TY - GEN
T1 - Ignition and breakup behavior of fuel tank by reactive material fragment
AU - Zheng, Yuanfeng
AU - Su, Chenghai
AU - Wang, Haifu
AU - Ge, Chao
AU - Lu, Guancheng
N1 - Publisher Copyright:
© 2019 by International Ballistics Society All rights reserved.
PY - 2019
Y1 - 2019
N2 - Combined studies on the behavior of reactive material fragment damaging fuel tank are performed, experimentally and theoretically. Firstly, ballistic experiments on reactive material fragment impacting and igniting fuel tank are conducted. The results show the reactive material fragment with the velocity above 732m/s can perforate the LY12 aluminum wall 10mm thick and then ignites the fuel/air mixture inside, causing breakup of fuel tank. However, the tungsten alloy fragment mass matched fails to ignite the fuel at a velocity of 933m/s. Secondly, the ignition enhancement behavior is analyzed and discussed, based on a fracture model of reactive materials and a fuel/air ignition model. For the mechanism considerations, traditional inert fragment emphasizes on the kinetic energy effect. However, reactive material fragment enhances lethality by incorporating the terminal defeat mechanisms of kinetic energy and chemical energy, and the convective heat conduction between reacting reactive materials and fuel/air mixture is the main ignition mechanism.
AB - Combined studies on the behavior of reactive material fragment damaging fuel tank are performed, experimentally and theoretically. Firstly, ballistic experiments on reactive material fragment impacting and igniting fuel tank are conducted. The results show the reactive material fragment with the velocity above 732m/s can perforate the LY12 aluminum wall 10mm thick and then ignites the fuel/air mixture inside, causing breakup of fuel tank. However, the tungsten alloy fragment mass matched fails to ignite the fuel at a velocity of 933m/s. Secondly, the ignition enhancement behavior is analyzed and discussed, based on a fracture model of reactive materials and a fuel/air ignition model. For the mechanism considerations, traditional inert fragment emphasizes on the kinetic energy effect. However, reactive material fragment enhances lethality by incorporating the terminal defeat mechanisms of kinetic energy and chemical energy, and the convective heat conduction between reacting reactive materials and fuel/air mixture is the main ignition mechanism.
UR - http://www.scopus.com/inward/record.url?scp=85083014210&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85083014210
T3 - Proceedings - 31st International Symposium on Ballistics, BALLISTICS 2019
SP - 1594
EP - 1602
BT - Terminal Ballistics, Explosion Mechanics, Vulnerability and Survivability
A2 - Saraswat, V. K.
A2 - Reddy, G. Satheesh
A2 - Woodley, Clive
PB - DEStech Publications Inc.
T2 - 31st International Symposium on Ballistics, BALLISTICS 2019
Y2 - 4 November 2019 through 8 November 2019
ER -