期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

绕水翼超空化流动形态与速度分布 被引量:10

CHARACTERISTICS OF SUPERCAVITATING FLOWS AROUND A HYDROFOIL
在线阅读 下载PDF
导出
摘要 为揭示超空化流场结构特性,利用高速全流场显示技术,观察了绕hydronautics水翼的超空化流动形态,并利用数字粒子图像测速仪(DPIV)测量了其速度分布.在测量空穴内部流速分布时,采用空化流场中的空化泡作为示踪粒子来显示流动结构.结果表明:随着空化数的降低,超空化流动显现出了明显的阶段特征,其中水汽混合相和汽相的分布决定了空化区域的形态与流速分布;空化区和主流区的汽液交界面处存在着较大的速度梯度;低速分布区域随着空化数的降低由水翼吸力面中后部向水翼下游移动;在空化区域内部,水汽混合区的速度相对较低,而汽相区则与主流区有着相近的速度分布. Supercavitation around a hydrofoil is studied experimentally to address the flowing characteristics. A high-speed video camera is used to visualize the flow structures under different cavitation numbers. The digital particle image velocimetry (DPIV) is employed to measure the velocity fields. The bubbles among the cavitating fields are used as the tracer particles to survey the velocity distribution inside the cavity and improve the tracking capability of the tracer particles. The results show that three distinct supercavitating flow regimes can be observed with the decreasing cavitation numbers, in which the cavitation structure varies with the distribution of the water-vapor mixing phase and vapor phase. A large velocity gradient exists around the interface between the cavitation area and the free stream. In the cavitation area, the lower-velocity region moves from the foil's middle part to the downstream with the decrease of the cavitation number. The fluid velocity is low in the water-vapor mixture region, while with the similar distribution in the free stream and the vapor region.
作者 李向宾 王国玉 张敏弟 刘淑艳
机构地区 北京理工大学机械与车辆工程学院
出处 《力学学报》 EI CSCD 北大核心 2008年第3期315-322,共8页 Chinese Journal of Theoretical and Applied Mechanics
基金 国家自然科学基金(50276004 50679001) 北京理工大学基础研究基金(BIT-UBF-200503E4206)~~
关键词 超空化水翼 DPIV 高速摄像 空化形态 流速分布 supercavitation hydrofoil, DPIV, high-speed video camera, cavitation characteristics, velocity distribution
分类号 TV131.32 [水利工程—水力学及河流动力学]
  • 相关文献

参考文献18

  • 1Wang GY, Cao SL, Ikohagi T. Study on behaviors of cavaitaring vortices in flows around a hollow-jet valve. In: Proc. Third international Conference on Fluid Machinery and Fluid Engineering. Beijing, China, 2000. 451-455
  • 2Brennen CE. Cavitation and Bubble Dynamics. UK: Oxford University Press, 1995
  • 3Wang GY, Senocak I, Shyy W, et al. Dynamics of attached turbulent cavitating flows. Progress in Aerospace Sciences, 2001, 37(6): 551-581
  • 4Rood EP. Review-mechanisms of cavitation inception. Journal of Fluids Engineering, 1991, 113(2): 163-175
  • 5Leger AT, Ceccio SL. Examination of the flow near the leading edge of attached cavitation. Part 1. Detachment of two-dimensional and axisymmetric cavities. Journal of Fluid Mechanics, 1998, 376(1): 61-90
  • 6Gopalan S, Katz J. Flow structure and modeling issues in the closure region of attached cavitation. Physics of Fluids, 2000, 16(4): 895-911
  • 7Kawanami Y, Kato H, Yamauchi H, et al. Mechanism and control of cloud cavitation. Journal of Fluids Engineering, 1997, 119(4): 788-794
  • 8Wu YT, Wang DP. A wake model for free-streamline flow theory, part 2. Cavity flows past obstacles of arbitrary profile. Journal of Fluid Mechanics, 1963, 18(1): 65-93
  • 9Furuya O, Acosta AJ. A note on the calculation of supercavitating hydrofoils with rounded noses. Journal of Fluid Engineering, Transactions of the ASME, 1973. 221-228
  • 10Oba R, Ikohagi T, Yasu S. Supercavitating cavity observation by mean of laser velocimeter. Journal of Fluids Engineering, 1980, 102(4): 433-440

二级参考文献10

  • 1Michel M J. Introduction to Cavitation and Supercavitation. RTO AVT/VKI Special Course: Supercavitating Flows. Von Karman Institute for Fluid Dynamics,Rhode-Saint-Genese, Belgium, 2001, 1-14.
  • 2Wang Guoyu, Ikohagi T. Cavitation Characteristics Around a Hollow-Jet Valve (Observation by High-Speed Photographs and Monitoring by Vibration), Trans.Japanese Turbomachinery Society, 1998, 26(9): 361-368.
  • 3Wang Guoyu, Liu Shujan, et al. Study on Cavitation Damage Characteristics around a Hollow-Jet Valve.JSME Int. J. Series B, 1999, 42(4): 649-658.
  • 4Knapp R T, Daily J W, Hammit F G. Cavitation. Mc-Graw Hill, 1970.
  • 5Wang Guoyu, Senocak I., Shyy W., et al. Dynamics of Attached Turbulent Cavitating Flows, Progress in Aerospace Sciences. 2001, 37:551-581.
  • 6Ashley S. Waxp Drive Underwater. Scientific American May, 2001:70-79.
  • 7Senocak I, Shyy W. A Pressure-Based Method for Turbulent Cavitating Flow Simulations. J. of Computational Physics, 2002, 176:1-22.
  • 8钟铠.超空泡武器揭开水中兵器发展史新篇章[J].舰船论证参考,1999(1):55-60. 被引量:3
  • 9刘伟.谈农业重大科研项目的选题定位[J].农业科技管理,2001,20(3):34-35. 被引量:2
  • 10王国玉,刘淑艳,曹树良,赵令家.高速水流中旋涡空化所引起的空蚀和振动[J].工程热物理学报,2002,23(6):707-710. 被引量:14

共引文献31

同被引文献90

引证文献10

二级引证文献65

力学学报
2008年 第3期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部