Kazem
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* <span style="color:#0000FF"> Level Set </span> method is used to determine the interface position at each step. | * <span style="color:#0000FF"> Level Set </span> method is used to determine the interface position at each step. | ||
* Local <span style="color:#0000FF"> pressure enrichmnet </span> is considered at the cutted element to capture the discontinuous pressure gradient. | * Local <span style="color:#0000FF"> pressure enrichmnet </span> is considered at the cutted element to capture the discontinuous pressure gradient. | ||
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=== <span style="color:#0000FF"> Technical descriptions </span> === | === <span style="color:#0000FF"> Technical descriptions </span> === | ||
Latest revision as of 16:40, 24 July 2013
Contents |
Multifluid module
Introduction
Mold filling of an industrial specimen.
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About this module
- Solves the Navier-Stokes equations for a multi-fluid system considering large jumps in density .
- Tractions are considered continuous at the interface and therefore no jump in viscosity is considered.
- Level Set method is used to determine the interface position at each step.
- Local pressure enrichmnet is considered at the cutted element to capture the discontinuous pressure gradient.
Technical descriptions
Fluid types
- Incompressible fluid
Constitutive laws
- Newtonian
Kinematic approaches
- Eulerian
- With free surface (level set)
Solution strategy
- Monolithic
- Residual based Newton Raphson strategy is exploited to treat nonlinearities.
Elements
3D: Linear tetrahedral elements (It works just in 3D)
- Element name: DPGVMS( Discontinuous Pressure Gradiant with Variational Multi Scale technique)
Boundary conditions
- Velocity boundary condition: Inlet of water
- Pressure boundary condition: Pressure can be imposed strongly or weakly...
- Wall boundary condition:
- Slip boundary condition: If velocity is not assigned to a boundary it is automatically considered as Slip.
Initial conditions
- Zero of the Level set has to be assigned as the initial condition by assigning + and - Distance flag.
Turbulence models
All turbulance models inside KRATOS can be used:
- Smagorinsky-Lily
- Spalart-Allmaras
HPC
The code can be run in shared or distributed memory:
- OpenMP: The official version is written to work in OpenMP.
- MPI: It has been tested but is not provided for the official version.
Problem parameters
Others relevand aspects
- Volume correction is activated.
Contact people
Kazem Kamran: kazem@cimne.upc.edu
