DE102013016027B4 - Device for producing a fiber-reinforced plastic component - Google Patents

Abstract

Device for the production of a fiber-reinforced plastic component by hot forming a board-like semi-finished fiber product (13) in which reinforcing fibers are embedded in a thermoplastic matrix material, with a contact heater (1) which can be brought into direct thermally conductive contact with the semi-finished fiber product (13) for heating, whereby on The contact heater (1) has a demolding layer (21) which forms the heating surface and prevents the semifinished fiber product (13) from sticking to the contact heater (1), characterized in that the electrical heating conductors (23) are used to form the contact heater (1) ) are integrated directly into the mold release layer (21).

Description

The invention relates to a device for producing a fiber-reinforced plastic component according to the preamble of patent claim 1.

For the production of a fiber-reinforced plastic component, a fiber-reinforced thermoplastic is used as a semi-finished fiber in common practice, in which the reinforcing fibers are incompletely pre-impregnated with a matrix material in an impregnation system. The pre-impregnated thermoplastic is conveyed to a heating system for further processing, in which the matrix material is heated up to a melting temperature. In this state, the fiber-reinforced thermoplastic is subjected to hot forming, in which the plastic component is molded.

A generic device for producing such a fiber-reinforced plastic component has a contact heater which can be brought into direct, heat-conducting contact with the semi-finished fiber for heating. In the prior art, contact heating usually has a metallic heating surface, which is heated either by an electrical resistor or by a hot fluid (such as oil). The heat conduction is improved by lightly pressing the semi-finished fiber product onto the heating surface.

Such metallic heating surfaces have a large heat capacity. However, residues of the melted thermoplastic polymer of the semi-finished fiber can deposit on the metallic heating surface, which can result in fiber abrasion. For this reason, contact heating has so far not been used in the large-scale production of plastic components.

From the DE 10 2011 117 338 A1 a method for producing a plastic molded part from a formed organic sheet is known. The organic sheet is heated in an oven. To prevent polymer residues of the organic sheet from sticking in the oven, the organic sheet to be heated is placed in the oven with the interposition of a non-stick film. From the DE 10 2011 078 430 A1 a molding tool for the production of fiber composite components is known. The molding tool has an anti-adhesive layer forming the mold surface.

The DE 29 701 263 U1 discloses a device for processing trim parts for the automotive industry from nonwoven mats with thermoplastic binders, with at least one heating station, a cooling station, a transport system for the parts to be processed and respective press systems in the heating stations or in the cooling station with pressure means.

The DE 196 32 037 A1 discloses a heating device in a thermoforming system for heating a packaging material web, with a contact surface facing the packaging material web, characterized in that a cavity is formed on the side of the contact surface facing away from the packaging material web, in which at least one electrical heating element for heating or evaporating water or a Water / steam mixture is arranged detachably.

The DE 10 2011 008 759 A1 discloses a process for the production of moldings from fiber-reinforced plastics, wherein a matrix material used is heated by means of one or more heated molds of the injection mold.

The DE 602 01 862 T1 discloses a thermoforming tool having modules for forming a strip (B) from thermoformable plastics, heating resistors or heating resistor wires being integrated in the modules.

The object of the invention is to provide a device for producing a fiber-reinforced plastic component, which has a contact heater suitable for large-scale production.

The object is solved by the features of claim 1. Preferred developments of the invention are disclosed in the subclaims.

The invention is based on the fact that in conventional contact heaters, especially with heating elements arranged on both sides of the semi-finished fiber, polymer residues are deposited on the heating surfaces during heating. Against this background, a demolding layer forming the heating surface is applied to the contact heater, with which the semi-finished fiber product is prevented from adhering to the contact heater. In this way, the heat can be transported into the semi-finished fiber preferably by heat conduction, and the problem of adhesion described above can be completely eliminated. The demolding layer preferably has a greater surface tension than the matrix material of the semi-finished fiber product. Preferred materials for the demolding layer are in particular electrochemical nickel, ceramics, a carbon particle emulsion or a nano lacquer. In contrast to the prior art, a metallic heating surface is no longer provided, but rather the heating surface is formed by the demolding layer.

For accelerated heating of the semi-finished fiber, the contact heater can have two heating elements arranged on both sides of the semi-finished fiber exhibit. With the heating elements arranged on both sides, the intermediate semi-finished fiber product can be heated under pressure. By exerting pressure on the semi-finished fiber, the heat transfer is significantly improved by reducing the contact resistance.

In a technical embodiment, the two heating elements of the contact heater above can be components of a press with two interacting pressing tools. The two heating elements can each be arranged as detachably mounted insert parts on the opposite tool surfaces of the two pressing tools. In this way, a conventional press can be easily retrofitted with the heating elements.

The contact heater is electrically operated as a resistance heater. To form the contact heating, the electrical heating conductors are integrated directly in the demolding layer.

Examples of suitable electrical heating conductors are carbon fibers or metal wires (for example made of nickel) arranged in a grid-like manner, which can be integrated in a grid structure in the ceramic heating plate mentioned above or directly in the demolding layer for uniform heat distribution.

Such ceramic heating plates can preferably be made of non-oxide ceramic (SiC, SiN ₄ ) or oxide ceramic (Al ₂ O ₃ , ZrO ₂ , BeO), for example made of aluminum oxide or silicon nitride, and have different designs. The ceramic heating plates can have a material thickness in the range of 5 mm. When using a ceramic heating plate, the ceramic material and the comparatively low mass result in very fast heating rates, a homogeneous temperature distribution and very good control accuracy. In addition, due to the low thermal expansion, the ceramic surface remains flat even in temperature change operation - in comparison to metals. The high strength of ceramics also allows pressure loads with very little wear.

The advantageous embodiments and / or further developments of the invention explained above and / or reproduced in the subclaims can - apart from, for example, in the case of clear dependencies or incompatible alternatives - be used individually or in any combination with one another.

The invention and its advantageous training and further developments and their advantages are explained in more detail below with reference to drawings.

• 1 in grob schematischer Darstellung eine Vorrichtung zur Herstellung eines faserverstärkten Kunststoffbauteils;
• 2 ein an einem Presswerkzeug montiertes Heizelement der Kontaktheizung gemäß einem ersten Ausführungsbeispiel entsprechend dem Stand der Technik; und .
• 3 eine Kontaktheizung gemäß einem zweiten erfindungsgemäßen Ausführungsbeispiel.

Show it:

• 1 in a roughly schematic representation a device for producing a fiber-reinforced plastic component;
• 2nd a heating element of the contact heater mounted on a pressing tool according to a first exemplary embodiment in accordance with the prior art; and .
• 3rd a contact heater according to a second embodiment of the invention.

In the 1 the device for producing a fiber-reinforced plastic component is shown in a schematic diagram. The device has contact heating 1 as well as a metal forming press downstream in the production direction F. 3rd on. The contact heater 1 is through two heating elements 5 built up, each part of a heating press 7 are. The heating elements 5 are on opposite tool surfaces 9 of the two interacting pressing tools 11 the press 7 positioned. In the 1 is an example of the upper press tool 11 stroke adjustable in the vertical direction in order to heat the semi-finished fiber product during a heating process 13 to pressurize.

In addition, the device has the forming press already mentioned 3rd on, which also consists of two opposing molds 15 is constructed. In the molding press 7 hot forming takes place, in which the preheated semi-finished fiber product 13 is pressurized to form the fiber-reinforced plastic component.

With hot forming, the first step in the 1 board-like semi-finished fiber 13 in the production direction F in the heating press 7 guided. Then the semi-finished fiber 13 pressurized and by means of the heating elements 5 heated up to the melting temperature of the thermoplastic matrix material, whereby the reinforcing fibers are completely wetted with the matrix material and the semi-finished fiber 13 consolidated.

This is the semi-finished fiber 13 a fiber-reinforced pre-impregnated thermoplastic, in which the reinforcing fibers have not yet been completely wetted with the matrix material in an impregnation system.

In the 1 are in dashed lines above and below the semi-finished fiber 13 other semi-finished fiber products 13 indicated. These can be used to form a one-piece fiber composite in the heating press 7 be introduced and consolidated into the one-piece fiber composite.

Then the preheated, consolidated semi-finished fiber 13 to the forming press 3rd performed and the forming process takes place.

In the 2nd is according to the prior art in an enlarged detail view of the lower pressing tool 11 the heating press 7 shown. The upper press tool, not shown 11 is identical in construction. According to the 2nd is on the tool surface 9 the heating element 5 detachable at attachment points 17th assembled. The heating element 5 is in the 2nd designed as a two-layer insert, with a lower ceramic heating plate 19th and an upper mold release layer 21 . The demolding layer 21 forms the heating surface of the heating element according to the invention 5 . The demolding layer is preferably formed from a galvano-chemical nickel, from a ceramic material or from a carbon particle emulsion. Alternatively, the mold release layer 21 a nano lacquer or a nano coating.

In the ceramic heating plate 19th are the electrical heating conductors 23 (in the 2nd and 3rd only roughly indicated schematically) integrated. The electrical contact heater can be designed, for example, as a resistance heater or as an induction heater. That in the 2nd The two-layer heating element shown can therefore be easily retrofitted in a conventional press.

In the 3rd the contact heater is shown according to a second embodiment. Accordingly, the demolding layer 21 directly on the metallic tool surface 9 of the pressing tool 7 applied. In the mold release layer 21 are the electrical heating conductors 23 immediately integrated. The electrical heating conductors 23 can be, for example, carbon fibers or metal wires.

Claims (8)

Device for producing a fiber-reinforced plastic component by hot-working a platelike fiber semifinished product (13), in which reinforcing fibers are embedded in a thermoplastic matrix material, with a contact heater (1), which can be brought into direct heat-conducting contact with the semifinished fiber product (13) for heating, whereby the contact heater (1) is applied with a demolding layer (21) forming the heating surface, by means of which the semi-finished fiber product (13) is prevented from adhering to the contact heater (1), characterized in that, to form the contact heater (1), the electrical heating conductors (23 ) are integrated directly in the demolding layer (21). Device after Claim 1 , characterized in that the demolding layer (21) has a greater surface tension than the matrix material of the semi-finished fiber product (13). Device after Claim 1 or 2nd , characterized in that the contact heater (1) has two heating elements (5) which are arranged on both sides of the semi-finished fiber (13), in particular of identical construction, with which the intermediate semi-finished fiber (13) can be heated under pressure. Device after Claim 3 , characterized in that the heating elements (5) are components of a press (7) with two interacting pressing tools (11), and that the heating elements (5), in particular as detachably mounted insert parts, each on opposite, facing tool surfaces (9) of the Press tools (11) are arranged. Device according to one of the preceding claims, characterized in that the contact heater (1) can be operated electrically, in particular as a resistance heater or as an induction heater. Device according to one of the preceding claims, characterized in that the demolding layer (21) is constructed from galvano-chemical nickel, from ceramic, from a carbon particle emulsion or from a nano lacquer. Device according to one of the preceding claims, characterized in that the electrical heating conductors (23) are carbon fibers or metal wires. Device according to one of the preceding claims, characterized in that the contact heating (1) in the production direction (F) is followed by a forming press (3) in which the semi-finished fiber product (13) is hot-formed.

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