DE102004016873B4 - Free-radically coupled perfluoropolymer polymer materials and processes for their preparation - Google Patents

Abstract

Radically coupled perfluoropolymer polymer materials, consisting of perfluoropolymer in the form of polytetrafluoroethylene [PTFE], poly (tetrafluoroethylene-co-hexafluoropropylene) [FEP], poly (tetrafluoroethylene-co-perfluoropropyl vinyl ether) [PFA], poly (tetrafluoroethylene-co-perfluoro) -2,2-dimethyldioxole) and / or poly (chlorotrifluoroethylene) [PCTFE], on the perfluoropolymer chains of which polymers with olefinically unsaturated groups in the main chain and / or in the side chain are chemically coupled in a free-radical manner via a reactive reaction, with the free-radical Coupling necessary radicals in the perfluoropolymer are persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups that do not originate from an irradiation process and / or a plasma modification.

Description

The invention relates to the field of chemistry and relates to radically coupled perfluoropolymer-polymer materials, which may be used, for example, as tribo materials and a process for their preparation.

... Unsintered and unspiked PTFE emulsion and suspension polymers are of a fibrous-felty character. A transmission z. As the anti-adhesive and sliding properties of the PTFE to other media by incorporation into aqueous or organic dispersions, polymers, paints, varnishes, resins or lubricants is not possible because this PTFE can not be homogenized, but tends to clumping, agglomerated, floating or itself settles.

Because of the insolubility of the PTFE and its degradation products (with the exception of the very low molecular weight products), the usual methods of Molmassenbestimmung can not be applied. The determination of the molar mass must be indirect. "[A. Heger et al., Technology of Radiation Chemistry on Polymers, Akademie-Verlag Berlin 1990]

The disadvantage is often the incompatibility with other materials. By a chemical activation of PTFE by the known methods with (1.) sodium amide in liquid ammonia and (2.) alkali alkyl and alkali aromatic compounds in aprotic inert solvents, a modification can be achieved. By means of these modifications, it is possible to achieve reactive or even only adsorptive forces for improved interfacial interactions.

The utilization of the products of the PTFE degradation takes place in a variety of applications - as well as an additive to plastics for the purpose of achieving sliding or non-stick properties. The fine powder substances are more or less finely dispersed as a filler component in a matrix [Ferse et al., Plaste u. Kautschuk, 29 (1982), 458; Ferse et al. DD-PS 146 716 (1979)]. When dissolving the matrix component, the PTFE fine powder is eliminated or is returned unchanged.

Although in the fields of application of PTFE fine powder an improvement of the properties compared to the commercial fluorocarbon-free additives is achieved, the incompatibility, the insolubility, the storage and also inhomogeneous distribution for many applications of disadvantage.

Also known are grafted fluorine-containing plastics ( US 5,576,106 ), which consist of fluorine-containing plastic particles, on the surface of a non-homopolymerized ethylenically unsaturated compound is grafted. The non-homopolymerized ethylenically unsaturated compounds may be acids, esters or anhydrides.

These grafted fluorine-containing plastics are prepared by exposing the fluorine-containing plastic powder in the presence of the ethylenically unsaturated compound to a source of ionizing radiation. In this case, the attachment of the ethylenically unsaturated compounds to the surface of the fluorine-containing plastic particles takes place.

The object of the invention is to provide perfluoropolymer polymer materials which have improved wear resistance with comparable sliding properties and thereby the life of the components is extended from these materials, and further to provide a simple and efficient method for producing such materials.

The free-radically coupled perfluoropolymer polymer materials according to the invention consist of perfluoropolymer, to whose perfluoropolymer chains, polymers in melt are chemically radically coupled via a reactive reaction, wherein the radicals required for free-radical coupling persist active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups that are not derived from an irradiation process and / or a plasma modification.

Advantageously, the persistent reactive and / or reactivatable perfluoroalkyl (peroxy) radicals and / or the radicals from thermally decomposed groups originate from a polymerization process.

In this case, advantageously, the binding site of the polymers with the perfluoropolymer chain is randomly distributed on the polymer chain.

Advantageously, such polymers are radically coupled as polymers which possess olefinically unsaturated groups in the main chain and / or in the side chain.

Such advantageous polymers are free-radically coupled SBS, ABS, SBR, NBR, NR and other butadiene and / or isoprene and / or chloroprene homo-, -Coderer -Ter polymers.

It is also advantageous if the perfluoropolymers are PTFE and / or FEP.

In the process according to the invention for the preparation of free-radically coupled perfluoropolymer polymer materials Perfluoropolymer with persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups, which do not originate from an irradiation process and / or from a plasma treatment, reactively reacted in melt with the addition of olefinically unsaturated polymers.

Advantageously, it is when the perfluoropolymer is used as a micropowder.

It is also advantageous if PTFE and / or FEP are used as the perfluoropolymer.

It is also advantageous if the reaction is carried out in melt in a melt mixer, preferably in an extruder.

Further advantageously, the polymers used are those polymers which have olefinically unsaturated groups in the main chain and / or in the side chain.

As such advantageous polymers are SBS, ABS, SBR, NBR, NR and other butadiene and / or isoprene and / or chloroprene homo-, -Co- or -Ter polymers used.

The inventive radical coupling of perfluoropolymer with olefinically unsaturated polymers via a (melt) modification reaction leads to compatibilization and solid incorporation into a matrix, which can be advantageously exploited for tribological materials. Thus, special thermoplastics, elastomers and special perfluoropolymer thermosets can be modified via reactive conversion / extrusion in such a way that not only improved sliding friction but also increased wear resistance is achieved compared to pure starting materials and physical blends with perfluoropolymer.

In the production of perfluoropolymer, which have not been modified by an irradiation process and / or a plasma modification, persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups surprisingly result for coupling with olefinically unsaturated polymers in a reactive implementation are capable. The coupling takes place via radical reactions and the olefinically unsaturated polymers used are present as polymers which may still have olefinically unsaturated double bonds after the radical coupling.

The production of the perfluoropolymers is advantageously carried out in a polymerization process. That the resulting persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups are suitable for coupling with olefinically unsaturated polymers in a reactive reaction was particularly surprising.

By means of IR spectroscopy, after the melt modification in the laboratory kneader, for example for SBS, ABS and also olefinically unsaturated elastomers, such as SBR, NBR, NR, polybutadiene with a perfluoropolymer not originating from an irradiation process and / or a plasma modification and after separation of the unbound matrix, a chemical Coupling detected. The olefinically unsaturated polymers could no longer be separated by extraction from this perfluoropolymer (for example Zonyl MP 1600 and TF 9207). In comparison to physical mixtures of thermally degraded perfluoropolymer (for example TF 9205), in which the perfluoropolymer could be quantitatively separated unchanged.

In a further variant of the invention, after preparation of the perfluoropolymer, which has not been modified by an irradiation process and / or a plasma modification, to increase and / or adjust a concentration of perfluoroalkyl (peroxy) radicals for the respective application, a radiation-chemical and / or or plasma treatment.

However, this radiation-chemical and / or plasma treatment serves exclusively to optimize the free-radical coupling of the perfluoropolymer-polymer material according to the invention. The effect according to the invention that such a coupling can be achieved at all between a perfluoropolymer which has not been modified by an irradiation process and / or a plasma modification and olefinically unsaturated polymers is also achieved without a radiation-chemical and / or plasma treatment. Be prepared according to the invention the free-radically coupled perfluoropolymer polymer materials, for example by a PTFE polymer (Zonyl ^® MP1600 or TF 9207) is used. This PTFE polymer has been produced in a polymerization process. In this case, persistent active or reactivatable perfluoroalkyl (peroxy) radical centers and / or groups which decompose thermally to form radicals have been formed, which undergo a radical coupling with the olefinically unsaturated polymers in the subsequent melt modification process.

The inventive radical coupling of the perfluoropolymer and the resulting integration / compatibilization into a matrix leads to the improvement of the material and the sliding friction properties and to increase the wear resistance in comparison to the unmodified Starting materials and the physical mixtures with perfluoropolymer. To improve the wear resistance, it is also advantageous to use the chemically coupled perfluoropolymer particles simultaneously as a storage medium for the PFPE additive (PFPE = perfluoropolyether), which is incompatible with the polymer matrix and contributes to lowering the coefficient of friction while increasing the wear resistance.

Due to the chemical coupling, these products have improved mechanical and tribological properties. These products are of particular interest for sliding friction processes. Radical modification / compatibilization of the perfluoropolymer particle with the matrix material provides good bonding and improved wear resistance because the perfluoropolymer grain can not be rubbed out of the matrix material by mechanical stress.

Since the perfluoropolymer grain is in direct interaction with the matrix, improved material properties are also observed in comparison to the physical mixtures, depending on the degree of bonding.

With the chemical coupling of the perfluoropolymer in the matrix, new materials are obtained which, with comparable coefficients of sliding friction, have improved wear resistance, ie. H. have an increased life in the applications. Furthermore, the addition of PFPE achieves a further reduction of the sliding friction coefficients and a noticeable improvement in the wear resistance, the chemically coupled perfluoropolymer also acting as storage medium.

• – Polytetrafluorethylen [PTFE],
• – Poly(tetraluorethylen-co-hexafluorpropylen) [FEP],
• – Poly(tetrafluorethylen-co-perfluorpropylvinylether) [PFA],
• – Poly(tetrafluorethylen-co-perfluor-2,2-dimethyldioxol) sowie auch das
• – Poly(chlortrifluorethylen) [PCTFE].

The following substances are counted among the perfluoropolymers:

• Polytetrafluoroethylene [PTFE],
• Poly (tetraloroethylene-co-hexafluoropropylene) [FEP],
• Poly (tetrafluoroethylene-co-perfluoropropyl vinyl ether) [PFA],
• - Poly (tetrafluoroethylene-co-perfluoro-2,2-dimethyldioxole) and also the
• - poly (chlorotrifluoroethylene) [PCTFE].

Furthermore, the invention will be explained in more detail with reference to several embodiments.

Comparative Example 1: Melt Modification of SBS with PTFE Micropowder,

40 g of SBS (Cariflex TR 1102 S, stabilized) is melted at 160 ° C. in a laboratory kneader at 60 rpm. After 3 minutes, 20 g of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are added. 5 minutes after the PTFE addition, the experiment is stopped and the material removed from the kneader chamber. The SBS matrix material is separated from the PTFE solid by dissolving in methylene chloride and centrifuging. The solid product / the residue is re-slurried with methylene chloride. The dissolution / extraction and centrifugation was repeated 4 times, then the PTFE solid product was separated and dried.

Infrared spectroscopic examination of the separated purified PTFE micropowder did not yield any chemically coupled PTFE SBS material. No SBS absorptions in the IR spectrum are found. This physical PTFE-SBS mixture is used as a standard for the measurement of the coefficient of sliding friction and the wear resistance during the tribological investigations.

Example 1: Melt Modification of SBS with PTFE Microfluidic TF 9207 (Dyneon)

The experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 1, however, 20 g of PTFE emulsion polymer TF 9207 (Dyneon) instead of the thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) were used.

Infrared spectroscopic examination of the separated and purified PTFE micropowder revealed detectable SBS absorptions besides those of PTFE as evidence for chemically coupled PTFE SBS material.

In Comparative Example 1 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological investigations showed that the chemically coupled PTFE-SBS material has a comparable coefficient of sliding friction for the physical mixture, but that an increased wear resistance can be observed. The wear in the block / ring experiment with the chemically coupled material has a reduction to 65% compared to the physical mixture (Comparative Example 1).

Example 2: Melt Modification of SBS with PTFE micropowder Zonyl ^® MP 1600 (DuPont)

Experimental procedure and separation of the polymer matrix was carried out similarly to Comparative Example 1, however, there are 1600 (DuPont) instead of the thermally degraded PTFE polymer TF 9205 PTFE 20 g Zonyl ^® MP (Dyneon, unirradiated) is used.

Infrared spectroscopic examination of the separated and cleaned PTFE micropowder revealed detectable SBS absorptions besides those of PTFE as evidence for chemically coupled PTFE SBS material. In Comparative Example 1 (physical mixture) only pure PTFE in the IR spectrum was detectable. The tribological investigations showed that the chemically coupled PTFE-SBS material has a comparable coefficient of sliding friction for the physical mixture, but that an increased wear resistance can be observed. The wear in the block / ring experiment with the chemically coupled material has a reduction to 68% compared to the physical mixture (Comparative Example 1).

Comparative Example 2: Melt modification of SBR with PTFE micropowder

40 g of SBR elastomer are cut in small pieces at 140 ° C in a laboratory kneader at 60 rpm. After 2 minutes, 20 g of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are added. 5 minutes after the PTFE addition, the experiment is stopped and the material removed from the kneader chamber. The SBR matrix material is separated from the PTFE solid by dissolving in methylene chloride and centrifuging. The solid product / the residue is re-slurried with methylene chloride. The dissolution / extraction and centrifugation was repeated 4 times, then the PTFE solid product was separated and dried.

Infrared spectroscopic examination of the separated purified PTFE micropowder did not yield a chemically coupled PTFE SBR material. No SBR absorptions in the IR spectrum are found. This physical PTFE-SBR blend, after vulcanization, is the standard for the measurement of the coefficient of sliding friction and wear resistance in tribological investigations.

Example 3: Melt modification of SBR with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 2, but 20 g of PTFE emulsion polymer TF 9207 (Dyneon) instead of the thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are used.

IR spectroscopic examination of the separated and purified PTFE micropowder revealed detectable SBR absorptions besides those of PTFE as evidence for chemically coupled PTFE SBR material. In Comparative Example 2 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological tests were carried out on vulcanized specimens - the experiments showed that the chemically coupled PTFE SBR material has a comparable sliding friction coefficient to the physical mixture (Comparative Example 2), but that an increased wear resistance is observed. The wear on the block / ring test showed a reduction to 70%.

As a further tribological examination, shortly before the laboratory kneader test was discontinued, 0.5% by weight PFPE (perfluoropolyether, DuPont) was added, which showed that the vulcanized specimens had a sliding friction coefficient of about 30% compared to the physical mixture (comparative example 2). lower value and that an increase in wear resistance is observed. The wear on the block / ring test showed a reduction to 25%.

Example 4: Melt modification of SBR with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 2, however, 20 g of PTFE Zonyl ^® MP 1600 (DuPont) instead of the thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are used.

IR spectroscopic examination of the separated and purified PTFE micropowder revealed detectable SBR absorptions besides those of PTFE as evidence for chemically coupled PTFE SBR material. In Comparative Example 2 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological tests were carried out on vulcanized specimens - the experiments showed that the chemically coupled PTFE SBR material has a comparable sliding friction coefficient to the physical mixture (Comparative Example 2), but that a significantly increased wear resistance is observed. The wear in the block / ring test showed a reduction of 20%.

As a further tribological examination, shortly before the laboratory kneader test was discontinued, 0.5% by weight PFPE (perfluoropolyether, DuPont) was added, which showed that the vulcanized specimens had a sliding friction coefficient of about 30% compared to the physical mixture (comparative example 2). lower value and that an increase in wear resistance is observed. The wear in the block / ring test showed a reduction to 60%.

Comparative Example 3: Melt Modification of ABS with PTFE Micropowder,

40 g ABS are melted at 160 ° C in the laboratory kneader with 60 U / min. After 3 minutes, 20 g of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are added. 5 minutes after the PTFE addition, the experiment is stopped and the material removed from the kneader chamber. The ABS matrix material is separated from the PTFE solid product by dissolving in methylene chloride and centrifuging. The solid product / the residue is re-slurried with methylene chloride. The dissolution / extraction and centrifugation was repeated 4 times, then the PTFE solid product was separated and dried.

IR spectroscopic examination of the separated and purified PTFE micropowder did not yield any chemically coupled PTFE ABS material. There are no ABS absorptions found in the IR spectrum. This physical PTFE-ABS mixture serves as the standard for the measurement of the coefficient of sliding friction and the wear resistance in the context of tribological investigations.

Example 5: Melt modification of ABS with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 3, however, 20 g PTFE TF 9207 (Dyneon) instead of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are used.

IR spectroscopic examination of the separated and purified PTFE micropowder revealed detectable ABS absorptions besides those of PTFE as evidence for chemically coupled PTFE-ABS material. In Comparative Example 3 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological investigations showed that the chemically coupled PTFE-ABS material has a comparable coefficient of sliding friction for the physical mixture, but that an increased wear resistance can be observed. The wear in the block / ring experiment with the chemically coupled material has a reduction to 70% compared to the physical mixture (Comparative Example 3).

Example 6: Melt-modified ABS with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out similarly to Comparative Example 3, but 20 g of PTFE MP Zonyl ^® 1600 (DuPont) instead of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) is used.

IR spectroscopic examination of the separated and purified PTFE micropowder revealed detectable ABS absorptions besides those of PTFE as evidence for chemically coupled PTFE-ABS material. In Comparative Example 3 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological investigations showed that the chemically coupled PTFE-ABS material has a comparable coefficient of sliding friction for the physical mixture, but that a significantly increased wear resistance can be observed. The wear in the pad / ring experiment with the chemically coupled material has a reduction to 75% compared to the physical mixture (Comparative Example 3).

Comparative Example 4: Melt Modification of NBR with PTFE Micropowder,

40 g of NBR elastomer are cut in small pieces at 80 ° C. in a laboratory kneader at 50 rpm. After 2 minutes, 20 g of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are added. 5 minutes after the PTFE addition, the experiment is stopped and the material removed from the kneader chamber. The NBR matrix material is separated from the PTFE solid by dissolving in methylene chloride and centrifuging. The solid product / the residue is re-slurried with methylene chloride. The dissolution / extraction and centrifugation was repeated 4 times, then the PTFE solid product was separated and dried.

IR spectroscopic examination of the separated purified PTFE micropowder did not yield any chemically coupled PTFE-NBR material. No NBR absorptions are found in the IR spectrum. This physical PTFE-NBR mixture is used after vulcanization as a standard for the measurement of the sliding friction coefficient or the wear resistance in the context of tribological investigations.

Example 7: Melt modification of NBR with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 4, but 20 g PTFE TF 9207 (Dyneon) instead of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) are used.

Infrared spectroscopic examination of the separated and purified PTFE micropowder yielded detectable NBR absorptions in addition to those PTFE as proof of chemically coupled PTFE-NBR material. In Comparative Example 4 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological tests were carried out on vulcanized specimens - the experiments showed that the chemically coupled PTFE-NBR material has a comparable sliding friction coefficient to the physical mixture (Comparative Example 4), but that an increased wear resistance is observed. The wear on the block / ring test showed a reduction to 65%.

As a further tribological examination, shortly before the laboratory kneader test was discontinued, 0.5 wt.% Of PFPE (perfluoropolyether, DuPont) was added, which showed that the vulcanized specimens had a sliding friction coefficient of about 30% compared to the physical mixture (comparative example 4). lower value and that an increase in wear resistance is observed. The wear on the block / ring test showed a reduction to 65%.

Example 8: Melt modification of NBR with PTFE micropowder

Experimental procedure and separation of the polymer matrix was carried out similarly to Comparative Example 4, but 20 g of PTFE MP Zonyl ^® 1600 (DuPont) instead of thermally degraded PTFE polymer TF 9205 (Dyneon, unirradiated) is used.

Infrared spectroscopic examination of the separated and purified PTFE micropowder yielded detectable NBR absorptions besides those of PTFE as evidence for chemically coupled PTFE-NBR material. In Comparative Example 4 (physical mixture) only pure PTFE in the IR spectrum was detectable.

The tribological tests were carried out on vulcanized specimens - the experiments showed that the chemically coupled PTFE-NBR material has a comparable sliding friction coefficient to the physical mixture (Comparative Example 4), but that a significantly increased wear resistance can be observed. The wear in the block / ring test showed a reduction to 72%.

As a further tribological examination, shortly before the laboratory kneader test was discontinued, 0.5 wt.% Of PFPE (perfluoropolyether, DuPont) was added, which showed that the vulcanized specimens had a sliding friction coefficient of about 30% compared to the physical mixture (comparative example 4). lower value and that an increase in wear resistance is observed. The wear in the block / ring test showed a reduction to 48%.

Comparative Example 5: Melt-Modification of SBS with FEP

40 g of SBS (Cariflex TR 1102 S, stabilized) is melted at 160 ° C. in a laboratory kneader at 60 rpm. After 3 minutes, 20 g of FEP polymer (thermally degraded and post-treated, unirradiated) are added. 5 minutes after the FEP addition, the experiment is stopped and the material removed from the kneader chamber. The SBS matrix material is separated from the FEP solid by dissolving in methylene chloride and centrifuging. The solid product / the residue is re-slurried with methylene chloride. The dissolution / extraction and centrifugation was repeated 4 times, then the FEP solid product was separated and dried.

IR spectroscopic analysis of the separated purified FEP revealed pure FEP and no chemically coupled FEP-SBS material. No SBS absorptions in the IR spectrum are found. This physical FEP-SBS mixture serves as the standard for the measurement of the coefficient of sliding friction and the wear resistance in the context of tribological investigations.

Example 9: Melt-Modification of SBS with FEP

The experimental procedure and separation of the polymer matrix was carried out analogously to Comparative Example 1, however, 20 g of FEP polymer were used instead of the thermally degraded FEP polymer (unirradiated).

IR spectroscopic analysis of the separated and purified FEP revealed detectable SBS absorptions besides those of FEP as evidence for chemically coupled FEP-SBS material.

In Comparative Example 1 (physical mixture), only pure FEP was detectable in the IR spectrum.

The tribological investigations showed that the chemically coupled FEP-SBS material has a comparable sliding friction coefficient for the physical mixture, but that an increased wear resistance is observed. The wear in the block / ring experiment with the chemically coupled material has a reduction to 76% compared to the physical mixture (Comparative Example 1).

Claims (12)

Radically coupled perfluoropolymer polymer materials consisting of perfluoropolymer in the form of polytetrafluoroethylene [PTFE], poly (tetrafluoroethylene-co-hexafluoropropylene) [FEP], poly (tetrafluoroethylene-co-perfluoropropylvinylether) [PFA], poly (tetrafluoroethylene-co-perfluoro 2,2,2-dimethyldioxole) and / or poly (chlorotrifluoroethylene) [PCTFE], at the perfluoropolymer chains of which polymers having olefinically unsaturated groups in the main chain and / or in the side chain in the melt are chemically radically coupled by way of a reactive reaction, with those to the free radical Necessary radicals in the perfluoropolymer are persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups which do not originate from an irradiation process and / or a plasma modification. Radically coupled perfluoropolymer polymer materials according to claim 1, wherein the persistent reactive and / or reactivatable perfluoroalkyl (peroxy) radicals and / or the radicals from thermally decomposed groups originate from a polymerization process. Radically coupled perfluoropolymer polymer materials according to claim 1, in which the binding site of the polymers with the perfluoropolymer chain on the polymer chain is randomly distributed. Radically coupled perfluoropolymer polymer materials according to claim 1, in which as polymers SBS, ABS, SBR, NBR, NR and other butadiene and / or isoprene and / or chloroprene homo-, -Co- or -Ter polymers radically are coupled. Radically coupled perfluoropolymer polymer materials according to claim 1, wherein the perfluoropolymers are PTFE and / or FEP. A process for the preparation of radically coupled perfluoropolymer-polymer materials in which perfluoropolymer having persistent active or reactivatable perfluoroalkyl (peroxy) radicals and / or radicals from thermally decomposed groups not derived from an irradiation process and / or plasma modification is melted Reactively reacted with the addition of olefinically unsaturated polymers. Process according to Claim 6, in which PTFE or FEP are used as the perfluoropolymer. The method of claim 6, wherein the perfluoropolymer is used as a micropowder. Process according to Claim 6, in which the reaction is carried out in melt in a melt mixer. Process according to Claim 6, in which the reaction is carried out in melt in an extruder. Process according to Claim 6, in which polymers having olefinically unsaturated groups in the main chain and / or in the side chain are used. Process according to Claim 6, in which the polymers used are SBS, ABS, SBR, NBR, NR and also other butadiene and / or isoprene and / or chloroprene homo, co or terpolymers.