WO2005046974A1 - Method for the production of a high-strength plastic material, and use of said plastic material - Google Patents

Abstract

The invention relates to a method for producing a high-strength plastic material, comprising the following steps: the plastic material is manufactured; the plastic material is stretched; the plastic material is fixed; and the plastic material is crosslinked. The invention further relates to hollow plastic elements and plastic products that are produced according to said method.

Description

 Process for producing a high-strength plastic material and use of the plastic material

description

The invention relates to a method for producing a high-strength plastic material, the use of such a plastic material for producing a high-strength hollow body, a plastic hollow body made of the material described and fibers, strips, profiles, films, filaments, semi-finished products and composite materials made from this material.

It is known from the prior art to stretch plastics in order to improve their mechanical and physical properties. Such stretching does not lead to sufficient strength or physical properties under all operating conditions.

The prior art also knows dimensionally resettable objects made of plastic, for example shrink films, shrink tubes or the like. The plastic material is stretched and then cross-linked. Subsequent heating causes shrinkage due to the shape change memory of the plastic material. However, this process is not prevented by the method according to the invention. comparable, since according to the invention no shrinkage behavior is desired, on the contrary this should be explicitly excluded or reduced to a minimum value.

The described dimensionally resettable objects (shrink tubes, shrink films or the like) are thus designed with regard to their material in such a way that a shape change memory is impressed on them. After the change in shape, the mechanical properties, in particular the strength values, are again in the order of magnitude of the plastic material originally used (base polymer).

The invention has for its object to provide a method for producing a high-strength plastic material which provides high strengths and physical values of the plastic with simple and inexpensive applicability. Furthermore, the task is based on creating a high-strength plastic component.

According to the invention, the tasks are solved by the features of the respective independent claims, the respective sub-claims show further advantageous embodiments of the invention.

According to the invention, the plastic or plastic material is first stretched with thermal fixation, subsequently this is additionally crosslinked.

It is therefore provided according to the invention that the plastic material is brought into the desired pre-shape, for example by extrusion. This is followed by stretching the plastic material. As a result, the molecules are oriented so that an oriented structure results. After stretching, the plastic material is fixed and crosslinked, and fixing can take place during crosslinking, before crosslinking or after crosslinking. By fixing which one too annealing, the amorphous parts of the plastic material relax while the crystallites are retained in their orientation. For this purpose, the plastic material is preferably held, clamped or prevented from changing its shape. If this stretched or stretched material is then fixed or tempered, a very uniform lamellar structure of the crystallites is created. The slats are aligned perpendicular to the direction of fixation. Since fixing leads to the fact that restoring forces from the amorphous part are missing after fixing, tempering or relaxing, the plastic product is dimensionally stable even at higher temperatures. There is therefore no shrinking. The higher temperatures described here extend to the fixing temperature.

If, as was not provided for in the invention, the stretched or stretched material was tempered or fixed without preventing it from changing its shape, the original, disordered structure that was present before stretching or stretching would be restored. This process leads to the shrinkage of the material already described in connection with the prior art.

According to the invention, the stretching can take place uniaxially or multi-axially. The degree of stretching and the direction of stretching can be adapted to the respective geometry of the plastic material and the desired physical properties.

The plastic material according to the invention can be thread-like, strip-like or foil-like, but there are also many other geometric shapes. For example, it is also possible to first produce a hollow body, stretch it, fix it and then crosslink it. According to the invention, the thermal fixation (tempering) is preferably carried out by heating the plastic material to a temperature below the crystallite melting temperature and above the use temperature of the plastic part. In this process, the plastic material is under tension or is mechanically clamped and prevented from changing its shape, so that the stresses introduced by the stretching process are reduced. According to the invention, this is particularly important in order to exclude the shrinking process described above in connection with the prior art.

The crosslinking is preferably carried out according to the invention with the introduction of energetic radiation. Networking can take place with or without the addition of a kicker. Such a kicker can be, for example, DCP (dicumyl peroxide) or TAIC (triallyl isocyanurate). Other crosslinkers (radical formers, catalysts) are also possible.

The crosslinking by means of energetic radiation can take place, for example, by means of UV radiation, IR radiation, X-ray radiation or the like. The radiation can be specifically matched to the plastic material, for example a polymer and / or the kicker, in order to activate them accordingly, as is known from photocrosslinking. It is preferred if the polymer itself is not damaged. Such damage is avoided in particular if the kickers are added to the plastics material in a suitable manner. The dosing of the kicker can preferably take place in accordance with the amorphous or crystalline portion of the plastic material and the desired degree of crosslinking. This ensures that the crosslinking process is precisely controlled and that the crystalline areas of the stretched plastic material are not disturbed or destroyed. It proves to be particularly advantageous if a polymeric plastic, for example PE (polyethylene) or a thermoplastic blend (mixture) is used. According to the invention, all crosslinkable semi-crystalline plastics and cellulose can thus be used. The following are examples of such plastics:

PE polyethylene (PEX = radiation-crosslinkable PE) PA polyamide POM polyoximethylene PET polyethylene terephthalate PP polypropylene PB polybutene TPE thermoplastic elastomer

Using the method according to the invention it is thus possible to achieve very considerable increases in the mechanical properties of the plastic material. For example, it is possible to achieve a tensile strength of> 100 MPa and an elastic modulus of> 3500 MPa. These high mechanical strengths remain in the plastic material produced according to the invention over a long period of time.

The invention is described below on the basis of a simplified illustration in conjunction with the figures. It shows:

1 shows a simplified structural representation in the non-stretched state of the plastic material,

2 shows an illustration in the stretched state,

3 shows a representation in the subsequently networked state, 4 shows a diagram of a material according to the invention showing different parameters during different manufacturing stages,

5 shows a diagram to show the temperature module curve for stretching, fixing and crosslinking in a plastic material produced according to the invention, and

Fig. 6 is a diagram, analogous to Fig. 5, for a material according to the prior art, which is used for a shrink article with dimensional recovery.

The stretching of partially crystalline polymers creates crystalline zones which have the shape of needle crystals and / or have single-crystal platelets stacked one behind the other. Immediately after the stretching process, tensions due to stretching are still present in the amorphous areas. In the subsequent thermal fixation, these are reduced to such an extent that the finished plastic material remains largely dimensionally stable. According to the invention, a shrinkage of 0% is ideally generated. Depending on the process parameters and the plastics used, there may still be a slight shrinkage with regard to the dimensional stability of the plastic material to be achieved according to the invention, which is <2.5%, in the worst case <5%. To prevent shrinkage, it can also be provided according to the invention to use the plastic material in the composite and thus to support it, so that correspondingly low shrinkage values result in the composite.

Such a partially crystalline structure is shown in the simplified representation in FIG. 1. During the crystallization, the kickers are deposited at the phase boundaries.

2 shows the structure in the stretched state. This shows that the crystalline zones are each aligned by stretching.

In the crosslinking of the polymer and / or the kicker shown in FIG. 3 by the initiated chemical reaction, for example by introducing energetic radiation, the amorphous regions in which the kicker has accumulated are crosslinked between and with the crystals. This state is shown in Fig. 3. The networked points are identified by reference number 3. It goes without saying that the representation of FIGS. 1 to 3 only shows the processes very schematically and is only used for general explanation.

When crosslinking without the use of a kicker, the crosslinking reaction can also take place in the crystalline regions of the plastic material.

The plastic material according to the invention can be used, for example, for the production of hollow bodies, in particular tubular hollow bodies. A plastic hollow body of this type is distinguished in particular by high strength properties in comparison to the plastic hollow bodies known from the prior art.

1 to 3, the crystalline regions are each illustrated with reference number 1, while the amorphous regions are indicated with reference number 2.

The plastic material according to the invention is thus characterized in that the crystallites are crosslinked together with the amorphous regions across the phase boundaries and the plastic material does not have any significant memory and shrinkage (shrinkage) takes on the smallest possible value. This significantly improves the physical properties. There is a significant increase in the overall strength, the temperature resistance increases and the impact strength is significantly increased. These improvements in physical values occur particularly normal (perpendicular) to the direction of stretching.

In the plastic material produced according to the invention, the tendency to splices is also reduced, which otherwise can be very pronounced in the case of highly stretched plastic fibers due to the morphology.

4 shows a schematic diagram, in which different elasticity modules for a material sample according to the invention are shown in different process steps. Here mean:

A: sample in the unstretched state, B: sample in the stretched state, C: sample in the stretched and crosslinked state.

For the representation of FIG. 4, the lh modulus of elasticity was measured on a typical cross-linkable HD-PE (polyethylene) material. The degree of stretching was 400%. It can clearly be seen which significant increase in the modulus of elasticity results from the crosslinking (state C).

FIG. 5 shows a temperature module curve for stretching, fixing and crosslinking, the solid line illustrating the respective modulus values, while the dashed line represents the temperature curve. The following data were used for the manufacture and measurement:

Material: HD-PE for crosslinking (PEX, radiation-crosslinkable polyethylene) density: 946 kg / m ³ MFI (melt index): 8.5 g / 10 min tensile strength: 18 MPa extrusion: melt temperature: 200 ° C pressure in front of the nozzle: 42 bar stretching: stretching ratio : 380% stretching temperature: 125 ° C fixing: temperature: 120 ° C crosslinking: by means of 10 MeV rhodotron electron steel system wavelength: 510 n dose: 80 kGy

FIG. 5 shows particularly clearly which increase in the modulus of elasticity is experienced by networking (see also FIG. 4). This modulus of elasticity is used up to the application area, i.e. until the plastic material is used.

FIG. 6 shows a representation analogous to FIG. 5, the same material having the corresponding parameters being processed in order to produce a shrink article as described in the introduction in connection with the prior art. Specifically, the same data as for the comparison sample in FIG. 5 were used. However, the stretching temperature was 80 ° C, the activation took place at 120 ° C. The crosslinking dose was 60 kGy. It is particularly clear here that the modulus of elasticity remains constant over the entire processing process, so that there is no increase in the modulus of elasticity or other mechanical values.

Claims

Expectations

1. A process for producing a high-strength plastic material with the following steps: manufacturing the plastic material, stretching the plastic material, fixing the plastic material, crosslinking the plastic material.

2. The method according to claim 1, characterized in that a change in dimension of the plastic material is prevented during fixing.

3. The method according to claim 1 or 2, characterized in that the fixing is carried out so that the amorphous portions of the plastic material relax, but the crystallites of the plastic material maintain their orientation.

4. The method according to any one of claims 1 to 3, characterized in that the working steps and in particular the temperature control are chosen so that the finished plastic material has a shrinkage value <5%, preferably <2.5%.

5. The method according to any one of claims 1 to 4, characterized in that the working steps and in particular the temperature control are chosen so that the finished plastic material has a tensile strength> 100 MPa.

6. The method according to any one of claims 1 to 5, characterized in that the working steps and in particular the temperature control are selected so that the finished plastic material. E modulus> 3500 MPa.

7. The method according to any one of claims 1 to 6, characterized in that the fixing takes place during the crosslinking.

8. The method according to any one of claims 1 to 6, characterized in that the fixing takes place after the crosslinking.

9. The method according to any one of claims 1 to 8, characterized in that the stretching is carried out uniaxially.

10. The method according to any one of claims 1 to 8, characterized in that the stretching is carried out multiaxially.

11. The method according to any one of claims 1 to 10, characterized in that a kicker is added to the plastic material.

12. The method according to any one of claims 1 to 11, characterized in that the crosslinking takes place under the action of energetic radiation.

13. The method according to claim 12, characterized in that UV radiation is used as the energetic radiation.

14. The method according to claim 12, characterized in that X-radiation is used as the energetic radiation.

15. The method according to claim 12, characterized in that IR radiation is used as the energetic radiation.

16. The method according to any one of claims 1 to 15, characterized in that a thermoplastic blend is used as the plastic material.

17. The method according to any one of claims 1 to 16, characterized in that the individual steps (stretching, fixing, cross-linking) run in several stages.

18. The method according to any one of claims 1 to 17, characterized in that the method is repeated in a cascade.

19. Use of a plastic material, produced according to one of claims 1 to 18 for producing a hollow body.

20. Use according to claim 19 for the production of a tubular hollow body.

21. Plastic hollow body made of a plastic material, produced according to one of claims 1 to 18.

22. Plastic hollow body according to claim 21, characterized in that it is tubular.

23. Use of a plastic material, produced according to one of claims 1 to 18 for the production of fibers, tapes, profiles, foils, filaments, semi-finished products and / or composite materials.

24. Plastic body in the form of a fiber, a tape, a film, a profile or a filament, produced by a method according to any one of claims 1 to 18.