Ali Rehman, Mostafa Inc, F. Tawfiq, Muhammad Bilal
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引用次数: 0
Abstract
This study examines the effects of viscous dissipation, thermal radiation, nanofluid over a stretched surface, and viscous dissipation on a two-dimensional couple stress blood base for the enhancement of heat transfer rate. Gold and multiwall carbon nanotubes are two forms of nanoparticles that are taken into consideration, with blood serving as the base fluid. The NLPDE controls the considering problem. The NLPDE was converted to NODEs using the mentioned similarity transformation. The analytical method known as HAM was used to analyze the transform NODE analytically. Graphs are used to illustrate the effects of many parameters, such as magnetic factors, nanoparticle volume friction, velocity power index, PN, thermal radiation factors, and EN, which are derived from TE and VE. The current research work highlights how important it is to include viscous dissipation in nanofluid dynamics. The results show complex interactions among stretching, thermal properties, and micro-scale effects. The results may have an impact on the development and enhancement of biomedical devices and treatments that use nanofluidic systems, especially those that deal with blood.
本研究探讨了粘性耗散、热辐射、拉伸表面上的纳米流体以及粘性耗散对二维耦合应力血液基质的影响,以提高传热速率。金和多壁碳纳米管是考虑的两种纳米粒子形式,血液是基础流体。NLPDE 控制考虑的问题。使用上述相似性转换将 NLPDE 转换为 NODE。使用称为 HAM 的分析方法对转换后的 NODE 进行分析。用图表说明了许多参数的影响,如磁性因子、纳米粒子体积摩擦、速度功率指数、PN、热辐射因子和 EN,这些都是从 TE 和 VE 导出的。当前的研究工作凸显了将粘性耗散纳入纳米流体动力学的重要性。研究结果显示了拉伸、热特性和微尺度效应之间复杂的相互作用。这些结果可能会对使用纳米流体系统的生物医学设备和治疗方法的开发和改进产生影响,尤其是那些与血液有关的设备和治疗方法。
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