论文信息 - Numerical study of spherical blast-wave propagation and reflection

Numerical study of spherical blast-wave propagation and reflection

Abstract. The objective of this study is to understand the flow structures of weak and strong spherical blast waves either propagating in a free field or interacting with a flat plate. A 5th-order weighted essentially non-oscillatory scheme with a 4th-order Runge-Kutta method is employed to solve the compressible Euler/Navier-Stokes equations in a finite volume approach. The real-gas effects are taken into account when high temperature occurs. A shock-tube problem with the real-gas effect is first tested in order to verify the solver accuracy. Moreover, unsteady shock waves moving over a stationary wedge with various wedge angles, resulting in different types of shock wave reflections, are also tested. It is found that the computed results agreed well with the existing data. Second, the propagation of a weak spherical blast wave, created by rupture of a high-pressure isothermal sphere, in a free field is studied. It is found that there are three minor shock waves moving behind the main shock. Third, the problem of a strong blast wave interacting with a flat plate is investigated. The flow structures associated with single and double Mach reflections are reported in detail. It is found that there are at least three local high-pressure regions near the flat plate.

[1] R. E. Ferguson,et al. Mach reflection from an HE-driven blast wave , 1986 .

[2] J. M. Dewey. The properties of a blast wave obtained from an analysis of the particle trajectories , 1971, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[3] Kazuyoshi Takayama,et al. Numerical and experimental study of a micro-blast wave generated by pulsed-laser beam focusing , 1998 .

[4] H. Brode. Numerical Solutions of Spherical Blast Waves , 1955 .

[5] H. Lomax,et al. Thin-layer approximation and algebraic model for separated turbulent flows , 1978 .

[6] John C. Tannehill,et al. Simplified curve fits for the transport properties of equilibrium air , 1987 .

[7] K. J. Weilmuenster,et al. Simplified curve fits for the thermodynamic properties of equilibrium air , 1986 .

[8] Jan Berghmans,et al. A simple blast wave model for bursting spheres based on numerical simulation , 1994 .

[9] K. Hoffmann,et al. Computational Fluid Dynamics for Engineers , 1989 .

[10] Chi-Wang Shu,et al. Efficient Implementation of Weighted ENO Schemes , 1995 .

[11] H. Brode. Blast Wave from a Spherical Charge , 1959 .

[12] Bernard Grossman,et al. Analysis of flux-split algorithms for Euler's equations with real gases , 1989 .

[13] K. Thompson. Time-dependent boundary conditions for hyperbolic systems, II , 1990 .