Numerical investigation of particle–blast interaction during explosive dispersal of liquids and granular materials

“…In the far field, the peak blast overpressure recovers almost to the same value as the base explosive charge for 50 wt% addition of glass and even exceeds the baseline case for 10 wt% and 30 wt% addition, by up to 22.8% even though the charges with added glass have a reduced amount of explosive. This behavior is consistent with the earlier results from Pontalier et al [10][11][12][13], who attributed the near-field reduction in blast pressure to the energy transfer from the detonation products to the kinetic energy and heating of the inert particles, and the later time blast pressure recovery to the pressure perturbations induced by the particle-flow interactions.…”

“…The contribution of these disturbances may also depend on the particle size. Small particles tend to adapt more quickly to the flow in comparison with larger particles and hence transfer their energy to the flow more rapidly [11].…”

“…On the contrary, the bow shocks tend to separate from the particle jets, due to aerodynamic drag with the surrounding atmosphere. The effect of the localized bow shocks on the peak blast overpressure has been discussed in previous publications [10,11].…”

“…For inert particles, as they are accelerated by the expanding combustion products, and subsequently decelerate, the particles exchange momentum with the surrounding gas and perturb the local pressure field non-uniformly as the particles typically form particle jets or filaments [9]. This effect leads to a reduction in peak blast overpressure in the near field as the particles accelerate and to a corresponding augmentation farther from the charge as the particles decelerate and return energy to the flow [10][11][12][13]. In the case of reactive particles, the contribution of the energy release from the particle reaction to the local pressure field is more complex.…”

Blast enhancement from metalized explosives

“…In the far field, the peak blast overpressure recovers almost to the same value as the base explosive charge for 50 wt% addition of glass and even exceeds the baseline case for 10 wt% and 30 wt% addition, by up to 22.8% even though the charges with added glass have a reduced amount of explosive. This behavior is consistent with the earlier results from Pontalier et al [10][11][12][13], who attributed the near-field reduction in blast pressure to the energy transfer from the detonation products to the kinetic energy and heating of the inert particles, and the later time blast pressure recovery to the pressure perturbations induced by the particle-flow interactions.…”

“…The contribution of these disturbances may also depend on the particle size. Small particles tend to adapt more quickly to the flow in comparison with larger particles and hence transfer their energy to the flow more rapidly [11].…”

“…On the contrary, the bow shocks tend to separate from the particle jets, due to aerodynamic drag with the surrounding atmosphere. The effect of the localized bow shocks on the peak blast overpressure has been discussed in previous publications [10,11].…”

“…For inert particles, as they are accelerated by the expanding combustion products, and subsequently decelerate, the particles exchange momentum with the surrounding gas and perturb the local pressure field non-uniformly as the particles typically form particle jets or filaments [9]. This effect leads to a reduction in peak blast overpressure in the near field as the particles accelerate and to a corresponding augmentation farther from the charge as the particles decelerate and return energy to the flow [10][11][12][13]. In the case of reactive particles, the contribution of the energy release from the particle reaction to the local pressure field is more complex.…”

Blast enhancement from metalized explosives

“…In a related study, Pontalier et al [52] examine the same experiments to extract the blast overpressure and impulse to determine the influence of the interaction between the particles and the flow and blast wave. In a companion manuscript, Pontalier et al [46] use a multiphase hydrocode to explore the effect of various parameters on the particleblast interaction which influences the decay rate of the blast wave overpressure and impulse.…”

Heterogeneous/particle-laden blast waves

Experimental investigation of blast mitigation and particle–blast interaction during the explosive dispersal of particles and liquids