一种用于在多孔基材上涂覆二级流体的精确解决方案

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

Journal of Plastic Film & Sheeting Pub Date : 2021-08-03 DOI:10.1177/87560879211035429

M. Mughees, M. Sajid, H. Shahzad, M. Sadiq, N. Ali

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引用次数: 6

摘要

本研究探索了用简单的固定叶片在移动多孔基板上对二级流体进行涂层的过程。本文对平面涂层和指数涂层进行了研究。在假设叶片长度远大于涂层厚度的情况下，利用润滑近似理论对控制方程进行了简化。适当的尺度使控制方程归一化。压力梯度和速度的表达式是解析得到的，而压力是用所谓的“射击法”数值技术得到的。观察雷诺数Re、吸力速度v 0和非牛顿二级参数λ如何影响速度、压力梯度、压力、涂层厚度和叶片上的载荷，并以图形和表格的形式显示。有趣的工程量，如速度、压力梯度和压力以图形形式突出显示，而负载和厚度以表格形式显示。可以观察到，无论是平面涂层还是指数涂层，压力梯度、压力、速度、载荷、厚度都随着参数∈和R e、v 0的增大而减小，而随着参数∈的增大，这些物理量都增大。最重要的物理量是负载，因为它负责保持涂层的质量和厚度。此外，可以看出载荷随着雷诺数Re和v 0的增加而减小，随着参数λ的增加而增大。

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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An exact solution for blade coating of a second-grade fluid on a porous substrate

This study explores the blade coating process with a simple fixed blade for a second-grade fluid over a moving porous substrate. The article investigates both plane and exponential blade coating. The analysis simplifies the governing equations via lubrication approximation theory by assuming that blade length is much larger than the coating layer thickness. Suitable scales normalize the governing equations. The expressions for pressure gradient and velocity are analytically obtained whereas pressure is attained using a so-called “shooting method” numerical technique. How the Reynolds number R e , suction velocity v 0 and non-Newtonian second-grade parameter ϵ affect the velocity, pressure gradient, pressure, coating layer thickness and load on the blade are observed and displayed graphically and as tables. Interesting engineering quantities like velocity, pressure gradient and pressure are highlighted in graphical form whereas load and thickness are presented as tables. It is observed that the pressure gradient, pressure, velocity, load and thickness decrease as the parameters ∈ and R e and v 0 icrease for the cases of both plane and exponential coaters while all these physical quantities are observed to increase when the parameter ∈ increases. The most important physical quantity is the load for it is responsible in maintaining the coating quality and thickness. Moreover, it is perceived that the load decreases as the Reynolds number R e and v 0 increases get accelerated and it increases when parameter ϵ is increased.

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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).