基于ALE算法的高速水射流对船体表面冲击特性研究

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摘要为探究水射流清洗附着物对船体表面的损伤影响，基于ALE算法研究了不同入射角θ和不同流速v冲击船体表面过程中射流的冲击压力特征和应力特征。结果显示随着入射角θ增大，靶件所受冲击压力会出现水锤压力与滞止压力阶段。高压水射流动能在适当入射角θ增加，入射角过大（θ=20°）反而会使其降低。以一定入射角θ冲击靶体时由于剪切效应加强靶体表面与内部应力分布比垂直冲击时更复杂，得出对船体表面材料影响最小的参数组合和最大主应力与射流参数入射角和速度的拟合公式。研究结果对水射流清洗船体表面附着物的应用具有较好的理论意义与实际应用价值。

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	方珍龙1
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关键词 ：水射流冲击, ALE算法, 冲击压力, 应力特征

Abstract：In order to explore the damage effect of water jet cleaning on the hull surface, based on ALE algorithm, the impact pressure and stress characteristics of water jet impacting hull surface with different incidence angle θ and different flow velocity v were studied. The results show that with the increase of incidence angle θ, the impact pressure on the target will appear in the stages of water hammer pressure and stagnation pressure. The kinetic energy of high pressure water jet increases at the appropriate incident angle θ, but decreased when the incident Angle is too large (θ=20°). The stress distribution on the surface and interior of the target strengthened by shear effect at a certain incident angle θ is more complex than that under vertical impact, the parameter combination with the least influence on the hull surface material and the fitting formula between the maximum principal stress and the incident angle and velocity of the jet parameters are obtained. The research results have good theoretical significance and practical value for the application of water jet cleaning on hull surface.

Key words： water jet impact Arbitrary Lagrange-Euler (ALE) algorithm impact pressure stress characteristics.

收稿日期: 2022-08-09 出版日期: 2023-09-15

引用本文:

熊庭1,2,3，康丁2,3,4，方珍龙1,2,3. 基于ALE算法的高速水射流对船体表面冲击特性研究[J]. 振动与冲击, 2023, 42(17): 17-24.
XIONG Ting1,2,3, KANG Ding2,3,4, FANG Zhenlong1,2,3. Impact characteristics analysis of high-speed water jet against hull surface based on ALE algorithm. JOURNAL OF VIBRATION AND SHOCK, 2023, 42(17): 17-24.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2023/V42/I17/17

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