Computation of turbulent flows using a finite calculus–finite element formulation

A parallel semi-explicit iterative ®nite element computational procedure for modelling unsteady incompressible ¯uid ¯ows is presented. During the procedure, element ¯ux vectors are calculated in parallel and then assembled into global ¯ux vectors. Equilibrium iterations which introduce some `local i

We refer to as mixed element/volume (MEV) methods the application of ®nite element for diffusion terms and ®nite volume for advection terms in a ¯ow model. The compatibility of these methods can be checked for some low-order approximations; the resulting schemes may enjoy the relative mesh-regularit

## Abstract Streamline‐upwind/Petrov–Galerkin finite element method is developed for buoyancy‐driven incom‐pressible flows with heat and mass transfer. The stabilized finite element formulations are implemented in parallel using message passing interface libraries. To measure the accuracy of the me

This paper is devoted to the computation of turbulent flows by a Galerkin finite element method. Effects of turbulence on the mean field are taken into account by means of a k--E turbulence model. The wall region is treated through wall laws and, more specifically, Reichardt's law. An inlet profile