卡塔尼奥-克里斯托夫模型对拉伸片上混合纳米流体流动中传热和传质的磁流体动力学效应

Q2 Mathematics CFD Letters Pub Date : 2023-11-30 DOI:10.37934/cfdl.16.2.105117
D. Ramesh, M. Mohan Babu, G Balaji Prakash, K. Jhansi Rani, J. Peter Praveen, G. V. R. Reddy
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引用次数: 0

摘要

本研究揭示了威廉姆森混合纳米流体对多孔拉伸片上 "传热和传质流 "的 MHD 数值模拟。该模型使用了 Cattaneo-Christov 热通量和质量通量。这种情况的基本物理原理是通过控制方程来模拟的。通过适当的相似性转换,这些方程被转换成常微分方程系统。方法/途径:使用 MATLAB 软件和 BVC4C 工具对问题进行数值求解。研究结果表明,虽然提高质量弛豫通量会增加浓度分布,但同时也会增加温度分布。研究还测量了热辐射、发热量以及改善温度和速度分布的附加值--埃克特数。主要发现:由于施加了电磁力,较高的磁场值会导致速度分布增加。此外,热辐射参数的上升也会扩大速度和温度的分布。天体物理学、地球物理学、生物科学和生物医学工程学都对本研究有帮助。本研究的结果总体上得到了文献的充分支持。
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Magneto-Hydrodynamic Effects on Heat and Mass Transfer in Hybrid Nanofluid Flow over A Stretched Sheet with Cattaneo-Christov Model
This study uncovered a numerical simulation of the Williamson hybrid nanofluid's MHD on “heat and mass transfer flow” over a porous stretched sheet. The model made use of Cattaneo-Christov heat and mass fluxes. The situation's underlying physics is modelled using governing equations. Using an appropriate similarity transformation, these equations were transformed into a system of ordinary differential equations. Methodology/Approach: MATLAB software along with BVC4C tool is used to find the numerical solution of the problem. The study's findings show that while boosting the mass relaxation flux increases concentration distributions, doing so also increases temperature distributions. Thermal radiation, heat generation, and an additional value to improve temperature and velocity distributions, the Eckert number was measured. Major findings: Higher magnetic field values are shown to result in an increase in the velocity distribution because of the applied electromagnetic force. Additionally, a rise in the thermal radiation parameter is seen to broaden the distributions of velocity and temperature. Astrophysics, geophysics, biological sciences, and biomedical engineering are all helpful to this study. The findings of this study are generally well supported by the literature.
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来源期刊
CFD Letters
CFD Letters Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
3.40
自引率
0.00%
发文量
76
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