Chemically reactive non-Newtonian fluid flow through a vertical microchannel with activation energy impacts: A numerical investigation

IF 2.1 4区 工程技术 Advances in Mechanical Engineering Pub Date : 2024-07-24 DOI:10.1177/16878132241261472
Ajjanna Roja, Pudhari Srilatha, Umair Khan, Anuar Ishak, Anjali Verma, Javare Gowda Rekha, Md Irfanul Haque Siddiqui
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Abstract

This work examines the second law analysis of an electrically conducting reactive third-grade fluid flow embedded with the porous medium in a microchannel with the influence of variable thermal conductivity, activation energy, viscous dissipation, joule heating, and radiative heat flux. A suitable non-dimensional variable is included into the governing equations to transform them into an ensemble of equations that are devoid of dimensions. The acquired equations are then tackled using the Runge Kutta Felhberg 4th and 5th order (RKF-45) approach in conjunction with the shooting methodology. Through comparison with the current results, the numerical results are verified, which provides a good agreement. From the present outcomes, it is established that the entropy generation is supreme for the viscous heating constraint, variable thermal conductivity, Frank Kameneski, heat source ratio parameter and third-grade fluid material constraint. The Bejan number boosts up with larger values of activation energy, and Frank Kameneski constraint and the decreasing nature is noticed for increasing third-grade material parameter, viscous heating parameter. With magnetism, the fluid’s velocity slows down because of a resistive force. A similar impact in the channel on velocity is noticed for larger third-grade fluid, activation energy parameter, and Frank-Kameniski parameters and increasing behavior is noticed for variable thermal conductivity, and permeability parameter. Further, it is cleared that the variable thermal conductivity assumption in the channel plate leads to a significant under prediction of the irreversibility rate.
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化学反应性非牛顿流体流经具有活化能影响的垂直微通道:数值研究
这项研究探讨了在微通道中嵌入多孔介质的导电反应性第三级流体流动的第二定律分析,以及可变热导率、活化能、粘性耗散、焦耳热和辐射热通量的影响。在控制方程中加入一个合适的非维度变量,将其转化为一个无维度的方程组。然后使用 Runge Kutta Felhberg 4 阶和 5 阶(RKF-45)方法,结合射击方法处理所获得的方程。通过与当前结果的比较,数值结果得到了验证,两者具有良好的一致性。从目前的结果来看,粘性加热约束、可变热导率、Frank Kameneski、热源比参数和三级流体材料约束下的熵生成是最高的。活化能和弗兰克-卡缅斯基约束条件的数值越大,贝扬数就越大,而三级材料参数和粘性加热参数越大,贝扬数就越小。在磁力作用下,流体的速度会因阻力而减慢。对于较大的第三级流体、活化能参数和弗兰克-卡门尼斯基参数,通道对速度的影响类似,而对于可变热导率和渗透率参数,则呈上升趋势。此外,研究还发现,通道板中的可变导热系数假设导致对不可逆速率的预测严重不足。
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来源期刊
Advances in Mechanical Engineering
Advances in Mechanical Engineering Engineering-Mechanical Engineering
自引率
4.80%
发文量
353
期刊介绍: Advances in Mechanical Engineering (AIME) is a JCR Ranked, peer-reviewed, open access journal which publishes a wide range of original research and review articles. The journal Editorial Board welcomes manuscripts in both fundamental and applied research areas, and encourages submissions which contribute novel and innovative insights to the field of mechanical engineering
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