Mixed Convection of Cu–H2O Nanofluid in a Darcy–Forchheimer Porous Medium Microchannel with Thermal Radiation and Convective Heating

IF 2.7 Q3 NANOSCIENCE & NANOTECHNOLOGY
Ebba Hindebu Rikitu, O. Makinde
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Abstract

Heat transfer and convective flow of Cu–H2O nanofluid in a microchannel with thermal radiation has many attributes in engineering, industries, and biomedical sciences including cooling of electronics, drug delivery, cancer therapy, optics, missiles, satellites, and lubricants. Therefore, this paper aims to investigate the hydrodynamical behaviors and heat transfer characteristics of Cu–H2O nanofluid through a porous medium microchannel with thermal radiation and convective heating. The highly non-linear partial differential equations that govern the momentum and energy equations are formulated, non-dimensionalized, transformed into ordinary differential equations and solved numerically via the fourth order Runge-Kutta integration scheme. Consequently, the numerical simulation reveals that the nanofluid velocity and temperature profiles show a rising pattern with increasing values of the pressure gradient parameter, variable viscosity parameter, Darcy number, thermal Grashof number and Eckert number. The temperature profile escalates with the Prandtl number however it diminishes with the Biot number, Forchheimer number, suction/injection Reynolds number and nanoparticles volume fraction. Furthermore, the thermal radiation parameter indicates a retarding effect on the temperature profile and hence, radiation quite effectively controls the microchannel temperature distribution which plays a significant role in cooling the flow transport system. The skin friction coefficient at both microchannel walls indicates a rising pattern with the suction/injection Reynolds number, thermal Grashof number, Eckert number and Darcy number. Moreover, at both microchannel walls the heat transfer rate enhances for large values of the suction/injection Reynolds number, thermal Grashof number, Eckert number, variable viscosity parameter and Darcy number whereas it decreases with the thermal radiation parameter, Forchheimer number and nanoparticles volume fraction. The Biot number reveals an opposite effect on the heat transfer rate at the left and right walls of the microvhannel.
达西-福克海默多孔介质微通道中的 Cu-H2O 纳米流体与热辐射和对流加热的混合对流
具有热辐射的微通道中 Cu-H2O 纳米流体的传热和对流在工程、工业和生物医学科学中具有许多特性,包括电子设备冷却、药物输送、癌症治疗、光学、导弹、卫星和润滑剂。因此,本文旨在研究通过多孔介质微通道的 Cu-H2O 纳米流体在热辐射和对流加热条件下的流体力学行为和传热特性。本文提出了支配动量和能量方程的高度非线性偏微分方程,并将其非量纲化,转化为常微分方程,通过四阶 Runge-Kutta 积分方案进行数值求解。数值模拟结果表明,随着压力梯度参数、可变粘度参数、达西数、热格拉肖夫数和埃克特数值的增加,纳米流体的速度和温度曲线呈上升趋势。温度曲线随着普朗特数的增加而上升,但随着比奥特数、福希海默尔数、吸入/喷射雷诺数和纳米颗粒体积分数的增加而下降。此外,热辐射参数显示出对温度曲线的延缓作用,因此辐射能有效控制微通道的温度分布,这对冷却流动传输系统起着重要作用。两个微通道壁上的表皮摩擦系数随着吸入/喷射雷诺数、热格拉肖夫数、埃克特数和达西数的增加而上升。此外,在两个微通道壁上,当吸入/注入雷诺数、热格拉肖夫数、埃克特数、可变粘度参数和达西数的数值较大时,热传导率会提高,而当热辐射参数、福克海默数和纳米颗粒体积分数较大时,热传导率会降低。比奥特数对微通道左壁和右壁的传热速率有相反的影响。
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来源期刊
Journal of Nanofluids
Journal of Nanofluids NANOSCIENCE & NANOTECHNOLOGY-
自引率
14.60%
发文量
89
期刊介绍: Journal of Nanofluids (JON) is an international multidisciplinary peer-reviewed journal covering a wide range of research topics in the field of nanofluids and fluid science. It is an ideal and unique reference source for scientists and engineers working in this important and emerging research field of science, engineering and technology. The journal publishes full research papers, review articles with author''s photo and short biography, and communications of important new findings encompassing the fundamental and applied research in all aspects of science and engineering of nanofluids and fluid science related developing technologies.
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