Measured and Calculated Expansion of Polystyrene Beads Comprising Four Blowing Agents in Hot Silicone Bath and in Water Vapor as well as in Extrusion for Boards

Current Applied Polymer Science Pub Date : 2022-04-28 DOI:10.2174/2452271605666220428100658

H. Horacek

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Abstract

The published models were sophisticated and described the expansion in dependence on time only in the first stage. The object was to explain the discrepancy between foaming under pressure release XPS and foaming by heat supply EPS by model calculations. The rate of expansion of small samples comprising blowing agent and polystyrene was measured by buoyancy in a silicone bath at 110°C and that of extrusion on photographs of the volume increase after the nozzle. A viscosity model and a diffusion model were established, and experimental data were compared with calculated data. The expansion rate in the silicone bath was about 100 times slower than that in extrusion at the same nozzle temperature. The velocity of foaming in the bath by heat supply was observed to be dominated by viscosity and that of foaming under pressure release in extrusion to be stirred by diffusion. Calculations according to the viscosity model allowed the description of foaming in silicone, and the diffusion model reproduced the data of extrusion. The common feature of both models was their simplicity. According to the models, the efficiency of blowing agents was only dependent on the molecular weight and on the solubility. The time determining influence on foaming was diffusion in extrusion of XPS and viscosity for expansion of EPS in silicone bath and water vapor.

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含四种发泡剂的聚苯乙烯小珠在热硅浴和水蒸气中以及在板材挤压中膨胀的测量和计算

已发表的模型是复杂的，并且仅在第一阶段描述了依赖于时间的扩张。目的是通过模型计算来解释压力释放型发泡与供热型发泡的差异。通过在110°C的硅胶浴中浮力测量了发泡剂和聚苯乙烯组成的小样品的膨胀率，并通过喷嘴后体积增加的照片测量了挤压率。建立了黏度模型和扩散模型，并将实验数据与计算数据进行了比较。在相同喷嘴温度下，硅胶浴中的膨胀速率比挤出中的膨胀速率慢约100倍。在加热条件下，浴槽内的发泡速度主要由粘度决定，而在挤压释放压力条件下的发泡速度主要由扩散搅拌决定。根据粘度模型的计算可以描述有机硅中的发泡，而扩散模型可以再现挤出的数据。这两种模型的共同特点是简单。根据模型，发泡剂的效率只取决于分子量和溶解度。影响泡沫发泡的主要因素是XPS在挤出过程中的扩散、EPS在硅胶浴和水蒸气中的膨胀粘度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current Applied Polymer Science

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