Numerical Study of Heat Transfer in a Lattice Matrix with Varying the Crossing Angle

IF 1.3 4区 工程技术 Q3 ENGINEERING, MECHANICAL Journal of Engineering Thermophysics Pub Date : 2024-04-10 DOI:10.1134/S1810232824010156
A. V. Barsukov, V. V. Terekhov, V. I. Terekhov
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Abstract

The development of methods for intensifying heat transfer is a priority task in various technological processes in the energy sector and aerospace engineering. One of the effective ways to enhance heat transfer is to install mutually intersecting ribs on opposite walls of the channels (vortex matrices or latticework). The use of such channels leads to formation of a complex three-dimensional turbulent flow, which contributes to a significant enhancement of heat transfer. Most of available literature publications deal with the study of the integral characteristics of hydraulic losses and the degree of heat transfer enhancement depending on a large number of defining parameters. At that, the local flow structure and heat transfer have not been fully investigated. In particular, this conclusion relates to understanding the mechanism of the flow from subchannels formed by parallel ribs on opposite walls and interaction of these flows with the lateral bounding walls of the latticework. In this work, the main attention is paid to the study of the flow processes without the influence of the side walls of the channel. The results of numerical calculations of separated turbulent flow in a latticework obtained using the RANS and LES methods and the OpenFOAM package are presented here. Calculations were performed for the angles of rib crossing \(2\beta=60\div120\) on opposite heat transfer surfaces and the Reynolds number Re = \(5,000\div15,000\), determined from the average flow rate and channel height. Data on the flow structure in a cell of a latticework were obtained. It is shown how the angle of crossing affects the interaction of flows in the lower and upper subchannels. The distribution of local heat transfer on the channel wall and the dependence of the average Nusselt number on the angle of crossing and the Reynolds number were obtained.

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晶格矩阵中不同交叉角传热的数值研究
摘要 开发强化传热的方法是能源部门和航空航天工程中各种技术流程的优先任务。加强传热的有效方法之一是在通道相对壁上安装相互交叉的肋条(涡流矩阵或格状结构)。使用这种通道可形成复杂的三维湍流,从而显著提高传热效果。现有文献出版物大多涉及水力损失整体特性的研究,以及取决于大量定义参数的传热增强程度。但对局部流动结构和传热还没有进行充分研究。特别是,这一结论涉及到如何理解由相对壁上的平行肋条形成的子通道的流动机制,以及这些流动与格子间横向边界壁的相互作用。在这项工作中,主要关注的是研究不受渠道侧壁影响的流动过程。本文介绍了使用 RANS 和 LES 方法以及 OpenFOAM 软件包对格子中分离湍流进行数值计算的结果。根据平均流速和通道高度确定了相对传热表面的肋条交叉角(2\beta=60\div120\)和雷诺数Re=\(5,000\div15,000\)。获得了格子间内流动结构的数据。显示了交叉角如何影响上下子通道中流动的相互作用。还获得了通道壁上局部传热的分布情况以及平均努塞尔特数对交叉角和雷诺数的依赖关系。
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来源期刊
Journal of Engineering Thermophysics
Journal of Engineering Thermophysics THERMODYNAMICS-ENGINEERING, MECHANICAL
CiteScore
2.30
自引率
12.50%
发文量
0
审稿时长
3 months
期刊介绍: Journal of Engineering Thermophysics is an international peer reviewed journal that publishes original articles. The journal welcomes original articles on thermophysics from all countries in the English language. The journal focuses on experimental work, theory, analysis, and computational studies for better understanding of engineering and environmental aspects of thermophysics. The editorial board encourages the authors to submit papers with emphasis on new scientific aspects in experimental and visualization techniques, mathematical models of thermophysical process, energy, and environmental applications. Journal of Engineering Thermophysics covers all subject matter related to thermophysics, including heat and mass transfer, multiphase flow, conduction, radiation, combustion, thermo-gas dynamics, rarefied gas flow, environmental protection in power engineering, and many others.
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