[1] Dodd B, Bai Y. Adiabatic shear localization. frontiers and advances[M].London, UK:Elsevier, 2012. [2] Zheng C, Wang F, Cheng X, et al. Capturing of the propagating processes of adiabatic shear band in Ti-6Al-4V alloys under dynamic compression[J]. Materials Science & Engineering A, 2016, 658:60-67. [3] Marchand A, Duffy J. An experimental study of the formation process of adiabatic shear bands in a structural steel[J]. Journal of the Mechanics & Physics of Solids,1988, 36(3) : 251-283. [4] Meyer L W, Manwaring S. Critical adiabatic shear strength of low alloyed steel under compressive loading[C]∥Murr L E, Staudhammer K P, Meyers M A, editors. Metallurgical Applications of Shock-wave and High-strain-rate Phenomena. New York, NY, US: Marcel Dekker Inc.,1986:657-674. [5] Meyer L W, Staskewitsch E, Burblies A. Adiabatic shear failure under biaxial dynamic compression/shear loading[J]. Mechanics of Materials, 1994, 17(2/3): 203-214. [6] Hartmann K H, Kunze H D, Meyer L W. Metallurgical effects on impact loaded materials[M]∥Meyers M A, Murr L E. Shock Waves and High Strain Rate Phenomena in Metals, Concepts and Applications. New York,NY,US: Plenum Press, 1981:325-337. [7] Clos R, Schreppel U, Veit P. Temperature, microstructure and mechanical response during shear band formation in different metallic materials [J]. Journal de Physique, 2003, 110(4):111-116. [8] 虎宏智, 付应乾, 董新龙. TA2钛合金绝热剪切失稳起始温度研究[J].固体力学学报, 2016,37(5):438-443. HU Hong-zhi, FU Ying-qian, DONG Xin-long. Study on the temperature evolution of adiabatic shear initiation in hat-shaped specimens for TA2 titanium Alloy[J]. Chinese Journal of Solid Mechanics, 2016,37(5):438-443. (in Chinese) [9] Sokovikov M,Bilalov D,Oborin V, et al. Structural mechanisms of formation of adiabatic shear bands[J]. Frattura ed Integrità Strutturale, 2016,38: 296-304.
[10] Peirs J, Verleyse P, Degrieck J, et al. The use of hat-shaped specimens to study the high strain rate shear behaviour of Ti-6AL-4V[J]. International Journal of Impact Engineering, 2010,37(6): 703-714. [11] 付应乾,董新龙,虎宏智. 准静态和动态加载TA2工业纯钛受迫剪切破坏演化[J].中国有色金属学报,2015, 25(11): 3092-3099. FU Ying-qian, DONG Xin-long, HU Hong-zhi. Quasi-static and dynamic failure evolution of titanium alloy under forced shear loading[J]. The Chinese Journal of Nonferrous Metals, 2015, 25(11): 3092-3099.(in Chinese)
[12] Bronkhorst C A, Cerreta E K, Xue Q, et al. An experimental and numerical study of the localization behavior of tantalum and stainless steel[J]. Internation Journal of Plasticity, 2006,22 (7): 1304-1335. [13] Nemat-Nasser S, Isaacs J B, Liu M. Microstructure of high-strain, high-strain-rate deformed tantalum[J]. Acta Materialia,1998,46(4):1307-1325. [14] Pérez-Prado M T, Hines J A, Vecchio K S. Microstructural evolution in adiabatic shear bands in Ta and Ta-W alloys[J]. Acta Materialia, 2001,49 (15): 2905-2917. [15] 皮萨连科Γ C,列别捷夫 A A. 复杂应力状态下的材料变形与强度[M]. 江明行,译. 北京:科学出版社,1983:32-34. Πисаренко Г С, Лебедев A A. Deformation and strength of materials under complex stress conditions[M]. JIANG Ming-xing, translated. Beijing: Science Press, 1983:32-34. (in Chinese)
[16] 罗文波. 关于“平面纯剪切大变形等效应变分析”一文的讨论[J].塑形工程学报,2001,8(1):8. LUO Wen-bo. Discussion on the equivalent strain of large plane-pure-shear defomaton[J]. Journal of Plasticity Engineering, 2001, 8(1):8.(in Chinese)
[17] 董新龙, 付应乾. TA2 钛合金动态压缩试样中的绝热剪切破坏研究[J]. 兵工学报, 2014, 35(7): 1016-1020. DONG Xin-long, FU Ying-qian. Experimental and numerical study of adiabatic shear failure of TA2 titanium alloy under dynamic compression[J]. Acta Armamentarii, 2014, 35(7):1016-1020. (in Chinese) [18] Zhang Z, Clifton R J. Shear band propagation from a crack tip[J].Journal of the Mechanics and Physics of Solid,2003,51(11): 1903-1922.
第38卷第12期 2017 年12月兵工学报ACTA ARMAMENTARIIVol.38No.12Dec.2017
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