超空泡射弹并联入水多相流场与弹道特性研究

摘要
图/表
参考文献(16)
相关文章 (15)

全文: PDF (2544 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要弹丸并联入水工况在实际作战环境中时有发生，然而针对超空泡射弹并联入水的研究较少。基于重叠网格技术，采用RANS方程，Schnerr-Sauer空化模型，Realizable k-ε湍流模型对超空泡射弹入水过程进行数值模拟，计算值与实验数据吻合情况良好，验证了数值方法的有效性。对不同弹丸间距及不同初速下的超空泡射弹开展多工况数值模拟，详细分析了并联超空泡射弹的入水流场特性及弹道特性。研究结果表明：弹丸间距过小将对弹道稳定性产生不利影响；初速一定时，弹丸间距越小，弹丸产生的空泡对称性越差，弹丸所受横向力越大，弹道稳定性越差；弹丸间距越小，弹丸内侧沾湿现象越明显，速度衰减越快；随着弹丸间距的增大，弹丸之间的干扰将逐渐减弱，当弹丸间距增加到3D时，两弹丸之间几乎无干扰。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	王辰1
	鹿麟1
	祁晓斌2
	闫雪璞1
	秦登辉3

关键词 ：并联入水, 数值模拟, 弹道特性, 计算流体力学

Abstract：The water entry condition of projectile in parallel often occurs in the actual combat environment. However, there were few studies on the parallel water entry of supercavitating projectile. Based on the overset mesh technique, the water entry process of projectile was numerically simulated by using RANS equation, Schnerr-Sauer cavitation model and Realizable k-ε turbulence model. The calculated values were in good agreement with the experimental data, which verified the effectiveness of the numerical method. The numerical simulation of projectiles with different projectile distance and different initial velocities was carried out, and the flow field characteristics and trajectory characteristics of parallel projectiles were analyzed in detail. The result shows that the close projectile distance will have an adverse effect on ballistic stability; When the initial velocity is constant, the closer the projectile distance is, the worse the symmetry of the cavitation is. And it also lead to the greater lateral force and the worse ballistic stability; The phenomenon of wetting on the inside of the projectile and velocity attenuation is more obvious in closer distance between projectile; With the increase of the projectiles distance, the interference between the projectiles will gradually weaken, and when the distance between the projectiles increases to 3D, there is almost no interference between the two projectiles.

Key words： parallel water-entry numerical simulation trajectory characteristics computational fluid dynamics

收稿日期: 2020-12-14 出版日期: 2022-05-28

引用本文:

王辰1，鹿麟1，祁晓斌2，闫雪璞1，秦登辉3. 超空泡射弹并联入水多相流场与弹道特性研究[J]. 振动与冲击, 2022, 41(10): 292-300.
WANG Chen1, LU Lin1, QI Xiaobin2, YAN Xuepu1,QIN Denghui3. Multiphase flow field and trajectory characteristics of two supercavitating projectiles in parallel water-entry. JOURNAL OF VIBRATION AND SHOCK, 2022, 41(10): 292-300.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2022/V41/I10/292

[1] 陈伟善,郭则庆,刘如石,黄振贵.空化器形状对超空泡射弹尾拍运动影响的数值研究[J].工程力学,2020,37(04):248-256.
CHEN Weishan, GUO Zeqing, LIU Rushi, HUANG Zhengui. Numerical simulation on the influence of cavitator shapes on the tail-slap of supercavitating projectiles [J]. Engineering Mechanics, 2020,37(04):248-256.
[2] 黄闯,党建军,李代金,等.跨声速运动对射弹阻力及空化特性的影响[J].兵工学报, 2016, 37(08):1482-1488.
HUANG Chuang, Dang Jianjun, Li Daijin, et al. Influence of transonic motion on resistance and cavitation characteristics of projectiles [J]. Acta Armamentarii, 2016, 37(08):1482-1488.
[3] 黄闯,罗凯,白杰,等.液体可压缩性对超空化流动的影响[J].上海交通大学学报,2016,50(08):1241-1245.
Huang Chuang, Luo Kai, Bai Jie, et al. Influence of liquid’s compressibility on supercavitating Flow [J]. Journal of ShangHai Jiao Tong University, 2016,50(08):1241-1245.
[4] 李达钦,张敏弟,黄彪,等.高速可压缩超空泡流动数值与理论研究[C]. 杭州:中国力学大会-2017暨庆祝中国力学学会成立60周年大会论文集(B), 2017.
LI Daqin, ZHANG Mindi, HUANG Biao, et al. Numerical simualtion of high speed compressible supercavitation flow [C]. The Chinese Congress of Theoretical Applied Mechanics, HangZhou, 2017.
[5] 陈晨,魏英杰,王聪.小型运动体高速倾斜入水空泡流动数值研究[J].兵工学报, 2019,40(2): 334-344.
CHEN Chen, WEI Yingjie, WANG Cong. Computational analysis of cavity flow induced by hgh-speed oblique water-entry of axisymmetric body [J]. Acta Armamentarii, 2019,40(2): 334-344.
[6] 赵成功,王聪,魏英杰,等.质心位置对超空泡射弹尾拍运动影响分析[J].北京航空航天大学学报.2014, 40(12):1754-1760.
ZHAO Chenggong, WANG Cong, WEI Yingjie, et al. Analysis of the effect of mass center position on tailslap of supercavitating projectile [J]. Journal of Beijing University of Aeronautics and Astronautics, 2014, 40(12):1754-1760.
[7] Qiang Li，Lin Lu. Numerical investigations of trajectory characteristics of a high-speed water-entry projectile [J].Aip Advance, 2020, 10: 95-107.
[8] Qiang Li，Lin Lu. Numerical investigations of cavitation nose structure of a high-speed projectile impact on water-entry characteristics [J]. Journal of Marine Science and Engineering, 2020, 8(4): 265.
[9] Mohammad Reza Erfanian, Morteza Anbarsooz, Nasrollah Rahimi, et al. Numerical and experimental investigation of a three dimensional spherical-nose projectile water entry problem [J]. Ocean Engineering, 2015, 104:397-404.
[10] John Abraham, John Gorman, Franco Reseghetti, et al. Modeling and numerical simulation of the forces acting on a sphere during early-water entry [J]. Ocean Engineering, 2014, 76:1-9.
[11] 何春涛,王聪,何乾坤,仇洋.圆柱体低速入水空泡试验研究[J].物理学报,2012,61(13):281-288.
HE Chuntao, WANG Cong, HE Qiankun, QIU Yang. Low speed water-entry of cylindrical projectile [J]. Acta Physica Sinica, 2012,61(13):281-288.
[12] 路丽睿,魏英杰,王聪,等.双圆柱体低速并联入水过程空泡及运动特性试验研究[J].振动与冲击,2019,38(07):42-49.
LU Lirui, WEI Yingjie, WANG Cong, et al. Tests for cavities and motion characteristics in process of two-cylinder in parallel water entry at low speed [J]. Journal of Vibration and Shock, 2019,38(07):42-49.
[13] 卢佳兴,王聪,魏英杰,路丽睿,等.轴线间距对圆柱体低速并联入水空泡演化影响试验研究[J].振动与冲击,2020,39(12):272-280.
LU Jiaxing, WANG Cong, WEI Yingjie, LU Lirui, et al. An experimental study on the effect of axis distances on the cavity evolution in the low-speed water [J]. Journal of Vibration and Shock, 2020,39(12):272-280.
[14] Schnerr G H and Sauer J. Physical and numerical modeling of unsteady cavitation dynamics[C]. In Fourth International Conference on Multiphase Flow, New Orleans, USA, 2001.
[15] Zitao Guo, Wei Zhang, Cong Wang. Experimental and theoretical study on the high-speed horizontal water entry behaviors of cylindrical projectiles[J]. Journal of Hydrodynamics, Ser. B, 2012, 24(2):217-225.
[16] 张鹤,魏英杰,王聪,樊继壮.并联射弹水下运动实验研究[J].舰船科学技术,2021,43(03):71-75.
ZHANG He,WEI Yingjie,WANG Cong,et al. Experimental study on underwater motion of parallel projectiles[J]. Ship Science and Technology, 2021,43(3):71-75.