Выходит 6 номеров в год
ISSN Печать: 2152-5102
ISSN Онлайн: 2152-5110
Indexed in
Experimental Studies of High-Speed Cavitated Flows
Краткое описание
Some experimental results on high-speed motion of models in water are presented. An empirical formula for calculating the shape of axisymmetric supercavities is derived. Qualitative features of supercavities at velocities commensurable with the speed of sound in water are described. A new method of controlling the parameters of supercavities by controlling the resistance of the cavitation generator is implemented experimentally.
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Saranjam B., Experimental and numerical investigation of an unsteady supercavitating moving body, Ocean Engineering, 59, 2013. Crossref
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Pan Zhan-cheng, Lu Chuan-jing, Chen Ying, Hu Shi-liang, Numerical study of periodically forced-pitching of a supercavitating vehicle, Journal of Hydrodynamics, 22, S1, 2010. Crossref
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Ping Wei, Jian Hou, Tingfeng Chen, Stability analysis and control of supercavitation projectile, 2012 IEEE International Conference on Intelligent Control, Automatic Detection and High-End Equipment, 2012. Crossref
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Rashidi I., Passandideh-Fard Mo., Pasandideh-Fard Ma., The Optimum Design of a Cavitator for High-Speed Axisymmetric Bodies in Partially Cavitating Flows, Journal of Fluids Engineering, 135, 1, 2013. Crossref
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Chen Y, Lu C J, Li J, Chen X, Gong Z X, On the non-equilibrium dynamics of cavitation around the underwater projectile in variable motion, Journal of Physics: Conference Series, 656, 2015. Crossref
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Guang-Ping Tian , Wei-Guang An , Ling Zhou , Simulation of supercavitating vehicle steady motion, 2008 International Conference on Machine Learning and Cybernetics, 2008. Crossref
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Zhang Xue-wei, Wei Ying-jie, Zhang Jia-zhong, Wang Cong, Yu Kai-ping, Experimental Research on the Shape Characters of Natural and Ventilated Supercavitation, Journal of Hydrodynamics, 19, 5, 2007. Crossref
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Pauzin Marie-Christine, Mensah Serge, Cochelin Bruno, Lefebvre Jean-Pierre, High order harmonic balance formulation of free and encapsulated microbubbles, Journal of Sound and Vibration, 330, 5, 2011. Crossref
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Kubenko V.D., Gavrilenko O.V., Impact interaction of cylindrical body with a surface of cavity during supercavitation motion in compressible fluid, Journal of Fluids and Structures, 25, 5, 2009. Crossref
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Zhao Jia-jun, Yu Yong-gang, The interaction between multiple high pressure combustion gas jets and water in a water-filled vessel, Applied Ocean Research, 61, 2016. Crossref
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Zou Wang, Liu Hua, Xue Lei-Ping, Three-dimensional ventilated supercavity on a maneuvering trajectory, Ocean Engineering, 122, 2016. Crossref
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Jiang Chen-Xing, Li Shu-Lei, Li Feng-Chen, Li Wan-You, Numerical study on axisymmetric ventilated supercavitation influenced by drag-reduction additives, International Journal of Heat and Mass Transfer, 115, 2017. Crossref
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Rashidi I., Pasandideh-Fard Ma., Passandideh-Fard Mo., Nouri N. M., Numerical and Experimental Study of a Ventilated Supercavitating Vehicle, Journal of Fluids Engineering, 136, 10, 2014. Crossref
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Jiang Yun Hua, An Wei Guang, An Hai, Dynamic Characteristics Analysis of Supercavitating Vehicle Structure with Stochastic Parameters, Advanced Materials Research, 430-432, 2012. Crossref
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Chen Chen, Sun Tiezhi, Wei Yingjie, Wang Cong, Computational analysis of compressibility effects on cavity dynamics in high-speed water-entry, International Journal of Naval Architecture and Ocean Engineering, 11, 1, 2019. Crossref
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Zhang Jiazhong, Liu Yan, Some Singularities in Fluid Dynamics and Their Bifurcation Analysis, in Complex Motions and Chaos in Nonlinear Systems, 15, 2016. Crossref
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Gao Jianguo, Chen Zhihua, Wu Wei-Tao, Li Xin, Numerical Investigations on the Water Entry of Cylindrical Projectiles with Different Initial Conditions, Applied Sciences, 9, 9, 2019. Crossref
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Fan Chunyong, Li Zengliang, Khoo B. C., Du Mingchao, Supercavitation phenomenon research of projectiles passing through density change area, AIP Advances, 9, 4, 2019. Crossref
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Nesteruk Igor, Drag Effectiveness of Supercavitating Underwater Hulls, in Supercavitation, 2012. Crossref
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Tehrani M.A., Firouz-Abadi R.D., An efficient system identification approach to estimate unsteady loads on cavitator plates, Ocean Engineering, 207, 2020. Crossref
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Huang Chuang, Luo Kai, Qin Kan, Li Daijin, Dang Jianjun, Performance Comparison of Bow and Stern Rudder for High-Speed Supercavitating Vehicles, Mathematical Problems in Engineering, 2020, 2020. Crossref
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Wang Rui, Yao Zhong, Li Daqin, Xu Baocheng, Wang Jiawen, Qi Xiaobin, Influence of head structure on hydrodynamic characteristics of transonic motion projectiles, International Journal of Naval Architecture and Ocean Engineering, 12, 2020. Crossref
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Zou Wang, Xue Leiping, Wang Benlong, Xiang Xintao, Gas flows and losses inside high-speed ventilated supercavitating flows, Ocean Engineering, 164, 2018. Crossref
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Yi Jong-Ju, Kim Min-Jae, Kim Seon-Hong, Paik Bu-Geun, Kim Kyung Chun, Prediction of supercavitation shapes for a wide range of Froude numbers, International Journal of Naval Architecture and Ocean Engineering, 14, 2022. Crossref
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Zou Wang, Zhang Xu, Shear layer on a ventilated supercavity wall, International Journal of Multiphase Flow, 135, 2021. Crossref
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Chen Ying, Lu Chuanjing, Chen Xin, Cao Jiayi, Numerical investigation on the cavitation collapse regime around the submerged vehicles navigating with deceleration, European Journal of Mechanics - B/Fluids, 49, 2015. Crossref
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Yang Yanxi, Wang Mengjun, Liu Pingan, Liu Junpeng, An experimental investigation of ventilated supercavity under the action of tail jet, Ocean Engineering, 266, 2022. Crossref