A multi-scale simulation of hot spot initiation of detonation utilizing experimental measurements

Abstract: Empirical and phenomenological hydrodynamic reactive flow models, such as the ignition-and-growth and Johnson–Tang–Forest models, have been effective in predicting the shock initiation and detonation characteristics of various energetic substances. These models utilize the compression and pressure properties of the reacting mixture to quantify its reaction rate. However, it has long been known that the shock initiation of detonation is controlled by local reaction sites called ‘hot spots’. In this study, a hot… Show more

Multiscale modeling of transients in the shock-induced detonation of heterogeneous energetic solid fuels

Multiscale modeling of transients in the shock-induced detonation of heterogeneous energetic solid fuels

Thermal decomposition behaviour and chemical kinetics of tungsten based electrically controlled solid propellants

The effect of cavity shape on critical high-temperature regions formation pattern and structural evolution difference in explosive particle bed