Stiffened gas approximation and GRP resolution for fluid flows of real materials

TL;DR

This paper introduces a local stiffened gas approximation combined with a generalized Riemann problem solver to efficiently and robustly simulate fluid flows of real materials with complex equations of state.

Contribution

It proposes a novel local approximation strategy for complex EOS using stiffened gas models and integrates it with GRP solvers for improved numerical performance.

Findings

The scheme is efficient and robust in simulations.

Numerical examples show excellent performance.

The approach simplifies Riemann solver computations.

Abstract

The equation of state (EOS) embodies thermodynamic properties of compressible fluid materials and usually has very complicated forms in real engineering applications, subject to the physical requirements of thermodynamics. The complexity of EOS in form gives rise to the difficulty in analyzing relevant wave patterns. Concerning the design of numerical algorithms, the complex EOS causes the inefficiency of Riemann solvers and even the loss of robustness, which hampers the development of Godunov-type numerical schemes. In this paper, a strategy of local stiffened gas approximation is proposed for real materials. The stiffened gas EOS is used to approximate general EOS locally at each interface of computational control volumes so that the Riemann solver can be significantly simplified. In the meantime, the generalized Riemann problem (GRP) solver is adopted not only for high resolution purpose but effective reflection of the local thermodynamics as well. The resulting scheme is demonstrated to be efficient and robust and numerical examples display the excellent performance of such an approximation.