/usr/share/code_saturne/user/uslag1.f90 is in code-saturne-data 3.2.1-1build1.
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! Code_Saturne version 3.2.1
! --------------------------
! This file is part of Code_Saturne, a general-purpose CFD tool.
!
! Copyright (C) 1998-2013 EDF S.A.
!
! This program is free software; you can redistribute it and/or modify it under
! the terms of the GNU General Public License as published by the Free Software
! Foundation; either version 2 of the License, or (at your option) any later
! version.
!
! This program is distributed in the hope that it will be useful, but WITHOUT
! ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
! FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
! details.
!
! You should have received a copy of the GNU General Public License along with
! this program; if not, write to the Free Software Foundation, Inc., 51 Franklin
! Street, Fifth Floor, Boston, MA 02110-1301, USA.
!-------------------------------------------------------------------------------
subroutine uslag1
!================
!===============================================================================
! Purpose:
! -------
! User subroutine of the Lagrangian particle-tracking module:
! User subroutine for input of calculation parameters (Fortran commons).
! This parameters concern physical, numerical and post-processing options.
!-------------------------------------------------------------------------------
! Arguments
!__________________.____._____.________________________________________________.
! name !type!mode ! role !
!__________________!____!_____!________________________________________________!
!__________________!____!_____!________________________________________________!
! Type: i (integer), r (real), s (string), a (array), l (logical),
! and composite types (ex: ra real array)
! mode: <-- input, --> output, <-> modifies data, --- work array
!===============================================================================
!===============================================================================
! Module files
!===============================================================================
use paramx
use entsor
use lagdim
use lagpar
use lagran
use ihmpre
!===============================================================================
implicit none
! Local variables
integer ii , ipv , icha
double precision sio2 , al2o3 , fe2o3 , cao
!===============================================================================
!===============================================================================
! 1. Particle-tracking mode
!===============================================================================
! iilagr = 0 : no particle tracking (default)
! = 1 : particle-tracking one-way coupling
! = 2 : particle-tracking two-way coupling
! = 3 : particle tracking on frozen field
! (this option requires a calculation restart isuite=1,
! all Eulerian fields are frozen (pressure, velocities,
! scalars). This option is stronger than iccvfg)
iilagr = 1
!===============================================================================
! 2. Particle-tracking calculation restart
!===============================================================================
! isuila = 0 : no restart (default)
! = 1 : restart (this value requires a restart on the continuous
! phase too, i.e. isuite = 1)
isuila = 0
! Restart on volume and boundary statistics, and two-way coupling terms;
! useful if isuila = 1 (defaul off: 0 ; on: 1)
if (isuila.eq.1) isuist = 0
!===============================================================================
! 3. Particle tracking: specific models
!===============================================================================
! iphyla = 0 : only transport modeling (default)
! = 1 : equation on temperature (in Celsius degrees), diameter or mass
! = 2 : pulverized coal combustion (only available if the continuous
! phase is a flame of pulverized coal)
iphyla = 0
! 3.1 equation on temperature, diameter or mass
if (iphyla.eq.1) then
! equation on diameter
! (default off: 0 ; on: 1)
idpvar = 0
! equation on temperature (in Celsius degrees)
! (default off: 0 ; on: 1)
! This option requires a thermal scalar for the continuous phase.
itpvar = 0
! equation on mass
! (default off: 0 ; on: 1)
impvar = 0
endif
! 3.2 coal fouling
! Reference internal reports EDF/R&D: HI-81/00/030/A and HI-81/01/033/A
! Evaluation of the probability for a particle to stick to a wall.
! This probability is the ratio of a critical viscosity on the
! viscosity of coal ashes
! visref
! P(Tp) = -------- for viscen >= visref
! viscen
! = 1 otherwise
! The expression of J.D. Watt and T.Fereday (J.Inst.Fuel-Vol42-p99)
! is used to evaluate the viscosity of the ashes
! Enc1 * 1.0d+7
! Log (10*viscen) = --------------- + Enc2
! 10 2
! (Tp(C) - 150)
! In literature, the range of the critical viscosity visref is between
! 8 Pa.s and 1.D7 Pa.s For general purpose 1.0D+4 Pa.s is chosen
if (iphyla.eq.2) then
! iencra = 0 no fouling (default)
! = 1 fouling
! * In uslag2.f90, the boundary on which the fouling can occur must be given
! * Post-processing: iensi3 = 1 and
! * iencnbbd = 1 / iencmabd = 1 / iencdibd = 1 /iencckbd = 1 (10.2)
iencra = 0
! Example of definition of fouling criteria for each coal
! first (and single) coal icha = 1
icha = 1
! tprenc : threshold temperature below which no fouling occurs
! (in degrees Celcius)
tprenc(icha) = 600.d0
! visref : critical viscosity (Pa.s)
visref(icha) = 10000.d0
! > coal composition in mineral matters:
! (with SiO2 + Al2O3 + Fe2O3 + CaO + MgO = 100% in mass)
sio2 = 36.0d0
al2o3 = 20.8d0
fe2o3 = 4.9d0
cao = 13.3d0
! Enc1 and Enc2 : coefficients in Watt and Fereday expression
enc1(icha) = 0.00835d0 * sio2 + 0.00601d0 * al2o3 - 0.109d0
enc2(icha) = 0.0415d0 * sio2 + 0.0192d0 * al2o3 &
+ 0.0276d0 * fe2o3 + 0.016 * cao - 3.92d0
endif
!===============================================================================
! 4. Number of particles allowed simultaneously inside the computational domain
!===============================================================================
! * Warning, memory is allocated with NBPMAX
nbpmax = 1000000
!===============================================================================
! 5. Calculation features for the dispersed phases
!===============================================================================
! 5.1 Additional variables
! ------------------------
! * these additional variables are stored in ettp and ettpa arrays
! * nvls is the number of additional variables
! * the upper limit is nusvar = 10 (fixed in block common lagpar.f90)
! * one access to additional variables in ettp ettpa using the pointer jvls:
! current step -> ettp(nbpt,jvls(nvus))
! previous step -> ettpa(nbpt,jvls(nvus))
! nbpt is the number of the considered particle
! (integer between 1 and nbpart),
! nvus is the number of the additional variable
! (integer between 1 and nvls),
! * the integration of the associated differential stochastic equation
! requires a user intervention in uslaed.f90 subroutine
nvls = 0
! 5.2 Stationary or unsteady continuous phase
! * if stationary: isttio = 1
! * if unsteady: isttio = 0
! * if iilagr = 3 then isttio = 1
! Remark: if isttio = 0, then the statistical averages are reset
! at each lagrangian iteration
if (iilagr.ne.3) isttio = 0
! 5.3 Two-way coupling: (iilagr = 2)
if (iilagr.eq.2) then
! * number of absolute lagrangian iteration (i.e. with restart)
! from which a time average for two-way coupling source terms is
! computed (stationary source terms)
! * if the Lagrangian iteration is lower than NSTITS, source terms are
! unstationary: they are reset at each lagrangian iteration
! * useful only if ISTTIO = 1.
! * the min value for NSTITS is 1
nstits = 1
! two-way coupling for dynamic (velocities and turbulent scalars)
! (default off: 0 ; on: 1)
! (useful if ICCVFG = 0)
ltsdyn = 0
! two-way coupling for mass (if IPHYLA = 1 and IMPVAR = 1)
! (default off: 0 ; on: 1)
if(iphyla.eq.1 .and. (impvar.eq.1 .or. idpvar.eq.1)) ltsmas = 0
! two-way coupling for thermal scalar
! (if iphyla = 1 and impvar = 1, or iphyla = 2)
! or for coal variables (if IPHYLA = 2)
! (default off: 0 ; on: 1)
if((iphyla.eq.1 .and. itpvar.eq.1) .or. iphyla.eq.2) ltsthe = 0
endif
! 5.4 Volume statistics
! ---------------------
! 5.4.1 Generic parameters
! ~~~~~~~~~~~~~~~~~~~~~~~~~
! Calculation of the volume statistics
! (default off: 0 ; on: 1)
istala = 0
if (istala.eq.1) then
! Threshold for the management of volume statistics
! -------------------------------------------------
! * the value of the seuil variable is a statistical weight.
! * each cell of the mesh contains a statistical weight
! (sum of the statistical weights of all the particles
! located in the cell); seuil is the minimal value from
! which the contribution in statistical weight of a particle
! is not taken into account anymore in the full model
! of turbulent dispersion, in the resolution of the
! Poisson equation of correction of the mean velocities, and
! in the writing of the listing and post-processing.
!
seuil = 0.d0
! Calculation of the volume statistics from the absolute number
! of Lagrangian iterations
! * idstnt is a absolute number of Lagrangian iterations
! (i.e. including calculation restarts)
idstnt = 1
! Steady calculation from the absolute Lagrangian iteration nstist
! * nstist is a absolute number of Lagrangian iterations
! (i.e. including calculation restarts) from which the statistics
! are averaged in time.
! * useful if the calculation is stationary (isttio=1)
! * if the number of Lagrangian iterations is lower than nstits,
! the transmitted source terms are unsteady (i.e. they are reset to
! zero ar each Lagrangian iteration)
! * the minimal value acceptable for nstist is 1.
nstist = idstnt
! 5.4.2 Volume statistical variables
! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
! Activation of the calculation of the particle volume fraction
! Name of the mean : Part_vol_frac
iactfv = 1
! Activation of the calculation of the particle velocity x-component
! (mean and variance)
! Name of the mean: Part_velocity_X
! Name of the variance: var_Part_velocity_X
iactvx = 1
! Activation of the calculation of the particle velocity y-component
! (average and variance)
! Name of the mean: Part_velocity_Y
! Name of the variance: var_Part_velocity_Y
iactvy = 1
! Activation of the calculation of the particle velocity z-component
! (average and variance)
! Name of the mean: Part_velocity_Z
! Name of the variance: var_Part_velocity_Z
iactvz = 1
! Activation of the calculation of the particle residence time
! (mean and variance)
! Name of the mean: Part_resid_time
! Name of the variance: var_Part_resid_time
iactts = 1
! 2) Specific models (iphyla = 1) following the chosen options:
! Mean and variance of the temperature
! Mean and variance of the diameter
! Mean and variance of the mass
if (iphyla.eq.1) then
if (itpvar.eq.1) then
ipv = ipv + 1
nomlag(ipv) = 'MoTempPt'
nomlav(ipv) = 'VaTempPt'
ihslag(ipv) = 2
endif
if (idpvar.eq.1) then
ipv = ipv + 1
nomlag(ipv) = 'MoDiamPt'
nomlav(ipv) = 'VaDiamPt'
ihslag(ipv) = 2
endif
if (impvar.eq.1) then
ipv = ipv + 1
nomlag(ipv) = 'MoMassPt'
nomlav(ipv) = 'VaMassPt'
ihslag(ipv) = 2
endif
else if (iphyla.eq.2) then
! 3) Pulverized coal (iphyla = 2) :
! Mean and variance of the mass
! Mean and variance of the temperature
! Mean and variance of the water mass
! Mean and variance of the mass of reactive coal
! Mean and variance of the mass of coke
! Mean and variance of the diameter of the shrinking core
ipv = ipv + 1
nomlag(ipv) = 'Part_mass'
nomlav(ipv) = 'var_Part_mass'
ihslag(ipv) = 2
ipv = ipv + 1
nomlag(ipv) = 'Part_temperature'
nomlav(ipv) = 'var_Part_temperature'
ihslag(ipv) = 2
ipv = ipv + 1
nomlag(ipv) = 'Part_wat_mass'
nomlav(ipv) = 'var_Part_wat_mass'
ihslag(ipv) = 2
ipv = ipv + 1
nomlag(ipv) = 'Part_ch_mass'
nomlav(ipv) = 'var_Part_ch_mass'
ihslag(ipv) = 2
ipv = ipv + 1
nomlag(ipv) = 'Part_ck_mass'
nomlav(ipv) = 'var_Part_ck_mass'
ihslag(ipv) = 2
ipv = ipv + 1
nomlag(ipv) = 'Part_shrink_core_diam'
nomlav(ipv) = 'var_Part_shrink_core_diam'
ihslag(ipv) = 2
endif
! 4) Additional volume statistical variables
! ---------------------------------------
! * If the user wishes other statistic calculations
! than the standard ones, he must 1) prescribe
! their number nvlsts, 2) prescribe their names,
! 3) prescribe ihslag and 4) intervene in the
! user subroutines uslast and uslaen to implement
! his new statistics (see the given examples)
! * Default maximal number of additional statistics: 20.
! (Otherwise, modify the nussta parameter is the
! include file lagpar.f90)
nvlsts = 0
if (nvlsts.gt.0) then
do ii = 1,nvlsts
ilvu(ii) = ipv + ii
WRITE(NOMLAG(ILVU(II)),'(A6,I4.4)') 'MoyLag',II
WRITE(NOMLAV(ILVU(II)),'(A6,I4.4)') 'VarLag',II
ihslag(ilvu(ii)) = 1
enddo
ipv = ipv + nvlsts
endif
! 6) Statistics per group:
! ----------------------
! * if the user wishes to calculate statistics per group of particles
! (by default there is no statistics of this kind), he must:
! 1) prescribe nbclst the number of groups (limited to 100)
! 2) assign in uslag2 the group to which belongs each particle
! through the iuslag array.
!
! * Be careful, nbclst cannot be modified during a calculation restart
! (isuila=1); even if the calculation of the statistics is not triggered yet
! (istala=0).
nbclst = 0
endif
!===============================================================================
! 6. Option concerning particle inlet
!===============================================================================
! Continous particle injection during the time step
! (and not only at the beginning the time step; this option
! makes it possible to avoid bunches of particles in the vicinity
! of the inlet zones)
! (default off: 0 ; on: 1)
injcon = 0
!===============================================================================
! 7. Techniue of variance reduction: cloning/merge of the particles
!===============================================================================
! Use of the Russian roulette
! default off : 0
! on : 1 without Y+ calculation
! 2 with Y+ calculation
iroule = 0
!===============================================================================
! 8. Options concerning the numerical treatment of the dispersed phase
!===============================================================================
! Integration order of the stochastic differential equations
! (default 2; acceptable values 1 or 2)
!
nordre = 2
! Resolution of the Poisson equation for the particle mean velocity
! and correction of the particle instantaneous velocity
! = 0: not correction of the velocities (default values)
! = 1: correction of the instantaneous velocities
! Caution: OPTION STRICTLY FOR DEVELOPERS; PLEASE LEAVE THE DEFAULT VALUE FOR A
! ======== STANDARD USE OF THE CODE. !
ilapoi = 0
!===============================================================================
! 9. Options concerning the treatment of the dispersed phase
!===============================================================================
! Caution: In this version, the turbulent dispersion works only if
! ------- the continuous phase is calculated with a k-eps or a Rij-eps model
! Activation of the turbulent dispersion
! (default on: 1 ; off: 0)
idistu = 1
! Turbulent dispersion imposed to the fluid one.
! If activated, then particle turbulent dispersion is
! equal to the fluid-particle one. The crossing-trajectory effects
! are suppressed ; it is then a case of turbulent diffusion. If the
! simulated particle density is equal to the fluid density, then
! we are simulating the displacement of fluid particles.
! (default off: 0 ; on: 1)
idiffl = 0
! modcpl :
! = 0 for the incomplete model (default value)
! > 0 for the full model, is equal the absolute number
! of Lagrangian iterations from which the full model is activated
! modcpl must not be lower than idstnt
modcpl = 0
! idirla (=1 or 2 or 3) : 1st, 2nd or 3rd direction
! of the full model. Corresponds to the main direction
! of the flow. Allow to calculate a non-isotropic Lagrangian timescale
! (default idirla=1)
if (modcpl.gt.0) idirla = 1
!===============================================================================
! 10. Options concerning the treatment of specific forces
!===============================================================================
! idlvo = 0
! = 1 dlvo deposition conditions are activated for the
! wall with appropriate conditions idepfa (see uslag2.f90)
idlvo = 0
if (idlvo.eq.1) then
! Constants for the van der Waals forces
! --------------------------------------
! Hamaker constant for the particle/fluid/substrate system:
cstham = 6.d-20
! Constants for the elecstrostatic forces
!----------------------------------------
! Dielectric constant of the fluid (example: water at 293 K)
epseau = 80.10d0
! Electrokinetic potential of the first solid (Volt)
phi1 = 50.d-3
! Electrokinetic potential of the second solid (Volt)
phi2 = -50.d-3
! Ionic force (mol/l)
fion = 1.d-2
endif
!===============================================================================
! 11. Activation of Brownian motion
!===============================================================================
! Activation of Brownian motion:
! (default off: 0 ; on: 1)
! Caution: OPTION FOR DEVELOPERS ONLY
! ========
lamvbr = 0
!===============================================================================
! 12. Activation of deposition model
!===============================================================================
! Activation of the deposition model
! (default off: 0 ; on: 1)
idepst = 0
!===============================================================================
! 12bis. Activation of resuspension model
!===============================================================================
! Activation of the resuspension model
! (default off: 0 ; on: 1)
! Caution: OPTION FOR DEVELOPERS ONLY
! ========
ireent = 0
! Parameters of the particle resuspension model
espasg = 20.d-6
denasp = 6.36d13
modyeq = 266.d9
rayasp = 5.d-9
rayasg = 2.d-6
!===============================================================================
! 12ter. Activation of the clogging model
!===============================================================================
! Activation of the clogging model
! (default off: 0 ; on: 1)
! Caution: OPTION FOR DEVELOPERS ONLY
! ========
iclogst = 0
! Parameters for the particle clogging model
jamlim = 0.74d0 ! Jamming limit
mporos = 0.366d0 ! Minimal porosity
!===============================================================================
! 13. Variables to visualize on the trajectories or the particles
!
! See also cs_user_postprocess_mesh in cs_user_postprocess.c to define
! the associated visualization particle or trajectory segment meshes.
!===============================================================================
! For all the following variables, a value of 0 means "off", and 1 means "on"
! velocity of the flow seen
ivisv1 = 0
! particle velocity
ivisv2 = 0
! residence time
ivistp = 0
! diameter
ivisdm = 0
! temperature
if (iphyla.eq.1 .and. itpvar.eq.1) iviste = 0
! mass
ivismp = 0
if (iphyla.eq.2) then
! coal: diameter of the shrinking core
ivisdk = 0
! coal: mass of water
iviswat = 0
! coal: mass of reactive coal
ivisch = 0
! coal: mass of coke
ivisck = 0
endif
! 13.2 Boundary statistics: visualization of the particle/boundaries interactions
! ------------------------------------------------
! 13.2.1 Generic parameters
! ~~~~~~~~~~~~~~~~~~~~~~~~~~
! Particle/boundary interaction mode
! (default off: 0 ; on: 1)
iensi3 = 0
! Stationary calculation of the boundary statistics from
! the absolute Lagrangian iteration nstbor.
! * nstbor is the absolute number of Lagrangian iterations
! (i.e. including restarts) from which the statistics are averaged
! (in time or by number of interactions)
! * useful if the calculation is stationary (isttio=1)
! * if the absolute number of Lagrangian iterations is inferior to
! nstbor, the statistics are unsteady (i.e. they are reset to zero at each
! Lagrangian iteration)
nstbor = 1
! Seuilf for the management of the boundary statistics
! * the value of seuilf is a statistical weight
! * Each boundary face has undergone a number of particle interactions
! in term of statistical weight (sum of the statistical weights of all
! the particles that interacted with the boundary face); seuilf is the
! minimal value from which the contribution of a face (in statistical terms)
! is not taken into account anymore in the writing of the listing and
! post-processing.
seuilf = 0.d0
! 13.2.2 Information to be recorded
! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
!
! * To activate them, the user has to set below
! the corresponding keyword to 1.
! * The default selection must be validated or modified by the user.
! * By default the asked information for all the particle/wall interactions
! are written in the same recording.
! * The boundary statistic 'number of particle/boundary interactions' must be
! selected to activate the particle average imoybr(...) = 2
! Number of particle/boundary interactions
! (default off: 0 ; on: 1)
inbrbd = 1
! Particle mass flux associated to particle/boundary interactions
! (default off: 0 ; on: 1)
iflmbd = 1
! Angle between particle velocity and the plan of the boundary face
! (default off: 0 ; on: 1)
iangbd = 0
! Norm of particle velocity during the interation with the boundary face
! (default off: 0 ; on: 1)
ivitbd = 0
! (default off: 0 ; on: 1)
if (iphyla.eq.2 .and. iencra.eq.1) then
! Number of particle/boundary interactions with fouling
iencnbbd = 0
! Mass of fouled coal particles
iencmabd = 0
! Diameter of fouled coal particles
iencdibd = 0
! Coke fraction of fouled coal particles
iencckbd = 0
endif
! Additional user information to be recorded
! ------------------------------------------
! (for instance, erosion rate, temperature..)
! * these additional recordings are stored in the parbor array
! * here we prescribe the nusbor number of additional recordings
! * the max value of this number is nusbrd=10 (in lagpar.f90)
nusbor = 0
! 13.2.3 Name of the recordings for display,
! Average in time of particle average
! of the boundary statistics
! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
! * A priori the user intervenes only in the additional user information
! to be recorded: he must prescribe the name of the recording as well as
! the type of average that he wishes to apply to it for the writing
! of the listing and the post-processing.
! * The applied average is prescribed through the imoybr array:
! - if imoybr(iusb(ii)) = 0 -> no average applied
! - if imoybr(iusb(ii)) = 1 -> a time average is applied, i.e. the
! statistic is divided by the last time step in the case of an unsteady
! calculation with a number of iterations lower than nstbor; or that
! the statistic is divided by the recording time in the case of a
! steady calculation.
! -if imoybr(iusb(ii)) = 2 -> a particle average is applied, i.e. the
! statistic is divided by the number of recorded particle/boundary
! interactions (in terms of statistical weight) in parbor(nfabor,inbr)
! To use this average, inbrbd must be set to 1.
! - if imoybr(iusb(ii)) = 3 -> (coal fouling only) a particle average
! is applied, i.e. the statistic is divided by the number of recorded
! particle/boundary interactions with fouling (in terms of statistical
! weight) in parbor(nfabor,inbr), To use this average, iencnbbd must be
! set to 1.
! * The back-ups in the restart file are performed without applying
! this average.
! * The average is applied if the number of interactions (in statistical
! weight) of the boundary face considered is greater than seuilf;
! otherwise this average is set to zero.
!===============================================================================
! 14. Lagrangian listing
!===============================================================================
! Lagrangian period for the writing of the Lagrangian listing
ntlal = 1
!===============================================================================
return
end subroutine uslag1
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