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*DECK EDIBAL
SUBROUTINE EDIBAL(IPEDIT,IPFLUX,IPRINT,NL,IFFAC,NGCOND,NMERGE,
> EIGENK,RATECM,FLUXCM,SCATTS,ILEAKS,B2,NW,
> NTAUXT)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Four factor calculation.
*
*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.
* IPFLUX pointer to the flux LCM object.
* IPRINT print level:
* =1 neutron balance or four factor;
* =2 material analysis (if available).
* NL number of Legendre orders.
* IFFAC number of neutrons for neutron balance.
* NGCOND number of condensed groups.
* NMERGE number of merge regions.
* EIGENK problem eigenvalue.
* RATECM averaged region/group cross sections:
* = RATECM(*,1) = total P0;
* = RATECM(*,2) = total P1;
* = RATECM(*,NW+2) = absorption;
* = RATECM(*,NW+3) = fission;
* = RATECM(*,NW+4) = fixed sources / productions;
* = RATECM(*,NW+5) = leakage;
* = RATECM(*,NW+6) = total out of group scattering;
* = RATECM(*,NW+7) = diagonal scattering x-s;
* = RATECM(*,NW+8) = chi;
* = RATECM(*,NW+9) = wims type transport correction;
* = RATECM(*,NW+10) = x-directed leakage;
* = RATECM(*,NW+11) = y-directed leakage;
* = RATECM(*,NW+12) = z-directed leakage.
* FLUXCM integrated region/group fluxes:
* = FLUXCM(*,1) = fluxes P0;
* = FLUXCM(*,2) = fluxes P1.
* SCATTS scattering matrix.
* ILEAKS leakage calculation flag:
* = 0 no leakage;
* = 1 homogeneous leakage (Diffon);
* = 2 isotropic streaming (Ecco);
* = 3 anisotropic streaming (Tibere).
* B2 square buckling:
* for ILEAKS=1,2: B2(4) is homogeneous;
* for ILEAKS=3: B2(1),B2(2),B2(3) are directional heterogeneous
* and B2(4) is homogeneous.
* NW type of weighting for PN cross section info (=0 P0; =1 P1).
* NTAUXT number of reaction rate edits (=12+NW+2*NDEL).
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPEDIT,IPFLUX
INTEGER IPRINT,NL,IFFAC,NGCOND,NMERGE,ILEAKS,NW,NTAUXT
REAL EIGENK,RATECM(NMERGE,NGCOND,NTAUXT),
> FLUXCM(NMERGE,NGCOND,NW+1),
> SCATTS(NMERGE,NGCOND,NGCOND,NL),B2(4)
*----
* LOCAL VARIABLES
*----
SAVE CNAMAT
PARAMETER (IUNOUT=6,INAMAT=2)
CHARACTER CNAMAT(INAMAT)*15
REAL XN(8)
DOUBLE PRECISION DACCK,BUCKL2,XNF(3),XKINF,XN1,XN2,XN3,XN4,XN5,
> XN6,XKEFF,XA,XLAMF,XLAMTH,XNORMF,XAUX
INTEGER, ALLOCATABLE, DIMENSION(:) :: ITYPER
REAL, ALLOCATABLE, DIMENSION(:,:) :: FLXINT
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:) :: DLEAK
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:,:) :: DRATE
DATA (CNAMAT(JJ),JJ=1,INAMAT)
> /' FUEL ','NON-FUEL '/
*----
* SCRATCH STORAGE ALLOCATION
* ITYPER region type.
* FLXINT integrated flux.
* DRATE group reaction rates:
* DRATE(1,*,*) for fuel;
* DRATE(2,*,*) for non-fuel;
* DRATE(*,1,*) production;
* DRATE(*,2,*) absorption;
* DRATE(*,*,ngcond+1) group total.
* DLEAK group leak rates:
* DLEAK(1,*) leakage;
* DLEAK(2,*) leakage + absorption;
* DLEAK(*,ngcond+1) group total.
*----
ALLOCATE(ITYPER(NMERGE))
ALLOCATE(FLXINT(NMERGE,NGCOND))
ALLOCATE(DRATE(2,2,NGCOND+1),DLEAK(2,NGCOND+1))
*----
* LOCALIZE FUEL AND NON-FUEL REGION
*----
NGC1=NGCOND+1
DO 100 IGR=1,NGC1
DO 110 IRAT=1,2
DRATE(1,IRAT,IGR)=0.0D0
DRATE(2,IRAT,IGR)=0.0D0
110 CONTINUE
DLEAK(1,IGR)=0.0D0
DLEAK(2,IGR)=0.0D0
100 CONTINUE
DO 120 IREG=1,NMERGE
ITYPER(IREG)=2
120 CONTINUE
DO 130 IGR=1,NGCOND
DO 140 IREG=1,NMERGE
IF(RATECM(IREG,IGR,NW+3).GT.0.0) ITYPER(IREG)=1
140 CONTINUE
130 CONTINUE
*----
* GET BUCKL2
*----
CALL LCMLEN(IPFLUX,'B2 B1HOM',ILCMLN,ILCMTY)
IF(ILCMLN.EQ.1) THEN
CALL LCMGET(IPFLUX,'B2 B1HOM',BL2)
BUCKL2=DBLE(BL2)
ELSE
BUCKL2=0.0D0
ENDIF
IF(EIGENK.EQ.0.0) THEN
WRITE(IUNOUT,7000)
FLXRGE=1.0
FLXREN=1.0
DACCK=1.0D0
WRITE(IUNOUT,6000)
ELSE
FLXRGE=REAL(IFFAC)
FLXREN=REAL(IFFAC)*EIGENK
DACCK=DBLE(EIGENK)
IF(NGCOND.NE.3) THEN
WRITE(IUNOUT,7001) NGCOND
WRITE(IUNOUT,6001)
ELSE
WRITE(IUNOUT,6002)
ENDIF
ENDIF
IF(IPRINT.EQ.1) THEN
WRITE(IUNOUT,6100)
WRITE(IUNOUT,6101)(IREG,CNAMAT(ITYPER(IREG)),IREG=1,NMERGE)
ENDIF
*----
* FIND INTEGRATED FLUX DIVIDED BY SPH FACTOR
*----
DO 150 IGR=1,NGCOND
DO 160 IREG=1,NMERGE
FLXINT(IREG,IGR)=FLUXCM(IREG,IGR,1)
160 CONTINUE
150 CONTINUE
IF(IPRINT.GE.1) THEN
WRITE(IUNOUT,6200)
ENDIF
DO 170 IGR=1,NGCOND
*----
* REACTION RATES PER GROUP AND MATERIAL TYPE
*----
IF(IPRINT.GE.1) THEN
WRITE(IUNOUT,6201) IGR,NGCOND
ENDIF
DO 180 IREG=1,NMERGE
*----
* ADD PRODUCTION AND ABSORPTION IN MATERIAL TYPE
*----
IF(ITYPER(IREG).EQ.1) THEN
DRATE(1,1,IGR)=DRATE(1,1,IGR)+DBLE(RATECM(IREG,IGR,NW+4))
> *DBLE(FLXINT(IREG,IGR))
DRATE(1,2,IGR)=DRATE(1,2,IGR)+DBLE(RATECM(IREG,IGR,NW+2))
> *DBLE(FLXINT(IREG,IGR))
ELSE
DRATE(2,1,IGR)=DRATE(2,1,IGR)+DBLE(RATECM(IREG,IGR,NW+4))
> *DBLE(FLXINT(IREG,IGR))
DRATE(2,2,IGR)=DRATE(2,2,IGR)+DBLE(RATECM(IREG,IGR,NW+2))
> *DBLE(FLXINT(IREG,IGR))
ENDIF
*----
* PRINT PRODUCTION AND ABSORPTION PER REGION
*----
IF(IPRINT.GE.2) THEN
IF(IFFAC.EQ.1000) THEN
WRITE(IUNOUT,6300) IREG,CNAMAT(ITYPER(IREG)),
> FLXRGE*RATECM(IREG,IGR,NW+4)*FLXINT(IREG,IGR),
> FLXREN*RATECM(IREG,IGR,NW+2)*FLXINT(IREG,IGR)
ELSE
WRITE(IUNOUT,6301) IREG,CNAMAT(ITYPER(IREG)),
> FLXRGE*RATECM(IREG,IGR,NW+4)*FLXINT(IREG,IGR),
> FLXREN*RATECM(IREG,IGR,NW+2)*FLXINT(IREG,IGR)
ENDIF
ENDIF
*----
* ADD GROUP LEAKAGE
*----
IF((ILEAKS.EQ.1).OR.(ILEAKS.EQ.2)) THEN
DLEAK(1,IGR)=DLEAK(1,IGR)+DBLE(RATECM(IREG,IGR,NW+5))
> *B2(4)*DBLE(FLXINT(IREG,IGR))
ELSE IF(ILEAKS.EQ.3) THEN
DLEAK(1,IGR)=DLEAK(1,IGR)+DBLE(FLXINT(IREG,IGR))
> *(DBLE(RATECM(IREG,IGR,NW+10))*B2(1)
> +DBLE(RATECM(IREG,IGR,NW+11))*B2(2)
> +DBLE(RATECM(IREG,IGR,NW+12))*B2(3))
ELSE
DO 190 JGR=1,NGCOND
IF(JGR.NE.IGR)
> DLEAK(2,IGR)=DLEAK(2,IGR)+DBLE(SCATTS(IREG,IGR,JGR,1))
> *DBLE(FLXINT(IREG,JGR))
190 CONTINUE
DLEAK(2,IGR)=DLEAK(2,IGR)+DBLE(FLXINT(IREG,IGR))*
> ( DBLE(RATECM(IREG,IGR,NW+4))/DACCK
> -DBLE(RATECM(IREG,IGR,1))
> +DBLE(RATECM(IREG,IGR,NW+2))
> +DBLE(SCATTS(IREG,IGR,IGR,1)) )
ENDIF
180 CONTINUE
IF((ILEAKS.EQ.1).OR.(ILEAKS.EQ.2)) THEN
DLEAK(2,IGR)=DLEAK(1,IGR)+DRATE(1,2,IGR)+DRATE(2,2,IGR)
ELSE
DLEAK(1,IGR)=DLEAK(2,IGR)-DRATE(1,2,IGR)-DRATE(2,2,IGR)
ENDIF
*----
* PRINT PRODUCTION AND ABSORPTION PER MATERIAL TYPE AND TOTAL
* PRODUCTION, ABSORPTION, LEAKAGE AND LEAKAGE+ABSORPTION
*----
IF(IPRINT.GE.1) THEN
IF(IFFAC.EQ.1000) THEN
WRITE(IUNOUT,6302) 'TOTAL FUEL ',
> FLXRGE*DRATE(1,1,IGR),
> FLXREN*DRATE(1,2,IGR)
WRITE(IUNOUT,6302) 'TOTAL NON-FUEL ',
> FLXRGE*DRATE(2,1,IGR),
> FLXREN*DRATE(2,2,IGR)
WRITE(IUNOUT,6302) 'FUEL + NON-FUEL',
> FLXRGE*(DRATE(1,1,IGR)+DRATE(2,1,IGR)),
> FLXREN*(DRATE(1,2,IGR)+DRATE(2,2,IGR)),
> FLXREN*DLEAK(1,IGR),FLXREN*DLEAK(2,IGR)
ELSE
WRITE(IUNOUT,6303) 'TOTAL FUEL ',
> FLXRGE*DRATE(1,1,IGR),
> FLXREN*DRATE(1,2,IGR)
WRITE(IUNOUT,6303) 'TOTAL NON-FUEL ',
> FLXRGE*DRATE(2,1,IGR),
> FLXREN*DRATE(2,2,IGR)
WRITE(IUNOUT,6303) 'FUEL + NON-FUEL',
> FLXRGE*(DRATE(1,1,IGR)+DRATE(2,1,IGR)),
> FLXREN*(DRATE(1,2,IGR)+DRATE(2,2,IGR)),
> FLXREN*DLEAK(1,IGR),FLXREN*DLEAK(2,IGR)
ENDIF
ENDIF
*----
* GROUP SUM
*----
DRATE(1,1,NGC1)=DRATE(1,1,NGC1)+DRATE(1,1,IGR)
DRATE(2,1,NGC1)=DRATE(2,1,NGC1)+DRATE(2,1,IGR)
DRATE(1,2,NGC1)=DRATE(1,2,NGC1)+DRATE(1,2,IGR)
DRATE(2,2,NGC1)=DRATE(2,2,NGC1)+DRATE(2,2,IGR)
DLEAK(1,NGC1)=DLEAK(1,NGC1)+DLEAK(1,IGR)
DLEAK(2,NGC1)=DLEAK(2,NGC1)+DLEAK(2,IGR)
170 CONTINUE
IF(NGCOND.GT.1) THEN
WRITE(IUNOUT,6202)
IF(IFFAC.EQ.1000) THEN
WRITE(IUNOUT,6302) 'TOTAL FUEL ',
> FLXRGE*DRATE(1,1,NGC1),
> FLXREN*DRATE(1,2,NGC1)
WRITE(IUNOUT,6302) 'TOTAL NON-FUEL ',
> FLXRGE*DRATE(2,1,NGC1),
> FLXREN*DRATE(2,2,NGC1)
WRITE(IUNOUT,6302) 'FUEL + NON-FUEL',
> FLXRGE*(DRATE(1,1,NGC1)+DRATE(2,1,NGC1)),
> FLXREN*(DRATE(1,2,NGC1)+DRATE(2,2,NGC1)),
> FLXREN*DLEAK(1,NGC1),FLXREN*DLEAK(2,NGC1)
ELSE
WRITE(IUNOUT,6303) 'TOTAL FUEL ',
> FLXRGE*DRATE(1,1,NGC1),
> FLXREN*DRATE(1,2,NGC1)
WRITE(IUNOUT,6303) 'TOTAL NON-FUEL ',
> FLXRGE*DRATE(2,1,NGC1),
> FLXREN*DRATE(2,2,NGC1)
WRITE(IUNOUT,6303) 'FUEL + NON-FUEL',
> FLXRGE*(DRATE(1,1,NGC1)+DRATE(2,1,NGC1)),
> FLXREN*(DRATE(1,2,NGC1)+DRATE(2,2,NGC1)),
> FLXREN*DLEAK(1,NGC1),FLXREN*DLEAK(2,NGC1)
ENDIF
ENDIF
IF( (EIGENK.GT.0.0) .AND. (NGCOND.EQ.3) ) THEN
*----
* FOUR FACTOR CALCULATION
*----
XNF(1)=0.0D0
XNF(2)=0.0D0
XNF(3)=0.0D0
DO 200 IREG=1,NMERGE
*----
* ADD NUSIGF AND TOTAL RATES IN FUEL
*----
IF(ITYPER(IREG).EQ.1) THEN
XNF(3)=XNF(3)+DBLE(RATECM(IREG,3,NW+3))*DBLE(FLXINT(IREG,3))
XNF(2)=XNF(2)+DBLE(RATECM(IREG,2,NW+3))*DBLE(FLXINT(IREG,2))
XNF(1)=XNF(1)+DBLE(RATECM(IREG,1,NW+3))*DBLE(FLXINT(IREG,1))
ENDIF
200 CONTINUE
XKINF=DRATE(1,1,4)/(DRATE(1,2,4)+DRATE(2,2,4))
XKEFF=DRATE(1,1,4)/DLEAK(2,4)
XN1=(DRATE(1,1,4)/XKEFF)-DLEAK(1,4)
XN2=XN1-(DRATE(1,2,1)+DRATE(2,2,1))
XN3=XN2-(DRATE(1,2,2)+DRATE(2,2,2))
XN4=XN3-DRATE(2,2,3)
XN5=XNF(2)+XNF(3)
XN6=XN5+XNF(1)
*----
* COMPUTATION OF EPSILON, F, ETA, P, LAMBDAF, LAMBDATH, KINF, KEFF
*----
XN(1)=REAL((XN6-DRATE(1,2,1)-DRATE(2,2,1))/XN5)
XN(5)=REAL(XN4/XN3)
XN(6)=REAL(XN5/XN4)
XN(3)=REAL(XKINF)/(XN(1)*XN(5)*XN(6))
XA=DRATE(1,2,4)+DRATE(2,2,4)
XLAMF=1/(1+((DLEAK(1,1)+DLEAK(1,2))/XA))
XLAMTH=1/(1+(DLEAK(1,3)/XA))
XAUX=XLAMF*XLAMTH
XNORMF=XKEFF/(XKINF*XAUX)
XN(2)=REAL(XLAMF*SQRT(XNORMF))
XN(4)=REAL(XLAMTH*SQRT(XNORMF))
XN(7)=XN(1)*XN(3)*XN(5)*XN(6)
XN(8)=XN(7)*XN(2)*XN(4)
IF(IPRINT.GE.1) THEN
WRITE(IUNOUT,6400) (XN(JJ),JJ=1,8)
ENDIF
CALL LCMPUT(IPEDIT,'FOUR-FACTOR ',8,2,XN)
ENDIF
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(DLEAK,DRATE)
DEALLOCATE(FLXINT)
DEALLOCATE(ITYPER)
RETURN
*----
* PRINT FORMATS
*----
6000 FORMAT(/20X,'F I X E D S O U R C E',
>' N E U T R O N B A L A N C E')
6001 FORMAT(/20X,'S I M P L E N E U T R O N B A L A N C E')
6002 FORMAT(/20X,'F O U R F A C T O R C A L C U L A T I O N')
6100 FORMAT(4(4X,'REGION',5X,'MATERIAL TYPE '))
6101 FORMAT(4(5X,I5,5X,A15))
6200 FORMAT(15X,' REGION',3X,'MATERIAL TYPE ',3X,'NEUTRON PRODUCTION',
> 3X,'NEUTRON ABSORPTION',3X,'NEUTRON LEAKAGE ',
> 3X,'ABSORPTION+LEAKAGE')
6201 FORMAT(' GROUP :',I3,'/',I3)
6202 FORMAT(' SUM OVER GROUPS')
6300 FORMAT(17X,I5,3X,A15,3X,F12.1,8X,F12.1)
6301 FORMAT(17X,I5,3X,A15,3X,1P,E15.7,5X,E15.7)
6302 FORMAT(25X,A15,3X,F12.1,8X,F12.1,8X,F12.1,8X,F12.1)
6303 FORMAT(25X,A15,3X,1P,E15.7,5X,E15.7,5X,E15.7,5X,E15.7)
6400 FORMAT(/' FOUR FACTORS'/1P,
> ' EPSILON (FAST FISSION FACTOR) =',E15.7/
> ' LAMBDAF (FAST NON-LEAKAGE) =',E15.7/
> ' P (ANTITRAP FACTOR) =',E15.7/
> ' LAMBDAT (THERMAL NON-LEAKAGE) =',E15.7/
> ' F (THERMAL UTILIZATION FACTOR) =',E15.7/
> ' ETA (THERMAL REPRODUCTION) =',E15.7/
> ' INFINITE MULTIPLICATION (4F) =',E15.7/
> ' EFFECTIVE MULTIPLICATION =',E15.7)
*----
* WARNING FORMATS
*----
7000 FORMAT(' * * * W A R N I N G * * * ',/
> ' NO FOUR FACTOR CALCULATION PERMITTED FOR FIXED SOURCE',
> ' PROBLEM',/' A SIMPLE GROUP BY GROUP NEUTRON',
> ' BALANCE PERFORMED HERE')
7001 FORMAT(' * * * W A R N I N G * * * ',/
> ' FOUR FACTOR CALCULATION REQUIRES 3 GROUPS, NUMBER OF',
> ' GROUPS HERE IS =',I10/' A SIMPLE GROUP BY GROUP NEUTRON',
> ' BALANCE PERFORMED HERE')
END
|
