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  • Units conversion
    Units conversion Density Mass Flux Diffusivity Mole Flux Dynamic viscosity Power Energy or Work Pressure Enthalpy Specific Heat Force Stress Heat Flux Temperature Heat Transfer Coefficient Thermal Conductivity Length Velocity

    Original URL path: http://www.cham.co.uk/phoenics/d_utils/d_units/units.htm (2016-02-15)
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  • CP1.HTM
    i e the use of the built in formulae which will now be described In these formulae the absolute temperature Tabs is equal to the local temperature TEM1 plus the constant TEMP0 which is set in the Q1 file It should be remarked that the built in formulae are rather unsophisticated Users are recommended to use the In Form method for introducing specific heat information of any complexity The built in formulae CP1 GRND1 selects CP CP1A CP1B Tabs This implies that the enthalpy is a quadratic function of temperature CP1 GRND2 selects CP CP1A CP1B Tabs CP1C Tabs 2 This implies that the enthalpy is a cubic function of temperature For air 280 1500K A 917 B 0 258 C 3 98E 5 For ammonia gas 300 1000K A 1520 B 1 94 C 1 79E 4 CP1 GRND3 selects CP CP1A CP1B Tabs CP1C Tabs 2 This also implies that the enthalpy is a cubic function of temperature For CO2 300 3500K A 1540 B 3 45E5 C 4 14E7 For O2 300 5000K A 1420 B 2 73E4 C 4 94E7 For N2 300 5000K A 1420 B 2 88E5 C 5 35E7 Note that the integration is carried out from Tabs 200 upward because the Cp expression cannot be integrated down to Tabs 0 CP1 GRND4 selects CP CP1A CP1B Tabs CP1C Tabs 0 5 For H2 300 2200K A 1 2E4 B 2 16 C 3 1E4 CP1 GRND5 selects CP1 CP1A CP1B sqrt Tabs CP1C Tabs For O2 300 2800K A 1 51E3 B 1 68E4 C 1 11E5 CP1 GRND6 selects CP CP1A for 0 Tabs CP1C and CP CP1B for CP1C Tabs where CP1C Tabs phase change and PHNH1A latent heat of phase change The latent heat is released over a 1

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_enc/cp1.htm (2016-02-15)
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  • TMP1
    TMP1 a non GROUND constant has the same effect TMP1 GRND2 selects temperature equal to F L0H12 I F L0CP12 I TMP1A H base is set via the PIL variable TMP1A which is evidently equal to minus H base Cp TMP1 GRND3 selects temperature equal to F L0H12 I F L0CP12 I TMP1A TMPCG F L0CB I Here it is TMP1A TMPCG F L0CB I which represents H base Cp This allows H base to vary linearly in accordance with some scalar for example the mass fraction of some component of the fluid mixture The scalar represented by L0CB is C3 for Phase 1 and C4 for Phase 2 TMP1 GRND4 selects temperature equal to F L0H12 I F L0CP12 I TMP1B AMAX1 0 0 F L0CA I TMP1C This allows H base to depend in a more complex way on the scalar value as when the flow simulated concerns mixing controlled combustion the scalar is the mixture fraction i e the proportion of the local mixture which derives from the fuel bearing inflow stream TMP1C represents the stoichiometric mixture fraction i e at which all the fuel has been oxidised The scalar represented by L0CA is C1 for Phase 1 and C2 for Phase 2 TMP1 GRND5 selects temperature equal to TMP1A 0 5 U1 2 V1 2 W1 2 F L0CP12 I where TMP1A denotes a constant stagnation enthalpy and the expression containing U1 V1 and W1 is the kinetic energy This option is useful for adiabatic high speed flows in conjunction with the setting RHO1 GRND5 which selects the ideal gas law TMP1 GRND6 selects the same formula as GRND5 except that the stagnation enthalpy field H1 is used instead of the constant TMP1A This is suitable for non adiabatic flows in which the stagnation enthalpy is a solved for variable TMP1 GRND7 selects temperature equal to enthalpy TMP2B Mfuel F L0CP12 I This option is used when the SCRS i e Simple Chemical Reaction System model of combustion is controlled by mixing see COMBUSTION The mass fractions of fuel product and oxidant are calculated from algebraic formulae involving the fuel oxidant mixture fraction which is solved as a dependent variable The specific heat CP1 should be set to GRND10 to activate the calculation of the specific heat of the fuel oxidant product mixture TMP1 GRND8 uses the same formula as GRND7 except that the mass fraction of fuel is solved as the dependent variable of its own transport equation as is necessary when the combustion rate is kinetically controlled See REACT for the source options for the Mfuel equation TMP1 GRND9 activates SXSCRI TMP1 GRND10 does likewise Setting TMP1 as a 3D stored variable When STORE TMP1 is present in the Q1 file the user has several ways of allocating it including By way of FIINIT TMP1 and PATCH INIT settings if the values are to vary only with position by way of GROUND coding perhaps PLANT created if values are to vary in the course

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_enc/tmp1.htm (2016-02-15)
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  • ShapeMaker: A VR-object creation package
    the outsides of tubes in a shell and tube heat exchanger The number of geometrical parameters is not less than 10 and the thought that a human being should be involved in systematically selecting one set after another is absurd It is arduous work even for computers But ShapeMaker allows them to do it It can to do so because it describes an object in two distinct ways firstly via a dat file which is used by the VR Editor to display it graphically and by the PHOENICS Earth solver module to determine which cells are cut by the solid and secondly via a usually much smaller geo file which records all the parameters which define the object and its dat representation Moreover whereas a dat file is only written a geo file can be read also Indeed the command shap fin geo fin dat will cause ShapeMaker to read from fin geo the parameters describing the geometry of a fin and then write a corresponding fin dat file which expresses its shape by way of facets But who or what writes the geo file A parameterised Q1 can do so as will now be described How PQ1 writes geo PHOENICS Input File Library case V htm is a parameterised Q1 devoted to flow in finned tube banks and it contains the following lines mesg about to write fin geo write fin geo shape compsfrstr write fin geo height ftkn1 write fin geo heigh2 ftkn2 write fin geo heigh3 ftkn3 write fin geo borad frou1 write fin geo birad fradin write fin geo torad frou1 write fin geo tirad fradin write fin geo tord2 frou2 write fin geo tird2 fradin write fin geo tord3 frou2 write fin geo tird3 fradin write fin geo f2pi 0 5 These when processed by the PHOENICS Satellite module cause it to write the following file fin geo shape compsfrstr height 7 5E 04 heigh2 7 5E 04 heigh3 1 5E 03 borad 0 035 birad 0 017 torad 0 035 tirad 0 017 tord2 0 02 tird2 0 017 tord3 0 02 tird3 0 017 f2pi 0 5 This is a file which ShapeMaker understands the first line indicating that the required object is of ShapeMaker s composite frustrum kind shown below and the subsequent lines indicating what non default parameter values it should use The numbers are the evaluations of the quantities ftkn1 etc which must have been declared in the PQ1 their values having been assigned or calculated higher up in that file Immediately below the WRITE instruction in the PQ1 there appears the single line EXEC t shap bat fin geo fin dat which causes ShapeMaker to read the fin geo file and write the fin dat one The VR Editor can then reveal what has been created thus The use of the command mode for creating facetted objects is thus extremely simple and it allows long sequences of runs to be made in each of which the shape of the

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_info/shapemak/shapemak.htm (2016-02-15)
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  • Batch Files
    m2 vre or vrv suffices to launch the executable in the selected mode For the convenience of users however mode specific commands are also provided The commands beginning run have been retained because users of earlier versions of PHOENICS may have become used to them Command What executable is or does sat SATELLITE input module I sil SATELLITE silent I txt SATELLITE text interactive I sm1 SATELLITE pre VR menu I sm2 SATELLITE latest menu I vre VR Editor vrv VR Viewer runpvr same as vre runsat same as sat runvre same as vre runvrv same as vrv Table 3 The EARTH solver and PHOTON display modules aut AUTOPLOT display module ear public EARTH solver module earpri private local EARTH solver module pho PHOTON display module runaut same as aut runear same as ear runpho same as pho runpri same as earpri Table 4 Actions in sequence WINDF command What executable is or does dem active demonstrations I lib SATELLITE EARTH PHOTON for library case rundem same as dem runlib same as lib Table 5 The utility modules WINDF command What executable is or does frust Fortran program creates cone frustrum segments for VR plntmen Menu program for PLANT runcmpr executable to compress or decompress a phi file runfil executable to fillet a phi file runpin PINTO the interpolation program runshap Interactive ShapeMaker module Table 6 Scripts to build executables WINDF command What it does bldear builds EARTH executable bldfrust compiles frustrum htm and builds frustrum executable bldsat builds SATELLITE executable bldsatx builds text only SATELLITE Table 8 Scripts valid for all command What it does modq1 saves Q1 as Q1 SAV and creates a model empty talk t Q1 Table 7 Compilation scripts WINDF command What it does compile compiles a Fortran file Information items bldear builds a solver

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_phoen/scripts.htm (2016-02-15)
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  • MIGAL for PHOENICS
    arbitrary unique number set by the SOLVEDnn statement 3 4 RELAX RELAX is the relaxation factor for the MIGAL multi grid smoother The efficiency of MIGAL is rather sensitive to this parameter and therefore a fine tuning is recommended Usual values should be larger than 0 8 SPEDAT MIGAL RELAXnn R value where value is a strictly positive real default 0 95 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 5 NBRELAX NBRELAX is the number of relaxations post relaxations to be done by the multi grid smoother on each grid level SPEDAT MIGAL NBRELAXnn I value where value is a strictly positive integer default 3 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 5 NBPRER NBPRER is the number of relaxations pre relaxations to be done by the multi grid smoother before transferring the calculation to each coarser grid level SPEDAT MIGAL NBPRERnn I value where value is a positive integer default 1 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 6 NBGRID NBGRID is the number of grid levels that MIGAL must use for its multi grid procedure When set to zero MIGAL automatically define the number of grid levels to be used When set to 1 MIGAL becomes a single grid solver SPEDAT MIGAL NBGRIDnn I value where value is a positive integer default 0 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 7 COEFF COEFF is the scaling factor of the preconditionner that MIGAL use when starting with a strong initial continuity residual When set to zero the preconditionner is switched off SPEDAT MIGAL COEFFnn R value where value is a positive real default 1 0 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 5 IGMRES IGMRES is the size of the Krylov subspace used by the GMRES implementation When set to zero the GMRES acceleration capability is switched off SPEDAT MIGAL IGMRESnn I value where value is a positive integer default 0 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 5 IPRECO IPRECO fixes the number of multi grid cycles that have to be done to precondition the GMRES process This parameter is associated to non zero values of IGMRES SPEDAT MIGAL IPRECOnn I value where value is a positive integer default 1 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 5 IGMS IGMS is the size of the Krylov subspace that MIGAL uses when the GMRES technique is also employed as a smoother In that case the smoother is preconditioned by NBPRER and NBRELAX relaxations of the ILU 0 solver SPEDAT MIGAL IPRECOnn I value where value is a positive integer default 0 and nn is the arbitrary unique number set by the SOLVEDnn statement 3 8 PRINT PRINT is a switch which turns on true or off false the internal residuals outputs from MIGAL The outputs are the

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_enc/migal/enc_mig.htm (2016-02-15)
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  • cfd cham PHOENICS simuserve info
    can be obtained by clicking here Back to top FME2VR FME2VR is a stand alone utility which converts an FME file such as is generated by CADFix into a file which can be interpreted as a VR object FME2VR is a standard component of the PHOENICS package Information about FME2VR can be obtained by clicking here Back to top STL2VR This stand alone utility is provided by CHAM to enable

    Original URL path: http://www.cham.co.uk/phoenics/d_polis/d_info/utils.htm (2016-02-15)
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  • q1ears
    NX 1 NY 1 NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z106 FREEZING WATER IN A LID DRIVEN CAVITY Z1 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z107 2D CHANNEL FLOW WITH LINEAR INLET PROFIL contains PHOTON USE commands for displaying results NX 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z108 3D STEADY HEAT CONDUCTION IN A CUBE 108 contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z109 RECIRCULATION IN A STILLING POND 109 contains PHOTON USE commands for displaying results NX 1 uses isentropic gas law for density fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z110 3D SHELL AND TUBE HEAT EXCHANGER 110 contains PHOTON USE commands for displaying results uses neighbour patch name NE uses PLANT to create extra Fortran coding cartesian grid Q1 z111 ABSORPTIVE DISPERSAL WITH TIME DEPENDENT contains PHOTON USE commands for displaying results time dependent NX 1 NY 1 NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z112 COMPLEX CONVECTION DEPENDENT SOURCE 112 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z113 NON ISOTHERMAL COUETTE FLOW 113 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z114 BRIDGED PIPE HEAT TRANSFER 114 contains PHOTON USE commands for displaying results cylindrical grid uses PLANT to create extra Fortran coding Q1 z115 SELF STEERING UNDER RELAXATION contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z116 Flow in stirred 3D vessel contains PHOTON USE commands for displaying results time dependent uses PLANT to create extra Fortran coding cartesian grid Q1 z117 2D HEAT CONDUCTION WITH SPACE DEPENDENT contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z118 3D DIFFUSION PROBLEM 118 contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z119 2D UNSTEADY DIFFUSION PROBLEM 119 contains PHOTON USE commands for displaying results time dependent NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z120 2D CONVECTIVE DIFFUSION PROBLEM 120 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z121 1D uniform flow dispersion 121 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z122 3D SHELL AND TUBE HEAT EXCHANGER 122 contains PHOTON USE commands for displaying results uses neighbour patch name NE uses PLANT to create extra Fortran coding cartesian grid Q1 z123 CONJUGATE HEAT TRANSFER IN THICK WALLED contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z124 NATURAL STIRRING IN A STABLY FLUID 124 contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z126 Soil water flow in a curved channel 126 contains PHOTON USE commands for displaying results NX 1 body fitted coordinates two phase flow uses PLANT to create extra Fortran coding cartesian grid Q1 z127 Polysized heavy aerosol dispersion 127 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z128 NATURAL STIRRING IN A STABLY FLUID 124 contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z129 NATURAL CONVECTION BETWEEN FLAT PLATES 1 contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z130 BENCHMARK CASE OF MIXED CONVECTION 130 contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z131 NATURAL CONVECTION IN POROUS MEDIA 131 contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid involves buoyancy uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z132 COMPLEX CHEMISTRY EXAMPLE 132 contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z133 Three component mixing of different gase contains PHOTON USE commands for displaying results cylindrical grid NZ 1 uses SCRS option for density uses PLANT to create extra Fortran coding Q1 z134 Natural cooler in a still atmosphere 134 contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid involves buoyancy uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z135 3D SHELL AND TUBE HEAT EXCHANGER 135 contains PHOTON USE commands for displaying results uses neighbour patch name NE uses PLANT to create extra Fortran coding cartesian grid Q1 z136 FLOW IN A MODEL FURNACE 136 contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z137 CANOPY GENERATED SECONDARY FLOW 137 contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z138 VEHICULAR EXHAUST DISPERSION IN SNOW FAL contains PHOTON USE commands for displaying results NZ 1 two phase flow fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z139 FIRE INSIDE BUILDING ARRAY 139 contains PHOTON USE commands for displaying results fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z140 HEAT TRANSFER IN ABRUPT ENLARGEMENT AT P contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z141 EXHAUST DISPERSION IN THE STREET 141 contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z142 EXHUAST DISPERSION NEAR TOWER BLOCK 142 contains PHOTON USE commands for displaying results fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z143 PHASE DISTRIBUTION IN A DUCT 143 contains PHOTON USE commands for displaying results NX 1 two phase flow uses PLANT to create extra Fortran coding cartesian grid Q1 z144 ON LINE WIND TURBINES 144 contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z145 CO LOCATED VELOCITY CALCULATION 145 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z146 Slumping of a liquid column by SEM meth contains PHOTON USE commands for displaying results time dependent NX 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z147 WALL DISTANCE CALCULATOR 147 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z244 Laminar pipe flow with non linear resist contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z250 Flow straightened by vanes resistances contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z251 Steady lam fl prop const 1 y 0 2 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z252 4fl fl prp rconst 1 mconst 0 5 contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z350 VENTS LINKED TO REMOTE DETECTOR contains PHOTON USE commands for displaying results time dependent NZ 1 computes heat transfer involves buoyancy uses PLANT to create extra Fortran coding cartesian grid Q1 z450 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z451 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z452 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z453 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z454 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z455 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z456 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z457 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z458 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z459 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z500 3D grid of star shaped cross section contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z501 3D corrugated circular pipe contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z502 3D S shaped circular pipe contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z503 3D helically coiled pipe contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z504 Epicycloidal pipe contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z505 3D hypocycloidal beam contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z506 3D periodically enlarged pipe contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z507 3D snail like chamber contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z508 3D hill like shell contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z509 3D igloo contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z510 3D chamber with cut cylinder contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z511 2D zigzag channel contains PHOTON USE commands for displaying results NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z512 2D periodically broken channel contains PHOTON USE commands for displaying results NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z513 2D converging diverging channel contains PHOTON USE commands for displaying results NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z514 Viscous flow in converging diverging ch contains PHOTON USE commands for displaying results NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z515 Flow in gradually corrugated channel contains PHOTON USE commands for displaying results time dependent NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z601 Drilling star shaped space contains PHOTON USE commands for displaying results body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z602 DRILling BOX CARTES T contains PHOTON USE commands for displaying results time dependent uses PLANT to create extra Fortran coding cartesian grid Q1 z603 DRILling CYLINDER CARTES F contains PHOTON USE commands for displaying results time dependent cylindrical grid uses PLANT to create extra Fortran coding Q1 z604 HEXAGON 2D SFT ANALYSIS FOR A MODEL contains PHOTON USE commands for displaying results NZ 1 solves for LTLS computes WALL DISTANCE computes heat transfer uses PLANT to create extra Fortran coding computes stresses and strains in solids material indices set via SPEDAT cartesian grid Q1 z605 Five examples initialization box contains PHOTON USE commands for displaying results fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding cartesian grid Q1 z607 Analytical BFC grids 2D sample kit contains PHOTON USE commands for displaying results time dependent NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z608 Analytical BFC grids 3D sample kit contains PHOTON USE commands for displaying results time dependent body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z609 Gradually corrugated channel contains PHOTON USE commands for displaying results time dependent NZ 1 body fitted coordinates uses PLANT to create extra Fortran coding cartesian grid Q1 z610 Unsteady mixing in two paddle stirred r contains PHOTON USE commands for displaying results time dependent NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z611 2D Stress in solid XY plane contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z612 SQUARE CAVITY WITH MOVING LID Z100 contains PHOTON USE commands for displaying results NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z613 Global and self steering under relaxatn contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z614 Conjugate heat transfer of rotating obj contains PHOTON USE commands for displaying results cylindrical grid NZ 1 uses PLANT to create extra Fortran coding Q1 z615 Inlet flux scaling swirling flow in a c contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z616 CONFINED JET FLOW 17 FLUID MFM contains PHOTON USE commands for displaying results cylindrical grid NX 1 uses PLANT to create extra Fortran coding Q1 z617 2dxy uniform heating contains PHOTON USE commands for displaying results computes heat transfer uses PLANT to create extra Fortran coding contains lines to be read by EARTH via READQ1 computes stresses and strains in solids material indices set via SPEDAT cartesian grid Q1 z618 Block passing through orifice contains PHOTON USE commands for displaying results time dependent NZ 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z619 TIME STEP CALCULATIONS time dependent uses PLANT to create extra Fortran coding cartesian grid Q1 z620 Idealised Gas Turbine Combustion Chamber contains PHOTON USE commands for displaying results cylindrical grid uses SCRS option for density fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding contains lines to be read by EARTH via READQ1 uses conjugate gradient solver contains properties set by In Form uses In Form STORED command contains sources set by In Form uses LONGNAME material indices set via SPEDAT Q1 z621 Alteration of convection fluxes contains PHOTON USE commands for displaying results uses PLANT to create extra Fortran coding cartesian grid Q1 z622 Expanding and contracting the grid contains PHOTON USE commands for displaying results NX 1 steady parabolic flow fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding cartesian grid Q1 z623 Plane Jet Mixing Length Model Para contains PHOTON USE commands for displaying results NX 1 steady parabolic flow Prndtl Mixing Length model uses PLANT to create extra Fortran coding cartesian grid Q1 z711 1D Fine coal particle combustion contains Autoplot USE commands for displaying results NX 1 NY 1 two phase flow uses SHADOW method of size calculation uses PLANT to create extra Fortran coding cartesian grid Q1 z712 Convection only steady combustion of CO contains Autoplot USE commands for displaying results NX 1 NY 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z713 Combustion of packed bed of coke contains Autoplot USE commands for displaying results NX 1 NY 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z714 Ore reduction in a packed bed contains Autoplot USE commands for displaying results NX 1 NY 1 uses PLANT to create extra Fortran coding cartesian grid Q1 z721 Combustion driven coke flow contains PHOTON USE commands for displaying results cylindrical grid NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT Q1 z722 Fines and coke combustion driven solid f contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z723 Combustion fusion driven solid flow contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z731 Combustion melting driven ore coke mixtu contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z741 Combustion driven raceway coal fines an contains PHOTON USE commands for displaying results NX 1 two phase flow uses SHADOW method of size calculation uses PLANT to create extra Fortran coding cartesian grid Q1 z742 Coal fines flame in a coke bed raceway contains PHOTON USE commands for displaying results NX 1 two phase flow uses SHADOW method of size calculation uses PLANT to create extra Fortran coding cartesian grid Q1 z751 SAFIR 2D blast furnace model contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z761 System level coke combustion simulation contains PHOTON USE commands for displaying results NX 1 fiinit prps 1 so use PIL properties for domain fluid uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z762 Environmental level coke combustion simu contains PHOTON USE commands for displaying results NZ 1 fiinit prps 1 so use PIL properties for domain fluid involves buoyancy uses PLANT to create extra Fortran coding material indices set via SPEDAT cartesian grid Q1 z763 Melting of solid flow contains PHOTON USE commands for displaying results cylindrical grid NX 1 fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT advanced radiation Q1 r100 CVD REACTOR RADIATION EXAMPLE R100 contains PHOTON USE commands for displaying results NZ 1 computes heat transfer material indices set via SPEDAT cartesian grid Q1 r101 CVD REACTOR RADIATION EXAMPLE BFC R101 contains PHOTON USE commands for displaying results NZ 1 body fitted coordinates computes heat transfer material indices set via SPEDAT cartesian grid Q1 r102 LAMINAR FLOW BETWEEN PARALLEL PLATE R102 contains Viewer USE commands for displaying results contains Autoplot USE commands for displaying results NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r103 TURB FLOW BETWEEN PARALLEL PLATE R103 contains Viewer USE commands for displaying results contains Autoplot USE commands for displaying results NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r105 1 D Y DIRECTION SHELL SURFACE R105 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r107 1 D Y DIRECTION SOLID SURFACE R107 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid star name patch source CO PHI NAME VAL material indices set via SPEDAT cartesian grid Q1 r108 1 D Y DIRECTION SHELL SURFACE R108 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r111 1 D FIXED SURFACE TEMPERATURE R111 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r113 1 D FIXED FLUX FLUID SURFACE R113 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r114 1 D FIXED FLUX SOLID SURFACE R114 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r115 1 D CARTESIAN Y DIRECTION R115 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r116 1 D SOLID FLUID SOLID SET UP R116 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r118 1 D THIN PLATE R118 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid cartesian grid Q1 r119 1 D TRANSIENT R119 contains Viewer USE commands for displaying results contains Autoplot USE commands for displaying results time dependent NX 1 NZ 1 computes heat transfer fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r120 SQUARE CAV WITH MOVING LID RADI R120 contains PHOTON USE commands for displaying results NZ 1 computes heat transfer material indices set via SPEDAT cartesian grid Q1 r121 1D RADIATIVE EQUILIBRIUM IN SLAB 121 contains Autoplot USE commands for displaying results NX 1 NZ 1 cartesian grid Q1 r122 1D RADIATION HEAT SOURCE IN A SLAB 122 contains Autoplot USE commands for displaying results NX 1 NZ 1 cartesian grid Q1 r123 1D RADIATION HEAT SOURCE IN A TUBE 123 contains Autoplot USE commands for displaying results cylindrical grid NX 1 NZ 1 Q1 r124 BFC RADIATION HEAT SOURCE IN A TUBE 124 contains Autoplot USE commands for displaying results NX 1 body fitted coordinates fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r125 BFC RADIATION HEAT SOURCE IN A SLAB 125 contains PHOTON USE commands for displaying results NX 1 body fitted coordinates cartesian grid Q1 r190 Gateway to IMMERSOL library cases NX 1 NY 1 NZ 1 cartesian grid Q1 r193 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r194 No title has been set for this run NZ 1 cartesian grid Q1 r195 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r196 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r197 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r198 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r199 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r200 No title has been set for this run NX 1 NY 1 NZ 1 cartesian grid Q1 r201 IMMERSOL 1D transparent medium 201 contains Autoplot USE commands for displaying results NX 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL material indices set via SPEDAT cartesian grid Q1 r202 IMMERSOL 1D Radiative equilibrium 202 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL material indices set via SPEDAT cartesian grid Q1 r203 IMMERSOL 1D Radiative equilibrium 203 contains Autoplot USE commands for displaying results NX 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r204 2D TEM1 T3 Participating gas contains PHOTON USE commands for displaying results NX 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses In Form STORED command material indices set via SPEDAT cartesian grid Q1 r205 3D TEM1 T3 Participating ideal gas 2 contains PHOTON USE commands for displaying results computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL material indices set via SPEDAT cartesian grid Q1 r206 IMMERSOL WALL 1D for TEM1 T3 206 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL cartesian grid Q1 r207 IMMERSOL WALL 1D for H1 T3 207 contains Autoplot USE commands for displaying results NX 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses In Form STORED command cartesian grid Q1 r208 IMMERSOL 1D fixed flux through domain contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL cartesian grid Q1 r209 2D radiative heat exchange TEM1 T3 209 contains PHOTON USE commands for displaying results NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses In Form STORED command material indices set via SPEDAT cartesian grid Q1 r210 2D radiative heat exchange H1 T3 210 contains PHOTON USE commands for displaying results NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid material indices set via SPEDAT cartesian grid Q1 r211 2D radiative heat exchange SCRS 211 contains PHOTON USE commands for displaying results NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses SCRS option for density fiinit prps 1 so use PIL properties for domain fluid chemical sources with eddy break up model material indices set via SPEDAT cartesian grid Q1 r212 IMMERSOL SCRS 2D model of burner 212 contains PHOTON USE commands for displaying results cylindrical grid NX 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL Q1 is used as PROPS file via MATFLG entries chemical sources with eddy break up model uses In Form STORED command material indices set via SPEDAT Q1 r213 IMMERSOL SCRS 2D model of burner 213 contains PHOTON USE commands for displaying results cylindrical grid NX 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL Q1 is used as PROPS file via MATFLG entries chemical sources with eddy break up model uses In Form STORED command material indices set via SPEDAT Q1 r214 IMMERSOL SCRS 2D model of burner 214 contains PHOTON USE commands for displaying results cylindrical grid NX 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL Q1 is used as PROPS file via MATFLG entries chemical sources with eddy break up model uses In Form STORED command material indices set via SPEDAT Q1 r220 IMMERSOL empty box fixed wall temps contains PHOTON USE commands for displaying results NZ 1 computes WALL GAP solves for LTLS computes WALL DISTANCE activates IMMERSOL material indices set via SPEDAT cartesian grid Q1 r221 IMMERSOL 1D between thick conducting wal contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses In Form STORED command material indices set via SPEDAT cartesian grid Q1 r222 IMMERSOL 1D Radiative equilibrium 202 contains Autoplot USE commands for displaying results NX 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses In Form STORED command material indices set via SPEDAT cartesian grid Q1 r230 No title has been set for this run NY 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r231 No title has been set for this run NY 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r232 No title has been set for this run NX 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r233 No title has been set for this run NX 1 NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r234 No title has been set for this run NX 1 NY 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r235 No title has been set for this run NX 1 NY 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r236 No title has been set for this run NY 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r237 No title has been set for this run NY 1 NZ 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r238 No title has been set for this run NY 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r239 No title has been set for this run NY 1 NZ 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r240 No title has been set for this run NY 1 NZ 1 computes heat transfer solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r241 No title has been set for this run NY 1 NZ 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r242 No title has been set for this run NZ 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r243 No title has been set for this run NZ 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r244 No title has been set for this run NX 1 NY 1 solves for LTLS computes heat transfer computes WALL DISTANCE computes WALL GAP activates IMMERSOL fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r245 No title has been set for this run NX 1 computes WALL DISTANCE computes WALL GAP activates IMMERSOL computes heat transfer solves for LTLS uses ideal gas law for density Prndtl Mixing Length model fiinit prps 1 so use PIL properties for domain fluid FLAIR for heat and air flow in buildings uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r333 No title has been set for this run contains PHOTON USE commands for displaying results NX 1 NY 1 NZ 1 computes heat transfer material indices set via SPEDAT cartesian grid Q1 r400 IMMERSOL for heat treatment furnace contains PHOTON USE commands for displaying results NY 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL computes heat transfer fiinit prps 1 so use PIL properties for domain fluid uses In Form STORED command material indices set via SPEDAT cartesian grid Q1 r401 A Radiant Heater Panel contains PHOTON USE commands for displaying results NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL computes heat transfer fiinit prps 1 so use PIL properties for domain fluid uses dat file for VR object material indices set via SPEDAT uses In Form STORED command cartesian grid Q1 r402 Buoyancy induced cooling of a radiating NZ 1 solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL computes heat transfer fiinit prps 1 so use PIL properties for domain fluid involves buoyancy uses dat file for VR object material indices set via SPEDAT cartesian grid Q1 r403 Heat treatment in a direct fired furnace contains PHOTON USE commands for displaying results contains Viewer USE commands for displaying results solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses SCRS option for density chemical sources with eddy break up model uses dat file for VR object material indices set via SPEDAT uses In Form STORED command cartesian grid Q1 r404 Thermal radiation in a compartment fire contains PHOTON USE commands for displaying results contains Viewer USE commands for displaying results solves for LTLS computes WALL DISTANCE computes WALL GAP activates IMMERSOL uses SCRS option for density fiinit prps 1 so use PIL properties for domain fluid involves buoyancy uses dat file for VR object material indices set via SPEDAT uses In Form STORED command cartesian

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