Flow of viscous nanofluids across a non-linear stretching sheet

IF 1.1 Q3 Engineering

Journal of Thermal Engineering Pub Date : 2023-05-17 DOI:10.18186/thermal.1332594

Pradyumna Kumar PATTNAIK, Shoeb Ahmed SYED, Sujogya MISHRA, Swarnalata JENA, Sachindar Kumar ROUT, Kamalakanta MUDULI

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引用次数: 0

Abstract

This article aims to demonstrate the flow of viscous nanofluid over a non-linear stretching sheet. Considering thermal radiation and dissipative heat in the heat transport phenomenon encourages the flow properties. In generally, nanofluids are employed in heat transfer equip-ment because they improve the thermal characteristics of coolants present in the equipment. Additionally, these fluids possess unique features that have the potential to be applied in a variety of applications, such as pharmaceutical procedures, hybrid power engines, household refrigerators, grinding, and microchips, among others. Consequently, the current model is built to allow for the optimal selection of thermophysical parameters such as conductivity and viscosity, which will enhance the overall effectiveness of the study. Appropriate transfor-mation rules have been used to modify the highly non-linear PDEs into a couple of highly non-linear ODEs. An efficient built-in MATLAB bvp5C algorithm addresses the boundary value problem under consideration. Using the dimensionless parameters assumed in the prob-lem, changes in the velocity as well as the temperature profiles are shown, and rate coefficients, by using numerical simulations are also employed in tabular form. The important outcomes which are exposed in the study are; that the particle concentration is used as a controlling pa-rameter to reduce the nanofluid velocity, whereas it favours enhancing the fluid temperature and the radiating heat along with the coupling parameter due to the inclusion of dissipative heat also encourages to overshoot the temperature profile.

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粘性纳米流体在非线性拉伸薄片上的流动

本文旨在演示粘性纳米流体在非线性拉伸片上的流动。考虑了热辐射和耗散热的传热现象，促进了流体的流动特性。一般来说，纳米流体被用于传热设备，因为它们改善了设备中存在的冷却剂的热特性。此外，这些流体具有独特的特性，具有应用于各种应用的潜力，例如制药程序、混合动力发动机、家用冰箱、研磨和微芯片等。因此，建立当前模型是为了允许热物性参数(如导电性和粘度)的最佳选择，这将提高研究的整体有效性。利用适当的转换规则将高度非线性的偏微分方程转化为一对高度非线性的偏微分方程。一种高效的内置MATLAB bvp5C算法解决了所考虑的边值问题。利用问题中假设的无量纲参数，给出了速度和温度的变化曲线，并通过数值模拟得到了速率系数的表格形式。研究中暴露的重要结果是;颗粒浓度作为控制参数，降低了纳米流体的速度，但由于包含了耗散热，它有利于提高流体温度和辐射热量以及耦合参数，也导致了温度曲线的超调。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Thermal Engineering THERMODYNAMICS-

CiteScore

2.40

自引率

18.20%

发文量

审稿时长

4 weeks

期刊介绍： Journal of Thermal Enginering is aimed at giving a recognized platform to students, researchers, research scholars, teachers, authors and other professionals in the field of research in Thermal Engineering subjects, to publish their original and current research work to a wide, international audience. In order to achieve this goal, we will have applied for SCI-Expanded Index in 2021 after having an Impact Factor in 2020. The aim of the journal, published on behalf of Yildiz Technical University in Istanbul-Turkey, is to not only include actual, original and applied studies prepared on the sciences of heat transfer and thermodynamics, and contribute to the literature of engineering sciences on the national and international areas but also help the development of Mechanical Engineering. Engineers and academicians from disciplines of Power Plant Engineering, Energy Engineering, Building Services Engineering, HVAC Engineering, Solar Engineering, Wind Engineering, Nanoengineering, surface engineering, thin film technologies, and Computer Aided Engineering will be expected to benefit from this journal’s outputs.