark layer can be seen between the light layers of thermoplastic molding material. FIG. 2C shows a magnification of 200 times, whereby it can be seen that the impregnation is partly not completed. FIG. 3 shows the fiber composite materials which have been tested according to test no. 3 were obtained. FIG. 3A shows the visual documentation. FIG. 3B shows the microscopic view of a section through the laminar fiber composite material arranged in a horizontal orientation (left: 25-fold magnification, right: 50-fold magnification), with no layer of fibers being recognizable. Figure 3C shows the 200-fold magnification, it can be seen that the impregnation is largely completed. FIG. 4 shows the fiber composite materials which have been tested according to test no. 4 were obtained. FIG. 4A shows the visual documentation. FIG. 4B shows the microscopic view of a section through the laminar fiber composite material arranged in a horizontal orientation (left: 25-fold magnification, right: 50-fold magnification), with no layer of fibers being recognizable. FIG. 4C shows a magnification of 200 times, whereby it can be seen that the impregnation at individual points is not completely completed.

FIG. 5 shows the fiber composite materials which are determined according to test no. 5 were obtained. FIG. 5A shows the visual documentation. FIG. 5B shows the microscopic view of a section through the laminar fiber composite material arranged in a horizontal orientation (left: 25-fold magnification, right: 50-fold magnification), with no layer of fibers being recognizable is. Figure 4C shows the 200-fold magnification, it can be seen that the impregnation is not completely completed in a few places.

FIG. 6 shows the production of the fiber composite materials (here: glass fiber fabric) in the press inlet V25-V28. It is clearly recognizable that such a production method allows continuous production. In addition, it can be seen from the imprinting of the pattern that the fiber composite material can also be shaped in three dimensions.

The invention is described in more detail in the following examples and claims. Examples

The following experiments were carried out on an interval hot press, which is able to produce a fiber / film composite of polymer film, melt or powder, for the quasi-continuous production of fiber-reinforced thermoplastic textiles.

Plate width: 660 mm

Laminate thickness: 0.2 to 9.0 mm

Laminate tolerances: max. ± 0.1 mm according to semi-finished product

Sandwich panel thickness: max. 30 mm

 Output: approx. 0.1 - 60 m / h, depending on quality and component thickness

Nominal feed 5 m / h

 Tool pressure: Press unit 5-25 bar, infinitely variable for minimum and maximum tool size (optional)

 Mold temperature control: 3 heating and 2 cooling zones

 Tool temperature: up to 400 ° C

 Tool length: 1000 mm

 Opening travel press: 0.5 to 200 mm

preferred direction of production: right to left

Technical data of melt plasticization:

 Medium-layer discontinuous melt application for the production of fiber-reinforced thermoplastic semi-finished products

Screw diameter: 35mm

Max. Stroke volume: 192 cm ³

 Max. Screw speed: 350 rpm

Max. Discharge flow: 108 cm ³ / s

 Max. Discharge pressure: 2406 bar specific

Transparency was measured on 1 mm organo-sheet samples in% of white daylight (100

%) (transparency meter Byk Haze gard i (BYK-gardner, USA) according to

ASTM D 1003 (about ASTM D 1003-13)).

 The described fiber composite materials (organic sheets), in particular with amorphous, thermoplastic matrix are particularly suitable for the production of technical textiles see. Some examples are shown below.

Unless otherwise stated, the fibers are made by injection molding. Fiber composite material 1

40 wt .-%, based on the fiber composite material, a component A, consisting of

75% by weight styrene-butadiene-styrene elastomer Styroflex 2G66 (comprising 65% by weight of styrene and

 35 wt .-% butadiene) and

 25% by weight of a styrene / maleic anhydride (containing 6% maleic anhydride) copolymer

be with

60 wt .-%, based on the fiber composite material, a glass-based reinforcing fiber with chemically reactive functionality (silane groups) at the surface [GW 123-580K2 of P-D Glasseiden GmbH, compounded as component B].

The following textiles are then produced with the fiber composite material:

Example A: Safety shoes

Example B: Sails Example C: Seat Cover With the organic sheets according to the invention both a flexible (eg sail) and firm textile (for example shoe) are produced. The crack resistance of the end products is compared to conventional textiles, without the fiber composite material according to the invention, significantly optimized.

Printable and dyeable fiber composite materials Hazardous thermoplastic combinations A:

 A1 (comparison): S / AN with 75% styrene (S) and 25% acrylonitrile (AN), viscosity number

 60, Mw of 250,000 g / mol (measured via gel permeation chromatography on standard columns with monodisperse polystyrene calibration standards)

A2: S / AN / maleic anhydride Copolymer having the composition (wt%): 74/25/1, Mw of 250,000 g / mol (measured via gel Permeation chromatography on standard columns with monodisperse polystyrene calibration standards)

 A3: mixture of A2: A1 = 2: 1

 A4: mixture of A2: A1 = 1: 2

Used fiber textiles B:

 B1: Bidirectional glass fiber substrate 0/90 ° (GF-GE) with basis weight

590g / m ² ,

 Weft and chain = 1200tex [for example KN G 590.1 from P-D Glasseiden GmbH]

B2: glass fiber fabric twill 2/2 (GF-KG) with basis weight = 576 g / m ² ,

 Shot, + chain = 1200tex

The combinations and parameter settings made in connection with experiments No. 1 -5 are listed in the following table:

Table 1 . Manufacturing conditions of the fiber composite materials

* Components A + B1: 0.465 mm Thickness Textile structure, 0.653 mm thickness Matrix structure, total volume Matrix: 22 ml, fiber volume fraction: 41 .6%, total density Semi-finished product: 1 .669 g / ml, total thickness Semi-finished product: 1 .1 17 mm

Experiment no. 1 (comparative experiment)

 The results are shown in FIG.

Visual assessment on the semi-finished surface:

Macro Impregnation: completed Micro-impregnation: clearly not completed

Microscopic evaluation in semi-finished products:

Matrix layer in middle position: clearly visible

Matrix layer in top layer: not visible on the roving

 Impregnation Warp threads: Central unimpregnated areas, all around slightly impregnated Impregnation Weft threads: in the middle clearly unimpregnated areas, all around slightly impregnated

 Air inclusions: little, only in roving

Consolidation: insufficient, damage warp and weft threads

Experiment no. 2

 The results are shown in FIG. Visual assessment on the semi-finished surface:

Macro Impregnation: completed

 Micro-impregnation: not completed in several places

Microscopic evaluation in semi-finished products:

Matrix layer in middle position: recognizable

 Matrix layer in top layer: little recognizable by the roving

 Impregnation Warp threads: Central unimpregnated areas visible, partially impregnated all around, partially unimpregnated

 Impregnation Weft threads: Central unimpregnated areas, all-round lightly impregnated

 Air inclusions: little

 Consolidation: insufficient, significant damage weft threads

Experiment no. 3

The results are shown in FIG.

Visual assessment on the semi-finished surface:

Macro Impregnation: completed

Micro-impregnation: completed

Experiment No. 3, Microscopic Evaluation in the Semi-Finished Interior:

Matrix layer in middle position: not recognizable

Matrix layer in top layer: easily recognizable

Impregnation Warp threads: hardly any unimpregnated areas visible, all-round well impregnated Impregnation Weft threads: hardly any unimpregnated areas visible, all-round well impregnated

 Air inclusions: many, large bubbles visible

Consolidation: good, no damage

Experiment no. 4

 The results are shown in FIG.

Visual assessment on the semi-finished surface:

Macro Impregnation: completed

 Micro-impregnation: mostly completed

 Microscopic evaluation in semi-finished products:

 Matrix layer in middle position: hardly recognizable

 Matrix layer in cover layer: recognizable

Impregnation Warp threads: Slightly unimpregnated areas visible, all-round well impregnated

 Impregnation Weft threads: unimpregnated areas visible, but impregnated all around

 Air inclusions: none recognizable

Consolidation: satisfactory, average damage of weft threads recognizable

Experiment no. 5

 The results are shown in FIG.

Visual assessment on the semi-finished surface:

Macro Impregnation: completed

Micro-impregnation: mostly completed

Microscopic evaluation in semi-finished products:

Matrix layer in middle position: not recognizable

Matrix layer in cover layer: recognizable

 Impregnation warp threads: little unimpregnated areas visible, all-round well impregnated

 Impregnation Weft threads: little unimpregnated areas recognizable, all-round well impregnated

 Air inclusions: none recognizable

Consolidation: partly good, partly insufficient, local damage of weft threads recognizable Summary of the test results

 Table 2. Summary trials and evaluation

^* Components A + B1: 0.465 mm Thickness Textile structure, 0.653 mm thickness Matrix structure, total volume Matrix: 22 ml, fiber volume fraction: 41.6%, total density Semi-finished product: 1.669 g / ml, total thickness Semi-finished product: 1 .1 17 mm

^** 1 = perfect, 2 = good, 3 = partial, 4 = low, 5 = poor / none

Table 3. Optical and haptic comparison of the experimental settings according to the invention with conventional organo sheets

 Experimental Composite Maleic Acid Upper Printability Trans

No. anhydride surfaces with 45 mdyne parenz

Concentration ^* Ink ^** (%) tion

 (% By weight)

 1 (Cf.) A1 + B1 0 2 1

2 (Cf.) A1 + B1 0 2 3

3 A2 + B1 1 1 -2 1 40

4 A3 + B1 0.66 1 -2 25

5 A4 + B1 0.33 1 -2 1 20

6 Bond Laminates 0 4-5 0

 Composite of approx

 60% fiberglass fabric and 40%

 polyamide

 7 composite from approx. 0 4-5 5 0

 60% fiberglass fabric and 40%

polypropylene ^* 1 = completely smooth, 2 = largely smooth, 3 = slightly rough, 4 = moderately rough, 5 = fibers are clearly noticeable

^** 1 = perfect, 2 = good, 3 = partial, 4 = low, 5 = poor / none

Experiment no. 6

 The results are shown in Table 5.

The combinations and parameter settings made in connection with experiment No. 6 are listed in the following table:

Table 4. Production conditions of the fiber composite materials

^* Components A + B1: 0.465 mm Thickness Textile structure, 0.653 mm thickness Matrix structure, total volume Matrix: 22 ml, fiber volume fraction: 41.6%, total density Semi-finished product: 1.669 g / ml, total thickness Semi-finished product: 1 .1 17 mm

Due to their partial translucency and printability, the fibrous composite materials according to the invention can be used to produce a wide variety of technical textiles which are particularly readily dyeable.

Example of multilayer organic sheets 40 wt .-%, based on the fiber composite material, of an acrylonitrile-styrene-maleic anhydride copolymer as thermoplastic molding material A (prepared from: 75 wt .-% of styrene, 24 wt .-% acrylonitrile and 1 wt .-% maleic anhydride) is compounded with 60 wt .-%, based on the fiber composite material, a glass-based reinforcing fiber with chemically reactive functionality (silane groups) on the surface [GW 123-580K2 of PD Glasseiden GmbH]. Further investigation of multilayer fiber composite materials

Technical Data of the Interval Hot Press (IVHP):

Quasi-continuous production of fiber-reinforced thermoplastic semi-finished products, laminates

and sandwich panels

Plate width: 660 mm

Laminate thickness: 0.2 to 9.0 mm

Laminate tolerances: max. ± 0.1 mm according to semi-finished product

Sandwich panel thickness: max. 30 mm

 Output: approx. 0.1 - 60 m / h, depending on quality and component thickness

Nominal feed 5 m / h

 Tool pressure: Press unit 5-25 bar, infinitely variable for minimum and maximum tool size (optional)

 Mold temperature control: 3 heating and 2 cooling zones

 Tool temperature: up to 400 ° C

 Tool length: 1000 mm

 Opening travel press: 0.5 to 200 mm

Production direction: right to left

Technical data of melt plasticization:

 Medium-length discontinuous melt application for the production of fiber-reinforced thermoplastic

semifinished

 Screw diameter: 35mm

Max. Stroke volume: 192 cm ³

 Max. Screw speed: 350 rpm

Max. Discharge flow: 108 cm ³ / s

Max. Discharge pressure: 2406 bar specific

here:

 Melt volume: 22 cc

isobar = pressure-controlled pressing process

isochor = volume-controlled pressing process

T [° C] = temperature of the temperature zones ^* ( ^* The press has 3 heating zones and 2 cooling zones.

p [bar] = pressing pressure per cycle: Isochor 20

s [mm] = travel limit Press thickness: 1 .1 mm

Temperature profile: (i) 210 to 245 ° C, therefore approx. 220 ° C (ii) 300 to 325 ° C, therefore about 300 ° C

 (iii) 270 to 320 ° C, therefore about 280 to 320 ° C

 (iv) 160 to 180 ° C

 (v) 80 ° C

t [sec] = pressing time per cycle: 20-30 s

 Construction / lamination: 6-layer structure with melt middle layer; Production process: melt direct (SD)

Matrix Components A:

M1 (SAN type): styrene-acrylonitrile-maleic anhydride (SAN-MA) terpolymer (S / AN / MA: 74/25/1) with an MA content of 1% by weight and an MVR of 22 cm ³ / 10 min at 220 ° C / 10kg (measured to IS01 133);

M1 b corresponds to the abovementioned component M1, the matrix additionally being admixed with 2% by weight of carbon black.

M2 (SAN type): styrene-acrylonitrile-maleic anhydride (SAN-MA) terpolymer (S / AN / MA: 73/25 / 2.1) with an MA content of 2.1% by weight and an MVR of 22 cm ^3/10 min at 220 ° C / 10kg (measured according to IS01 133);

M2b corresponds to the abovementioned component M2, the matrix additionally being admixed with 2% by weight of carbon black.

M3 (SAN type): blend of 33% by weight of M1 and 67% by weight of the SAN copolymer Luuran VLN, therefore 0.33% by weight of maleic anhydrideMA) in the entire blend;

M3b corresponds to the abovementioned component M3, the matrix additionally being admixed with 2% by weight of carbon black. PA6: semi-crystalline, easy-flowing polyamide Durethan B30S

PD (OD): easy flowing, optical grade amorphous polycarbonate

 Discs); Fiber components B:

Glass filament cooper fabric (short names: GF-KG (LR) or LR), twill weave 2/2, basis weight 290 g / m ² , roving EC9 68tex, finish TF-970, delivery width 1000 mm (type: 01 102 0800-1240; Manufacturer: Hexcel, obtained from: Lange + Ritter) Glass filament twill weave (short designations: GF-KG (PD) or PD), twill weave 2/2, basis weight 320 g / m ² , Roving 320tex, finish 350, delivery width 635 mm (type: EC14-320-350, manufacturer and supplier : PD Glasseide GmbH Oschatz) Glass filament scrim (short name: GF-GE (Sae) or Sae) 0 45 90 -45 °, basis weight 313 g / m ² , main roving 300tex, finish PA size, delivery width

655mm (Type: X-E-PA-313-655, No. 7004344, manufacturer and supplier: Saertex

GmbH & Co.KG) Sae ns = glass filament scrim 300 g / m ² , manufacturer's name: Saertex new sizing, + 457-457 + 457-45 °

Glass fiber fleece (short name: GV50), basis weight 50 g / m ² , fiber diameter 10 μηη, delivery width 640 mm (Type: Evalith S5030, manufacturer and supplier: Johns Manville Europe)

Visual rating

 All produced composite fiber materials could each be produced as (large) flat textile materials in a continuous process, which could be cut to size (in laminatable, transportable dimensions such as 1 m x 0.6 m). In the case of transparent fiber composite materials, the embedded fiber material was just recognizable when examined in detail against the light. In the fiber composite materials with a (black) colored matrix, the embedded fiber material was not / hardly recognizable even under closer light in the backlight.

Microscopic evaluation

 In this case, defects (voids, incidence, etc.) were evaluated by incident light microscopy and the surface quality via confocal laser scanning microscopy (LSM). Using LSM, a top view of a three-dimensional (3D) height image (7.2 mm x 7.2 mm) of the local measuring range and a two-dimensional (2D) representation of the height differences after scaling and application of different profile filters was created. Measurement errors and a general distortion / skew of the sample were compensated by the use of profile filters (noise filter and tilt filter). The 2D height profile of the image was transmitted via defined measuring lines by integrated software in line profiles and evaluated computer-assisted.

Fiber-composite materials with four embedded layers of the respective fabric of fibers (here GF-KG (PD) (4) or Sae (4)) were produced in the respective matrix. To further increase the comparability of the samples were on the fiber composite materials produced in each case a thin glass fiber fleece (GV50, see above) applied on both sides. This had no noticeable influence on the mechanical properties. The mean wave depth (MW Wt) and the spatial ration value (Ra) were determined for numerous fiber composite materials. It was found that the MW Wt for all fiber composite materials in which the matrix contains a functional component that can react with the fibers is clearly <10 μm, whereas in composite fiber materials with comparable PA6 and PD (OD ) Matrices is clearly <10 μηη. The determined spatial values were also significantly lower for composite fiber materials according to the invention. By way of example, these are the measured values below.

Table 5. LSM Measurement Results with SAN Matrix System - Wave Depth (Wt) and Stellite (Ra)

This was just as clear when instead of the fabric a scrim (like Sae) is used:

Table 6. LSM Measurement Results with SAN Matrix System - Wave Depth (Wt) and Stellite (Ra)

In further tests, the strength in the warp and weft directions was examined separately. It could be shown that the fiber composite materials are very stable in both warp and weft directions. In the warp direction, the fiber composite materials are usually even more stable than in the weft direction. Mechanical properties

Matrix components A

 The matrix components A are as described above.

Fiber components B (unless described above)

FG290 = glass filament fabric 290g / m ² , manufacturer's name: Hexcel HexForce® 01202 1000 TF970 FG320 = glass filament fabric 320g / m ² , manufacturer's name: PD Glasseide GmbH Oschatz EC 14-320-350

Sae = MuAx313, glass filament scrim 300g / m ² , manufacturer's name: Saertex XE-PA-313-655

Sae ns = glass filament scrim 300g / m ² , manufacturer's name: Saertex new sizing, + 457-457 + 457-45 °

Number of layers (e.g., 4x = four layers of the respective fiber fabric or fibers)

The puncture behavior (dart test according to ISO 6603) was determined for the fiber composite materials. Here, the fiber composite materials showed a high stability of Fm> 3000 N.

Optional further processing

 It could also be shown experimentally that the resulting fiber composite materials could be formed in good three-dimensional form, for example into half shell-shaped materials, such as shoe caps. It was also found that the resulting fiber composite materials could be printed and laminated.

Summary of the test results

The evaluation of different textile systems based on glass fibers with different matrix systems to a fiber composite material has shown that good fiber composite materials can be produced reproducibly. These can be produced colorless or colored and optionally subsequently dyed and / or laminated. The fiber composite materials showed good to very good optical, haptic tables and mechanical properties (such as their puncture resistance). Mechanically, the tissues showed slightly greater strength than scrim. The styrene copolymer-based matrices (SAN matrices) tended to result in better fiber composite materials in terms of mechanical properties than the alternative matrices such as PC and PA6. The fiber composite materials according to the invention could be produced semi-automatically or fully automatically by means of a continuous process. The fiber composite materials (organic sheets) according to the invention can be well converted into three-dimensional shapes, for example for shoe caps.

Claims

claims

Use of a thermoplastic fiber composite material comprising: a) at least one thermoplastic molding compound A as matrix,

 b) at least one layer of reinforcing fibers B, and

 c) optionally at least one additive C,

 wherein the at least one layer of the reinforcing fibers B is embedded in the matrix and wherein the thermoplastic molding composition A has elastomeric properties and in the manufacturing process of the thermoplastic fiber composite material having at least one chemically reactive functionality, which in the manufacturing process of the fiber composite material with chemical groups of the surface of the Reinforcing fibers B reacts,

 for the production of technical textiles.

Use of a thermoplastic fiber composite material according to claim 1, comprising: a) from 30 to 95, in particular from 38 to 70,% by weight of the thermoplastic molding composition A having elastomeric properties,

 b) 5 to 70 wt .-%, in particular 29.9 to 61, 9 wt .-%, of the reinforcing fibers B, and

 c) 0 to 40, in particular 0.1 to 10 wt .-%, of at least one additive C.

Use of a thermoplastic fiber composite material according to claim 1 or 2, wherein the thermoplastic molding material A is amorphous and is based on an impact-modified styrene copolymer having at least one chemically reactive functionality.

Use of a thermoplastic fiber composite material according to one of claims 1 to 3, wherein the matrix is based on a molding compound A which has at least one chemically reactive functionality, wherein the molding compound A is selected from the group consisting of: styrene-based elastomers (S) TPE), hydrogenated or partially hydrogenated styrene-butadiene (block) copolymers, polyolefin-based thermoplastic elastomers, thermoplastic polyurethanes and elastomeric polyether / esters of the HYTREL® type, optionally mixed with polymers such as: polystyrene (clear or impact-resistant), Styrene-acrylonitrile polymers, acrylonitrile-butadiene-styrene copolymers, styrene-methyl methacrylate copolymers (SMMA), methacrylate-acrylonitrile-butadiene-styrene copolymers (MABS) or acrylic ester-styrene-acrylonitrile copolymers (ASA).

5. Use of a thermoplastic fiber composite material according to any one of claims 1 to 4, wherein the chemically reactive functionality of the thermoplastic molding composition A is based on components selected from the group consisting of: maleic anhydride, N-phenylmaleimide and glycidyl (meth) acrylate ,

6. Use of a thermoplastic fiber composite material according to any one of claims 1 to 5, wherein the thermoplastic molding composition A contains 0.1 to 10 wt .-% of monomers Al, based on the amount of component A, which have a chemically reactive functionality ,

7. Use of a thermoplastic fiber composite material according to any one of claims 1 to 6, wherein the surface of the reinforcing fibers B one or more of the chemically reactive functionalities from the group: hydroxyl, ester and amino groups.

8. Use of a thermoplastic fiber composite material according to any one of claims 1 to 7, wherein the reinforcing fibers B consist of glass fibers which contain as chemically reactive functionality silanol groups on the surface.

9. Use of a thermoplastic fiber composite material according to any one of claims 1 to 8, wherein the reinforcing fibers B in the form of a Geleges, a fabric, a mat, a nonwoven fabric or a knitted fabric are used.

10. Use of a thermoplastic fiber composite material according to one of claims 1 to 9, wherein the fiber composite material has a thickness of <10 mm, preferably of <2 mm, in particular of <1 mm.

1 1. Use of a thermoplastic fiber composite material according to one of claims 1 to 10, wherein the fiber composite material is layered and contains more than two layers.

12. Use of a fiber composite material according to any one of claims 1 to 1 1 for the production of surface materials for sports, leisure and safety shoes.

13. Use of a fiber composite material according to any one of claims 1 to 1 1, for the production of covers for high mechanical loads, in particular for sails.

14. A process for producing a thermoplastic fiber composite material, comprising the steps:

Providing: a matrix of at least one thermoplastic molding material A having elastomeric properties comprising a copolymer A-1 containing monomers A-1 having a chemically reactive functionality; at least one reinforcing fiber B whose surface has a chemically reactive functionality B-1 which is capable of covalent bonding with the monomers A-1; (ii) melting the thermoplastic molding material A and displacing it

Molding compound A with the reinforcing fiber B from step (i); and

(iii) reacting the monomers A-1 of the copolymer A-1 with the chemically reactive functionality B-1 of the reinforcing fibers B from step (ii) to form covalent bonds.

15. Technical textiles produced from a fiber composite material produced according to claim 14.

16. Use of a thermoplastic fiber composite material according to one of claims 1 to 13 for the production of covers for high mechanical loads,

 wherein the reinforcing fibers B are used in the form of a mat, a fabric, a mat, a nonwoven or a knitted fabric, the fiber composite material is layered and contains more than two layers.

17. Use of a thermoplastic fiber composite material according to claim 16, wherein the fiber composite material has a thickness of <2 mm.