带有内部加热多孔介质的矩形外壳中的对流：边界条件的影响

IF 1.4 4区工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY

Journal of Engineering Mathematics Pub Date : 2024-01-12 DOI:10.1007/s10665-023-10324-0

Amit Mahajan, Madhvi Raj

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引用次数: 0

摘要

目前的工作重点是分析多孔结构内流体的稳定性，通过采用线性（法向模式技术）和非线性稳定性（能量）技术来考虑恒定的内部发热。此外，还探讨了不同边界约束条件（包括不透水、导电、多孔和绝缘）对稳定性的影响。治理方程被转化为由稳定性分析得出的特征值问题，该问题被转化为分离傅立叶分量的四阶问题，然后使用切比雪夫伪谱法进行数值求解，以找到临界瑞利数。结果发现，内部发热的存在会导致潜在的亚临界不稳定性。研究考虑了基于边界曲面的五个模型，并分析了内部加热的影响，结果表明，通过适当组合这些模型和发热参数值，可以增强稳定性或加速对流。同时还注意到，在没有内部加热的情况下，亚临界不稳定区域并不存在。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Convection in a rectangular enclosure with internally heated porous medium: impact of boundary conditions

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Convection in a rectangular enclosure with internally heated porous medium: impact of boundary conditions

The present work is focussed on analyzing the stability of fluid within the porous structure, accounting for constant internal heat generation by employing both linear (normal mode technique) and nonlinear stability (energy) techniques. The impact of diverse sets of boundary constraints, encompassing impermeable, conducting, porous, and insulating on the stability is also explored. The governing equations are transformed into an eigenvalue problem derived from stability analysis, which is transformed into a fourth-order problem on separating Fourier component and then numerically solved using the Chebyshev pseudospectral method for finding the critical Rayleigh numbers. It is found that the presence internal heat generation gives rise to the potential of subcritical instability. Five models are considered based on bounding surfaces and the impact of internal heating is analysed which suggest that the stability can be enhanced or convection can be accelerated by taking appropriate combination of these models and values of heat generation parameter. It is also noted that in the absence of internal heating the subcritical region of instability does not exist.

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来源期刊

Journal of Engineering Mathematics 工程技术-工程：综合

CiteScore

2.10

自引率

7.70%

发文量

审稿时长

6 months

期刊介绍： The aim of this journal is to promote the application of mathematics to problems from engineering and the applied sciences. It also aims to emphasize the intrinsic unity, through mathematics, of the fundamental problems of applied and engineering science. The scope of the journal includes the following: • Mathematics: Ordinary and partial differential equations, Integral equations, Asymptotics, Variational and functional−analytic methods, Numerical analysis, Computational methods. • Applied Fields: Continuum mechanics, Stability theory, Wave propagation, Diffusion, Heat and mass transfer, Free−boundary problems; Fluid mechanics: Aero− and hydrodynamics, Boundary layers, Shock waves, Fluid machinery, Fluid−structure interactions, Convection, Combustion, Acoustics, Multi−phase flows, Transition and turbulence, Creeping flow, Rheology, Porous−media flows, Ocean engineering, Atmospheric engineering, Non-Newtonian flows, Ship hydrodynamics; Solid mechanics: Elasticity, Classical mechanics, Nonlinear mechanics, Vibrations, Plates and shells, Fracture mechanics; Biomedical engineering, Geophysical engineering, Reaction−diffusion problems; and related areas. The Journal also publishes occasional invited ''Perspectives'' articles by distinguished researchers reviewing and bringing their authoritative overview to recent developments in topics of current interest in their area of expertise. Authors wishing to suggest topics for such articles should contact the Editors-in-Chief directly. Prospective authors are encouraged to consult recent issues of the journal in order to judge whether or not their manuscript is consistent with the style and content of published papers.