半疏水-半亲水球体垂直入水空泡数值仿真研究

doi:10.3969/j.issn.1000-1093.2017.05.017

兵工学报 ›› 2017, Vol. 38 ›› Issue (5): 968-977.doi: 10.3969/j.issn.1000-1093.2017.05.017

半疏水-半亲水球体垂直入水空泡数值仿真研究

孙钊，曹伟，王聪，路中磊

(哈尔滨工业大学航天学院, 黑龙江哈尔滨 150001)

收稿日期:2016-12-02 修回日期:2016-12-02 上线日期:2017-07-03
通讯作者: 王聪(1966—)，男，教授，博士生导师 E-mail:alanwang@hit.edu.cn
作者简介:孙钊(1985—)，男，博士研究生。 E-mail: flame_1985@163.com
基金资助:
国家自然科学基金项目(11672094)；哈尔滨市科技创新人才专项基金项目（2013RFLXJ007）

Numerical Investigations on Water-entry Cavity of Half Hydrophobic-half Hydrophilic Sphere

SUN Zhao， CAO Wei， WANG Cong， LU Zhong-lei

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

Received:2016-12-02 Revised:2016-12-02 Online:2017-07-03

摘要/Abstract

摘要： 采用流体体积多相流模型耦合连续表面力模型，对具有非对称表面润湿性的半疏水-半亲水球体垂直入水空泡形态发展过程进行数值仿真，分析了半疏水-半亲水球体垂直入水过程中受到的流体动力。研究结果表明：半疏水-半亲水球体垂直入水后，产生非对称入水空泡及“心”型喷溅，同时球体运动轨迹将偏离原竖直运动轨道，由疏水半球一侧向亲水半球一侧偏斜；入水初期，在球体表面形成液体薄层运动，在疏水半球一侧，液体薄层与球体表面分离，导致空气进入形成敞开空泡；在亲水半球体一侧，液体薄层沿球体表面向上运动最终在球体顶点汇聚；液体薄层汇聚后形成楔形流，楔形流在球体顶点与球体表面分离，继续向疏水半球一侧产生的入水空泡壁面运动并撞击，形成“心”型喷溅。

关键词: 流体力学, 多相流, 半疏水-半亲水球体, 垂直入水, 表面润湿性, 数值仿真, 空泡

Abstract: The water entry of a solid sphere impacting on a liquid surface has challenged researchers for centuries and remains of interest to the researchers today. A simulation study of the water entry cavity of half hydrophobic-half hydrophilic sphere is performed. Particular attention is given to the simulation method based on solving the Navier-Stokes equations coupled with VOF model and CSF model. The numerical results are in agreement with the experimental results, thus validating the suitability of the numerical approach to simulate the water entry of sphere under different wetting conditions. Based on this method, the development of cavity created by the half hydrophilic-half hydrophobic sphere is investigated. Results show that the water entry of half hydrophobic-half hydrophilic sphere creates an asymmetric cavity and “cardioid” splash, which causes the sphere to travel laterally from the hydrophobic side to the hydrophilic side. Further investigations show that the fluid film presents during initial stage of impact, and on the half hydrophobic sphere, the fluid film detaches from the sphere to lead to cavity formation; on the half hydrophilic sphere, the fluid film moves up on the sphere surface and gathers at the vertex of the sphere, forming a wedge flow. The wedge flow moves and finally impacts on the opposite side of the cavity so as to cause “cardioid” splash. In addition, the total hydrodynamic force coefficient is investigated as a result of the forces acting on the sphere during water entry dictated by the cavity formation. Key

Key words: fluidmechanics, multiphaseflow, halfhydrophobic-halfhydrophilicsphere, verticalwater-entry, surfacewettability, numericalsimulation, cavity

中图分类号:

TV131.2⁺2

孙钊，曹伟，王聪，路中磊. 半疏水-半亲水球体垂直入水空泡数值仿真研究[J]. 兵工学报, 2017, 38(5): 968-977.

SUN Zhao， CAO Wei， WANG Cong， LU Zhong-lei. Numerical Investigations on Water-entry Cavity of Half Hydrophobic-half Hydrophilic Sphere[J]. Acta Armamentarii, 2017, 38(5): 968-977.

参考文献

［1］ Worthington A M, Cole R S. Impact with a liquid surface, studied by the aid of instantaneous photography[J]. Philosophical Transactions of the Royal Society of London, 1900, 189:137-148.
[2] Worthington A M. A study of splashes[M]. NY, US: Longmans Green and Company, 1908.
[3] Rosellini L, Hersen F, Clanet C, et al. Skipping stones[J]. Journal of Fluid Mechanics , 2005, 543:137-146.
[4] May A. Water entry and the cavity-running behavior of missiles, ADA020429[R]. Silver Spring, MD, US: NAVSEA Hydroballistics Advisory Committee, 1975.
[5] Von Karman T. The impact on seaplane floats during landing, TN321[R]. Washington DC, US: National Advisory Committee on Aeronautics , 1929.
[6] Bush J W M, Hu D L. Walking on water: biolocomotion at the interface[J]. Annual Review of Fluid Mechanics, 2006, 38: 339-369.
[7] Duclaux V, Caillé F, Duez C,et al. Dynamics of transient cavities[J]. Journal of Fluid Mechanics, 2007, 591: 1-19.
[8] Grumstrup T, Keller J B, Belmonte A. Cavity ripples observed during the impact of solid objects into liquids[J]. Physical Review Letters, 2007, 99(11):114502-1-114502-4.
[9] Bergmann R, van der Meer D, Gekle S,et al. Controlled impact of a disk on a water surface: cavity dynamics[J]. Journal of Fluid Mechanics, 2009, 633:381-409.

[10] Aristoff J M, Truscott T T T, Techet A H, et al. The water entry of decelerating spheres[J]. Physics of Fluids, 2010, 22:032102-1-032102-8.
[11] 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: 121703-1-121703-4.
[12] Truscott T T, Techet A H. Water entry of spinning spheres[J]. Journal of Fluid Mechanics, 2009, 625:135-165.
[13] Techet A H, Truscott T T. Water entry of spinning hydrophobic and hydrophilic spheres[J]. Journal of Fluids and Structures, 2011, 27(5/6):716-726.
[14] 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.
[15] Yilmaz N, Nelson R. Cavity dynamics of smooth sphere and golf ball at low Froude numbers, part 1: high-speed imaging and quantitative measurements[J]. Journal of Visualization, 2015, 18(2): 335-342.
[16] Yilmaz N, Nelson R. Cavity dynamics of smooth sphere and golf ball at low Froude numbers, part 2: PIV analysis[J]. Journal of Visualization, 2015, 18(4): 679-686.
[17] Marston J O, Truscott T T, Speirs N B,et al. Crown sealing and buckling instability during water entry of spheres[J]. Journal of Fluid Mechanics, 2016, 794: 506-529.
[18] Benedict C W T, Vlaskkamp J H A, Denissenko P, et al. Cavity formation in the wake of falling spheres submerging into a stratified two-layer system of immiscible liquids[J]. Journal of Fluid Mechanics, 2016, 790: 33-56.
［19］路中磊，魏英杰，王聪，等. 基于高速摄像实验的开放腔体圆柱壳入水空泡流动研究［J］. 物理学报，2016,65(1):301-315.

LU Zhong-lei, WEI Ying-jie, WANG Cong, et al. An experimental study of water-entry cavitating flows of an end-closed cylindrical shell based on the high-speed［J］. Acta Physica Sinica, 2016,65(1):301-315. (in Chinese)
[20] Duez C, Ybert C, Clanet C, et al. Making a splash with water repellency[J]. Nature Physics, 2007, 3:180-183.
[21] DoQuang M, Amberg G. The splash of a solid sphere impacting on a liquid surface: numerical simulation of the influence of wetting[J]. Physics of Fluids, 2009, 21:022102.
[22] Kintea D M, Breitenbach J, Gurumurthy V T, et al. On the influence of surface tension during the impact of particles on a liquid-gaseous interface[J]. Physics of Fluids, 2016, 28: 012108.
[23] Brackbill J U, Kothe D B, Zemach C. A continuum method for modeling surface tension[J].Journal of Computational Physics, 1992, 100:335-354.

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半疏水-半亲水球体垂直入水空泡数值仿真研究

Numerical Investigations on Water-entry Cavity of Half Hydrophobic-half Hydrophilic Sphere

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