English

Numerical modelling of shock-bubble interactions using a pressure-based algorithm without Riemann solvers

Computational Physics 2019-07-04 v2 Fluid Dynamics

Abstract

The interaction of a shock wave with a bubble features in many engineering and emerging technological applications, and has been used widely to test new numerical methods for compressible interfacial flows. Recently, density-based algorithms with pressure-correction methods as well as fully-coupled pressure-based algorithms have been established as promising alternatives to classical density-based algorithms based on Riemann solvers. The current paper investigates the predictive accuracy of fully-coupled pressure-based algorithms without Riemann solvers in modelling the interaction of shock waves with one-dimensional and two-dimensional bubbles in gas-gas and liquid-gas flows. For a gas bubble suspended in another gas, the mesh resolution and the applied advection schemes are found to only have a minor influence on the bubble shape and position, as well as the behaviour of the dominant shock waves and rarefaction fans. For a gas bubble suspended in a liquid, however, the mesh resolution has a critical influence on the shape, the position and the post-shock evolution of the bubble, as well as the pressure and temperature distribution.

Keywords

Cite

@article{arxiv.1907.01173,
  title  = {Numerical modelling of shock-bubble interactions using a pressure-based algorithm without Riemann solvers},
  author = {Fabian Denner and Berend van Wachem},
  journal= {arXiv preprint arXiv:1907.01173},
  year   = {2019}
}
R2 v1 2026-06-23T10:09:33.974Z