Analysis of compaction shock interactions during DDT of low density HMX

Authors

Pratap T. Rao, Louisiana State University
Keith A. Gonthier, Louisiana State University

Document Type

Conference Proceeding

Publication Date

1-13-2017

Abstract

Deflagration-to-Detonation Transition (DDT) in confined, low density granular HMX occurs by a complex mechanism that involves compaction shock interactions within the material. Piston driven DDT experiments indicate that detonation is abruptly triggered by the interaction of a strong combustion-supported secondary shock and a piston-supported primary (input) shock, where the nature of the interaction depends on initial packing density and primary shock strength. These interactions influence transition by affecting dissipative heating within the microstructure during pore collapse. Inert meso-scale simulations of successive shock loading of low density HMX are performed to examine how dissipation and hot-spot formation are affected by the initial density, and the primary and secondary shock strengths. This information is used to formulate an ignition and burn model for low density HMX that accounts for the effect of shock densensitization on burn. Preliminary DDT predictions are presented that illustrate how primary shock strength affects the transition mechanism.

Publication Source (Journal or Book title)

AIP Conference Proceedings

Recommended Citation

Rao, P., & Gonthier, K. (2017). Analysis of compaction shock interactions during DDT of low density HMX. AIP Conference Proceedings, 1793 https://doi.org/10.1063/1.4971610