TY - JOUR
T1 - Detonation reaction characteristics for CL-20 and CL-20-based aluminized mixed explosives
AU - Liu, Danyang
AU - Chen, Lang
AU - Wang, Chen
AU - Wu, Junying
N1 - Publisher Copyright:
© 2017 Institute of Industrial Organic Chemistry, Poland.
PY - 2017
Y1 - 2017
N2 - The interfacial particle velocities for CL-20 and CL-20-based aluminized mixed explosives were measured by interferometry in order to analyze the aluminum reactions in the latter. The reaction characteristics were obtained, as well as a better understanding of the effects of aluminum powder on the detonation reaction zone length. Two functions were used to fit the particle velocity-time profiles, and their intersection was the corresponding Chapman-Jouget (CJ) point. From these profiles, the detonation reaction zone length and the aluminum reaction were then analyzed. CL-20-based explosives have a short reaction time (48 ns for a high CL-20 content), while the reaction time of CL-20/Al explosives increased with the aluminum content and particle size. Micron-scale aluminum particles barely reacted in the CL-20 detonation reaction zone, but instead reacted with the detonation products after the CJ point. This reduced the detonation pressure; however, the aluminum reaction can slow down the decrease in particle velocities. The start times of small-particle aluminum reactions were earlier than those of the larger particles. The 2-3-μm aluminum particles start to react within 1 μs after the CJ point, while the 200-nm particles may start to react in the reaction zone.
AB - The interfacial particle velocities for CL-20 and CL-20-based aluminized mixed explosives were measured by interferometry in order to analyze the aluminum reactions in the latter. The reaction characteristics were obtained, as well as a better understanding of the effects of aluminum powder on the detonation reaction zone length. Two functions were used to fit the particle velocity-time profiles, and their intersection was the corresponding Chapman-Jouget (CJ) point. From these profiles, the detonation reaction zone length and the aluminum reaction were then analyzed. CL-20-based explosives have a short reaction time (48 ns for a high CL-20 content), while the reaction time of CL-20/Al explosives increased with the aluminum content and particle size. Micron-scale aluminum particles barely reacted in the CL-20 detonation reaction zone, but instead reacted with the detonation products after the CJ point. This reduced the detonation pressure; however, the aluminum reaction can slow down the decrease in particle velocities. The start times of small-particle aluminum reactions were earlier than those of the larger particles. The 2-3-μm aluminum particles start to react within 1 μs after the CJ point, while the 200-nm particles may start to react in the reaction zone.
KW - Aluminum reaction
KW - Detonation reaction zone
KW - Interfacial particle velocity
KW - Interferometry
UR - http://www.scopus.com/inward/record.url?scp=85029598033&partnerID=8YFLogxK
U2 - 10.22211/cejem/75114
DO - 10.22211/cejem/75114
M3 - Article
AN - SCOPUS:85029598033
SN - 1733-7178
VL - 14
SP - 573
EP - 588
JO - Central European Journal of Energetic Materials
JF - Central European Journal of Energetic Materials
IS - 3
ER -