Construction of optimised theoretical model using ANOVA -Taguchi methodology for transient flow of Carreau nanofluid through microchannel prone to radiation

IF 6.2 2区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY
Pradeep Kumar , Felicita Almeida , Ajaykumar AR , Qasem Al-Mdallal
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Abstract

The current study intends to predict the optimised condition to attain the objective of acquiring highest heat transfer rate to develop an efficient model. The transient flow of Carreau nanofluid within a microchannel when channel walls are susceptible to radiation is contemplated. Buongiorno model is employed, which emphasizes the repercussions of Brownian motion and thermophoresis phenomena; also, mixed-convective flow is accounted. The modelled problem gives rise to partial differential equations, which are non-dimensionalized employing non-dimensional quantities. The resultant equations are solved numerically using the finite difference method. Results of analysis demonstrate that the Weissenberg number for n<1 depicts shear thinning nature, and for n>1, depicts shear thickening nature, decreasing velocity. The skin friction coefficient increases when solutal Grashof number rises for the high range of the Reynolds number. The Sherwood number increases when Schmidt number is less for increased value of Reynolds number. Optimization method reveals the highest heat transfer rate of 7.3687 for the considered model. ANOVA results show that the manipulation of Reynolds number is crucial with 57.29% impact and the manipulation of Prandtl number has minor impact of 1.41%on Nusselt number. Shear thinning nature of Carreau fluid finds its application in extrudability, printability and injectability and shear thickening nature is extensively used in industrial polishing, explosion resistance.
利用方差分析--塔口方法构建易受辐射影响的微通道中卡里奥纳米流体瞬态流动的优化理论模型
目前的研究旨在预测优化条件,以实现获得最高传热率的目标,从而开发出一种有效的模型。研究考虑了当通道壁易受辐射影响时,Carreau 纳米流体在微通道内的瞬态流动。采用的 Buongiorno 模型强调了布朗运动和热泳现象的影响,并考虑了混合对流。建模问题产生了偏微分方程,这些方程采用了非尺寸量进行非尺寸化。使用有限差分法对结果方程进行数值求解。分析结果表明,韦森伯格数 n<1 表示剪切变薄,n>1 表示剪切变厚,速度减小。在高雷诺数范围内,当溶质格拉肖夫数升高时,表皮摩擦系数增大。当雷诺数增加时,施密特数降低,谢伍德数增加。优化方法显示,所考虑模型的最高传热率为 7.3687。方差分析结果表明,雷诺数的调节对努塞尔特数的影响最大,为 57.29%,而普朗特数的调节对努塞尔特数的影响较小,仅为 1.41%。Carreau 流体的剪切稀化特性可用于挤出、印刷和注射,而剪切增稠特性则可广泛用于工业抛光和防爆。
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来源期刊
alexandria engineering journal
alexandria engineering journal Engineering-General Engineering
CiteScore
11.20
自引率
4.40%
发文量
1015
审稿时长
43 days
期刊介绍: Alexandria Engineering Journal is an international journal devoted to publishing high quality papers in the field of engineering and applied science. Alexandria Engineering Journal is cited in the Engineering Information Services (EIS) and the Chemical Abstracts (CA). The papers published in Alexandria Engineering Journal are grouped into five sections, according to the following classification: • Mechanical, Production, Marine and Textile Engineering • Electrical Engineering, Computer Science and Nuclear Engineering • Civil and Architecture Engineering • Chemical Engineering and Applied Sciences • Environmental Engineering
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