EP2552663A1

EP2552663A1 - Method for producing a continuous fiber-reinforced molded part using an injection molding tool

Info

Publication number: EP2552663A1
Application number: EP11711458A
Authority: EP
Inventors: Franz Kind; Peter Michel
Original assignee: Rehau AG and Co
Current assignee: Rehau Automotive SE and Co KG
Priority date: 2010-03-31
Filing date: 2011-03-23
Publication date: 2013-02-06
Also published as: WO2011120650A1; DE102010013541A1

Abstract

The invention relates to a method for producing a continuous fiber-reinforced molded part (1) using an injection molding tool (10), wherein the injection molding tool (10) comprises a first and a second tool part (18, 20) defining a cavity (22) for ultimately forming the molded part (1), wherein the first tool part (18) comprises a first injection channel (24) and the second tool part (20) comprises a second injection channel (26) provided for injecting free-flowing thermoplastic plastic material (28) into the cavity (22), wherein the second tool part (20) comprises an injection device (30) and a metering chamber (32) that can be filled with free-flowing thermoplastic plastic material (28), wherein the second injection channel (26) opens into the metering chamber (32), and wherein the injection device (30) is set up for injecting free-flowing thermoplastic plastic material (28) present in the metering chamber (32) into the cavity (22) via the second injection channel (26), and wherein the method comprises steps A through I.

Description

Process for the preparation of a continuous fiber reinforced molding under

Use of an injection mold

Background of the Invention The present invention relates to a method of making a continuous fiber reinforced molded article using an injection molding tool.

The document US Pat. No. 7,235,149 B2 describes a process for the production of motor vehicle moldings from continuous fiber-reinforced thermoplastics. Here, the band-shaped continuous fiber-reinforced preform pieces are placed on a flat surface at different angles to each other. The resulting flat scrim is then preheated and thermoformed. Depending on the wall thickness of the component, the consolidation takes place in a separate or in the same thermoforming tool. Alternatively, encapsulation methods are also known which carry out the consolidation by encapsulation of the preform, such that the preform is introduced into a cavity of an injection molding unit intended for the final molding of the molding and subsequently left in the mold after the preform has been introduced Fill space of the cavity thermoplastic material is injected. However, with the known extrusion-coating methods for consolidating the preform, it is possible to realize complex shaped-part geometries in only a low production quality, since, owing to the complex geometry, injection paths for the plastic material must be provided in known solutions, which can be quite long and far away can differ greatly in their length, so that, for example, due to cooling processes during injection, the thermoplastic material occurs depending on the injection path with different flow properties or temperatures in the filling or due to a long injection path also too cold can enter the filling space. Underlying task

The present invention has for its object to provide a method for producing a continuous fiber-reinforced molded part using an injection molding tool with which an endless fiber-reinforced molded part with complex geometry can be produced, which has a significantly higher manufacturing quality compared to a molded part produced by a known method ,

Inventive solution

This object is achieved with a method for producing a continuous fiber-reinforced molded part using an injection molding tool having the features of claim 1.

The method according to the invention comprises the following steps:

(A) provision of cut, substantially flat, unidirectional fiber-reinforced mats with a thermo-plastic matrix at least partially surrounding the fibers,

(B) transfer of the mats to a workpiece carrier which predetermines the rough contour of the molded part, (C) depositing and continuously building the mats on the workpiece carrier into a three-dimensional preform such that the fiber orientation of the mats is based on the forces acting in the subsequent use of the molded article, and matching the load paths resulting therefrom within the molding, (D) fixing the mats together during or after completion of the preform construction,

(E) heating the preform to or above the melting temperature of the thermoplastic matrix of the preform, (F) introducing the preform into the cavity of the injection molding tool,

(G) introducing flowable thermoplastic material from outside the injection mold into the dosing space, and

(H) final molding of the molded article by injecting flowable thermoplastic material from outside the injection mold into the cavity remaining after introduction of the preform and additionally injecting the thermoplastic flowable plastic material in the dispensing space into the filling space, the plastic material from outside of the injection molding tool is injected via the first injection channel, and wherein for injecting the plastic material of the metering chamber, the injection device is activated.

According to the present invention, after performing steps A to E in step G, flowable thermoplastic material is introduced from outside the injection molding tool into the metering space. In step H, the final forming of the molded article from the preform then takes place by injecting flowable thermoplastic synthetic material from outside the injection molding tool into the cavity filling space remaining after introduction of the preform and by additionally injecting the thermoplastic flowable plastic material into the filling space , In this case, the plastic material is injected from outside the injection molding tool via the first injection channel and for injecting the additional plastic material of the dosing chamber, the injection device is activated, which injects the flowable thermoplastic material located in the dosing chamber via the second injection channel into the cavity. In step I, the molding is removed from the cavity. The second tool part is provided with an injection system comprising the metering space and the injection device. By using a second tool part with this injection system, which may preferably be in the form of a so-called "shot-pot" device, it is possible to significantly shorten the injection paths required in known solutions Injection device via the second injection channel of the second tool part in the filling cavitated in the cavity. On provided in known solutions long injection paths which extend from the first to the second tool part and which are provided for supplying the example of an injection unit in the first tool part introduced plastic material to areas of the filling space, which are located in the second tool part, can thus be dispensed with. By means of the injection system of the second tool part, the length of the longest injection paths or injection channels can be significantly reduced compared to known solutions. In particular, the length differences between the respective injection paths can thus be significantly reduced, so that thermoplastic material injected via different injection paths can enter the filling space with essentially the same flow properties or the same temperature.

By providing the injection system of the second tool part, in particular an external spraying system comprising a plasticizing unit for producing the flowable thermoplastic material and an injection unit for feeding the plastic material can be effectively reduced in terms of its maximum power dimensioning or performance data, so that by means of the inventive method also a reduction in production costs is made possible. Overall, an endless fiber-reinforced molded part with complex geometry and high production quality can be produced with the method according to the invention.

Preferably, the first tool part is fixed and the second tool part is movable for introducing the preform into the cavity relative to the first tool part. Thus, the preform can be introduced in a practical manner by appropriate movement of the second tool part in the cavity of the injection molding tool or removed therefrom. In particular, in the context of an automated production method, a large number of preforms for producing a corresponding multiplicity of molded parts can thus be introduced into or removed from the cavity in a practical manner.

Preferably, in step H to achieve the highest possible manufacturing quality of the molded part, the injection of the plastic material from outside the injection mold is carried out substantially simultaneously with the injection of the located in the metering Kunststoffstoffmaterials. Particularly preferably, step G is carried out during cooling of the preform after the heating carried out in step E. In this way, the time to be reserved for cooling the preform can advantageously be used to carry out step G without having to specifically provide process time or process time.

In a practical embodiment of the method according to the invention, the injection molding tool has at least one feed line which fluidly connects the first injection channel with the metering, wherein in step G flowable thermoplastic plastic material from outside the injection mold by injecting the plastic material into the first injection channel and by redirecting the injected plastic material is introduced into the feed line into the metering space, and wherein the feed line is closed before, according to step H, the flowable thermoplastic material is injected into the filling space.

By means of the feed line, the thermoplastic material can be introduced in a practical manner via the first injection channel into the metering chamber, so that only a single injection unit to be provided in the vicinity of the injection tool for supplying the plastic material is to be provided.

In a preferred embodiment of the method according to the invention, the second tool part at least two injection devices, at least two metering chambers, each associated with one of the injection devices, and at least two second injection channels, each one of the second injection channels opens into a respective metering and each set up the injection devices is to inject thermoplastic material from the associated dosing into the cavity, and wherein in step G in each of the dosing introduced flowable thermoplastic material and in step H, the flowable thermoplastic material located in each dosing is injected into the filling space.

By providing the plurality of at least two injection devices and the plurality of at least two metering chambers according to this practical embodiment, which form a corresponding plurality of injection systems, very short injection paths can be realized, so that also moldings with very complex geometry can be produced with high production quality. In a further practical embodiment, the first tool part has a plurality of first injection channels, and in the vicinity of the injection molding tool at least two injection units are provided which are adapted to inject the flowable thermoplastic material from outside into at least one of the first injection channels. Also, by means of this practical embodiment, very short injection paths can be realized due to the provision of at least two injection units, so that moldings with very complex geometry can be produced with high production quality.

Brief description of the drawings

Hereinafter, embodiments of the invention with reference to the accompanying drawings closer. It shows:

Fig. 1 shows schematically a plant for carrying out the method according to the invention, and

Fig. 2, 3 are each a schematic representation of an embodiment of a

Injection molding tool according to the inventive method.

1 schematically shows a plant for carrying out the process according to the invention for producing a continuous fiber-reinforced molded part 1. Cut-to-size, substantially flat, unidirectional fiber-reinforced mats 2 are provided with a thermoplastic matrix at least partially surrounding the fibers ,

In this embodiment, the mats 2 are taken from the magazine 3 from a magazine and provided at a predetermined position. Alternatively, the provision of the mats 2 via a rolling and / or cutting unit done (not shown here). The mats 2 are at least partially preheated before depositing on a workpiece carrier 5 with the aim of increasing the flexibility of the mats 2. This is followed by a transfer of the mats 2 to a workpiece carrier 5 which predetermines the rough contour 4 of the molded part 1. The workpiece carrier 5 itself is moved on a conveyor track 13. On the workpiece carrier 5, the cut mats 2 are deposited and continuously constructed into a three-dimensional preform 6 in such a way that the fiber orientation of the mats 2 affects the forces acting in the subsequent use of the molded part 1, and the load paths resulting therefrom within the molded part 1, is agreed. The transfer, storage and erection of the preform 6 take over a plurality of robot stations or robot systems 14, which are arranged along the conveyor line 13. After completion of the construction of the preform 6, the mats 2 are fixed in position relative to one another. In this case, the position fixation by means of a laser welding system 7, wherein a laser optics (not shown in detail) is arranged at a further robot station 17. Alternatively, even during the construction of the preform 6, a positional fixation of the mats 2 to each other can take place by means of textile technology.

The preform 6 is subsequently heated in an infrared continuous furnace 8 above the melting temperature of the thermoplastic matrix of the preform 6. Alternatively, the heating can also take place within a convection continuous furnace or in the injection molding tool 10 itself. By means of a further robot station 9, the introduction of the three-dimensional preform 6 into the cavity of an injection mold 10 for final molding of the molded part takes place, wherein the flowable thermoplastic material, which is to be injected into the remaining filling space of the cavity, from an injection unit 15 is supplied. The finished molded part 1 is also removed by means of the robot station 9 from the injection molding tool 10 and fed to a storage unit 16.

2 and 3 each show a schematic representation of an embodiment of an injection molding tool 10 according to the inventive method.

The injection molding tool 10 has a first fixed tool part 18 and a second tool part 20, which form a cavity 22 for the final molding of the molded part 1, in which a very schematically illustrated preform 6 is introduced.

The first tool part 18 has a first injection channel 24 and the second tool part 20 has a second injection channel 26, which are provided for injecting flowable thermoplastic material 28 into the cavity 22. From the first and the second injection channel 24, 26 extend perpendicularly each two branch channels, each opening into the cavity 22. The second tool part 20 is movable for introducing the preform 6 into the cavity 22 relative to the first tool part 18 (not illustrated here) and has an injection device 30 in the form of a longitudinally movable plunger and a metering chamber 32 which can be filled with flowable thermoplastic material 28, wherein the second injection channel 26 opens into the metering chamber 32.

The injection molding tool 10 also has a feed line 34, which connects the first injection channel 24 in a fluid-conducting manner with the metering chamber 32. The feed line 34 has two line valves 36 which, in the open state, make it possible for flowable thermoplastic material material 28 to flow into the metering space 32, which is supplied from the injection unit 24 provided in the surroundings of the injection molding tool 10 via the first injection channel 24. In order to enable diversion of the plastic material 28 fed into the feed line 34 via the first injection channel 24, the first injection channel 24 has a channel valve 40 which, in the closed state, allows diversion into the feed line 34 if the two line valves 36 are open ,

Also, the second injection channel 26 has a channel valve 40, which avoids leakage of the thermoplastic material 28 during its introduction into the metering chamber 32 in the closed state and which for injecting the introduced into the metering chamber 32 plastic material 28 in the after insertion of the preform 6 remaining Filling space 42 is opened. 2 illustrates a situation according to step G of the method according to the invention, in which the flowable thermoplastic material 28 is introduced into the metering chamber 32, for which purpose the two line valves 36 are opened beforehand and the two channel valves 40 are closed beforehand. 3 illustrates a situation according to step H of the method according to the invention, in which the final molding of the molded part 1 flowable thermoplastic material 28 from the injection unit 38 into the filling space 42 of the cavity 22 and additionally in the dosing 32 located thermoplastic flowable Kunststoffmate- material 28 is injected into the filling space 42 by activating the injection device 30, wherein the feed line 34 is closed by closing the line valves 36 before the flowable thermoplastic material 28 is injected into the filling space 42.

LIST OF REFERENCE NUMBERS

1 molding

2 mat

3 conveyor unit

4 rough contour

5 workpiece carrier

6 preform

7 laser welding machine

8 infrared continuous furnace

9 robot station

10 injection mold

13 conveyor line

14 robot system

15 injection unit

16 storage unit

18 first tool part

20 second tool part

22 cavity

24 first injection channel

26 second injection channel

28 thermoplastic plastic material

30 injection device

32 dosing space

34 feed line

36 line valve

38 injection unit

40 channel valve

42 filling space

Claims

claims

Method for producing a continuous fiber-reinforced molded part (1) using an injection molding tool (10), wherein the injection molding tool (10) has at least one first and at least one second tool part (18, 20) which has a cavity (22) for final molding of the molded part (22). 1), wherein the first tool part (18) has at least one first injection channel (24) and the second tool part (20) has at least one second injection channel (26) for injecting flowable thermoplastic material (28) into the cavity (22). wherein the second tool part (20) has at least one injection device (30) and at least one dosing chamber (32) which can be filled with flowable thermoplastic material (28), the second injection channel (26) opening into the dosing chamber (32), and the injection device (30) is arranged in the

Injecting space (32) located flowable thermoplastic material (28) via the second injection channel (26) into the cavity (22), the method comprising the following steps:

(A) provision of cut, substantially flat, unidirectional fiber-reinforced mats (2) with a thermoplastic matrix at least partially surrounding the fibers,

(B) transfer of the mats (2) to a workpiece carrier (5) which predetermines the rough contour (4) of the molded part (1),

(C) depositing and continuously building the mats (2) on the workpiece carrier (5) to a three-dimensional preform (6) such that the fiber orientation of the mats (2) on the subsequent use of the molding (1) forces and the from within the molding (1) resulting load paths, is tuned, (D) fixing the mats (2) to one another during or after completion of the construction of the preform (6),

(E) heating the preform (6) up to or above the melting temperature of the thermoplastic matrix of the preform (6),

(F) introducing the preform (6) into the cavity (22) of the injection molding tool (10),

(G) introducing flowable thermoplastic material (28) from outside the injection molding tool (10) into the metering chamber (32),

(H) Final molding of the molding (1) by injection of flowable thermoplastic material (28) from outside the injection mold (10) in the after filling of the preform (6) remaining filling space (42) of Kavi ity (22) and by additional injection the thermoplastic flowable plastic material (28) located in the metering chamber (32) into the filling space (42), wherein the plastic material (28) is injected from outside the injection molding tool (10) via the first injection channel (24), and wherein for injecting the plastic material (28) of the metering chamber (32), the injection device (30) is activated, and

(I) removing the molding (1) from the cavity (22).

A method according to claim 1, characterized in that the first tool part (18) is fixed, and that the second tool part (20) for introducing the preform (6) into the cavity (22) is movable relative to the first tool part (18).

A method according to claim 1 or 2, characterized in that in step (H) the injection of the plastic material (28) from outside the injection molding tool (10) substantially simultaneously with the injection of the in the dosing (32) located plastic material (28) is made ,

4. The method according to any one of the preceding claims, characterized in that step (G) is carried out during cooling of the preform (6) after the heating carried out in step (E).

Method according to one of the preceding claims, characterized in that the injection molding tool (10) has at least one feed line (34) which fluidly connects the first injection channel (24) with the metering chamber (32), wherein in step (G) flowable thermoplastic material ( 28) from outside the injection molding tool (10) by injecting the plastic material (28) into the first injection channel (24) and by diverting the injected plastic material (28) into the feed line (34) into the metering chamber (32), and wherein the Feed line (34) is closed before according to step (H), the flowable thermoplastic material is injected into the filling space (42).

Method according to one of the preceding claims, characterized in that the second tool part (20) at least two injection devices (30), at least two metering chambers (32) which are each associated with one of the injection devices (30), and at least two second injection channels (26) in each case one of the second injection channels (26) opens into a respective metering chamber (2) and each of the injection devices (30) is adapted to inject thermoplastic material (28) from the associated metering chamber (32) into the cavity (22), and wherein in step (G) flowable thermoplastic material (28) is introduced into each of the metering spaces (32) and in step (H) the flowable thermoplastic material (28) in each metering space (32) is injected into the filling space (42) ,

Method according to one of the preceding claims, characterized in that the first tool part (18) has a plurality of first injection channels (24), and that in the vicinity of the injection molding tool (10) at least two injection units (38) are provided, which are arranged, the flowable thermoplastic Plastic material (28) from outside into at least one of the first injection channels (24) inject.