超空泡射弹小入水角高速斜入水试验研究

doi:10.3969/j.issn.1000-1093.2020.02.015

兵工学报 ›› 2020, Vol. 41 ›› Issue (2): 332-341.doi: 10.3969/j.issn.1000-1093.2020.02.015

超空泡射弹小入水角高速斜入水试验研究

侯宇，黄振贵，郭则庆，陈志华，刘如石，罗驭川

(南京理工大学瞬态物理国家重点实验室，江苏南京 210094)

收稿日期:2019-03-18 修回日期:2019-03-18 上线日期:2020-04-04
通讯作者: 黄振贵（1986—），男，副研究员，硕士生导师 E-mail:hzgkeylab@njust.edu.cn
作者简介:侯宇（1993—），男，博士研究生。E-mail: houyu@njust.edu.cn
基金资助:
装备发展部装备预先研究基金项目(61426040303162604004、614260403041803)；中央高校基本科研业务费专项项目（309190112A2、30917012101）；江苏省研究生科研与创新计划项目（KYCX19_0259）

Experimental Investigation on Shallow-angle Oblique Water-entry of a High-speed Supercavitating Projectile

HOU Yu， HUANG Zhengui， GUO Zeqing， CHEN Zhihua， LIU Rushi， LUO Yuchuan

(National Key Laboratory of Transient Physics， Nanjing University of Science and Technology， Nanjing 210094， Jiangsu， China)

Received:2019-03-18 Revised:2019-03-18 Online:2020-04-04

摘要/Abstract

摘要： 为研究超空泡射弹小入水角高速斜入水性能，利用高速摄像技术开展了超空泡射弹入水试验。沿水下弹道轨迹的左侧等距布置压力传感器测试压力变化，分析弹体不同侧滑角入水冲击过程的弹道轨迹、喷溅演变和水下压力波传播特征。结果表明：对于射弹小入水角高速斜入水，弹体小侧滑角入水能形成较光滑透明的入水空泡和稳定的入水弹道，较大的侧滑角易造成空泡内严重雾化、弹道轨迹偏转和弹体损坏等现象，严重程度随侧滑角增大而增大；小侧滑角下弹头空化器及圆锥段斜面与水面的撞击使得入水喷溅在俯视下呈左右近似对称的“蝶”状，侧滑角对前半部分喷溅的左右对称性影响较小，对后半部分喷溅的对称性和范围影响较大，前半部分喷溅的对称轴随着侧滑角增大会出现相应偏转；入水冲击产生的水下压力波变化过程可分成两阶段：由弹体和水域冲击产生的初始压力波动阶段和各压力波叠加的高频脉动阶段，两阶段压力波动因侧滑角增加后入水状态的不同而呈现不同的变化特征。

关键词: 超空泡射弹, 小入水角, 入水试验, 侧滑角, 喷溅, 水下压力波

Abstract: The shallow-angle oblique water-entry of a high-speed supercavitating projectile is studied by using the high-speed photography technology. The characteristics of the ballistic trajectory, splash formation and underwater pressure wave propagation during the initial water-entry impact at different sideslip angles are observed and analyzed from the underwater pressure signal monitored along the left side of the trajectory. The results show that the small sideslip angle of the projectile has few effect on the smooth cavity formation and the enter trajectory stability during the high-speed oblique water-entry at small entry angle. The larger sideslip angle is able to lead to the severe water atomization in the cavity, the ballistic deflection and the projectile damage. The increase in the sideslip angle can exacerbate this instability. The impacts of the cavitator and the warhead conical section on the free surface at a small entry angle make the splash be an approximate symmetrical “butterfly shape” in birds-eye view. The sideslip angle has inverse influence on the symmetry of the front half of splash comparing with the rear half of splash. Large changes are presented in the splash range with the increase in sideslip angle. The symmetry axis of the front half of splash is deflected with the increase in sideslip angle. The changing process of underwater pressure wave induced by the water-entry impact is divided into two stages: the initial pressure fluctuation stage induced by the initial impact of the projectile on the water and the fluctuation stage of high frequency induced by the superposition of the pressure waves from various directions. The two pressure fluctuation stages show different variation characteristics with the corresponding water entry state due to the increased sideslip angle.Key

Key words: supercavitatingprojectile, shallowentryangle, water-entryexperiment, sideslipangle, splash, underwaterpressurewave

中图分类号:

TJ630.1

侯宇，黄振贵，郭则庆，陈志华，刘如石，罗驭川. 超空泡射弹小入水角高速斜入水试验研究[J]. 兵工学报, 2020, 41(2): 332-341.

HOU Yu， HUANG Zhengui， GUO Zeqing， CHEN Zhihua， LIU Rushi， LUO Yuchuan. Experimental Investigation on Shallow-angle Oblique Water-entry of a High-speed Supercavitating Projectile[J]. Acta Armamentarii, 2020, 41(2): 332-341.

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第41卷
第2期2020 年2月兵工学报ACTA
ARMAMENTARIIVol.41No.2Feb.2020

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超空泡射弹小入水角高速斜入水试验研究

Experimental Investigation on Shallow-angle Oblique Water-entry of a High-speed Supercavitating Projectile

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