阿伦尼乌斯活化能对热辐射威廉姆森纳米流体在粘性耗散的透气拉伸片上流动的影响

Swarna Jannapura Bhaskar Acharya, Bommanna Lavanya, Kolli Vijaya, Manikandan Murugiah
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摘要

本文探讨了威廉姆森纳米流体在可渗透拉伸片上流动时的粘性耗散、阿伦尼乌斯活化能和热辐射的作用。通过转换过程简化了控制偏微分方程,得到一组非线性微分方程。为了找到这些方程的解,采用了数值方法,特别是四阶 Runge-Kutta 方法。此外,还采用了射击技术来提高数值解的精确度。总之,这项研究涉及将复杂方程还原,进行数值求解,并通过各种方法的组合来完善结果。研究调查了不同物理参数对速度、温度、表皮摩擦系数、纳米颗粒体积分数以及传质和传热速率等关键因素的影响。这项研究表明,活化能参数会增强浓度曲线,而拟合速率常数则表现出相反的行为。将活化能纳入传热模型可以优化利用威廉姆森纳米流体的传热系统。
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Effects of Arrhenius Activation Energy on Thermally Radiant Williamson Nanofluid Flow Over a Permeable Stretching Sheet with Viscous Dissipation
This paper explores the role of viscous dissipation, Arrhenius activation energy, and thermal radiation of Williamson nanofluid flow over a permeable stretching sheet. The governing partial differential equations have been simplified through a transformation process, resulting in a set of non-linear differential equations. To find a solution for these equations, a numerical approach is employed, specifically the fourth order Runge-Kutta method. Additionally, a shooting technique is utilized to enhance the accuracy of the numerical solutions. Overall, the study involves reducing complex equations, solving them numerically, and refining the results through a combination of methods. The study investigates the impact of different physical parameters on key factors like velocity, temperature, skin friction coefficient, nano particle volume fraction, and rates of mass and heat transfer. This study exhibits that activation energy parameter enhances concentration profiles, whereas fitted rate constant shows opposite behavior. The activation energy into heat transfer model allows for the optimization of heat transfer systems utilizing Williamson nano fluids.
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来源期刊
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
2.40
自引率
0.00%
发文量
176
期刊介绍: This journal welcomes high-quality original contributions on experimental, computational, and physical aspects of fluid mechanics and thermal sciences relevant to engineering or the environment, multiphase and microscale flows, microscale electronic and mechanical systems; medical and biological systems; and thermal and flow control in both the internal and external environment.
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