水横流作用下铝翅片管阵列振动参数研究

IF 1.7 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Multidiscipline Modeling in Materials and Structures Pub Date : 2022-09-20 DOI:10.1108/mmms-05-2022-0093
Pravin H. Yadav, S. Desai, D. Mohanty
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引用次数: 1

摘要

为了防止管壳式换热器因振动而失效,在不稳定阈值下预测临界速度至关重要。在本研究中,对铝管束在水横流作用下的振动响应进行了实验分析。铝管比钢管更受欢迎,因为铝管具有优异的耐腐蚀性、易于制造和高热效率。设计/方法/方法研究了基管直径为19.05 mm、节距为34 mm的铝管翅片管阵列中的流体弹性不稳定性和涡流脱落机制。目前的研究考虑了翅片高度为3 mm和6 mm的平行三角形翅片管阵列,翅片厚度和翅片间距均匀。对平面管阵列进行了测试,以比较翅片管阵列的结果。使用安装在第三排中间管上的加速度计测量管的振动响应。为了确定各种管阵列的流体弹性不稳定性行为,测量了不稳定性阈值处的临界速度。通过在失稳前的小峰处寻找斯特劳哈尔数,检验了管阵列的旋涡脱落行为。结果表明,粗翅片管阵列失稳时的临界速度随着翅片高度的增加而增加。通过将结果与先前报道的钢制平行三角形管阵列的结果进行比较来评估管材料的效果。最后,基于雷诺数和斯特劳哈尔数的关系,证实了管阵列中涡流脱落的发生。钢和铝材料的平面管阵列的不稳定性常数K分别为4.97和4.87。原创性/价值本文提供了翅片高度对粗密度翅片管阵列影响的研究结果。这将为流体弹性不稳定性和涡流脱落领域的文献增加大量知识,这是管壳式换热器安全运行所必需的。
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Investigation on vibration parameters in aluminum finned tube arrays subjected to water cross flow
PurposePredicting the critical velocity is crucial at the instability threshold for shell and tube heat exchangers in order to prevent tube failure due to vibrations. In this study, the vibration response of an aluminum tube bundle subjected to water cross flow was analyzed experimentally. Aluminum tubes are preferred over steel tubes because of aluminum tubes' excellent corrosion resistance, ease of manufacture, and high thermal efficiency.Design/methodology/approachThe fluid elastic instability and vortex shedding mechanisms in a finned tube array of aluminum tubes with a base tube diameter of 19.05 mm and pitch of 34 mm were investigated. The current study considers parallel triangular finned tube arrays with fin heights of 3 mm and 6 mm with a uniform fin thickness and fin pitch. The plain tube array was tested to compare the finned tube array results. The tube vibration response was measured using an accelerometer mounted on the middle tube of the third row. In order to define the fluid elastic instability behavior of various tube arrays, the critical velocity at the instability threshold is measured. By finding the Strouhal number at the small peaks before instability, the vortex shedding behavior of the tube arrays is examined.FindingsThe results reveal that the critical velocity at instability for coarse finned tube arrays increases as the fin height increases. The effect of the tube material is evaluated by comparing the results with those previously reported for parallel triangular tube arrays made of steel. Finally, the occurrence of vortex shedding in a tube array is confirmed based on the Reynolds number and Strouhal number relationship. The instability constant K for the plain tube array of steel and aluminum material are 4.97 and 4.87, respectively.Originality/valueThis paper provides the research findings on the effect of fin height on coarse density finned tube array. This will add substantial knowledge to the literature in the field of fluid elastic instability and vortex shedding, which is needed for the safe functioning of shell and tube heat exchangers.
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来源期刊
CiteScore
3.70
自引率
5.00%
发文量
60
期刊介绍: Multidiscipline Modeling in Materials and Structures is published by Emerald Group Publishing Limited from 2010
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