Scrutinization of Solar Thermal Energy and Variable Thermophysical Properties Effects on Non-Newtonian Nanofluid Flow

IF 0.8 Q3 ENGINEERING, MULTIDISCIPLINARY

International Journal of Engineering Research in Africa Pub Date : 2023-06-19 DOI:10.4028/p-s60w3k

A. Obalalu, O. Olayemi, Salawu Olakunle, Christopher Bode Odetunde

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引用次数: 1

Abstract

Nanofluids generate high values of convection heat transfer coefficients, low specific heat, and density, which improve the solar thermal energy performance by making it work effectively. By utilizing nanotechnology and solar thermal radiation, the modern world is moving in the direction of new technologies. Therefore, this research is communicated to explore the significance of solar thermal energy, variable properties on non-Newtonian nanofluid flow. However, to exemplify the fluid transport features of the Casson nanofluid (CF), the Buongiorno nanofluid model was utilized. Also, the Lie-group technique is used in the framework to develop similarity variables that will be used to reduce the number of independent variables in partial differential equations (PDEs) and is solved numerically by using the weighted residual Galerkin method (WRGM). The graphical findings revealed that when the variable viscosity parameter is increased, the fluid temperature decreases, while the presence of the solar radiation parameter has the opposite impact. Additionally, when the non-Newtonian parameter approaches infinity, the Casson fluid obeys the viscosity law. The report of this study will be of benefit to thermal and chemical engineering for nanotechnology advancement. KEYWORD: Solar Thermal Energy, Nanofluids, Non-Newtonian, weighted residual Galerkin method (WRGM).

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太阳热能的精细化和变热物理性质对非牛顿纳米流体流动的影响

纳米流体产生高值的对流传热系数、低比热和密度，通过使其有效工作来提高太阳能的性能。通过利用纳米技术和太阳热辐射，现代世界正朝着新技术的方向发展。因此，本研究旨在探讨太阳能热能、变特性对非牛顿纳米流体流动的意义。然而，为了举例说明Casson纳米流体（CF）的流体传输特征，使用了Buongiorno纳米流体模型。此外，在该框架中使用李群技术来开发相似变量，这些相似变量将用于减少偏微分方程（PDE）中自变量的数量，并通过使用加权残差伽辽金方法（WRGM）进行数值求解。图形研究结果表明，当可变粘度参数增加时，流体温度降低，而太阳辐射参数的存在则产生相反的影响。此外，当非牛顿参数接近无穷大时，Casson流体服从粘度定律。这项研究的报告将有利于热能和化学工程促进纳米技术的发展。关键词：太阳能，纳米流体，非牛顿，加权残差伽辽金法。

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来源期刊

International Journal of Engineering Research in Africa ENGINEERING, MULTIDISCIPLINARY-

CiteScore

1.80

自引率

14.30%

发文量

期刊介绍： "International Journal of Engineering Research in Africa" is a peer-reviewed journal which is devoted to the publication of original scientific articles on research and development of engineering systems carried out in Africa and worldwide. We publish stand-alone papers by individual authors. The articles should be related to theoretical research or be based on practical study. Articles which are not from Africa should have the potential of contributing to its progress and development.