Extension of geometrical shock dynamics for blast wave propagation

The direct numerical simulation of blast waves is a challenging task due to the wide range of spatial and temporal scales involved. Moreover, in a real environment (topography, urban area), the blast wave interacts with geometrical obstacles, resulting in reflection, diffraction, and wave recombinat...

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Bibliographic Details
Published in:Shock waves 2020-09, Vol.30 (6), p.563-583
Main Authors: Ridoux, J., Lardjane, N., Monasse, L., Coulouvrat, F.
Format: Article
Language:English
Subjects:
Acoustics
Barriers
Condensed Matter Physics
Direct numerical simulation
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Fluid- and Aerodynamics
Heat and Mass Transfer
Mathematical models
Numerical integration
Original Article
Shock wave propagation
Thermodynamics
Urban areas
Wave diffraction
Wave reflection
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Summary:The direct numerical simulation of blast waves is a challenging task due to the wide range of spatial and temporal scales involved. Moreover, in a real environment (topography, urban area), the blast wave interacts with geometrical obstacles, resulting in reflection, diffraction, and wave recombination phenomena. The shape of the front becomes complex, which limits the efficiency of simple empirical methods. This work aims at contributing to the development of a fast running method for blast waves propagating in the presence of obstacles. This is achieved through an ad hoc extension of the simplified hyperbolic geometrical shock dynamics (GSD) model, which leads to a drastic reduction in the computational cost in comparison with the full Euler system. The new model, called geometrical blast dynamics, is able to take into account any kind of source and obstacle. It relies on a previous extension of GSD for diffraction over wedges to obtain consistent physical behavior, especially in the limit of low Mach numbers. The new model is fully described. Its numerical integration is straightforward. Results compare favorably with experiments, semiempirical models from the literature, and Eulerian simulations, over a wide range of configurations.
ISSN:0938-1287
1432-2153
DOI:10.1007/s00193-020-00954-z