卡塔尼奥-克里斯托夫热通量理论和对流热传输对麦克斯韦纳米流体流动的意义

Muhammad Shoaib Kamran, Muhammad Irfan, Muavia Mansoor, Taseer Muhammad, Qazi Mahmood Ul‐Hassan
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摘要

最近,纳米流体,即混合了悬浮纳米颗粒(如碳纳米管、金属和金属氧化物)的流体溶液,已成为传统冷却剂的一种有利替代品。由于纳米流体具有出色的导热性能,因此被广泛应用于电池驱动鼓、热电生产商和太阳能领域。在能量分散流体中悬浮少量固体成分可提高其导热性能,并提供了一种经济而有效的方法来显著提高其热传导性能。此外,将纳米流体添加到许多工程和机械设备中也是纳米流体的用途之一,例如电气设备保护、热交换器和化学反应。本文旨在通过考虑化学反应和热沉/热源来阐述麦克斯韦纳米流体的流动。数学结构是在存在布朗运动和热泳效应的情况下建立的。此外,还考虑了非傅里叶热流的显著方面以及对流条件下的传输现象。相似性改变将偏微分方程 (PDE) 变为常微分方程 (ODE)。得到的 ODE 表达式通过 bvp4c 方法进行数值求解。图形草图显示了速度麦克斯韦因子的下降行为;然而,布朗因子和热泳因子也受到了同样的影响。此外,施密特因子和化学反应因子也会降低麦克斯韦纳米流体的浓度场。
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Significance of Cattaneo–Christov heat flux theory and convective heat transport on Maxwell nanofluid flow
Recently, nanofluids, which are solutions of fluids mixed with suspended nano‐particles, for instance, carbon nanotubes, metals, and metal oxides, have become a favorable alternative to conventional coolants. Caused by their outstanding thermal performance of conductivity, nanofluids are extensively used in battery‐operated drums, thermoelectric producers, and solar power. The suspension of minor solid components in energy dispersion fluids boosts their thermal enactment of conductivity and gives an economical and resourceful method to increase their transfer properties of heat significantly. Furthermore, additions of nanofluids to numerous engineering and mechanical matters, for instance, electrical kit conserving, heat exchangers, and chemical progressions, are uses of nanofluid. Here, the purpose of this work is to elaborate on the flow of Maxwell nanofluid by considering chemical reactions and heat sink/source. The mathematical structure is established with the presence of Brownian movement and thermophoresis effects. The remarkable aspects of non‐Fourier heat flux are also considered with the transport phenomenon of convective conditions. The similarity alterations change the partial differential equations (PDEs) into ordinary differential equations (ODEs). The obtained expressions of ODEs are solved numerically via the bvp4c approach. The graphical sketches display the declining behavior of Maxwell factor for velocity; however, the same impacts are examined for Brownian and thermophoresis factors. Furthermore, Schmidt and chemical reaction factors decline the concentration field of Maxwell nanofluid.
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