ULiege - Aerospace & Mechanical Engineering http://metafor.ltas.ulg.ac.be/dokuwiki/ 2026-05-15T20:28:26+00:00 http://metafor.ltas.ulg.ac.be/dokuwiki/ http://metafor.ltas.ulg.ac.be/dokuwiki/_media/logo.png text/html 2024-03-01T14:45:29+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/ballfalling?rev=1709304329&do=diff Buoyant cylinder falling into water * 2D simulation of a buoyant cylinder falling into an open reservoir filled with water. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure Stabilisation is used. * Once the limit velocity is reached the typical Von-Karman vortex shedding phenomenon can be observed. text/html 2024-02-26T16:28:59+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/columnfall?rev=1708964939&do=diff Dam collapse * 2D simulation of the collapse of a water dam. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure Stabilisation is used. Velocity field Pressure field text/html 2024-03-01T14:46:45+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/dambreakwithobstacle?rev=1709304405&do=diff Dam break with obstacle * 2D simulation of the collapse of a water dam against a rigid obstacle. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure Stabilisation is used. * A surface tension model is included in the description of the free surface text/html 2018-01-26T14:27:06+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/poiseuilleaxisym?rev=1516976826&do=diff Poiseuille flow (2D Axisymmetric) * Simulation of Poiseuille flow. * A monolithic axisymmetric PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure stabilization is used. Velocity field [Velocity field] Pressure field [Pressure field] Velocity profile along the channel radius - Comparison with theory text/html 2024-03-01T14:47:16+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/sloshingrotation?rev=1709304436&do=diff Sloshing of a water reservoir * 2D simulation of the sloshing of a reservoir filled with water. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure stabilization is used. * Experimental results coming from A. Souto-Iglesias, E. Botia-Vera, A. Martin, and F. Pérez-Arribas, “A set of canonical problems in Sloshing. Part 0: Experimental setup and data processing,” Ocean Engineering (2011) and freely available on line at text/html 2024-03-01T14:46:18+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/surfacetension?rev=1709304378&do=diff Surface tension effects * Surface tension effects on an incompressible fluid. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure Stabilisation is used. * Surface tension is introduced into boundary terms through a simple model. text/html 2024-02-26T16:27:32+00:00 Anonymous (anonymous@undisclosed.example.com) http://metafor.ltas.ulg.ac.be/dokuwiki/applications/fluid/taylorcouette?rev=1708964852&do=diff 2D Taylor-Couette flow * 2D simulation of Taylor-Couette flow between two cylinders. * Values of density = 1.0 kg/m3, dynamic viscosity = 0.1 Pa s, inner cylinder angular velocity = π rad/s, outer cylinder angular velocity = 0 rad/s. * A monolithic PFEM (Particle-FEM) formulation with Petrov-Galerkin Pressure stabilization is used.