Non-Fourier computations of heat and mass transport in nanoscale solid-fluid interactions using the Galerkin finite element method

IF 4 3区 工程技术 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS
Abdulaziz Alsenafi, Fares Alazemi, M. Nawaz
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引用次数: 0

Abstract

Purpose

To improve the thermal performance of base fluid, nanoparticles of three types are dispersed in the base fluid. A novel theory of non-Fourier heat transfer is used for design and development of models. The thermal performance of sample fluids is compared to determine which types of combination of nanoparticles are the best for an optimized enhancement in thermal performance of fluids. This article aims to: (i) investigate the impact of nanoparticles on thermal performance; and (ii) implement the Galerkin finite element method (GFEM) to thermal problems.

Design/methodology/approach

The mathematical models are developed using novel non-Fourier heat flux theory, conservation laws of computational fluid dynamics (CFD) and no-slip thermal boundary conditions. The models are approximated using thermal boundary layer approximations, and transformed models are solved numerically using GFEM. A grid-sensitivity test is performed. The accuracy, correction and stability of solutions is ensured. The numerical method adopted for the calculations is validated with published data. Quantities of engineering interest, i.e. wall shear stress, wall mass flow rate and wall heat flux, are calculated and examined versus emerging rheological parameters and thermal relaxation time.

Findings

The thermal relaxation time measures the ability of a fluid to restore its original thermal state, called thermal equilibrium and therefore, simulations have shown that the thermal relaxation time associated with a mono nanofluid has the most substantial effect on the temperature of fluid, whereas a ternary nanofluid has the smallest thermal relaxation time. A ternary nanofluid has a wider thermal boundary thickness in comparison with base and di- and mono nanofluids. The wall heat flux (in the case of the ternary nanofluids) has the most significant value compared with the wall shear stresses for the mono and hybrid nanofluids. The wall heat and mass fluxes have the highest values for the case of non-Fourier heat and mass diffusion compared to the case of Fourier heat and mass transfer.

Originality/value

An extensive literature review reveals that no study has considered thermal and concentration memory effects on transport mechanisms in fluids of cross-rheological liquid using novel theory of heat and mass [presented by Cattaneo (Cattaneo, 1958) and Christov (Christov, 2009)] so far. Moreover, the finite element method for coupled and nonlinear CFD problems has not been implemented so far. To the best of the authors’ knowledge for the first time, the dynamics of wall heat flow rate and mass flow rate under simultaneous effects of thermal and solute relaxation times, Ohmic dissipation and first-order chemical reactions are studied.

利用伽勒金有限元法对纳米级固液相互作用中的热量和质量传输进行非傅里叶计算
目的 为改善基础流体的热性能,在基础流体中分散了三种类型的纳米粒子。设计和开发模型时采用了非傅里叶传热的新理论。通过比较样本流体的热性能,确定哪种类型的纳米粒子组合最适合优化增强流体的热性能。本文旨在:(i) 研究纳米颗粒对热性能的影响;(ii) 将 Galerkin 有限元方法 (GFEM) 应用于热问题。设计/方法/途径采用新颖的非傅里叶热通量理论、计算流体动力学 (CFD) 守恒定律和无滑动热边界条件开发数学模型。模型使用热边界层近似值进行近似,并使用 GFEM 对转换后的模型进行数值求解。进行了网格敏感性测试。确保了求解的准确性、修正性和稳定性。计算所采用的数值方法与已公布的数据进行了验证。模拟结果表明,单纳米流体的热弛豫时间对流体温度的影响最大,而三元纳米流体的热弛豫时间最小。与基纳米流体、二元纳米流体和单元纳米流体相比,三元纳米流体的热边界厚度更宽。与单纳米流体和混合纳米流体的壁面剪应力相比,三元纳米流体的壁面热通量最为显著。与傅里叶传热和传质相比,非傅里叶传热和质量扩散情况下的壁面热通量和质量通量具有最高值。 原创性/价值 大量文献综述显示,迄今为止,还没有任何研究使用新颖的热量和质量理论(由 Cattaneo (Cattaneo, 1958) 和 Christov (Christov, 2009) 提出)考虑过热量和浓度记忆对跨流变液体流体中传输机制的影响。此外,迄今为止还没有针对耦合和非线性 CFD 问题的有限元方法。据作者所知,他们首次研究了在热弛豫和溶质弛豫时间、欧姆耗散和一阶化学反应的同时作用下,壁面热流率和质量流率的动态变化。
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来源期刊
CiteScore
9.50
自引率
11.90%
发文量
100
审稿时长
6-12 weeks
期刊介绍: The main objective of this international journal is to provide applied mathematicians, engineers and scientists engaged in computer-aided design and research in computational heat transfer and fluid dynamics, whether in academic institutions of industry, with timely and accessible information on the development, refinement and application of computer-based numerical techniques for solving problems in heat and fluid flow. - See more at: http://emeraldgrouppublishing.com/products/journals/journals.htm?id=hff#sthash.Kf80GRt8.dpuf
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