EM974 – Métodos Computacionais 2s 2013 - Teste – Tuma AProf. Eugênio Spanó Rosa – 1h50

Instruções: Esta folha deverá ser devolvida no final do teste; Crie uma pasta na área de trabalho e nomeie-a com o RA e nome ex.: B-61234-Einsten; Na pasta adicione: q1, result, phi e crie um arquivo Word com suas respostas; Ao final do teste o professor passará um ‘pen-drive’ recolhendo as pastas.

RA ___________ Nome _______________________________________________

Questão: Um canal de seção retangular possui uma bifurcação tipo T com dimensões indicadas na figura. As paredes do canal são lisas, porém possuem atrito. O fluido que escoa no canal é CO2

considerado como um gás ideal. A entrada do canal é dividida em duas partes iguais denominadas por (1) e (2). Na entrada o fluido possui 10 m/s, mas a temperatura na seção (1) é de 20oC enquanto que na seção (2) é de 100oC. A pressão de referência é 105 Pa, os ramos principal e secundário descarregam CO2

a uma pressão relativa de 0 Pa e -90 Pa respectivamente.

Dimensões Objetos, materiais e condições de contorno

Considerações: i. O escoamento é em regime permanente;

ii. O domínio é o plano XY e possui 1 vol. direção Z, escoamento bi-dimensional;iii. Para gerar a grade utilize o gerador automático de grade do Phoenics;iv. Fazendo ajustes apenas no ‘Init. cell factor’ faça com que o número de volumes nas direções X e

Y passam a ser de 34 e 67, respectivamente;v. Considere o escoamento turbulento, com 5% de intensidade de turbulência na entrada e utilize o

modelo KE-Chem Kim na simulação;vi. Utilize um número de interações do ‘Solver’ de maneira que os resíduos satisfaçam os critérios

de parada estabelecidos pelo próprio Phoenics.

Itens Solicitados Abaixo devem ter suas respostas anexadas ao arquivo Word:

a) Capture a ‘tela de convergência’ após finalizar os cálculos.b) Obtenha no RESULT a vazão mássica na entrada, e aquela descarregada pelos ramos principal e

secundário, expresse sua resposta em (kg/s).c) Utilizando o VIEWER determine a temperatura média na entrada, e na descarrega dos ramos

principal e secundário, expresse sua resposta em Celsius.d) Faça um gráfico XY da Temperatura na direção X ao longo da linha de centro do ramo principal

(Y = 0,25m).e) Gere 15 linhas de corrente a partir da entrada do canal.

GabaritoGrande pegada na correção é que a colocar a densidade do CO2 no inlet.

a) Capture a ‘tela de convergência’ após finalizar os cálculos e indique o número de iterações necessário

b) Determine a vazão mássica na entrada, e aquela descarregada pelos ramos principal e secundário, expresse sua resposta em (kg/s) e anexe os resultados ao arquivo Word de respostas.

Nett source of R1 at patch named: OB3 (INLET-S ) = 2.695500E+00 Nett source of R1 at patch named: OB4 (EXIT-BRA) =-1.053452E+00 (Mass Out -1.061421E+00 In 7.969029E-03) Nett source of R1 at patch named: OB5 (EXIT-MAI) =-3.832123E+00 (Mass Out -3.832123E+00 In 0.000000E+00) Nett source of R1 at patch named: OB6 (INLET-N ) = 2.190000E+00 pos. sum=4.8855 neg. sum=-4.885575 nett sum=-7.486343E-05

Entrada = 4.88 kg/s, Principal = 3.83 kg/s e Secundário: 1.05 kg/s

f) Determine a temperatura média na entrada, e aquela descarregada pelos ramos principal e secundário.Resposta: Entrada = 60 oC, Principal = 52 oC e Secundário: 86 oC

g) Faça um gráfico XY contendo a velocidade na direção X ao longo da linha de centro do ramo principal e anexe a figura ao arquivo Word de respostas.

h) Gere na entrada do canal 15 linhas de corrente e anexe a figura ao arquivo Word de respostas.

************************************************************ --------------------------------------------------------- CCCC HHH PHOENICS September 2010 - EARTH CCCCCCCC H (C) Copyright 2010 CCCCCCC See H Concentration Heat and Momentum Ltd CCCCCCC our new H All rights reserved. CCCCCC Web-site H Address: Bakery House, 40 High St CCCCCCC www.cham. H Wimbledon, London, SW19 5AU CCCCCCC co.uk H Tel: 020-8947-7651 CCCCCCCC H Fax : 020-8879-3497 CCCC HHH E-mail: phoenics@cham.co.uk --------------------------------------------------------- This program forms part of the PHOENICS installation for: CHAM The code expiry date is the end of : feb 2021 --------------------------------------------------------- Running with 32-bit executable ************************************************************ Initial estimated storage requirement is 10000000 Information about material properties Total number of SPEDATs is 27 number of materials specified by SPEDATs is 3 solprp = 100 porprp = 198 vacprp = 199 !!!! The properties file is PROPS Properties being read from PROPS Properties have been read from PROPS PRPS is stored with initial value= =198. Material properties used for phase 1 are density laminar viscosity turbulent viscosity mixing length specific heat >>> End of property-related data <<< ************************************************************ Number of F-array locations available is 10000000 Number used before BFC allowance is 249069 Number used after BFC allowance is 249069 >> Current turbulence model constants << They may be changed by inserting in Q1 SPEDAT(KECONST,name of constant,R,value) CMU =0.5478 CD =0.1643 CMUCD =0.090004 C1E =1.44 C2E =1.92 AK =0.41 EWAL =8.6 biggest cell volume divided by average is 4.417658 at: ix = 1 iy = 18 iz = 1 xg =0.174534 yg =0.258333 zg =0.5 smallest cell volume divided by average is 0.1857450 at:

ix = 18 iy = 24 iz = 1 xg =2.008562 yg =0.35 zg =0.5 ratio of smallest to biggest is 4.2046029E-02 ************************************************************ -------- Recommended settings ------- CONWIZ=T activates settings based on refrho =1. refvel =10. reflen =1. reftemp =1000. rlxdu1 =0.5 rlxdv1 =0.5 rlxdw1 =0.5 Maximum change of U1 per sweep= 100.0000 Maximum change of V1 per sweep= 100.0000 Maximum change of KE per sweep= 0.1000000 Maximum change of EP per sweep= 1000.000 Maximum change of TEM1 per sweep= 1000.000 relaxation and min/max values left at defaults may have been changed ************************************************************ ************************************************************ Group 1. Run Title and Number ************************************************************ ************************************************************ TEXT(2s 2012 test turma b ) ************************************************************ ************************************************************ IRUNN = 1 ;LIBREF = 0 ************************************************************ Group 2. Time dependence STEADY = T ************************************************************ Group 3. X-Direction Grid Spacing CARTES = T NX = 34 XULAST =3. XFRAC(1)=0.116356 ;XFRAC(7)=0.503298 XFRAC(13)=0.632884 ;XFRAC(19)=0.679224 XFRAC(25)=0.727589 ;XFRAC(31)=0.857645 ************************************************************ Group 4. Y-Direction Grid Spacing NY = 67 YVLAST =1. YFRAC(1)=0.014286 ;YFRAC(14)=0.205 YFRAC(27)=0.4 ;YFRAC(40)=0.595 YFRAC(53)=0.79 ;YFRAC(66)=0.985 ************************************************************ Group 5. Z-Direction Grid Spacing PARAB = F NZ = 1 ZWLAST =1. ************************************************************

Group 6. Body-Fitted Coordinates ************************************************************ Group 7. Variables: STOREd,SOLVEd,NAMEd ONEPHS = T NAME(1)=P1 ;NAME(3)=U1 NAME(5)=V1 ;NAME(12)=KE NAME(13)=EP ;NAME(143)=PRPS NAME(144)=SKIN ;NAME(145)=YPLS NAME(146)=TEM1 ;NAME(147)=EPKE NAME(148)=DEN1 ;NAME(149)=EL1 NAME(150)=ENUT * Y in SOLUTN argument list denotes: * 1-stored 2-solved 3-whole-field * 4-point-by-point 5-explicit 6-harmonic averaging SOLUTN(P1,Y,Y,N,N,N,Y) SOLUTN(U1,Y,Y,N,N,N,Y) SOLUTN(V1,Y,Y,N,N,N,Y) SOLUTN(KE,Y,Y,N,N,N,N) SOLUTN(EP,Y,Y,N,N,N,N) SOLUTN(PRPS,Y,N,N,N,N,N) SOLUTN(SKIN,Y,N,N,N,N,Y) SOLUTN(YPLS,Y,N,N,N,N,Y) SOLUTN(TEM1,Y,Y,N,N,N,Y) SOLUTN(EPKE,Y,N,N,N,N,Y) SOLUTN(DEN1,Y,N,N,N,N,Y) SOLUTN(EL1,Y,N,N,N,N,Y) SOLUTN(ENUT,Y,N,N,N,N,Y) DEN1 = 148 VIST = 150 LEN1 = 149 PRPS = 143 ************************************************************ Group 8. Terms & Devices * Y in TERMS argument list denotes: * 1-built-in source 2-convection 3-diffusion 4-transient * 5-first phase variable 6-interphase transport TERMS(P1,Y,Y,Y,N,Y,N) TERMS(U1,Y,Y,Y,N,Y,N) TERMS(V1,Y,Y,Y,N,Y,N) TERMS(KE,N,Y,Y,N,Y,N) TERMS(EP,N,Y,Y,N,Y,N) TERMS(TEM1,Y,Y,Y,N,Y,N) DIFCUT =0.5 ;ZDIFAC =1. GALA = F ;ADDDIF = T NEWENT = T ISOLX = -1 ;ISOLY = -1 ;ISOLZ = 0 ************************************************************ Group 9. Properties used if PRPS is not stored, and where PRPS = -1.0 if it is! RHO1 =0. ;TMP1 =0. EL1 = GRND4 TSURR =0. ;TEMP0 =273. PRESS0 =1.01325E+05 DVO1DT =0. ;DRH1DP =0. EMISS =0. ;SCATT =0. RADIA =0. ;RADIB =0. EL1A =0. ;EL1B =0. EL1C =0. ENUL =0. ;ENUT = GRND3 ENUTA =0. ;ENUTB =0. ENUTC =0. IENUTA = 2 PRNDTL(U1)=1. ;PRNDTL(V1)=1. PRNDTL(KE)=1. ;PRNDTL(EP)=1. PRNDTL(TEM1)=0. PRT(U1)=1. ;PRT(V1)=1.

PRT(KE)=0.75 ;PRT(EP)=1.15 PRT(TEM1)=1. CP1 =0. ;CP2 =1. ************************************************************ Group 10.Inter-Phase Transfer Processes ************************************************************ Group 11.Initial field variables (PHIs) FIINIT(P1)=0. ;FIINIT(U1)=1.0E-10 FIINIT(V1)=1.0E-10 ;FIINIT(KE)=0.25 FIINIT(EP)=2.738693 ;FIINIT(PRPS)=198. FIINIT(SKIN)=1.0E-10 ;FIINIT(YPLS)=1.0E-10 FIINIT(TEM1)=20. ;FIINIT(EPKE)=1.0E-10 FIINIT(DEN1)=1.0E-10 ;FIINIT(EL1)=1.0E-10 FIINIT(ENUT)=1.0E-10 Parent VR object for this patch is: MAIN PATCH(OB1 ,INIVAL, 1, 34, 8, 27, 1, 1, 1, 1) INIT(OB1 ,PRPS,0. ,7. ) Parent VR object for this patch is: BRANCH PATCH(OB2 ,INIVAL, 18, 22, 21, 67, 1, 1, 1, 1) INIT(OB2 ,PRPS,0. ,5. ) INIADD = F FSWEEP = 1 NAMFI =CHAM ************************************************************ Group 12. Patchwise adjustment of terms Patches for this group are printed with those for Group 13. Their names begin either with GP12 or & ************************************************************ Group 13. Boundary & Special Sources Parent VR object for this patch is: INLET-S PATCH(OB3 ,WEST , 1, 1, 8, 17, 1, 1, 1, 1) COVAL(OB3 ,P1 , FIXFLU ,17.969999 ) COVAL(OB3 ,U1 ,0. ,10. ) COVAL(OB3 ,V1 ,0. ,0. ) COVAL(OB3 ,KE ,0. ,0.25 ) COVAL(OB3 ,EP ,0. ,2.738693 ) COVAL(OB3 ,TEM1,0. ,20. ) Parent VR object for this patch is: EXIT-BRA PATCH(OB4 ,NORTH , 18, 22, 67, 67, 1, 1, 1, 1) COVAL(OB4 ,P1 ,1000. ,-90. ) COVAL(OB4 ,U1 ,0. ,0. ) COVAL(OB4 ,V1 ,0. ,0. ) COVAL(OB4 ,KE ,0. , SAME ) COVAL(OB4 ,EP ,0. , SAME ) COVAL(OB4 ,TEM1,0. ,20. ) Parent VR object for this patch is: EXIT-MAI PATCH(OB5 ,EAST , 34, 34, 8, 27, 1, 1, 1, 1) COVAL(OB5 ,P1 ,1000. ,0. ) COVAL(OB5 ,U1 ,0. ,0. ) COVAL(OB5 ,V1 ,0. ,0. ) COVAL(OB5 ,KE ,0. , SAME ) COVAL(OB5 ,EP ,0. , SAME ) COVAL(OB5 ,TEM1,0. ,20. ) Parent VR object for this patch is: INLET-N PATCH(OB6 ,WEST , 1, 1, 18, 27, 1, 1, 1, 1) COVAL(OB6 ,P1 , FIXFLU ,14.6 ) COVAL(OB6 ,U1 ,0. ,10. )

COVAL(OB6 ,V1 ,0. ,0. ) COVAL(OB6 ,KE ,0. ,0.25 ) COVAL(OB6 ,EP ,0. ,2.738693 ) COVAL(OB6 ,TEM1,0. ,100. ) PATCH(KESOURCE,PHASEM, 1, 34, 1, 67, 1, 1, 1, 1) COVAL(KESOURCE,KE , GRND4 , GRND4 ) COVAL(KESOURCE,EP , GRND4 , GRND4 ) PATCH(KECHEN ,PHASEM, 1, 34, 1, 67, 1, 1, 1, 1) COVAL(KECHEN ,EP , FIXFLU , GRND4 ) Parent VR object for this patch is: MAIN PATCH(OC1 ,VOLUME, 1, 34, 8, 27, 1, 1, 1, 1) Parent VR object for this patch is: BRANCH PATCH(OC2 ,VOLUME, 18, 22, 21, 67, 1, 1, 1, 1) XCYCLE = F EGWF = T WALLCO = GRND2 ************************************************************ Group 14. Downstream Pressure For PARAB ************************************************************ Group 15. Terminate Sweeps LSWEEP = 1000 ;ISWC1 = 1 LITHYD = 1 ;LITFLX = 1 ;LITC = 1 ;ITHC1 = 1 SELREF = T RESFAC =1.0E-03 ************************************************************ Group 16. Terminate Iterations LITER(P1)=200 ;LITER(U1)=10 LITER(V1)=10 ;LITER(KE)=20 LITER(EP)=20 ;LITER(TEM1)=20 ENDIT(P1)=1.0E-03 ;ENDIT(U1)=1.0E-03 ENDIT(V1)=1.0E-03 ;ENDIT(KE)=1.0E-03 ENDIT(EP)=1.0E-03 ;ENDIT(TEM1)=1.0E-03 ************************************************************ Group 17. Relaxation RELAX(P1,LINRLX,0.5) RELAX(U1,LINRLX,0.5) RELAX(V1,LINRLX,0.5) RELAX(KE,LINRLX,0.5) RELAX(EP,LINRLX,0.5) RELAX(PRPS,LINRLX,1.) RELAX(SKIN,LINRLX,1.) RELAX(YPLS,LINRLX,1.) RELAX(TEM1,LINRLX,0.25) RELAX(EPKE,LINRLX,1.) RELAX(DEN1,LINRLX,0.5) RELAX(EL1,LINRLX,1.) RELAX(ENUT,LINRLX,0.5) KELIN = 3 OVRRLX =0. EXPERT = F ;NNORSL = F ************************************************************ Group 18. Limits VARMAX(P1)=1.0E+10 ;VARMIN(P1)=-1.0E+10 VARMAX(U1)=1.0E+06 ;VARMIN(U1)=-1.0E+06 VARMAX(V1)=1.0E+06 ;VARMIN(V1)=-1.0E+06 VARMAX(KE)=1.0E+10 ;VARMIN(KE)=1.0E-10 VARMAX(EP)=1.0E+10 ;VARMIN(EP)=1.0E-10 VARMAX(PRPS)=1.0E+10 ;VARMIN(PRPS)=-1.0E+10

VARMAX(SKIN)=1.0E+10 ;VARMIN(SKIN)=-1.0E+10 VARMAX(YPLS)=1.0E+10 ;VARMIN(YPLS)=-1.0E+10 VARMAX(TEM1)=3000. ;VARMIN(TEM1)=-204.75 VARMAX(EPKE)=1.0E+10 ;VARMIN(EPKE)=1.0E-10 VARMAX(DEN1)=1.0E+10 ;VARMIN(DEN1)=1.0E-06 VARMAX(EL1)=1.0E+10 ;VARMIN(EL1)=1.0E-10 VARMAX(ENUT)=1.0E+10 ;VARMIN(ENUT)=1.0E-10 ************************************************************ Group 19. Data transmitted to GROUND GENK = T PARSOL = F CONWIZ = T IENUTA = 2 GEN1 = 681 ISG50 = 1 SPEDAT(SET,DOMAIN,PHASE_1_MAT,I,198) SPEDAT(SET,KECONST,C1E,R,1.44) SPEDAT(SET,KECONST,C2E,R,1.92) SPEDAT(SET,OBJNAM,!OB1,C,MAIN) SPEDAT(SET,OBJTYP,!OB1,C,BLOCKAGE) SPEDAT(SET,MAIN,MATERIAL,R,7.) SPEDAT(SET,OBJNAM,!OC1,C,MAIN) SPEDAT(SET,OBJTYP,!OC1,C,BLOCKAGE) SPEDAT(SET,OBJNAM,!OB2,C,BRANCH) SPEDAT(SET,OBJTYP,!OB2,C,BLOCKAGE) SPEDAT(SET,BRANCH,MATERIAL,R,5.) SPEDAT(SET,OBJNAM,!OC2,C,BRANCH) SPEDAT(SET,OBJTYP,!OC2,C,BLOCKAGE) SPEDAT(SET,OBJNAM,!OB3,C,INLET-S) SPEDAT(SET,OBJTYP,!OB3,C,INLET) SPEDAT(SET,OBJNAM,!OB4,C,EXIT-BRA) SPEDAT(SET,OBJTYP,!OB4,C,OUTLET) SPEDAT(SET,ARATIO,!OB4,R,1.) SPEDAT(SET,OBJNAM,!OB5,C,EXIT-MAI) SPEDAT(SET,OBJTYP,!OB5,C,OUTLET) SPEDAT(SET,ARATIO,!OB5,R,1.) SPEDAT(SET,OBJNAM,!OB6,C,INLET-N) SPEDAT(SET,OBJTYP,!OB6,C,INLET) SPEDAT(SET,FACETDAT,NUMOBJ,I,6) SPEDAT(SET,MATERIAL,198,L,T) SPEDAT(SET,MATERIAL,7,L,T) SPEDAT(SET,MATERIAL,5,L,T) ************************************************************ Group 20. Preliminary Printout ************************************************************ Group 21. Print-out of Variables INIFLD = F ;SUBWGR = F * Y in OUTPUT argument list denotes: * 1-field 2-correction-eq. monitor 3-selective dumping * 4-whole-field residual 5-spot-value table 6-residual table OUTPUT(P1,Y,N,Y,Y,Y,Y) OUTPUT(U1,Y,N,Y,Y,Y,Y) OUTPUT(V1,Y,N,Y,Y,Y,Y) OUTPUT(KE,Y,N,Y,Y,Y,Y) OUTPUT(EP,Y,N,Y,Y,Y,Y) OUTPUT(PRPS,Y,N,Y,N,N,N) OUTPUT(SKIN,Y,N,Y,N,N,N) OUTPUT(YPLS,Y,N,Y,N,N,N) OUTPUT(TEM1,Y,N,Y,Y,Y,Y) OUTPUT(EPKE,Y,N,Y,N,N,N) OUTPUT(DEN1,Y,N,Y,N,N,N) OUTPUT(EL1,Y,N,Y,N,N,N) OUTPUT(ENUT,Y,N,Y,N,N,N) WALPRN = T ************************************************************

Group 22. Monitor Print-Out IXMON = 2 ;IYMON = 32 ;IZMON = 1 NPRMON = 100000 ;NPRMNT = 1 ;TSTSWP = 10001 UWATCH = F ;USTEER = F HIGHLO = F ************************************************************ Group 23.Field Print-Out & Plot Control NPRINT = 1000 ;NUMCLS = 5 NXPRIN = 6 ;IXPRF = 1 ;IXPRL = 34 NYPRIN = 13 ;IYPRF = 1 ;IYPRL = 67 IPLTF = 1 ;IPLTL = 1000 ;NPLT = 50 ISWPRF = 1 ;ISWPRL = 100000 ITABL = 3 ;IPROF = 1 ABSIZ =0.5 ;ORSIZ =0.4 NTZPRF = 1 ;NCOLPF = 50 ICHR = 2 ;NCOLCO = 45 ;NROWCO = 20 No PATCHes yet used for this Group ************************************************************ Group 24. Dumps For Restarts SAVE = T ;NOWIPE = F NSAVE =CHAM *** grid-geometry information *** X-coordinates of the cell centres 1.745E-01 4.945E-01 7.612E-01 9.834E-01 1.169E+00 1.323E+00 1.451E+00 1.559E+00 1.648E+00 1.722E+00 1.784E+00 1.836E+00 1.879E+00 1.915E+00 1.945E+00 1.970E+00 1.991E+00 2.009E+00 2.027E+00 2.050E+00 2.073E+00 2.091E+00 2.111E+00 2.136E+00 2.166E+00 2.202E+00 2.246E+00 2.298E+00 2.360E+00 2.434E+00 2.524E+00 2.632E+00 2.761E+00 2.916E+00 Y-coordinates of the cell centres 7.143E-03 2.143E-02 3.571E-02 5.000E-02 6.429E-02 7.857E-02 9.286E-02 1.075E-01 1.225E-01 1.375E-01 1.525E-01 1.675E-01 1.825E-01 1.975E-01 2.125E-01 2.275E-01 2.425E-01 2.583E-01 2.750E-01 2.917E-01 3.071E-01 3.214E-01 3.357E-01 3.500E-01 3.643E-01 3.786E-01 3.929E-01 4.075E-01 4.225E-01 4.375E-01 4.525E-01 4.675E-01 4.825E-01 4.975E-01 5.125E-01 5.275E-01 5.425E-01 5.575E-01 5.725E-01 5.875E-01 6.025E-01 6.175E-01 6.325E-01 6.475E-01 6.625E-01 6.775E-01 6.925E-01 7.075E-01 7.225E-01 7.375E-01 7.525E-01 7.675E-01 7.825E-01 7.975E-01 8.125E-01 8.275E-01 8.425E-01 8.575E-01 8.725E-01 8.875E-01 9.025E-01 9.175E-01 9.325E-01 9.475E-01 9.625E-01 9.775E-01 9.925E-01 Z-coordinates of the cell centres 5.000E-01 X-coordinates of the (higher) cell faces 3.491E-01 6.400E-01 8.824E-01 1.084E+00 1.253E+00 1.393E+00 1.510E+00 1.607E+00 1.688E+00 1.756E+00 1.813E+00 1.860E+00 1.899E+00 1.931E+00 1.958E+00 1.981E+00 2.000E+00 2.017E+00 2.038E+00 2.062E+00 2.083E+00 2.100E+00 2.123E+00 2.150E+00 2.183E+00 2.222E+00 2.269E+00 2.326E+00 2.394E+00 2.475E+00 2.573E+00 2.690E+00 2.831E+00 3.000E+00

Y-coordinates of the (higher) cell faces 1.429E-02 2.857E-02 4.286E-02 5.714E-02 7.143E-02 8.571E-02 1.000E-01 1.150E-01 1.300E-01 1.450E-01 1.600E-01 1.750E-01 1.900E-01 2.050E-01 2.200E-01 2.350E-01 2.500E-01 2.667E-01 2.833E-01 3.000E-01 3.143E-01 3.286E-01 3.429E-01 3.571E-01 3.714E-01 3.857E-01 4.000E-01 4.150E-01 4.300E-01 4.450E-01 4.600E-01 4.750E-01 4.900E-01 5.050E-01 5.200E-01 5.350E-01 5.500E-01 5.650E-01 5.800E-01 5.950E-01 6.100E-01 6.250E-01 6.400E-01 6.550E-01 6.700E-01 6.850E-01 7.000E-01 7.150E-01 7.300E-01 7.450E-01 7.600E-01 7.750E-01 7.900E-01 8.050E-01 8.200E-01 8.350E-01 8.500E-01 8.650E-01 8.800E-01 8.950E-01 9.100E-01 9.250E-01 9.400E-01 9.550E-01 9.700E-01 9.850E-01 1.000E+00 Z-coordinates of the (higher) cell faces 1.000E+00 Total number of F-array elements used is 249123 --- INTEGRATION OF EQUATIONS BEGINS --- sweeping terminated before lsweep last swp= 945 lsweep = 1000 iswstp = 1000 Flow field at ITHYD= 1, IZ= 1, ISWEEP= 945, ISTEP= 1 Field Values of P1 IY= 67 none none none -9.000E+01 none IY= 54 none none none -9.770E+01 none IY= 41 none none none -1.102E+02 none IY= 28 none none none -9.300E+01 none IY= 15 -3.499E+01 -3.786E+01 -3.503E+01 -1.890E+01 -3.317E+00 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 3.796E-01 IY= 2 none IX= 31 Field Values of U1 IY= 67 none none none -1.425E-01 none IY= 54 none none none -1.141E-01 none IY= 41 none none none -4.324E-01 none IY= 28 none none none 7.246E+00 none IY= 15 1.002E+01 1.017E+01 9.873E+00 8.812E+00 7.956E+00 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 7.799E+00 IY= 2 none IX= 31 Field Values of V1 IY= 66 none none none 2.622E+00 none IY= 53 none none none 2.243E+00 none IY= 40 none none none 1.396E+00 none IY= 27 none none none 5.780E+00 none

IY= 14 -3.602E-02 1.787E-02 4.441E-01 8.905E-01 4.576E-01 IY= 1 none none none none none IX= 1 7 13 19 25 IY= 66 none IY= 53 none IY= 40 none IY= 27 none IY= 14 1.347E-02 IY= 1 none IX= 31 Field Values of KE IY= 67 none none none 1.395E+00 none IY= 54 none none none 1.420E+00 none IY= 41 none none none 1.244E+00 none IY= 28 none none none 3.890E-01 none IY= 15 1.898E-01 9.547E-02 8.132E-02 8.327E-02 8.240E-02 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 6.808E-02 IY= 2 none IX= 31 Field Values of EP IY= 67 none none none 6.152E+01 none IY= 54 none none none 7.277E+01 none IY= 41 none none none 7.728E+01 none IY= 28 none none none 2.208E+01 none IY= 15 1.702E+00 4.887E-01 3.585E-01 3.738E-01 3.699E-01 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 2.629E-01 IY= 2 none IX= 31 Field Values of PRPS IY= 67 blockage blockage blockage 5.000E+00 blockage IY= 54 blockage blockage blockage 5.000E+00 blockage IY= 41 blockage blockage blockage 5.000E+00 blockage IY= 28 blockage blockage blockage 5.000E+00 blockage IY= 15 7.000E+00 7.000E+00 7.000E+00 7.000E+00 7.000E+00 IY= 2 blockage blockage blockage blockage blockage IX= 1 7 13 19 25 IY= 67 blockage IY= 54 blockage IY= 41 blockage IY= 28 blockage IY= 15 7.000E+00 IY= 2 blockage IX= 31 Field Values of SKIN

IY= 67 none none none 1.000E-10 none IY= 54 none none none 1.000E-10 none IY= 41 none none none 1.000E-10 none IY= 28 none none none 1.000E-10 none IY= 15 1.000E-10 1.000E-10 1.000E-10 1.000E-10 1.000E-10 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 1.000E-10 IY= 2 none IX= 31 Field Values of YPLS IY= 67 none none none 1.000E-10 none IY= 54 none none none 1.000E-10 none IY= 41 none none none 1.000E-10 none IY= 28 none none none 1.000E-10 none IY= 15 1.000E-10 1.000E-10 1.000E-10 1.000E-10 1.000E-10 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 1.000E-10 IY= 2 none IX= 31 Field Values of TEM1 IY= 67 none none none 9.575E+01 none IY= 54 none none none 9.567E+01 none IY= 41 none none none 9.564E+01 none IY= 28 none none none 9.666E+01 none IY= 15 2.072E+01 2.369E+01 2.321E+01 2.201E+01 2.125E+01 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 2.119E+01 IY= 2 none IX= 31 Field Values of EPKE IY= 67 none none none 4.412E+01 none IY= 54 none none none 5.124E+01 none IY= 41 none none none 6.213E+01 none IY= 28 none none none 5.677E+01 none IY= 15 8.966E+00 5.119E+00 4.409E+00 4.489E+00 4.489E+00 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 3.861E+00 IY= 2 none IX= 31 Field Values of DEN1 IY= 67 none none none 1.797E+00 none

IY= 54 none none none 1.797E+00 none IY= 41 none none none 1.797E+00 none IY= 28 none none none 1.797E+00 none IY= 15 1.826E+00 1.807E+00 1.810E+00 1.818E+00 1.823E+00 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 1.823E+00 IY= 2 none IX= 31 Field Values of EL1 IY= 67 none none none 4.398E-03 none IY= 54 none none none 3.821E-03 none IY= 41 none none none 2.949E-03 none IY= 28 none none none 1.805E-03 none IY= 15 7.983E-03 9.916E-03 1.063E-02 1.056E-02 1.051E-02 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 1.110E-02 IY= 2 none IX= 31 Field Values of ENUT IY= 67 none none none 2.845E-03 none IY= 54 none none none 2.494E-03 none IY= 41 none none none 1.802E-03 none IY= 28 none none none 6.167E-04 none IY= 15 1.905E-03 1.678E-03 1.660E-03 1.669E-03 1.652E-03 IY= 2 none none none none none IX= 1 7 13 19 25 IY= 67 none IY= 54 none IY= 41 none IY= 28 none IY= 15 1.587E-03 IY= 2 none IX= 31 ************************************************************ Whole-field residuals before solution with resref values determined by EARTH & resfac=1.0E-03 variable resref (res sum)/resref (res sum) P1 9.392E-05 1.220E+00 1.145E-04 U1 6.770E-04 6.871E-01 4.651E-04 V1 2.409E-04 9.737E-01 2.346E-04 KE 2.723E-05 8.943E-01 2.435E-05 EP 9.899E-04 7.561E-01 7.485E-04 TEM1 5.469E+00 9.782E-01 5.350E+00 ************************************************************ Sources and sinks !! Zero nett sources are not printed !!!

Nett Sources have units of mass_per_unit_time * variable Average values have units of the variable Typically the units of the sources are: U1,V1,W1 - Force - Newtons R1 - Mass - kg/s TEM1 - Energy - Watts Nett source of U1 at patch named: OB3 (INLET-S ) = 2.695500E+01 Nett source of U1 at patch named: OB4 (EXIT-BRA) = 1.009327E-01 Nett source of U1 at patch named: OB5 (EXIT-MAI) =-2.910032E+01 Nett source of U1 at patch named: OB6 (INLET-N ) = 2.190000E+01 pos. sum=48.955933 neg. sum=-29.100323 nett sum=19.85561 Nett source of V1 at patch named: OB4 (EXIT-BRA) =-9.071315E+00 Nett source of V1 at patch named: OB5 (EXIT-MAI) = 2.143301E-02 pos. sum=0.021433 neg. sum=-9.071315 nett sum=-9.049882 Nett source of R1 at patch named: OB3 (INLET-S ) = 2.695500E+00 Nett source of R1 at patch named: OB4 (EXIT-BRA) =-1.053452E+00 (Mass Out -1.061421E+00 In 7.969029E-03) Nett source of R1 at patch named: OB5 (EXIT-MAI) =-3.832123E+00 (Mass Out -3.832123E+00 In 0.000000E+00) Nett source of R1 at patch named: OB6 (INLET-N ) = 2.190000E+00 pos. sum=4.8855 neg. sum=-4.885575 nett sum=-7.486343E-05 Nett source of KE at patch named: OB3 (INLET-S ) = 6.738750E-01 (Average 2.500000E-01) Nett source of KE at patch named: OB4 (EXIT-BRA) =-8.904201E-01 (Ave Out 8.389122E-01 In 2.349703E-03) Nett source of KE at patch named: OB5 (EXIT-MAI) =-4.025342E-01 (Ave Out 1.050421E-01 In 0.000000E+00) Nett source of KE at patch named: OB6 (INLET-N ) = 5.475000E-01 (Average 2.500000E-01) Nett source of KE at patch named: KESOURCE =-9.092108E+00 pos. sum=1.221375 neg. sum=-10.385062 nett sum=-9.163687 Nett source of EP at patch named: OB3 (INLET-S ) = 7.382146E+00 (Average 2.738693E+00) Nett source of EP at patch named: OB4 (EXIT-BRA) =-3.702305E+01 (Ave Out 3.488069E+01 In 5.331111E-03) Nett source of EP at patch named: OB5 (EXIT-MAI) =-6.884869E+00 (Ave Out 1.796620E+00 In 0.000000E+00) Nett source of EP at patch named: OB6 (INLET-N ) = 5.997738E+00 (Average 2.738693E+00) Nett source of EP at patch named: KESOURCE =-7.256718E+02 Nett source of EP at patch named: KECHEN = 9.525824E+02 pos. sum=965.96228 neg. sum=-769.579651 nett sum=196.382629 DP/Dt contribution to TEM1 nett source = 0.000000E+00 (Flx Out 0.000000E+00 In 0.000000E+00)

Nett source of TEM1 at patch named: OB3 (INLET-S ) = 6.676812E+05 (Average 2.477022E+05) Nett source of TEM1 at patch named: OB4 (EXIT-BRA) =-3.310868E+05 (Ave Out 9.574264E+01 In 2.000000E+01) Nett source of TEM1 at patch named: OB5 (EXIT-MAI) =-1.027220E+06 (Ave Out 4.407492E+01 In 0.000000E+00) Nett source of TEM1 at patch named: OB6 (INLET-N ) = 6.905819E+05 (Average 3.153342E+05) pos. sum=1.358263E+06 neg. sum=-1.358307E+06 nett sum=-43.75 ************************************************************ spot values vs sweep or iteration number IXMON= 2 IYMON= 32 IZMON= 1 TIMESTEP= 1 Tabulation of abscissa and ordinates... ISWP P1 U1 V1 KE EP 1 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 51 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 101 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 151 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 201 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 251 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 301 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 351 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 401 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 451 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 501 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 551 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 601 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 651 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 701 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 751 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 801 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 851 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 901 0.0000E+00 0.0000E+00 0.0000E+00 1.0000E-10 1.0000E-10 ISWP TEM1 1 2.0000E+01 51 2.0000E+01 101 2.0000E+01 151 2.0000E+01 201 2.0000E+01 251 2.0000E+01 301 2.0000E+01 351 2.0000E+01 401 2.0000E+01 451 2.0000E+01 501 1.9999E+01

551 1.9995E+01 601 1.9989E+01 651 1.9989E+01 701 1.9988E+01 751 1.9988E+01 801 1.9988E+01 851 1.9988E+01 901 1.9988E+01 Variable 1 = P1 2 = U1 3 = V1 4 = KE 5 = EP Minval= 0.000E+00 0.000E+00 0.000E+00 1.000E-10 1.000E-10 Maxval= 0.000E+00 0.000E+00 0.000E+00 1.000E-10 1.000E-10 Cellav= 0.000E+00 0.000E+00 0.000E+00 1.000E-10 1.000E-10 Variable 6 = TEM1 Minval= 1.999E+01 Maxval= 2.000E+01 Cellav= 2.000E+01 1.00 6..6.+6.6.+6..6+.6.6+.6..6....+....+....+....+....+ . . 0.90 + 6 + . . 0.80 + + . . 0.70 + + . . 0.60 + + . 6 . 0.50 + + . . 0.40 + + . . 0.30 + + . . 0.20 + + . . 0.10 + 6 6 + . . 0.00 5..5.+5.5.+5..5+.5.5+.5..5..5.+5.5.+5..6+.6.6+.6..6 0 .1 .2 .3 .4 .5 .6 .7 .8 .9 1.0 the abscissa is ISWP. min= 1.00E+00 max= 9.01E+02 ************************************************************ ************************************************************ residuals vs sweep or iteration number Tabulation of abscissa and ordinates... ISWP P1 U1 V1 KE EP 1 2.3366E+09 2.2780E+06 1.5132E+06 2.0537E+06 2.1377E+06 51 4.1050E+02 1.0985E+04 2.7648E+04 5.9086E+03 1.1961E+04 101 2.2337E+02 1.2346E+03 7.9117E+03 2.1470E+03 5.1025E+03 151 1.2286E+02 9.5957E+02 4.0199E+03 2.1602E+03 6.3456E+03 201 7.1662E+01 6.6077E+02 3.0046E+03 1.4684E+03 3.7280E+03 251 4.5237E+01 3.2224E+02 2.1510E+03 6.8188E+02 2.3243E+03 301 2.3207E+01 9.2426E+01 1.2566E+03 8.9428E+02 2.8613E+03 351 1.1263E+01 3.8029E+01 5.8907E+02 5.1995E+02 1.5914E+03

401 8.1893E+00 3.9978E+01 2.6400E+02 2.0858E+02 6.0211E+02 451 5.3676E+00 2.5998E+01 1.3296E+02 5.1658E+01 1.2617E+02 501 3.9060E+00 1.2003E+01 8.1570E+01 2.0344E+01 6.7880E+01 551 1.6237E+00 3.3826E+00 4.5259E+01 2.0319E+01 6.5321E+01 601 3.0784E+00 1.9640E+00 1.7535E+01 1.2090E+01 3.6142E+01 651 1.1028E+00 1.6152E+00 7.7880E+00 5.7330E+00 1.6116E+01 701 1.4498E+00 1.0054E+00 4.0478E+00 1.4753E+00 3.5841E+00 751 1.5634E+00 9.7527E-01 2.3155E+00 8.4889E-01 1.0452E+00 801 1.5636E+00 8.4211E-01 1.2384E+00 1.4351E+00 3.9722E+00 851 1.2856E+00 7.5573E-01 9.8156E-01 5.9834E-01 4.6343E-01 901 1.2336E+00 6.3293E-01 9.9083E-01 8.0751E-01 6.7185E-01 ISWP TEM1 1 2.2398E+05 51 3.3832E+02 101 4.7757E+01 151 6.0174E+01 201 5.6057E+01 251 2.6755E+01 301 8.5429E+00 351 3.5386E+00 401 4.2338E+00 451 2.7658E+00 501 1.4952E+00 551 1.0614E+00 601 9.3078E-01 651 1.0359E+00 701 8.9856E-01 751 9.9137E-01 801 9.3106E-01 851 9.6713E-01 901 9.7208E-01 Variable 1 = P1 2 = U1 3 = V1 4 = KE 5 = EP Minval= 9.785E-02 -4.574E-01 -1.862E-02 -5.136E-01 -7.691E-01 Maxval= 2.157E+01 1.464E+01 1.423E+01 1.454E+01 1.458E+01 Variable 6 = TEM1 Minval= -1.070E-01 Maxval= 1.232E+01 1.00 6....+....+....+....+....+....+....+....+....+....+ . . 0.90 + + . . 0.80 + + . . 0.70 + 3 + . 5 3 . 0.60 + 4 5 5 5 + . 4 4 3 5 5 5 . 0.50 + 6 2 2 4 4 + . 2 4 4 5 . 0.40 + 2 4 + . 6 6 2 5 . 0.30 + 1 6 4 5 5 5 + . 1 6 2 2 2 4 4 5 . 0.20 + 1 1 6 2 4 + . 1 1 4 5 5 . 0.10 + 6 6 6 2 2 3 + . 1 6 1 2 4 5 4 .

0.00 +....+....+....+....+....+....+6.6.+6..6+.6.6+.6..6 0 .1 .2 .3 .4 .5 .6 .7 .8 .9 1.0 the abscissa is ISWP. min= 1.00E+00 max= 9.01E+02 ************************************************************ ************************************************************ SATLIT RUN NUMBER = 1 ; LIBRARY REF.= 0 Run started at 15:19:48 on Thursday, 27 September 2012 Run completed at 15:35:47 on Thursday, 27 September 2012 CPU time of run 18 s This includes 14 seconds of user time and 3 seconds of system time. TIME/(VARIABLES*CELLS*TSTEPS*SWEEPS*ITS) = 1.394E-06 ************************************************************