具有变黏度和变电导率的非对称通道传热和蠕动流动的数值研究

IF 1.4 4区工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY

Scientia Iranica Pub Date : 2023-10-09 DOI:10.24200/sci.2023.60404.6783

Jamil Abbas Haider, Sana Gul, Sohail Nadeem

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引用次数: 0

摘要

纳米流体的蠕动流动是流体动力学中一个日益受到关注的话题。本研究探讨了温度依赖性粘度和电导率对纳米流体蠕动流动的影响。利用牛顿流体的连续性、动量和能量控制方程，建立了蠕动流动的数学模型。采用大波长和小雷诺数假设来研究蠕动流动，简化了连续性、动量和能量方程。本文假设纳米流体具有导电性和温度依赖性，研究了哈特曼数和埃克特数对纳米流体性能的影响。用射击法求解得到的方程。结果表明，黏度和电导率随温度的变化对纳米流体的蠕动流动有显著影响。随着粘度和电导率的增加，流速和压力梯度减小，而温度和换热速率增大。此外，纳米流体的浓度和粒径对流动特性有显著影响。综上所述，本研究全面分析了具有温度依赖性粘度和电导率的纳米流体的蠕动流动。研究结果有助于理解纳米流体在各种应用中的行为，如药物输送系统、微流体和热管理。

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Numerical Investigation of the Heat Transfer and Peristaltic Flow Through a Asymmetric Channel Having Variable Viscosity and Electric Conductivity

The peristaltic flow of nanofluids is a topic of growing interest in fluid dynamics. This study investigates the effect of temperature-dependent viscosity and electric conductivity on the peristaltic flow of nanofluids. The mathematical model of the peristaltic flow is developed using the governing equations of continuity, momentum, and energy for a Newtonian fluid. Large wavelength and small Reynolds number assumptions are used to study peristaltic flow to simplify the equations of continuity, momentum, and energy. In this article, the nanofluids are assumed to be electrically conducting and temperature dependent, and the effects of Hartman number and Eckert number is studied. The resulting equations are solved using the Shooting Method. The results show that the temperature-dependent viscosity and electric conductivity significantly affect the peristaltic flow of nanofluids. The flow rate and pressure gradient decrease with increasing viscosity and conductivity while the temperature and heat transfer rate increase. Moreover, the nanofluid concentration and particle size significantly impact the flow characteristics. In conclusion, this study comprehensively analyses the peristaltic flow of nanofluids with temperature-dependent viscosity and electric conductivity. The results can be useful for understanding the behaviour of nanofluids in various applications, such as drug delivery systems, microfluidics, and thermal management.

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来源期刊

Scientia Iranica 工程技术-工程：综合

CiteScore

2.90

自引率

7.10%

发文量

审稿时长

2 months

期刊介绍： The objectives of Scientia Iranica are two-fold. The first is to provide a forum for the presentation of original works by scientists and engineers from around the world. The second is to open an effective channel to enhance the level of communication between scientists and engineers and the exchange of state-of-the-art research and ideas. The scope of the journal is broad and multidisciplinary in technical sciences and engineering. It encompasses theoretical and experimental research. Specific areas include but not limited to chemistry, chemical engineering, civil engineering, control and computer engineering, electrical engineering, material, manufacturing and industrial management, mathematics, mechanical engineering, nuclear engineering, petroleum engineering, physics, nanotechnology.