Development of runner reservoir and its effect on optical properties of small high-precision plastic injection molded parts

IF 1.2 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES Plastics, Rubber and Composites Pub Date : 2023-04-18 DOI:10.1080/14658011.2023.2200332

Demitri Shotwell, Mong-Tung Lin, Jia-Hau Liu, L. Turng

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Abstract

ABSTRACT Adding reservoirs as extensions to a multi-cavity runner-system to regulate cavity fill-rate within small, high-precision optical parts during filling and fill-to-pack switch-over (F/P) was studied with the aid of simulations. This work aimed for a constant melt-front velocity inside the cavities with varying geometries. Three methods of reservoir designs were considered: first, using engineering intuition, second and third, using mass balance and mass and momentum balance equations, respectively. Eight reservoirs were designed and compared to two no-reservoir cases. For each case, 27 runs covering three levels of fill-rate, F/P, and packing pressure were simulated, resulting in 270 simulation runs. The quality variables of flow and thermally induced retardation and the average and standard deviation of volumetric shrinkage were considered and for each parameter, the minimum, best cases, occurred with a reservoir case. Thus, this study offers a proof-of-concept design for using reservoirs to improve molding of small, high-precision optical parts.

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流道贮液的发展及其对小型高精度注塑件光学性能的影响

通过模拟，研究了在充填和充填-充填切换(F/P)过程中，将储层作为多腔管系统的延伸部分，在小型高精度光学部件内调节空腔填充率。这项工作的目标是在不同几何形状的空腔内保持恒定的熔体前沿速度。考虑了三种油藏设计方法:第一种是利用工程直觉，第二种是利用质量平衡，第三种是利用质量和动量平衡方程。设计了8个储层，并与2个无储层的情况进行了比较。对于每种情况，模拟了27趟井，涵盖了三种水平的填充率、F/P和充填压力，共模拟了270趟井。考虑了流动和热阻的质量变量以及体积收缩的平均值和标准差，对于每个参数，在油藏情况下出现最小和最佳情况。因此，本研究提供了一种概念验证设计，用于使用储层来改进小型高精度光学部件的成型。

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来源期刊

Plastics, Rubber and Composites 工程技术-材料科学：复合

CiteScore

4.10

自引率

0.00%

发文量

审稿时长

4 months

期刊介绍： Plastics, Rubber and Composites: Macromolecular Engineering provides an international forum for the publication of original, peer-reviewed research on the macromolecular engineering of polymeric and related materials and polymer matrix composites. Modern polymer processing is increasingly focused on macromolecular engineering: the manipulation of structure at the molecular scale to control properties and fitness for purpose of the final component. Intimately linked to this are the objectives of predicting properties in the context of an optimised design and of establishing robust processing routes and process control systems allowing the desired properties to be achieved reliably.