Calculating diffusion coefficients from molecular dynamics simulations for foam extrusion modelling of polypropylene with CO2, N2 and ethanol

IF 3.2 4区 工程技术 Q2 CHEMISTRY, APPLIED
Felix Melzer, R. Breuer, R. Dahlmann, C. Hopmann
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引用次数: 4

Abstract

In foaming processes, the blowing agent has a significant influence on the material behaviour and the necessary processing parameters. Low-density polypropylene foam sheets are usually produced with aliphatic hydrocarbons or alkanes as physical blowing agent. Due to the necessary safety precautions and the environmental impact, there is great interest in using alternative blowing agents such as CO2. The sole use of CO2 often leads to corrugation, open cells or surface defects on the foam sheet and therefore requires modifications to the process technology. For this reason, blowing agent mixtures based on CO2 and organic solvents are used for the production of foam sheets. For developing a process model describing the melt flow in the extrusion die and the formation of cells, specific material data like diffusion coefficients are necessary. For CO2 and N2 as sole blowing agent, experimental data exist in the literature. Since no experimental data are available for co-blowing agents such as ethanol at elevated temperatures as they occur in the foam process, these data were calculated using molecular dynamics (MD) simulations. The benefit of MD simulations lies in their ability to reduce the experimental effort and, in particular, to provide data in cases where this data is not available through experimental measurements. The calculated diffusion coefficient values are compared to experimental data from the literature and presented for CO2, N2 and ethanol in polypropylene. The calculated diffusion coefficients of CO2 and N2 are compared with literature results and agree well with them. For the ethanol molecules, the diffusion coefficient is compared relative to the both aforementioned ones considered the larger size of the ethanol molecule compared to N2 and CO2. The results of the diffusion coefficients for ethanol are reasonable compared to the values found for the other two molecules.
用分子动力学方法计算CO2、N2和乙醇对聚丙烯泡沫挤出的扩散系数
在发泡过程中,发泡剂对材料性能和必要的工艺参数有重要影响。低密度聚丙烯泡沫板通常以脂肪烃或烷烃为物理发泡剂生产。由于必要的安全预防措施和对环境的影响,人们对使用二氧化碳等替代发泡剂非常感兴趣。二氧化碳的单独使用通常会导致泡沫板上的波纹,开孔或表面缺陷,因此需要修改工艺技术。因此,以CO2和有机溶剂为基础的发泡剂混合物用于生产泡沫板。为了建立一个描述熔体在挤压模具中的流动和单元形成的过程模型,需要特定的材料数据,如扩散系数。对于CO2和N2作为唯一发泡剂,文献中有实验数据。由于在高温下的共发泡剂(如乙醇)在泡沫过程中没有实验数据,因此这些数据是使用分子动力学(MD)模拟计算的。MD模拟的好处在于它们能够减少实验工作量,特别是在无法通过实验测量获得数据的情况下提供数据。计算得到的扩散系数值与实验数据进行了比较,并给出了CO2、N2和乙醇在聚丙烯中的扩散系数值。将计算得到的CO2和N2扩散系数与文献结果进行了比较,两者吻合较好。对于乙醇分子,考虑到乙醇分子比N2和CO2大,将其扩散系数与上述两种扩散系数进行比较。与其他两种分子的扩散系数相比,乙醇的扩散系数结果是合理的。
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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来源期刊
Journal of Cellular Plastics
Journal of Cellular Plastics 工程技术-高分子科学
CiteScore
5.00
自引率
16.00%
发文量
19
审稿时长
3 months
期刊介绍: The Journal of Cellular Plastics is a fully peer reviewed international journal that publishes original research and review articles covering the latest advances in foamed plastics technology.
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