Abstract EN:

This thesis is devoted to the numerical simulation of stiff fluid flows, governed by sys¬tems of conservation laws with source terms (non homogeneous systems). Both one dimensional and two-dimensional configurations are considered. The numerical method used is an extension of the two steps flux scheme (SRNH), which depends on a local adjustable parameter aj+i and which has been proposed by professor F. Benkhaldoun in the one dimensional framework. In a first part of the work, aiming to extend the scheme to the two-dimensional case, we introduce an alternative scheme (SRNHR), which is obtained from SRNH by replacing the numerical velocity, by the local physical Rusanov velocity. Thereafter, the stability analysis of the scheme, shows that the new scheme can be of order 1 or 2 according to the value of the parameter 0j+1. A strategy of variation of this parameter, based on limiters theory was then adopted. The scheme can thus be turned to order 1 in the regions where the flow has a strong variation, and to order 2 in the regions where the flow is regular. After this step, we established the conditions so that this scheme respects the exact C-property introduced by Bermudez and Vazquez. A study of boundary conditions, adapted to this kind of two steps schemes, has also been carried out using the Riemann invariants. In the second part of the thesis, we applied this new scheme to homogeneous and non¬homogeneous monophasic systems. For example, we performed the numerical simulation of shallow water phenomena with bottom topography in both one and two dimensions. We also carried out a numerical convergence study by plotting the error curves. Finally, we used the scheme for the numerical simulation of two phase flow models (Ransom ID and 2D).