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*DECK FLPRNT
SUBROUTINE FLPRNT(IPMAP,NCH,NB,NX,NY,NZ,POWB,PBNM,ICHM,IBNM,POWC,
1 PCHM,IPCH,BAVG,BFACT,CAVG,CFACT,IMPX)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Print the bundle and channel powers over the fuel lattice.
*
*Copyright:
* Copyright (C) 2007 Ecole Polytechnique de Montreal.
*
*Author(s):
* D. Sekki
*
*Parameters: input/output
* IPMAP pointer to fuel-map information.
* NCH number of reactor channels.
* NB number of fuel bundles per channel.
* NX number of elements along x-axis.
* NY number of elements along y-axis.
* NZ number of elements along z-axis.
* POWB bundle powers in kW.
* PBNM maximum bundle power.
* ICHM maximum-power channel number.
* IBNM maximum-power bundle number.
* POWC channel powers in kW.
* PCHM maximum channel power.
* IPCH maximum-power channel number.
* BAVG average bundle power.
* BFACT bundle power-form factor.
* CAVG average channel power.
* CFACT channel power-form factor.
* IMPX printing index: 0 = no print
* 1 = minimal printing
* 2 = channel power only
* 3 = bundle power by plane only
* 10 = bundle power by channel
* any added values of 2, 3 and 10: 5,12,13,15
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPMAP
INTEGER NCH,NB,NX,NY,NZ,ICHM,IBNM,IPCH,IMPX
REAL POWB(NCH,NB),POWC(NCH),PBNM,PCHM
DOUBLE PRECISION BAVG,CAVG,BFACT
*----
* LOCAL VARIABLES
*----
PARAMETER(IOUT=6)
REAL RADB(NX,NY,NB),RADC(NX,NY)
INTEGER MIX(NX*NY,NZ),NAMX(NX),NAMY(NY)
CHARACTER TEXT*12,CHANX*2,CHANY*2,TEXT1A*17,TEXT2A*17,TEXT3A*17,
1 TEXT1B*17,TEXT2B*17,TEXT3B*17
*
MIX(:NX*NY,NZ)=0
NAMX(:NX)=0
NAMY(:NY)=0
CALL LCMGET(IPMAP,'BMIX',MIX)
* CHANNEL NAMES
CALL LCMGET(IPMAP,'XNAME',NAMX)
CALL LCMGET(IPMAP,'YNAME',NAMY)
*----
* BUNDLE POWERS OVER EACH CHANNEL
*----
IF(IMPX.GE.10) WRITE(IOUT,1009)
IEL=0
ICH=0
JCM=0
ICM=0
JBM=0
IBM=0
DO 11 J=1,NY
DO 10 I=1,NX
IEL=IEL+1
DO 5 K=1,NZ
IF(MIX(IEL,K).NE.0)GOTO 6
5 CONTINUE
GO TO 10
6 ICH=ICH+1
IF(ICH.EQ.IPCH)THEN
JCM=J
ICM=I
ENDIF
IF(ICH.EQ.ICHM)THEN
JBM=J
IBM=I
ENDIF
IF(IMPX.GE.10) THEN
WRITE(TEXT,'(A9,I3.3)')'CHANNEL #',ICH
WRITE(CHANX,'(A2)') (NAMX(I))
WRITE(CHANY,'(A2)') (NAMY(J))
WRITE(IOUT,1000)TEXT,CHANY,CHANX,POWC(ICH)
IF(PBNM.LT.1.)THEN
WRITE(IOUT,'(1X,1P,12E11.4)')(POWB(ICH,IB),IB=1,NB)
ELSE IF(PBNM.LT.1000.)THEN
WRITE(IOUT,'(1X,12F11.3)')(POWB(ICH,IB),IB=1,NB)
ELSE
WRITE(IOUT,'(1X,12F11.1)')(POWB(ICH,IB),IB=1,NB)
ENDIF
ENDIF
10 CONTINUE
11 CONTINUE
*
WRITE(TEXT1A,'(A6,I2,A8)') '(A4,',(NX/2),'(A9,2X))'
WRITE(TEXT2A,'(A4,I2,A6)') '(A3,',(NX/2),'F11.3)'
WRITE(TEXT3A,'(A8,I2,A6)') '(A3,1P,',(NX/2),'E11.3)'
WRITE(TEXT1B,'(A4,I2,A8)') '(A4,',NX-(NX/2),'(A9,2X))'
WRITE(TEXT2B,'(A4,I2,A6)') '(A3,',NX-(NX/2),'F11.3)'
WRITE(TEXT3B,'(A8,I2,A6)') '(A3,1P,',NX-(NX/2),'E11.3)'
IF((IMPX.LT.3).OR.((IMPX.GE.10).AND.(IMPX.LT.13)))GOTO 50
*----
* BUNDLE POWERS PER RADIAL PLANE
*----
RADB(:NX,:NY,:NB)=0.0
WRITE(IOUT,1010)
DO IB=1,NB
IEL=0
ICH=0
DO 25 J=1,NY
DO 20 I=1,NX
IEL=IEL+1
DO 15 K=1,NZ
IF(MIX(IEL,K).NE.0)GOTO 16
15 CONTINUE
GO TO 20
16 ICH=ICH+1
RADB(I,J,IB)=POWB(ICH,IB)
20 CONTINUE
25 CONTINUE
ENDDO
DO IB=1,NB
WRITE(IOUT,1011)IB
WRITE(IOUT,TEXT1A)' ',(NAMX(I),I=1,(NX/2))
WRITE(IOUT,*)' '
DO 30 J=1,NY
WRITE(CHANY,'(A2)') (NAMY(J))
IF(INDEX(CHANY,'-').EQ.1)GOTO 30
IF(PBNM.GE.1.)THEN
WRITE(IOUT,TEXT2A)CHANY,(RADB(I,J,IB),I=1,(NX/2))
ELSE
WRITE(IOUT,TEXT3A)CHANY,(RADB(I,J,IB),I=1,(NX/2))
ENDIF
30 CONTINUE
WRITE(IOUT,*)' '
WRITE(IOUT,TEXT1B)' ',(NAMX(I),I=(NX/2+1),NX)
WRITE(IOUT,*)' '
DO 40 J=1,NY
WRITE(CHANY,'(A2)') (NAMY(J))
IF(INDEX(CHANY,'-').EQ.1)GOTO 40
IF(PBNM.GE.1.)THEN
WRITE(IOUT,TEXT2B)CHANY,(RADB(I,J,IB),I=(NX/2+1),NX)
ELSE
WRITE(IOUT,TEXT3B)CHANY,(RADB(I,J,IB),I=(NX/2+1),NX)
ENDIF
40 CONTINUE
ENDDO
50 IF((IMPX.EQ.0).OR.(IMPX.EQ.1).OR.(IMPX.EQ.3).OR.(IMPX.EQ.4)
1 .OR.(IMPX.EQ.10).OR.(IMPX.EQ.11).OR.(IMPX.EQ.13).OR.(IMPX.EQ.14))
2 GOTO 90
*----
* CHANNEL POWERS IN RADIAL PLANE
*----
RADC(:NX,:NY)=0.0
WRITE(IOUT,1013)
IEL=0
ICH=0
DO 65 J=1,NY
DO 60 I=1,NX
IEL=IEL+1
DO 55 K=1,NZ
IF(MIX(IEL,K).NE.0)GOTO 56
55 CONTINUE
GO TO 60
56 ICH=ICH+1
RADC(I,J)=POWC(ICH)
60 CONTINUE
65 CONTINUE
WRITE(IOUT,TEXT1A)' ',(NAMX(I),I=1,(NX/2))
WRITE(IOUT,*)' '
DO 70 J=1,NY
WRITE(CHANY,'(A2)') (NAMY(J))
IF(INDEX(CHANY,'-').EQ.1)GOTO 70
IF(PBNM.GE.1.)THEN
WRITE(IOUT,TEXT2A)CHANY,(RADC(I,J),I=1,(NX/2))
ELSE
WRITE(IOUT,TEXT3A)CHANY,(RADC(I,J),I=1,(NX/2))
ENDIF
70 CONTINUE
WRITE(IOUT,*)' '
WRITE(IOUT,TEXT1B)' ',(NAMX(I),I=(NX/2+1),NX)
WRITE(IOUT,*)' '
DO 80 J=1,NY
WRITE(CHANY,'(A2)') (NAMY(J))
IF(INDEX(CHANY,'-').EQ.1)GOTO 80
IF(PBNM.GE.1.)THEN
WRITE(IOUT,TEXT2B)CHANY,(RADC(I,J),I=(NX/2+1),NX)
ELSE
WRITE(IOUT,TEXT3B)CHANY,(RADC(I,J),I=(NX/2+1),NX)
ENDIF
80 CONTINUE
*----
* FINAL INFORMATION
*----
90 IF((IBM.EQ.0).OR.(JBM.EQ.0)) CALL XABORT('FLPRNT: INVALID POWERS')
WRITE(IOUT,1002)
WRITE(CHANX,'(A2)') (NAMX(IBM))
WRITE(CHANY,'(A2)') (NAMY(JBM))
IF(PBNM.LT.1000.)THEN
WRITE(IOUT,1003)PBNM,CHANY,CHANX,IBNM
ELSE
WRITE(IOUT,1016)PBNM,CHANY,CHANX,IBNM
ENDIF
IF(BAVG.LT.1000.)THEN
WRITE(IOUT,1005)BAVG
ELSE
WRITE(IOUT,1017)BAVG
ENDIF
FACT=1./REAL(BFACT)
IF((ICM.EQ.0).OR.(JCM.EQ.0)) CALL XABORT('FLPRNT: INVALID POWERS')
WRITE(IOUT,1006)BFACT,FACT
WRITE(CHANX,'(A2)') (NAMX(ICM))
WRITE(CHANY,'(A2)') (NAMY(JCM))
IF(PCHM.LT.10000.)THEN
WRITE(IOUT,1004)PCHM,CHANY,CHANX
ELSE
WRITE(IOUT,1018)PCHM,CHANY,CHANX
ENDIF
IF(CAVG.LT.10000.)THEN
WRITE(IOUT,1007)CAVG
ELSE
WRITE(IOUT,1019)CAVG
ENDIF
FACT=1./CFACT
WRITE(IOUT,1008)CFACT,FACT
RETURN
*
1000 FORMAT(/5X,A12,5X,'NAME:',1X,A2,A2,5X,'CHANNEL POWER =',1X,1P,
1 E11.4,'kW')
1002 FORMAT(/5X,5('--o--',6X)/)
1003 FORMAT(/1X,'MAXIMUM BUNDLE POWER =',1X,F9.1,1X,'kW',
1 3X,'=>',3X,'CHANNEL:',1X,A2,A2,3X,'BUNDLE #',I2.2)
1004 FORMAT(/1X,'MAXIMUM CHANNEL POWER =',1X,F9.1,1X,'kW',
1 3X,'=>',3X,'CHANNEL:',1X,A2,A2)
1005 FORMAT(1X,'AVERAGE POWER OVER ALL BUNDLES',
1 1X,'=',1X,F9.1,1X,'kW')
1006 FORMAT(1X,'BUNDLE-POWER FORM FACTOR',2X,'=>',2X,
1 'AVG/MAX =',1X,F8.4,3X,'(MAX/AVG = ',F8.4,')')
1007 FORMAT(1X,'AVERAGE POWER OVER ALL CHANNELS',
1 1X,'=',1X,F9.1,1X,'kW')
1008 FORMAT(1X,'CHANNEL-POWER FORM FACTOR',2X,'=>',2X,
1 'AVG/MAX =',1X,F8.4,2X,'(MAX/AVG = ',F8.4,')'/)
1009 FORMAT(/20X,'** BUNDLE POWERS OVER EACH',
1 1X,'CHANNEL (kW) **'/)
1010 FORMAT(//20X,'** BUNDLE POWERS PER RADIAL',
1 1X,'PLANE **'/)
1011 FORMAT(//1X,'BUNDLE POWERS',1X,'(kW)',1X,
1 '=>',1X,'RADIAL PLANE',1X,'#',I2.2/)
1013 FORMAT(//20X,'** CHANNEL POWERS IN RADIAL',1X,'PLANE (kW) **'/)
1016 FORMAT(/1X,'MAXIMUM BUNDLE POWER =',1X,F9.1,1X,'kW',
1 3X,'=>',3X,'CHANNEL:',1X,A2,A2,3X,'BUNDLE #',I2.2)
1017 FORMAT(1X,'AVERAGE POWER OVER ALL BUNDLES',
1 1X,'=',1X,F9.1,1X,'kW')
1018 FORMAT(/1X,'MAXIMUM CHANNEL POWER =',1X,F9.1,1X,'kW',
1 3X,'=>',3X,'CHANNEL:',1X,A2,A2)
1019 FORMAT(1X,'AVERAGE POWER OVER ALL CHANNELS',
1 1X,'=',1X,F9.1,1X,'kW')
END
|
