DE19711247C2 - Process for the production of long fiber granules based on fiber sliver - Google Patents

Description

description

Long fiber granules or long fiber pellets have been around for about 10 years Market offered. Because of the large fiber lengths, which ideally the Granulate length can match with long fiber reinforced thermoplastics higher mechanical properties than with thermoplastic short fiber comp can be achieved. Above all, the large energy absorption capacity sudden or sudden stress and safe breaking behavior The long fiber reinforced thermoplastics are characterized by no broken fragments. The production of long-fiber granules or long-fiber pellets becomes main Realized with the help of the melt pultrusion process. Reason the principle of this process is the continuous pulling in of reinforcement fiber strands (rovings) in a tool with simultaneous feeding of molten matrix material. The rovings are spread out in the tool, to ensure a good watering. Ideally, the polymer penetrates melt the rovings and the single filaments with a melt film envelops. At the exit of the tool, the strand is passed through a nozzle leads, which creates a defined cross-section. After that the matrix material is cooled and the material is cut to length stranges. The fiber length in a granulate produced in this way corresponds to the stretched position of the fibers, the length of the granules.

The melt pultrusion process is in a variety of variants is known and is used both for the production of long-fiber granules and Production of semi-finished products used (see US 3,993,726, GB 1,439,327).

The production of long-fiber granules using the Extrusion process (PA 36-254 847 A). This can be due to entanglements and Loops of reinforcing fibers make the length of individual fibers even longer than the length of the granules. The majority of the reinforcing fibers is due to the Shear effect of the extruder screws shorter than the length of the granulate. Pultrusion processes for prepreg processing are also known. With these special pultrusion processes, the supply of ge molten polymer material are eliminated. Use is a prerequisite for this of pre-impregnated reinforcing fiber rovings (prepregs).  

The impregnation of the reinforcing fibers with the matrix material can be different ways. The most common methods of prepreg manufacturing are melt, solution and powder impregnation processes as well the hybrid yarn technology.

In the pultrusion of pre-impregnated reinforcing fiber rovings, the Roving is first heated in a preheating zone. This will make the matrix material melted. Then the molding takes place in a be heated mold nozzle. The material passes through for consolidation and cooling another cooling nozzle. Subsequently, the strand can be a granulator fed and cut into pellets. The production of semi-finished products such as B. pipes or profiles is also possible according to the same principle (cf. Müller, W .: "Pultrusion of fiber composite material" Kunststoffbera ter 12/1991, pp. 22-30; Michaeli, W .: "Production of components in the Pultru sions- and winding process "Kunststoffberater 6/1995, S. 29-33).

The prerequisite for processing fiber composites in the pultrusion process is however in any case a strand-like semi-finished fiber material (roving or fiber yarn), which can transmit higher tensile forces (≧ 10 N). At Use of reinforcing fibers such as glass, aramid and carbon Fibers is not a problem because the reinforcing fibers are used in the production continuously withdrawn from nozzles and folded into rovings. Derar rovings can be unwound during pultrusion and with high tensile forces are applied.

In addition to the synthetic reinforcing fibers, there are also natural fibers such as B. flax, hemp, nettle, jute u. a. Plant fibers for reinforcement suitable for plastics. Due to their natural origin, However, the natural fibers are only unlocked with a limited fiber length will be. For this reason, the use of such fiber materials in continuous processing processes such as B. the winding and pul trusion process problematic. To create an endless textile Semi-finished products made of natural fibers are first a ribbon and then a yarn generation required. The tensile strength of such fiber yarns depends in addition to the fiber properties, especially the number of Dre given depended. As a rule, fiber yarns with little twist have only minor twists Tensile strengths (<10 N) and are not suitable for processing in pultrusion method. Higher strength yarns can be made by giving a strong twist are generated, but are only due to the increasing compaction of the material difficult to melt. In addition, the manufacturing process is complex and expensive.

The present invention is therefore based on the object, the manufacturer long fiber granulate based on sliver from a Staple fiber blend of reinforcing fibers and thermoplastic fibers realize. This can make the complex and expensive yarn manufacturing process be saved.

With reference to FIG. 1, the invention is explained in detail below by means of examples of execution.

According to Fig. 1, the object is achieved in that a sliver ( 2 ) made of a fiber mixture of reinforcing fibers and thermoplastic fibers is fed from a storage container ( 1 ) via take-off rollers ( 3 ) to a preheating zone ( 4 ) and passes through it. This melts the thermoplastic fibers.

After leaving the preheating zone, the heated strand of material passes through a heated nozzle ( 5 ) which calibrates the cross-section of the strand. Subsequently, the material strand is given a certain number of rotations by a rotating member 1 ( 6 ) (10-150 rotations / m). This significantly increases the tensile strength of the strand. At the same time, the reinforcing fibers are compressed in the strand and glued to the melted thermoplastic material. The rotation of the material strand continues through the heating nozzle into the preheating zone and is limited by the pair of draw rollers ( 3 ). After leaving the heating nozzle and giving the rotation, the strand passes through a cooling section ( 7 ) in order to cool and consolidate the melted thermoplastic material. The rotation imparted to the material strand is kept constant over the length of the cooling section by a rotating member 2 ( 8 ) rotating at the same speed. The strand is then cut into pellets (long-fiber granules) with the aid of a granulator ( 9 ).

The advantage of the method is the possibility of heating and rotating Issuing slivers of staple fibers in a continuous process into one form the consolidated strand. The strand produced in this way can clearly transmit higher tensile forces than a sliver. This also allows natural fibers with limited fiber length (30 mm ≦ I ≦ 200 mm) in connection with low melting thermoplastic fibers such. B. polypropylene or Polyethylene fibers, used for long fiber granulate production.

Long fiber granules produced in this way have compared to conventional ones Long fiber-containing pellets also have the advantage that the reinforcing fibers, due to the rotation of the strand of material, are arranged spirally. The achievable fiber length in a granule particle is therefore greater than that Granule length.  

Embodiment 1

A sliver of flax and polypropylene fibers with a sliver fineness of 8 ktex, an average fiber length of the flax and polypropylene fibers of 40 mm and a flax fiber content of 30% by weight is heated to a temperature of 200 ° C. over a 1.5 m long preheating section heated. After leaving the preheating section, the sliver passes through a nozzle heated to 200 ° C with a diameter of 3 mm. After leaving the nozzle, the fiber sliver is given 50 turns / m. The material is then cooled to 50 ° C in a downstream cooling section and consolidated. The rotation given is kept constant over the length of the cooling section. Finally, the material strand is cut to length with the aid of a granulator to form pellets with a length of 20 mm.

Embodiment 2

A sliver of hemp and polypropylene fibers with a sliver count of 10 ktex, an average fiber length of hemp and polypropylene fibers of 60 mm and a hemp fiber content of 20% by weight is heated to a temperature of 200 ° C over a 1.5 m long preheating section heated. After leaving the preheating section, the sliver passes through a nozzle heated to 200 ° C with a diameter of 4 mm. After leaving the nozzle, the sliver is given 80 turns / m. The strand of material is cooled to 50 ° C in the downstream cooling section, consolidated and cut to length to form pellets with a length of 30 mm after leaving the cooling section.

Claims (6)

1. A process for the production of long-fiber granules, in particular with natural fiber reinforcement, characterized in that a sliver ( 2 ) of a fiber mixture of reinforcing fibers and thermoplastic fibers, from a storage container ( 1 ) via take-off rollers ( 3 ) a preheating zone ( 4 ) and this is fed passes through, then drawn through a heating nozzle ( 5 ), subsequently rotated for compacting and solidification by rotating elements ( 6 ), ( 8 ), passed through a cooling section ( 7 ) for consolidation and cut into pellets. 2. The method according to claim 1, characterized in that the number of given rotations in a range of 10 to 150 revolutions per m lies. 3. The method according to claim 1 and 2, characterized in that the thermoplastic fibers have a melting point ≦ 210 ° C. 4. The method according to claim 1 to 3, characterized in that the nature fiber content in the sliver is between 10 and 60 wt .-%. 5. The method according to claim 1 to 4, characterized in that the nature fibers in the sliver have an average fiber length between 30 and 200 mm to have. 6. The method according to claim 1 to 5, characterized in that the band fineness is in a range from 5 to 30 ktex.