(1.Chongqing Hongyu Precision Industrial Group Co.,Ltd.,Chongqing 402760,China;2.School of Mechatronical Engineering,Beijing Institute of Technology,Beijing 100081,China)
[1] DIENES J K.Frictional hot-spots and propellant sensitivity[J].Materials Research Society Symposium Proceedings,1984,24:373-381. [2] 李尚昆,黄西成,王鹏飞.高聚物黏结炸药的力学性能研究进展[J].火炸药学报,2016,39(4): 1-11. LI S K,HUANG X C,WANG P F.Recent advances in the investigation on mechanical properties of PBX[J].Chinese Journal of Explosives and Propellants,2016,39(4):1-11.(in Chinese) [3] ARNOLD W,GUPTA A.Sensitivity and structural investigations on quasi-static and shock loaded KS22a high explosive[C]∥Proceedings of the 35th International Annual Conference of Institut Chemische Technologie. Karlsruhe,Germany: Institut Chemische Technologie,2004. [4] LEFRANCIOS A,LAMBERT P,CHESNET P,et al. Microstructural analysis of HE submitted to penetration experiments[C]∥Proceedings of the 31th International Pyrotechnics Seminar. FortCollins,CO,US:IPSUSA Seminars,Inc.,2004: 687-706. [5] 李亮亮,屈可朋,沈飞,等.基于霍普金森压杆的RDX基含铝炸药装药双脉冲加载实验[J].火炸药学报,2018,41(1):52-56. LI L L,QU K P,SHEN F,et al.Double-pulse loading experiment of RDX based aluminized explosive charge based on Hopkinson pressure bar[J].Chinese Journal of Explosives and Propellants,2018,41(1):52-56.(in Chinese) [6] 姚李娜,王海清,赵省向,等.温度对压装RDX基含铝炸药力学性能的影响[J].火工品,2017(3):45-48. YAO L N,WANG H Q,ZHAO S X,et al. Effects of temperature on mechanical properties of pressed RDX-based aluminized explosive[J].Initiators & Pyrotechnics,2017(3):45-48.(in Chinese) [7] 李亮亮,屈可朋,沈飞,等.摩擦效应对某PBX炸药动态力学性能的影响[J].火炸药学报,2016,39(6): 69-73. LI L L,QU K P,SHEN F,et al. Effect of friction effect on dynamic mechanical performances of a PBX explosives[J]. Chinese Journal of Explosives and Propellants, 2016, 39(6): 69-73. (in Chinese) [8] 王彩玲 赵省向,方伟,等. 热冲击对压装含铝炸药性能的影响[J]. 含能材料,2016,24(3): 244-248. WANG C L,ZHAO S X,FANG W,et al. Effects of thermal shock on the performance of a pressed aluminized explosive[J].Chinese Journal of Energetic Materials,2016,24(3):244-248. (in Chinese) [9] 张文英,邓晓雅,陈思瑾,等.PBX9501热感度、热膨胀及力学性能的分子动力学模拟[J].火炸药学报,2016,39(3):32-36. ZHANG W Y,DENG X Y,CHEN S J,et al. Molecular dynamics simulation of thermal sensitivity,thermal expansion and mechanical properties of PBX9501[J].Chinese Journal of Explosives and Propellants,2016,39(3):32-36. (in Chinese) [10] 王利侠,戴致鑫,周涛,等.压装工艺对CL-20基炸药性能及聚能破甲威力的影响[J].火炸药学报,2016,39(4): 56-60. WANG L X,DAI Z X,ZHOU T,et al.Effect of pressing molding on the property and shaped charge penetration power of CL-20-based PBX[J].Chinese Journal of Explosives and Propellants,2016,39(4):56-60.(in Chinese) [11] 肖磊,刘杰,郝嘎子,等.微纳米RDX颗粒级配对压装PBX性能影响[J].含能材料,2016,24(12):1193-1197. XIAO L,LIU J,HAO G Z,et al.Effects of nano-/micrometer RDX particle gradation on the property of PBX[J].Chinese Journal of Energetic Materials,2016,24(12):1193-1197. (in Chinese) [12] 孙国祥,陈鲁祥. B 炸药的品种、组成和性能[J].火炸药学报,1989,12(1):15-21. SUN G X,CHEN L X.The variety,constituents and performance of composition B[J].Chinese Journal of Explosives and Propellants,1989,12(1):15-21.(in Chinese) [13] WIEGAND D A,PINTO J,NICOLAIDES S. The mechanical response of TNT and a composite, composition B, of TNT and RDX to compressive stress: I uniaxial stress and fracture[J].Journal of Energetic Materials,1991,9(1/2):19-80. [14] PINTO J,WEIGAND D A.The mechanical response of TNT and a composite, composition B, of TNT and RDX to compressive stress:II triaxial stress and yield[J].Journal of Energetic Materials,1991,9(3): 205-263. [15] WEIGAND D A, PINTO J.The mechanical response of TNT and a composite,composition B,of TNT and RDX to compressive stress:III dependence on processing and composition[J]. Journal of Energetic Materials,1991,9(5):349-413. [16] 韩小平,张元冲,沈亚鹏,等. 高能材料动态力学性能的研究[J]. 爆炸与冲击,1995,15( 1): 20-27. HAN X P,ZHANG Y C,SHEN Y P,et al.An experimental study on dynamic mechanical properties of energetic materials[J]. Explosion and Shock Waves,1995,15(1): 20-27. (in Chinese) [17] 曹同堂. DNAN基熔注炸药冲击起爆特性及反应速率方程研究[D].北京:北京理工大学, 2018. CAO T T.Research on shock initiation characteristics and reaction rate equation of DNAN based melt-cast explosives[D].Beijing: Beijing Institute of Technology, 2018. (in Chinese) [18] 李东伟. 侵彻环境下炸药装药安定性评估方法[D]. 北京:北京理工大学,2018 LI D W. Evaluation method of explosive charge stability in penetration environment[D].Beijing: Beijing Institute of Technology,2018. (in Chinese) [19] PROVATAS A.2,4-dinitroanisole (DNAN) as a TNT replacement for melt-cast explosive formulations[C]∥Proceedings of Australian Energetic Materials Symposium. Adelaide,Australia: DSTO,2008. [20] DAVIES P J, PROVATAS A. DNAN: A replacement for TNT in melt-cast formulations[C]∥Proceedings of 2006 Insensitive Munitions & Energetic Materials Technology symposium. Bristol,UK: IDIA, 2006. [21] 蒙君煚,周霖,曹同堂,等.2,4-二硝基苯甲醚(DNAN)基熔铸炸药研究进展[J].含能材料,2020,28(1): 13-24. MENG J J,ZHOU L,CAO T T,et al. Research progress of 2,4-dinitroanisole-based melt-cast explosives[J].Chinese Journal of Energetic Materials,2020,28(1):13-24. (in Chinese) [22] 王礼立. 应力波基础[M].北京:国防工业出版社,1985. WANG L L.Foundation of stress wave[M].Beijing:National Defense Industry Press,1985.(in Chinese) [23] 董海山,周芬芬.高能炸药及相关物性能[M].北京:科学出版社,1989. DONG H S,ZHOU F F.High-energy explosive and its relative physical properties[M].Beijing: Science Press,1989. (in Chinese) [24] ZHAO H,GARY G,KLEPACZKO J R.On the use of a viscoelastic split Hopkinson pressure bar[J]. International Journal of Impact Engineering,1997,19(4): 319-330. [25] WANG L, LABIBES K, AZARI Z, et al. Generalization of split Hopkinson bar technique to use viscoelastic bars[J]. International Journal of Impact Engineering,1994,15(5):669-686. [26] CHEN W,ZHANG B,FORRESTAL M J.A split Hopkinson bar technique for low-impedance materials[J]. Experimental Mechanics,1999,39(2): 81-85. [27] FREW D J,FORRESTAL M J,CHEN W. Pulse shaping techniques for testing brittle materials with a split Hopkinson pressure bar[J].Experimental Mechanics,2002,42(1):93-106. [28] 宋力,胡时胜.SHPB数据处理中的二波法与三波法[J]. 爆炸与冲击,2005,25(4):368-373. SONG L,HU S S.Two wave and three wave method in SHPB data processing[J].Explosion and Shock Waves,2005,25(4):368-373. (in Chinese) [29] JOHNSON G R,COOK W H . A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures[J]. Engineering Fracture Mechanics,1983,21:541-548. [30] LESUER D.Experimental investigations of material models for Ti-6Al-4V and 2024-T3[R].Livermore,CA,US:Lawrence Livermore National Laboratory,1999.