在斜磁场条件下,储能外壳中部分填充非达西多孔介质的水磁性 GO-Fe3O4/H2O 混合纳米流体的浮力驱动传热和熵分析

IF 4 3区 工程技术 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS International Journal of Numerical Methods for Heat & Fluid Flow Pub Date : 2024-08-22 DOI:10.1108/hff-03-2024-0193
H. Thameem Basha, Hyunju Kim, Bongsoo Jang
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引用次数: 0

摘要

目的热能储存系统利用热能来提高储存物质的温度,从而在放电周期中释放能量。在显热储存系统中,能量的储存或回收是通过液体或固体的加热或冷却实现的,不会发生相变。在显热填料床热能储存系统中,结构由多孔介质组成,形成填料固体材料,而流体则占据空隙。因此,部分由流体层填充、部分由饱和多孔层填充的空腔已成为研究自然对流传热的重要方法,在热能储存系统中具有重要意义。受这些见解的启发,目前的研究深入探讨了在部分多孔空腔内由浮力和熵产生驱动的对流传热,该空腔被不同程度地加热,垂直分层,并充满了混合纳米流体。在第一种情况下,多孔层紧靠加热壁,而对面区域则是流体层。在第二种情况下,多孔层交换位置,流体层紧邻加热壁。流体和多孔介质的方程系统以及适当的初始条件和边界条件,均采用有限差分法进行计算。研究中使用了 Tiwari-Das 模型,并使用球形纳米颗粒特有的相关性确定了粘度和导热性。研究结果进行了全面的数值模拟,考虑了达西数、纳米颗粒体积分数、瑞利数、底部狭缝位置和哈特曼数等控制因素。数值结果的可视化表示包括流线、等温线和熵线,以及说明平均熵生成和平均努塞尔特数的曲线图。计算结果表明,随着达西数的增加,在 GO 纳米流体中添加 2.5% 的磁铁矿纳米颗粒可提高传热速率,在情况 1 中提高了 0.567%,在情况 2 中提高了 3.894%。与情况 2 相比,情况 1 在外壳内的传热效果提高了 59.90%。将多孔层放置在部分冷却的墙壁旁,可显著提高平均总熵产生量,在雷利数值升高时,熵产生量大幅增加 11.36%。将热缝隙设置在靠近底壁的位置,与设置在中心位置相比,总熵产生量减少了 33.20%,与靠近顶壁相比,总熵产生量减少了 33.32%。
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Buoyancy-driven heat transfer and entropy analysis of a hydromagnetic GO-Fe3O4/H2O hybrid nanofluid in an energy storage enclosure partially filled with non-Darcy porous medium under an oblique magnetic field

Purpose

Thermal energy storage systems use thermal energy to elevate the temperature of a storage substance, enabling the release of energy during a discharge cycle. The storage or retrieval of energy occurs through the heating or cooling of either a liquid or a solid, without undergoing a phase change, within a sensible heat storage system. In a sensible packed bed thermal energy storage system, the structure comprises porous media that form the packed solid material, while fluid occupies the voids. Thus, a cavity, partially filled with a fluid layer and partially with a saturated porous layer, has become important in the investigation of natural convection heat transfer, carrying significant relevance within thermal energy storage systems. Motivated by these insights, the current investigation delves into the convection heat transfer driven by buoyancy and entropy generation within a partially porous cavity that is differentially heated, vertically layered and filled with a hybrid nanofluid.

Design/methodology/approach

The investigation encompasses two distinct scenarios. In the first instance, the porous layer is positioned next to the heated wall, while the opposite region consists of a fluid layer. In the second case, the layers switch places, with the fluid layer adjacent to the heated wall. The system of equations for fluid and porous media, along with appropriate initial and boundary conditions, is addressed using the finite difference method. The Tiwari–Das model is used in this investigation, and the viscosity and thermal conductivity are determined using correlations specific to spherical nanoparticles.

Findings

Comprehensive numerical simulations have been performed, considering controlling factors such as the Darcy number, nanoparticle volume fraction, Rayleigh number, bottom slit position and Hartmann number. The visual representation of the numerical findings includes streamlines, isotherms and entropy lines, as well as plots illustrating average entropy generation and the average Nusselt number. These representations aim to provide insight into the influence of these parameters across a spectrum of scenarios.

Originality/value

The computational outcomes indicate that with an increase in the Darcy number, the addition of 2.5% magnetite nanoparticles to the GO nanofluid results in an enhanced heat transfer rate, showing increases of 0.567% in Case 1 and 3.894% in Case 2. Compared with Case 2, Case 1 exhibits a 59.90% enhancement in heat transfer within the enclosure. Positioning the porous layer next to the partially cooled wall significantly boosts the average total entropy production, showing a substantial increase of 11.36% at an elevated Rayleigh number value. Positioning the hot slit near the bottom wall leads to a reduction in total entropy generation by 33.20% compared to its placement at the center and by 33.32% in comparison to its proximity to the top wall.

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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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