Thermal response of DNAN based explosives considering thermodynamic coupling：Under different charge quantity and diameter changes

Abstract

This paper explores the impact of changes in charge quantity and diameter on the thermal response of DNAN-based explosives. To achieve this, we established a method for simulating thermal, chemical, and mechanical coupling. The study focuses on three fixed charge quantities of explosives, each with varying length-to-diameter ratios, examining alterations in ignition position, timing, and temperature changes under different heating rates, as well as the safe thermal response size in various heating environments. The findings show that the maximum discrepancy between the simulation results and experimental data is under 5 %. It was observed that larger charges are less sensitive to variations in external heating rates and aspect ratios. Specifically, at a heating rate of 1 K/min, projectiles with a diameter exceeding their length by the same factor exhibit greater thermal safety than those with a length exceeding their diameter. This research not only enhances the accuracy of simulation experiments but also offers a comprehensive safety analysis for the combustion of ammunition. The findings provide valuable insights for designing low-vulnerability ammunition structures that are subject to significant thermal stress in various environments, and they are useful for guiding ammunition storage and destruction experiments.