表面润湿性对球体入水空泡形态的影响研究

doi:10.3969/j.issn.1000-1093.2016.04.014

兵工学报 ›› 2016, Vol. 37 ›› Issue (4): 670-676.doi: 10.3969/j.issn.1000-1093.2016.04.014

表面润湿性对球体入水空泡形态的影响研究

孙钊，曹伟，王聪，魏英杰

(哈尔滨工业大学航天学院, 黑龙江哈尔滨 150001)

收稿日期:2015-07-23 修回日期:2015-07-23 上线日期:2016-06-20
作者简介:孙钊(1985—)，男，博士研究生
基金资助:
哈尔滨市科技创新人才专项基金项目（2013RFLXJ007）

Effect of Surface Wettability on Cavitation of Sphere during Its Water Entry

SUN Zhao， CAO Wei， WANG Cong， WEI Ying-jie

(School of Astronautics, Harbin Institute of Technology, Harbin 150001, Heilongjiang, China)

Received:2015-07-23 Revised:2015-07-23 Online:2016-06-20

摘要/Abstract

摘要： 基于Navier-Stokes方程，采用流体体积法多相流模型，并引入动网格技术，对不同表面润湿性球体的垂直入水问题开展了数值模拟研究。将球体垂直入水空泡形态的数值结果与实验结果进行对比，验证了数值结果的正确性。对不同润湿性球体的垂直入水空泡形态的研究结果表明，球体入水空泡形态主要有4种：完全无空泡、深闭合空泡、面闭合空泡以及类面闭合空泡。入水初期形成的液体薄层是影响随后产生空泡形态的关键因素。进一步分析表明，生成不同空泡形态的临界速度与球体的表面润湿性有密切关系，建立了描述入水空泡生成的临界速度与表面接触角关系的经验公式。

关键词: 流体力学, 表面润湿性, 空泡形态, 面闭合, 球体入水

Abstract: The problem of water entry of a solid sphere has challenged researchers for centuries and remains of interest to the researchers today, but how the surface condition affect the cavitation during a water entry of sphere has not been studied well. The problem of water entry of a solid sphere is investigated numerically simulated based on the Navier-Stokes equations and volume of fluid method. The numerical results show good agreement with the experimental data. Numerical results with different surface wettabilities and impact speeds are presented. The results show that the condition to create an air cavity is that the impact speed must be strictly above a critical velocity, and the critical velocity is discovered to be dependent on the wetting contact angle of sphere. That means the air entrainment is best inhibited by hydrophilic surfaces, hydrophobic spheres like making a big cavity. Four distinct cavitations are observed at different water entry velocities and contact angles: non-cavitation, deep-seal cavitation, surface-seal cavitation and surface-like cavitation. The simulation results are analyzed, and an empirical theory about the relationship between critical velocity and contact angle is presented.

Key words: fluid mechanics, surface wettability, cavity formation, surface-seal, water entry of sphere

中图分类号:

TV131.2

孙钊，曹伟，王聪，魏英杰. 表面润湿性对球体入水空泡形态的影响研究[J]. 兵工学报, 2016, 37(4): 670-676.

SUN Zhao， CAO Wei， WANG Cong， WEI Ying-jie. Effect of Surface Wettability on Cavitation of Sphere during Its Water Entry[J]. Acta Armamentarii, 2016, 37(4): 670-676.

参考文献

［1］ Techet A H, Truscott T T. Water entry of spinning hydrophobic and hydrophilic spheres[J]. Journal of Fluids and Structures, 2011, 27(S5/S6):716-726.
[2］ Bergmann R, Devaraj V D M, Gekle S, et al. Controlled impact of a disk on a water surface:cavity dynamics[J]. Journal of Fluid Mechanics, 2009, 633: 381-409.
[3］ Duclaux V, Caillé F, Duez C, et al. Dynamics of transient cavities[J]. Journal of Fluid Mechanics, 2007, 591:1-19.
[4］ Sudo S, Takayanagi H, Kamiyama S. Water entry of a magnetic fluid coated sphere[J]. Journal of Magnetism and Magnetic Materials, 2011, 323(10):1348-1353.
[5］ Aristoff J M, Truscott T T, Techet A H, et al. The water entry of decelerating spheres[J]. Physics of Fluids, 2010, 22(3):417-422.
[6］ Truscott T T, Techet A H. Water entry of spinning spheres[J].

Journal of Fluid Mechanics, 2009, 625:135-165.
［7］朱珠，袁绪龙，刘维. 柱体大攻角入水弹道建模与仿真［J］. 火力与指挥控制, 2015, 40(2):13-23.
ZHU Zhu, YUAN Xu-long, LIU Wei. On modeling and simulation of cylinder dropping in water with high angle of attack［J］. Fire Control & Command Control, 2015, 40(2):13-23. (in Chinese)
[8］ Worthington A M. A study of splashes[M]. London: Longmans, Green,1908.
[9］ May A. Effect of surface condition of a sphere on its water entry cavity[J]. Founal of Applied Physics, 1951, 22(10):1219-1222.
[10］ Duez C, Ybert C, Clanet C, et al. Making a splash with water repellency[J]. Nature Physics, 2007, 3(3):180-183.
[11］ Lee J. Chapter 1.2-surface tension and contact angle[M]∥Seetharaman S. Treatise on Process Metallurgyn. Amsterdam, NED:Elsevier, 2014:11-18.
[12］ Brackbill J U, Kothe D B, Zemach C. A continuum method for modeling surface tension[J]. Journal of Computational Physics, 1992, 100(2):335-354.
[13］ Truscott T T, Techet A H. A spin on cavity formation during water entry of hydrophobic and hydrophilic spheres[J]. Physics of Fluids，2009, 21(12):429-439.
[14］ And A A K, Pukhnachov V V. Initial stages of water impact[J].Annual Review of Fluid Mechanics, 2003, 20(2):159-185.
[15］ Oliver J. Water entry and related problems[D]. Oxford, UK:Oxford University, 2002.
[16］ Eggers J. Hydrodynamic theory of forced dewetting[J]. Physical Review Letters, 2004, 93(9): 094502.

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表面润湿性对球体入水空泡形态的影响研究

Effect of Surface Wettability on Cavitation of Sphere during Its Water Entry

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