压装密实炸药装药非冲击点火反应传播与烈度演化实验研究进展

简要概述了国内外同行最近二十多年来对炸药安全性精密物理实验研究认识进展历程，聚焦分析了炸药安全性研究领域一些传统流派在事故反应机理认知和反应行为建模理论方法上的通常误区。本文中还引证了本研究团队近年开展的一组分解实验进行案例点评，对非冲击点火事故反应在装药结构中的传播及反应演化行为的复杂表现背后共同的基本行为机制进行了集中解读。本文中介绍的系列实验从主导机理视角展示了非冲击点火事故演化物理图像的诸多关键细节。对典型密实炸药而言，非冲击点火反应的本质是炸药表面层燃烧反应主体行为，因高压气体产物流动与炸药间隙及基体中裂纹演化耦合，使反应烈度走向呈现极度非线性特征，同时会因主炸药的燃速特性及约束结构的变形、破裂而存在限制，使得密实炸药DDT转化难于在典型装药结构中发生。

Progress in experimental studies on the evolution behaviors of non-shock initiation reaction in low porosity pressed explosive with confinement

The progress in explosive safety studies related to experiment achievements with precise diagnostics and understanding of non-shock initiation of explosive phenomena in recent 20 years is reviewed. Some widespread misconceptions and misleading in non-shock initiation reaction behavior and corresponding process modeling is commented and suggestions for improvement are given. Recent experiments focused on the reaction propagation and violence evolution conducted by the author’s team in recent years are introduced and interpreted in detail as an illustration of the basic mechanism of non-shock initiation reaction. For low porosity explosive, the abnormal reaction behavior is dominated by the surface conductive burning and the convective flow of hot, high pressure gaseous reaction products through confinement slot and cracks in explosive bulk, which should be taken as the basic kinetics during the reaction propagation and reaction violence growth process. The evolution of reaction violence is unstable when the surface combustion is coupled with the dynamic evolution of crack network in explosive, but the utmost violence is usually limited by the mild conductive combustion rate of typical secondary explosive and confinement failure. Especially, the deflagration to detonation transition could hardly come true in low porosity explosive system with confinement of limited strength.