BOUNDARY AND SOURCE TERM TREATMENT IN THE LARGE TIME STEP METHOD FOR A COMMON TWO-FLUID MODEL

In this paper we present the Large Time Step method based on the Roe scheme applied to a standard two-fluid model. The Large Time Step method was originally developed in the nineteen eighties by Randall LeVeque and has enjoyed increasing popularity in the CFD community in recent years due to its attractive features such as increased accuracy and efficiency compared to its standard low time step counterparts. In terms of efficiency and computation time, one of the main disadvantages in common explicit schemes is the limited time step size imposed by the CFL condition. The idea behind the Large Time Step method is to increase the domain of dependence which leads to a relaxation of the CFL condition, allowing us to use Courant numbers larger than one, i.e. using very large time steps compared to standard explicit methods. It is shown that such an approach notably reduces the computation time and increases the accuracy of the solution. However, the idea of increasing the domain of dependence causes difficulties when it comes to boundary treatment, especially in the presence of source terms. In this paper, we describe and address these diffi- culties. We extend the standard Roe scheme with the Large Time Step method and apply it to the standard two-fluid model for the water faucet test case, focusing on the treatment of the boundary conditions. Furthermore, we compare the performance of the scheme with the classical Roe scheme in terms of computational time.