带腔矩形通道换热器的强化传热研究

IF 0.4 4区 工程技术 Q4 NUCLEAR SCIENCE & TECHNOLOGY
Kerntechnik Pub Date : 2023-07-17 DOI:10.1515/kern-2023-0032
Prateek D. Malwe, Aarti Mukayanamath, H. Panchal, N. Gupta, C. Prakash, M. M. Abdul Zahra
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引用次数: 0

摘要

在燃气轮机、核电站、微观和宏观传热、翼型冷却、电子冷却、半导体、生物医学和燃烧室管道等许多场合都需要增强传热。从热交换器表面增加传热系数的主要方法之一是移动热边界层的位置,使其变薄或部分断裂。它需要利用增加的表面积/翅片。因此,利用换热器表面凹陷/凹陷来提高换热系数和换热率的强化换热研究取得了进展。这些浸渍是在热交换器表面的内部流管/表面上进行的。本文的研究工作旨在对换热器进行实验研究,以确定波纹表面上的气流形态和传热速率的计算。该研究工作将有利于并适用于考虑空间约束的微传热等传热强化应用。实验中考虑的几何形状包括平板和凹陷表面。考虑了雷诺数(从20,000到50,000变化)、凹痕深度与压痕直径比(从0.2到0.4变化)以及测试板的加热器输入(从75到120 W变化)等参数进行比较。将有凹痕表面的结果与无凹痕的平板表面进行了比较。雷诺数和努塞尔数与加热器输入成正比。对于引脚鳍和凹形板,当输入功率为75 W和100 W时,努塞尔数与面积平均努塞尔数之比下降。压痕直径与凹痕深度之比为0.3的凹痕板,其努塞尔数与努塞尔数值之比在全组中最高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Heat transfer enhancement of heat exchanger using rectangular channel with cavities
Abstract Heat transfer enhancement is required for numerous situations, i.e., gas turbines, nuclear power plants, micro and macro scale heat transfer, airfoil cooling, electronic cooling, semiconductors, biomedical and combustion chamber lines, etc. One of the prominent ways of increasing the heat transfer coefficient from the surface of a heat exchanger is by moving the position of the thermal boundary layer to make it either thinner or break the same partially. It requires making use of an increased surface area/fins. Accordingly, the research progressed in heat transfer enhancement by using concavities/dimples of the heat exchanger surfaces to improve the heat transfer coefficient and heat transfer rate. These impregnations are made on the internal flow tubes/surfaces of the heat exchanger surfaces. The present research work aims at the experimental investigation of a heat exchanger to determine the airflow pattern and computation of heat transfer rate on the dimpled surfaces. This research work will be beneficial and applicable to heat transfer enhancement applications like micro heat transfer, where space constraint is considered. The geometries considered for the experiment include flat plates and dimpled surfaces. The parameters like Reynolds number (varied from 20,000 to 50,000), dimple depth to imprint diameter ratio (varied from 0.2 to 0.4), and heater input to the test plates (varied from 75 to 120 W) are considered for the comparisons. The results with dimpled surfaces are compared with the flat plate surfaces having no dimples. The Reynolds and Nusselt numbers rise in direct proportion to the heater input. For pin fin and dimpled plate, the ratio of Nusselt number to area average Nusselt number drops for 75 W and 100 W input. The dimpled plate with a ratio of 0.3 between imprint diameter to dimple depth had the highest ratio of Nusselt number to Nusselt number value for the entire group.
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来源期刊
Kerntechnik
Kerntechnik 工程技术-核科学技术
CiteScore
0.90
自引率
20.00%
发文量
72
审稿时长
6-12 weeks
期刊介绍: Kerntechnik is an independent journal for nuclear engineering (including design, operation, safety and economics of nuclear power stations, research reactors and simulators), energy systems, radiation (ionizing radiation in industry, medicine and research) and radiological protection (biological effects of ionizing radiation, the system of protection for occupational, medical and public exposures, the assessment of doses, operational protection and safety programs, management of radioactive wastes, decommissioning and regulatory requirements).
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