WO2011069792A1

WO2011069792A1 - Method and device for producing optical components

Info

Publication number: WO2011069792A1
Application number: PCT/EP2010/067721
Authority: WO
Inventors: Philipp Helbig; Peter Helbig
Original assignee: Osram Gesellschaft mit beschränkter Haftung
Priority date: 2009-12-09
Filing date: 2010-11-18
Publication date: 2011-06-16
Also published as: DE102009047735A1

Abstract

The invention relates to a method and device for producing optical components, wherein a preform is produced in an injection mold and then finish-embossed in an embossing tool.

Description

description

Method and device for producing optical components

Technical area

The invention relates to a method for producing optical components according to the preamble of patent claim 1 and a device for carrying out this method.

State of the art

For some time, optical components, which are subject to high quality requirements, made of plastic for cost and weight reasons by injection molding. The documents DE 10 2006 056 150 AI, DE 10 2006 048 230 AI and DE 11 2006 001 683 T5 describes, for example, components to which high op ^¬ tables requirements or high demands are made on the dimensional stability, such as optical fiber, Optikelement- Produce arrays, light-emitting diode housing or the like by injection molding. This method is also used for the production of lenses, cat's eyes, etc.

During compression molding the thermoplastic or du- roplastische molding material is introduced into the cavity of an injection ^¬ tool which is not completely closed to ^¬ next in a variant of the procedural ^¬ proceedings during the solidification or curing process, wherein the closing ^¬ pressure for final formation of the molding is uniform, so that on the one hand relatively large workpieces with low closing force or Make workpieces with very fine structures with high accuracy. In another variant of the injection-compression molding, the mold cavity is completely filled, wherein the closing force is initially kept relatively low, so that the cavity pressure increasing during filling easily opens the tool. The work ^¬ generating a relatively stress-free molded article is in the sequence then by continuously increasing the closing force closed and embossed. This injection molding variant is used for example in the production of data carriers (DVD, CD).

A disadvantage of these methods is that due to the embossing process associated with the actual injection molding process, the cycle time is prolonged compared to a pure injection molding, in particular taking into account that the molding compound temperature should be kept approximately at the glass transition temperature (softening temperature) T _G during the injection-compression molding To be able to perform the expression with the required accuracy, ie, the molding material must be cooled in the injection mold from the melting temperature to the Glasüberweichungstempe- rature.

Presentation of the invention

In contrast, the invention has for its object to provide a method and an apparatus for producing optical components, by the cost of sufficient component quality he ^¬ possible is possible.

This object is achieved with regard to the method by the features of claim 1 and with regard to the direction solved by the features of the independent claim 9. Special advantageous embodiments of the invention are described in the dependent claims. According to the invention, a preform in an injection molding tool made of a thermoplastic or thermosetting molding compound is first produced by injection molding in the method for producing optical components ^¬ . This preform is then formed by an embossing process in the optical component, according to the invention, the preform taken from the injection mold, cooled and then inserted into a separate embossing tool for final embossing. The cooling can take place in a separate cooling station or in the embossing tool.

Due to the inventive division of the method in the injection molding in an injection mold and the Fer ^¬ tig stamping in a finished stamping tool can be maintained in the injection molding the conventional, optimal for the injection molding cycle time, with parallel the finished stamping takes place in the stamping tool, so that despite higher investment costs due to significantly lower cycle times a more cost-effective production is possible.

The effective cycle time for the manufacture of the optical component is especially short when the embossing tool is operated at approximately constant temperature, preferably at ^¬ glass transition temperature, thus losing no time for cooling and heating said stamping tool. The embossing tool has the dimensions of the finished dimensions of the opti ^¬ cal component corresponding dimensions. Ie no shrinking dimensions are taken into account so that the construction ^¬ part can be made independent of the shrinkage with excellent quality ty.

The manufacturing quality can be further improved, even if in the injection mold a pre-embossing Runaway ^¬ leads is said pre-embossing requires substantially less time than the conventional injection-compression molding, so that the cycle time is extended only insignificantly.

The inventive method provides a quasi continu ous production ^¬, wherein initially a first preform is formed in the injection mold and to a second, previously manufactured preform is marked ready parallel in the embossing tool. The formed first in the injection molding preform is then removed from the injection mold and inserted ^¬ placed in the pressing tool. The cycle time is largely determined by the injection mold because of the injection molding cycle et ^¬ what will be longer than the embossing cycle.

In a variant of the invention, the removal of the preform from the injection mold and the ^insertion into the embossing tool take place by means of a handling ^device , so that no manual access is required. According to the invention, it is preferred if the method is used for the production of lenses, for example of PC, PMMA, PMMI, COC or other suitable plastics. Short description of the drawing

The single drawing shows a flow chart of the inventions ^¬ inventive method.

Preferred embodiment of the invention

The invention will be explained below with reference to a method for producing a lens of an optical assembly.

The lens is made in a conventional manner from a thermoplastic material, such as PC, PMMA, PMMI, COC. In conventional solutions, this production takes place in the injection compression molding process in a single tool with the disadvantages described above.

In the method according to the invention, the predetermined material or the material mixture is first melted (plasticized) in an injection molding machine and then injected via the injection unit into the cavity of an injection molding tool. This cavity of the Spritzgieß ^¬ tool is designed with a certain excess, so that the shrinkage of the injection molded part is taken into account during cooling and solidification of the plastic melt. In order to ensure a dimensional stability of the injection-molded part, the melt is acted upon by the injection unit with a pressure, so that a complete filling of the cavity is ensured. In contrast to conventional injection molding ago ^¬ the injection mold is so heated that the temperature of the plastic mass in the cavity remains well above the glass transition temperature T _G. This glass transition temperature is the temperature at which the plastic mass is the largest Has change in the deformability. This glass transition separates the brittle, energy-elastic area from a soft, entropy-elastic (rubber-elastic) area. In a variation of the invention, this preform is pre-stamped in the manner described above, wherein - as already explained - either the injection mold during the injection of the plastic material is not fully ^¬ constantly kept closed or opened after filling the cavity len, so that is increased accordingly by the fol ^¬ increasing increasing the closing force of the pressure on the Formmas ^¬ se. This pre-embossing takes place ^¬ but to a much lesser extent than in the conventional solutions. In principle, as indicated by dashed lines in the attached process scheme, the pre-embossing step can be dispensed with.

This formed by injection molding or injection compression molding preform is then men well above the glass transition temperature entnom- with comparatively high tempera ture ^¬ and then cooled in a relatively short time on the glass transition temperature T _G ^¬. This cooling can be either in a separate cooling station (see solid line in the process scheme) or by direct Einle ^¬ gen this preform in a press tool. The mold temperature of this press tool is provided as a ^¬ that the preform is brought to a temperature in the region of the said glass transition temperature or held.

The cavity of this pressing tool does not hold shrinkage dimensions but must be manufactured according to the geometry of the designed lenden optical component. In other words, the post-shrinkage of the preform, which already has the part weight of the finished part, is "distributed" in this embossing tool to the required part geometry.This final stamping in the embossing tool can be used to produce microstructures, small facets or even matting , Process variations in injection molding, which may also affect different shrinkage, to compensate for the external embossing.

After this finish embossing at glass transition temperature, the workpiece is then cooled within the embossing tool or ex ^¬ tern, so that the molding compound completely aushär ^¬ Tet or solidifies. The advantage of the above-described method is that the cycle time of the injection molding in the injection molding tool ^¬ can be significantly shortened compared with conventional solutions, since no cooling in the injection molding tool ^¬ must be provided to a temperature range below the glass transition temperature. The injection-compression tool is always operated with a constant tool Tempe ^¬ temperature in the range of glass transition temperature, so the usual manner eliminates required heating-Kühlen- process in the tool and thus the cycle time can be reduced. Preliminary experiments indicated that the optical components produced via the inventive method have by an extremely low self-clamping ^¬ voltage. This is due to the annealing of the device at temperatures in the range or below the glass transition temperature. Provided for in the process scheme knockouts of the advantages of preform in the injection mold is especially in the form ^¬ share with extreme shrinkage used because of the two-stage embossing ER excellent dimensional stability is targetable.

The inventive method is preferably realized on ei ^¬ ner combination plant, in which the Spritzgießwerk ^¬ tool is clamped in an injection molding machine, wherein the embossing tool is clamped ^¬ in an immediate proximity to this injection molding machine embossing machine, so that the molded parts over a automatic ^¬ table formed automatic handling device when opening of the injection mold and a ^¬ can be placed in the open embossing tool. That is, the production of a preform by injection molding or injection compression molding and the final embossing of a preform previously produced by injection molding are substantially parallel to each other, wherein the cycle time of the injection molding / injection compression molding is slightly larger than the cycle time in the embossing tool. By reducing the Spritzgießzykluszeit ever ^¬ but the total time for the production of the optical component compared to conventional solutions can be reduced, the quality of the component is considerably above jeje ^¬ nigen quality that can be achieved with the conventional solutions.

Disclosed are a method and an apparatus for manufacturing optical components, wherein a preform is produced in an injection mold and then coined in an embossing tool.

Claims

claims

A method for producing optical components, wherein a preform in an injection molding of a thermoplastic or thermoset Kunststoffmas- se by injection molding and this preform is then formed by an embossing process and cooling in the device, characterized by the steps: remove the preform from the injection mold ;

Cooling of the preform outside of the Spritzgieß ^¬ tool and

Insert the preform into an embossing tool and finish embossing to the component.

2. The method according to claim 1, wherein the embossing tool is operated approximately at a constant temperature.

3. The method according to claim 2, wherein the mold temperature is adjusted so that the preform is maintained in the range of a glass transition temperature (T _G ).

4. The method according to any one of the preceding patent claims, wherein a cavity of the embossing tool is designed according to the finished dimensions of the component.

5. The method according to any one of the preceding claims, wherein in the injection molding a pre-stamping is performed.

6. The method according to any one of the preceding claims, wherein the injection molding and the embossing are carried out in parallel, so that a quasi-continuous produc- ^¬ tion is possible, in which during the formation of a first preform in the injection mold a second preform in the embossing tool finished coined and removed from this is and then the previously manufactured first preform is inserted into the stamping tool ^¬ .

7. The method according to any one of the preceding claims, wherein the demolding of the preform from the injection mold and the insertion of this Vorform ^¬ ling takes place in the embossing tool via a handling device.

8. The method according to any one of the preceding claims, wherein the components are lenses which are made of PC, PMMA, PMMI, COC.

9. An apparatus for producing an optical component with an injection mold for injection molding a preform and an embossing tool for finishing ^¬ embossing of the preform.

10. The device according to claim 9, wherein the injection mold with a Schwindmaß the Vorform ^¬ lings into account oversizing and the Prägewerk- tool is designed with the finished dimension of the device.

11. The device according to claim 9 or 10, comprising a handling device for removing the preform from the injection mold and for inserting the preform in the embossing tool.