A novel ignition model for low velocity impact of heterogeneous explosives based on interacting hot spots.

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Bibliographic Details
Title: A novel ignition model for low velocity impact of heterogeneous explosives based on interacting hot spots.
Authors: Long, Alan1 (AUTHOR), Ma, Xia1 (AUTHOR), Petsev, Nikolai1 (AUTHOR), Clements, Brad1 (AUTHOR) bclements@lanl.gov
Source: Combustion & Flame. Feb2026, Vol. 284, pN.PAG-N.PAG. 1p.
Subjects: Explosives analysis, Heat conduction, Ignition temperature, Impact (Mechanics), Numerical solutions to equations, Combustion engineering
Abstract: While numerous studies have focused on the ignition of explosives occurring in high velocity impact and the associated shock-to-detonation transition, there has been growing interest in developing computational models focused on low-velocity impact regimes. A predictive low-velocity impact ignition model will be important for analyzing high explosive safety and potential accident scenarios. This work introduces a novel ignition model based on the concept of thermally interacting hot spots to simulate low velocity impacted heterogeneous explosives where observed ignition times are on the order of milliseconds. The model asserts that relevant hot spots are micron-sized, the typical separation between neighboring hot spots is on the order of a hundred microns, and that neighbors interact thermally through heat conduction across the interstitial region between them. To achieve tractable numerical solutions, hot spots are assumed to form a periodic array as opposed to the highly irregular positioning in an actual explosive. This idealization allows a single two hotspot system to characterize the ignition process. Consequently, the model is referred to as the two hot spot Frank-Kamenetskii ignition model. In the present study, hot spots are modeled as constant heat sources terms, but this can be extended to include grain-scale phenomena like frictional heating of micron-sized growing cracks that are confined under high pressure. Because the micron-sized features are below the scale that can be efficiently resolved at a systems level, an efficient subscale scheme based on the Method of Weighted Residuals (MWR) is used to efficiently solve the equations. We carry out numerical examples and analytic predictions illustrating the accuracy and the functioning of the model. [ABSTRACT FROM AUTHOR]
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Database: Engineering Source
Description
Abstract:While numerous studies have focused on the ignition of explosives occurring in high velocity impact and the associated shock-to-detonation transition, there has been growing interest in developing computational models focused on low-velocity impact regimes. A predictive low-velocity impact ignition model will be important for analyzing high explosive safety and potential accident scenarios. This work introduces a novel ignition model based on the concept of thermally interacting hot spots to simulate low velocity impacted heterogeneous explosives where observed ignition times are on the order of milliseconds. The model asserts that relevant hot spots are micron-sized, the typical separation between neighboring hot spots is on the order of a hundred microns, and that neighbors interact thermally through heat conduction across the interstitial region between them. To achieve tractable numerical solutions, hot spots are assumed to form a periodic array as opposed to the highly irregular positioning in an actual explosive. This idealization allows a single two hotspot system to characterize the ignition process. Consequently, the model is referred to as the two hot spot Frank-Kamenetskii ignition model. In the present study, hot spots are modeled as constant heat sources terms, but this can be extended to include grain-scale phenomena like frictional heating of micron-sized growing cracks that are confined under high pressure. Because the micron-sized features are below the scale that can be efficiently resolved at a systems level, an efficient subscale scheme based on the Method of Weighted Residuals (MWR) is used to efficiently solve the equations. We carry out numerical examples and analytic predictions illustrating the accuracy and the functioning of the model. [ABSTRACT FROM AUTHOR]
ISSN:00102180
DOI:10.1016/j.combustflame.2025.114669