[1] TAYLOR G I. The fragmentation of tubular bombs[M]∥ATCHELOR G K B. The Scientific Papers of G. I. Taylor. Cambridge, UK: Cambridge University Press,1963:387-390. [2] MOTT N F. Fragmentation of shell cases[J]. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences,1947,189(1018):300-308. [3] GRADY D E. Impact failure and fragmentation properties of tungsten carbide[J]. International Journal of Impact Engineering,1999,23(1):307-317. [4] GRADY D E. Fragmentation of rings and shells[M]. New York, NY, US: Springer Verlag, 2006. [5] GRADY D E, OLSEN M L. A statistics and energy based theory of dynamic fragmentation[J]. International Journal of Impact Engineering,2003,29(1):293-306. [6] ARNOLD W, ROTTENKOLBER E. Fragment mass distribution of metal cased explosive charges[J]. International Journal of Impact Engineering, 2008, 35(12):1393–1398. [7] 俞鑫炉,董新龙,付应乾,等.金属柱壳外爆膨胀断裂特性的数值模拟研究[J].兵工学报,2014,35(增刊2):257-262. YU X L, DONG X L,FU Y Q, et al. Numerical simulation study on fracture mechanism of cylindrical shells subjected to explosive loading[J]. Acta Armamentarii,2014,35(S2):257-262.(in Chinese) [8] 朱建军,李伟兵,李文彬,等.高应变率下金属柱壳动态变形及形成破片特性研究[J].兵工学报,2017,38(10):1933-1941. ZHU J J, LI W B, LI W B, et al. Dynamic deformation and fracture fragmentation behavior of metal cylindrical shell at high strain rates[J]. Acta Armamentarii,2017,38(10):1933-1941.(in Chinese) [9] GRISARO H Y, DANCYGIER A N. Spatial mass distribution of fragments striking a protective structure[J]. International Journal of Impact Engineering, 2017, 112:1-14. [10] GRISARO H Y, DANCYGIER A N. Model of fragmentation distribution over a protective wall[J]. International Journal of Impact Engineering, 2019, 128:1-10. [11] AN X Y, YE P, LIU J Y, et al. Dynamic fracture and fragmentation characteristics of metal cylinder and rings subjected to internal explosive loading[J]. Materials,2020,13(3):778-795. [12] KONG X S, WU W G,LI J, et al. A numerical investigation on explosive fragmentation of metal casing using smoothed particle hydrodynamic method[J]. Materials and Design, 2013, 51:729-741. [13] LIAO W, JIANG J W, MEN J B, et al. Effect of the end cap on the fragment velocity distribution of a cylindrical cased charge[J]. Defence Technology,2021,17(3): 1052-1061. [14] 李春雷,张志彪,王雨时,等.某亚音速破甲弹弹底结构破片安全性改进[J].弹箭与制导学报,2018,38(1):27-30, 40. LI C L, ZHANG Z B, WANG Y S, et al. Safety improvement of the fragment of projectile base structure of a subsonic high explosive anti-tank projectile[J].Journal of Projectiles,Rockets,Missiles and Guidance,2018,38(1):27-30, 40.(in Chinese) [15] 朱建军,李伟兵,王晓鸣,等.回火温度对50SiMnVB钢壳体形成破片性能的影响[J].兵工学报,2015,36(11):2080-2086. ZHU J J, LI W B, WANG X M, et al. Effect of tempering temperature on the forming properties of fragments of 50SiMnVB steel shell[J]. Acta Armamentarii,2015,36(11):2080-2086.(in Chinese) [16] 常列珍,张治民,范煜珩.回火温度对50SiMnVB合金钢动态力学性能的影响[J].中北大学学报(自然科学版),2009,30(5): 489-494. CHANG L Z, ZHANG Z M, FAN Y H. Effect of tempering temperature on dynamical properties of 50SiMnVB alloy steel[J]. Journal of North University of China(Natural Science Edition),2009,30(5):489-494.(in Chinese) [17] LI W, HUANG G Y, FENG S S. Effect of eccentric edge initiation on the fragment velocity distribution of a cylindrical casing filled with charge[J]. International Journal of Impact Engineering, 2015, 80:107-115. [18] 王韫泽,王树山,魏平亮,等.穿甲弹异物阻滞膛炸机理数值仿真分析[J].兵工学报,2018,39(5):859-866. WANG Y Z,WANG S S,WEI P L,et al. Numerical simulation and analysis of bore premature of armor piercer caused by foreign matter obstruction[J].Acta Armamentarii,2008,39(5):859-866. (in Chinese) [19] Л. П.奥尔连科.爆炸物理学[M].孙承玮,译.北京:科学出版社,2011. ORLENKO Л П. Explosion physics[M]. SUN C W, translated. Beijing: Science Press, 2011.(in Chinese) [20] 丁力,蒋建伟,门建兵,等.爆炸成型弹丸成型过程中的断裂数值模拟及机理分析[J].兵工学报,2017,38(3):417-423. DING L, JIANG J W, MEN J B, et al. Numerical simulation and mechanism analysis of EFP's fracture in forming process[J]. Acta Armamentarii,2017,38(3):417-423. (in Chinese)
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