Dynamics and measurement of cavitation bubble 被引量：3

Dynamics and measurement of cavitation bubble

导出

摘要 Based on the introduction of international progress, our investigations on acoustic cavitation have been reported. Firstly we considered the cavity's dynamics under the drive of the asymmetrical acoustic pressure. An aspheric dynamical model was proposed and a new stable and aspheric solution was found in numerical simulation of the theoretical framework of the aspheric model. Then, a dual Mie-scattering technique was developed to measure the cavity's aspheric pulsation. A significant asynchronous pulsation signal between two Mie-scattering channels was caught in the case of large cavity driven by low acoustic pressure. As a direct deduction, we observed an evidence of cavity's aspheric pulsation. Furthermore, we studied the dependency of the asynchronous pulsation signal on the various parameters, such as the amplitude and frequency of the driving acoustic pressure, and the surface tension, viscosity and gas concentration of the liquid. Finally, we introduced a new numeric imaging technique to measure the shapes of the periodic pulsation cavities. The time-resolution was in the order of 20 ns, one order of magnitude lower than that in the previous work, say, 200 ns. Based on the introduction of international progress, our investigations on acoustic cavitation have been reported. Firstly we considered the cavity's dynamics under the drive of the asymmetrical acoustic pressure. An aspheric dynamical model was proposed and a new stable and aspheric solution was found in numerical simulation of the theoretical framework of the aspheric model. Then, a dual Mie-scattering technique was developed to measure the cavity's aspheric pulsation. A significant asynchronous pulsation signal between two Mie-scattering channels was caught in the case of large cavity driven by low acoustic pressure. As a direct deduction, we observed an evidence of cavity's aspheric pulsation. Furthermore, we studied the dependency of the asynchronous pulsation signal on the various parameters, such as the amplitude and frequency of the driving acoustic pressure, and the surface tension, viscosity and gas concentration of the liquid. Finally, we introduced a new numeric imaging technique to measure the shapes of the periodic pulsation cavities. The time-resolution was in the order of 20 ns, one order of magnitude lower than that in the previous work, say, 200 ns.

作者 CHEN Weizhong LIU Ya'nan HUANG Wei GAO Xianxian

机构地区 Key Laboratory of Modern Acoustics and Institute of Acoustics

出处《Science China(Physics,Mechanics & Astronomy)》 SCIE EI CAS 2006年第4期385-395,共11页 中国科学：物理学、力学、天文学（英文版）

基金 This work was supported partially by the National Natural Science Foundation of China (Grant No. 10434070) the Key Project of Ministry of Education of China (Grant No. 103078).

关键词 cavitation DYNAMICS of CAVITATION bubble sonoluminescence. cavitation, dynamics of cavitation bubble, sonoluminescence.

分类号 N [自然科学总论]

引文网络
相关文献

参考文献28

1[1]Leighton T G.The Acoustic Bubble.London:Academic Press,1994 被引量：1
2[2]Rayleigh L.On the pressure developed in a liquid during the collapse of a spherical cavity.Philos Mag,1917,34:94―98 被引量：1
3[3]Didenko Y T,McNamara W B,Suslick K S.Molecular emission from single-bubble sonoluminescence.Nature,2000,407:877―879 被引量：1
4[4]Marinesco N,Trillat J J.Action of supersonic waves upon the photographic plate.Proc R Acad Sci,1933,196:858―860 被引量：1
5[5]Gaitan D F,Crum L A,Church C C,Roy R A.Sonoluminescence and bubble dynamics for a single,stable,cavitation bubble.J Acoust Soc Am,1992,91:3166―3183 被引量：1
6[6]Barber B P,Putterman S J.Observation of synchronous picosecond sonoluminescence.Nature,1991,352:318―320 被引量：1
7[7]Gompf B,Günther R,Nick G,Pecha R,Eisenmenger W.Resolving sonoluminescence pulse width with time-correlated single photon counting.Phys Rev Lett,1997,79:1405―1408 被引量：1
8[8]Pecha R,Gompf B,Nick G,Wang Z Q,Eisenmenger W.Resolving the sonoluminescence pulse shape with a streak camera.Phys Rev Lett,1998,81:717―720 被引量：1
9[9]Crum L A.Sonoluminescence.Physics Today,1994,47:22―29 被引量：1
10[10]Dam J S,Levinsen M T,Skogstad M.Period-doubling bifurcations from the spherical symmetry in sonoluminescence:Experimental verification.Phys Rev Lett,2002,89:84303 被引量：1

同被引文献26

1张建生,何俊华,冀邦杰,陈良益.尾流光学信号的处理方法[J].光子学报,2005,34(8):1274-1277. 被引量：17
2朱哲民,杜功焕.含气泡水的强非线性声学特性[J].声学学报,1995,20(6):425-431. 被引量：12
3Zeng D L.Sound velocity in vapor-liquid two-phase medium. Proceedings of Second Inter Symposium on Multi-phase Flow and Heat Transfer . 1989 被引量：1
4Zeng D L,Zhao L J,Xiao Y.Sound velocity in two-phase fluid system. Proceedings of the Inter Conference on En- ergy Conversion and Application . 2001 被引量：1
5Ji B J,Zhou D S,Zhang J S.Guided torpedo based on ship wakes’optical specialty. Torpedo Technol . 2000 被引量：1
6Liu B S,Lei J Y.Principle of Hydro-acoustic. . 1993 被引量：1
7Qian Z W,Li B W,Zheng X Y,et al.Sound propagation and inversion in bubble films. Sci China Ser A-Math Phys Astron . 1992 被引量：1
8Gibson F W.Measurement of the effect of air bubbles on the speed of sound in water. The Journal of The Acoustical Society of America . 1970 被引量：1
9Chen W Z,Huang W,Liu Y N,et al.Dynamics and measurement of sonic cavitation bubble. Sci China Ser G-Phys,Mech Astron . 2006 被引量：1
10Urick R J.Sound Propagation in the Sea. . 1990 被引量：1

引证文献3

1ZHANG JianSheng,LIN ShuYu,LIU Peng,MIAO RunCai,YANG WanMin.Sound speed in bubble film of ship wakes[J].Science China(Physics,Mechanics & Astronomy),2008,51(1):64-71.
2ZHANG AMan,NI BaoYu.Influences of different forces on the bubble entrainment into a stationary Gaussian vortex[J].Science China(Physics,Mechanics & Astronomy),2013,56(11):2162-2169. 被引量：16
3JIANG Liang,GE Han,FENG ChengLiang,CHEN DaRong.Numerical simulation of underwater explosion bubble with a refined interface treatment[J].Science China(Physics,Mechanics & Astronomy),2015,58(4):91-100. 被引量：5

二级引证文献21

1FANG WenCheng,TONG DeChun,GU Qiang,ZHAO ZhenTang,SHENG Xing,CHEN LiFang,WANG Lin.The nonresonant perturbation theory based field measurement and tuning of a linac accelerating structure[J].Science China(Physics,Mechanics & Astronomy),2013,56(11):2104-2109. 被引量：3
2ZHANG AMan,NI BaoYu.Influences of different forces on the bubble entrainment into a stationary Gaussian vortex[J].Science China(Physics,Mechanics & Astronomy),2013,56(11):2162-2169. 被引量：16
3MA LiQun,FENG LiHao,PAN Chong,GAO Qi,WANG JinJun.Fourier mode decomposition of PIV data.[J].Science China(Technological Sciences),2015,58(11):1935-1948. 被引量：6
4HU Jing,CHEN ZuYu,ZHANG XueDong,WEI YingQi,LIANG XiangQian,LIANG JianHui,MA GuoWei,WANG QiuSheng,LONG Yuan.Underwater explosion in centrifuge partⅠ:Validation and calibration of scaling laws[J].Science China(Technological Sciences),2017,60(11):1638-1657. 被引量：16
5何升阳,张志友,金良安,苑志江.波浪中舰船远程尾流区气泡运动研究[J].应用力学学报,2018,35(1):47-53. 被引量：3
6赵琪,张梦萍,徐胜利,卢键方.激波和单列水柱、气水固多界面相互作用的数值模拟[J].计算物理,2018,35(3):285-293. 被引量：1
7张志友,金良安,何升阳,苑志江.波浪场中气泡运动的影响要素研究[J].水动力学研究与进展（A辑）,2018,33(3):305-313.
8张志友,金良安,何升阳,苑志江.气泡上浮运动与传热传质的耦合模型[J].高校化学工程学报,2018,32(2):358-367. 被引量：3
9金良安,何升阳,张志友,苑志江.传热传质耦合影响的水中气泡上浮特性研究[J].工程热物理学报,2019,40(5):1143-1150. 被引量：2
10倪宝玉,戴绍仕,王诗平.基于“兴趣-科研-探索”的船舶与海洋工程流体力学启发式教学模式初探[J].力学与实践,2020,42(1):103-107. 被引量：6

1DI Zengru(Department of Physics, Beijing Normal University, Beijing 100875 P.R.China)LI Maoling(Department of Safety Engineering, Capital University of Economics and Business, Beijing100026 P.R. China).The Nonlinear Dynamical Model for the Evolution of Productivity[J].Systems Science and Systems Engineering,1998,8(4):445-456.
2LIU Jia Dept. Math., Shanxi University, Taiyuan, 030006.On Asynchronous Exponential Stability of C_0 Semigroups[J].Systems Science and Systems Engineering,1998,8(3):42-47.
3DING Chunfeng XING Da.Studies on threshold pressures of sonoluminescence for bubbles with different noble gases[J].Science China(Physics,Mechanics & Astronomy),2004,47(4):513-520.
4冯若,许坚毅,史群.STUDY ON CHEMICAL EFFECTS OF THER-APEUTIC ULTRASOUND CAVITATION[J].Progress in Natural Science:Materials International,1991,1(4):376-380.
5张莹.东部片区MIE硕果累累[J].中国制造业信息化（应用版）,2009(8):90-92.
6T.V.Prevenslik.The Planck theory of Sonoluminescence[J].Progress in Natural Science:Materials International,1998,8(4):53-60.
7王双维,冯若,许坚毅,史群.EFFECT OF ULTRASOUND PULSE WIDTH ON CAVITATION IN SMALL-SIZE REVERBERATION[J].Progress in Natural Science:Materials International,1992,2(3):275-279.
8HAN Lei1,2 & YUAN YeLi2 1 Department of Ocean Environment, Ocean University of China, Qingdao 266003, China,2 The First Institute of Oceanography, State Ocean Administration, Qingdao 266061, China.Bubble size distribution in surface wave breaking entraining process[J].Science China Earth Sciences,2007,50(11):1754-1760. 被引量：2
9杨钧,汤大新,金曾孙,吕宪义,王卉,邹广田.INFRARED INTENSIFYING TRANSMISSION DEPENDENCE OF POLYCRYSTAL DIAMOND THIN FILM ON CRYSTAL GRAIN SCATTERING ABSORPTION[J].Chinese Science Bulletin,1991,36(6):457-460.
10钱祖文,李保文,郑晓瑜,邵道远.SOUND PROPAGATION AND INVERSION IN BUBBLY CURTAINS[J].Science China Mathematics,1992,35(4):443-451.

Science China(Physics,Mechanics & Astronomy)

2006年第4期

浏览历史

内容加载中请稍等...

Dynamics and measurement of cavitation bubble 被引量：3

参考文献28

同被引文献26

引证文献3

二级引证文献21

相关作者

相关机构

相关主题

浏览历史