TY - GEN
T1 - THREE-DIMENSIONAL NUMERICAL SIMULATION ON THE FORMATION OF EFP WITH CRACKS IN CHARGE
AU - Xie, Hongwei
AU - Jiang, Jianwei
AU - Men, Jianbing
AU - Wang, Shuyou
AU - Li, Mei
N1 - Publisher Copyright:
© Proceedings - 33rd International Symposium on Ballistics, BALLISTICS 2023. All rights reserved.
PY - 2023
Y1 - 2023
N2 - The EFP (Explosively Formed Projectile) charge design assumes that the charge is uniform and does not consider charge defects. However, in actual situations, the explosive charge will have crack defects due to the change of ambient temperature. Many experimental results show that the existence of cracks in charge will reduce the penetration capability of EFP, but there are no relevant reports to explain the mechanism. In this paper, the propagation mechanism of detonation waves in explosives with cracks is analyzed by means of theoretical analysis and numerical simulation. Taking the slope pattern crack as a typical crack shape for analysis, the three-dimensional numerical simulation was carried out by using the shock physics explicit Eulerian dynamics software SPEED, and the influence of crack structure parameters on the asymmetry of EFP forming was studied. Based on dimensional analysis, the relationship between crack inclination angle, position and the lateral velocity of EFP head was established. The analysis results show that due to the existence of cracks, there is the lateral velocity in the formation of EFP, and the lateral velocity of EFP increases with the increase of crack width, inclination angle and crack height. Due to the existence of the lateral velocity of the EFP head and the asymmetry of the EFP shape, its flight attitude is unstable, which in turn affects the penetration power.
AB - The EFP (Explosively Formed Projectile) charge design assumes that the charge is uniform and does not consider charge defects. However, in actual situations, the explosive charge will have crack defects due to the change of ambient temperature. Many experimental results show that the existence of cracks in charge will reduce the penetration capability of EFP, but there are no relevant reports to explain the mechanism. In this paper, the propagation mechanism of detonation waves in explosives with cracks is analyzed by means of theoretical analysis and numerical simulation. Taking the slope pattern crack as a typical crack shape for analysis, the three-dimensional numerical simulation was carried out by using the shock physics explicit Eulerian dynamics software SPEED, and the influence of crack structure parameters on the asymmetry of EFP forming was studied. Based on dimensional analysis, the relationship between crack inclination angle, position and the lateral velocity of EFP head was established. The analysis results show that due to the existence of cracks, there is the lateral velocity in the formation of EFP, and the lateral velocity of EFP increases with the increase of crack width, inclination angle and crack height. Due to the existence of the lateral velocity of the EFP head and the asymmetry of the EFP shape, its flight attitude is unstable, which in turn affects the penetration power.
UR - http://www.scopus.com/inward/record.url?scp=85178998368&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85178998368
T3 - Proceedings - 33rd International Symposium on Ballistics, BALLISTICS 2023
SP - 524
EP - 541
BT - Exterior Ballistics, Explosion Mechanics, Emerging Technologies, Launch Dynamics, Vulnerability and Survivability
A2 - Coghe, Frederik
PB - DEStech Publications
T2 - 33rd International Symposium on Ballistics, BALLISTICS 2023
Y2 - 16 October 2023 through 20 October 2023
ER -