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*DECK EDIHFC
SUBROUTINE EDIHFC(IPEDIT,NGROUP,NGCOND,NREGIO,NMERGE,NBISO,
> MATCOD,VOLUME,ISONAM,IPISO,MIX,FLUXES,DEN,
> IGCOND,IMERGE,VOLME,IPRINT,EMEVF2)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Recover H-factors and normalize the flux.
*
*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): G. Marleau
*
*Parameters: input
* IPEDIT pointer to the edition LCM object.
* NGROUP number of groups.
* NGCOND number of condensed groups.
* NREGIO number of regions.
* NMERGE number of merged regions.
* NBISO number of isotopes.
* MATCOD material per region.
* VOLUME volume of region.
* ISONAM isotopes names.
* IPISO pointer array towards microlib isotopes.
* MIX mixture associated with isotopes.
* FLUXES multigroup fluxes.
* DEN isotope density.
* IGCOND limits of condensed groups.
* IMERGE index of merged region.
* VOLME merged volume.
* IPRINT print level.
*
*Parameters: output
* EMEVF2 equivalent fission production energy by isotope.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPEDIT,IPISO(NBISO)
INTEGER IUNOUT
INTEGER NGROUP,NGCOND,NREGIO,NMERGE,NBISO,MATCOD(NREGIO),
> ISONAM(3,NBISO),MIX(NBISO),IGCOND(NGCOND),
> IMERGE(NREGIO)
REAL VOLUME(NREGIO),FLUXES(NREGIO,NGROUP),DEN(NBISO),
> EMEVF2(NBISO),VOLME(NMERGE)
INTEGER IPRINT
DOUBLE PRECISION TOTPOW,POWF
REAL, ALLOCATABLE, DIMENSION(:) :: SIG,HFACT
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:) :: FLXMER,WORK
*----
* LOCAL VARIABLES
*----
TYPE(C_PTR) JPEDIT,KPEDIT,KPLIB
PARAMETER (IUNOUT=6)
CHARACTER HSMG*131
LOGICAL LH
DOUBLE PRECISION GAR,CONV,XDRCST,Z1,Z2
*----
* SCRATCH STORAGE ALLOCATION
* SIG fission/capture cross sections.
* HFACT H-factor in a macrogroup.
* FLXMER merged and condensed flux.
* WORK H-factors.
*----
ALLOCATE(SIG(NGROUP),HFACT(NMERGE))
ALLOCATE(FLXMER(NMERGE,NGCOND),WORK(NMERGE,NGCOND))
*----
* COMPUTE H-FACTOR
*----
CONV=1.0D6 ! convert MeV to eV
FLXMER(:NMERGE,:NGCOND)=0.0D0
WORK(:NMERGE,:NGCOND)=0.0D0
LH=.FALSE.
DO 160 ISO=1,NBISO
KPLIB=IPISO(ISO) ! set ISO-th isotope
IF(.NOT.C_ASSOCIATED(KPLIB)) THEN
WRITE(HSMG,'(17HEDIHFC: ISOTOPE '',3A4,16H'' IS NOT AVAILAB,
> 19HLE IN THE MICROLIB.)') (ISONAM(I0,ISO),I0=1,3)
CALL XABORT(HSMG)
ENDIF
Z1=0.0D0
Z2=0.0D0
EMEVF2(ISO)=0.0
*----
* RECOVER H-FACTOR INFORMATION IF AVAILABLE
*----
CALL LCMLEN(KPLIB,'H-FACTOR',ILLCM,ITLCM)
IF(ILLCM.EQ.0) GO TO 160
LH=.TRUE.
CALL LCMGET(KPLIB,'H-FACTOR',SIG)
DO 90 IREG=1,NREGIO
IMR=IMERGE(IREG)
IF((IMR.GT.0).AND.(MATCOD(IREG).EQ.MIX(ISO))) THEN
IGRFIN=0
DO 80 IGC=1,NGCOND
IGRDEB=IGRFIN+1
IGRFIN=IGCOND(IGC)
GAR=0.0D0
DO 70 IGR=IGRDEB,IGRFIN
GAR=GAR+FLUXES(IREG,IGR)*DEN(ISO)*VOLUME(IREG)*SIG(IGR)
70 CONTINUE
WORK(IMR,IGC)=WORK(IMR,IGC)+GAR
Z1=Z1+GAR
80 CONTINUE
ENDIF
90 CONTINUE
*----
* COMPUTE FISSION ENERGY
*----
CALL LCMLEN(KPLIB,'NFTOT',ILLCM,ITLCM)
IF(ILLCM.EQ.NGROUP) THEN
CALL LCMGET(KPLIB,'NFTOT',SIG)
DO 120 IREG=1,NREGIO
IMR=IMERGE(IREG)
IF((IMR.GT.0).AND.(MATCOD(IREG).EQ.MIX(ISO))) THEN
IGRFIN=0
DO 110 IGC=1,NGCOND
IGRDEB=IGRFIN+1
IGRFIN=IGCOND(IGC)
DO 100 IGR=IGRDEB,IGRFIN
Z2=Z2+FLUXES(IREG,IGR)*DEN(ISO)*VOLUME(IREG)*SIG(IGR)
100 CONTINUE
110 CONTINUE
ENDIF
120 CONTINUE
IF(Z2.NE.0.0) EMEVF2(ISO)=REAL(Z1/Z2)
ENDIF
160 CONTINUE
*----
* Normalize total power to 1 W
* Print fission, capture and total power density
*----
TOTPOW=0.0D0
DO IGC=1,NGCOND
DO IMR=1,NMERGE
TOTPOW=TOTPOW+WORK(IMR,IGC)*XDRCST('eV','J')
ENDDO
ENDDO
IF(TOTPOW.GT.0.0D0) THEN
IF(ABS(IPRINT).GE.2) THEN
WRITE(IUNOUT,6000)
DO IMR=1,NMERGE
POWF=0.0D0
DO IGC=1,NGCOND
POWF=POWF+WORK(IMR,IGC)
ENDDO
IF(VOLME(IMR).NE.0.0) THEN
POWF=POWF/(TOTPOW*VOLME(IMR))
WRITE(IUNOUT,6001) IMR,VOLME(IMR),POWF
ENDIF
ENDDO
ENDIF
ENDIF
*----
* COMPUTE THE HOMOGENIZED/CONDENSED FLUX
*----
IF(LH) THEN
DO 190 IREG=1,NREGIO
IMR=IMERGE(IREG)
IF(IMR.GT.0) THEN
IGRFIN=0
DO 180 IGC=1,NGCOND
IGRDEB=IGRFIN+1
IGRFIN=IGCOND(IGC)
GAR=0.0D0
DO 170 IGR=IGRDEB,IGRFIN
GAR=GAR+FLUXES(IREG,IGR)*VOLUME(IREG)
170 CONTINUE
FLXMER(IMR,IGC)=FLXMER(IMR,IGC)+GAR
180 CONTINUE
ENDIF
190 CONTINUE
DO 210 IGC=1,NGCOND
DO 200 IMR=1,NMERGE
IF(FLXMER(IMR,IGC).GT.0.0) THEN
WORK(IMR,IGC)=WORK(IMR,IGC)/FLXMER(IMR,IGC)
ENDIF
200 CONTINUE
210 CONTINUE
*----
* SAVE ON LCM
*----
CALL LCMSIX(IPEDIT,'MACROLIB',1)
JPEDIT=LCMLID(IPEDIT,'GROUP',NGCOND)
DO 230 IGC=1,NGCOND
DO 220 IMR=1,NMERGE
HFACT(IMR)=REAL(WORK(IMR,IGC))
220 CONTINUE
KPEDIT=LCMDIL(JPEDIT,IGC)
CALL LCMPUT(KPEDIT,'H-FACTOR',NMERGE,2,HFACT)
230 CONTINUE
CALL LCMSIX(IPEDIT,' ',2)
ENDIF
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(WORK,FLXMER)
DEALLOCATE(HFACT,SIG)
RETURN
*----
* FORMAT
*----
6000 FORMAT(/' EDIHFC: POWER DENSITY (W/cc) NORMALIZED TO 1 W TOTAL ',
> 'POWER '/' REGION',6X,'VOLUME',7X,'FISSION')
6001 FORMAT(1X,I4,1P,2E14.5)
END
|
