programmer's documentation
Variables
Thermal 1D module parameters
Collaboration diagram for Thermal 1D module parameters:

Variables

integer, save nfpt1d
 number of boundary faces which are coupled with a wall 1D thermal module. See the user subroutine uspt1d More...
 
integer, save nmxt1d
 
integer, dimension(:), allocatable izft1d
 zones of t1d, dimensioned with nfabor (TODO) More...
 
integer, dimension(:), allocatable nppt1d
 number of discretisation cells in the 1D wall for the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The number of cells for these boundary faces is given by nppt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d More...
 
integer, dimension(:), allocatable ifpt1d
 array allowing to mark out the numbers of the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The numbers of these boundary faces are given by ifpt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d More...
 
integer, dimension(:), allocatable iclt1d
 typical boundary condition at the external (pseudo) wall: Dirichlet condition (iclt1d=1) or flux condition (iclt1d=3) More...
 
double precision, dimension(:), allocatable eppt1d
 thickness of the 1D wall for the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The wall thickness for these boundary faces is therefore given by eppt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d More...
 
double precision, dimension(:), allocatable rgpt1d
 geometry of the pseudo wall mesh (refined as a fluid if rgt1d is smaller than 1 More...
 
double precision, dimension(:), allocatable tppt1d
 initialisation temperature of the wall (uniform in thickness). In the course of the calculation, the array stores the temperature of the solid at the fluid/solid interface. More...
 
double precision, dimension(:), allocatable tept1d
 external temperature of the pseudo wall in the Dirichlet case. More...
 
double precision, dimension(:), allocatable hept1d
 external coefficient of transfer in the pseudo wall under Dirichlet conditions (in $W.m^{-2}.K^.$). More...
 
double precision, dimension(:), allocatable fept1d
 external heat flux in the pseudo wall under the flux conditions (in $W.m^{-2}$, negative value for energy entering the wall). More...
 
double precision, dimension(:), allocatable xlmbt1
 thermal diffusivity More...
 
double precision, dimension(:), allocatable rcpt1d
 volumetric heat capacity $\rho C_p$ of the wall uniform in thickness (in $J.m^{-3}.K^{-1}$). More...
 
double precision, dimension(:), allocatable dtpt1d
 physical time step associated with the solved 1D equation of the pseudo wall (which can be different from the time step in the calculation). More...
 

Detailed Description

Variable Documentation

double precision, dimension(:), allocatable dtpt1d

physical time step associated with the solved 1D equation of the pseudo wall (which can be different from the time step in the calculation).

double precision, dimension(:), allocatable eppt1d

thickness of the 1D wall for the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The wall thickness for these boundary faces is therefore given by eppt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d

double precision, dimension(:), allocatable fept1d

external heat flux in the pseudo wall under the flux conditions (in $W.m^{-2}$, negative value for energy entering the wall).

double precision, dimension(:), allocatable hept1d

external coefficient of transfer in the pseudo wall under Dirichlet conditions (in $W.m^{-2}.K^.$).

integer, dimension(:), allocatable iclt1d

typical boundary condition at the external (pseudo) wall: Dirichlet condition (iclt1d=1) or flux condition (iclt1d=3)

integer, dimension(:), allocatable ifpt1d

array allowing to mark out the numbers of the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The numbers of these boundary faces are given by ifpt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d

integer, dimension(:), allocatable izft1d

zones of t1d, dimensioned with nfabor (TODO)

integer, save nfpt1d

number of boundary faces which are coupled with a wall 1D thermal module. See the user subroutine uspt1d

integer, save nmxt1d
integer, dimension(:), allocatable nppt1d

number of discretisation cells in the 1D wall for the nfpt1d boundary faces which are coupled with a wall 1D thermal module. The number of cells for these boundary faces is given by nppt1d(ii), with 1 <= ii <= nfpt1d. See the user subroutine uspt1d

double precision, dimension(:), allocatable rcpt1d

volumetric heat capacity $\rho C_p$ of the wall uniform in thickness (in $J.m^{-3}.K^{-1}$).

double precision, dimension(:), allocatable rgpt1d

geometry of the pseudo wall mesh (refined as a fluid if rgt1d is smaller than 1

double precision, dimension(:), allocatable tept1d

external temperature of the pseudo wall in the Dirichlet case.

double precision, dimension(:), allocatable tppt1d

initialisation temperature of the wall (uniform in thickness). In the course of the calculation, the array stores the temperature of the solid at the fluid/solid interface.

double precision, dimension(:), allocatable xlmbt1

thermal diffusivity