[1] Jussila J. Preparing ballistic gelatine—review and proposal for a standard method [J]. Forensic Science International, 2004, 141(2): 91-98. [2] Cronin D S, Falzon C. Characterization of 10% ballistic gelatin to evaluate temperature, aging and strain rate effects [J]. Experimental Mechanics, 2010, 51(7): 1197-1206. [3] Cronin D S. Ballistic gelatin characterization and constitutive modeling [M]∥Dynamic Behavior of Materials: Volume 1. New York: Springer, 2011: 51-55. [4] Cronin D S, Falzon C. Dynamic characterization and simulation of ballistic gelatin [C]∥SEM Conference and Exposition on Experimental and Applied Mechanics. New Mexico, US: Society for Experimental Mechanics, 2009: 1-4. [5] Salisbury C P, Cronin D S. Mechanical properties of ballistic gelatin at high deformation rates[J]. Experimental Mechanics, 2009, 49(6): 829-840. [6] Kwon J, Subhash G. Compressive strain rate sensitivity of ballistic gelatin [J]. Journal of Biomechanics, 2010, 43(3): 420-425. [7] Parker N G, Povey M J W. Ultrasonic study of the gelation of gelatin: phase diagram, hysteresis and kinetics [J]. Food Hydrocolloids, 2012, 26(1): 99-107. [8] Nagayama K, Mori Y, Motegi Y, et al. Shock Hugoniot for biological materials [J]. Shock Waves, 2006, 15(3-4): 267-275. [9] Appleby-Thomas G J, Hazell P J, Wilgeroth J M, et al. On the dynamic behavior of three readily available soft tissue simulants [J]. Journal of Applied Physics, 2011, 109(8): 1-6. [10] Aihaiti M, Hemley R J. Equation of state of ballistic gelatin (Ⅱ) [R]. US: Carinegie Institutioin of Washington DC Geophysical Lab, 2011. [11] Shen W, Niu Y, Bykanova L, et al. Characterizing the interaction among bullet, body armor, and human and surrogate targets [J]. Journal of Biomechanical Engineering, 2010, 132(12): 121001. [12] Koene L, Papy A. Experimental and numerical study of the impact of shperical projectiles on ballistic gelatin at velocities up to 160 m/s[C]∥25th International Symposium on Ballistics. Beijing, China: IBC, 2010: 1573-1579. [13] Datoc D. Fnite element analysis and modeling of a.38 lead round nose ballistic gelatin test [R]. San Luis Obispo, US: California Polytechnic State University, 2010. [14] Minisi M D. Gelatin Impact Modeling, PM-MAS ES-1A-9000[R]. [2013-04-10]. Http:∥dtic.mil/ndia/2006smarlla-rms/minisi.pdf. [15] 温垚珂,徐诚,陈爱军,等. 球形破片高速侵彻明胶靶标的数值模拟[J]. 弹道学报, 2012, 24(3): 25-30. WEN Yao-ke, XU Cheng, CHEN Ai-jun, et al. Numerical simulation ofspherical fargments penetrating into ballistic gelatin at high velocity[J]. Journal of Ballistics, 2012, 24(3): 25-30. (in Chinese) [16] 温垚珂,徐诚,陈爱军,等. 步枪弹侵彻明胶靶标的数值模拟[J]. 兵工学报, 2013, 34(1): 14-19. WEN Yao-ke, XU Cheng, CHEN Ai-jun, et al. Numerical simulation of the penetration of bullet on gelatin target[J]. Acta Armamentarii, 2013, 34(1): 14-19. (in Chinese) [17] Hallquist J O. LS-DYNA keyword user's manual volume Ⅱ: material models[M]. CA, US: Livermore Software Technology Corporation, 2012. [18] Du-Bois P A. A simplified approach to the simulation of rubber-like materials under dynamic loading [C]∥4th European LS-DYNA Users Conference. ULM, Germany: Livemore Software Technology Corporation, 2003: 31-45. [19] Kolling S, Du-Bois P A, Benson D J, et al. A tabulated formulation of hyperelasticity with rate effects and damage [J]. Computational Mechanics, 2007, 40(5): 885-899. [20] Benson D J, Kolling S, Du-Bois P A. A simplified approach for strain-rate dependent hyperelastic materials with damage[C]∥9th International LS-DYNA Users Conference. Detroit, US: Livemore Software Technology Corporation, 2006: 29-51. [21] Feng W W, Hallquist J O. A failure criterion for polymers and soft biological materials[C]∥5th European LS-DYNA Users Conference. Birmingham, UK: Livemore Software Technology Corporation, 2005: 1-10. [22] 吕洪生, 曾新吾. 连续介质力学(下):动载固体力学与应力波 [M]. 长沙: 国防科技大学出版社,1999. LYU Hong-sheng, ZENG Xin-wu. Continuum mechanics: dynamical solid mechanics and stress waves[M]. Changsha: National University of Defense Technology Publish House, 1999. (in Chinese) [23] Johnson A F, Holzapfel M. Numerical prediction of damage in composite structures from soft body impacts [J]. Journal of Materials Science, 2006, 41(20): 6622-6630. [24] Wilbeck J S. Impact behavior of low strength projectiles, AFML-TR-77-134[R]. US: Air Force Materials Laboratory, 1978. |