FI84843C - Process for producing fiber-reinforced raw material for plastics - Google Patents

Description

1 84843

METHOD OF MANUFACTURING A FIBER-REINFORCED PLASTIC RAW MATERIAL

The present invention relates to a process for producing a fiber-reinforced plastic material by a dry webbing process.

A problem with the manufacture of fiber-reinforced materials is often the bundle of the reinforcing fibers, whereby the fiber bundle is not fully opened into the matrix and the fiber distribution is uneven. The fibrous web is most often made by forming an aqueous dispersion of reinforcing fibers and particulate plastic material and filtering off the water. The disadvantage of this wet process is often the leaching of the coupling chemicals away from the pretreated fibers during the dispersion step.

It is an object of the present invention to avoid such drawbacks. The improved fiber distribution path can be made by the dry method so that the fiber is opened by carding to provide an open, porous, bulk web 20. Thanks to the dry process, the chemical treatment of the fibers can be chosen more widely than with the wet processes to suit different matrices, because there is no risk of leaching off the coupling chemicals.

The method of the present invention provides a product that is more homogeneous and has more favorable mechanical properties due to better coupling than products made by conventional methods.

The method according to the present invention comprises the following steps: - opening the fiber by carding - forming a web from the fibers opened by carding - applying a powdered matrix to the formed web 35 - folding the web layers on top of each other 2 84843 - heating, pressing and cooling the layered web

Glass fiber is usually used as the reinforcing fiber. The processability of glass fibers can be improved by mixing synthetic organic fibers with them, thus facilitating in-machine track transfers. The synthetic fibers can be selected such that a) they consist of the same polymer as the matrix material, whereby when heated they melt here and together form a matrix. Suitable are, for example, polypropylene, polyester and polyamide b) that they do not melt when heated but form a reinforcing part of the composite with the glass fiber. Suitable are, for example, aramid fiber, carbon fiber or a fiber having a significantly higher melting point than the matrix material used, e.g. polyester fiber in a polypropylene matrix.

The fibers can be pre-treated, e.g. with peroxide, in which case they behave when shaping, improving the flowability of the matrix and giving the product an even better surface.

The invention will be described in more detail with reference to the accompanying diagram.

25

The stem glass and synthetic fiber are dispensed with a belt scale 1 and initially carded with a shredder 2. The fibers are transferred to a fan 3 in a mixing tank 4, where they are mixed with a stream of air, i.e. homogenized and the basis weight is adjusted. Thereafter, the fibers are further opened on a textile nonwoven carding machine 5. The treated fibers are formed into a web 6 on a flat wire. After the formation of the web, a powdery matrix 7 is dispensed between each layer of fibrous web, using vibration if necessary. The basis weight of the web is determined in step 13. The machine layers by folding the thin layers on top of each other in the folding unit 8, whereby the desired basis weight of 3,84843 is reached and the matrix 7 is evenly distributed in the depth direction. This web is heated e.g. with a double wire press 11 above the melting point of the matrix e.g. e.g. polypropylene 190-200 eC or polyamide about 300 eC. The track 5 is then compressed and cooled under pressure and cut into sheets (12) of the desired size, which can be formed into the desired high-strength plastic products.

Prior to the press 11, a film 10 which is the same polymer as the matrix or a roll-finished film (9, 10) is applied by an extruder and heated simultaneously with the web in the press 11 to obtain a fiber-free layer which promotes a good, even surface. At the same point or already after track formation, the so-called roving-15 yarns or fabrics between web layers as well as various fibrous webs, e.g., a web made of electrically conductive fibers.

The length of the glass fiber is preferably 8-30 mm and the carding provides a 50-200 g m * 2 porous web.

20

Synthetic organic fibers are added to the glass fibers in an amount of 5-20% by weight.

The powdered matrix is added between each layer of fibrous web 25 in the correct weight ratio, normally 80-50% of the total weight. All thermoplastics are suitable for this purpose.

The folding unit gives the desired basis weight for the product, 30 e.g. 2000-4000 g m "2.

The method of the present invention results in a reinforced thermoplastic sheet with a preferred fiber distribution. Due to the relative shortness of the fibers, the fibers travel 35 with the flowable matrix to form even 4,84843 shapes, such as reinforcing ribs, where the strength provided by the fibers is required.

E.g.

5 12 mm long glass fibers to which 10% by weight of polypropylene fibers have been added are treated with a carding machine. After the formation of the web, polypropylene powder is sprinkled on the web, whereby the proportion of reinforcing fiber becomes 30% by weight. The thin layers of the track are then folded over to give a mass weight of 3000 g m * 2. This track is heated to 190 ° C and pressed at 2 bar and cooled and cut into sheets of the desired size, from which the desired products with a tensile strength of 90 MPa, elongation at break of 2.5%, impact strength of 55 Charpy, bending strength of 140 N 15 mm * 2, stretching modulus 4500 N mm "2 and bending modulus 5500 N mm" 2. The web can also be coated with polypropylene foil if a very smooth surface is desired.

Claims (6)

A method of manufacturing a fiber-reinforced plastic raw material by a dry process, characterized in that the process comprises steps in which - formed the web - layers of the web are folded on each other - the layered web is heated, compressed and cooled. Method according to Claim 1, characterized in that the layered web is laminated. 3. A method according to claim 1, characterized in that the reinforcing fiber is glass fiber. 20 Method according to Claim 3, characterized in that the length of the glass fiber is 8 - 30 mm. 5. Process according to claim 3, characterized in that, apart from fiberglass, synthetic organic fibers are also used. Method according to Claim 5, characterized in that 5 - 20% synthetic fibers are added. li