Parametric studies of mixed convective fluid flow around cylinders of different cross-sections期刊界 All Journals 搜尽天下杂志传播学术成果专业期刊搜索期刊信息化学术搜索

Parametric studies of mixed convective fluid flow around cylinders of different cross-sections

Authors:	Olalekan Adebayo Olayemi Adebowale Martins Obalalu Segun Emmanuel Ibitoye Khaled Al-Farhany Temidayo Samsudeen Jolayemi Abdulbaqi Jinadu Tomisin Favour Ajide Isaac Kayode Adegun

Affiliation:	1. Department of Aeronautics and Astronautics, Faculty of Engineering and Technology, Kwara State University, Malete, Kwara State, Nigeria;2. Department of Mathematical Sciences, Augustine University, Ilara-Epe, Lagos State, Nigeria;3. Department of Mechanical Engineering, Faculty Engineering and Technology, University of Ilorin, Ilorin, Kwara State, Nigeria;4. Department of Mechanical Engineering, University of Al-Qadisiyah, Al-Qadisiyah, Iraq

Abstract:	A numerical study of mixed convective heat transfer in a lid-driven square enclosure containing a hot elliptic cylinder is conducted. The impacts of the Grashof number $(10^{3} \leq Gr \leq 1 0^{6}) $({10}^{3}\le {Gr}\le 1{0}^{6})$$ , Reynolds number $(1.0 \leq R e \leq 100) $(1.0\le Re\le 100)$$ , cylinder tilt angle $(0^{°} \leq ? \leq 90^{°}) $({0}^{^\circ }\le \phi \le {90}^{^\circ })$$ , and aspect ratio $(1.0 \leq A R \leq 3.0) $(1.0\le AR\le 3.0)$$ have been examined for a fluid of $P r $Pr$$ of 0.71. The horizontal enclosure walls are insulated, while its vertical walls are restricted to a nonvarying temperature T_c, whereas a sinusoidal temperature of $T_{h} + ? T \sin (π x / L) ${T}_{h}+\unicode{x02206}T\unicode{x0200A}\sin (\pi x/L)$$ is imposed on the wall of the elliptical cylinder. The governing equations are solved using COMSOL Multiphysics 5.6 software. The fluid dynamic and the heat transport profiles between the enclosure and the elliptical cylinder walls are represented by the stream function, isothermal contours, and average Nusselt number. Results established that for all the considered aspect ratios, the thermal heating range of $10^{3} \leq Gr \leq 1 0^{4} ${10}^{3}\le {Gr}\le 1{0}^{4}$$ is predominantly a conduction mechanism. The critical position of the ellipse where the inclination effect becomes insignificant is determined by the Grashof number and aspect ratio when the Re = 100. The strength of vortices and cell numbers are significantly influenced by the aspect ratio, particularly when the $Gr = 1 0^{4} ${Gr}=1{0}^{4}$$ . When $A R = 1.0 $AR=1.0$$ , the average heat transfer from the cylinder remains the same regardless of the cylinder's orientation. The impact of cylinder orientation on heat transfer from the cylinder wall is minimal for $1.5 \leq A R \leq 2.0 $1.5\le AR\le \phantom{\rule{}{0ex}}2.0$$ . For AR values of $2.5 \leq A R \leq 3.0 $2.5\le AR\le \phantom{\rule{}{0ex}}3.0$$ , increasing the inclination angle does not result in improved heat transfer. The influence of the increasing inclination angle on the right wall diminishes as the angle increases, except when the Grashof number is greater than 10⁵, where the rate of heat transfer is enhanced for inclination angles beyond 45°.

Keywords:	aspect ratio geometric parameters lid-driven mixed convective heat transfer

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