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|
*DECK EVODRV
SUBROUTINE EVODRV(IPDEPL,IPLIB,INDREC,IMPX,NBISO,NGROUP,NBMIX,
1 ISONAM,ISONRF,MIX,DEN,IEVOL,ISTYP,VX,NDEPL,NSUPS,NREAC,NCOMB,
2 EPS1,EPS2,EXPMAX,H1,ITYPE,INR,IEXTR,IGLOB,ISAT,IDIRAC,ITIXS,
3 IFLMAC,IYLMIX,FIT,ISAVE,ISET,IDEPL,XTI,XTF,XT,LMACRO,FLUMIX,
4 IPICK,MIXBRN,MIXPWR)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Isotopic depletion calculation main driver.
*
*Copyright:
* Copyright (C) 2002 Ecole Polytechnique de Montreal
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version
*
*Author(s): A. Hebert
*
*Parameters: input
* IPDEPL pointer to the depletion history (L_BURNUP signature).
* IPLIB pointer to the lattice microscopic cross section library
* (L_LIBRARY signature).
* INDREC beginning of depletion flag (=1: beginning; =2: else).
* IMPX print flag (equal to zero for no print).
* NBISO number of isotopes present in the calculation domain.
* NGROUP number of energy groups.
* NBMIX number of mixtures.
* ISONAM alias name of isotopes.
* ISONRF library name of isotopes.
* MIX mix number of each isotope (can be zero).
* DEN density of each isotope.
* IEVOL non-depleting flag (=1 to force an isotope to be
* non-depleting; =2 to force an isotope to be depleting;
* =3: to force an isotope to be at saturation).
* ISTYP isotope type (=1 not fissile nor fission product; =2: fissile;
* =3: fission product).
* VX volume occupied by each mixture.
* NDEPL number of isotopes in the depletion chain.
* NSUPS number of non-depleting isotopes producing energy.
* NREAC maximum number of depletion reactions.
* NCOMB number of depleting mixtures.
* EPS1 required accuracy for the ODE solver.
* EPS2 required accuracy for constant power iterations.
* EXPMAX saturation limit. A nuclide is saturating if
* -ADPL(MU1(I))*(XT(2)-XT(1)).GT.EXPMAX. Suggested value:
* EXPMAX=80.0.
* H1 guessed first stepsize.
* ITYPE type of ODE solution:
* =1 fifth-order Runge-Kutta method;
* =2 fourth-order Kaps-Rentrop method.
* INR type of flux normalization:
* =0: out-of-core depletion;
* =1: constant flux depletion;
* =2: constant fuel power depletion;
* =3: constant assembly power depletion.
* IEXTR flux extrapolation flag (=0: no extrapolation; =1: perform
* linear extrapolation; =2: perform parabolic extrapolation).
* IGLOB out-of-fuel power in flux normalization. Compute the burnup:
* =-1: using the Serpent mode 0 empirical formula in the fuel;
* =0: using the power released in the fuel;
* =1: using the power released in the global geometry.
* ISAT initial saturation flag (=1 to save initial saturated number
* densities).
* IDIRAC saturation model flag (=1 to use Dirac function contributions
* in the saturating nuclide number densities).
* ITIXS flag for time-dependent cross sections (=0/1: on/off).
* IFLMAC 0/1/2 flag to recover fluxes from L_FLUX/L_MACROLIB/L_POWER.
* IYLMIX 0/1 flag to recover fission yield data from DEPL-CHAIN/PYIELD
* data.
* FIT flux normalization factor:
* n/cm**2/s if INR=1;
* MW/tonne of initial heavy elements if INR=2;
* W/cc of assembly volume if INR=3.
* ISAVE save flag:
* =-1: do not save the last flux calculation in the depletion
* table;
* .GE.0 save the last flux calculation in the depletion
* table at time XTI.
* ISET set flag:
* =-1: do not set the number densities to a selected time;
* .GE.0 set the number densities to time XTF of the depletion
* table.
* IDEPL depletion flag:
* =0: do not perform a depletion calculation
* =1: perform a depletion calculation.
* XTI initial save time (save the last flux calculation in the
* depletion table at time XTI).
* XTF final set time (recover the number densities from the
* depletion table at time XTF and modify the internal library).
* XT time variable (independent variable) for the depletion
* calculation.
* XT(1) initial time
* XT(2) final time
* LMACRO macrolib building flag (=.true. to compute the embedded
* macrolib).
* FLUMIX average fluxes in mixtures.
* IPICK burnup recovery flag:
* =0: do not recover the burnup in a CLE-2000 variable
* =1: recover the burnup in a CLE-2000 variable.
* MIXBRN flags for mixtures to burn.
* MIXPWR flags for mixtures to include in power normalization.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPDEPL,IPLIB
INTEGER INDREC,IMPX,NBISO,NGROUP,NBMIX,ISONAM(3,NBISO),
1 ISONRF(3,NBISO),MIX(NBISO),IEVOL(NBISO),ISTYP(NBISO),NDEPL,
2 NSUPS,NREAC,NCOMB,ITYPE,INR,IEXTR,IGLOB,ISAT,IDIRAC,ITIXS,
3 IFLMAC,IYLMIX,ISAVE,ISET,IDEPL,IPICK,MIXBRN(NBMIX),
4 MIXPWR(NBMIX)
REAL DEN(NBISO),VX(NBMIX),EPS1,EPS2,EXPMAX,H1,FIT,XTI,XTF,
1 XT(2),FLUMIX(NGROUP,NBMIX)
LOGICAL LMACRO
*----
* LOCAL VARIABLES
*----
PARAMETER (IUNOUT=6,NSTATE=40)
TYPE(C_PTR) KPLIB
CHARACTER TEXT12*12,HSMG*131
LOGICAL LCOOL
INTEGER IDIM(NSTATE),IPAR(NSTATE)
REAL DELTA(3),RPAR(5),BRNWIR(2),TMPDAY(3),VPH(2),
1 FUELDN(3),DELTAT(2,2),TIMEP(2,3)
DOUBLE PRECISION T(3),WEI,DPD,XDRCST,AVCON,VTOTD,VPHINI,DBLLIR
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: MILVO,ISOCMB,NFISS2,
1 NDFP2,HREAC,IPIFI,IZAE
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: JM,INADPL,IEVOLB,KFISS,
1 KPAR,IDR,KPF
REAL, ALLOCATABLE, DIMENSION(:) :: ENERG,RRD,AWR,PYIELD,TIMES
REAL, ALLOCATABLE, DIMENSION(:,:) :: BPAR,RER,VPHV
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: YDPL,YIELD,YIELD2
REAL, ALLOCATABLE, DIMENSION(:,:,:,:) :: SIG
LOGICAL, ALLOCATABLE, DIMENSION(:) :: MASK,MASKL
TYPE(C_PTR), ALLOCATABLE, DIMENSION(:) :: IPISO
*----
* SCRATCH STORAGE ALLOCATION
* MILVO mixture index corresponding to each depleting mixture.
*----
ALLOCATE(JM(NBMIX,NDEPL),MILVO(NCOMB),ISOCMB(NBISO),
1 INADPL(3,NDEPL),IEVOLB(NDEPL,NBMIX))
ALLOCATE(SIG(NDEPL-NSUPS+1,NREAC+1,NBMIX,1-IEXTR:2),
1 VPHV(NBMIX,1-IEXTR:2),ENERG(NBMIX),AWR(NDEPL),IZAE(NDEPL),
2 YDPL(NDEPL-NSUPS+1,2,NCOMB))
ALLOCATE(MASK(NBMIX),MASKL(NGROUP))
ALLOCATE(IPISO(NBISO))
*----
* INITIALIZE DATA.
*----
AVCON=XDRCST('Neutron mass','amu')/
1 (1.0D-24*XDRCST('Avogadro','N/moles'))
*
IF(INDREC.EQ.1) THEN
* BEGINNING OF DEPLETION.
NTIM=0
ELSE IF(INDREC.EQ.2) THEN
CALL LCMLEN(IPDEPL,'DEPL-TIMES',NTIM,ITYLCM)
ENDIF
IF(NTIM+2.GE.10000) CALL XABORT('EVODRV: No more than 9999'//
>'burnup steps permitted.')
ALLOCATE(TIMES(NTIM+2))
TIMES(:NTIM+2)=0.0
IF(NTIM.EQ.0) THEN
CALL LCMPUT(IPDEPL,'DEPL-TIMES',1,2,TIMES)
ELSE
CALL LCMGET(IPDEPL,'DEPL-TIMES',TIMES)
ENDIF
*----
* RECOVER DEPLETION CHAIN INFO FROM LCM
*----
NVAR=NDEPL-NSUPS
CALL LCMLEN(IPLIB,'DEPL-CHAIN',LENGT,ITYLCM)
IF (LENGT.EQ.0) CALL XABORT('EVODRV: DEPLETION CHAIN MISSING.')
CALL LCMSIX(IPLIB,'DEPL-CHAIN',1)
CALL LCMGET(IPLIB,'STATE-VECTOR',IDIM)
IF((NDEPL.NE.IDIM(1)).OR.(NSUPS.NE.IDIM(7)))
1 CALL XABORT('EVODRV: INCONSISTENT NDEPL OR NSUPS.')
IF(NVAR.EQ.0) CALL XABORT('EVODRV: NO DEPLETING ISOTOPES')
NFISS=IDIM(2)
NDFP=IDIM(3)
NPAR=IDIM(9)
NBESP=MAX(1,IDIM(10))
ALLOCATE(KPAR(NDEPL,NPAR),HREAC(2*NREAC),IDR(NREAC,NDEPL))
ALLOCATE(BPAR(NDEPL,NPAR),YIELD2(NBESP,NFISS,NDFP),
1 RER(NREAC,NDEPL),RRD(NDEPL))
CALL LCMGET(IPLIB,'ISOTOPESDEPL',INADPL)
IF(IMPX.GT.1) THEN
WRITE(IUNOUT,'(/38HEVODRV: DEPLETING ISOTOPES FROM CHAIN:)')
WRITE(IUNOUT,'(1X,3A4,2X,3A4,2X,3A4,2X,3A4,2X,3A4,2X,3A4,2X,
1 3A4,2X,3A4,2X,3A4,2X,3A4,2X,3A4,2X,3A4)') INADPL(:3,:NVAR)
ENDIF
CALL LCMGET(IPLIB,'PRODUCE-REAC',KPAR)
CALL LCMGET(IPLIB,'PRODUCE-RATE',BPAR)
CALL LCMGET(IPLIB,'DEPLETE-IDEN',HREAC)
CALL LCMGET(IPLIB,'DEPLETE-REAC',IDR)
CALL LCMGET(IPLIB,'DEPLETE-ENER',RER)
CALL LCMGET(IPLIB,'DEPLETE-DECA',RRD)
CALL LCMGET(IPLIB,'CHARGEWEIGHT',IZAE)
IF(NFISS*NDFP.GT.0) CALL LCMGET(IPLIB,'FISSIONYIELD',YIELD2)
CALL LCMSIX(IPLIB,' ',2)
*----
* SET THE LCM MICROLIB ISOTOPEWISE DIRECTORIES.
*----
CALL LIBIPS(IPLIB,NBISO,IPISO)
*----
* DETECT THE DEPLETING ISOTOPES AND MIXTURES IN THE MICROLIB.
*----
ICOMB=0
JM(:NBMIX,:NDEPL)=0
IEVOLB(:NDEPL,:NBMIX)=1
ALLOCATE(NFISS2(NBMIX),NDFP2(NBMIX))
NFISS2(:NBMIX)=0
NDFP2(:NBMIX)=0
AWR(:NDEPL)=0.0
DO 30 ISOT=1,NBISO
IBM=MIX(ISOT)
IF(IBM.EQ.0) GO TO 30
KPLIB=IPISO(ISOT) ! set ISOT-th isotope
DO 20 INUCL=1,NDEPL
IF((ISONRF(1,ISOT).EQ.INADPL(1,INUCL)).AND.(ISONRF(2,ISOT).EQ.
1 INADPL(2,INUCL))) THEN
IF(JM(IBM,INUCL).GT.0) GO TO 20
IF(C_ASSOCIATED(KPLIB)) THEN
CALL LCMLEN(KPLIB,'AWR',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(KPLIB,'AWR',AWR(INUCL))
ENDIF
IF(INUCL.GT.NVAR) THEN
IF(JM(IBM,INUCL).EQ.0) THEN
IEVOLB(INUCL,IBM)=1
JM(IBM,INUCL)=-ISOT
ENDIF
ELSE IF(IEVOL(ISOT).EQ.1) THEN
IF(JM(IBM,INUCL).EQ.0) THEN
IEVOLB(INUCL,IBM)=1
JM(IBM,INUCL)=-ISOT
ENDIF
IF(ISTYP(ISOT).EQ.2) THEN
NFISS2(IBM)=NFISS2(IBM)+1
JM(IBM,INUCL)=ISOT
ENDIF
ELSE
IF(ISTYP(ISOT).EQ.2) THEN
NFISS2(IBM)=NFISS2(IBM)+1
ELSE IF(ISTYP(ISOT).EQ.3) THEN
NDFP2(IBM)=NDFP2(IBM)+1
ENDIF
IEVOLB(INUCL,IBM)=IEVOL(ISOT)
JM(IBM,INUCL)=ISOT
IF(IEVOL(ISOT).EQ.1) GO TO 30
DO 10 J=1,ICOMB
IF(IBM.EQ.MILVO(J)) GO TO 30
10 CONTINUE
ICOMB=ICOMB+1
MILVO(ICOMB)=IBM
ENDIF
GO TO 30
ENDIF
20 CONTINUE
30 CONTINUE
IF(ICOMB.NE.NCOMB) THEN
WRITE(HSMG,'(38HEVODRV: INVALID VALUE OF NCOMB (ICOMB=,I5,
1 7H NCOMB=,I5,2H).)') ICOMB,NCOMB
CALL XABORT(HSMG)
ENDIF
DO 35 J=1,ICOMB
IBM=MILVO(J)
IF(MIXBRN(IBM).EQ.0) MILVO(J)=0
35 CONTINUE
IF(IYLMIX.EQ.1) THEN
NFISS=MAXVAL(NFISS2)
NDFP=MAXVAL(NDFP2)
ENDIF
DEALLOCATE(NDFP2,NFISS2)
IF(IMPX.GT.0) WRITE(IUNOUT,500) NFISS,NDFP
*----
* SET KFISS, KPF AND YIELD
*----
ALLOCATE(KFISS(NFISS,NBMIX),KPF(NDFP,NBMIX),
1 YIELD(NFISS,NDFP,NBMIX))
KFISS(:NFISS,:NBMIX)=0
KPF(:NDFP,:NBMIX)=0
IF(IYLMIX.EQ.0) THEN
* Use fission yield data from 'DEPL-CHAIN'
DO 40 IS=1,NVAR
KDRI=IDR(2,IS)/100
IF((KDRI.GT.0).AND.(MOD(IDR(2,IS),100).EQ.4)) THEN
IF(KDRI.GT.NFISS) CALL XABORT('EVODRV: INVALID NFISS.')
KFISS(KDRI,:NBMIX)=IS
ELSE IF((KDRI.GT.0).AND.(MOD(IDR(2,IS),100).EQ.5)) THEN
IF(KDRI.GT.NDFP) CALL XABORT('EVODRV: INVALID NDFP.')
KPF(KDRI,:NBMIX)=IS
ENDIF
40 CONTINUE
DO IDFP=1,NDFP
DO IFISS=1,NFISS
YIELD(IFISS,IDFP,:NBMIX)=YIELD2(NBESP,IFISS,IDFP)
ENDDO
ENDDO
ELSE IF(IYLMIX.EQ.1) THEN
* Use isotopic PIFI/PYIELD fission yield data
YIELD(:NFISS,:NDFP,:NBMIX)=0.0
DO 65 IBM=1,NBMIX
IFISS=0
IDFP=0
DO 50 IS=1,NVAR
ISOT=ABS(JM(IBM,IS))
IF(ISOT.EQ.0) GO TO 50
IF(ISTYP(ISOT).EQ.2) THEN
IFISS=IFISS+1
IF(IFISS.GT.NFISS) CALL XABORT('EVODRV: NFISS OVERFLOW.')
KFISS(IFISS,IBM)=IS
IF(IDR(2,IS).EQ.0) IDR(2,IS)=4
ELSE IF(ISTYP(ISOT).EQ.3) THEN
IDFP=IDFP+1
IF(IDFP.GT.NDFP) CALL XABORT('EVODRV: NDFP OVERFLOW.')
KPF(IDFP,IBM)=IS
IF(IDR(2,IS).EQ.0) IDR(2,IS)=5
ENDIF
50 CONTINUE
DO 60 IS=1,NVAR
ISOT=JM(IBM,IS)
IF(ISOT.LE.0) GO TO 60
KPLIB=IPISO(ISOT) ! set ISOT-th isotope
IF(.NOT.C_ASSOCIATED(KPLIB)) THEN
WRITE(HSMG,'(17HEVODRV: ISOTOPE '',3A4,16H'' IS NOT AVAILAB,
> 22HLE IN THE MICROLIB(1).)') (ISONAM(I0,ISOT),I0=1,3)
CALL XABORT(HSMG)
ENDIF
CALL LCMLEN(KPLIB,'PIFI',NDFI,ITYLCM)
IF(NDFI.GT.0) THEN
ALLOCATE(IPIFI(NDFI),PYIELD(NDFI))
CALL LCMGET(KPLIB,'PIFI',IPIFI)
CALL LCMGET(KPLIB,'PYIELD',PYIELD)
IDFP=0
DO I=1,NDFP
IF(KPF(I,IBM).EQ.IS) THEN
IDFP=I
EXIT
ENDIF
ENDDO
IF(IDFP.EQ.0) THEN
WRITE(IUNOUT,510) 'FISSION PRODUCT',IS,(KPF(I,IBM),
1 I=1,NDFP)
WRITE(HSMG,'(39HEVODRV: UNABLE TO FIND FP INDEX FOR ISO,
1 5HTOPE ,3A4,5H (1).)')(ISONAM(I0,ISOT),I0=1,3)
CALL XABORT(HSMG)
ENDIF
DO 55 I=1,NDFI
IF(IPIFI(I).EQ.0) GO TO 55
DO JST=1,NVAR
IF(ABS(JM(IBM,JST)).EQ.IPIFI(I)) THEN
IFISS=0
DO J=1,NFISS
IF(KFISS(J,IBM).EQ.JST) THEN
IFISS=J
EXIT
ENDIF
ENDDO
IF(IFISS.EQ.0) THEN
WRITE(IUNOUT,510) 'FISSILE ISOTOPE',JST,
1 (KFISS(J,IBM),J=1,NFISS)
CALL XABORT('EVODRV: UNABLE TO FIND FISSILE I'
1 //'SOTOPE INDEX')
ENDIF
YIELD(IFISS,IDFP,IBM)=PYIELD(I)
GO TO 55
ENDIF
ENDDO
WRITE(HSMG,'(39HEVODRV: UNABLE TO FIND FP INDEX FOR ISO,
1 5HTOPE ,3A4,5H (2).)')(ISONAM(I0,ISOT),I0=1,3)
CALL XABORT(HSMG)
55 CONTINUE
DEALLOCATE(PYIELD,IPIFI)
ENDIF
60 CONTINUE
65 CONTINUE
ELSE
CALL XABORT('EVODRV: INVALID VALUE OF FLAG IYLMIX.')
ENDIF
DEALLOCATE(YIELD2)
*----
* COMPUTE THE INITIAL INTEGRATED FLUX
*----
VPHINI=0.0D0
DO 85 IU=1,NGROUP
DO 80 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.GT.0) VPHINI=VPHINI+FLUMIX(IU,IBM)*VX(IBM)
80 CONTINUE
85 CONTINUE
*----
* CHECK IF PERTURBATION XS OR STANDARD XS.
*----
NXSPER=1
CALL LCMLEN(IPLIB,'TIMESPER',LENGTH,ITYLCM)
IF((LENGTH.GE.2).AND.(LENGTH.LE.6)) THEN
CALL LCMGET(IPLIB,'TIMESPER',TIMEP)
DELTAT(1,1)=TIMEP(1,1)
DELTAT(2,1)=TIMEP(2,1)
TMPREF=DELTAT(1,1)
NXSPER=2
IF(ITIXS.EQ.0) THEN
DO 90 IP=1,2
DELTAT(1,IP)=1.0
DELTAT(2,IP)=XT(IP)/8.64E-4-TMPREF
90 CONTINUE
ELSE
XREF=XT(1)/8.64E-4
DO 100 IP=1,2
DELTAT(1,IP)=1.0
DELTAT(2,IP)=XREF-TMPREF
100 CONTINUE
ENDIF
ELSE
DO 110 IP=1,2
DELTAT(1,IP)=1.0
DELTAT(2,IP)=0.0
110 CONTINUE
ENDIF
*----
* COMPUTE AND SAVE THE INITIAL MASS OF HEAVY ELEMENTS
*----
VTOTD=0.0D0
DO ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.EQ.0) CYCLE
IF(MIXPWR(IBM).GT.0) VTOTD=VTOTD+DBLE(VX(IBM))
ENDDO
IF(INDREC.EQ.1) THEN
*
* COMPUTE THE GLOBAL HEAVY-ELEMENT MASS FOR ISOTOPES IN MIXPWR.
FUELDN(1)=0.0
IF(IGLOB.LE.0) THEN
DO 120 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.EQ.0) GO TO 120
IF(MIXPWR(IBM).GT.0) THEN
DO 115 IS=1,NBISO
IF((MIX(IS).NE.IBM).OR.(IEVOL(IS).EQ.1)) GO TO 115
KPLIB=IPISO(IS) ! set IS-th isotope
IF(C_ASSOCIATED(KPLIB)) THEN
AWRGAR=0.0
CALL LCMLEN(KPLIB,'AWR',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(KPLIB,'AWR',AWRGAR)
IF((AWRGAR.GT.210.0).OR.(ISTYP(IS).EQ.2)) THEN
FUELDN(1)=FUELDN(1)+AWRGAR*DEN(IS)*VX(IBM)
ENDIF
ENDIF
115 CONTINUE
ENDIF
120 CONTINUE
ELSE IF(IGLOB.EQ.1) THEN
DO 125 IBM=1,NBMIX
IF(MIXPWR(IBM).GT.0) THEN
DO 124 IS=1,NBISO
IF(MIX(IS).NE.IBM) GO TO 124
KPLIB=IPISO(IS) ! set IS-th isotope
IF(C_ASSOCIATED(KPLIB)) THEN
AWRGAR=0.0
CALL LCMLEN(KPLIB,'AWR',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(KPLIB,'AWR',AWRGAR)
IF((AWRGAR.GT.210.0).OR.(ISTYP(IS).EQ.2)) THEN
FUELDN(1)=FUELDN(1)+AWRGAR*DEN(IS)*VX(IBM)
ENDIF
ENDIF
124 CONTINUE
ENDIF
125 CONTINUE
ENDIF
IF(FUELDN(1).EQ.0) THEN
IF(INR.LE.1) THEN
FUELDN(1)=0.0
ELSE
CALL XABORT('EVODRV: Burnup at fixed power without '//
1 'heavy fissile isotopes is forbidden')
ENDIF
ELSE
FUELDN(1)=FUELDN(1)*REAL(AVCON/VTOTD)
ENDIF
FUELDN(2)=FUELDN(1)*REAL(VTOTD)
VASSMB=0.0
DO 130 IBM=1,NBMIX
IF(MIXPWR(IBM).EQ.1) THEN
VASSMB=VASSMB+VX(IBM)
ENDIF
130 CONTINUE
FUELDN(3)=FUELDN(2)/VASSMB
CALL LCMPUT(IPDEPL,'FUELDEN-INIT',3,2,FUELDN)
*
* COMPUTE THE HEAVY-ELEMENT MASS PER MIXTURE.
DO 150 IBM=1,NBMIX
ENERG(IBM)=0.0
DO 140 IS=1,NBISO
IF((MIX(IS).NE.IBM).OR.(IEVOL(IS).EQ.1)) GO TO 140
KPLIB=IPISO(IS) ! set IS-th isotope
IF(C_ASSOCIATED(KPLIB)) THEN
AWRGAR=0.0
CALL LCMLEN(KPLIB,'AWR',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(KPLIB,'AWR',AWRGAR)
IF((AWRGAR.GT.210.0).OR.(ISTYP(IS).EQ.2)) THEN
ENERG(IBM)=ENERG(IBM)+AWRGAR*DEN(IS)*VX(IBM)
ENDIF
ENDIF
140 CONTINUE
ENERG(IBM)=ENERG(IBM)*REAL(AVCON)
150 CONTINUE
CALL LCMPUT(IPDEPL,'FUELDEN-MIX',NBMIX,2,ENERG)
*
* COMPUTE THE TOTAL MASS PER MIXTURE.
ENERG(:NBMIX)=0.0
DO 170 IS=1,NBISO
IF(DEN(IS).EQ.0.0) GO TO 170
KPLIB=IPISO(IS) ! set IS-th isotope
AWRGAR=0.0
IF(C_ASSOCIATED(KPLIB)) THEN
CALL LCMLEN(KPLIB,'AWR',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(KPLIB,'AWR',AWRGAR)
ENDIF
DO 160 IBM=1,NBMIX
IF(MIX(IS).EQ.IBM) THEN
ENERG(IBM)=ENERG(IBM)+REAL(AWRGAR*DEN(IS)*VX(IBM)*AVCON)
ENDIF
160 CONTINUE
170 CONTINUE
CALL LCMPUT(IPDEPL,'WEIGHT-MIX',NBMIX,2,ENERG)
ELSE
CALL LCMGET(IPDEPL,'FUELDEN-INIT',FUELDN)
ENDIF
IF(IMPX.GT.0) THEN
WRITE (6,610) FUELDN(1),VTOTD,FUELDN(2),FUELDN(3)
ENDIF
*----
* SAVE THE LAST FLUX CALCULATION SET POINT IN THE DEPLETION TABLE.
* CROSS-SECTION PERTURBATION IS ENABLED IF ISAVE=0 AND NXSPER=2.
*----
IF(ISAVE.EQ.0) THEN
DO 200 IP=1,NXSPER
ITIM=0
IF(NTIM.GT.0) THEN
DO 180 I=1,NTIM
IF(ABS(TIMES(I)-XT(IP)).LE.1.0E-4*XT(IP)) ITIM=I
180 CONTINUE
ENDIF
IF(ITIM.EQ.0) THEN
IF(NTIM.GT.0) THEN
IF(XT(IP).LT.TIMES(NTIM)) CALL XABORT('EVODRV: INVALID X1.')
ENDIF
NTIM=NTIM+1
TIMES(NTIM)=XT(IP)
CALL LCMPUT(IPDEPL,'DEPL-TIMES',NTIM,2,TIMES)
ITIM=NTIM
ENDIF
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,530) XT(IP),XT(IP)/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMPUT(IPDEPL,'ISOTOPESDENS',NBISO,2,DEN)
*----
* COMPUTE, NORMALIZE AND SAVE THE MICROSCOPIC REACTION RATES.
*----
CALL EVOSIG(IMPX,INR,IGLOB,NGROUP,NBMIX,NBISO,NCOMB,ISONAM,
1 IPISO,DEN,FLUMIX,VX,MILVO,JM,NVAR,NSUPS,NREAC,HREAC,IDR,
2 RER,RRD,FIT,AWR,IZAE,FUELDN,NXSPER,DELTAT(1,IP),MIXPWR,PFACT,
3 SIG(1,1,1,IP),VPHV(1,IP))
NLENGT=(NVAR+1)*(NREAC+1)*NBMIX
CALL LCMPUT(IPDEPL,'MICRO-RATES',NLENGT,2,SIG(1,1,1,IP))
CALL LCMPUT(IPDEPL,'INT-FLUX',NBMIX,2,VPHV(1,IP))
VPHD=0.0
DO 190 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.GT.0) VPHD=VPHD+VPHV(IBM,IP)
190 CONTINUE
VPH(IP)=VPHD
IF(INR.NE.0) THEN
FNORM=VPH(IP)/REAL(VPHINI)
IF(INR.EQ.3) CALL LCMPUT(IPDEPL,'FORM-POWER',1,2,PFACT)
ELSE
FNORM=0.0
ENDIF
CALL LCMPUT(IPDEPL,'FLUX-NORM',1,2,FNORM)
IF((INDREC.EQ.1).AND.(IP.EQ.1)) THEN
BRNWIR(1)=0.0
BRNWIR(2)=0.0
CALL LCMPUT(IPDEPL,'BURNUP-IRRAD',2,2,BRNWIR)
ENDIF
CALL LCMSIX(IPDEPL,' ',2)
200 CONTINUE
ELSE IF(ISAVE.EQ.1) THEN
IP=1
ITIM=0
IF(NTIM.GT.0) THEN
DO 210 I=1,NTIM
IF(ABS(TIMES(I)-XTI).LE.1.0E-4*XTI) ITIM=I
210 CONTINUE
ENDIF
IF(ITIM.EQ.0) THEN
IF(NTIM.GT.0) THEN
IF(XTI.LT.TIMES(NTIM)) CALL XABORT('EVODRV: INVALID X1.')
ENDIF
NTIM=NTIM+1
TIMES(NTIM)=XTI
CALL LCMPUT(IPDEPL,'DEPL-TIMES',NTIM,2,TIMES)
ITIM=NTIM
ENDIF
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,530) XTI,XTI/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMPUT(IPDEPL,'ISOTOPESDENS',NBISO,2,DEN)
*----
* COMPUTE, NORMALIZE AND SAVE THE MICROSCOPIC REACTION RATES.
*----
CALL EVOSIG(IMPX,INR,IGLOB,NGROUP,NBMIX,NBISO,NCOMB,ISONAM,
1 IPISO,DEN,FLUMIX,VX,MILVO,JM,NVAR,NSUPS,NREAC,HREAC,IDR,
2 RER,RRD,FIT,AWR,IZAE,FUELDN,NXSPER,DELTAT(1,IP),MIXPWR,PFACT,
3 SIG(1,1,1,IP),VPHV(1,IP))
NLENGT=(NVAR+1)*(NREAC+1)*NBMIX
CALL LCMPUT(IPDEPL,'MICRO-RATES',NLENGT,2,SIG(1,1,1,IP))
CALL LCMPUT(IPDEPL,'INT-FLUX',NBMIX,2,VPHV(1,IP))
VPHD=0.0
DO 220 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.GT.0) VPHD=VPHD+VPHV(IBM,IP)
220 CONTINUE
VPH(IP)=VPHD
IF(INR.NE.0) THEN
FNORM=VPH(IP)/REAL(VPHINI)
IF(INR.EQ.3) CALL LCMPUT(IPDEPL,'FORM-POWER',1,2,PFACT)
ELSE
FNORM=0.0
ENDIF
CALL LCMPUT(IPDEPL,'FLUX-NORM',1,2,FNORM)
IF((INDREC.EQ.1).AND.(IP.EQ.1)) THEN
BRNWIR(1)=0.0
BRNWIR(2)=0.0
CALL LCMPUT(IPDEPL,'BURNUP-IRRAD',2,2,BRNWIR)
ENDIF
CALL LCMSIX(IPDEPL,' ',2)
ENDIF
*
IF(IDEPL.EQ.1) THEN
*----
* PERFORM A DEPLETION CALCULATION BETWEEN TIMES XT(1) AND XT(2).
*----
IF(IMPX.GT.0) WRITE(IUNOUT,600) XT(1),XT(2)
LCOOL=.TRUE.
DO 300 IP=1,2
ITIM=0
DO 230 I=1,NTIM
IF(ABS(TIMES(I)-XT(IP)).LE.1.0E-4*XT(IP)) ITIM=I
230 CONTINUE
IF(ITIM.GT.0) THEN
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,520) XT(IP),XT(IP)/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMGET(IPDEPL,'ISOTOPESDENS',DEN)
IF(IP.EQ.1) CALL LCMGET(IPDEPL,'BURNUP-IRRAD',BRNWIR)
CALL LCMLEN(IPDEPL,'MICRO-RATES',LENGT,ITYLCM)
IF((LENGT.GT.0).OR.(IP.EQ.1)) THEN
CALL LCMGET(IPDEPL,'MICRO-RATES',SIG(1,1,1,IP))
CALL LCMGET(IPDEPL,'INT-FLUX',VPHV(1,IP))
ENDIF
IF((IP.EQ.1).AND.(INR.EQ.3)) THEN
CALL LCMGET(IPDEPL,'FORM-POWER',PFACT)
ENDIF
CALL LCMSIX(IPDEPL,' ',2)
ELSE
IF(IP.EQ.1) CALL XABORT('EVODRV: NO DEPLETION DATA STORED.')
IF((IEXTR.GE.1).AND.(NTIM.GE.2).AND.(INR.NE.0)) THEN
* PERFORM MICRO REACTION RATE EXTRAPOLATION.
ITIM=0
DO 240 I=1,NTIM
IF(ABS(TIMES(I)-XT(1)).LE.1.0E-4*XT(1)) ITIM=I
240 CONTINUE
IF(ITIM.EQ.0) CALL XABORT('EVODRV: TABLE LOOKUP FAILURE.')
NLENGT=(NVAR+1)*(NREAC+1)*NBMIX
DO IEX=1,MIN(ITIM-IEXTR+1,IEXTR)
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM-IEX
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMLEN(IPDEPL,'MICRO-RATES',LENGT,ITYLCM)
IF(LENGT.NE.NLENGT) THEN
CALL XABORT('EVODRV: MICRO-RATES OVERFLOW.')
ENDIF
CALL LCMGET(IPDEPL,'MICRO-RATES',SIG(1,1,1,1-IEX))
CALL LCMGET(IPDEPL,'INT-FLUX',VPHV(1,1-IEX))
CALL LCMSIX(IPDEPL,' ',2)
ENDDO
N=0
IF((IEXTR.GE.2).AND.(ITIM.GE.3)) THEN
! parabolic extrapolation
N=3
T(1)=TIMES(ITIM-2)
T(2)=TIMES(ITIM-1)
T(3)=TIMES(ITIM)
IF(T(1).GE.T(3)) CALL XABORT ('EVODRV: T(1).GE.T(3).')
IF(IMPX.GT.0) WRITE(IUNOUT,'(/21H EVODRV: PARABOLIC EX,
1 51HTRAPOLAPOLATION OF MICRO REACTION RATES AT END-OF-S,
2 5HTAGE.)')
ELSE IF((IEXTR.GE.1).AND.(ITIM.GE.2)) THEN
! linear extrapolation
N=2
T(1)=TIMES(ITIM-1)
T(2)=TIMES(ITIM)
IF(T(1).GE.T(2)) CALL XABORT ('EVODRV: T(1).GE.T(2).')
IF(IMPX.GT.0) WRITE(IUNOUT,'(/23H EVODRV: LINEAR EXTRAPO,
1 51HLAPOLATION OF MICRO REACTION RATES AT END-OF-STAGE.)')
ELSE IF(ITIM.EQ.1) THEN
N=1
T(1)=TIMES(ITIM)
IF(IMPX.GT.0) WRITE(IUNOUT,'(/21H EVODRV: NO EXTRAPOLA,
1 49HPOLATION OF MICRO REACTION RATES AT END-OF-STAGE.)')
ENDIF
DPD=1.0D0 ! perform Lagrange extrapolation
DO I=1,N
DPD=(XT(2)-T(I))*DPD
ENDDO
VPHV(:NBMIX,2)=0.0
SIG(:NVAR+1,:NREAC+1,:NBMIX,2)=0.0
DO I=1,N
WEI=DPD/(XT(2)-T(I))
DO J=1,N
IF(J.EQ.I) CYCLE
IF(T(I).EQ.T(J)) CALL XABORT('EVODRV: DIVIDE CHECK.')
WEI=WEI/(T(I)-T(J))
ENDDO
DO IBM=1,NBMIX
VPHV(IBM,2)=VPHV(IBM,2)+REAL(WEI)*VPHV(IBM,I-N+1)
SIG(:NVAR+1,:NREAC+1,IBM,2)=SIG(:NVAR+1,:NREAC+1,IBM,2)+
1 REAL(WEI)*SIG(:NVAR+1,:NREAC+1,IBM,I-N+1)
ENDDO
ENDDO
ELSE
DO IBM=1,NBMIX
VPHV(IBM,2)=VPHV(IBM,1)
SIG(:NVAR+1,:NREAC+1,IBM,2)=SIG(:NVAR+1,:NREAC+1,IBM,1)
ENDDO
IF(IMPX.GT.0) WRITE(IUNOUT,'(/23H EVODRV: USE BEGINNING-,
1 46HOF-STAGE MICRO REACTION RATES AT END-OF-STAGE.)')
ENDIF
ENDIF
VPHD=0.0
DO 250 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.GT.0) VPHD=VPHD+VPHV(IBM,IP)
250 CONTINUE
VPH(IP)=VPHD
*
DO 270 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.EQ.0) GO TO 270
DO 260 IS=1,NVAR
IF(JM(IBM,IS).GT.0) THEN
YDPL(IS,IP,ICMB)=DEN(JM(IBM,IS))
ELSE
YDPL(IS,IP,ICMB)=0.0
ENDIF
260 CONTINUE
270 CONTINUE
*
IF(INR.NE.0) THEN
* CHECK FOR OUT-OF-CORE DEPLETION.
DO 290 IBM=1,NBMIX
DO 280 IU=1,NGROUP
LCOOL=LCOOL.AND.(FLUMIX(IU,IBM).EQ.0.)
280 CONTINUE
290 CONTINUE
ENDIF
300 CONTINUE
*
IF(LCOOL.AND.(FIT.NE.0.0)) CALL XABORT('EVODRV: NEUTRON FLUX I'
1 //'S ZERO. UNABLE TO NORMALIZE.')
IF(LCOOL.AND.(IMPX.GT.1)) THEN
WRITE (IUNOUT,'(/31H EVODRV: OUT-OF-CORE DEPLETION.)')
ELSE IF(IMPX.GT.1) THEN
WRITE (IUNOUT,'(/27H EVODRV: IN-CORE DEPLETION.)')
IF((FUELDN(3).GT.0.0).AND.(INR.EQ.3)) THEN
WRITE(IUNOUT,'(/31H EVODRV: FUEL POWER NORMALISATI,
1 10HON FACTOR=,1P,E12.5,29H MW/TONNE. OUT-OF-FUEL POWER ,
2 12HFORM FACTOR=,E12.5)') FIT/FUELDN(3)/PFACT,PFACT
ENDIF
ENDIF
INR2=INR
IF(LCOOL) INR2=0
*----
* PERFORM THE DEPLETION CALCULATION
*----
CALL EVOBLD(IMPX,INR2,IGLOB,NBMIX,NBISO,NCOMB,ISONAM,IPISO,
1 YDPL,VX,MILVO,JM,NVAR,NDFP,NSUPS,NREAC,NPAR,NFISS,XT,EPS1,EPS2,
2 EXPMAX,H1,ITYPE,IDIRAC,FIT,DELTA,ENERG,KPAR,BPAR,YIELD,IDR,RER,
3 RRD,AWR,FUELDN,SIG(1,1,1,1),VPH,VPHV(1,1),MIXPWR,VTOTD,IEVOLB,
4 KFISS,KPF)
*----
* SAVE THE INITIAL SATURATED NUMBER DENSITIES IN THE DEPLETION TABLE
*----
IF((ISAVE.GE.0).AND.(ISAT.EQ.1)) THEN
DO 315 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.EQ.0) GO TO 315
DO 310 IS=1,NVAR
IF(JM(IBM,IS).GT.0) DEN(JM(IBM,IS))=YDPL(IS,1,ICMB)
310 CONTINUE
315 CONTINUE
ITIM=0
DO 320 I=1,NTIM
IF(ABS(TIMES(I)-XT(1)).LE.1.0E-4*XT(1)) ITIM=I
320 CONTINUE
IF(ITIM.EQ.0) CALL XABORT('EVODRV: MISSING TIME ENTRY.')
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,530) XT(1),XT(1)/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMPUT(IPDEPL,'ISOTOPESDENS',NBISO,2,DEN)
CALL LCMSIX(IPDEPL,' ',2)
ENDIF
*----
* SAVE THE DEPLETION CALCULATION RESULT IN THE DEPLETION TABLE
*----
DO 335 ICMB=1,NCOMB
IBM=MILVO(ICMB)
IF(IBM.EQ.0) GO TO 335
DO 330 IS=1,NVAR
IF(JM(IBM,IS).GT.0) DEN(JM(IBM,IS))=YDPL(IS,2,ICMB)
330 CONTINUE
335 CONTINUE
ITIM=0
DO 340 I=1,NTIM
IF(ABS(TIMES(I)-XT(2)).LE.1.0E-4*XT(2)) ITIM=I
340 CONTINUE
IF(ITIM.EQ.0) THEN
IF(XT(2).LT.TIMES(NTIM)) CALL XABORT('EVODRV: INVALID X2')
NTIM=NTIM+1
TIMES(NTIM)=XT(2)
CALL LCMPUT(IPDEPL,'DEPL-TIMES',NTIM,2,TIMES)
ITIM=NTIM
ENDIF
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,530) XT(2),XT(2)/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMPUT(IPDEPL,'ISOTOPESDENS',NBISO,2,DEN)
NLENGT=(NVAR+1)*(NREAC+1)*NBMIX
CALL LCMPUT(IPDEPL,'MICRO-RATES',NLENGT,2,SIG(1,1,1,2))
CALL LCMPUT(IPDEPL,'INT-FLUX',NBMIX,2,VPHV(1,2))
CALL LCMPUT(IPDEPL,'ENERG-MIX',NBMIX,2,ENERG)
* We use DELTA(3) instead of DELTA(1) in order to avoid different
* base points in multi-D tables.
BRNWIR(1)=BRNWIR(1)+DELTA(3)/8.64E-4
BRNWIR(2)=BRNWIR(2)+DELTA(2)
CALL LCMPUT(IPDEPL,'BURNUP-IRRAD',2,2,BRNWIR)
IF(IMPX.GE.1) WRITE(IUNOUT,580) XT(2)/8.64E-4,
> BRNWIR(1),BRNWIR(2)
CALL LCMSIX(IPDEPL,' ',2)
ENDIF
*----
* RELEASE THE ALLOCATED MEMORY
*----
DEALLOCATE(IDR,HREAC,KPAR)
DEALLOCATE(RRD,RER,YIELD,BPAR)
DEALLOCATE(KPF,KFISS)
*----
* USE THE RESULT OF A DEPLETION CALCULATION IN THE FOLLOWING RUN
*----
IF(ISET.GE.0) THEN
ITIM=0
DO 350 I=1,NTIM
IF(ABS(TIMES(I)-XTF).LE.1.0E-4*XTF) ITIM=I
350 CONTINUE
IF(ITIM.EQ.0) CALL XABORT('EVODRV: NO DEPLETION DATA STORED.')
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,520) XTF,XTF/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMGET(IPDEPL,'ISOTOPESDENS',DEN)
CALL LCMGET(IPDEPL,'BURNUP-IRRAD',BRNWIR)
CALL LCMSIX(IPDEPL,' ',2)
IF(IMPX.GT.1) THEN
WRITE(IUNOUT,550) XTF,XTF/8.64E-4
DO 370 ICMB=1,NCOMB
IMIXC=MILVO(ICMB)
IF(IMIXC.EQ.0) GO TO 370
NISOCC=0
DO 360 ISOT=1,NBISO
IMIXI=MIX(ISOT)
IF(IMIXI.EQ.IMIXC) THEN
NISOCC=NISOCC+1
ISOCMB(NISOCC)=ISOT
ENDIF
360 CONTINUE
WRITE(IUNOUT,560) IMIXC
WRITE(IUNOUT,570) ((ISONAM(I0,ISOCMB(I)),I0=1,2),
1 DEN(ISOCMB(I)),I=1,NISOCC)
370 CONTINUE
ENDIF
ENDIF
*----
* RECOVER THE BURNUP AND SAVE IT IN A CLE-2000 VARIABLE
*----
IF(IPICK.EQ.1) THEN
ITIM=0
DO 375 I=1,NTIM
IF(ABS(TIMES(I)-XTF).LE.1.0E-4*XTF) ITIM=I
375 CONTINUE
IF(ITIM.EQ.0) CALL XABORT('EVODRV: NO DEPLETION DATA STORED.')
WRITE(TEXT12,'(8HDEPL-DAT,I4.4)') ITIM
IF(IMPX.GT.0) WRITE(IUNOUT,520) XTF,XTF/8.64E-4,TEXT12
CALL LCMSIX(IPDEPL,TEXT12,1)
CALL LCMGET(IPDEPL,'BURNUP-IRRAD',BRNWIR)
CALL LCMSIX(IPDEPL,' ',2)
CALL REDGET(ITYPLU,INTLIR,REALIR,TEXT12,DBLLIR)
IF(ITYPLU.NE.-2) CALL XABORT('EVODRV: OUTPUT REAL EXPECTED.')
ITYPLU=2
REALIR=BRNWIR(1)
IF(IMPX.GT.2) WRITE(IUNOUT,540) REALIR
CALL REDPUT(ITYPLU,INTLIR,REALIR,TEXT12,DBLLIR)
CALL REDGET(ITYPLU,INTLIR,REALIR,TEXT12,DBLLIR)
IF((ITYPLU.NE.3).OR.(TEXT12.NE.';')) THEN
CALL XABORT('EVODRV: ; CHARACTER EXPECTED.')
ENDIF
ENDIF
*
IF((IDEPL.EQ.1).OR.(ISET.EQ.1).AND.LMACRO) THEN
* COMPUTE THE NEW DEPLETED MACROSCOPIC CROSS SECTIONS.
MASKL(:NGROUP)=.TRUE.
MASK(:NBMIX)=.FALSE.
DO 380 ICOMB=1,NCOMB
IBM=MILVO(ICOMB)
IF(IBM.GT.0) MASK(IBM)=.TRUE.
380 CONTINUE
*
ITSTMP=2
TMPDAY(1)=XT(2)/8.64E-4
TMPDAY(2)=BRNWIR(1)
TMPDAY(3)=BRNWIR(2)
CALL LIBMIX(IPLIB,NBMIX,NGROUP,NBISO,ISONAM,MIX,DEN,MASK,MASKL,
1 ITSTMP,TMPDAY)
ENDIF
*----
* STORE THE GENERAL DEPLETION RELATED PARAMETERS
*----
CALL LCMPUT(IPDEPL,'VOLUME-MIX',NBMIX,2,VX)
CALL LCMPUT(IPDEPL,'DEPLETE-MIX',NVAR*NBMIX,1,JM)
CALL LCMPUT(IPDEPL,'MIXTURESBurn',NBMIX,1,MIXBRN)
CALL LCMPUT(IPDEPL,'MIXTURESPowr',NBMIX,1,MIXPWR)
IPAR(:NSTATE)=0
IPAR(1)=ITYPE
IPAR(2)=INR
IPAR(3)=NTIM
IPAR(4)=NBISO
IPAR(5)=NCOMB
IPAR(6)=NREAC
IPAR(7)=NVAR
IPAR(8)=NBMIX
IPAR(9)=IEXTR
IPAR(10)=IGLOB
IPAR(11)=ISAT
IPAR(12)=IDIRAC
IPAR(13)=ITIXS
IPAR(14)=IFLMAC
IPAR(15)=IYLMIX
CALL LCMPUT(IPDEPL,'STATE-VECTOR',NSTATE,1,IPAR)
RPAR(1)=EPS1
RPAR(2)=EPS2
RPAR(3)=EXPMAX
RPAR(4)=H1
RPAR(5)=FIT
CALL LCMPUT(IPDEPL,'EVOLUTION-R',5,2,RPAR)
IF((IMPX.GT.1).OR.((IMPX.GT.0).AND.(INDREC.EQ.1))) THEN
WRITE(IUNOUT,590) IMPX,ITYPE,INR,NTIM,NBISO,NCOMB,NREAC,
1 NVAR,NBMIX,IEXTR
WRITE(IUNOUT,595) IGLOB,ISAT,IDIRAC,ITIXS,IFLMAC,IYLMIX
ENDIF
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(TIMES)
DEALLOCATE(IPISO)
DEALLOCATE(MASKL,MASK)
DEALLOCATE(YDPL,IZAE,AWR,ENERG,VPHV,SIG)
DEALLOCATE(IEVOLB,INADPL,ISOCMB,MILVO,JM)
RETURN
*
500 FORMAT(/36H EVODRV: NUMBER OF FISSILE ISOTOPES=,I4/9X,8HNUMBER O,
1 19HF FISSION PRODUCTS=,I4)
510 FORMAT(/24H EVODRV: UNABLE TO FIND ,A15,6H INDEX,I5,6H AMONG,10I5
1 /(56X,10I5))
520 FORMAT(/44H EVODRV: RECOVER INFORMATION RELATED TO TIME,1P,E12.4,
1 8H E+8 S (,E12.4,32H DAY) FROM LCM DIRECTORY NAMED ',A12,2H'.)
530 FORMAT(/41H EVODRV: SAVE INFORMATION RELATED TO TIME,1P,E12.4,
1 8H E+8 S (,E12.4,30H DAY) ON LCM DIRECTORY NAMED ',A12,2H'.)
540 FORMAT(/21H EVODRV: PICK BURNUP=,1P,E12.4,10H MWd/tonne)
550 FORMAT(/' EVODRV: NUMBER DENSITIES PER ISOTOPE AT TIME',1P,
1 E12.4,' E+8 S (',E12.4,' DAY)')
560 FORMAT(/' ISOTOPIC DENSITIES AFTER BURNUP FOR MIXTURE = ',I5,
1 22H (10**24 PARTICLES/CC))
570 FORMAT(1P,5(4X,2A4,':',E12.4))
580 FORMAT(' -> FINAL BURNUP AT TIME = ',1P,E14.6,' DAYS'/
> ' FUEL BURNUP = ',E14.6,' MW*D/TONNE'/
> ' NEUTRON EXPOSURE = ',E14.6,' N/KB')
590 FORMAT(/8H OPTIONS/8H -------/
1 7H IMPX ,I8,30H (0=NO PRINT/1=SHORT/2=MORE)/
2 7H ITYPE ,I8,31H (1=CASH-KARP/2=KAPS-RENTROP)/
3 7H INR ,I8,47H (0=OUT-OF-CORE/1=CONSTANT FLUX/2=CONSTANT PO,
4 4HWER)/
5 7H NTIM ,I8,35H (NUMBER OF DEPLETION SET POINTS)/
6 7H NBISO ,I8,29H (TOTAL NUMBER OF ISOTOPES)/
7 7H NCOMB ,I8,33H (NUMBER OF DEPLETING MIXTURES)/
8 7H NREAC ,I8,34H (NUMBER OF DEPLETING REACTIONS)/
9 7H NVAR ,I8,33H (NUMBER OF DEPLETING ISOTOPES)/
1 7H NBMIX ,I8,23H (NUMBER OF MIXTURES)/
2 7H IEXTR ,I8,47H (FLUX EXTRAPOLATION: 0=NONE/1=LINEAR/2=PARAB,
3 5HOLIC))
595 FORMAT(
1 7H IGLOB ,I8,47H (-1=SERPENT EDEPMODE-0 FORMULA/0=COMPUTE BUR,
2 44HNUP IN FUEL/1=COMPUTE BURNUP IN GLOBAL CELL)/
3 7H ISAT ,I8,47H (0/1=DO NOT/DO SAVE SATURATED INITIAL NUMBER,
4 11H DENSITIES)/
5 7H IDIRAC,I8,47H (0/1=DO NOT/DO USE DIRAC FUNCTION CONTRIBUTI,
6 34HONS IN SATURATED NUMBER DENSITIES)/
7 7H ITIXS ,I8,38H (0/1=TIME-DEPENDENT XS FLAG ON/OFF)/
8 7H IFLMAC,I8,47H (0/1/2=RECOVER FLUX FROM L_FLUX/L_MACROLIB/L,
9 7H_POWER)/
1 7H IYLMIX,I8,47H (0/1=RECOVER FISSION YIELD DATA FROM DEPL-CH,
2 16HAIN/PYIELD DATA))
600 FORMAT(/54H EVODRV: SOLUTION OF A DEPLETION SYSTEM BETWEEN TIMES ,
1 1P,E12.4,4H AND,E12.4,6H E+8 S)
610 FORMAT(/' EVODRV: FUEL INITIAL DENSITY = ',1P,E14.6,' G/CC'/
> ' FUEL TOTAL VOLUME = ',E14.6,' CC'/
> ' FUEL INITIAL MASS = ',E14.6,' G'/
> ' FUEL INITIAL MASS/CELL VOL = ',E14.6,' G/CC')
END
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