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sunfluidh:fluid_properties_namelist [2017/02/07 17:46] yannsunfluidh:fluid_properties_namelist [2020/01/24 11:22] yann
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                    Multi_Species_Mixture_Law_for_Thermal_Conductivity_Enabled= .false. ,                    Multi_Species_Mixture_Law_for_Thermal_Conductivity_Enabled= .false. ,
                    Multi_Species_Mixture_Law_for_Mass_Diffusion_Enabled      = .false.  ,                    Multi_Species_Mixture_Law_for_Mass_Diffusion_Enabled      = .false.  ,
-                   Soret_Effect_Enabled                                      = .false. /+                   Soret_Effect_Enabled                                      = .false. , 
 +                   Axisymmetric_Case_3D_Enabled                              = .false. / 
 +                   
  
 <note important> <note important>
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      * For incompressible flows with heat transfer, the "Reference_Temperature" is used to define the reference temperature implied in the buoyancy force (see the namelist [[sunfluidh:gravity_namelist| "Gravity"]].      * For incompressible flows with heat transfer, the "Reference_Temperature" is used to define the reference temperature implied in the buoyancy force (see the namelist [[sunfluidh:gravity_namelist| "Gravity"]].
      * If the incompressible fluid is a gas, the "Reference_Temperature" can be also used by the code in order to calculate automatically the thermal expansion coefficient (**for that, the user must set the variable "Thermal_Expansion_Coefficient" to zero**).      * If the incompressible fluid is a gas, the "Reference_Temperature" can be also used by the code in order to calculate automatically the thermal expansion coefficient (**for that, the user must set the variable "Thermal_Expansion_Coefficient" to zero**).
-     * For incompressible two-phase flows, the "Reference_Density" and the "Reference_Density_2" are used in order to initialize the density field. This field must be explicitly defined by an user's function in the module "module_user_define_init_fields.f90". The dynamic viscosity filed is automatically created from the data "Reference_Density" and "Reference_Density_2".+     * For incompressible two-phase flows, the "Reference_Density" and the "Reference_Density_2" are used in order to initialize the density field. This field must be explicitly defined by an user's function in the module "module_user_define_init_fields.f90". The dynamic viscosity field is automatically initialized from the data "Reference_Density" and "Reference_Density_2".
      * For low Mach number flows, the reference pressure value is calculated from the "Reference_Density", the "Reference_Temperature" and the "Molecular_Mass" by using the equation of state of perfect gas. \\ This pressure, that is uniform over the domain, is thus used for initializing the density field, knowing the temperature field (defined with the namelist [[sunfluidh:temperature_initialization_namelist|"Temperature_Initialization"]]) and the species mass fraction fields (defined with the namelist [[sunfluidh:species_initialization_namelist|"Species_Initialization"]]) in the particular case of multi-species flows.      * For low Mach number flows, the reference pressure value is calculated from the "Reference_Density", the "Reference_Temperature" and the "Molecular_Mass" by using the equation of state of perfect gas. \\ This pressure, that is uniform over the domain, is thus used for initializing the density field, knowing the temperature field (defined with the namelist [[sunfluidh:temperature_initialization_namelist|"Temperature_Initialization"]]) and the species mass fraction fields (defined with the namelist [[sunfluidh:species_initialization_namelist|"Species_Initialization"]]) in the particular case of multi-species flows.
      * For low Mach number flows or incompressible two-phase flows, the "Reference_Density" is also implied in the gravity/buoyancy force (see the namelist [[sunfluidh:gravity_namelist| "Gravity"]].      * For low Mach number flows or incompressible two-phase flows, the "Reference_Density" is also implied in the gravity/buoyancy force (see the namelist [[sunfluidh:gravity_namelist| "Gravity"]].
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 ==== Axisymmetric_Case_3D_Enabled ==== ==== Axisymmetric_Case_3D_Enabled ====
    * type : boolean value     * type : boolean value 
-   * true : the third velocity component is taken in to account for a 2D axisymmetric problem+   * true : the third velocity component is taken in to account for a 2D axisymmetric problem (You must set [[sunfluidh:domain_features_namelist?s[]=geometric|Geometric_Layout]] = 2)
    * false:  the third velocity component is not taken in to account for a 2D axisymmetric problem    * false:  the third velocity component is not taken in to account for a 2D axisymmetric problem
    * Default value = .false.    * Default value = .false.
sunfluidh/fluid_properties_namelist.txt · Dernière modification : 2021/04/15 18:26 de yann

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