IMPREGNATION SYSTEM AND METHOD FOR IMPREGNATING A TEXTILE FABRIC FOR COMPOSITE COMPONENTS

Abstract

An impregnation system and a method for impregnating a textile fabric for composite components are described. A matrix 2 can be applied to a textile fabric 1 in such a way that the matrix 2 penetrates it at least partially and/or at least on one side. A first and a second endless belt 1 each designed as a belt loop are provided for the impregnation system. Between the first 4 and the second belt loop 5, the textile fabric 1 can guided on the mutually facing surfaces 6 of the belt loops and can be impregnated there. The deflection rollers 7 are provided in the respective belt loop 4, 5 of the respective endless belts at the deflection areas, with at least one roller being adjustable in the direction of the mutually facing surfaces 6 of the belt loops 4, 5. By adjusting the rollers 8 in the y direction, the wrap angle and thus the pressure exerted on the textile fabric during impregnation is controlled.

Claims

1. Impregnation system for impregnating a textile fabric (1) for composite components, by means of which a matrix (2) can be applied to the textile fabric (1) in such a way that the matrix (2) penetrates it at least partially and/or at least on one side, characterized in that a first and a second endless belt designed as a belt loop (4, 5) are provided, between which the textile fabric (1) can be guided and impregnated on their mutually facing surfaces (6) and which have deflection rollers (7) at their respective deflection areas, from of which at least one roller can be adjusted in the direction of the mutually facing surfaces (6) of the belt loops, and that at least one further roller (8) is arranged within at least one of the belt loops (4, 5), which is adjustable in the direction of the mutually facing surfaces (6), the deflecting rollers (7) and the at least one further roller (8) being adjustable independently of one another at least in the y-direction.

2. (canceled)

3. Impregnation system according to claim 1, characterized in that at least one of the belt loops (4, 5) has a plurality of further rollers (8) which are arranged between the deflection rollers (7) and are adjustable at least with one directional component perpendicular to the facing surfaces (6) so that they can be immersed in the belt loop region (9) of the other belt loop.

4. Impregnation system according to claim 1, characterized in that the adjustable deflection rollers (7) are adjustable independently of one another.

5. Impregnation system according to claim 1, characterized in that the further rollers (8) and/or the deflection rollers (7) are adjustable in the direction of the mutually facing surfaces (6) and perpendicular to it.

6. Impregnation system according to claim 1, characterized in that the textile fabric (1) on the at least one further roller (8) when immersed in the other belt loop (4 or 5) has a variable wrap angle depending on the immersion depth, wherein the endless belts can be regulated with respect to their contact pressure on the further roller (8) on the textile fabric (1) by adjusting the deflecting rollers (7) in the direction of the mutually facing surfaces (6).

7. Impregnation system according to claim 1, characterized in that at least the further rollers (8) are bale-shaped or concave.

8. Impregnation system according to claim 1, characterized in that at least the further roller (8) is movable, in particular vibratable, in its longitudinal direction.

9. Impregnation system according to claim 1, characterized in that at least the further roller (8) can be tempered.

10. Impregnation system according to claim 1, characterized in that the endless belts are temperature-stable, low-friction and non-stick coated.

11. Impregnation system according to claim 1, with a matrix impregnated textile fabric (1) which has a unidirectional layer comprising fibers or a multi-axial scrim.

12. Fabric according to claim 11, the matrix (2) of which is a resin matrix, in particular a thermoplastic resin matrix.

13. Method for impregnating a textile fabric (1) for composite components, which is impregnated with a matrix (2) in which the textile fabric (1) is guided between two belt loops (4, 5) formed from an endless belt and running over deflection rollers (7), the contact pressure of which on the textile fabric (1) impregnated with the matrix (2) is controlled by controlling the tension of the endless belts and by adjusting the deflection rollers (7) and further rollers (8) in the direction of the mutually facing surfaces (6) of the belt loops (4, 5) and by varying the wrap angle of the endless belts on the rollers (7), the deflection rollers (7) and the at least one further roller (8) being adjusted independently of one another in the y-direction.

14. Method according to claim 13, in which the contact pressure is set so that the textile fabric (1) is at least partially impregnated with the matrix (2), in particular on both sides.

15. The method of claim 14, wherein the textile fabric (1) is completely impregnated.

16. Method according to 13, in which the textile fabric (1) is a unidirectional layer or a multi-axial layer, which is impregnated with a matrix (2), in particular a thermoplastic matrix.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] Further advantages, possible applications and details of the impregnation system according to the invention will now be explained in detail using the following drawing. In the drawing:

[0031] FIG. 1 shows an impregnation system or an impregnation module with two mutually assigned belt loops with respective deflection rollers and further rollers;

[0032] FIG. 2 shows a further roller within a belt loop showing the wrap angle through the textile fabric; and

[0033] FIG. 3 shows a system made up of various modules for the production of impregnated unidirectional single-layer tapes and multi-layer composite semi-finished products with multiaxial reinforcement alignment with impregnation module.

DETAILED DESCRIPTION

[0034] FIG. 1 shows an impregnation system or an impregnation module 13 (see FIG. 3), which has two belt loops 4, 5 assigned to each other. The first 4 and the second belt loop 5 are formed by respective endless belts which have deflection rollers 7 at their deflection areas and additionally have a plurality of further rollers 8 arranged between the respective deflection rollers 7.

[0035] The deflection rollers, over which the respective endless belts are guided, span a belt loop region 9 between the top and the bottom. The first belt loop 4 shown above in FIG. 1 has three further rollers 8 arranged between the two deflection rollers 7 and forms a surface 6 which is assigned to the second belt loop 5 shown below in FIG. 1. That is, the lower side of the belt loop 4 and the upper side of the belt loop 5 are facing towards each other. The textile fabric 1 is passed between the inclined surfaces 6 and subjected to a corresponding pressure, which is intended to ensure that the textile fabric consists of a pure textile fabric 3 and a matrix 2 in the form of, for example, a film or a fleece. The deflection rollers 7 are adjustable in the x-direction, which is indicated by the horizontal thick arrow on the upper right deflection roller 7. As a result, the tension of the endless belt within the first belt loop 4 can be changed. Arranged within the belt loop 4 are three further rollers 8, which are at a distance from one another which is large enough that the rollers 8 in the belt loop 4 can immerse with a certain depth in the belt loop region 9 of further rollers 8, which are arranged in the second belt loop 5. Likewise, the further rollers 8 of the second belt loop 5 can immerse into the belt loop region of the first belt loop 4, not shown, and likewise also between the further rollers 8 in the second belt loop 5, which are spaced from one another. By adjusting the other rollers 8 in the y-direction, the wrap angle that the textile fabric experiences in the region of the mutually facing surfaces 6 when conveying over the respective additional roller 8 is varied. The deeper the further roller immerses into the space between the further rollers 8 of the opposite belt loop, the greater the wrap angle. The wrap angle guarantees a substantially uniform pressurization of the textile fabric 1 together with the matrix 2, so that an substantially constant pressure can be exerted on the matrix 2 over a surface region, which penetrates evenly into the actual textile fabric 3 and accordingly causes an even distribution there.

[0036] If the other rollers 8 are displaced in the y-direction, this causes a shortening of the length of the belt loop, which is compensated for by a corresponding setting or adjustment of the deflection rollers 7 in the x direction. However, it is also conceivable not to adjust the deflection rollers 7 in the x-direction when the further rollers 8 are adjusted in the y-direction for immersion in the belt loop region 9 of the respective other belt loop 4 or 5, so that the belt tension of the respective belt loop is increased, as a result of which the pressure which forms on the textile fabric 1 together with the matrix 2 in the region of the wrap angle can be increased by the further roller 8.

[0037] In FIG. 2 it is shown how the fabric consisting of a material layer A, the matrix, and the material layer B, the textile layer, is applied to the further roller 8 by the wrap angle, as a result of which a compressive force FD on the wrap angle in the region of the wrap angle textile fabric 1 is exercised. At the same time, a corresponding belt tension is generated in accordance with the adjustment of the deflection rollers 7 in the x-direction, which is shown in FIG. 2 by the tensile force F.sub.Z in the direction of the textile fabric 1. As a result, the corresponding pressurization when passing through the impregnation module is transferred to the layered material system, namely the textile fabric 1, which means that the flowable material layer of the matrix 2 impregnates the porous material layer of the textile layer 3 due to the pressure acting in the thickness direction. The pressure builds up along the textile fabric 1 in the conveying direction. This allows the air to escape from the porous layer against the direction of conveyance.

[0038] The impregnation module shown in principle in FIGS. 1 and 2 has the advantage that, via the adjustable wrap angle, the pressure force exerted and thus the respective length from a respective further roller 8 onto the textile fabric 1 for penetrating the matrix 2 into the porous textile material layer 3, i.e. the textile fabric 1, is adjustable. For this purpose, the deflection rollers 7 and expediently also the further rollers 8 within the respective belt loop 4, 5 can be varied in the y-direction. The deflecting rollers 7 can be adjusted at least in the x-direction in order to compensate for a reduction in length by adjusting the further rollers 8 in the y-direction for the respective belt loop 4, 5. If the deflecting rollers 7 are arranged one below the other in the impregnation system shown in FIG. 1, the adjustment in the y direction is dispensed with in the case of such an arrangement, since the pressure introduced linearly into the textile fabric is to be avoided. However, it is also possible for the first band loop 4 and the second band loop 5 to have a different length. In such a case, the deflection rollers 7 of the one belt loop 4 or 5 can of course immerse into the belt loop region 9 of the other belt loop 4 or 5. The deflecting rollers 7 can thus take over the function of the further rollers 8 arranged within a respective belt loop.

[0039] FIG. 3 shows how an impregnation system is arranged as an impregnation module 13 in a complete system in the sense of a two-stage processing technology for the production of impregnated unidirectional single-layer tapes and multi-layer composite semi-finished products with multiaxial reinforcement alignment. The basic structure of such a complete system has a creel 10, from which a corresponding number of threads is drawn, which are combined in a unit, a spreading module 11, connected downstream of the creel 10, in such a way that the widest possible spreading is achieved in order to achieve the lowest possible mass per unit area. The spreading module 11 is followed by a dewinding unit 12, which has preferably wound up the matrix 2 as a film or fleece, so that the processing of the matrix 2 results in a flat structure 1, which has an actual textile layer 3 and a matrix layer 2, which when passing through the system are combined in such a way that the matrix 2 penetrates the porous textile layer 3. The system can be set so that the matrix material has completely penetrated into the porous textile layer. However, it is also possible for the matrix 2 to penetrate into the textile fabric from both sides of the textile layer 3. Furthermore, it is possible for the matrix 2 to completely penetrate the textile layer.

[0040] The dewinding unit 12 for the matrix 2 connects to the impregnation system 13, i.e. the impregnation module, which is also referred to as the consolidation module. The basic structure of this impregnation module is that which has already been described with reference to FIGS. 1 and 2. After the impregnation system, a winding is carried out in the downstream turret winder 14 with simultaneous turning of the impregnated textile fabric. In the exemplary embodiment according to FIG. 3, the textile fabric 1 after its impregnation is an impregnated UD tape 15, which is unwound in a tape dewinding unit 16 and fed to a laminating module 17. A laminating module is always used when additional layers are to be laminated to the impregnated textile fabric, which is done in the case of composite components which are intended to achieve a predetermined property. In a cross-cutting module 18 downstream of the laminating module 17, the impregnated and laminated textile fabric is cut into lengths which are placed on a pallet in the sense of palletizing 19. The semi-finished products produced in this way can be brought into appropriate shapes for further use due to the use of thermoplastics for the matrix material by heating, which is done at the place of use without a matrix 2 then having to be added under difficult conditions of use.