通过锥形波状壁的耗散振荡杰弗里流体流的非线性动力学:不可逆性和熵生成分析探索

P. Vaidehi, J. Sasikumar
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引用次数: 0

摘要

本研究的主要目的是探索杰弗里流体在洛伦兹力和热辐射作用下通过非对称锥形波浪形通道的振荡流动中引入的熵产生分析的新颖性。它在一系列学科中有着广泛的应用:材料选择过程中的汽车弹性体、生物力学中的软组织力学建模、聚合物加工中的挤出和注塑优化、流变学中的流变测试设计和数据解释。通道中锥形波浪形状的独特性质及其对 MHD 振荡杰弗里流体流动速度曲线的影响是一个新颖的元素,以前未被广泛探讨过。利用非相似性变换将控制方程转化为非线性微分方程系统。无量纲偏微分方程(PDE)瞬态系统采用隐式有限差分数值方案(即 Crank-Nicolson 方法)求解。结合相关参数,用图形描述了流动在速度、温度和熵产生的体积率方面的确切行为。随着布林克曼数的增大,熵产生率也随之增大,这意味着多孔结构的影响增强,导致杰弗里流体流动的不可逆性增大。通过分析速度和温度曲线,对牛顿流体和杰弗里流体的行为特征进行了比较研究。最后,将当前研究结果与之前的研究结果进行了比较。比较结果表明,研究结果与现有文献一致。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Nonlinear dynamics of dissipative oscillatory Jeffrey fluid flow via tapered wavy walls: exploration of irreversibility and entropy generation analysis

Nonlinear dynamics of dissipative oscillatory Jeffrey fluid flow via tapered wavy walls: exploration of irreversibility and entropy generation analysis

The primary objective of the present study is to explore the novelty in the analysis of entropy generation introduced in the oscillatory flow of Jeffrey fluid through an asymmetric tapered wavy channel subjected to Lorentz force and thermal radiation. It has diverse applications in a range of disciplines: automotive elastomers in the material selection process, soft tissue mechanics modeling in biomechanics, extrusion and injection molding optimization in polymer processing, rheological test design and data interpretation in rheology. The unique nature of the tapered wavy shape in the channel and its influence on the velocity profile of MHD oscillatory Jeffrey fluid flow represents a novel element that has not been extensively explored previously. The governing equations are transformed into a system of nonlinear differential equations using non-similarity transformations. The transient system of dimensionless partial differential equations (PDEs) is solved using an implicit finite difference numerical scheme called the Crank-Nicolson method. Incorporating relevant parameters, the exact behavior of the flow with respect to velocity, temperature and volumetric rate of entropy generation is graphically depicted. The increase in entropy generation with a higher Brinkman number implies that the enhanced influence of the porous structure leads to greater irreversibility in the Jeffrey fluid flow. A comparative study is carried out to characterize Newtonian and Jeffrey fluid behavior by analyzing the velocity and temperature profiles. Finally, the findings of the current study have been compared to those of earlier studies. The comparison is seen to bear a good agreement with the existing literature.

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