Hot spot criticality in shocked HMX over a range of pore sizes and pressures.

Autor: Springer, H. Keo, Gambino, J. R., Bastea, S., Nichols, A. L., Tarver, C. M., Lane, J. Matthew D., Germann, Timothy C., Armstrong, Michael R., Wixom, Ryan, Damm, David, Zaug, Joseph
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Zdroj: AIP Conference Proceedings; 2020, Vol. 2272 Issue 1, p1-5, 5p
Abstrakt: Continuum hot spot models for explosives now incorporate information on pore size distribution. However, there is a limited understanding of the participation of different sized pores in shock initiation scenarios. The objective of this simulation- based study is to determine the criticality of single hot spots in HMX as a function of circular pore diameter and shock pressure. Simulations are performed with the multi-physics hydrocode, ALE3D. A coupled thermochemical code provides the equation-of-states and the chemical kinetics. We also employ a strain, strain-rate, and pressure-dependent strength model. We fit the results of our pore collapse simulations to an ignition criticality equation: Rig(P) = (RmaxRmin)(P/P0)−a + Rmin. For the 2D plane strain case, Rmax = 2.5 µm, Rmin=0.25 µm, P0=5.0 GPa, and a=3.5. For the 2D axisymmetric case, Rmax=0.5 µm, Rmin=0.04 µm, P0=5.0 GPa, and a = 1. Non-reactive pore collapse simulations are also used to determine the ignition threshold but extracting definitive hot spot information from these simulations is complicated by their complex geometries and non-uniform temperature distributions. We found that using the mass of a hot spot with T > 2Tbulk appears to be a fair discriminator for ignition in complex hot spots. These studies are important because they enable upscaling grain-scale information to the continuum-scale as part of developing morphology-aware models. [ABSTRACT FROM AUTHOR]
Databáze: Complementary Index