Numerical modeling of Buongiorno’s nanofluid on free convection: thermophoresis and Brownian effects

IF 1.2 Q3 ENGINEERING, MARINE

Journal of Naval Architecture and Marine Engineering Pub Date : 2021-12-31 DOI:10.3329/jname.v18i2.54694

Shatay Khatun, R. Nasrin

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引用次数: 7

Abstract

In this research, numerical modeling is conducted on free convective flow inside a trapezoidal domain with sinusoidal material and temperature allocations at both inclined boundaries using Buongiorno’s nanofluid. The model considers thermophoresis with Brownian activity effects taking place in the flow, temperature as well as concentration contours. Non-uniform nanoparticle solid concentration and temperature allocations have been imposed at both inclined surfaces. Top and bottom parallel surfaces have been kept as adiabatic. All the walls have been considered as no-slip and impermeable. The leading equations in addition border conditions are initially converted into a dimensionless pattern by a suitable similarity transformation and then resolved arithmetically employing the finite element technique with Galerkin’s residual. Buongiorno’s model of nanofluid on thermal and material transports, and flow structure has been investigated in detail. Outcomes have been displayed in the form of velocity, temperature, and concentration contours with various governing factors like Brownian action, Lewis number, Buoyancy relation, thermophoresis, Rayleigh number, Prandtl number, etc. Also, the rate of thermal transport has been calculated. The thermophoresis and Brownian effects on velocity, heat, and material fields are identified and finally, the flow, heat, and concentration controlling parameters for a specific material and thermal transport applications inside a trapezium-shaped cavity are obtained. Result demonstrates that the increase of Brownian action guides to enhance thermal transport by 34.75 and 34.27% for the right and left walls, respectively.

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自由对流中Buongiorno纳米流体的数值模拟:热泳动和布朗效应

在这项研究中，使用Buongiorno的纳米流体对具有正弦材料的梯形域内的自由对流进行了数值模拟，并在两个倾斜边界处进行了温度分配。该模型考虑了在流量、温度和浓度等值线中发生布朗活性效应的热泳作用。在两个倾斜表面上施加了不均匀的纳米粒子固体浓度和温度分配。顶部和底部的平行表面保持绝热。所有的墙都被认为是防滑和不透水的。附加边界条件下的主导方程最初通过适当的相似性变换转换为无量纲模式，然后使用具有Galerkin残差的有限元技术进行算术求解。详细研究了Buongiorno的纳米流体热输运和材料输运模型以及流动结构。结果以速度、温度和浓度等值线的形式显示，并具有各种控制因素，如布朗作用、路易斯数、浮力关系、热泳、瑞利数、普朗特数等。此外，还计算了热输运速率。确定了热泳和布朗效应对速度、热量和材料场的影响，最后获得了特定材料的流动、热量和浓度控制参数以及梯形空腔内的热传输应用。结果表明，布朗作用的增加引导左右壁的热传输分别增加34.75%和34.27%。

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 Naval Architecture and Marine Engineering ENGINEERING, MARINE-

CiteScore

2.50

自引率

5.60%

发文量

审稿时长

20 weeks

期刊介绍： TJPRC: Journal of Naval Architecture and Marine Engineering (JNAME) is a peer reviewed journal and it provides a forum for engineers and scientists from a wide range of disciplines to present and discuss various phenomena in the utilization and preservation of ocean environment. Without being limited by the traditional categorization, it is encouraged to present advanced technology development and scientific research, as long as they are aimed for more and better human engagement with ocean environment. Topics include, but not limited to: marine hydrodynamics; structural mechanics; marine propulsion system; design methodology & practice; production technology; system dynamics & control; marine equipment technology; materials science; under-water acoustics; satellite observations; and information technology related to ship and marine systems; ocean energy systems; marine environmental engineering; maritime safety engineering; polar & arctic engineering; coastal & port engineering; aqua-cultural engineering; sub-sea engineering; and specialized water-craft engineering. International Journal of Naval Architecture and Ocean Engineering is published quarterly by the Society of Naval Architects of Korea. In addition to original, full-length, refereed papers, review articles by leading authorities and articulated technical discussions of highly technical interest are also published.