Investigation of Waves Interaction in Annular Gas-Liquid Flow Using High-Speed Fluorescent Visualization Technique

S. V. Alekseenko; V. A. Antipin; A. V. Cherdantsev; S. M. Kharlamov; D. M. Markovich

首页> 外文期刊>Microgravity science and technology >Investigation of Waves Interaction in Annular Gas-Liquid Flow Using High-Speed Fluorescent Visualization Technique

【24h】

Investigation of Waves Interaction in Annular Gas-Liquid Flow Using High-Speed Fluorescent Visualization Technique

机译：利用高速荧光可视化技术研究环形气液流中的波相互作用

获取原文

获取原文并翻译 | 示例

获取外文期刊封面封底 >>

开具论文收录证明 >>

文献代查 >>

团队文献服务 >>

页面导航

摘要
著录项
相似文献
相关主题

摘要

High-speed fluorescent visualization complex has been developed for quantitative investigation of the process of interaction of waves on liquid film in annular two-phase flow. Evolution of ripples on disturbance waves surface and disturbance waves coalescence are investigated. It is shown that all the ripples in presence of disturbance waves appear at the base of the back front of disturbance waves and then either decelerate, travel on substrate and are overtaken by the following disturbance wave or accelerate, grow and then disappear at the front of disturbance wave. The disappearance happens due to entrainment of liquid into the core of gas stream. Several scenarios of coalescence of disturbance waves were identified. For disturbance waves with close velocities different types of remote interaction were observed.

机译：已开发出高速荧光可视化复合体，用于定量研究环形两相流中液膜上的波相互作用过程。研究了扰动波表面的波纹演化和扰动波的合并。结果表明，存在扰动波的所有波纹都出现在扰动波的背面的底部，然后减速，在基板上移动并被随后的扰动波超越，或者加速，增长然后消失在扰动波的前面。干扰波。这种消失是由于液体夹带进入气流的核心而发生的。确定了干扰波合并的几种情况。对于速度接近的干扰波，观察到了不同类型的远程相互作用。

著录项

来源
《Microgravity science and technology 》 |2008年第4期| p.271-275| 共5页
作者
S. V. Alekseenko; V. A. Antipin; A. V. Cherdantsev; S. M. Kharlamov; D. M. Markovich;
展开▼
作者单位

Institute of Thermophysics, Siberian Branch of Russian Academy of Science, Novosibirsk, Russia;

展开▼
收录信息
原文格式 PDF
正文语种 eng
中图分类工程材料学 ;
关键词
liquid film; annular flow; disturbance waves; ripples; waves interaction; entrainment;

机译：液膜;环流;扰动波;波纹;波相互作用;夹带;

相似文献

外文文献
中文文献
专利

1. Application of a high-speed laser-induced fluorescence technique for studying the three-dimensional structure of annular gas-liquid flow [J] . Alekseenko S., Cherdantsev A., Cherdantsev M., Experiments in Fluids: Experimental Methods and Their Applications to Fluid Flow . 2012 ,第1期

机译：高速激光诱导荧光技术在研究环形气液两相流三维结构中的应用
2. Investigation of Secondary Waves Dynamics in Annular Gas-Liquid Flow [J] . Sergey Alekseenko, Andrey Cherdantsev, Mikhail Cherdantsev, Microgravity science and technology . 2009 ,第suppla1期

机译：环形气液流中的二次波动力学研究
3. In-Cylinder Flow and Fuel Spray Interactions in a Stratified Spray-Guided Gasoline Engine Investigated by High-Speed Laser Imaging Techniques [J] . R. Stiehl, J. Schorr, C. Krüger, Flow, Turbulence and Combustion . 2013 ,第3期

机译：高速激光成像技术研究分层导向汽油发动机的缸内流动和燃油喷雾相互作用
4. Various Aspects of Application of High-Speed LIF-Technique to Studying the Wavy Structure of Liquid Film in Annular Gas-Liquid Flow. [C] . Sergey Alekseenko, Andrey Cherdantsev, Sergey Kharlamov, The 7th international symposium on measurement techniques for multiphase flows . 2011

机译：高速LIF技术在研究环形气液流动中液膜的波浪结构中的各个方面。
5. AN EXPERIMENTAL INVESTIGATION OF SHOCK WAVES AND TURBULENT BOUNDARY LAYER INTERACTIONS IN A SUPERSONIC FLOWFIELD THROUGH AN ANNULAR DUCT (SCRAMJET). [D] . STOCKBRIDGE, RICHARD DREXEL. 1986

机译：通过环形管道（SCRAMJET）进行超音速流场中冲击波和湍流边界层相互作用的实验研究。
6. Gas Void Fraction Measurement of Gas-Liquid Two-Phase CO2 Flow Using Laser Attenuation Technique [O] . Haochi Wu, Quansheng Duan 2019

机译：激光衰减技术测量气液两相CO2气孔分数
7. Combined wave and flow field visualization for investigation of short-wave/long-wave interaction [O] . Hering Frank, Wierzimok Dietmar, Melville W. K., 1996

机译：波和流场的组合可视化，用于研究短波/长波相互作用
8. The Fluorescent-Oil Film Method and Other Techniques for Boundary-Layer Flow Visualization [R] . Loving, Donald L., Katzoff, S. 1959

机译：荧光油膜法和边界层流动可视化的其他技术

Investigation of Waves Interaction in Annular Gas-Liquid Flow Using High-Speed Fluorescent Visualization Technique

摘要

著录项

相似文献

相关主题

期刊订阅