恒定涡流粘度下变动黏度和导热系数微极流体滞止点流动的熔融换热效应

Sunday Kolawole Adegbie, Olubode Kolade Kọrikọ, Isaac Lare Animasaun
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引用次数: 48

摘要

研究了微极流体在水平线性拉伸表面上向驻点方向的二维边界层流动。考虑了表面熔化换热、温度和流体域内指数空间相关的内热生成。假设动态粘度和热导率与温度有关,而微极涡粘度是恒定的。讨论了这些假设。根据所有必要的理论,对经典的温度依赖粘度和导热模型进行了修正,以适应熔化传热的情况。利用相似变换将控制方程转化为非线性边值问题并进行数值求解。分析了不同参数对微极流体流动和传热的影响。研究结果表明,提高微极流体在熔体表面横向流动速度的可能途径之一是考虑微极流体在恒定涡流粘度下的变热物性,即熔体参数随流速比的增大而减小。为了正确分析/研究具有可变性质的微极流体在熔点表面的流动,必须考虑新的热物理模型。与微极流体在熔融表面流动的经典条件(热物性恒定)相比,新条件下的速度随速度比的增大而增大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Melting heat transfer effects on stagnation point flow of micropolar fluid with variable dynamic viscosity and thermal conductivity at constant vortex viscosity

The two dimensional boundary layer flow of micropolar fluid towards stagnation point formed on a horizontal linearly stretching surface is investigated. Melting heat transfer at the surface, temperature and exponentially space dependent internal heat generation within fluid domain are considered. It is assumed that dynamic viscosity and thermal conductivity are temperature dependent while micropolar vortex viscosity is constant. These assumptions are discussed. Classical temperature dependent viscosity and thermal conductivity models were modified to suit the case of melting heat transfer following all the necessary theories. Similarity transformations are used to convert the governing equations into non-linear boundary value problem and solved numerically. Effects of various parameters on the micropolar fluid flow and heat transfer are analyzed. The results reveal that one of the possible ways to increase transverse velocity of micropolar fluid flow over melting surface is to consider variable thermo-physical property of micropolar fluid at constant vortex viscosity with a decrease in melting parameter while velocity ratio increases. For correct analysis/investigation of micropolar fluid flow with variable properties over melting surface, the new thermo-physical models are to be considered. The velocity increases with the increase of velocity ratio under the new condition compare to classical condition (constant thermo-physical property) of micropolar fluid flow over melting surface.

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