DE19608127B9 - Method for producing a fiber composite component - Google Patents

Abstract

A method for producing a three-dimensionally shaped motor vehicle floor made of fiber composite, consisting of one in the areas of increased stress locally reinforced base structure of superimposed long fiber layers, which are sewn together to form a semi-finished fiber and then consolidated in a press mold under pressure and heat to the finished fiber composite component, characterized in that the long fiber layers (4) are provided in the non-formed state with local reinforcing parts (6.5, 6.6) of non-fiber reinforced material and sewn together to form a planar, integral semifinished fiber product (2) and in that the semifinished fiber product (2) in the regions Deformation by local needling (10) is provided with a short fiber structure and that then the semifinished fiber product as a whole in the press forming tool (12) is formed into the three-dimensional component geometry.

Description

The invention relates to a Method for producing a three-dimensionally shaped motor vehicle floor made of fiber composite, according to the preamble of patent claim 1.

It is known to have more extensive supporting wall structures, about car floors or similar, three-dimensionally shaped vehicle parts, for reasons of weight Long fiber composite with local reinforcements in the areas of increased It must be during the transformation and consolidation be ensured that the fiber structure of strength-reducing Faserdesorientierungen kept and a intimate bonding of the fiber layers to each other and to the reinforcing parts guaranteed becomes. To ensure this, the long fiber layers are each individually or in thin layers successively formed on the mold and at predetermined locations of the resulting structure will be the local reinforcements accompanied before the fiber laminate is then consolidated under heat and pressure. Such a manufacturing method is with such a large production cost connected that she in practice only in limited Scope for high-quality components are used in relatively small numbers, for one inexpensive Mass production but is unsuitable.

The DE 41 39 523 A1 describes a method by which components made of fiber-reinforced plastics can be produced, which are highly integral, ie are designed with individual profile stiffeners. It is produced a preform whose shape already corresponds to that of the Hauteils. To produce such a three-dimensional preform, the reinforcing materials for stiffeners are sewn to the reinforcements for the flat skins prior to insertion into the molding. This three-dimensional preform is then to be introduced into the mold to produce the composite structure.

Such a preform already before processing with the mold in a true-to-scale, three-dimensional Taking shape is complicated and requires, for example, at layered storage or transport increased care, to avoid shifts in the structure of the preform. This proves to be extremely disadvantageous.

The object of the invention is that Manufacturing process of the type mentioned above, that the Manufacturing costs significantly reduced and thereby cost-effective mass production from spatially shaped, local reinforced long fiber composite components allows becomes.

This object is achieved by the Characteristics of method claim 1 solved.

According to the invention, the long fiber layers and the local ones reinforcements in front of the spatial Deformation in a first step by automated stitch connected together to form an integral planar fiber structure, which can be handled as semi-finished fiber. Subsequently, will the shape behavior of the semifinished fiber product improved by being in areas strong deformation by local Needling is provided with a short fiber structure and then in a further process step as a whole, similar to the simple as in the non-cutting cold forming of metal sheet metal parts, by machine in a press mold in the final spatial Hauteilgeometrie transformed and then consolidated. there becomes due to the mutual textile binding of the individual fiber layers and local reinforcement parts made sure that resulting semi-finished fiber products in the forming and consolidation of disturbing Fiber shifts or other disorientations in fiber layer construction is kept free. Due to the low production costs and the far-reaching automation is the method of the invention in an excellent way for a cost-effective Mass production of high quality, spatially shaped long-fiber composite components, such as floor groups in the automotive industry.

Optionally or additionally, like according to claim 2 preferred as local reinforcements metallic, by sewing provided on the long fibers stiffening or fasteners become.

Both thermoset and thermoplastic matrix systems can be used within the scope of the invention. According to an embodiment according to claim 3, the semifinished fiber can be sewn in the dry state and by wet impregnation prior to insertion into the compression mold ( 12 ) or matrix-soaked through heart injection within the mold.

When using a thermoplastic matrix system However, this is the semi-finished fiber according to claim 4 preferably before sewing mixed in the form of thermoplastic fiber components.

With regard to a load and fiber composite Embodiment, the semifinished fiber product further according to claim 5 expediently manufactured with different fiber types and orientations.

The invention will now be apparent from an embodiment in conjunction with the drawings described in more detail. Show it in a highly schematic representation:

1 a planar, integral semi-finished fiber product for producing a motor vehicle floor with local reinforcement gene and sections different fiber main orientations;

2 a section along the line II-II of 1 in the area of a doubling;

3 a section along the line III-III of 1 in the area of a metallic fastener lements;

4 a section along the line IV-IV of 1 in the area of a sandwich zone;

5 an impregnating device for the semi-finished fiber product and a downstream press-forming tool for forming and consolidating; and

6 the fiber composite flooring group in the finished state.

1 shows a semi-finished fiber 2 for a motor vehicle floor group, which consists of a plurality of just superimposed, textile fabric blanks 4 is constructed and has a multi-axial fiber orientation, with the individual, in 1 dash-dotted bordered areas of the semifinished fiber product 2 each have different fiber preferential directions. Thus, for the middle region of the semifinished fiber product 2 , which forms the bottom tunnel in the finished floor panel, mainly fabric layers with a longitudinal unidirectional fiber orientation 4A chosen, while the lateral edge regions, which give the Schwel ler, mainly of fabric layers with a crossing, to the longitudinal direction of the semifinished fiber product 2 at ± 45 ° inclined fiber orientation 4B and the intermediate portions of the semifinished fiber product 2 , So the pedal, seat and koffaumaumseitige bottom parts of the component to be produced, primarily from fabric layers with a unidirectional fiber direction in the transverse direction 4C are constructed.

For strength and weight reasons, the fabric layers 4 made of carbon fibers mixed with glass or aramid fiber in certain areas where locally increased elasticity or impact absorption is required. When using a thermoplastic matrix system, the tissues contain 4 furthermore, thermoplastic fiber components in a uniform distribution. If, on the other hand, a thermoset matrix system is used, as in the exemplary embodiment described below, then the semifinished fiber product is produced 2 from dry tissue layers 4 built up. Instead, if desired, it is also possible to use preimpregnated fabric blanks, so-called prepregs.

The semi-finished fiber product is completed 2 by local, load-specific designed reinforcing parts 6 at the points of increased mechanical stress on the floor group between or on the fabric layers of the semifinished fiber product 2 to be ordered. This is how the semi-finished fiber is made 2 z. B. in the region of the seat bottom part with ribs extending in the longitudinal direction fiber knit 6.1 to increase the local bending stiffness and at the koffaumseitige end with textile preforms 6.2 for the local application of force, and in the area of the pedal floor part the fabric layers are aramid stripes 6.3 attached to improve the impact absorption and toughness behavior, Furthermore, the center zone of the fiber layer structure 4 by a doubling 6.4 fiber layers having a quasi-isotropic, longitudinal and ± 45 ° fiber orientation 4D own, locally strengthened ( 2 ), and in the area of the seat bottom part are in fiber layer structure 4 metallic connection elements 6.5 embedded for future screw connections ( 3 ). As for the koffeaumseitigen section of the semifinished fiber product 2 and in detail in 4 can also be shown between the fabric layers 4 Foam inserts or spacer fabric 6.6 be inserted to give the finished floor assembly a local sandwich structure.

The textile structure thus constructed is then, as in 1 by the reference numeral 8th indicated, together with the local reinforcing parts 6 machining while maintaining the planar lamination to the integral semifinished fiber product 2 sewn, causing all reinforcing parts 6 and tissue blanks 4 be securely fixed to each other and in their fiber orientation, so that the semi-finished fiber 2 as a whole without the risk of disturbing fiber shifts or other misalignments easily transport, store and finally reshape into the final three-dimensional component geometry and consolidate. Individual reinforcement parts, such as the metallic fasteners 6.5 or the spacer fabrics 6.6 Of course, they are only stitched together at the edges.

In an intermediate step, the semi-finished fiber is 2 even at the points of stronger spatial shape change needled, so that the long fiber layers locally get a short fiber structure, as in 1 through the needling zones 10 is indicated.

The thermosetting matrix system becomes the semifinished fiber product 2 either by way of resin injection within the press mold 12 ( 5 ) or on an impregnating station upstream of this 14 added where the semi-finished fiber 2 on both sides with a press rolls over 16 pressed-on resin film 18 occupied and / or by means of a spray device 20 is impregnated with liquid resin before it as a whole in the press mold 12 is inserted and reshaped when closing it in the spatial component geometry and then consolidated under pressure and heat.

In 6 is the completed in this way motor vehicle floor assembly with exhaust tunnel 22 Swells 24 , Pedal floor 26 , Seat bottom 28 and trunk side end wall 30 including the local reinforcement parts 6 and the corresponding fiber preferred directions.

Claims (5)

A method for producing a three-dimensionally shaped motor vehicle floor made of fiber composite, consisting of a locally reinforced in the areas of increased stress basic structure of superimposed long fiber layers sewn together to form a semi-finished fiber product and then ßend be consolidated in a press mold under pressure and heat to the finished fiber composite component, characterized in that the long fiber layers ( 4 ) in the non-deformed state with local reinforcing parts ( 6.5 . 6.6 ) made of non-fiber-reinforced material and together with these to form a planar, integral semifinished fiber product ( 2 ) and that the semifinished fiber product ( 2 ) in the areas of severe deformation by local needling ( 10 ) is provided with a short fiber structure and that subsequently the semifinished fiber product as a whole in the compression molding tool ( 12 ) is converted into the three-dimensional component geometry. Process according to Claim 1, characterized in that metallic reinforcements, as by local stitching, are applied to the long fiber layers ( 4 ) fixed stiffening or fastening elements ( 6.5 ). Method according to claim 1 or 2, characterized in that the semi-finished fiber product ( 2 ) sewn in the dry state and by wet impregnation prior to insertion into the press mold ( 12 ) or matrix impregnated in the way of the resin injection inside the press-forming tool. Method according to claim 1 or 2, characterized in that the semi-finished fiber product ( 2 ) contains as a matrix thermoplastic fiber components. Method according to one of the preceding claims, characterized in that the semi-finished fiber product ( 2 ) is manufactured with different fiber types and orientations.