Stability Analysis of Mixed Convection of Nanofluid Flow Through a Horizontal Porous Channel Using LTNE Model

IF 1.3 4区 工程技术 Q2 ENGINEERING, AEROSPACE
Harsha S V, Chandra Shekara G, Hemanth Kumar C, Mayur D H
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Abstract

The present article investigates the stability of the mixed convective flow of nanofluids through a horizontal porous channel under the influence of a constant pressure gradient, utilizing the local thermal nonequilibrium (LTNE) model. The governing equations are derived by integrating the Oberbeck-Boussinesq theory with the Darcy model for low-permeability porous media. Using linear stability theory, we formulate a generalized eigenvalue problem (GEP) in terms of non-dimensional parameters. The weighted residual Galerkin method (WRGM) is then employed to solve the GEP, and the results are compared analytically. The findings of this study reveal that a horizontal pressure gradient initiates convection in an oscillatory mode rather than a stationary one. We identify that the interphase scaled heat transfer coefficient, thermal diffusivity ratio, nanoparticle volume fraction, and horizontal pressure gradient collectively influence the onset of oscillatory convection. Notably, our investigation into Titanium Oxide (TiO2), Copper Oxide (CuO), and Aluminum Oxide (Al2O3) nanoparticles reveals that TiO2 particles enhance the onset of convection compared to Al2O3 and CuO, while CuO nanoparticles exhibit greater thermal stability. Further, the nonlinear stability analysis is performed using the method of lines in conjunction with regularization and finite difference schemes for spatial derivatives. The time evolution of all field variables is simulated through the visualization of streamlines and isotherms, providing a detailed representation of the system's dynamics. Additionally, the critical values of the Darcy-Rayleigh number are computed and compared for both linear and nonlinear stability analyses. The results demonstrate the equivalence of linear instability and nonlinear stability boundaries in the absence of a constant pressure gradient, whereas subcritical instability becomes apparent in its presence. These insights advance our understanding of mixed convective flows in porous media, with potential implications for various engineering and environmental applications.

Abstract Image

利用 LTNE 模型对纳米流体流经水平多孔通道的混合对流进行稳定性分析
本文利用局部热非平衡(LTNE)模型,研究了纳米流体在恒定压力梯度影响下通过水平多孔通道的混合对流的稳定性。通过将 Oberbeck-Boussinesq 理论与低渗透多孔介质的达西模型进行整合,得出了控制方程。利用线性稳定性理论,我们用非维参数提出了广义特征值问题(GEP)。然后采用加权残差 Galerkin 法(WRGM)求解 GEP,并对结果进行了分析比较。研究结果表明,水平压力梯度以振荡模式而非静止模式引发对流。我们发现,相间比例传热系数、热扩散率、纳米颗粒体积分数和水平压力梯度共同影响着振荡对流的发生。值得注意的是,我们对氧化钛(TiO2)、氧化铜(CuO)和氧化铝(Al2O3)纳米粒子的研究表明,与 Al2O3 和 CuO 相比,TiO2 粒子能增强对流的发生,而 CuO 纳米粒子则表现出更高的热稳定性。此外,非线性稳定性分析采用了线性方法,并结合了正则化和空间导数有限差分方案。通过流线和等温线的可视化模拟了所有场变量的时间演化,提供了系统动态的详细表示。此外,还计算了达西-雷利数的临界值,并对线性和非线性稳定性分析进行了比较。结果表明,在没有恒定压力梯度的情况下,线性不稳定性和非线性稳定性边界是等同的,而在有恒定压力梯度的情况下,亚临界不稳定性则变得明显。这些见解加深了我们对多孔介质中混合对流的理解,对各种工程和环境应用具有潜在影响。
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来源期刊
Microgravity Science and Technology
Microgravity Science and Technology 工程技术-工程:宇航
CiteScore
3.50
自引率
44.40%
发文量
96
期刊介绍: Microgravity Science and Technology – An International Journal for Microgravity and Space Exploration Related Research is a is a peer-reviewed scientific journal concerned with all topics, experimental as well as theoretical, related to research carried out under conditions of altered gravity. Microgravity Science and Technology publishes papers dealing with studies performed on and prepared for platforms that provide real microgravity conditions (such as drop towers, parabolic flights, sounding rockets, reentry capsules and orbiting platforms), and on ground-based facilities aiming to simulate microgravity conditions on earth (such as levitrons, clinostats, random positioning machines, bed rest facilities, and micro-scale or neutral buoyancy facilities) or providing artificial gravity conditions (such as centrifuges). Data from preparatory tests, hardware and instrumentation developments, lessons learnt as well as theoretical gravity-related considerations are welcome. Included science disciplines with gravity-related topics are: − materials science − fluid mechanics − process engineering − physics − chemistry − heat and mass transfer − gravitational biology − radiation biology − exobiology and astrobiology − human physiology
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