Numerical analysis of two-layered isothermal calendering of viscoplastic and Newtonian fluids with different viscosity ratios

IF 2.1 4区材料科学 Q3 MATERIALS SCIENCE, COATINGS & FILMS

Journal of Plastic Film & Sheeting Pub Date : 2022-07-01 DOI:10.1177/87560879221093902

M. Ilyas, M. Zahid, M. Mushtaq

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Abstract

Co-extruded multi-layer plastic sheets and polymer structures formed by calendering process or by cold rolling are widely used in the packaging industry and thin-film transistor manufacturing. The different materials are extruded from separate extruders into the single sheet die which delivers a multi-layer sheet with uniform layer thickness at die exit. This multi-layer sheet is then stretched between counter-rotating rolls to obtain final uniform multi-layer sheet. There are many factors which can influence this process. In this article, calendering a single layer Newtonian or Non-Newtonian material has been extended to analyze a two-layer calendering process for an incompressible Viscoplastic and Newtonian fluids as upper and lower layers with different viscosity ratios. To simplify the equations of motion, the lubrication approximation theory is used. The expressions of non-dimensional pressure gradient, pressure and velocity distribution of both layers are obtained analytically by using proper no slip boundary conditions and dimensionless variables. The dimensionless detachment point is approximated by Regula-Falsi (false position) method. The important engineering factors including detachment point, calendered sheet thickness, roll separation force, power input by rolls, torque on each roll, and adiabatic temperature are all computed. In addition, how the viscosity ratios and viscoplastic casson parameter affect these factors have been investigated. Moreover all established results in literature for single layer calendering Newtonian fluids are also validated at casson parameter β tending towards infinity.

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不同黏度比的粘塑性和牛顿流体双层等温压延的数值分析

通过压延或冷轧工艺形成的共挤多层塑料片材和聚合物结构广泛应用于封装工业和薄膜晶体管制造。不同的材料从单独的挤出机挤出到单片模具中，在模具出口提供具有均匀层厚的多层板材。然后将多层薄板在反向旋转的辊子之间拉伸以获得最终均匀的多层薄板。有许多因素可以影响这一过程。本文将单层牛顿或非牛顿材料的压延扩展到不可压缩粘塑性和牛顿流体作为不同粘度比的上下两层压延过程。为了简化运动方程，采用了润滑近似理论。采用适当的无滑移边界条件和无因次变量，得到了两层的无因次压力梯度、压力和速度分布的解析表达式。采用正则-假位置法对无量纲分离点进行近似。计算了剥离点、压延薄板厚度、轧辊分离力、轧辊输入功率、各轧辊扭矩和绝热温度等重要工程因素。此外，还研究了粘度比和粘塑性卡松参数对这些因素的影响。此外，在卡森参数β趋于无穷时，所有已建立的单层压延牛顿流体的结果也得到了验证。

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 Plastic Film & Sheeting 工程技术-材料科学：膜

CiteScore

6.00

自引率

16.10%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Plastic Film and Sheeting improves communication concerning plastic film and sheeting with major emphasis on the propogation of knowledge which will serve to advance the science and technology of these products and thus better serve industry and the ultimate consumer. The journal reports on the wide variety of advances that are rapidly taking place in the technology of plastic film and sheeting. This journal is a member of the Committee on Publication Ethics (COPE).