A test method for launch safety of explosive charge accurately simulating launch overload

References

• Austin, R., N. Barton, and W. Howard. 2014. Modeling pore collapse and chemical reactions in shock-loaded HMX crystals. Journal of Physics. Conference Series. doi:10.1088/1742-6596/500/5/052002.
   Google Scholar
• Bennett, J. G., K. S. Haberman, J. N. Johnson et al. 1998. A constitutive model for the non-shock ignition and mechanical response of high explosives. Journal of the Mechanics and Physics of Solids 46 (12):2303–22. doi:10.1016/S0022-5096(98)00011-8.
   Web of Science ®Google Scholar
• Chang, S. 2004. Influence of explosive charge quality on launch safety. China Safety Science Journal 14 (11):3.
   Google Scholar
• Chen, L., and Y. Ding. 2004. Simulation experiment system of low speed gas gun for impact initiation of explosive charge. Proceeding of the 3th explosion mechanics experiment technology Symposium, He Fei.
   Google Scholar
• Cui, K. 2010. Numerical simulation of shock initiation of high explosives. Mian Yang: China Academy of Engineering Physics.
   Google Scholar
• Cui, Y., Y. Hong, and L. Xiuqian. 2011. Calibration of PVDF pressure sensor and its application in laser propulsion experiment. Explosion and Shock Waves 31 (1):31–35.
   Google Scholar
• Dienes, J. K., Q. H. Zuo, and J. D. Kershner. 2006. Impact initiation of explosives and propellants via statistical crack mechanics[J]. Journal of the Mechanics and Physics of Solids 54 (6):1237–75. doi:10.1016/j.jmps.2005.12.001.
   Web of Science ®Google Scholar
• Han, X., Y. Zhang, and Y. Shen. 1996. Experimental study on dynamic and static triaxial compression mechanical properties of TNT explosive under variable temperature. Chinese Journal of Applied Mechanics 13 (3):28–32.
   Google Scholar
• Hu, Y., J. Liu, and W. Gu. 2016. PVDF stress measurement technology and its application in explosion impact experiment of porous materials. Explosion and Shock Waves 36 (5):654–62.
   Google Scholar
• Hu, S., Q. Zhang, and C. Xiang. 2010. Study on drop weight load characteristics of explosive charge impact experiment. Journal of Vibration and Shock 29: (12):126–27.
   Google Scholar
• Ma, H., and B. Yao. 2004. Simulation test method for launch safety of explosive charge. Journal of Ballistics 16: (4):57–61.
   Google Scholar
• Myers, T. F. 1981.The effect of base gaps on setback-shock sensitivities of cast composition B and TNT as determined by the NSWC setback-shock simulator. 7th Symposium (International) on Detonation, Maryland (USA), Navel Surface Weapons Center, 914–23.
   Google Scholar
• Qin, J. 2014. Experimental investigation and numerical modelling of non-shock ignition mechanism in PBX explosives. PhD diss., National University of Defense Science and Technology.
   Google Scholar
• Rui, X., L. Yun, and G. Wang. 2009. Direction to Launch Safety of Ammunition. Beijing: National Defense Industry Press.
   Google Scholar
• Starkenberg, J. 1989. Cavity collapse ignition of composition B in the launch environment. 8th Symposium (International) on Detonation New Mexico, USA.
   Google Scholar
• Starkenberg, J., L. H. Ervin, and D. L. McFadden. 1986. Air compression heating ignition of high explosives in the launch environment. AD-A164961.
   Google Scholar
• Taylor, B. C., J. Starkenberg, and L. H. Ervin.1980. An experimental investigation of composition-B ignition under artillery setback conditions. AD A095348, 13–35.
   Google Scholar
• Wang, S., and H. Hu. 2003a. Experimental study on launch safety of composition-B based on drop weight simulation loading. Explosion and Shock Waves 23 (3):275–78.
   Google Scholar
• Wang, S., and H. Hu. 2003b. Influence of explosive charging technology on launch safety. Chinese Journal of Explosive and Propellants 026 ( 001):20–22.
   Google Scholar
• Wei, L., W. Guoping, R. Xiaoting, G. Jian, and X. Zhao. 2020. A hotspot model for PBX explosive charge ignition in a launch environment. Combustion Science and Technology (2):1–19. doi:10.1080/00102202.2020.1849166.
   Google Scholar
• Zhang, J., and T. L. Jackson. 2016. Direct detonation initiation with thermal deposition due to pore collapse in energetic materials-towards the coupling between micro-and macroscale. Combustion Theory and Modelling 1–26. doi:10.1080/13647830.2016.1218053.
   Web of Science ®Google Scholar
• Zhang, Q., and C. Xiang. 2008. Numerical simulation of energy characteristics of pores in charge under the launching load. Transactions of Beijing Institute of Technology 28: 945–948.
   Google Scholar
• Zhou, P., G. Xu, and J. Zhang. 1999. Experimental study on launch safety of composition-B. Chinese Journal of Explosive and Propellants 4:34–35.
   Google Scholar