Analysis of Material Flow around Projectile Nose by Elbow-streamline Model during Long-rod Projectile Penetrating into Steel Target

doi:10.3969/j.issn.1000-1093.2019.09.004

Abstract

Abstract: In order to study the two-dimensional rheological behavior of a long-rod projectile penetrating into steel target, a two-dimensional elbow-streamline penetration model was developed based on long-rod projectile hydrodynamic penetration model, mass conservation during penetration and elbow model. The impact velocity, reference point angle and reference point radius are considered in the proposed model. The material flow around the nose of tungsten long-rod projectile penetrating into a steel target was analyzed based on the proposed model and compared with the test results. The results show that the material flow around the tungsten long-rod projectile nose is non-uniformly distributed, and the flow velocity on the outer side is less than that on the inner side. The pressure on the long-rod projectile nose material is distributed gradiently. The proposed model is used to describe the material flow of long-rod projectile nose during penetration, and explain the process of transition from fluid to solid in the projectile nose at the final stage of penetration. It reveals the relation between the change of ballistics channel and the penetration state transition of projectile. Key

Key words: long-rodprojectile, high-velocitypenetration, impactdynamics, elbow-streamlinemodel, nosematerial, fluiddynamics

CLC Number:

O385
TJ012.4

CHEN Haihua, ZHANG Xianfeng, LIU Chuang, DING Li, WANG Jipeng, DU Ning. Analysis of Material Flow around Projectile Nose by Elbow-streamline Model during Long-rod Projectile Penetrating into Steel Target[J]. Acta Armamentarii, 2019, 40(9): 1787-1796.

References

［1］王杰, 武海军, 杨荷,等. 高速/超高速侵彻半无限靶研究进展［J］. 兵工学报, 2017, 38(增刊1):73-88.
WANG J, WU H J, YANG H, et al. Research progress in penetration of projectiles into semi-infinite targets at high velocity/hypervelocity［J］.Acta Armammentarii,2017, 38(S1):73-88.（in Chinese）
［2］孔祥振, 方秦, 吴昊, 等. 长杆弹超高速侵彻半无限靶理论模型的对比分析与讨论［J］. 振动与冲击, 2017, 36(20):37-43,58.
KONG X Z, FANG Q, WU H, et al. Comparison of long rod high velocity penetration models for semi-infinite targets ［J］. Journal of Vibration and Shock, 2017, 36(20):37-43,58. （in Chinese）
［3］肖云凯, 吴昊, 方秦. 长杆弹超高速侵彻金属靶体的实验和模型分析［J］. 兵工学报, 2017, 38(增刊1):15-23.
XIAO Y K, WU H, FANG Q. Experiment and theoretical model analysis of hypervelocity penetration of long-rod projectiles into metallic targets ［J］. Acta Armammentarii, 2017,38(S1):15-23. （in Chinese）
［4］ LU Z C, WEN H M. On the penetration of high strength steel rods into semi-infinite aluminium alloy targets［J］. International Journal of Impact Engineering, 2018, 111:1-10.
［5］ TATE A. A theory for the deceleration of long rods after impact ［J］. Journal of the Mechanics & Physics of Solids, 1967, 15(6): 387-399.
［6］ TATE A. Further results in the theory of long rod penetration［J］. Journal of the Mechanics & Physics of Solids, 1969, 17(3):141-150.
［7］ ALEKSEEVSKII V P. Penetration of a rod into a target at high velocity［J］. Combustion, Explosion and Shock Waves, 1966, 2(2): 63-66.
［8］ TATE A. A simple hydrodynamic model for the strain field produced in a target by the penetration of a high speed long rod projectile［J］. International Journal of Engineering Science, 1978, 16(11):845-858.
［9］ TATE A. A comment on a paper by Awerbuch and Bodner concerning the mechanics of plate perforation by a projectile［J］. International Journal of Engineering Science, 1979, 17(3):341-344.

［10］ TATE A. Long rod penetration models-part I. A flow field model for high speed long rod penetration ［J］. International Journal of Mechanical Sciences, 1986, 28(8):535-548.
［11］ TATE A. Long rod penetration models-part II. Extensions to the hydrodynamic theory of penetration［J］. International Journal of Mechanical Sciences, 1986, 28(9):599-612.
［12］ WALTERS W P, SEGLETES S B. An exact solution of the long rod penetration equations［J］. International Journal of Impact Engineering, 1991, 11(2):225-231.
［13］ ANDERSON J C E, WALKER J D. An examination of long-rod penetration［J］. International Journal of Impact Engineering, 1991, 11(4):481-501.
［14］ ANDERSON J C E, LITTLEFIELD D L, WALKER J D. Long-rod penetration, target resistance, and hypervelocity impact［J］.
International Journal of Impact Engineering, 1993, 14(1/2/3/4):1-12.
［15］ ANDERSON J C E, WALKER J D, BLESS S J, et al. On the LD effect for long-rod penetrators［J］. International Journal of Impact Engineering, 1996, 18(3):247-264.
［16］ ANDERSON J C E, HOHLER V, WALKER J D, et al. Influence of projectile hardness on ballistic performance［J］. International Journal of Impact Engineering, 1999, 22(6):619-632.
［17］ ANDERSON J C E, ORPHAL D L, FRANZEN R R, et al. On the hydrodynamic approximation for long-rod penetration［J］. International Journal of Impact Engineering, 1999, 22(1):23-43.
［18］ WALKER J D, ANDERSON J C E . A time-dependent model for long-rod penetration［J］. International Journal of Impact Engineering, 2015, 16(1):19-48.
［19］孙庚辰, 吴锦云, 赵国志,等. 长杆弹垂直侵彻半无限厚靶板的简化模型［J］. 兵工学报, 1981, 2(4):1-8.
SUN G C, WU J Y, ZHAO G Z, et al. A simplified model of the penetration of the long-rod penetrator against the plates with semi-infinite thickness at normal angle ［J］. Acta Armammentarii, 1981, 2(4):1-8. （in Chinese）
［20］ ZHANG L S, HUANG F L. Model for long-rod penetration into semi-infinite targets［J］. Journal of Beijing University of Science and Technology, 2004, 13(3):285-289.
［21］兰彬. 长杆弹侵彻半无限靶的数值模拟和理论研究［D］. 合肥：中国科学技术大学, 2008.
LAN B. A combined numerical and theoretical study of long rod penetration into semi-infinite targets［D］. Hefei：University of Science and Technology of China, 2008. （in Chinese）
［22］白以龙. 材料和结构的动态响应［M］. 合肥：中国科学技术大学出版社, 2005.
BAI Y L. Dynamic response of materials and structures ［M］. Hefei: University of Science and Technology of China Press, 2005.(in Chinese)
［23］ LEE M, BLESS S. Cavity dynamics for long rod penetration［R］. Austin,TX, US: University of Texas at Austin, 1996.
［24］吴群彪, 沈培辉, 刘荣忠,等. 长杆体稳定侵彻阶段头部形状的侵彻效率分析［J］. 兵器材料科学与工程, 2014, 37(3):80-83.
WU Q B, SHEN P H, LIU R Z, et al. Long rod penetration efficiency analysis of nose shape at quasi-steady penetration stage ［J］. Ordnance Material Science and Engineering, 2014, 37(3): 80-83. （in Chinese）
［25］ FORRESTAL M J, LONGCOPE D B, NORWOOD F R. A mo-del to estimate forces on conical penetrators into dry porous rock［J］. Journal of Applied Mechanics, 1981, 48(1):25.
［26］ FORRESTAL M J, NORWOOD F R, LONGCOPE D B. Penetration into targets described by locked hydrostats and shear strength［J］. International Journal of Solids & Structures, 1981, 17(9):915-924.
［27］ WRIGHT T W, FRANK K. Approaches to penetration problems: MD 21005-5066 ［R］. Aberdeen Proving Ground, MD,US: Ballistic Research Laboratory, 1988.
［28］林晓. 撞击与侵彻力学［M］. 北京：兵器工业出版社, 1992.
LIN X. Impact and penetration mechanics ［M］. Beijing: Publising House of Ordnance Industry, 1992. （in Chinese）
［29］杜广生, 田瑞, 王国玉,等. 工程流体力学［M］. 北京：中国电力出版社, 2005.
DU G S, TIAN R, WANG G Y, et al. Engineering fluid mechanics ［M］. Beijing: China Electric Power Press, 2005. （in Chinese）

第40卷
第9期2019 年9月兵工学报ACTA
ARMAMENTARIIVol.40No.9Sep.2019

[1]	WANG Tailin, WANG Ye, ZHANG Fuyi, CHEN Huiyan, WANG Guoyu. Design and Simulation of Vector Nozzle on Amphibious Vehicle [J]. Acta Armamentarii, 2022, 43(4): 826-850.
[2]	LIU Tielei, XU Yuxin, WANG Xiaofen, ZHANG Peng, ZHANG Jian. Ballistic Limit Calculation Model of Tungsten Alloy Spherical Fragments Penetrating into Low Carbon Steel Plate [J]. Acta Armamentarii, 2022, 43(4): 768-779.
[3]	ZHU Yifei, LIN Defu, MO Li, YE Jianchuan. Transient Aerodynamic Interference between Rotor and Fuselage for a Quadcopter [J]. Acta Armamentarii, 2022, 43(2): 410-422.
[4]	LIU Shuang, HE Guanghua, WANG Wei, GAO Yun. Effect of Appendages on Hydrodynamic Characteristics of Submarine in Stratified Fluid [J]. Acta Armamentarii, 2021, 42(1): 108-117.
[5]	XU Lucheng， HAO Xueying， XIAO Kaitao， SONG Weiwei， CHEN Chunsheng. Simulation Study of Screening Efficiency of Explosive Smoke Bomb [J]. Acta Armamentarii, 2020, 41(7): 1299-1306.
[6]	ZHONG Yang， WANG Liangming， WU Yingfeng. Calculation of Trajectory of High-speed Spinning Projectile Based on Computational Fluid Dynamics/Rigid Body Dynamics Coupling [J]. Acta Armamentarii, 2020, 41(6): 1085-1095.
[7]	QUAN Hui, XIE Jian, LI Liang, ZHANG Li. Jet from Exhaust Tunnel Outlet on Rocket Launch Site [J]. Acta Armamentarii, 2020, 41(6): 1111-1122.
[8]	CHENG Xiao， ZHU Maotao, TIAN Naili. Numerical Analysis of Effect of Liquid-gas Two-phase Flow on the Drag Torque Characteristics of Wet Clutch [J]. Acta Armamentarii, 2020, 41(5): 850-857.
[9]	WANG Lili，LIU Ying，LI Daqin，WU Qin，WANG Guoyu. Numerical Study of Underwater Supersonic Gas Jets for Solid Rocket Engine [J]. Acta Armamentarii, 2019, 40(6): 1161-1170.
[10]	ZHENG Qiuya, SU Ningya, LIANG Yihua. High Accuracy Flux Splitting Method for Numerical Solution of Euler Equation [J]. Acta Armamentarii, 2019, 40(12): 2545-2550.
[11]	ZHAO Xinyi， ZHOU Kedong， HE Lei， LU Ye， LI Junsong. Wavelet Analysis and Numerical Simulation of Jet Noise induced by a Large Caliber Small Arms [J]. Acta Armamentarii, 2019, 40(11): 2195-2203.
[12]	ZHANG Manman， JIANG Yi， CHENG Lidong， YANG Hua， LIU Qi. Numerical Analysis of Separation of Supersonic Submunition Based on Nested Grid [J]. Acta Armamentarii, 2019, 40(1): 79-88.
[13]	DU Pei-pei， LU Jun-yong， FENG Jun-hong， LI Xiang-ping. Numerical Simulation and Analysis of Flow Field during Dynamic Launching of Electromagnetic Rail Launcher Based onOverlapping Multi-block Structured Mesh [J]. Acta Armamentarii, 2018, 39(2): 234-244.
[14]	SUO Wen-chao， XU Xiang， GENG Fei. Optimization of Radiator Core Shape of Vehicle Engine Based on CFD [J]. Acta Armamentarii, 2017, 38(9): 1839-1844.