A largrangian finite element method for the simulation of flow of Newtonian liquids

This paper reports numerical simulation of the flow past a heated/cooled sphere. A Galerkin finite element method is used to solve the 3D incompressible Boussinesq equations in primitive variable form. Numerical simulations of flow around the sphere for a range of Grashof numbers and moderate Reynol

A numerical simulation has been performed to investigate planar and radial #ows of thin liquid "lm subject to constant wall temperature or constant wall heat #ux, considering the surface tension e!ect. To simulate the variation of the "lm height including a hydraulic jump, an Arbitrary Lagrangian}Eu

In this paper we give a numerical method based on ®nite element discretizations to simulate the thermoelectrical behaviour of electrodes for electric reduction furnaces. After introducing the mathematical model we take advantage of the cylindrical symmetry of the problem to compute boundary conditio

The boundary integral formulation of the solution to the Stokes equations is used to describe the deformation of small compound non-Newtonian axisymmetric drops suspended in a Newtonian fluid that is subjected to an axisymmetric flow field. The non-Newtonian stress is treated as a source term in the

The objective of this paper is twofold. First, a stabilized finite element method (FEM) for the incompressible Navier-Stokes is presented and several numerical experiments are conducted to check its performance. This method is capable of dealing with all the instabilities that the standard Galerkin