DE102004008061B3 - Mold for multi-component, especially two-component, injection molding has sliding and rotating arm mounted in one mold half, on which molding core and ejector for molding are mounted - Google Patents

Abstract

Mold for multi-component, especially two-component, injection molding has a sliding and rotating arm (2) mounted in one mold half (1). Molding cores (4) and an ejector (5) for the molding are mounted on the arm.

Description

The The invention relates to a tool for multi-component injection molding, in particular 2-component injection molding, of Plastic parts according to the preamble of claim 1.

Tools for multi-component injection molding of plastic parts are known in many variants.

at a tool of the type specified two tool halves are provided, which to open Diverge and then closed again are. When the tool is closed, the two tool halves define between the mold cavities, in which the hot Plastic is injected. To several in the same tool To be able to inject components a so-called turning part is provided. This turning part is in one tool half longitudinally slidably as well as - im extended state - rotatable stored. At this turning part mold cores are arranged, which the mold cavities define and around which the plastic is injected. These Form cores can in terms of their longitudinal extent in the parting plane between the two tool halves or - in other words - with respect to their longitudinal extension lie in the plane of rotation of the turning part. To the finished syringes To strip from the mold cores for demolding, are ejector devices intended. These are either on the fixed mold half or but arranged on the tool frame.

The DE 101 45 730 C1 shows a tool for multi-component injection molding, in particular for 2-component injection molding, of plastic injection molded parts, wherein the ejector device is arranged together with the tool insert movable within the mold half. The actuator for the ejector is fixedly arranged in the mold half. This results in long actuation paths.

From that Based on the object of the invention, a tool for multi-component injection molding, in particular 2-component injection molding, of plastic parts of initially specified type with an ejector device with short Because operation to accomplish.

The technical solution is characterized by the features of claim 1.

The Basic idea of the tool according to the invention for multi-component injection molding, in particular 2-component injection molding, of plastic parts is the ejector device firmly to arrange on the turning part. This has the advantage that the ejector device placed where the ejection of the Fertigspritzlinges done. This creates short actuation paths. In particular, the ejector device can be integrated in the turning part in this way be that this For example ejector functions with, for example, the Leadership of Ejector elements. Overall, this is a tool with a improved ejector device created.

Of the Advantage according to the development in claim 2 is that the Ejector device is actuated by the turning part. By the ejector device with respect to the associated mold core opposite Side of the turning part is arranged, this is a space saver created within the tool, since the ejector device inside the tool.

Preferably is according to the training in claim 3 each mold core of the turning part own ejector device assigned. This has the advantage that after spraying the finished plastic part ejected this directly through its associated ejector device can be.

A special arrangement and design of the mold cores suggests according to the development in claim 4, that the on the turning part arranged forming cores with respect to their longitudinal extent or longitudinal axis lie in the parting plane between the two tool halves or - with others In terms of their words longitudinal extension or longitudinal axis lie in the plane of rotation of the turning part. This means that the mold cores on the radial outer surface of the Turning parts are arranged. This also means that the associated ejector device in the parting plane between the two mold halves or in the plane of rotation of the Turning parts lies.

The basic idea of the further development in claim 5 is that the actual ejector device is assigned a separate actuating device. This means that the ejector device can only be actuated in its ejector function when the actuating device is in operative connection with the ejector device. This can be done by the fact that after completion of the lifting movement engages a coupling between the actuator and the ejector device and in this way then the ejector means can be converted by means of the actuator in its ejection position. The special Advantage in this separate actuator is that in the event that each mold core is assigned its own ejector, only a total of a single actuator must be provided, which is required, brought into operative connection with the desired ejector. This results in a constructive simplicity.

Preferably is in accordance with the training in claim 6, the actuating device on the tool half arranged in which the turning part is mounted.

The Training according to claim 7 has the advantage that during the Auswerfvorganges in turning part no torques occur, but that rather incurred torques are absorbed by the stop. For example it may be in the attack to a U-shaped rail, in which - for example with rollers - the turning part engages when it is in the ejector position. there it is conceivable that already while the entire lifting movement of the turning part from the basic position in the ejector position the rollers of the turning part in the fixed Traversed rails. Order for the implementation a rotational movement of the turning part out of engagement with the stop bring, preferably carried out a further lifting movement, so that then the Turning part is free.

As previously executed, beats a further development according to claim 8 before that after a subsequent one further stroke of the turning part of this again outside the range of action of the actuator gets into the rotational position.

Thereby Is it possible, To implement the pre-molded parts by turning the turning part, then the second component to inject.

The Training according to claim 9 beats a concrete technical realization of the ejector device before. The advantage is that the Ejector rods are guided in the turning part. This means, that the Ejector rods from behind through the mold core through the Fertigspritzling push away from this mold core.

The Training according to claim 10 finally beats a further technical realization of the ejection device before. Specifically, it is proposed how the guide rods longitudinally displaceable guided on turning part are.

One embodiment a tool for 2-component injection molding of plastic parts is described below with reference to the drawings. In these shows:

1 the closed tool in the basic position in three views, on the left a plan view of a mold half with the turning part, right above a longitudinal sectional view through the tool and right below a top view of the tool are shown;

2 to 7 corresponding representations, which show the tool sequence one after the other.

The tool for 2-component injection molding of plastic parts (in the present embodiment, the plastic part is a plastic housing of an electric tool) has two mold halves 1 . 1' on, which can be moved apart and closed.

In the one tool half 1 (in the drawing on the top right is this tool half 1 shown on the left) is a turning part 2 on an axis 3 longitudinally displaceable and rotatably mounted. This turning part 2 is formed substantially strip-shaped.

The turning part 2 has two cores 4 on. These are each in the plane of rotation of the turning part 2 , ie in the dividing line between the two mold halves 1 . 1' , Each is a mold core 4 on both sides of the pivot point of the axis 3 provided, wherein the two mold cores 4 with respect to the axis 3 point symmetric.

On the to every mold core 4 opposite side of the turning part 2 is at this an ejector device 5 arranged. This has four guide rods 6 on which a plate-shaped displacement element 7 is guided longitudinally displaceable. At this sliding element 7 are ejector bars 8th arranged. These protrude through the turning part 2 through in the respective mold core 4 ,

The ejector device 5 is still associated with an actuator 9 , This is on the tool half 1 arranged, in which also the turning part 2 is stored. This actuator 9 has a coupling 10 on, which with a corresponding counterpart of the ejector device 5 interacts, as will be explained below. The actuating device 9 has a pneumatically actuated cylinder / piston unit.

Finally, there is a stop 11 for the turning part 2 intended. This stop 11 is formed by two fixed rails with U-profile, in which outer rollers of the turning part 2 intervention.

The functionality of the tool is as follows:
The basic position of the closed tool is in 1 shown. It is in the left drawing of this 1 top left of the preform 12 and right below the Fertigspritzling 13 to recognize. This finished spray 13 should be ejected after spraying the second component.

For this purpose, the tool according to 2 first opened by the right tool half 1' is moved to the right.

In 3 is shown that subsequently the turning part 2 with its axis 3 performs a partial lift. There are two things: First, the turning part 2 with its two rollers during the lifting process in the U-shaped rail of the stop 11 guided and remains on reaching the end position of this Teilhubes continue in this position in the rail. On the other hand, the ejector device attacks 5 with its rear end in the clutch 10 the actuator 9 one. This is done in such a way that the displacement element 7 has an omega-shaped profile, which points to a mushroom-shaped head of the clutch 10 is postponed.

In this position, the system is in the ejector position. As in 4 is recognizable drives the actuator 9 before and thus moves the sliding element 7 on the guide rods 6 Forward. Because the ejector rods 8th on the sliding element 7 are fastened, they are equally moved forward and demould the finished part 13 from the mold core 4 ,

Then the ejector device moves 5 with its actuator 9 back to the starting position ( 5 ).

Then the turning part moves 2 according to 6 continue forward and carry out the rest of the stroke. The roles of the turning part occur 2 from the rails of the stop 11 out.

Finally, the turning part rotates 2 180 °, so that the injected in the meantime preform 12 enters the finished injection position, while the demolded mold core 4 in the position for spraying the pre-molded part 12 arrives ( 7 ).

Subsequently, the turning part 2 moved back and the tool closed again, so that the starting position in 1 is reached.

1

tool half

1'

tool half

2

turning part

3

axis

4

mold core

5

ejector

6

guide rod

7

displacement element

8th

ejector

9

actuator

10

clutch

11

attack

12

Preform

13

Finished molded part

Claims (10)

Tool for multi-component injection molding, in particular 2-component injection molding, of plastic parts with two openable and closable tool halves ( 1 . 1' ), which define mold cavities between them in the closed state, with one in the one mold half ( 1 ) longitudinally displaceable and rotatably mounted turning part ( 2 ), with at the turning part ( 2 ) arranged cores ( 4 ) and with an ejector device ( 5 ) for the finished syringes ( 13 ), characterized in that the ejector device ( 5 ) directly on the turning part ( 2 ) is arranged. Tool according to the preceding claim, characterized in that the ejector device ( 5 ) with respect to the core ( 4 ) other side of the turning part ( 2 ) is arranged. Tool according to one of the preceding claims, characterized in that each mold core ( 4 ) of the turning part ( 2 ) a separate ejector device ( 5 ) assigned. Tool according to one of the preceding claims, characterized in that the mold cores ( 4 ) with respect to their longitudinal extension in the parting plane between the two mold halves ( 1 . 1' ) as well as with respect to its longitudinal extent in the plane of rotation of the turning part ( 2 ) lie. Tool according to one of the preceding claims, characterized in that on one of the two tool halves ( 1 . 1' ) a separate actuator ( 9 ) for the ejector device ( 5 ) is fixed and that when the tool halves ( 1 . 1' ) after a stroke movement of the turning part ( 2 ) the ejections reindirection ( 5 ) of the turning part ( 2 ) into the effective range of the actuator ( 9 ). Tool according to claim 5, characterized in that the actuating device ( 9 ) on the mold half ( 1 ) is arranged, in which the turning part ( 2 ) is stored. Tool according to claim 5 or 6, characterized in that in the ejector position of the turning part ( 2 ) this turning part ( 2 ) in the effective direction of the ejector device ( 5 ) by a stop ( 11 ) is supported. Tool according to one of the preceding claims 5 to 7, characterized in that after a subsequent further stroke movement of the turning part ( 2 ) this turning part ( 2 ) again outside the operating range of the actuator ( 9 ) enters the rotational position. Tool according to one of the preceding claims, characterized in that the ejector device ( 5 ) at least one longitudinally displaceable ejector rod ( 8th ), which by the turning part ( 2 ) through into the region of the associated shaping core ( 4 protrudes. Tool according to claim 9, characterized in that on the turning part ( 2 ) at least one guide rod ( 6 ) of the ejector device ( 5 ) is arranged and that on the guide rod ( 6 ) a displacement element ( 7 ) is mounted longitudinally displaceable, on which the rear end of the ejector rods ( 8th ) is attached.