Ramification of Hall effects in a non-Newtonian model past an inclined microchannel with slip and convective boundary conditions

IF 5.8 4区 工程技术 Q1 MECHANICS Applied Rheology Pub Date : 2024-07-08 DOI:10.1515/arh-2024-0010
Ajjanna Roja, Rania Saadeh, Raman Kumar, Ahmad Qazza, Umair Khan, Anuar Ishak, El-Sayed M. Sherif, Ioan Pop
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Abstract

Many applications, including micro air vehicles, automotive, aerospace, refrigeration, mechanical–electromechanical systems, electronic device cooling, and micro heat exchanger systems, can be used to determine the heat flow in microchannels. Regarding engineering applications, heat flow optimization discusses the role of entropy production minimization. Therefore, this work explores new facets of entropy production in fully developed Carreau fluid heat transport in an inclined microchannel considering exponential space/temperature dependence, radiative heat flux, and Joule heating. The Carreau fluid model’s rheological properties are taken into account. Additionally, the influence of Hall slip velocity and convective boundary conditions is considered. Using appropriate transformation constraints, the governing equations are transformed into a system of ordinary differential equations, which are then numerically solved using the fourth- and fifth-order Runge–Kutta–Fehlberg method. Graphs illustrate a significant discussion of physical parameters on production of entropy, Bejan number, thermal field, and velocity. Our findings established that there is a dual impact of entropy generation for the exponential space/temperature-dependent, radiation parameter, Hall parameter, Weissenberg number, and velocity slip parameter. The Bejan number decreased with the Hall current and the Weissenberg number, and it enhanced with exponential space/temperature dependent. The convection constraint maximizes the entropy at the channel walls. The results are compared with exact solutions, which show excellent agreement.
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非牛顿模型中霍尔效应在倾斜微通道滑移和对流边界条件下的夯实作用
许多应用,包括微型飞行器、汽车、航空航天、制冷、机械机电系统、电子设备冷却和微型热交换器系统,都可用于确定微通道中的热流。在工程应用方面,热流优化讨论了熵产生最小化的作用。因此,考虑到指数空间/温度相关性、辐射热通量和焦耳加热,本研究探索了在倾斜微通道中充分发展的卡若流体热传输中熵产生的新方面。Carreau 流体模型的流变特性也考虑在内。此外,还考虑了霍尔滑移速度和对流边界条件的影响。利用适当的转换约束条件,将控制方程转换成常微分方程系统,然后使用四阶和五阶 Runge-Kutta-Fehlberg 方法对其进行数值求解。图表说明了物理参数对熵的产生、贝扬数、热场和速度的重要影响。我们的研究结果表明,熵的产生与指数空间/温度、辐射参数、霍尔参数、魏森伯格数和速度滑移参数有双重影响。贝扬数随霍尔电流和韦森伯格数的增大而减小,随指数空间/温度相关性的增大而增大。对流约束使通道壁的熵最大化。研究结果与精确解进行了比较,两者显示出极好的一致性。
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来源期刊
Applied Rheology
Applied Rheology 物理-力学
CiteScore
3.00
自引率
5.60%
发文量
7
审稿时长
>12 weeks
期刊介绍: Applied Rheology is a peer-reviewed, open access, electronic journal devoted to the publication in the field of applied rheology. The journal provides the readers with free, instant, and permanent access to all content worldwide; and the authors with extensive promotion of published articles, long-time preservation, language-correction services, no space constraints and immediate publication.
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