METHOD AND TOOL SYSTEM FOR MANUFACTURING A MULTI-COMPONENT PLASTIC MOLDED PART

Abstract

A method is provided for manufacturing a multi-component plastic molded part and a tool system. The method comprises a first injection molding step for molding at least one preform, and a second injection molding step for molding at least one second component onto the preform. The first and second injection molding steps are performed with an injection molding machine comprising a first outer half-mold and at least one second outer half-mold positioned on opposite sides of a rotatable carrier-block. The carrier-block has at least four side faces each comprising an inner half-mold. The preform in the first injection molding step the second component in the second injection molding step are simultaneously injection molded. The injection molding machine is opened by moving the first and second outer half-mold spaced apart from the rotatable carrier-block. The preform is carried out of the first injection molding step, the plastic molded part is carried out of the second injection molding step by rotating the carrier-block. The preform is cooled while carried by the inner-half mold on the carrier-block by means of a cooling medium. The plastic molded part is removed from the inner-half mold on the carrier-block by means of a handling means.

Claims

1. A method for manufacturing a multi-component plastic molded part via an injection molding machine that includes a first outer half-mold and at least one second outer half-mold positioned on opposite sides of a rotatable carrier-block, the carrier-block having at least four side faces each comprising an inner half-mold, the method comprising: injection molding at least one preform via the injection molding machine; injection molding at least one second component onto the preform via the injection molding machine simultaneously with the injection molding of the at least one preform, opening the injection molding machine by moving the first and second outer half-mold spaced apart from the rotatable carrier-block; carrying the preform and carrying the plastic molded part by rotating the carrier-block, cooling the preform while the preform is carried by the inner-half mold on the carrier-block by means of a cooling medium; and removing the plastic molded part from the inner-half mold on the carrier-block by means of a handling means.

2. The method according to claim 1, wherein the cooling of the pre-form while being held by the inner-half mold on the carrier-block is performed simultaneously with the injection molding steps.

3. The method according to claim 1, wherein the removing of the plastic molded part from the inner-half mold of the carrier-block is performed simultaneously with the injection molding steps.

4. The method according to claim 1, wherein the first outer half-mold, the second outer half-mold and the inner half-molds for performing the injection molding steps are heated up while at least one of the cooling and removing steps are performed.

5. The method according to claim 1, wherein the first outer half-mold, the second outer half-mold and the inner half-molds are cooled down after performing the injection molding steps while at least one of the cooling and removing steps are performed.

6. A tool system configured to perform the method for manufacturing a multi-component plastic molded part according to claim 1, the tool system comprising: an injection molding machine including: a first outer half-mold; a second outer half-mold; a rotatable carrier block with at least four side faces each comprising at least one inner half-mold.

7. The tool system according to claim 6, further comprising: a streaming means for creating the cooling medium by means of a stream or an air stream onto the preform, and a handling arm for removing the plastic molded part from the inner half-mold.

8. The tool system according to claim 6, wherein the first outer half-mold, the second outer half-mold and the inner half-molds feature a structure for molding a plurality of multi-component plastic molded parts in only one simultaneous first injection molding step and second injection molding step.

9. The tool system according to claim 6, wherein the inner-half molds for molding and holding the preform and holding the plastic molded-part are identical and the first and the second outer half-molds comprise a different design to one another.

10. The tool system according to claim 6, wherein the second outer half-mold comprises a micro-structured mold design.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] Reference is now made more particularly to the drawings, which illustrate the best presently known mode of carrying out the invention and wherein similar reference characters indicate the same parts throughout the views.

[0024] FIG. 1 is a perspective view of a tool system with an injection molding machine.

[0025] FIG. 2 illustrates the tool system with the injection molding machine in a top view.

[0026] FIG. 3 illustrates a preform in a schematic sectional side view.

DETAILED DESCRIPTION OF THE DRAWINGS

[0027] The present invention is not limited by the embodiment described above, which is represented as an example only and can be modified in various ways within the scope of protection defined by the appending patent claims. Thus, the invention is also applicable to different embodiments, in particular of the method for manufacturing a multi-component plastic molded part and a tool system with an injection molding machine.

[0028] Depicted in FIGS. 1 and 2 is the tool system 100 with the injection molding machine comprising a first outer half-mold 12 and a second outer half-mold 22 and a rotational carrier-block 40. The carrier-block 40 is rotatable around a rotational axis 43, comprises four side faces 41 each holding an inner half-mold 42. The injection molding machine is in an open position, wherein the first outer half-mold 12 and the second outer half-mold 22 were moved into a spaced apart direction 45. The carrier-block 40 is positioned centrally between the first and second outer half-mold 12 and 22.

[0029] FIG. 2 in particular shows the tool system in operation, wherein after a first and second injection molding step 10 and 20 the injection molding machine was opened and a newly molded preform 11 was transported by clockwise rotation 44 of the carrier block 40 to a cooling step 30 and a newly produced plastic molded part 200 was simultaneously transported to a handling step 50. The second outer half mold 22 comprises a micro structure 25 which is molded onto the preform together with a second component 21 forming the plastic molded part 200. In the cooling step 30 a streaming means 31 directs an air stream onto the preform 11 for cooling. The handling means reaches out to the newly produced plastic molded part 200 for removing the plastic molded part 200 from the inner half-mold 42 on the carrier block 40. The amount of material being injected into a cavity build of the inner half-mold 42 and the first outer half-mold 12 during the first injection molding step 10 is higher than the amount of material injected into second injection molding step 20. Therefore, cooling of the preform 11 is of particular importance to ensure a timely cooling of the preform 11 and thus enable a quick following second injection molding step 20.

[0030] Simultaneous to the above described operational steps 10, 20, 30, 50 the first and second outer half-mold 12 and 22 and the two inner half-molds 42 facing the first and second outer half molds 12 and 22 are being heated in preparation for the following first and second injection molding steps 10 and 20. Also simultaneously the inner half-mold 42 facing the handling means 51 and the streaming means 31 are being cooled to facilitate the cooling of the preform 11 and the cooling of the plastic molded part 200 respectively. The handling means 51 and the stream means 31 comprise a temperature sensor to measure the temperature of the preform 11 and the plastic molded part 200 and determine if removing and continuing to the second-injection molding step 20 is possible. Furthermore, the handling means 51 and the stream means 31 comprise a camera unit and analysis unit for detection of defects on the preform 11 and plastic molded part 200 to initiate corrective actions in the production process if needed.

[0031] FIG. 3 depicts the plastic molded part 200 comprising the preform 11 and with the second component 21 carrying the micro structure 25 molded onto the preform 11 in the second injection molding step 20, whereas the micro structure 25 also can form light-relevant structures.

LIST OF NUMERALS

[0032] 100 tool system [0033] 200 plastic molded part [0034] 10 first injection molding step [0035] 11 preform [0036] 12 first outer half-mold [0037] 20 second injection molding step [0038] 21 second component [0039] 22 second outer half-mold [0040] 25 microstructure [0041] 30 cooling step [0042] 31 streaming means [0043] 32 cooling medium [0044] 40 carrier block [0045] 41 side face [0046] 42 inner half-mold [0047] 43 rotational axis [0048] 44 clockwise rotation [0049] 45 spaced apart direction [0050] 50 handling step [0051] 51 handling means