Lateral enhancement effect of reactive PELE: Two-step segmented simulation and analytical modeling

Jiahao Zhang, Haifu Wang, Yuanfeng Zheng, Pengwan Chen, Chao Ge, Qingbo Yu*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

6 Citations (Scopus)

Abstract

Comparing with traditional PELE, the reactive PELE shows a more significant lateral enhancement effect due to the deflagration reaction of the filling by impact. Here an analytical model for thin-walled jacket fragmentation and dispersion is presented based on the wave interaction and the reaction of reactive filling. Subsequently, a two-step segmented numerical simulation for the impact deflagration of reactive PELE is developed. Based on the numerical simulation, the wave interaction process and the internal stress distribution of the filling were given firstly, then the deflagration reaction of reactive filling, jacket fragmentation and dispersion were simulated. By the theory and simulation, the experiment results of reactive PELE impacting steel plate are analyzed. In the experiment, the thickness of the front steel target is 6mm-20 mm, and the multi-layer witness aluminum plate is set behind the steel target to obtain the lateral effect of the reactive PELE. The analysis results show that the released energy of the reactive filling increases the maximum radial velocity of the jacket fragments by more than 40 %, and the perforation dispersion on the witness plate significantly depends on the filling reaction level and the front steel plate thickness, the lateral enhancement mechanism of reactive PELE impacting plate is explained.

Original languageEnglish
Article number111204
JournalThin-Walled Structures
Volume192
DOIs
Publication statusPublished - Nov 2023

Keywords

  • Impact deflagration
  • Lateral enhancement effect
  • Radial energy density
  • Reactive PELE
  • Two-step segmented simulation

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