Water entry simulation analysis of a truncated projectile

M. M. Cao; S. Y. Wu; Z. Y. Shao

doi:10.1088/1742-6596/2047/1/012006

Water entry simulation analysis of a truncated projectile

M. M. Cao, S. Y. Wu, Z. Y. Shao^*

^*此作品的通讯作者

机电学院

Beijing Institute of Technology

科研成果: 期刊稿件 › 会议文章 › 同行评审

摘要

In order to explore the influence of the bevel angle of the projectile on the vertical velocity attenuation characteristics and cavitation of the projectile after it enters the water vertically, this paper uses numerical simulation to analyze the bevel angles of 45°, 30°, 25° and 20°. At the same time, the high-speed camera is used to study the vertical penetration of the projectile with a 45° bevel angle to verify the simulation model. The research results show that the vertical velocity decays exponentially, and the trajectory of the truncated projectile is bent after entering the water so that an asymmetric open cavitation occurs. The bevel angle will affect the degree of trajectory curvature, velocity attenuation and the shape of the cavity. The larger the bevel angle, the greater the degree of trajectory curvature; the smaller the bevel angle, the slenderer the cavity and the smaller the asymmetry.

源语言	英语
文章编号	012006
期刊	Journal of Physics: Conference Series
卷	2047
期	1
DOI	https://doi.org/10.1088/1742-6596/2047/1/012006
出版状态	已出版 - 25 10月 2021
活动	4th International Conference on Material Strength and Applied Mechanics, MSAM 2021 - Macau, Virtual, 中国期限: 16 8月 2021 → 19 8月 2021

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title = "Water entry simulation analysis of a truncated projectile",

abstract = "In order to explore the influence of the bevel angle of the projectile on the vertical velocity attenuation characteristics and cavitation of the projectile after it enters the water vertically, this paper uses numerical simulation to analyze the bevel angles of 45°, 30°, 25° and 20°. At the same time, the high-speed camera is used to study the vertical penetration of the projectile with a 45° bevel angle to verify the simulation model. The research results show that the vertical velocity decays exponentially, and the trajectory of the truncated projectile is bent after entering the water so that an asymmetric open cavitation occurs. The bevel angle will affect the degree of trajectory curvature, velocity attenuation and the shape of the cavity. The larger the bevel angle, the greater the degree of trajectory curvature; the smaller the bevel angle, the slenderer the cavity and the smaller the asymmetry.",

author = "Cao, {M. M.} and Wu, {S. Y.} and Shao, {Z. Y.}",

note = "Publisher Copyright: {\textcopyright} 2021 Institute of Physics Publishing. All rights reserved.; 4th International Conference on Material Strength and Applied Mechanics, MSAM 2021 ; Conference date: 16-08-2021 Through 19-08-2021",

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AU - Shao, Z. Y.

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N2 - In order to explore the influence of the bevel angle of the projectile on the vertical velocity attenuation characteristics and cavitation of the projectile after it enters the water vertically, this paper uses numerical simulation to analyze the bevel angles of 45°, 30°, 25° and 20°. At the same time, the high-speed camera is used to study the vertical penetration of the projectile with a 45° bevel angle to verify the simulation model. The research results show that the vertical velocity decays exponentially, and the trajectory of the truncated projectile is bent after entering the water so that an asymmetric open cavitation occurs. The bevel angle will affect the degree of trajectory curvature, velocity attenuation and the shape of the cavity. The larger the bevel angle, the greater the degree of trajectory curvature; the smaller the bevel angle, the slenderer the cavity and the smaller the asymmetry.

AB - In order to explore the influence of the bevel angle of the projectile on the vertical velocity attenuation characteristics and cavitation of the projectile after it enters the water vertically, this paper uses numerical simulation to analyze the bevel angles of 45°, 30°, 25° and 20°. At the same time, the high-speed camera is used to study the vertical penetration of the projectile with a 45° bevel angle to verify the simulation model. The research results show that the vertical velocity decays exponentially, and the trajectory of the truncated projectile is bent after entering the water so that an asymmetric open cavitation occurs. The bevel angle will affect the degree of trajectory curvature, velocity attenuation and the shape of the cavity. The larger the bevel angle, the greater the degree of trajectory curvature; the smaller the bevel angle, the slenderer the cavity and the smaller the asymmetry.

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T2 - 4th International Conference on Material Strength and Applied Mechanics, MSAM 2021

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Water entry simulation analysis of a truncated projectile

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