A finite element procedure coupled with the method of characteristics for simulation of viscoelastic fluid flow

It is known that for the numerical approximation of Oldroyd's B model for viscoelastic ¯uid ¯ows some upwinding is needed for the convection of the extra-stress tensor. In this paper we make the numerical analysis of such an approximation with upwinding by the method of characteristics in a ®nite el

We consider a coupled problem of the deformation of a porous solid, ¯ow of a compressible ¯uid and the electrical ®eld in the mixture. The governing equations consist of balance of the linear momentum of solid and of ¯uid, continuity equations of the ¯uid and current density, and a generalized form

We present a theoretical study of a creeping, steady-state, isothermal flow of a viscoelastic fluid obeying an Oldroyd-type constitutive law with slip boundary condition. The slip boundary condition is appropriate for problems that involve free boundaries and other examples where the usual no-slip c

We present a new fast iterative solution technique for the large sparse-matrix system that is commonly encountered in the mixed finite-element formulation of transient viscoelastic flow simulation: the DEVSS (discrete elastic-viscous stress splitting) method. A block-structured preconditioner for th