DD203011A1 - METHOD FOR TEMPERING INJECTION MOLDING TOOLS - Google Patents

Abstract

The inventive method can be applied to all Spritzgieszprozessen where high quality requirements are placed on the plastic moldings. The aim and object of the invention is to provide a method which requires little technical and economic effort and with low energy consumption and low maintenance costs durchfuehrbar and an improvement of the molded part quality at high Ausstoszleistung, in particular the production of moldings without residual stress and orientations at the same Degree of crystallization over the entire cross section of the molded part, made possible. According to the invention, the injection process takes place in a temperature-controlled injection mold, which is cooled with water after and / or during the injection process. Thereafter, the cooling is interrupted and there is a tempering of the molded part by the molding still inherent intrinsic energy. This tempering is followed by a renewed cooling phase, which only lasts so long that the residual energy content of the molded part is sufficient to temper the injection molding tool in such a way that the subsequent injection process can take place again under sufficient flow conditions.

Description

Tifael of the invention

"Method for tempering injection molds"

Field of use; the invention

The invention relates to; a method for controlling the temperature of injection molds, which can be used in all injection molding processes, where high quality demands are placed on the plastic moldings.

Characteristic of the known technical solutions

In the production of "plastic moldings by injection molding technology, process-related residual stresses, orientations and, in the case of crystalline molding compositions, different degrees of crystallization occur via the molding, which result in a reduction in the utility properties of the particular molding In practice, it is common practice that the injection molds are constantly cooled with water from the operational cooling water system to rapid cooling of ^ molding and thus a low cycle time to reach,

From the DD-WP 29 817 another method for controlling the temperature of injection molds is known. After this

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Procedure, the plastic melt is first injected into a tempered injection mold. After the tool has been filled, a metered quantity of a relatively deeply cooled coolant is impulsively introduced into the mold and, if appropriate, brought into circulation. Before the demolding of the molded part of the cooling process, the time and process dependent 'can be controlled, but interrupted, so that the injection mold, with a corresponding dosage of the coolant and choice of coolant temperature at the end of the injection molding' heats up again so far that the injection process can take place again under sufficient flow conditions.

The disadvantages of this method lie in the high equipment complexity for carrying out the method, which is determined in particular by necessary refrigeration units and temperature control. In addition, an additional energy requirement for operating these devices is necessary. Furthermore, it has been found that excessive temperature differences between the coolant and the molding cavity in the injection molding tool during the cooling process cause an increase in the residual stresses as well as different degrees of crystallization in the molded part and thus a reduction in utility.

Another method for controlling the temperature of injection molds is described in DS-OS 19 38 496. Thereafter, the injection mold is heated or cooled depending on the end of Spritζgießzyklusses and is connected to corresponding heating or cooling circuits, which are fed by temperature control devices. The injection molding tool is designed shell-shaped for optimal implementation of the method, wherein the heating or cooling system supporting tool parts are made of good temperature conductive materials. Another disadvantage of this method, the high expenditure on equipment by additional temperature control, the high energy consumption and the

'complicated tool design, which results from the bowl-shaped structure of Sprifczgießwerkzeuges and leads to correspondingly complicated Formfceilen to application limits. In addition, this method requires a relatively long cycle time.

Object of the invention

The object of the invention is to provide a method for tempering of injection molds, which requires little technical and economic effort by low cost of accessories and with low energy consumption and low maintenance costs is feasible.

Explanation of the essence of the invention

The object of the invention is to provide a simplified method zum.Temperieren of injection molds, which works without the use of additional Eeiz- and cooling units - and improving the molding quality at high output, especially the production of moldings without residual stresses and orientations at the same Kris - Tallisationsgrad over the entire cross section of the molded part allows.

According to the invention the object is achieved in that the Sinspritzvorgang initially takes place in a tempered by the Sprifczgießzyklus injection mold. The injection mold is cooled after and / or during the injection process with water from the operating cooling water system, then the cooling is interrupted and there is a tempering of the molded part through the molding still inherent intrinsic energy, to this annealing

 30 joins a renewed cooling phase, which lasts only so long that the residual energy content of the molded part is sufficient to temper the injection mold so that the nach-

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following Binspritzvorgang can take place again under sufficient Eließbedingungen. Depending on the ITormteilgröße and mass and the process conditions, the annealing process can be repeated one to several times. Thereafter, the standard part is removed from the injection mold ο

The beginning of the cooling is initiated as a function of the Gesamtzyklusses by control or regulating elements, the duration of the cooling and the Äbschaltvorgang be determined by timer or by process computer and triggered. Of "advantage is when a temperature measurement of the tool and / or the temperature of the cooling water in the return is used to determine the time of the coolant flow,

The temperature difference between cooling water and average mold temperature at the beginning of the cooling process should be 10 - 70 ° G, preferably 4 - 0 ° C. The tempering of the standard part following the cooling phase should take place at a temperature of 10 ° to 30 ° C. above the mean starting temperature of the injection molding tool, the cooling phase following the one or more heat treatment only lasting until the residual energy content of the molded part is sufficient To temper the injection mold so that the subsequent injection cycle can be initiated ·

Claims (3)

234716 4 grfindungsansOruch A process for controlling the temperature of injection molds, in which the plastic melt is injected into a tempered injection mold, wherein the Spritsgießwerkseug is cooled after or during the 3inspritzvorganges with Wasser.aus from the operating cooling water system, .Dadurch characterized in that the Eühlphase is interrupted after the injection process, that this is followed by a tempering of the standard part by which the oil still has its own inherent energy, and .the tempering follows in a known manner a renewed cooling phase which lasts so long that the residual energy content of the standard part is sufficient to bring the injection mold to a to heat up the favorable temperature for the next fuel cycle 2 «method for tempering Spritzgießv / Tooling according to item ^1,: characterized in that the tempering of the 'molding is a sharks to several, preferably one to five times carried out in a Spritzsyklus. 3 · The method for tempering Spritsgießwerkzeugen according to item 1, characterized in that the Tenperaturdifferenz between the coolant temperature and mean tool temperature at the beginning of the Zühlprozesses 10-70 ° C, preferably 40 ⁰ C,