The final publication is available at Springer via http://dx.doi.org/10.1007/s00466-006-0060-yWe present a general formulation for incompressible fluid flow analysis using the finite element method. The necessary stabilization for dealing with convective effects and the incompressibility condition are introduced via the Finite Calculus method using a matrix form of the stabilization parameters. This allows to model a wide range of fluid flow problems for low and high Reynolds numbers flows without introducing a turbulence model. Examples of application to the analysis of incompressible flows with moderate and large Reynolds numbers are presented.Peer Reviewe
A stabilized finite point method (FPM) for meshless analysis of incompressible fluid flows is presen...
AbstractFormulated in terms of velocity, pressure and the extra stress tensor, the incompressible Na...
We describe solution of incompressible fluid flow using the finite element method on meshes adjusted...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
The final publication is available at Springer via http://dx.doi.org/10.1007/s00466-006-0060-yWe pre...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a formulation for analysis of turbulent incompressible flows using a stabilized finite el...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a new stabilized finite element (FEM) formulation for incompressible flows based on the F...
We present a formulation for analysis of turbulent incompressible flows using a stabilized finite el...
CIMNE, Technical Report Nº PI-150, Barcelona, SpainA stabilized finite element formulation for incom...
We present a general formulation for incompressible fluid flow analysis using the finite element method...
A stabilized finite point method (FPM) for the meshless analysis of incompressible fluid flow proble...
Abstract. This paper presents a step forward in the formulation for incompressible fluid flow analys...
A stabilized finite point method (FPM) for meshless analysis of incompressible fluid flows is presen...
AbstractFormulated in terms of velocity, pressure and the extra stress tensor, the incompressible Na...
We describe solution of incompressible fluid flow using the finite element method on meshes adjusted...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
The final publication is available at Springer via http://dx.doi.org/10.1007/s00466-006-0060-yWe pre...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a formulation for analysis of turbulent incompressible flows using a stabilized finite el...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a general formulation for incompressible fluid flow analysis using the finite element met...
We present a new stabilized finite element (FEM) formulation for incompressible flows based on the F...
We present a formulation for analysis of turbulent incompressible flows using a stabilized finite el...
CIMNE, Technical Report Nº PI-150, Barcelona, SpainA stabilized finite element formulation for incom...
We present a general formulation for incompressible fluid flow analysis using the finite element method...
A stabilized finite point method (FPM) for the meshless analysis of incompressible fluid flow proble...
Abstract. This paper presents a step forward in the formulation for incompressible fluid flow analys...
A stabilized finite point method (FPM) for meshless analysis of incompressible fluid flows is presen...
AbstractFormulated in terms of velocity, pressure and the extra stress tensor, the incompressible Na...
We describe solution of incompressible fluid flow using the finite element method on meshes adjusted...