Numerical analysis of thermal improvement in hydrogen‐based host fluids under buoyancy force and EPNM effects: Study for vertical cylinder

Adnan, W. Abbas, Aboulbaba Eladeb, L. Kolsi
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Abstract

The nanofluids became much of interest due to their superior heat mechanism over the conventional fluids. The addition of nanoparticles in the host solvent enhances the internal ability of the liquid to store and transmit heat. Therefore, these fluids are widely used in biomedical engineering, detergents, medication, applied thermal engineering, mechanical, and chemical engineering and so forth. Keeping in mind the significance of nanofluids, this study is conducted to investigate the comparative heat transmission in and under the Effective Prandtl Number Model (EPNM) effects over a vertical permeable cylinder. Formulation of the model is carried out over a vertical cylinder about the stagnation point and the heat transport model is achieved after the successful implementation of the cylindrical stream function, nanofluids effective characteristics, and cylindrical similarity equations. The mathematical treatment was done via RK technique and furnished the results. The nanofluids have the capacity to control the fluid motion more effectively than ordinary fluid and combined convection is better where rapid fluid movement is desired. In the existence of EPNM, higher heat transmission is achieved and is prominent for based on their thermophysical values. Further, the skin friction and Nusselt number are optimum for against .
浮力和 EPNM 效应下氢基主流体热改进的数值分析:垂直气缸研究
纳米流体因其优于传统流体的热机制而备受关注。在主溶剂中添加纳米粒子可增强液体内部储存和传递热量的能力。因此,这些液体被广泛应用于生物医学工程、洗涤剂、药物、应用热力工程、机械和化学工程等领域。考虑到纳米流体的重要性,本研究对垂直渗透圆柱体在有效普朗特数模型(EPNM)作用下的热传递进行了比较研究。模型的建立是在一个关于停滞点的垂直圆柱体上进行的,在成功实施圆柱流函数、纳米流体有效特性和圆柱相似性方程后,实现了热传输模型。数学处理是通过 RK 技术完成的,并得出了结果。与普通流体相比,纳米流体能更有效地控制流体运动,在需要流体快速运动时,联合对流效果更好。在 EPNM 存在的情况下,可以实现更高的热传导,这一点在其热物理值基础上表现得尤为突出。此外,表皮摩擦系数和努塞尔特数也是最佳值。
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