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Variables
Enthalpic variables pointers
Collaboration diagram for Enthalpic variables pointers:

Variables

integer, save ihm
 enthalpy, if transported More...
 
double precision, save srrom
 with gas combustion, pulverised coal or the electric module, srrom is the sub-relaxation coefficient for the density, following the formula: $\rho^{n+1}$\,=\,srrom\,$\rho^n$+(1-srrom)\,$\rho^{n+1}$ hence, with a zero value, there is no sub-relaxation. With combustion and pulverized coal, srrom is initialized to -grand and the user must specify a proper value through the Interface or the initialization subroutine (cs_user_combustion). With the electric module, srrom is initialized in to 0 and may be modified by the user in useli1. With gas combustion, pulverised coal or electric arcs, srrom is automatically used after the second time-step. With Joule effect, the user decides whether or not it will be used in uselph from the coding law giving the density. More...
 

Detailed Description

Variable Documentation

integer, save ihm

enthalpy, if transported

double precision, save srrom

with gas combustion, pulverised coal or the electric module, srrom is the sub-relaxation coefficient for the density, following the formula: $\rho^{n+1}$\,=\,srrom\,$\rho^n$+(1-srrom)\,$\rho^{n+1}$ hence, with a zero value, there is no sub-relaxation. With combustion and pulverized coal, srrom is initialized to -grand and the user must specify a proper value through the Interface or the initialization subroutine (cs_user_combustion). With the electric module, srrom is initialized in to 0 and may be modified by the user in useli1. With gas combustion, pulverised coal or electric arcs, srrom is automatically used after the second time-step. With Joule effect, the user decides whether or not it will be used in uselph from the coding law giving the density.

Always useful with gas combustion, pulverized coal or the electric module.