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采用高速摄像实验和数值计算相结合的方法,对开放空腔壳体入水过程中空腔内气体涨缩对入水空泡的扰动机理和扰动作用下空泡局部失稳特征开展研究.基于实验观测结果,对比开放空腔和封闭空腔两种壳体入水空泡形态差异性,获得开放空腔壳体入水空泡波动特征,并根据能量守恒定律和能量转化关系,定性分析空腔自激扰动机理和扰动引起的空泡波动机理.基于数值计算结果,结合实验观测到的空泡阶段性局部失稳现象,定量分析空泡局部的结构性失稳特征和流动性失稳特征,并参照边界层理论和漩涡理论,揭示了空泡局部失稳机理.结果表明:入水冲击压缩空腔气体形成扰动源,对流场结构形成周期性扰动,导致空泡波动;撞水前空腔气体经冲击压缩密度升高,导致入水后气体首次膨胀阶段部分气体外泄,改变分离点流动,空泡局部结构失稳;空泡壁面流动具有类边界层流动特性,波动形态空泡形成多级回流现象,并逐级作用在空泡凹陷位置,使局部掺混区厚度增加,产生涡旋、转捩流动,空泡局部云化失稳;空泡逐级在波谷位置闭合、脱落,伴随大尺度漩涡生成,脱落过程形成拟序结构流场,漩涡导致脱落空泡迅速溃灭,但不会对附着空泡的流动产生影响.The purpose of this present study is to address instability flowing characteristics and mechanism of the water-entry cavity created by a semi-closed cylinder. For this purpose, an experimental study and a numerical study of the water-entry of a semi-closed cylinder are carried out. According to the results of the experiments and comparison, the cavitating flows between the semi-closed cylinder water entry and the sealing cylinder water entry, and the fluctuation flow pattern form of the semi-closed cylinder cavitation is found around the body. The flow characteristics of the cavity shape are gained by analyzing the image data. A further insight into the mechanisms of perturbation to the flow structure and the cavity fluctuation by the air in the opening cell are studied based on the law of conservation of energy in water entry. According to the results of simulation and comparison with the cavity visualization of experiment, three instability flow phenomena of cavity are formed during the different stages of water-entry, i.e., flow separation destroyed, local flow transformed near cavity, and unique cavity shedding pattern. A further insight into the characteristics of the flow and the distribution of pressure and velocity during the stage of the cavity unstabilized flow is gained. Finally, the formation mechanism of the cavity unstabilized flow is studied based on the boundary layer theory and Helmhotz vortex theory. The obtained results show that the water poured into the cell of cylinder after the opening end has impacted free surface causes the internal air to compress and expand, and as a consequence of these effects, periodic disturbances of flow structure occur around the cavity, then the cavity presents an identical periodic wave flow with air piston motion and the flow stability of cavity is destroyed. At the eve of impacting, the opening end approaches the free surface, which leads to the inflow velocity attenuation rapidly and the pressure increasing in the cell, which creates an initial pressure higher than ambient pressure. Because of the high pressure, air efflux from the cell forms a gas jet injected into the cavity for the first air expansion stage, then the detaching flow is destroyed and the cavity extension diameter is enlarged. The flow in the gas-liquid mixing domain of cavity is seen as an approximate boundary layer flow pattern where favorable pressure gradient on the upwind side and adverse pressure gradient on the lee side appear alternately. As this flow pattern, re-entrant flow acting on the trough of wave cavitation results in the fact that the laminar-turbulent transition is weakened in the trough field and the local gas-liquid mixing domain is thickened to be involved in unstabilized structure as cloud cavitation. The wave cavity presents a partial and multiple shedding pattern occurring at the trough positions in sequence. There is no mutual interference between shedding cavity and the main cavity. Following the cavity shedding, vortex shedding is formed. The vorticity concentrates on the inside of shedding cavity, and the pressure and velocity present a coherent structure.
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Keywords:
- semi-closed cylinder /
- perturbation /
- flow structure /
- cavitation flow instability
[1] May A 1951 J. Appl. Phys. 22 1219
[2] He C T, Wang C, He Q K, Qiu Y 2012 Acta Phys. Sin. 61 134701 (in Chinese) [何春涛, 王聪, 何乾坤, 仇洋 2012 61 134701]
[3] Birkhoff G, Caywood T E 1949 J. Appl. Phys. 20 646
[4] Weninger K R, Cho H, Hiller R A, Putterman S J, Williams A 1997 Phys. Rev. E 56 6745
[5] May A 1970 J. Hydrodyn. 4 140
[6] Waugh J G 1968 J. Hydrodyn. 2 87
[7] Jiang Y H, Xu S L, Zhou J 2016 J. Ballistics 28 81 (in Chinese) [蒋运华, 徐胜利, 周杰 2016 弹道学报 28 81]
[8] Stern S A, Tallentire F I 1985 J. Spacecraft Rockets 22 668
[9] Wilson Q, Sahota B S 1980 Proceedings of the 12th Annual Offshore Technology Conference Houston, USA, May 5-8, 1980 p5
[10] Lu Z L, Wei Y J, Wang C, Sun Z 2016 J. Beijing Univ. Aeronaut Astronaut 42 2403 (in Chinese) [路中磊, 魏英杰, 王聪, 孙钊 2016 北京航空航天大学学报 42 2403]
[11] Lu Z L, Wei Y J, Wang C, Sun Z 2016 Acta Phys. Sin. 65 014704 (in Chinese) [路中磊, 魏英杰, 王聪, 孙钊 2016 65 014704]
[12] Worthington A M, Cole R S 1900 Phil. Trans. Roy. Soc. 189A 175
[13] Silberman E, Song C S 1961 J. Ship Res. 5 13
[14] Brennen C 1970 J. Fluid Mech. 44 33
[15] Grumstrup T, Keller J B, Belmonte A 2007 Phys. Rev. Lett. 99 114502
[16] Bergmann R, van der M D, Gekle S, van der Bos A, Lohse D 2008 J. Fluid Mech. 633 381
[17] Abraham J, Gorman J, Reseghetti F, Sparrow E, Stark J, Shepard T 2014 Ocean Eng. 76 1
[18] Zhang X W, Zhang J Z, Wei Y J, Wang C 2008 J. Vibr. Shock. 40 52 (in Chinese) [张学伟, 张嘉钟, 魏英杰, 王聪 2008 振动与冲击 40 52]
[19] Logvinovich G V (Translated by Lederman D) 1972 Hydrodynamics of Free-Boundary Flows (Jersualem: IPST Press) pp104-118
[20] Haller G 2005 J. Fluid Mech. 525 1
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[1] May A 1951 J. Appl. Phys. 22 1219
[2] He C T, Wang C, He Q K, Qiu Y 2012 Acta Phys. Sin. 61 134701 (in Chinese) [何春涛, 王聪, 何乾坤, 仇洋 2012 61 134701]
[3] Birkhoff G, Caywood T E 1949 J. Appl. Phys. 20 646
[4] Weninger K R, Cho H, Hiller R A, Putterman S J, Williams A 1997 Phys. Rev. E 56 6745
[5] May A 1970 J. Hydrodyn. 4 140
[6] Waugh J G 1968 J. Hydrodyn. 2 87
[7] Jiang Y H, Xu S L, Zhou J 2016 J. Ballistics 28 81 (in Chinese) [蒋运华, 徐胜利, 周杰 2016 弹道学报 28 81]
[8] Stern S A, Tallentire F I 1985 J. Spacecraft Rockets 22 668
[9] Wilson Q, Sahota B S 1980 Proceedings of the 12th Annual Offshore Technology Conference Houston, USA, May 5-8, 1980 p5
[10] Lu Z L, Wei Y J, Wang C, Sun Z 2016 J. Beijing Univ. Aeronaut Astronaut 42 2403 (in Chinese) [路中磊, 魏英杰, 王聪, 孙钊 2016 北京航空航天大学学报 42 2403]
[11] Lu Z L, Wei Y J, Wang C, Sun Z 2016 Acta Phys. Sin. 65 014704 (in Chinese) [路中磊, 魏英杰, 王聪, 孙钊 2016 65 014704]
[12] Worthington A M, Cole R S 1900 Phil. Trans. Roy. Soc. 189A 175
[13] Silberman E, Song C S 1961 J. Ship Res. 5 13
[14] Brennen C 1970 J. Fluid Mech. 44 33
[15] Grumstrup T, Keller J B, Belmonte A 2007 Phys. Rev. Lett. 99 114502
[16] Bergmann R, van der M D, Gekle S, van der Bos A, Lohse D 2008 J. Fluid Mech. 633 381
[17] Abraham J, Gorman J, Reseghetti F, Sparrow E, Stark J, Shepard T 2014 Ocean Eng. 76 1
[18] Zhang X W, Zhang J Z, Wei Y J, Wang C 2008 J. Vibr. Shock. 40 52 (in Chinese) [张学伟, 张嘉钟, 魏英杰, 王聪 2008 振动与冲击 40 52]
[19] Logvinovich G V (Translated by Lederman D) 1972 Hydrodynamics of Free-Boundary Flows (Jersualem: IPST Press) pp104-118
[20] Haller G 2005 J. Fluid Mech. 525 1
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