Numerical simulation of high reynolds number flows by Petrov-Galerkin finite element method

In this paper, Navier -Stokes fluid flows in curved channels are considered. Upstream of the backwardfacing step, there exists a channel with a 90°bend and a fixed curvature of 2.5. The purpose of conducting this study was to apply a finite element code to study the effect of the distorted upstream

In this work, we discuss a finite element/operator-splitting method for simulating viscoelastic flow at high Weissenberg numbers. This scheme is stable when simulating lid-driven cavity Stokes flow at high Weissenberg numbers.

A new finite-difference method is presented to solve the unsteady two-dimensional Navier-Stokes equations in the vorticity stream function form and tested for the flow around a cylinder at Reynolds number Re of IO?-104. The simulation uses a body-fitting Cartesian coordinate system in the physical p

Velocity-pressure integrated and consistent penalty finite element computations of high-Reynolds-number laminar flows are presented. In both methods the pressure has been interpolated using linear shape functions for a triangular element which is contained inside the biquadratic flow element. It has