q1ears

Core library
body-fitted coordinates
advanced chemistry
GENTRA (particle tracking)
multi-fluid turbulence
advanced multi-phase
advanced turbulence
multi-block and fine-grid embedding
two-phase flow
FLAIR (air and heat flow in buildings)
HOTBOX (electronics cooling)
advanced numerical algorithms
non-Newtonian
advance radiation
virtual reality
PLANT
stresses in solids
Chemical vapour deposition
Furnace
TACT: natural-draft cooling towers
Miscellaneous special-purpose programs
Power Condensers
UnStructured PHOENICS - USP

Core library

Q1 100 3D Steady Heat Conduction In Cube
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ cartesian grid

Q1 102 3D Heat Cond, Slab-Wise Solver
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 103 3D Heat Cond. Gauss-Seidel Solver
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ uses Gauss-Seidel solver
___ cartesian grid

Q1 104 3D Unsteady Heat Cond. Thick Pipe
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid

Q1 105 1D TRANS FOR H1 WITH FLOW + SOURCE
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 106 Rad Transf From Hot Wall,TGAS=CST
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 109 1D Trans Laminar Flame Propagation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ chemical sources
___ cartesian grid

Q1 110 Trans Heat Conduction-Uniform Fin
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 111 Fin Non-Uniform Cross-Section
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 112 Fin Non-Uniform Conductivity
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 113 Fin Non-Uniform Specific Heat
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 114 Fin Non-Uniform Surface Coeff.
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 115 Pot. Flow; Perpendicular Plate
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ cartesian grid

Q1 116 Flow Over Double-Wedge Airfoil
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 117 Comp Flow Over Double-Wedge Airfoil
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 118 Transient Tunnel Heat Transfer
___ time-dependent
___ cylindrical grid
___ NX = 1
___ uses neighbour patch (name = NE...)

Q1 119 Wall Distance Distribution Within A Box
___ contains PHOTON USE commands for displaying results
___ computes WALL DISTANCE
___ computes WALL GAP
___ solves for LTLS
___ cartesian grid

Q1 120 Pipe Flow; Effect Of Prandtl No.
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 121 2DXZ Duct Flow; Effect Of Pr No.
___ NY = 1
___ steady parabolic flow
___ cartesian grid

Q1 122 Pipe Flow With Axial Free Convec
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy

Q1 123 Water In A Heated Aluminium Pipe
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 124 Internally-Finned Pipe; Laminar
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ steady parabolic flow

Q1 125 Free Convection In Horizontal Pipe
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ steady parabolic flow
___ involves buoyancy

Q1 126 Pot. Flow; Inclined Plate
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for VELOCITY POTENTIAL
___ contains sources set by In-Form
___ cartesian grid

Q1 127 Irrotational Flow; Inclined Plate
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 128 F-1 Car; Balsa Wood Blank; Pot. Flow
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 129 Pot. Flow; In-Form-Created Source-Sink
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ contains sources set by In-Form
___ cartesian grid

Q1 130 Steady laminar rotating-disc flow
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ uses In-Form STORED command

Q1 133 Case 123 With Mercury, Not Water
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 134 Case 123 With Freon, Not Water
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 135 2D Laminar B-Layer On A Hot Wall
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 136 Free Convec From Hot Vertical Wall
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ involves buoyancy
___ In-Form sets the z-direction grid
___ cartesian grid

Q1 137 Free Convec From Plate In Cross Flow
___ steady parabolic flow
___ involves buoyancy
___ cartesian grid

Q1 138 3D Boundary Layer In A Corner
___ contains PHOTON USE commands for displaying results
___ steady parabolic flow
___ cartesian grid

Q1 140 Case 123 With Steel, Not Aluminium
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 141 Case 123 With Glass, Not Aluminium
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 142 Case 123 With LVEL Model
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ material indices set via SPEDAT

Q1 143 Case 123 In Parabolic Mode
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ computes heat transfer
___ material indices set via SPEDAT

Q1 144 Case 142, Parabolic, With Glass
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ material indices set via SPEDAT

Q1 145 Residence-Time Demonstration
___ time-dependent
___ NZ = 1
___ uses density linear in 1/Tabs
___ material indices set via SPEDAT
___ cartesian grid

Q1 150 Plane Jet;Mixing Length Model;Para
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 151 Plane Jet;K-L Turbul Model;Para
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 152 Plane Jet; K-E Turbu Model; Para
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 153 Round Jet;Mixing Length Model;Para
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model

Q1 154 Round Jet; K-L Turbu Model; Parab
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 155 Round Jet; K-E Turbu Model; Parab
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 156 Inclined Supersonic Flow In A Duct
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 157 2D CHANNEL FLOW - NEWTONIAN FLUID
___ NX = 1
___ cartesian grid

Q1 158 2D Flow In A Supersonic Diffuser
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 159 2D Sonic Underexpanded Round Jet
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses ideal-gas law for density

Q1 160 2D SUPERSONIC UNDEREXPANDED ROUND JET:16
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses ideal-gas law for density

Q1 161 2D Supersonic Rocket Exhaust Plume
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses ideal-gas law for density

Q1 162 gas-release with wind angle = 0.785398
___ contains Viewer USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses In-Form BOX function
___ cartesian grid

Q1 163 Steady conduction in electrically-heated
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 170 Channel Flow; Mixing-Length Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 171 Channel Flow K-L Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 172 Channel Flow K-EPS Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 173 Pipe Flow M-Length Turb Model;Para
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model

Q1 174 Pipe Flow K-L Model;Parabolic
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 175 Pipe Flow K-E Turbul Model;Parab
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 176 Channel Flow K-EPS Turblnc. Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ cartesian grid

Q1 190 Boundary Layer Mixing-Length Model
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 191 Boundary Layer K-L Turbulen Model
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 192 Boundary Layer K-E Turbulen Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 193 Wall Jet K-E Turbu Model; Parab
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 198 PHOENICS-Letter Masking, CHAM
___ contains PHOTON USE commands for displaying results
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ uses per-cent patch for masking
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 199 PHOENICS-Letter Masking, LOGO
___ contains PHOTON USE commands for displaying results
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ involves buoyancy
___ uses per-cent patch for masking
___ material indices set via SPEDAT
___ cartesian grid

Q1 200 PARALLEL PHOENICS-Letter Masking Feature
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ involves buoyancy
___ uses per-cent patch for masking
___ material indices set via SPEDAT
___ cartesian grid

Q1 210 1D Hydrostatic; X-Direction
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 213 Hydrostatic Equil In Annular Cav.
___ cylindrical grid
___ NZ = 1
___ involves buoyancy

Q1 215 1D Venturi, Y-Direction
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 217 1D 30-Degree X-Direction Diffuser
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 218 1D Y; Test of u1*r = constant
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 219 1D Y; test of u/r = constant
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 220 Free Vortex In 2 Dimensions
___ cylindrical grid
___ NZ = 1

Q1 221 Rectilinear Flow In Polar Quadrant
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1

Q1 222 Jet Injection Into Polar Grid
___ cylindrical grid
___ NZ = 1

Q1 223 2 Quadrant Polar Wind Flow
___ cylindrical grid
___ NZ = 1

Q1 224 Polar Wind 360 Degree
___ cylindrical grid
___ NZ = 1

Q1 225 2D Flow Over A Cylinder Polar Grid
___ cylindrical grid
___ NZ = 1

Q1 226 2D Flow Over A Cylinder K-E Model
___ cylindrical grid
___ NZ = 1

Q1 227 Forced Vortex In A Pipe - Inviscid
___ cylindrical grid

Q1 228 Viscous Heating In Couette Flow
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 229 Viscous Heating In An Annulus
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 230 Decay Of Turbulence. K-Epsilon Model
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 233 2DY-Directed Free Vortex Test
___ cylindrical grid
___ NZ = 1

Q1 234 De Laval Nozzle X Direction
___ NY = 1
___ NZ = 1
___ uses isentropic-gas law for density
___ cartesian grid

Q1 237 Shallow Sample Cup In Crosswind
___ cylindrical grid

Q1 238 Shallow Sample Cup In Crosswind
___ cylindrical grid

Q1 240 2D Channel Flow
___ NX = 1
___ cartesian grid

Q1 241 2D Restricted Inlet/Outlet Channel
___ NX = 1
___ cartesian grid

Q1 242 Supersonic Flow In Duct
___ NZ = 1
___ uses isentropic-gas law for density
___ cartesian grid

Q1 243 Transonic Flow In A Curved Duct
___ cylindrical grid
___ NZ = 1
___ uses isentropic-gas law for density

Q1 244 Heat Transfer In Pipe; Pr No Effect
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 245 Heat Trans In Pipe;Pr.Effect;WHL-P
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 246 Abrupt Enlargement At Pipe Entra
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 247 Pipe With Internal Restriction
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 248 Area Restriction With Inlet Swirl
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 249 Square Cavity With Moving Lid
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses In-Form STORED command
___ cartesian grid

Q1 250 2D Low-Re Flow Past A Plate
___ NX = 1
___ cartesian grid

Q1 251 Laminar Free Convection In Cavity
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ involves buoyancy
___ uses EXPERT dynamic relaxation
___ cartesian grid

Q1 252 Steady Free-Convection In Annular Cavity
___ cylindrical grid
___ NZ = 1
___ involves buoyancy

Q1 253 Benard Convection
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ involves buoyancy
___ uses conjugate-gradient solver
___ cartesian grid

Q1 254 Free Convection Between Vertical Plates
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 255 Potential Flow over Perpendicular Plate
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ darcy flow in porous medium
___ cartesian grid

Q1 256 Steady Free-Convec In Calandria
___ cylindrical grid
___ NZ = 1
___ involves buoyancy

Q1 257 Laminar Free Convection In Cavity
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ involves buoyancy
___ uses EXPERT dynamic relaxation
___ uses conjugate-gradient solver
___ cartesian grid

Q1 260 Conjugate Heat Transf In Air Flow
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses volumetric block correction
___ cartesian grid

Q1 261 Conjugate Heat Transf In Air Flow
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses volumetric block correction
___ cartesian grid

Q1 262 Conjugate Heat Transfer Problem 2
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses volumetric block correction
___ cartesian grid

Q1 263 Conjugate Heat Transfer Problem 3
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses volumetric block correction
___ cartesian grid

Q1 264 Conjugate Heat Transfer Problem 4
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses volumetric block correction
___ cartesian grid

Q1 270 Impinging Jet In Rectangular Grid
___ cartesian grid

Q1 271 Flow Around A Chimney
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 272 Steady Journal-Bearing Flow, 3D
___ solves for LTLS
___ computes WALL DISTANCE
___ cartesian grid

Q1 273 Mixing At A T-Junction
___ cylindrical grid

Q1 274 3D Nav.Sto.Flow Around A Moving Van
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 275 "Darcy Flow" Around A Moving Van
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ darcy flow in porous medium
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 276 Potential Flow Around A Moving Van
___ contains PHOTON USE commands for displaying results
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 277 Cubical Cavity With Moving Lid
___ contains PHOTON USE commands for displaying results
___ uses EXPERT dynamic relaxation
___ uses conjugate-gradient solver
___ cartesian grid

Q1 278 Laminar Natural Convec In A Cavity
___ involves buoyancy
___ uses conjugate-gradient solver
___ cartesian grid

Q1 280 Turbulent Pipe Flow; Pr. No. Effect
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model

Q1 281 Ricou's Jet In Cylindrical Chamber
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ Prndtl Mixing-Length model
___ Two-scale high-Re model

Q1 289 LVEL model; EGWF= T
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 290 KE-EPS model; Re = 4.5E+04; EGWF= F
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 291 Cav. Flow K-EPS Turbu Model;Ellip
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 292 2D Pipe Flow K-E Model; Re=8.327646E+04
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1

Q1 293 Simple Labyrinth; Q1 Made By Menu
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 294 Simple Labyrinth; Heavy Relaxation
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 295 Simple Labyrinth; Expert Relaxation
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses EXPERT dynamic relaxation
___ material indices set via SPEDAT
___ cartesian grid

Q1 296 2D Turbulent Free Convection In A Cavity
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ uses density linear in 1/Tabs
___ Lam=Bremhorst-Re model
___ involves buoyancy
___ cartesian grid

Q1 297 2D Rayleigh-Benard Convection
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ cartesian grid

Q1 298 Test case for rotating grid
___ cylindrical grid
___ uses ROTOR VR Object
___ uses In-Form STORED command
___ contains initial values set by In-Form

Q1 300 Backward-Facing STP KE MDL Y-X POS
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 320 Temporal Decay Of Turbu; K-E Model
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 321 Pressure Waves From Valve Closure
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 322 Laminar Flow In Pipe-Transient
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1

Q1 323 Central Obstacle In Laminar Pipe
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1

Q1 324 Pipe; Outlet Restriction Added
___ time-dependent
___ cylindrical grid
___ NX = 1

Q1 325 Obstacle,Outlet Restriction And Cart
___ time-dependent
___ NX = 1
___ cartesian grid

Q1 326 Vortex Near A Moving Wall
___ time-dependent
___ NZ = 1
___ cartesian grid

Q1 327 0D Piston-In-Cylinder Study
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses isentropic-gas law for density
___ cartesian grid

Q1 328 1D Piston-With-Bowl Study
___ time-dependent
___ NX = 1
___ NY = 1
___ uses isentropic-gas law for density
___ cartesian grid

Q1 329 1D Piston With Bowl; High Speed
___ time-dependent
___ NX = 1
___ NY = 1
___ uses isentropic-gas law for density
___ cartesian grid

Q1 330 Case 1 AXI-Symmetric Piston Bowl
___ time-dependent
___ cylindrical grid
___ NX = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 331 Two Stroke Loop Scavenge Cycle 3D
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ uses ideal-gas law for density

Q1 332 Shock Tube
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 333 Shock Tube With 2D Obstacle
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 334 Spherical Blast Wave
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 335 1D Transient Shock Tube
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND convgr
___ cartesian grid

Q1 340 Transient Free Convection In A Box
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ involves buoyancy
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 341 Rayleigh-Taylor Instability
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ involves buoyancy
___ cartesian grid

Q1 342 HYD. EQ. In XY Tank With Blockages
___ time-dependent
___ NZ = 1
___ cartesian grid

Q1 343 HYD. EQ. In YZ Tank With Blockages
___ time-dependent
___ NX = 1
___ cartesian grid

Q1 344 2DTrans Buoyant Flow Of Melt In A Ladle
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ involves buoyancy

Q1 345 3D Laminar Free Convection In A Cavity
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ involves buoyancy
___ contains properties set by In-Form
___ uses In-Form STORED command
___ In-Form STORED command uses SUM(
___ cartesian grid

Q1 350 Porous Plate (K-E
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ Chen-Kim high-Re model
___ material indices set via SPEDAT
___ plate porosity set via SPEDAT
___ cartesian grid

Q1 351 Porous Plate (Laminar
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT
___ plate porosity set via SPEDAT
___ cartesian grid

Q1 360 MOFOR by In-Form: 2D motion of 2 objects
___ contains PHOTON USE commands for displaying results
___ contains Viewer USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses MOFOR
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 362 Slabwise-averaging and display
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ computes heat transfer
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT
___ cartesian grid

Q1 363 Slabwise-averaging and display
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ computes heat transfer
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT
___ cartesian grid

Q1 364 ARR In-Form function
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses ideal-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains properties set by In-Form
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 365 MOFOR by In-Form: Underwater navigation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ uses MOFOR
___ uses In-Form STORED command
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 366 In-Form equivalent of library case 118
___ time-dependent
___ cylindrical grid
___ NX = 1
___ contains sources set by In-Form

Q1 367 In-Form equivalent of library case 790
___ NY = 1
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 368 In-Form equivalent of library case 791
___ time-dependent
___ NY = 1
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 369 Rotating coordinates
___ NZ = 1
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 370 MOFOR - In-Form: BOX linear motion in Z
___ time-dependent
___ NX = 1
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 371 MOFOR - In-Form: BOX linear motion in Y
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 372 MOFOR - In-Form: BOX linear motion in X-
___ time-dependent
___ NY = 1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 373 MOFOR - In-Form: BOX linear motion X-dir
___ time-dependent
___ NX = 1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 374 Rotating coordinates
___ NZ = 1
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 375 MOFOR/In-Form: diagonal motion in XY
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 376 MOFOR/In-Form: diagonal motion in YZ
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 377 MOFOR/In-Form: diagonal motion in XZ
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 378 MOFOR/In-Form: diagonal motion in XY
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 379 MOFOR/In-Form: diagonal motion in YZ
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 380 MOFOR/In-Form: diagonal motion in XZ
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 381 MOFOR by In-Form,CYLINDR object rotation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 382 MOFOR by In-Form: BOX object rotation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 383 Box-shaped In-Form object
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ uses In-Form BOX function
___ cartesian grid

Q1 384 ellipsoid-shaped In-Form object
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 385 sub-grid objects POINT, LINE and PLANE
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 386 sphere with centre at origin
___ uses In-Form SPHERE function
___ uses In-Form STORED command
___ cartesian grid

Q1 387 patch-limited objects
___ material indices set via SPEDAT
___ cartesian grid

Q1 401 Oil tanker rupture; warm-water layer eff
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses In-Form STORED command

Q1 402 Oil tanker rupture - Turbulent plume
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ contains sources set by In-Form
___ uses In-Form STORED command

Q1 413 Transient Radiation From Fin
___ time-dependent
___ NY = 1
___ NZ = 1
___ star-name patch: source=CO*PHI*NAME**VAL
___ contains lines to be read by EARTH via READQ1
___ cartesian grid

Q1 414 X-Spatial Decay Of Turbu, K-Omega
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 415 X-Spatial Decay Of Turbu, K-Vosq
___ NY = 1
___ NZ = 1
___ star-name patch: source=CO*PHI*NAME**VAL
___ cartesian grid

Q1 419 Swirling Flow Test, Inlet U1=1m/s
___ cylindrical grid

Q1 426 1DX Coal Combustion; Secondary Air
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 427 2DYZ Coal-Particle Combustion
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 429 1DY Oil-Droplet Combustion
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 434 0D Transient Reaction Rate
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 435 Gala Example 1D
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 436 Filling Of A 2d Duct - HOL Method
___ NY = 1
___ cartesian grid

Q1 437 Filling Of A 2D Duct - HOL Method
___ NX = 1
___ cartesian grid

Q1 439 Backward-Facing Step KE Mod YZ Pos
___ NX = 1
___ uses ideal-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 448 Vertical Chamber
___ cylindrical grid
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT

Q1 450 Rigid-Surface Flow, 3D Incompress
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 451 Rigid-Surface Flow, 3D Compress
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 452 Free Surface Flow, 3D Surface
___ contains PHOTON USE commands for displaying results
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 453 Free Surface Flow, 2D Incompressi
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 454 Free Surface Flow, 2D Shllw Water
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 455 Free Surface Flow, 3D, Submerged
___ contains PHOTON USE commands for displaying results
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 456 Rigid Surface, 3D, Submerged
___ contains PHOTON USE commands for displaying results
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 457 Variable Porosity, 2D
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 458 Variable Porosity, 3D
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 469 Temperature Solution Demonstration
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 470 Shallow-Water Waves After Exit Shut
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 471 Waves After Shutting Inlet And Outlet
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 472 Flow In Lake After Wind Stops
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 473 Non Unif.Depth Channel.Out.Closure
___ time-dependent
___ NY = 1
___ cartesian grid

Q1 474 Pollutant Flow In A Tidal Harbour
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 476
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 477
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 478
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 479
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 480 1DX Coal-Particle Combustion
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 481 1D Coal-Particle Combustion
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 482 1DZ Coal-Particle Combustion
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 483 1DX Coal-Particle Comb. Equvel=T
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ both phases have equal velocity components
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 484 1DY Coal-Particle Comb. Equvel=T
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ two-phase flow
___ both phases have equal velocity components
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 485 1DZ Coal-Particle Comb. Equvel=T
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ two-phase flow
___ both phases have equal velocity components
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 486 Test Of Whole Field Solver
___ cylindrical grid

Q1 487 Transient Dye Injection Into Steady Flow
___ time-dependent
___ cylindrical grid

Q1 488 Wave Propagation - 1D Scalar
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 489 Wave Propagation - 1D Scalar
___ time-dependent
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 490 Wave Propagation - 1D Scalar
___ time-dependent
___ NX = 1
___ NY = 1
___ cartesian grid

Q1 491 Simple chemical reaction (SCRS
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses SCRS option for density
___ chemical sources with eddy-break-up model
___ cartesian grid

Q1 492 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
___ contains lines to be read by EARTH via READQ1
___ 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 493
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 494 3D Radiant Heat Transfer In A Box
___ computes heat transfer
___ cartesian grid

Q1 495 Radiative Transfer + Heat Source
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 498 X-D Radiative Equilibrium In Slab
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 500 1D Laminar Pipe Flow And Heat Trans
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ uses fully-developed-flow option

Q1 501 1D Laminar Pipe Flow And Mass Trans
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ uses fully-developed-flow option

Q1 502 1D Turb Pipe Flow + Heat Trans
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ uses fully-developed-flow option

Q1 503 2D Laminar Duct Flow And Heat Trans
___ NZ = 1
___ uses fully-developed-flow option
___ cartesian grid

Q1 504 2D Turb Duct Flow And Heat Trans
___ NZ = 1
___ uses fully-developed-flow option
___ cartesian grid

Q1 505 1D Lam Couette Flow And Heat Trans
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ NZ = 1
___ cartesian grid

Q1 506 1D Laminar MHD Channel Flow
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ uses fully-developed-flow option
___ cartesian grid

Q1 507 1D Laminar MHD Couette Flow
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ NZ = 1
___ cartesian grid

Q1 510 Power-Law Fluid FD Lam Pipe Flow
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option

Q1 511 Bingham-Fluid FD Lam Pipe Flow
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option

Q1 512 Power-Law Fluid_2D FD Duct Flow
___ NZ = 1
___ uses fully-developed-flow option
___ cartesian grid

Q1 513 Powre-Law_2D Fluid Ellip. Lam Pipe
___ cylindrical grid
___ NX = 1

Q1 514 Bingham Fluid_2D Ellip. Lam Pipe
___ cylindrical grid
___ NX = 1

Q1 520 Link Test In YZ Plane; 2 Dummy Cells
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ uses link patch
___ cartesian grid

Q1 521 Y-Direction Link In XY Plane
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ uses link patch

Q1 522 Y-Direction Link In XY; Xcycle=t
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ uses link patch

Q1 523 East-West Link Test In X-Y Plane
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses link patch
___ cartesian grid

Q1 524 Duct With 2 Side Branches;XYplane
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses link patch
___ cartesian grid

Q1 525 Multi-Blocking By Shear, XY Plane
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses link patch
___ material indices set via SPEDAT
___ cartesian grid

Q1 526 Rotating Inner And Fixed Outer Grid
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NZ = 1
___ uses link patch

Q1 530 Influences On Convergence; Steady
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 531 Influences On Convergence; Transient
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 550 1D Radiant Heat Transfre In A Box
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 551 2D Radiant Heat Transfer In A Box
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 552 3D Radiant Heat Transfer In A Box
___ contains PHOTON USE commands for displaying results
___ cartesian grid

Q1 553 3D Radiant Heat Transfer In A Box
___ contains PHOTON USE commands for displaying results
___ cartesian grid

Q1 565 Air-Cooled Electric-Motor Sector
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ computes heat transfer
___ material indices set via SPEDAT

Q1 566 3D Steady Heat Conduction In Cube
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ star-name patch: source=CO*PHI*NAME**VAL
___ material indices set via SPEDAT
___ cartesian grid

Q1 567 GXTIM Example
___ time-dependent
___ NX = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 568 Expert Test-The Driven-Cavity Flow
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses In-Form STORED command
___ cartesian grid

Q1 571 GAS_AT_REST._SUDDEN_SUSTAINED_ENTRY_FROM
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 572 Rect Cav With Moving Lid;Heat Tran
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 575 2D Channel Flow Newtonian Fluid
___ NX = 1
___ cartesian grid

Q1 576 2D Channel Flow;Non Newtonian Fluid
___ NX = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 577 Counter Flow Demo
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ material indices set via SPEDAT

Q1 601 3D Heat Cond. Conjug.Grad. Solver
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ uses conjugate-gradient solver
___ cartesian grid

Q1 602 Pot. Flow Around Van; CNGR. Solver
___ contains PHOTON USE commands for displaying results
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 603 Pot. Flow; Perp. Plate; Conj.GR.
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ uses conjugate-gradient solver
___ cartesian grid

Q1 604 Diffuser ; Effect Of Prandtl No.
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow

Q1 605 Fully-Developed Flow; K-EPS Model
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 606 Buoyant Plume in tunnel, 1.0E+06 Cells
___ contains PHOTON USE commands for displaying results
___ steady parabolic flow
___ involves buoyancy
___ cartesian grid

Q1 607 Flow Around A Group Of Buildings
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 608 Free Convectn And Radiatn Heat Sink
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ involves buoyancy
___ star-name patch: source=CO*PHI*NAME**VAL
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 610 2D Laminar Air-Water Bound. Layer
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 611 Secondary Flow In Curved Duct
___ contains PHOTON USE commands for displaying results
___ cylindrical grid

Q1 612 Conduction In Cube; Expert
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ cartesian grid

Q1 613 Heat Sources; Air-Cooled Box; EGWF
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 614 Flow Of Glass In T-shaped Channel
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 615 Potl. 2D Flow; Source-Sink Pair
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ uses conjugate-gradient solver
___ cartesian grid

Q1 616 Potl. 2D Flow; Source-Sink Pair
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ uses conjugate-gradient solver

Q1 617 1D Ignition And Extinction
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ chemical sources
___ cartesian grid

Q1 620 Case 100; Various Solver Options
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ cartesian grid

Q1 621 Simulation of a Labyrinth Flow
___ NY = 1
___ computes heat transfer
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 622 Domain faces and Duplication in VRE
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 623 Flow between cylindrical obstacles
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 624 Array and group settings
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 625 Fans and Inlets
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 626 Jetpump
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 627 Flow simulation in a pipe
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 628 Flow around buildings
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 629 Flow over heated bricks
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 630 Introducing contaminants
___ NY = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 631 Editing properties
___ NY = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 632 Duct at 30 degree to the horizontal
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 633 Transient Heat Conduction
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ cartesian grid

Q1 634 Transient Heat Conduction
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 635 Complete Diaphragm Rupture
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 636 Partial Diaphragm Rupture
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 637 2D Axi-Symmetrical Jet Pump
___ cylindrical grid
___ NX = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 638 Swirling flow through an orifice plate
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 639 Swirling flow through an orifice plate
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 640 A duct flow (Immersol)
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 641 Electronic box
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 642 Combustion SCRS
___ cylindrical grid
___ uses SCRS option for density
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ chemical sources with eddy-break-up model
___ material indices set via SPEDAT

Q1 643 ESCRS - Fast Chemistry
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ Chen-Kim high-Re model
___ uses extended SCRS

Q1 644 Combustion: CHEMKIN
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ uses CHEMKIN option for density
___ Constant-effective-viscosity model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 645 KE-EPS model; Re = 45000.00; EGWF= T
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 646 RNG model; Re = 45000.00; EGWF= T
___ NZ = 1
___ RNG high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 647 KECHEN model; Re = 45000.00; EGWF= T
___ NZ = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 648 Simple Labyrinth; LVEL model
___ NZ = 1
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 649 2PHS model; Re = 45000.00; EGWF= T
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 651 Boiling in a pipe (IPSA)
___ cylindrical grid
___ NX = 1
___ two-phase flow
___ Chen-Kim high-Re model
___ involves buoyancy

Q1 652 Flow over a backward-facing step (VOF)
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 653 Water pouring into a bund
___ time-dependent
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 654 Droplet falling over wedge - VOF
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 655 Flow in a separator ASM
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 656 Shallow water IN TURNAROUND DUCT: B
___ NX = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 657 A whirlpool in a shallow pond
___ NX = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 658 Inform: Inlet boundary layer profile
___ NY = 1
___ MMK high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 659 2D Warehouse Example
___ NY = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 660 Inlet flow normal to cylinder surface
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 661 Simulation of a Labyrinth Flow
___ NY = 1
___ computes heat transfer
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 662 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 663 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 664 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 665 Flow around buildings
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ cartesian grid

Q1 667 3D Nav.Sto.Flow Around A Moving Van
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form
___ cartesian grid

Q1 668 My first flow simulation
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 669 My first flow simulation
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 670 My first flow simulation
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 671 Linked Angled-in objects
___ NY = 1
___ computes heat transfer
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 672 3D Nav.Sto.Flow Around A Moving Van
___ contains Viewer USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT
___ cartesian grid

Q1 673 Wind and Solar Heating Example
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ star-name patch: source=CO*PHI*NAME**VAL
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 674 Wind and Solar Heating Example
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ star-name patch: source=CO*PHI*NAME**VAL
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 675 Flow through a Forest
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 690 KE-EPS model; Re = 4.5E+04; EGWF= T
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 700 In-Form equivalent of PLANT case Z100
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains properties set by In-Form
___ uses LONGNAME
___ cartesian grid

Q1 701 In-Form equivalent of PLANT case Z101
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ contains properties set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ cartesian grid

Q1 702 In-Form equivalent of PLANT case Z102
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 703 Extract fin.-vol. equations and diffusio
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains properties set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ cartesian grid

Q1 704 2D UNSTEADY DIFFUSION PROBLEM:Z104
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses conjugate-gradient solver
___ contains initial values set by In-Form
___ time-dependent source set by In-Form
___ cartesian grid

Q1 705 In-Form equivalent of PLANT case Z106
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 706 In-Form equivalent of PLANT case Z106
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 707 decay of temp. profile in metal slab
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 708 In-Form equivalent of PLANT case Z108
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 709 In-Form equivalent of simplified PLANT c
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 710 3D SHELL-AND-TUBE HEAT EXCHANGER:110
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 711 In-Form equivalent of PLANT case Z111
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ time-dependent source set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 712 In-Form equivalent of PLANT case Z112
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 713 In-Form equivalent of PLANT case Z113
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains properties set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 717 In-Form equivalent of PLANT case Z117
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 718 In-Form equivalent of PLANT case Z118
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 719 In-Form equivalent of PLANT case Z119
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ time-dependent source set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 720 In-Form equivalent of PLANT case Z120
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 721 In-Form equivalent of PLANT case Z604
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 722 In-Form equivalent of PLANT case Z122
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 723 In-Form equivalent of PLANT case Z123
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ contains properties set by In-Form

Q1 724 In-Form equivalent of PLANT case Z124
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ contains sources set by In-Form

Q1 725 In-Form equivalent of PLANT case Z125
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ NY = 1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains properties set by In-Form
___ cartesian grid

Q1 726 In-Form equivalent of PLANT case Z126
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ contains sources set by In-Form
___ cartesian grid

Q1 727 In-Form equivalent of PLANT case Z127
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 729 In-Form equivalent of PLANT case Z129
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 731 In-Form equivalent of PLANT case Z131
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 733 In-Form equivalent of PLANT case Z133
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ uses SCRS option for density
___ contains sources set by In-Form

Q1 734 In-Form equivalent of PLANT case Z134
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 735 In-Form equivalent of PLANT case Z135
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 737 CAREY Oscillating water column
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ time-dependent source set by In-Form
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ contains properties set by In-Form
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 738 In-Form equivalent of PLANT case Z138
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 739 In-Form equivalent of PLANT case Z139
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 740 In-Form equivalent of PLANT case Z140
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ contains properties set by In-Form
___ uses LONGNAME

Q1 741 In-Form equivalent of PLANT case Z141
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains properties set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 742 In-Form equivalent of PLANT case Z142
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 743 p 1.0E+10 1.0E+05 u 1.0E+10 1.0E+10
___ time-dependent
___ NZ = 1
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT
___ cartesian grid

Q1 745 Non-uniform moving-wall velocity
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 746 Heat Transfer In Channel By In-Form.
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 747 Injection In Channel By In-Form.
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ cartesian grid

Q1 748 Wall-functions By In-Form.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 749 Shapes made bu sphere; caseno=1
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ uses In-Form SPHERE function
___ material indices set via SPEDAT
___ cartesian grid

Q1 750 In-Form equivalent of PLANT case Z244
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ contains sources set by In-Form

Q1 751 Steady lam. fl. propagation :751
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 752 In-Form equivalent of PLANT case Z132
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 753 Flow straightened by vanes + resistances
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ cartesian grid

Q1 754 Simple shapes by box In-Form object
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ computes heat transfer
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ uses In-Form BOX function
___ material indices set via SPEDAT
___ cartesian grid

Q1 756 Mixing caused by rotating paddle: 756
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ contains properties set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 757 Flow in stirred 3D vessel: 757
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ contains properties set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 758 Three examples of initialization :758
___ contains PHOTON USE commands for displaying results
___ contains initial values set by In-Form
___ cartesian grid

Q1 759 CO-LOCATED VELOCITY CALCULATION:759
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 760 In-Form Equivalent Of PLANT Case Z101
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ contains properties set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ cartesian grid

Q1 761 SATURATED_WATER
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ uses In-Form STORED command
___ contains properties set by In-Form
___ cartesian grid

Q1 762 3D moving-wall; fluid is AIR..277
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ uses conjugate-gradient solver
___ uses In-Form STORED command
___ contains properties set by In-Form
___ cartesian grid

Q1 763 3D SQUARE CAVITY; various fluids: 763
___ contains PHOTON USE commands for displaying results
___ uses conjugate-gradient solver
___ uses LONGNAME
___ uses In-Form STORED command
___ contains properties set by In-Form
___ cartesian grid

Q1 764 InForm Settings And Sources For Objects
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses conjugate-gradient solver
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 765 In-Form Represents Hot Moving Spheres
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ uses In-Form SPHERE function
___ contains sources set by In-Form
___ cartesian grid

Q1 766 2D Football Trajectory.
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses In-Form SPHERE function
___ contains sources set by In-Form
___ time-dependent source set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 767 3D football trajectory: 767
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ uses In-Form SPHERE function
___ time-dependent source set by In-Form
___ contains sources set by In-Form
___ uses In-Form STORED command
___ cartesian grid

Q1 768 3D heating spiral: 768
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ computes heat transfer
___ uses In-Form STORED command
___ uses In-Form SPHERE function
___ contains initial values set by In-Form
___ contains sources set by In-Form

Q1 769 In-Form makes pyramid: 3D
___ contains PHOTON USE commands for displaying results
___ uses In-Form BOX function
___ uses In-Form STORED command
___ cartesian grid

Q1 770 Unsteady mixing in two paddle-stirred r
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses In-Form STORED command
___ uses In-Form BOX function
___ contains sources set by In-Form
___ cartesian grid

Q1 771 Drilling of Pump chamber, BFC: 771
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses In-Form SPHERE function
___ contains initial values set by In-Form
___ cartesian grid

Q1 772 In-Form, sphere in polar coordinates: 77
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ uses In-Form SPHERE function
___ uses In-Form STORED command

Q1 773 Heat Conductivity: In-Form Source.
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 774 T-Junction: In-Form Source.
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 775 Flow In A Model Furnace: In-Form Source.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 776 In-Form equivalent of PLANT case Z623
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model
___ In-Form sets the z-direction grid
___ cartesian grid

Q1 777 In-Form equivalent of PLANT case Z622
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ In-Form sets the y-direction grid
___ cartesian grid

Q1 778 In-Form equivalent of PLANT case Z619
___ time-dependent
___ In-Form sets the "time grid"
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ cartesian grid

Q1 779 In-Form equivalent of PLANT case Z613
___ contains PHOTON USE commands for displaying results
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 780 In-Form equivalent of PLANT case Z604
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ computes stresses and strains in solids
___ contains properties set by In-Form
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 781 17-fluid turbulence model
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ contains sources set by In-Form
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ uses In-Form STORED command

Q1 782 In-Form equivalent of case 240
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 783 3D Piston by In-Form
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ uses ideal-gas law for density
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ uses In-Form BOX function
___ contains sources set by In-Form

Q1 784 Valve motion into 2D Chamber by In-Form
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses In-Form BOX function
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 785 In-Form equivalent of PLANT case Z615
___ contains PHOTON USE commands for displaying results
___ uses In-Form SPHERE function
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ uses In-Form STORED command
___ uses LONGNAME
___ contains sources set by In-Form
___ cartesian grid

Q1 786 In-Form equivalent of PLANT case Z350
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ involves buoyancy
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ contains sources set by In-Form
___ In-Form STORED command uses SUM(
___ uses LONGNAME
___ cartesian grid

Q1 787 TWO VESSELS BY IN-FORM
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses In-Form SPHERE function
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 788 Cubical Cavity With Moving Lid
___ contains PHOTON USE commands for displaying results
___ uses In-Form STORED command
___ cartesian grid

Q1 789 Shell-and-tube heat exchanger
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 790 Steady Counterflow Heat Exchanger
___ NY = 1
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 791 Transient Counterflow Heat Exchr.
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 792 791 + Allowance For Metal Capacity
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 793 Case 4 Steady Crossflow
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 794 Case 5 Transient Crossflow
___ time-dependent
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 795 Case 6; Allowance For Metal CP
___ time-dependent
___ NZ = 1
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 796 Case 7 3D Shell,Tube Heat Exchnger
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 797 Case 8; As For Case 7 But Trans
___ time-dependent
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 798 Case 9; Allowance For Metal Capac
___ time-dependent
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 799 Injection In Channel By In-Form.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ contains sources set by In-Form
___ cartesian grid

Q1 800 3D Shell and (1-pass) Tube Heat Exchange
___ contains PHOTON USE commands for displaying results
___ uses neighbour patch (name = NE...)
___ uses In-Form STORED command
___ contains properties set by In-Form
___ contains sources set by In-Form
___ uses LONGNAME
___ cartesian grid

Q1 801 Inclined Channel; 32,40,1 Grid
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 802 Flow around an inclined tube
___ contains Viewer USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 803 Turn-around duct; Fine Grid
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 804 Turn-Around Duct; 20*40 Grid
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 805 Sphere In A Uniform Stream; Re=40
___ contains Viewer USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 806 Diamond-Shaped Obstacle; 1,18,31 Grid
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 807 2 spheres Re=40. quarter=T finegrid=T
___ contains Viewer USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 808 Cylinder In Uniform Stream; 1,18,31 Grid
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 809 Skewed Box In Uniform Stream; 18,18,31 G
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 810 Free Convection In A Porous Medium
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ involves buoyancy

Q1 811 1D Darcy Flow With Heat Transfer
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses PLANT to create extra Fortran coding
___ cartesian grid

Q1 820 1D U1 Diffusion In An Annulus
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 821 1D U1 Diffusion In An Annulus;Rinner=0
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 822 1D U1 Diffusion In A Rotating Cylinder
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 823 1D U1 Diffusion In An Annulus;Omegi=0.
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 824 2D U1 Flow In An Annulus;Omegi=0.0
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NZ = 1

Q1 825 1D U1 Coriolis/Diffusion Test:Rinner.gt.
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 826 2D U1 Coriolis/Diffusion Test:Rinner.gt.
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NZ = 1

Q1 827 2D U1 Coriolis/Diffusion Test:Rinner=0
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 828 1D U1 Diffusion Of A Free Vortex
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 829 1D U1 Diffusion Of A Forced Vortex
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 830 1D U1 Diffusion Of A Combined Vortex
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 831 1D U1 Coriolis/Diff. Test:Rinner.gt.0 An
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1

Q1 832 2D U1 Coriolis/Diff. Test:Rinner.gt.0 An
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NZ = 1

Q1 833 2D 360 Deg Polar Wind Flow
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1

Q1 850 Longwell Bomb; X-Y Model
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ chemical sources

Q1 851 Steady 1D Flame Phenomena
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ chemical sources
___ cartesian grid

Q1 852 Spherical Flame Propagation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NZ = 1
___ chemical sources
___ involves buoyancy

Q1 853 SCRS Combustion In A Duct
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ uses SCRS option for density
___ cartesian grid

Q1 855 Transfer objects; 1d diffusion; 1st run.
___ NX = 1
___ computes heat transfer
___ cartesian grid

Q1 856 Transfer objects; 2d convection; 1st run
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ contains sources set by In-Form
___ cartesian grid

Q1 857 domain-partitioning technique. First run
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 858 ATMOSPHERIC B.L., first run
___ contains PHOTON USE commands for displaying results
___ contains sources set by In-Form
___ uses In-Form STORED command
___ contains properties set by In-Form
___ cartesian grid

Q1 859 ATMOSPHERIC B.L., first run
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ contains sources set by In-Form
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ contains properties set by In-Form
___ cartesian grid

Q1 860 Fire in room.
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 861 Smoke near building
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 862 Smoke in room.
___ cartesian grid

Q1 863 Computer cabinet.
___ contains Viewer USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 864 Computer room.
___ contains Viewer USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 870 Contact Resistance To Heat Condctn
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ cartesian grid

Q1 871 3D Steady Heat Conduction In A Cube
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 887 Slow Jet Entering Fast-Moving Surr
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model

Q1 890 2D Subsonic Turbulent Round Jet
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses ideal-gas law for density

Q1 895 3D Solid-Propellant Rocket
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 896 Fully-Developed, Moving-Wall Duct
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 899 macro used by cases 901-906
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 900 macro by case 909
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 901 De Laval Nozzle - Htot +X
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 902 De LavalL Nozzle - Htot + GXCONV +X
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 903 De Laval Nozzel - Hst +X
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 904 De Laval Nozzle - Hst + GXCONV +X
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 905 De Laval Nozzle - Hst + GXCONV +X
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 906 De Laval Nozzle - Using SMART Scheme
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 907 macro used by cases 908, 909
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 908 Supersonic Flow In Duct - Htot YX
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 909 Supersonic Flow In Duct - Hsta YX
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 910 Fanno Flow - Subsonic Inlet
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 911 2D Supersonic Rocket Exhaust Plume
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses ideal-gas law for density
___ use special GROUND convgr

Q1 921 Square Cavity; Steel Block; Water
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 922 Free Conv.; Steel Block In Water
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 923 Free Conv.; Steel Block In Mercury
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 924 Free Conv.; Steel Block In Glycerine
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 925 As For Case 921, But With Turmod(lvel
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ material indices set via SPEDAT
___ cartesian grid

Q1 926 As For Case 921, But With Turmod(lvel
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ material indices set via SPEDAT
___ cartesian grid

Q1 927 As For Case 923, But With Turmod(lvel
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 928 As For Case 924, But With Turmod(lvel
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 933 HotBox N-W Aper N-S Grav XY-Plane
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 939 HotBox N-W Aper N-S Grav XY-Plane
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ Two-scale high-Re model
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 947 Couette Flow VX
___ NY = 1
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ Two-scale high-Re model
___ material indices set via SPEDAT
___ cartesian grid

Q1 951 Couette Flow, Reynolds Number = 10.0
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 958 Couette Flow, K-EPS, Various RE
___ NX = 1
___ NZ = 1
___ cartesian grid

advanced multi-phase

Q1 p100 FILLING OF A 2D DUCT BY HOL:P100
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p101 FILM FORMATION BY HOL :P101
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p102 SLUMPING OF A LIQUID COLUMN BY HOL:P102
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p103 FALLING WATER JET - HOL METHOD:P103
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p104 FILLING OF A 2D DUCT BY SEM :P104
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p105 FILM FORMATION BY SEM METHOD:P105
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p106 SLUMPING OF A LIQUID COLUMN BY SEM:P106
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p107 FALLING WATER JET - SEM METHOD
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p108 Particle accumulation along duct walls:P
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ involves buoyancy
___ cartesian grid

Q1 p109 3D flow in a channel with an obstacle:P1
___ contains PHOTON USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p110 3D flow in a circular pipe: P110
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ involves buoyancy

Q1 p111 SETTLING IN A CIRCULAR PIPE: P111
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NZ = 1
___ involves buoyancy

Q1 p112 Trans. phase separation of gas/liq:P112
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ involves buoyancy
___ cartesian grid

Q1 p113 INCLINED JET-PROP FLOW OVER FLAT BED :P1
___ cylindrical grid
___ NX = 1
___ material indices set via SPEDAT

Q1 p114 ASM 1D SETTLING OF PARTICLES P112
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ involves buoyancy
___ cartesian grid

Q1 p115 ASM Workshop: 2D Separator
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p116 SEM Inflow boundary set with InForm
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 p117 FILLING OF A 2D DUCT BY VOF :P117
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p119 SLUMPING OF A LIQUID COLUMN BY VOF:P119
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p120 FALLING WATER JET - VOF METHOD
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p121 XY Water-Paraffin VOF-CICSAM g-y
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p122
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p123 Case 2D VOF-CICSAM 50 ml/min H2O-CO2
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p126 Test Zalesak disk CICSAM
___ contains Viewer USE commands for displaying results
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 p127 XY Water-Paraffin VOF + surface tension
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p128 XY Water-Paraffin VOF-CICSAM x-y hot
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p129 XY Water-Paraffin VOF-CICSAM x-y hot
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p130 2 drops in a 3 fluid setup
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p131 Liquid lens
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p132 3-phase Droplet Levitation
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p133 2-Phase Rising Bubble
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p134 3 Fluid Dam problem
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p135 VOF Cartes slug Water-kero XY CA 1
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 p136 3-phase Rising Bubble - Case 1
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p137 3-phase Rising Bubble - Case 2
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p138 3-phase Rising Bubble - Case 3
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p200 1D PARTICLE FLOW IN UNIFORM GAS STREAM
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p201 1D SETTLING OF PARTICLES UNDER GRAVITY
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p202 1D RISING OF AIR BUBBLES IN WATER
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p203 1D SOLIDS TRANSPORT IN WATER
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p204 1D VERTICAL PNEUMATIC CONVEYING
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p205 1D GAS-PARTICLE FLOW WITH HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p206 1D VIRTUAL MASS TEST CASES
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p207 1DX TRANSIENT SEDIMENTATION
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p216 1D INTERFACIAL-PRESSURE TEST CASE
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 p217 3D PIPE FLOW TEST OF LIFT FORCES
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 p218 BUBBLY AIR/WATER PIPE- Seriwaza upflow
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ two-phase flow

Q1 p219 AIR-SOLIDS FLOW- No turb. Mods
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ two-phase flow

Q1 p220 2D 2-PHASE BUBBLE-STIRRED GAS LADLE
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 p221 TRONDHEIM BUBBLE COLUMN- K-E turb.
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 p222 2D 2-PHASE HILLS BUBBLE COLUMN
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 p300 Water pouring into a bund
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 p301 FLOW IN OPEN TURNAROUND CHANNEL
___ NX = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 p302 recirculation in a stilling pond
___ 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 p303 Flow impingement on a blunt body
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

body-fitted coordinates

Q1 b100 3D grid created by menu
___ body-fitted coordinates
___ cartesian grid

Q1 b101 Bent-pipe grid, created by gset
___ body-fitted coordinates
___ cartesian grid

Q1 b102 Helical-pipe grid, made by DO loop :B102
___ body-fitted coordinates
___ cartesian grid

Q1 b103 Parameterised inclined-plated flow :B103
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses general collocated velocities option
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ material indices set via SPEDAT
___ cartesian grid

Q1 b111 No title has been set for this run.
___ NX = 1
___ NY = 1
___ NZ = 1
___ body-fitted coordinates
___ material indices set via SPEDAT
___ cartesian grid

Q1 b112 No title has been set for this run.
___ NX = 1
___ NY = 1
___ NZ = 1
___ body-fitted coordinates
___ material indices set via SPEDAT
___ cartesian grid

Q1 b113 No title has been set for this run.
___ body-fitted coordinates
___ material indices set via SPEDAT
___ cartesian grid

Q1 b114 No title has been set for this run.
___ body-fitted coordinates
___ material indices set via SPEDAT
___ cartesian grid

Q1 b115 No title has been set for this run.
___ body-fitted coordinates
___ uses general collocated velocities option
___ Chen-Kim high-Re model
___ material indices set via SPEDAT
___ cartesian grid

Q1 b116 No title has been set for this run.
___ NZ = 1
___ body-fitted coordinates
___ uses general collocated velocities option
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b200 Data from ICEM CFD
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 b201 GeoGrid Example
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 b202 Data from ICEM CFD
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 b414 POTENTIAL FLOW AROUND 1/2 CYLINDER: B514
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b422 Plane transonic flow through a nozzle
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses ideal-gas law for density
___ cartesian grid

Q1 b459 CONJ.HEAT TRANS.IN A CURVED DUCT: B459
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 b510 2-D DIFFUSER ;Y-Z CARTESIAN COORD.: B510
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b511 2-D DIFFUSER ;Y-Z CARTESIAN COORD.: B510
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b512 2-D CURVED DUCT; Y-Z PLANE : B512
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b513 PLANE DUCT + ANGLED SPLITTER PLATE: B513
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b514 POTENTIAL FLOW AROUND 1/2 CYLINDER: B514
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b515 MAGIC-GENERATED 1/2 CYLINDER GRID: B515
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b516 POT FLOW OVER ELLIPSE;ALGEBR. GRID: B516
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b517 POT FLOW OVER ELLIPSE;MAGIC GRID: B517
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b518 As for 517 with Navier-Stokes Soltn:B518
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b519 FLOW OVER ELLIPSE;MAGIC GRID: B519
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b520 POT. FLOW AROUND A HALF-CYL X-Z: B520
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b521 POT. FLOW AROUND A HALF-CYL X-Y : B521
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ darcy flow in porous medium
___ cartesian grid

Q1 b522 TRANSONIC FLOW THRU A NOZZLE: B522
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b523 SUPERSONIC FLOW THRU WEDGE CASCADE: B523
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b524 MIZUKI radial flow impeller: B524
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ cartesian grid

Q1 b525 FLOW THROUGH A REACTION TURBINE: B525
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ uses EXPERT dynamic relaxation
___ cartesian grid

Q1 b526 Flow in Hobson's cascade : B526
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b527 PLANE FLOW IN TURNAROUND DUCT: B527
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b528 Flow over a symmetric aerofoil: B528
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b529 External flow over a rocket: B529
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses ideal-gas law for density
___ cartesian grid

Q1 b530 FLOW AROUND A SHIP'S STERN : B530
___ body-fitted coordinates
___ cartesian grid

Q1 b531 2D BODY-SECTION IN A WIND TUNNEL: B531
___ contains PHOTON 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 b532 DEMONSTRATIONS OF GRID GENERATION: B532
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b533 PLANE CHANNEL + SMOOTH EXPANSION.: B533
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b534 FLOW THROUGH A BALL VALVE : B534
___ contains PHOTON 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 b536 PRANDTL-MEYER turning in the X-Y: B536
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b537 TURNAROUND DUCT WITH USER CHOICES :B537
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b538 GSET COMMAND TUTORIAL 1 :B538
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b539 TRANSFER_BETWEEN_TWO_SHAPES : B539
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b540 COPY-ROTATE_EXAMPLE:B540
___ body-fitted coordinates
___ cartesian grid

Q1 b541 CURVATURE_FOR_CAR_BODYB541
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b542 SUB-DOMAIN_SMOOTHINGB542
___ NY = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b543 TIME_SETTINGB543
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 b544 GRID_ON_CIRCLE :B544
___ NX = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b545 FLOW IN A 180 Deg CURVED DUCT
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ material indices set via SPEDAT
___ cartesian grid

Q1 b546 Pipe flow with two semi-circular blocks
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b551 macro by case 909
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 b552 macro by case 909
___ NY = 1
___ body-fitted coordinates
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 b561 Flow through a circular domain :561
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 b562 POLAR GRID DOWNFLOW V RAD., U AZI. :562
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b563 Viscous flow in a S-shaped duct :563
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b565 Radiused slot entry :565
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b566 Case 1 (WUA-CFD meeting in Basel,1994).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ RNG high-Re model
___ cartesian grid

Q1 b567 Bent-pipe grid, created by GSET :567
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ solves for VELOCITY POTENTIAL
___ cartesian grid

Q1 b568 Twisted-pipe grid; potential flow :568
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ solves for VELOCITY POTENTIAL
___ cartesian grid

Q1 b569 Flow in a curved pipe :569
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ cartesian grid

Q1 b570 XY Duct, GCV Solver, Skew angle 70.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses general collocated velocities option
___ cartesian grid

Q1 b571 Skewed Cavity, Staggered Solver, Angle =
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b572 Flow around a Cylinder at Re = 40.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 b573 Flow around a Cylinder at Re = 40.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 b574 Flow around a Cylinder at Re = 40.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b575 Flow past Off-set Cylinders - Staggered
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b576 Case 1 WUA-CFD Basel,1994 - Staggered
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ RNG high-Re model
___ cartesian grid

Q1 b577 CAR body.
___ body-fitted coordinates
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b578 Stirred reactor with baffles
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b579 CAR body - Staggered Solver
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b580 IAHR Smooth Channel, Re = 10.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 b581 Radiused Slot Entry - Staggered
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b582 Pipe Flow with Unstructured Multi-Block
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ material indices set via SPEDAT
___ cartesian grid

Q1 b583 3D TURBULENT FLOW IN AN ELBOW METER
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b584 Sliding grid test case
___ contains Viewer USE commands for displaying results
___ time-dependent
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 b585 Pipe Flow with Multi-Block Grid and LVEL
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses multi-block grid
___ uses general collocated velocities option
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ LVEL model
___ material indices set via SPEDAT
___ cartesian grid

Q1 b963 expanding closed 3D box
___ time-dependent
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b964 expanding open-ended 2D box
___ time-dependent
___ NY = 1
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b965 Moving-bfc test; grid distortion :b965
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b966 Expanding sphere :B966
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b967 cylinder with grid distortion :B967
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 b968 Expanding sphere :B968
___ time-dependent
___ body-fitted coordinates
___ involves moving body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

advanced chemistry

Q1 c109 NOX Post-Processing Of Case 481
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ cartesian grid

Q1 c110 2-D Coal Combustion With NOX
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses LONGNAME
___ material indices set via SPEDAT

Q1 c111 3-D Coal Combustion In A Furnace
___ contains PHOTON USE commands for displaying results
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND furngr
___ cartesian grid

Q1 c112
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ uses SCRS option for density
___ cartesian grid

Q1 c113 2-D CH4/AIR combustion+thermal NOX: C113
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses SCRS option for density

Q1 c114 1D coal + wood combustion
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses wood-combustion model
___ uses 7gases option for density
___ chemical sources with Arrhenius model
___ chemical sources
___ cartesian grid

Q1 c115 coal- and wood-burning furnace
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses wood-combustion model
___ uses 7gases option for density
___ chemical sources with Arrhenius model
___ chemical sources
___ cartesian grid

Q1 c116 Low Load, Coal and Wood
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses wood-combustion model
___ uses 7gases option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ chemical sources with Arrhenius model
___ chemical sources
___ material indices set via SPEDAT
___ cartesian grid

Q1 c201 CHEMKIN-1DY Plug Flow H2-O2 Reactor 201
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ uses CHEMKIN option for density
___ cartesian grid

Q1 c202 Plug Flow Reactor, Para. PHOENICS solver
___ NX = 1
___ NY = 1
___ steady parabolic flow
___ computes heat transfer
___ uses CHEMKIN option for density
___ cartesian grid

Q1 c203 CHEMKIN - 0D-Transient Reaction
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ uses CHEMKIN option for density
___ cartesian grid

Q1 c204 CHEMKIN - 1DY Premixed H2-Air Flame
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ uses CHEMKIN option for density
___ Constant-effective-viscosity model
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 c205 CHEMKIN - 1DZ Premixed H2-Air Flame
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ computes heat transfer
___ uses CHEMKIN option for density
___ Constant-effective-viscosity model
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 c206 C206: 1DX Thermal Diffusion Test
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ cartesian grid

Q1 c207 C207: 1DY Thermal Diffusion Test
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ cartesian grid

Q1 c208 C208: 1DZ Thermal Diffusion Test
___ NX = 1
___ NY = 1
___ computes heat transfer
___ cartesian grid

Q1 c209 1DX Simple H2=g2H Reaction Test Case
___ NY = 1
___ NZ = 1
___ uses CHEMKIN option for density
___ cartesian grid

Q1 c210 Thermal Diffusion Test-Case: XY-plane
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ cartesian grid

Q1 c211 Thermal Diffusion Demo.: YZ-plane
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ computes heat transfer
___ cartesian grid

Q1 c301 Premixed CH4 Combustion
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c302 Owen Furnace CH4 Diffusion Flame
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS
___ special print-out activated via SPEDAT

Q1 c303 Premixed CO Combustion
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c304 Premixed CO And H2 Combustion
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c305 Premixed 2Step CH4 Combustion
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c306 RADIAN: 2D Turbulent Diffusion Flame
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c307 Kent-Bilger H2 Diffusion Flame
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c308 CO Diffusion Flame
___ cylindrical grid
___ NX = 1
___ uses CHEMKIN option for density
___ uses extended SCRS

Q1 c309 CH4 Statoil Furnace
___ NX = 1
___ body-fitted coordinates
___ uses CHEMKIN option for density
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses extended SCRS
___ material indices set via SPEDAT
___ cartesian grid

Q1 c310 ke_rf220_106
___ body-fitted coordinates
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 c400 Coke Burning In A Grate Stoker
___ 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 c401 Coal-Fired Boiler
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 c402 Rotary Kiln For Particulate Refuse
___ cylindrical grid
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ involves buoyancy

Q1 c403 Transport Of Toxic Spill
___ NX = 1
___ body-fitted coordinates
___ uses general collocated velocities option
___ 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 c404 Building Fire In Cross-Wind
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 c405 Secondary Combustion Chamber
___ 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 c406 Two-step reaction: 1 fluid
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses ideal-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 c407 Wall-fired model furnace
___ contains PHOTON USE commands for displaying results
___ two-phase flow
___ uses ideal-gas law for density
___ uses PLANT to create extra Fortran coding
___ cartesian grid

GENTRA (particle tracking

Q1 g200 Backward-facing step : G200
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 g201 Spray dryer (BFC=T) : G201
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 g204 Particles in radial impeller: G204
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ cartesian grid

Q1 g205 Particles through a ball valve: G205
___ contains PHOTON 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 g207 Sample cup in rain: G207
___ contains PHOTON USE commands for displaying results
___ cylindrical grid

Q1 g209 Particles in 2D curved duct: G209
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 g210 1D Evaporation of a Water Jet in a Duct
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ uses In-Form STORED command
___ cartesian grid

Q1 g301 Particle heating in pipe : G301
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ cylindrical grid

Q1 g302 HEAT-EXCHANGING, 1-D : G302
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 g303 HEAT-EXCHANGING, 1-D, TRANSIENT: G303
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 g401 SOLIDIFYING,1D,TRANSIENT,M=3.0:G401
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 g403 SOLIDIFYING,1D,TRANS.,L=L(T): G403
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 g405 ISOTHER. SOLIDIFYING,1D,TRANS.:G405
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 g502 PARTICLE EVAPORATING IN PIPE: G502
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ cartesian grid

Q1 g505 Evapor. particl.in spray dryer:G505
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses ideal-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 g506 PARTICLES IN 2D CURVED DUCT: G506
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 g507 ISOTHER. EVAPORN, CONST PROP'S:G507
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 g508 ISOTHER. EVAPORN, CONST PROP'S:G508
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 g704 Test for tracers in BFC: G704
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ cartesian grid

Q1 g706 Beams in reaction turbine: G706
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses isentropic-gas law for density
___ cartesian grid

Q1 g721 Particle bouncing in grav field: G721
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ cartesian grid

Q1 g722 Oblique impingement of box on water: G72
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ involves buoyancy
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ cartesian grid

multi-block and fine-grid embedding

Q1 f100 CCM : Square cavern (Re=10000.).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses CCM method
___ cartesian grid

Q1 f101 CCM: Back-facing step (2 layer K-E).
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ uses CCM method
___ solves for LTLS
___ computes WALL DISTANCE
___ Second simple low-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f102 CCM : Re= 1000.; TET= 45.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f103 CCM : Laminar convection in Annuli.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f104 CCM: U-duct (Y-Z plane, Re=1000.).
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f105 CCM: Swirl-flow (Re=100).
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 f106 CCM-SCHM: X-Y convection in skewed flow.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f107 CCM : Pressure Drop (X-Y).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses CCM method
___ cartesian grid

Q1 f108 FGE: Backward facing step with KEMODL mo
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f109 CCM : Salted water flow.
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f110 CCM : Swirling flow; Lin-expan. (Re=200)
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f111 CCM : 2D-duct with F(Re)-expansion.
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f112 CCM: Bay flow (3D,K-E
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f113 PHOENICS: Swirling flow.
___ NX = 1
___ body-fitted coordinates
___ uses CCM method
___ cartesian grid

Q1 f114 NON-ISOTHERMAL 2D LAMINAR MIXING LAYER
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses CCM method
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 f150
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses CCM method
___ cartesian grid

Q1 f200 MB-FGE: 2D Potential flow over airfoil.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f201 MB-FGE: Heat Conduction in a 5-pointed s
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f202 MB-FGE: Laminar flow between two cylinde
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f203 MBFGE: Flow in cavity (5 blocks).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f204 MB-FGE: 2D skewed cavity with moving lid
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f205 MB-FGE: 2D Flow Over Back-Step (2L K-E).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ solves for LTLS
___ computes WALL DISTANCE
___ Second simple low-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f206 MB-FGE: 2D Continuous Caster Model
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f207 MB-FGE: 2D Turbulent Flow Inside The 'Ar
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ Second simple low-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f208 MB-FGE: Swirl-flow (Re=100).
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f209 FGEM, Gas Leak Example
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f210 MB-FGE: Case 1 (WUA-CFD-94, Laminar).
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f211 Linked Tank Assembly
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f212 Multi-block BFC grid for T-junction
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f213 MB-FGE: Laminar flow through 'cyclone'.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f214 MBFGE-SCHM: X-Y convection in skewed flo
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f215 MBFGE: Swirling flow; Lin-expan. (Re=200
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f216 MBFGE: Laminar axisymmetric flow.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 f217 SHOCK TUBE;Ideal-Gas P-Ro relation.
___ time-dependent
___ NY = 1
___ NZ = 1
___ uses CCM method
___ computes heat transfer
___ material indices set via SPEDAT
___ cartesian grid

Q1 f218 MBFGE: 2D Stirred flow (K-E).
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f219 MBFGE: Flow around rotating disk (Re=1).
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f220 MBFGE: 3D (Re=2000.; K-E) sliding grid.
___ time-dependent
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f221 MBFGE: 2D Moving 'boxes' (K-E).
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f222 MBFGE: 2 phase 2D X-flow (X-Y plane, Re=
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f223 MBFGE: 2 phase 2D X-flow (X-Y plane, Re=
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f224 MBFGE-2P: Mono-Propellant Combustion.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ uses multi-block grid
___ uses CCM method
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ cartesian grid

Q1 f301 Flow over a cylinder (FGEB)
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f302 FGE: 2D Flow around a square object
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f303 FGE: Jet flow into a large duct
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ cartesian grid

Q1 f304 FGE: 3D Flow through a rectangular duct
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ cartesian grid

Q1 f305 FGE: 3D Flow around a heated object
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f306 FGE: Backward Facing Step
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f307 FGE: Flow over backward facing step
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f308 FGE: Backward facing step with KEMODL mo
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 f309 Simple f301 (tem1, x-y plane)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f310 Simple f301 (tem1 + uniform u1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f311 Simple f301 (tem1 + heat generation)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f312 f309 for x-z plane
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f313 F310 FOR X-Z PLANE
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f314 F311 FOR X-Z PLANE
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f315 Simple f302 (tem1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f316 Simple f302 (tem1 + uniform u1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f317 Simple f303 (tem1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f318 Simple f303 (tem1 + uniform u1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f319 F317 for X-Z PLANE
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f320 F318 WITH X-Z PLANE
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f321 Simple f304 (tem1, 3D)
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f322 Simple f304 (tem1 + uniform u1, 3D)
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f323 Simple f306 (tem1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f324 Simple f306 (tem1 + uniform u1)
___ contains PHOTON 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
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ uses outer iterations in FGEM solver
___ cartesian grid

Q1 f325 Simple f307 (tem1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f326 Simple f307 (tem1 + uniform u1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f327 Simple f308 (tem1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f328 Simple (tem1 + uniform u1)
___ contains PHOTON 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
___ uses outer iterations in FGEM solver
___ uses In-Form STORED command
___ uses fine-grid-embedding
___ cartesian grid

Q1 f329 3D solution of f309 (Tem1)
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses fine-grid-embedding
___ cartesian grid

Q1 f330 3D solution of f310 (tem1 with uniform u
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses outer iterations in FGEM solver
___ uses fine-grid-embedding
___ cartesian grid

Q1 f400 Two tubes in a semi-rectangular chamber
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 f401 Flame holders in an afterburner
___ NZ = 1
___ 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 f402 Two-phase flow in a bifurcation
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 f403 SUPERSONIC FLOW OVER DIAMOND-SHAPE BODY
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f404 Longitudinal vortex generators
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 f405 Delta-winglets behind a cylinder
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

multi-fluid turbulence

Q1 l100 WSR, 1D (Reactedness) Population
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l101 WSR, 1D Population; Flowa=0.5
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l102 WSR, 1D Population; RATEXP=5.
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l103 AWSR transient, conmix=100. conrea=1.
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ contains sources set by In-Form
___ cartesian grid

Q1 l110 2d population, steady; case L110
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l113 2d Population, Transient, L113
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l220 1D Flame Propgn; Conmix=1. Conrea=0.025
___ NY = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l230 MFM; 1dsmoke; conmix=5.
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ uses SCRS option for density
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l231 MFM; 1dsmoke; conmix=5.
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ activates IMMERSOL
___ uses SCRS option for density
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l300 10-Fluid Model Of Mixing Layer; Conmix=5
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ uses dollar: source=(VAL-PHI)*CO*NAME patch
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l301 1d ocean layer; 2d pop. ; v + w as PDAs
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l302 Round Jet; MFM; parabolic
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses dollar: source=(VAL-PHI)*CO*NAME patch
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses multi-fluid turbulence model

Q1 l303 Round Jet; MFM; parabolic
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ steady parabolic flow
___ uses dollar: source=(VAL-PHI)*CO*NAME patch
___ contains properties set by In-Form
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses multi-fluid turbulence model

Q1 l304 K-EP:KH instability
___ time-dependent
___ NZ = 1
___ involves buoyancy
___ uses In-Form STORED command
___ uses multi-fluid turbulence model
___ cartesian grid

Q1 l310 Round Jet; MFM; parabolic
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ uses dollar: source=(VAL-PHI)*CO*NAME patch
___ uses In-Form STORED command
___ contains properties set by In-Form
___ uses multi-fluid turbulence model

Q1 l400 2D Combustor With Smoke Generation
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses SCRS option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains lines to be read by EARTH via READQ1
___ contains properties set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ uses LONGNAME
___ uses multi-fluid turbulence model
___ material indices set via SPEDAT

Q1 l401 Case 400 With Enlarged EBU Constant, Viz
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses SCRS option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains lines to be read by EARTH via READQ1
___ contains properties set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ uses LONGNAME
___ uses multi-fluid turbulence model
___ material indices set via SPEDAT

Q1 l500 MFM; Stirred Tank; Conmix=5.
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ uses In-Form STORED command
___ uses multi-fluid turbulence model

Q1 l501 MFM; Stirred Tank; Nfluids = 21
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ uses In-Form STORED command
___ uses multi-fluid turbulence model

Q1 l502 MFM; Stirred Tank; Conmix=50.
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ uses In-Form STORED command
___ uses multi-fluid turbulence model

Q1 l530 MFM; 3D Cmbstr; Conmix=5.
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses SCRS option for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains lines to be read by EARTH via READQ1
___ contains properties set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ uses LONGNAME
___ uses multi-fluid turbulence model
___ material indices set via SPEDAT

Q1 l600 MFM; 3D Cmbstr; Conmix=5.
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ uses SCRS option for density
___ contains lines to be read by EARTH via READQ1
___ contains properties set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ uses LONGNAME
___ uses multi-fluid turbulence model
___ material indices set via SPEDAT

Q1 l999
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

non-Newtonian

Q1 j100 100 2d pipe flow - Power-law fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 j101 101 2d pipe flow - Sisko Power-Law fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j102 102 2d pipe flow - Cross fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j103 103 2d Pipe flow - Carreau-fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j104 104 2d Pipe flow - Carreau-Yusada fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j105 105 2d pipe flow - Powell-Eyring fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 j106 106 2d pipe flow - Ellis fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j107 107 2d pipe flow - Bingham-plastic fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 j108 108 2d pipe flow-Bingham-Pl-Papan. fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 j109 109 2d pipe flow-Herschel-Bulkley fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j110 110 2d pipe flow-Hers.-Bulk.-Papan.fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j111 111 2d pipe flow - Casson fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j112 112 2d pipe flow - Casson-Papan. fluid
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes WALL DISTANCE
___ solves for LTLS
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 j113 113 Heat transfer to molten polymer flow
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ computes WALL DISTANCE
___ solves for LTLS
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ In-Form STORED command uses SUM(
___ contains initial values set by In-Form

Q1 j114 114 3D SPARSOL Pipe Flow-1Power-Law
___ contains Autoplot USE commands for displaying results
___ computes WALL DISTANCE
___ computes heat transfer
___ solves for LTLS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 j115 115 3D SPARSOL Pipe Flow-2Carreau-Yusada
___ contains Autoplot USE commands for displaying results
___ computes heat transfer
___ computes WALL DISTANCE
___ solves for LTLS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 j116 116 3D SPARSOL Pipe Flow-3Carreau-Yusada
___ contains Autoplot USE commands for displaying results
___ computes heat transfer
___ computes WALL DISTANCE
___ solves for LTLS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 j117 117 3D SPARSOL Pipe Flow-4 Cross
___ contains Autoplot USE commands for displaying results
___ computes heat transfer
___ computes WALL DISTANCE
___ solves for LTLS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

advanced numerical algorithms

Q1 n101 YX DIAGONAL SCALAR CONVECTION :N101
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses LONGNAME
___ cartesian grid

Q1 n102 YX LAMINAR WALL-DRIVEN CAVITY
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 n103 YX LAMINAR BACKWARD-FACING-STEP FLOW
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 n104 YX SCALAR CONVECTION WITH RECIRCULATION
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 n105 YX TURBULENT BACKWARD-FACING-STEP FLOW
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 n106 2DXZ LAMINAR WALL-DRIVEN CAVITY
___ NY = 1
___ cartesian grid

Q1 n107 2DXZ TURBULENT BKWRD FACING STEP: N107
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n108 2DYX LAMINAR FLOW OVER A FENCE: N108
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ cartesian grid

Q1 n109 2D BFC LAMINAR WALL-DRIVEN CAVITY
___ NY = 1
___ body-fitted coordinates
___ cartesian grid

Q1 n110 2D TURBULENT FLOW THROUGH AN ORIFICE
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses LONGNAME
___ material indices set via SPEDAT

Q1 n111 1D SHOCK-FREE TRANSONIC NOZZLE FLOW
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ cartesian grid

Q1 n112 1D SHOCKED TRANSONIC FLOW IN A LAVAL NOZ
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ uses ideal-gas law for density
___ use special GROUND convgr
___ cartesian grid

Q1 n113 2D TRANSONIC UNDEREXPANDED JET: N113
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses ideal-gas law for density
___ use special GROUND convgr

Q1 n114 2D BLUFF-BODY STABILISED METHANE JET
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ use special GROUND convgr

Q1 n115 YX BFC DIAGONAL SCALAR CONVECTION
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 n116 YX BFC UNIFORM FLOW THROUGH A BOX
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 n117 YX BFC UNIFORM FLOW ACROSS SKEWED BOX
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ cartesian grid

Q1 n121 point source, various schemes
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses LONGNAME
___ cartesian grid

Q1 n122 point source, best schemes + CLDA
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses Conservative Low-Dispersion Algorithm
___ uses LONGNAME
___ cartesian grid

Q1 n131 YX DIAGONAL SCALAR CONVECTION :N101
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses LONGNAME
___ cartesian grid

Q1 n201 CORE CASE 290 WITH JACB SOLVER :N201
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n202 CORE CASE 290 WITH GASD SOLVER :N202
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n203 CORE CASE 290 WITH ORLU SOLVER :N203
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n204 CORE CASE 290 WITH MSIP SOLVER :N204
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n205 CORE CASE 290 WITH CRGR SOLVER :N205
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n206 CORE CASE 290 WITH JACD SOLVER :N206
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n207 CORE CASE 290 WITH JACR SOLVER :N207
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n208 CORE CASE 290 WITH LUCG SOLVER :N208
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n209 CORE CASE 290 WITH LUCR SOLVER :N209
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n210 CORE CASE 290 WITH LACM SOLVER :N210
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n211 CORE CASE 290 WITH MACM SOLVER :N211
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n212 CORE CASE 290 WITH ALCM SOLVER :N212
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n213 CORE CASE 290 WITH AMCM SOLVER :N213
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 n301 GXCLDA tests : N301
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses Conservative Low-Dispersion Algorithm
___ contains lines to be read by EARTH via READQ1
___ cartesian grid

Q1 n401
___ NZ = 1
___ cartesian grid

Q1 n402
___ NZ = 1
___ cartesian grid

Q1 n403
___ NX = 1
___ cartesian grid

Q1 n404
___ NX = 1
___ cartesian grid

Q1 n405
___ NX = 1
___ cartesian grid

Q1 n406
___ NX = 1
___ cartesian grid

Q1 n407
___ cartesian grid

PLANT

Q1 z100 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 z101 XYLEN FLOW IN CONV.-DIV, DUCT: Z101
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ body-fitted coordinates
___ uses PLANT to create extra Fortran coding
___ cartesian grid

Q1 z102 VEHICULAR EXHAUST DISPERSION IN RAINFALL
___ 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 z103 PHASE DISTRIBUTION IN A SMOOTH EXPANSION
___ 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 z104 2D UNSTEADY DIFFUSION PROBLEM:Z104
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ uses PLANT to create extra Fortran coding
___ uses conjugate-gradient solver
___ cartesian grid

Q1 z105 ABSORPTIVE DISPERSAL WITH STEP-TIME DEPE
___ time-dependent
___ 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
___ 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

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
___ computes heat transfer
___ uses In-Form STORED command
___ 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
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r194
___ NZ = 1
___ cartesian grid

Q1 r195
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r196
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r197
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r198
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r199
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 r200
___ 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
___ uses In-Form STORED command
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ 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
___ material indices set via SPEDAT
___ cartesian grid

Q1 r333
___ 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
___ 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
___ 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
___ material indices set via SPEDAT
___ cartesian grid

Q1 r403 Heat treatment in a direct-fired furnace
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ uses SCRS option for density
___ chemical sources with eddy-break-up model
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 r404 Thermal radiation in a compartment fire
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ uses SCRS option for density
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 r405 Convection affected by radiation
___ 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
___ involves buoyancy
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 r406 Lid-driven flow in a radiating cavity
___ 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
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 r407 Radiative oven
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 r408 A stove with significant radiation
___ contains PHOTON USE commands for displaying results
___ uses SCRS option for density
___ uses PLANT to create extra Fortran coding
___ cartesian grid

Q1 r409 Wall-fired model furnace: P-1 radiation
___ contains PHOTON USE commands for displaying results
___ two-phase flow
___ uses ideal-gas law for density
___ uses PLANT to create extra Fortran coding
___ cartesian grid

stresses in solids

Q1 s101 Cube in X-direction tension; S101
___ NY = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s102 Cube in Y-direction tension; S102
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s103 CUBEINX-DIRECTIONTENSION
___ NX = 1
___ NY = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s104 Pressurised long cylinder; 1Dy
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s105 bent beam; engineer's theory;s105
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s106 Stress in a rotating disk; 1Dy
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s111 bent beam in plane strain; s220
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s200 2D Plate with polynomial stress function
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses LONGNAME
___ cartesian grid

Q1 s201 2D xy Plate with square hole; s201
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s202 2D xy Plate with CIRCULAR hole; s202
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ contains sources set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ cartesian grid

Q1 s203 Polar Plate with CIRCULAR hole
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s204 2D xy 2-material plate in tension; s204
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s205 2D xz plate in z-direction tension; s205
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s206 2D yz-plate in z-direction tension; s206
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s208 2D xy 2-material plate in tension; s208
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s209 2D xy plate in compression; two material
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s210 2D xy Plate of two materials + TEM; s210
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s211 2D bent beam in plane strain; s211
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s212 Plate; 2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s220 bent beam in plane strain; s220
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s221 square channel;2D[xy]
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s222 Pressurised long cylinder [X,Y]
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s223 Pressurised long cylinder [R,Z]
___ cylindrical grid
___ NX = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s224 Pressurised cylinder [R,Z] with Hole
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ material indices set via SPEDAT

Q1 s225 Pressurised cylinder [R,Z] with Hole and
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s226 Centre-Heated, Edge-Cooled Block
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ computes heat transfer
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s227 Multi-Physics. Reyno= 1000. Unit=12
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ activates IMMERSOL
___ computes heat transfer
___ LVEL model
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s228 Pressurised long cylinder [X,Y]
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s230 Plate with square hole;2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s240 square channel;2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s242 square channel;2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s250 square channel + TEM1;2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s251 Plate with square hole;2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s252 square channel + TEM1;2D[xy]
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s254 square channel + TEM1;2D[xy]
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s258 Plate of two Horizontal materials; 2D[xy
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s259 Plate of two Vertical materials; 2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s260 BiPlate of two materials + TEM; 2D[xy]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s261 Stress in a rotating disk; 2D[x,y]
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s262 Model of turbine rotor
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s263 Model of turbine rotor with big Blades
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s301 3D Prismatic bar + gravity force; s301
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s302 1/2/3D thermal stress in a cub; s302
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s303 3D block in y-direction compression
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s304 3D TORSION of beam; s304
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s305 3D TORSION of thin Beam; s305
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s307 3D block in y-direction compression; s30
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s351 3D Prismatic bar + gravity force
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s352 1/2/3D thermal stress in a cube; s352
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s401 2D Flow Past A Bent Solid Plate; S401
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ plate porosity set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 s402 2D Flow Past A Bent Solid Plate; S402
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ plate porosity set via SPEDAT
___ uses In-Form STORED command
___ cartesian grid

Q1 s501 cube in x-direction tension
___ NY = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s502 cube in y-direction tension
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ uses LONGNAME
___ material indices set via SPEDAT
___ cartesian grid

Q1 s504 Pressurised long cylinder; 1Dy
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ contains lines to be read by EARTH via READQ1
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s508 USP: Stress in a 2D rotating disk; S508
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s511 USP: 2D xy plate in tension;U501
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s512 USP: 2D xy Hot Bi-metallic plate
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s513 USP.USP: 2D Plate in tension with FY=var
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s514 USP:2D xy Plate with CIRCULAR hole; us20
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 s515 USP: 2D xy Plate with square hole; U505
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s516 USP: Cooled long cylinder
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s517 USP: Pressurised long cylinder;U507
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s518 USP: Stress in a 2D rotating disk; S508
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s550 3D Thermal Stress In BLADE
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s600 2D Plate with polynomial stress function
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s601 2D xy Plate with square hole; S601
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s602 mechanical stress in a cube
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s603 Polar Plate with CIRCULAR hole
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s604 2D xy 2-material plate in tension; S604
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s605 2D xy plate in y-direction tension; S605
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s606 THERMal stress in a cube
___ NX = 1
___ NY = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s622 Pressurised long cylinder [X,Y]
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ material indices set via SPEDAT

Q1 s624 Pressurised long cylinder with hole;S624
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s630 Cooled long cylinder [polar]
___ cylindrical grid
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT

Q1 s631 Cooled long cylinder [Cartesian]
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s660 Bi-Metalic Plate of two materials + TEM
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s661 Stress in a rotating 2D[x,y] disk; S661
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s662 Model of turbine rotor; S662
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses ROTOR VR Object
___ material indices set via SPEDAT

Q1 s670 Wave in 1DX free beam; S670
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s671 Wave in fixed 1D x beam; S671
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s672 2D wave in "T" beam; S672
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s673 Free wave in 2D "tuning-fork" model; S67
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s674 The steep propagating 1DY wave; S674
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s675 The steep propagating 2DXY wave; S675
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s698 Cartesian Pressurised long cylinder;S699
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s699 Cartesian Pressurised long cylinder;S699
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s701 3D Prismatic bar + gravity force; s701
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s702 1/2/3D thermal stress in a cub; s302
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 s703 3D block in y-direction compression
___ contains PHOTON USE commands for displaying results
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses LONGNAME
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s704 3D TORSION of beam; s704
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s705 3D TORSION of thin Beam; s705
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s799 2D VR-bar + gravity force; s799
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s801 2D Fluid flow around an beam; S801
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s802 Thermal Stress In Heated/Cooled Block
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 s803 2D Fluid flow around an elastic beam;S80
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s804 heat exchanger with stress
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT

Q1 s901 Steady 2DXY Piezoelectric; S901
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s902 Full Steady 2DXY Piezoelectric; S902
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

Q1 s903 Transient 2DXY Piezoelectric; S903
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ time-dependent source set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 s999 Steady 2DXY Piezoelectric; S903
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ cartesian grid

advanced turbulence

Q1 t100 CHEN-KIM K-E_1D PLANE COUETTE FLOW :T100
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ uses In-Form STORED command
___ cartesian grid

Q1 t101 CHEN-KIM K-E DEVELOPED CHANNEL FLOW:T101
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ Chen-Kim high-Re model
___ uses fully-developed-flow option
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 t102 REAL K-E_1D DEVELOPED PIPE FLOW:T102
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ uses fully-developed-flow option
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 t103 K-W_BKWRD FACING STEP Y-X :T103
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t104 CHEN KIM K-E MODEL_PARAB PLANE JET :T104
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ Chen-Kim high-Re model
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 t105 CHEN KIM K-E MODEL_PARAB ROUND JET :T105
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ Chen-Kim high-Re model
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 t106 RNG KE-2D FLOW IN TURNAROUND DUCT :T106
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ RNG high-Re model
___ uses In-Form STORED command
___ cartesian grid

Q1 t107 T107:KE-2D TRANSONIC UNDEREXPANDED JET
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ uses ideal-gas law for density
___ use special GROUND convgr

Q1 t110 K-W_BKWRD FACING STEP Y-Z :T110
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t200 VAN DRIEST_1D PLANE COUETTE FLOW :T200
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 t201 VAN DRIEST_1D DEVELOPED PIPE FLOW :T201
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Prndtl Mixing-Length model

Q1 t202 VAN DRIEST_2D PARAB BOUNDARY LAYER :T202
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 t204 VAN DRIEST_2D-YX ELLIP CHANNL FLOW :T204
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 t205 LAM-BRE KE_1D PLANE COUETTE FLOW :T205
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Lam=Bremhorst-Re model
___ uses In-Form STORED command
___ cartesian grid

Q1 t206 LAM-BRE KE_1D DEVEL CHANNL FLOW :T206
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Lam=Bremhorst-Re model
___ uses fully-developed-flow option
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 t207 Wilcox 1988 K-W_1D DEVELOPED PIPE FLOW:T
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ Wilcox-Kolmogorov low-Re model
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option
___ uses In-Form STORED command
___ In-Form STORED command uses SUM(
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT

Q1 t208 Low-Re LB k-e BF Step Y-X :T208
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ Lam=Bremhorst-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t211 LAM-BRE K-E_2D PARABOLIC PIPE FLOW :T211
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ solves for LTLS
___ computes WALL DISTANCE
___ Lam=Bremhorst-Re model

Q1 t212 LAM-BRE K-E_2D PARAB BNDRY LAYER :T212
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ solves for LTLS
___ computes WALL DISTANCE
___ Lam=Bremhorst-Re model
___ cartesian grid

Q1 t213 SST k-w__2D ABRUPT PIPE EXPANS :T213
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ material indices set via SPEDAT

Q1 t214 LRN KW SST-2D TURNAROUND-DUCT FLOW:T214
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ solves for LTLS
___ computes WALL DISTANCE
___ Chen-Kim high-Re model
___ uses In-Form STORED command
___ cartesian grid

Q1 t215 LAM-BRE_2D Y-Z NOPOR CHANNEL TEST :T215
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ Lam=Bremhorst-Re model
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 t216 LAM-BRE_2D Y-Z POROS CHANNEL TEST :T216
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Lam=Bremhorst-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t217 LAM-BRE_2D Y-Z CONJ CHANNEL TEST :T217
___ NX = 1
___ computes heat transfer
___ uses volumetric block correction
___ computes WALL DISTANCE
___ solves for LTLS
___ Lam=Bremhorst-Re model
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 t218 LoRe LB K E YAP_2D IMPINGING ROUND JET
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ Lam=Bremhorst-Re model
___ uses In-Form STORED command

Q1 t219 2D Turb. Buoyant Cavity Flow K-E:T219
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ uses density linear in 1/Tabs
___ Lam=Bremhorst-Re model
___ involves buoyancy
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 t300 2D Turbulent Free Convection In A Cavity
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ uses density linear in 1/Tabs
___ Lam=Bremhorst-Re model
___ involves buoyancy
___ cartesian grid

Q1 t301 KE-2D BLUFF-BODY STABILISED METHANE JET
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ use special GROUND convgr
___ uses In-Form STORED command
___ contains sources set by In-Form

Q1 t302 T302: Wilcox 1988 k-w Orifice-Plate Flow
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 t303 YAP_KE 2D IMPINGING ROUND JET: T303
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ solves for LTLS
___ computes WALL DISTANCE

Q1 t304 CK KE_1D PIPE POWER-LAW FLUID :T304
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ CHEN-Kim low-Re model
___ uses fully-developed-flow option

Q1 t305 KE_PIPE FLOW OF A BINGHAM FLUID: T305
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ uses fully-developed-flow option

Q1 t306 2D KE ATMOSPHERIC BOUNDARY LAYER: T306
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 t307 RK K-E SQUARE RIB FLOW :T307
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t308 RK K-E SURFACE CUBE FLOW :T308
___ contains Autoplot USE commands for displaying results
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t309 Realisable KE_2D Elliptic Round Free Jet
___ cylindrical grid
___ NX = 1
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT

Q1 t310 Realisable KE_2D Elliptic Plane Jet
___ NX = 1
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 t311 Realisable_KE Blunt Flat Plate:T311
___ contains Autoplot USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t312 NEUTRAL ABL WIND FLOW - K-F MODEL: T312
___ contains initial values set by In-Form
___ cartesian grid

Q1 t313 NEUTRAL ABL WIND FLOW - K-E MODEL: T313
___ contains initial values set by In-Form
___ cartesian grid

Q1 t314 NEUTRAL ABL WIND FLOW-REAL.K-E MOD:T314
___ contains initial values set by In-Form
___ cartesian grid

Q1 t400 2S K-E MODEL_1D PLANE COUETTE FLOW :T400
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ Two-layer high-Re model
___ cartesian grid

Q1 t401 2S K-E MODEL_1D DEVELOPED PIPE FLOW:T401
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ Two-layer high-Re model

Q1 t402 2S K-E MODEL_1D DVLPD CHANNEL FLOW :T402
___ NX = 1
___ NZ = 1
___ Two-layer high-Re model
___ cartesian grid

Q1 t403 2S K-E MODEL_PARABOLIC PLANE JET :T403
___ NX = 1
___ steady parabolic flow
___ Two-layer high-Re model
___ cartesian grid

Q1 t404 2S K-E MODEL_PARABOLIC ROUND JET :T404
___ cylindrical grid
___ NX = 1
___ steady parabolic flow
___ Two-layer high-Re model

Q1 t405 2S K-E MODEL_BKWRD FACING STEP Y-X :T405
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ Two-layer high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t406 2S K-E_PLANE FLOW, TURNAROUND DUCT :T406
___ NX = 1
___ body-fitted coordinates
___ Two-layer high-Re model
___ cartesian grid

Q1 t500 LAMINAR TEST OF EGWF - SOWF VARIANT
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 t501 LAMINAR TEST OF EGWF - SOWF VARIANT
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 t502 1D Turb Pipe Flow + Heat Trans
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ uses fully-developed-flow option

Q1 t503 USE OF EARTH GENERATED WALL-FUNCTIONS
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ material indices set via SPEDAT
___ cartesian grid

Q1 t600 RSTM_1DY DEVELOPED CHANNEL FLOW :T600
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option
___ material indices set via SPEDAT
___ cartesian grid

Q1 t602 RSTM_1D DEVELOPED PIPE FLOW :T602
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option
___ material indices set via SPEDAT

Q1 t603 RSTM_2D PARABOLIC PLANE JET :T603
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 t604 RSTM_2D PARABOLIC PLANE WALL JET :T604
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 t605 RSTM_1D ROTATING PIPE FLOW :T605
___ contains Autoplot USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ uses fully-developed-flow option
___ material indices set via SPEDAT

Q1 t606 RSTM_1DY PLANE COUETTE FLOW :T606
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ cartesian grid

Q1 t607 RSTM_2DY-Z PARABOLIC CHANNEL :T60
___ NX = 1
___ steady parabolic flow
___ cartesian grid

Q1 t608 RSTM_3D DVLPD DUCT FLOW/HEAT TRANS :T608
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses fully-developed-flow option
___ cartesian grid

Q1 t609 RSTM_2D IMPINGING ROUND JET :T609
___ cylindrical grid
___ NX = 1

Q1 t610 2D LES SQUARE CYLINDER- steady precursor
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t611 2D LES SQUARE CYLINDER- unsteady run
___ time-dependent
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t701 T701: 2D Z-Y ABL WIND FLOW - k-e model
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 t702 T702:2DZY ABL WIND FLOW- Real. k-e model
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 t703 T703:2DZY ABL WIND FLOW- Wilcox 1988 k-w
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 t704 T704:2DZY ABL WIND FLOW- k-w SST model
___ solves for LTLS
___ computes WALL DISTANCE
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 t705 T705:2DZY ABL WIND FLOW- Wilcox 2008 k-w
___ uses In-Form STORED command
___ contains initial values set by In-Form
___ cartesian grid

Q1 t800 2D LES SQUARE CYLINDER- steady precursor
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t801 2D LES SQUARE CYLINDER- unsteady run
___ time-dependent
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 t900
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 t950
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

two-phase flow

Q1 w100 EQUVEL input-file fragment :W100
___ NX = 1
___ NY = 1
___ NZ = 1
___ two-phase flow
___ both phases have equal velocity components
___ cartesian grid

Q1 w350 1D STEADY BOILING IN PIPE: W350
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w351 1D-Z PIPE BOILING PH1-LIQ,PH2-GAS: W351
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ two-phase flow
___ cartesian grid

Q1 w352 1D-Z PIPE BOILING PH1-GAS,PH2-LIQ: W352
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ two-phase flow
___ cartesian grid

Q1 w370 2D STEADY BOILING IN PIPE: W370
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow
___ involves buoyancy

Q1 w371 AREA RESTRICTION AT QUARTER LENGTH: W371
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w372 2D STEADY BOILING IN PIPE: W370
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow
___ involves buoyancy

Q1 w410 0D UNSTEADY BOILING IN VESSEL: W410
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w411 CLOSED-VESSEL BOILING, L=F(P): W411
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w412 0D BOILING IN VESSEL+PRESS RELIEF: W412
___ time-dependent
___ NX = 1
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w421 SUDDEN TILTING OF TWO-FLUID CHANNEL:W421
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ involves buoyancy
___ cartesian grid

Q1 w422 1D TRANSIENT THERMOSYPHON : W422
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ involves buoyancy
___ cartesian grid

Q1 w423 fluids moving in opposite directions:423
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w425 1D TRANSIENT PIPE FILLING : W425
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w427 THE TILTING OF A BOX : W427
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w428 Oil slick in a gulf with wind: W428
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ two-phase flow

Q1 w430 transient air-lift pump :W430
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow
___ uses isentropic-gas law for density

Q1 w440 AREA RESTRICTION AT QUARTER LENGTH: W440
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w441 TRANSIENT 2PH FLOW WITH MOVING WALL:W441
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w468 EQUVEL input-file fragment :W100
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ both phases have equal velocity components
___ cartesian grid

Q1 w568 PLANE 2PHS FLOW IN TURNAROUND DUCT: W568
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ cartesian grid

Q1 w569 2PHS NON NEWTONIAN FLOW IN DUCT : W569
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ cartesian grid

Q1 w570 MONOPROPELLANT ROCKET : W570
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ cartesian grid

Q1 w571 1D PARTICLE FLOW (cint=grnd7 test): W571
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w573 ROUND JET;K-E 2PHS TURB MODULATION: W573
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w574 2PH BACKWARD-FACING-STEP K-E MODEL: W574
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 w575 EFFECT OF SWIRL : W575
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w576 W574 with heat transfer; EQUVEL=T : W576
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ both phases have equal velocity components
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 w577 2 PHASE DEMO - DP = 1.0E-4 : W577
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w578 2PHS FLOW IN TURNAROUND DUCT : W578
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ cartesian grid

Q1 w580 2 PH BACKWARD STEP,WITH GRAVITY :W580
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 w581 2-PHASE STEADY SEDIMENTATION; PARAB:W581
___ contains PHOTON USE commands for displaying results
___ NY = 1
___ steady parabolic flow
___ two-phase flow
___ cartesian grid

Q1 w700 W576 with extra cold light-phase inflow
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ both phases have equal velocity components
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 w771 1-D TRANSIENT SEDIMENTATION :W771
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w772 AS FOR RUN 771 BUT IN Y DIRECTION : W772
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w773 1-D SEDIMENTATION; parametric study:W773
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w775 2D channel flow as in tray column :W775
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w799 3D SHELL-AND-TUBE CONDENSER : W799
___ contains PHOTON USE commands for displaying results
___ two-phase flow
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 w800 AS FOR CASE W799 BUT TRANS. : W800
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ two-phase flow
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 w801 ALLOW FOR METAL CAPACITY : W801
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ two-phase flow
___ uses neighbour patch (name = NE...)
___ cartesian grid

Q1 w802 3D STEAM GENERATOR : W802
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ two-phase flow

Q1 w870 CF=1.E7 RHO2=10. POUT=-.5 W870
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w871 CF=1.E7 RHO2=10. POUT=3.0 : W871
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w872 CF=1.E7 RHO2=10. POUT=6.0 : W872
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w873 CF=0. RHO2=1.E3 POUT=-.5 : W873
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w874 CF=0. RHO2=10. POUT=-.5 : W874
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w875 CF=2.0 RHO2=10. POUT=-.5 : W875
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w876 CF=10. RHO2=10. POUT=-.5 : W876
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w877 CF=1.E3 RHO2=10. POUT=-.5 : W877
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w878 CF=1.E3 RHO2=1.0 POUT=-.5 : W878
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w879 CF=1.E7 RHO2=1.E2 POUT=-.5 : W879
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w880 CF=1.E7 RHO2=1.E3 POUT=-.5 : W880
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w885 Boiling Droplets in a Duct
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ body-fitted coordinates
___ two-phase flow
___ involves buoyancy
___ cartesian grid

Q1 w886 Boiling 2-Phase Flow in S-bend Duct:W886
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ body-fitted coordinates
___ two-phase flow
___ cartesian grid

Q1 w887 BOILING , NO GRAVITY : W887
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w888 BOILING , LONGITUDINAL GRAVITY : W888
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w889 BOILING ,TRANSVERSE GRAVITY : W889
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w890 MONOPROPELLANT ROCKET : W890
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ cartesian grid

Q1 w891 PROBLEM 2.4. SEDIMENTATION : W891
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w892 SEDIMENTATION WITH RHO2=0.2 : W892
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w893 SEDIMENTATION WITH SMALLER FRICTION W893
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w894 WATER DISPLACED BY AIR FROM ABOVE :W894
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w895 WATER DISPLACED BY AIR FROM BELOW :W895
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w896 COMPRESSION OF AIR BY WATER :W896
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ cartesian grid

Q1 w897 BOILING , NO GRAVITY : W897
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w898 BOILING , LONGITUDINAL GRAVITY : W898
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w899 BOILING ,TRANSVERSE GRAVITY : W899
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w900 STRATIFIED FLOW, CASE 1 CHANNEL : W900
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w901 STRATIFIED FLOW, CASE 2 PIPE : W901
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w902 TRANSIENT DRAINAGE FROM A PIPE W902
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w903 Kelvin-Helmholtz instability : W903
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w904 KELVIN-HELMHOLTZ; RHO1=1.01 : W904
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w905 KELVIN-HELMHOLTZ; RHO2=1.10 : W905
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w906 PROBLEM 3F RHO2=2.0 : W906
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w907 PROBLEM 3F RHO2=10.0 : W907
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w908 PROBLEM 3F RHO2=1.0;U2=0.;U1=2. : W908
___ contains Autoplot USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w909 TEE-JUNCTION : W909
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w917 PROBLEM 4.1 - 2D SEDIMENTATION : W917
___ time-dependent
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w918 STIRRED TANK; RUN1 STRONG STIRRING: W918
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w919 STIRRED TANK; RUN2 WEAK STIRRING : W919
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w920 STIRRED TANK; RUN3 NO STIRRING : W920
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ cylindrical grid
___ NX = 1
___ two-phase flow

Q1 w971 Rock2; 2D MONOPROPELLANT ROCKET :W971
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ two-phase flow
___ uses SHADOW method of size calculation
___ cartesian grid

Q1 w972 Stafford's saline-layer experiment
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

Q1 w974 Mixing in a duct; Two-Fluid Model :W97
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses two-fluid turbulence model
___ material indices set via SPEDAT
___ cartesian grid

Q1 w975 RUN1 COUETTE BUOY CONST=1.E2 : 975
___ time-dependent
___ NX = 1
___ NZ = 1
___ two-phase flow
___ uses two-fluid turbulence model
___ involves buoyancy
___ cartesian grid

Q1 w976 Backward-Facing Step;2-Fluid Model: 976
___ NX = 1
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses two-fluid turbulence model
___ material indices set via SPEDAT
___ cartesian grid

Q1 w977 Steady 2-fluid ducted flame; parab:W977
___ contains PHOTON USE commands for displaying results
___ NX = 1
___ steady parabolic flow
___ two-phase flow
___ uses ideal-gas law for density
___ uses two-fluid turbulence model
___ chemical sources
___ cartesian grid

Q1 w978 1D PISTON-IN-CYLINDER; 2-FLUID : 978
___ time-dependent
___ NX = 1
___ NY = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ uses two-fluid turbulence model
___ cartesian grid

Q1 w979 1-D transient shock-induced prpgtn :W979
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ NZ = 1
___ two-phase flow
___ uses isentropic-gas law for density
___ chemical sources
___ uses two-fluid turbulence model
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 w980 Flame spread in duct, 1D analysis
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ two-phase flow
___ cartesian grid

USP

Q1 u001 USP. 3D Steady Heat Conduction In Cube
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u002 3D Steady Heat Conduction In Cube
___ computes heat transfer
___ uses UnStructured PHOENICS
___ uses .dat file for VR object
___ cartesian grid

Q1 u003 USP. Conductivity task on divided grid
___ computes heat transfer
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ uses .dat file for VR object
___ cartesian grid

Q1 u004 2D HEAT CONDUCTION WITH SPACE DEPENDENT
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ cartesian grid

Q1 u005 USP 2D UNSTEADY DIFFUSION PROBLEM
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u006 Flow in porous media. USP Test 6.
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u007 USP labirinth.
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u008 USP labirinth with divided grid.
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u009 USP labirinth with conjugate heat transf
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u010 XY Duct, USP Test
___ NZ = 1
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ cartesian grid

Q1 u011 USP. Test 11
___ NZ = 1
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u012 Pot. Flow; Perpendicular Plate. USP Test
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u013 Flow Over Double-Wedge Airfoil. USP Test
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses .dat file for VR object
___ material indices set via SPEDAT
___ cartesian grid

Q1 u014 2DXZ Duct Flow; Effect Of Pr No. USP Tes
___ NY = 1
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u015 2D Laminar B-Layer On A Hot Wall
___ NX = 1
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u016 USP. Temperature in uniform flow
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ uses .dat file for VR object
___ cartesian grid

Q1 u017 USP. Laminar flow over step.
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u018 2D Flow in LID-DRIVEN cavity
___ NZ = 1
___ uses UnStructured PHOENICS
___ uses .dat file for VR object
___ cartesian grid

Q1 u019 USP. KE model
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u020 Test 20. Laminar flow around of cylinder
___ NY = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u021 Test 21 Flow around of cylinder (fine gr
___ NY = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u022 F-1 Car; Balsa Wood Blank; Visc. Flow
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u023 Test 23. Flow around small body.
___ NY = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u024 Test 24. Simple shapes by box In-Form ob
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ uses In-Form BOX function
___ cartesian grid

Q1 u025 Test 25. Flow around small body on divid
___ NY = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ uses .dat file for VR object
___ cartesian grid

Q1 u026 USP Test 26. Flow around small sphere.
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ uses .dat file for VR object
___ cartesian grid

Q1 u027 Laminar flow around of pyramid.
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u028 Two spheres In A Uniform Stream
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ uses .dat file for VR object
___ cartesian grid

Q1 u029 Turbulent flow near the wall, ENUT=const
___ uses UnStructured PHOENICS
___ uses .dat file for VR object
___ cartesian grid

Q1 u030 Flow in pipe. Effective viscosity.
___ uses UnStructured PHOENICS
___ material indices set via SPEDAT
___ cartesian grid

Q1 u031 Cubical Building, uniform turbulent Flow
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses .dat file for VR object
___ material indices set via SPEDAT
___ cartesian grid

Q1 u032 USP: T channel+Corr NUL.
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u033 Flow around of pyramid.
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u034 Flow in closed cavity.
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u035 Turb. flow in Square Cavity With Moving
___ NZ = 1
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ cartesian grid

Q1 u036 XY Duct, USP+SP Test
___ NZ = 1
___ cartesian grid

Q1 u037 2D CHANNEL
___ NZ = 1
___ uses UnStructured PHOENICS
___ uses In-Form STORED command
___ cartesian grid

Q1 u101 Couette Flow with Exact solution
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains properties set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 u103 Flow in channel with non-uniform viscosi
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains properties set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 u105 Stagnation point Flow
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ cartesian grid

Q1 u107 Cavity with moving lid and heat exchange
___ NZ = 1
___ uses UnStructured PHOENICS
___ cartesian grid

Q1 u109 Turn-around duct, laminar flow
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u110 Heat exchange in Tube Bank, trub. flow
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains properties set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u111 Cubical Building, K-E model, uniform Flo
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u113 Flow over backward step. LVEL model
___ NZ = 1
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ uses UnStructured PHOENICS
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u115 STAGUS: Turn-around duct
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ uses UnStructured PHOENICS
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u116 Turn-Around Duct with fastener. K-E mode
___ NX = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u201 Axi-symmetrical heat-conduction.
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u202 Axi-symmetrical heat-conduction.
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u501 USP: 2D xy plate in tension
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u502 USP: 2D xy Hot Bi-metallic plate
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u503 2D Plate in tension with FY=var
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u504 USP:2D xy Plate with CIRCULAR hole
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ material indices set via SPEDAT
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Q1 u505 USP: 2D xy Plate with square hole
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u506 USP: Cooled long cylinder
___ NZ = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u507 USP: Pressurised long cylinder
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u508 USP: Stress in a 2D rotating disk
___ NZ = 1
___ uses UnStructured PHOENICS
___ Q1 is used as PROPS file via MATFLG entries
___ computes stresses and strains in solids
___ uses In-Form STORED command
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 u701 Body with large Conductivity in uniform
___ NY = 1
___ computes heat transfer
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u710 Turn-around duct; Fine Grid
___ NZ = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 u711 2D Cylinder; 1,10,20 Grid
___ NX = 1
___ uses UnStructured PHOENICS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Chemical vapour deposition

Q1 d100 ASM Single Wafer Si Reactor - Wilke:D100
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d101 ASM Single Wafer Si Reactor - S-M :D101
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d102 ASM Single Wafer Si Reactor-Soret :D102
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d103 ASM Single Wafer Si3N4 Reactor :D103
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses CVD option for density
___ LVEL model
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d104 Tungsten Reactor - normal inlet :D104
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d105 Tungsten Reactor - showerhead inlet:D105
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d106 Simple Reactor Test Case :D106
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses CVD option for density
___ LVEL model
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d107 Batch Reactor Test Case :D107
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d108 Batch Reactor - super wafers :D108
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d109 Parallel Plate Plasma Reactor :D109
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses CVD option for density
___ LVEL model
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d201 SIMPLE FLOW TUBE TEST CASE - BATCH :D201
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d202 SIMPLE FLOW TUBE TEST CASE- COMPLEX:D202
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d203 Parallel Plate Plasma Reactor :D203
___ cylindrical grid
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT

Q1 d204 RADIATION TEST CASE - AXISYMMETRIC :D204
___ cylindrical grid
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 d205 RADIATION TEST CASE - XY :D205
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 d206 RADIATION TEST CASE - XZ :D206
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 d207 RADIATION TEST CASE - YZ :D207
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 d208 RADIATION TEST CASE - XYZ :D208
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 d209 SHOWER PLATE TEST- X :D209
___ NY = 1
___ uses volumetric block correction
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ CVD (chemical vapour deposition)
___ material indices set via SPEDAT
___ cartesian grid

FLAIR (air and heat flow in buildings

Q1 i101 Single room with a fire: I101
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i102 Smoke in a chimney: I102
___ time-dependent
___ NZ = 1
___ body-fitted coordinates
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i103 Fire in a building: I103
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i104 Fire in an underground train: I104
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i105 Air-Conditioning a supermarket: I108
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i106 Cleansing station: I106
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ contains sources set by In-Form
___ cartesian grid

Q1 i107 Exhaust dispersion near tower block:I107
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i108 A room with Sunlight
___ solves for LTLS
___ computes heat transfer
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i109 Flow in a computer room
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i110 A room with two radiators
___ computes WALL GAP
___ activates IMMERSOL
___ solves for LTLS
___ computes heat transfer
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i111 Room comfort
___ computes WALL GAP
___ activates IMMERSOL
___ solves for LTLS
___ computes heat transfer
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i112 Fire in a room
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i113 A cabinet with a fan
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i114 Tunnel Fire
___ time-dependent
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i120 YZ TEST: I120
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i121 Transient XY Test: I121
___ time-dependent
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i128 XY Test: I128
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i129 YZ TEST: I129
___ NX = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i130 1 Round_Diffuser_in_XY_plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i131 Round Diffuser in XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i132 Vortex Diffuser in XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i133 Square Diffuser in XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i134 4-way Directional Diffuser in X-Y plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i135 2 Grille Diffusers in X plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i136 Displacement Diffuser
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i137 Jetfan in XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i138 Round Diffuser in XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i200 My first flow simulation
___ solves for LTLS
___ computes heat transfer
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ contains sources set by In-Form
___ cartesian grid

Q1 i201 Room air flows; I201; zUP=T
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 i202 Reactor room: I202
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i203 Hackney hall: I203
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i204 Lecture theatre: I204
___ computes heat transfer
___ uses ideal-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i205 Computer room: I205
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i206 Flow inside a building: I206
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i207 Viking Ed Compressor Hazard: I207
___ computes heat transfer
___ uses ideal-gas law for density
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i208 Flow over Big Ben
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ cartesian grid

Q1 i209 Fire-Spray in a compartment
___ time-dependent
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ time-dependent source set by In-Form
___ contains sources set by In-Form
___ cartesian grid

Q1 i210 Food Court CFD Simulation: no vents
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 i211 Food Court CFD Simulation: with vents
___ solves for LTLS
___ computes WALL DISTANCE
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT
___ cartesian grid

Q1 i212 ASHRAE Displacement Diffuser
___ contains Viewer USE commands for displaying results
___ computes heat transfer
___ RNG high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 i213 Fire-Spray in a compartment
___ contains Viewer USE commands for displaying results
___ solves for LTLS
___ computes WALL DISTANCE
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ uses ideal-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ star-name patch: source=CO*PHI*NAME**VAL
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ contains properties set by In-Form
___ time-dependent source set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 i214 Fire and Smoke Modelling
___ time-dependent
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i215 Fire and Smoke Modelling
___ time-dependent
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i216 Fire and Smoke Modelling
___ time-dependent
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ contains sources set by In-Form
___ cartesian grid

Q1 i301 Square
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i302 round
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i303 Vortex
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i304 wedge - XY plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i305 wedge - XZ plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i306 wedge - YZ plane
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ material indices set via SPEDAT
___ cartesian grid

Q1 i307 square - rotated
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ Chen-Kim high-Re model
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ cartesian grid

Q1 i401 I401: Aerosol deposition in a model room
___ contains PHOTON USE commands for displaying results
___ uses ideal-gas law for density
___ RNG high-Re model
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ In-Form STORED command uses SUM(
___ cartesian grid

Q1 i402 I402: Deposition, horizontal duct @9m/s
___ contains PHOTON USE commands for displaying results
___ uses ideal-gas law for density
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 i403 I403: Deposition, horizontal duct@5.3m/s
___ contains PHOTON USE commands for displaying results
___ uses ideal-gas law for density
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 i404 I404: Deposition, horizontal duct@2.2m/s
___ contains PHOTON USE commands for displaying results
___ uses ideal-gas law for density
___ FLAIR, for heat and air flow in buildings
___ uses In-Form STORED command
___ In-Form used to "MAKE" variables
___ special print-out activated via SPEDAT
___ cartesian grid

Q1 i405 I405: Deposition, downpipe, Re=9.894E3
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ FLAIR, for heat and air flow in buildings
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 i406 I406: Deposition, downpipe, Re=5E4
___ contains PHOTON USE commands for displaying results
___ cylindrical grid
___ NX = 1
___ FLAIR, for heat and air flow in buildings
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ special print-out activated via SPEDAT

Q1 i407 I407: Aerosol deposition in a small room
___ computes heat transfer
___ uses ideal-gas law for density
___ RNG high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ FLAIR, for heat and air flow in buildings
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ special print-out activated via SPEDAT
___ uses In-Form STORED command
___ contains sources set by In-Form
___ cartesian grid

Furnace

Q1 a100 3-D coal combustion in a furnace : C111
___ contains PHOTON USE commands for displaying results
___ two-phase flow
___ uses SHADOW method of size calculation
___ uses 7gases option for density
___ use special GROUND furngr
___ cartesian grid

HOTBOX (electronics cooling)

Q1 h101 Tilted Box
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h102 Transient Flow In A Box
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NY = 1
___ computes heat transfer
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h103 PCB With 6 Chips
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h104 System curve calculation: H104
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h105 Experimental Box
___ contains PHOTON USE commands for displaying results
___ body-fitted coordinates
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h106 Cooling Of 12 Chips
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h107 Linear Heat Dissipation
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h108 Electronic System Rack
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h109 Telephone Exchange
___ contains PHOTON USE commands for displaying results
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h110 Fan matching: H110
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h111 Multiple Fan matching: H111
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h121 The Effect Of Enclosure Orientation
___ NZ = 1
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h122 Natural Cooling Of PQFP In An Enclosure
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h123 Natural Cooling Of PQFP Array
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h124 Thermal Interface Under PQFP
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h125 Typical PQFP On PCB In A Wind Channel
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h126 PCB With 6 Chips In An Angled Flow
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h127 Populated PCB In A Swirling Flow
___ uses volumetric block correction
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h128 AFT Module With Heat Sink
___ uses volumetric block correction
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h201 Air-Water Flow Through Cooling
___ NY = 1
___ uses volumetric block correction
___ computes heat transfer
___ computes WALL GAP
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h202 3D Model Of PQFP
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ cartesian grid

Q1 h205 Cooling Of 12 Chips - Smoke Test
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h206 Cooling of an Electronics Cabinet
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h301 Thermal Analysis Of PC Desktop Enclosure
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ cartesian grid

Q1 h302 Electronic System Rack
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h303 Electronic Unit With Heat Sink
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ uses conjugate-gradient solver
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 h304 Telephone Exchange
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h305 Table Top Control Box
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 h306 Cooling Of A Tower Case
___ uses volumetric block correction
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ LVEL model
___ involves buoyancy
___ HOTBOX for electronics cooling
___ uses conjugate-gradient solver
___ material indices set via SPEDAT
___ cartesian grid

Q1 h401 Planar Sources Attached To PCB
___ NX = 1
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses volumetric block correction
___ LVEL model
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ uses SPLINE function
___ cartesian grid

Q1 h402 Planar Sources/Heat Sink On Anisothropic
___ NX = 1
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses volumetric block correction
___ LVEL model
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ uses SPLINE function
___ cartesian grid

Q1 h403 A Composite Model Of PQFP
___ NX = 1
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h404 Recirculating Cooling Of A Package
___ NX = 1
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ contains sources set by In-Form
___ cartesian grid

Q1 h405 Closed Circuit Cooling Of A Package
___ NX = 1
___ solves for LTLS
___ computes WALL GAP
___ computes WALL DISTANCE
___ computes heat transfer
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Q1 h406 A simple model of laptop design: H406
___ NX = 1
___ computes WALL GAP
___ activates IMMERSOL
___ computes heat transfer
___ solves for LTLS
___ computes WALL DISTANCE
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ HOTBOX for electronics cooling
___ material indices set via SPEDAT
___ cartesian grid

Miscellaneous special-purpose programs

Q1 y101 SUPERSONIC FLOW IN DUCT : Y101
___ NZ = 1
___ uses isentropic-gas law for density
___ uses fine-grid-embedding
___ cartesian grid

Q1 y102 Flow over a cylinder: Y102
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y103 Flow over a cylinder: Y103
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y104 Flow over an inclined plate: Y104
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y105 SUPERSONIC FLOW OVER A WEDGE: Y105
___ NZ = 1
___ uses isentropic-gas law for density
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y106 Flow over a wedge: Y106
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y107 3D flow over a diamond-shaped object: Y1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y108 3D flow over a sphere and heat transfer
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y109 Flow over a heated sphere in a chamber
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y110 Flow over a sphere: Y110
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y111 Flow around a pipe junction: Y111
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y112 Turbulent flow around car shaped object
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y113 Drag and lift of two blocks
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ uses PLANT to create extra Fortran coding
___ cartesian grid

Q1 y114 Drag of rectangular box
___ contains PHOTON USE commands for displaying results
___ uses PLANT to create extra Fortran coding
___ cartesian grid

Q1 y115 Flow over an airfoil: Y115
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y116 Flow around submarine: Y116
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 y211 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 y212 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 y213 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 y214 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 y221 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 y222 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 y223 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 y231 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 y241 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 y242 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 y251 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 y261 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 y262 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 y400 ESTER demonstration, one-phase
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y401 ESTER demonstration, two-phase
___ two-phase flow
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y402 ESTER demo, Transient one-phase - Case 1
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y403 ESTER demo, Transient one-phase - Case 1
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y404 ESTER demo, Transient one-phase - Case 2
___ time-dependent
___ NX = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y405 ESTER demo, Transient one-phase - Case 3
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y406 ESTER demonstration, one-phase, KE-EP
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y407 ESTER demo, Transient one-phase - Case 1
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y408 ESTER demo, Transient one-phase - Case 1
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y409 ESTER demo, Transient one-phase - Case 2
___ time-dependent
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y410 ESTER demo, Transient one-phase - Case 3
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y411 ESTER demo, one-phase, KE-EP, fine grid
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y412 ESTER demonstration, one-phase
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y494 ESTER - full model of 36 Anode Cell
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y495 ESTER - full model of 24 Anode Cell
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y496
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 y497 ESTER default settings - 24 Anode Cell
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ use special GROUND ESTRgr
___ material indices set via SPEDAT
___ cartesian grid

Q1 y498
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 y499
___ NX = 1
___ NY = 1
___ NZ = 1
___ cartesian grid

Q1 y501 F1 Racing Car - Balsa Wood Blank (Coarse
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y502 F1 Racing Car - Balsa Wood Blank (Medium
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y503 F1 Racing Car - Balsa Wood Blank (Fine)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y504 GrandPrix Racing Car (Coarse)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y505 GrandPrix Racing Car (Medium)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y506 GrandPrix Racing Car (Fine)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y507 Jaguar Racing Car (Fine)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 y508 Design 2 R6 (Medium)
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

TACT, for natural-draft cooling towers

Q1 x100 COOLING_TOWER_SIMULATION
___ NX = 1
___ body-fitted coordinates
___ involves buoyancy
___ TACT for natural-draught cooling towers
___ cartesian grid

Q1 x101 COOLING_TOWER_SIMULATION 3D
___ body-fitted coordinates
___ involves buoyancy
___ TACT for natural-draught cooling towers
___ cartesian grid

Power Condensers

Q1 k100 2D Test Condenser
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ uses conjugate-gradient solver
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 k101 3D Test Condenser
___ solves for LTLS
___ computes WALL DISTANCE
___ uses conjugate-gradient solver
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 k102 2d 'Church-window' condenser
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ uses conjugate-gradient solver
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 k103 3d 'church-window' condenser
___ solves for LTLS
___ computes WALL DISTANCE
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses conjugate-gradient solver
___ contains properties set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

virtual reality

Q1 v100 Pressure Drop Across Porous Plate
___ cartesian grid

Q1 v101 T-Junction
___ material indices set via SPEDAT
___ cartesian grid

Q1 v102 Ink-Jet Simulation
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v103 Soaking Pit
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v104 Drill bit
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v105 Two Fans At Baffled Domain Boundary
___ computes heat transfer
___ cartesian grid

Q1 v106 Two Internal Fans; Baffled Domain
___ computes heat transfer
___ cartesian grid

Q1 v107 Two Circular Fans At Baffled Domain Boun
___ computes heat transfer
___ cartesian grid

Q1 v108 Two Circular Internal Fans; Baffled Doma
___ computes heat transfer
___ cartesian grid

Q1 v110 Walking Man
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v111 chemical reaction between stirred fluids
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v112 Falling box with broken tip
___ contains Viewer USE commands for displaying results
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v113 Moving multiple objects from carrier
___ time-dependent
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v114 Cylinder in chaotic motion
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v115 Cylinder moving at 45 degrees
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v116 Flow in crank-shaft-piston mechanism
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v117 Ejection seat
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v118 Underwater launch
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v119 Cube moving horizontally
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v120 Rolling cube: translation + rotation
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v121 Cube rotating about its centre
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v122 Stirring by rotating paddle
___ time-dependent
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v123 Trains passing in a tunnel
___ time-dependent
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v124 2 cylinders with crossing trajectories
___ time-dependent
___ NX = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v125 2 cylinder engine
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v126 Flow in 2-crank-shaft-piston mechanism
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v127 Moving ski-jumper via MOFOR
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v128 Sphere in horizontal motion
___ time-dependent
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v129 2-D methane-air combustion, EBU model
___ cylindrical grid
___ NX = 1
___ uses SCRS option for density
___ chemical sources with eddy-break-up model

Q1 v130 Heat source on face of 198 XZ plane lam
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v131 Heat source on face of 198 XY plane turb
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v132 Heat source on face of 198 XZ plane turb
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v133 Heat source on face of 198 XY plane lam
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v134 Flow in crank-shaft-piston mechanism
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v135 T-Junction
___ material indices set via SPEDAT
___ cartesian grid

Q1 v136 NACA wing Cd test ( angle 2.8)
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v137 Flow through channels cut from solid
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v138 FGE: 2D Flow around a cylinder - 2 FGV
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 v139 FGE: 2D Flow around a cylinder - 1 FGV
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 v140 FGE: 2D Flow around a cylinder - No FGV
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v141 FGE: 2D Flow around a cylinder PARSOL=F
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v142 Inclined Channel; grid 152,152,1
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v143 cartes hollow ps
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v144 No title has been set for this run.
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v145 Potential Flow Over Circular Cylinder
___ NX = 1
___ solves for VELOCITY POTENTIAL
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v146 Non-uniform heat source in vr-object
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ contains initial values set by In-Form
___ cartesian grid

Q1 v147 Heat exchange about a array of pipes.
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains initial values set by In-Form
___ contains sources set by In-Form
___ In-Form used to "MAKE" variables
___ In-Form STORED command uses SUM(
___ uses In-Form STORED command
___ special print-out activated via SPEDAT
___ material indices set via SPEDAT
___ contains sources set by In-Form
___ contains initial values set by In-Form
___ cartesian grid

Q1 v148 Heat exchange about a steel conductor
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v149 Heat transfer from air in pipe to outsid
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v150 Device for turning flow
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v151 Device for changing flow direction
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v152 Temperature-controlled fan
___ contains PHOTON USE commands for displaying results
___ time-dependent
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ In-Form used to "MAKE" variables
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 v153 Heat exchange about a single pipe
___ contains PHOTON USE commands for displaying results
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v154 Heat exchange by one side internal plate
___ NZ = 1
___ computes heat transfer
___ contains sources set by In-Form
___ cartesian grid

Q1 v155 Heat exchange by two sides internal plat
___ NZ = 1
___ computes heat transfer
___ contains sources set by In-Form
___ cartesian grid

Q1 v156 Heat exchange by external plates.
___ NZ = 1
___ computes heat transfer
___ uses SPLINE function
___ contains sources set by In-Form
___ cartesian grid

Q1 v160 ATMOSPHERIC B.L - XZ LL TEST
___ NY = 1
___ cartesian grid

Q1 v161 ATMOSPHERIC B.L - YZ LL TEST
___ NX = 1
___ cartesian grid

Q1 v162 ATMOSPHERIC B.L - ZX LL TEST
___ NY = 1
___ cartesian grid

Q1 v163 ATMOSPHERIC B.L - ZX PL TEST
___ NY = 1
___ cartesian grid

Q1 v164 ATMOSPHERIC B.L - ZX PL TEST
___ NY = 1
___ cartesian grid

Q1 v165 ATMOSPHERIC B.L - ZX PL TEST
___ NY = 1
___ cartesian grid

Q1 v166 ATMOSPHERIC B.L -3DYZ-E LL TEST
___ cartesian grid

Q1 v167 ATMOSPHERIC B.L - 3DYZW LL TEST
___ cartesian grid

Q1 v168 No title has been set for this run.
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v169 No title has been set for this run.
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v170 MOFOR + porous plate test
___ time-dependent
___ NZ = 1
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v172 Louver flow; 120*135 grid
___ NZ = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v173 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v174 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v175 ANGLED-IN Test - Velocity
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v176 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v177 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v178 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v180 Y-dir test of deduced inflow vel at edge
___ NX = 1
___ Chen-Kim high-Re model
___ contains sources set by In-Form
___ cartesian grid

Q1 v181 Y-dir test of deduced inflow vel at edge
___ NX = 1
___ Chen-Kim high-Re model
___ contains sources set by In-Form
___ cartesian grid

Q1 v182 Y-dir test of deduced inflow vel at edge
___ NX = 1
___ Chen-Kim high-Re model
___ contains sources set by In-Form
___ cartesian grid

Q1 v183 Heat source on surface of 198 XZ plane l
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v184 Heat source on surface of 198 XZ plane t
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v201 Flow Around A Car; fine-grid embedding
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses fine-grid-embedding
___ material indices set via SPEDAT
___ cartesian grid

Q1 v202 2D Piston
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v203 Flow Past A Moving Cylinder
___ time-dependent
___ NZ = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses MOFOR
___ material indices set via SPEDAT
___ cartesian grid

Q1 v204 Inlets in Polar Grid
___ cylindrical grid
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v205 Angled Inlets in Polar Grid
___ cylindrical grid
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v206 angled plate(s) in xz plane caseno=0
___ contains Viewer USE commands for displaying results
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v207 Moving sphere with constant accelaration
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses PLANT to create extra Fortran coding
___ time-dependent source set by In-Form
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v208 Moving sphere with varing accelaration
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses PLANT to create extra Fortran coding
___ time-dependent source set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v209 Falling sphere with air resistance
___ contains Viewer USE commands for displaying results
___ time-dependent
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses PLANT to create extra Fortran coding
___ time-dependent source set by In-Form
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 v301 Supersonic Flow In A Duct
___ NZ = 1
___ uses isentropic-gas law for density
___ uses fine-grid-embedding
___ cartesian grid

Q1 v401 Simulation Of A Labyrinth Flow
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v402 Duplication of Objects
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v404 Array And Group Settings
___ NY = 1
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v405 Flow In A Pipe
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v406 Jet Pump
___ NY = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v407 Flow Around Buildings
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v408 Flow Over Heated Bricks
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v409 Fans and Inlets
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v410 Fans And Inlets - Inlet/Outlet
___ NY = 1
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v411 Flow In A Closed Cavity
___ NY = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 v412 Axi-symmetric Jet Pump
___ cylindrical grid
___ NX = 1
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v413 Swirling flow without straightener
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v414 Swirling flow with straightener
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v415 Supersonic flow in a duct
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 v416 Supersonic flow in a duct - UMIST scheme
___ NZ = 1
___ computes heat transfer
___ uses ideal-gas law for density
___ Prndtl Mixing-Length model
___ cartesian grid

Q1 v500 A Tube With Spiral Rib
___ cylindrical grid
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ involves buoyancy
___ material indices set via SPEDAT

Q1 v501 Flow In A Screw Pump
___ cylindrical grid
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v502 Two-Pass Tube Heat Exchanger
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v503 Water Currents In A River Course
___ solves for LTLS
___ computes WALL DISTANCE
___ LVEL model
___ material indices set via SPEDAT
___ cartesian grid

Q1 v600 Parallel plates with uniform temperature
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v601 Parallel plates with uniform temperature
___ 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 v602 Parallel plates with uniform temperature
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v603 Parallel plates with uniform temperature
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v604 Parallel plates with uniform temperature
___ 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 v605 Parallel plates with uniform temperature
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v606 Parallel plates with uniform temperature
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v607 Parallel plates with uniform temperature
___ 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 v608 Parallel plates with uniform temperature
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v609 Parallel plates with uniform temperature
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v610 Parallel plates with uniform temperature
___ 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 v611 Parallel plates with uniform temperature
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v612 PARSOL 1D HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ 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 v613 PARSOL 1D HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v614 PARSOL 1D HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v615 PARSOL 1D HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v616 PARSOL 1D-X HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v617 PARSOL 1D-Z HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v618 PARSOL 1D-X HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v619 PARSOL 1D-Z HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v620 PARSOL 1D-X HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v621 PARSOL 1D-Z HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v622 PARSOL 1D-X HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v623 PARSOL 1D-Z HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v624 PARSOL 1D-X HEAT TRANSFER
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v625 PARSOL 1D-Z HEAT TRANSFER
___ NX = 1
___ NY = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ contains sources set by In-Form
___ material indices set via SPEDAT
___ cartesian grid

Q1 v626 CONJUGATE HEAT TRANSFER OF A WEDGE IN F
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v627 CONJUGATE HEAT TRANSFER OF A WEDGE IN F
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v628 CONJUGATE HEAT TRANSFER OF A WEDGE IN F
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v629 CONJUGATE HEAT TRANSFER OF A WEDGE IN F
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v630 cylinder
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v631 cylinder
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v632 cylinder
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v633 cylinder
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v634 cylinder
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v635 cylinder
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v636 cylinder
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v637 cylinder
___ NX = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v638 Angular Velocity IURVAL=-1 Inflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form

Q1 v639 Angular Velocity IURVAL=-1 Outflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form

Q1 v640 Angular Momentum IURVAL=+1 Inflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form

Q1 v641 Angular Momentum IURVAL=+1 Outflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form

Q1 v642 Velocity IURVAL= 0 Inflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT

Q1 v643 Velocity IURVAL= 0 Outflow
___ cylindrical grid
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ contains sources set by In-Form

Q1 v650 cut cell heat conduction testing case
___ NY = 1
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v701 No title has been set for this run.
___ Chen-Kim high-Re model
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v703 NEWPARSOL, 1D heat-conduction in x dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ 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 v704 NEWPARSOL, 1D heat-conduction in y dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ 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 v705 NEWPARSOL, 1D heat-conduction in z dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ 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 v706 NEWPARSOL, 1D heat-conduction in x dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NY = 1
___ NZ = 1
___ 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 v707 NEWPARSOL, 1D heat-conduction in y dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NZ = 1
___ 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 v708 NEWPARSOL, 1D heat-conduction in z dir
___ contains PHOTON USE commands for displaying results
___ contains Autoplot USE commands for displaying results
___ NX = 1
___ NY = 1
___ 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 v709 2D PARSOL heat-conduction, xy plane
___ contains PHOTON USE commands for displaying results
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ uses In-Form STORED command
___ material indices set via SPEDAT
___ cartesian grid

Q1 v710 Ellipsoid simulation
___ NZ = 1
___ computes heat transfer
___ Q1 is used as PROPS file via MATFLG entries
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v711 Wall Distance Distribution Within A Box
___ NZ = 1
___ computes WALL DISTANCE
___ computes WALL GAP
___ solves for LTLS
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v712 Couette Flow In Inclined Channel
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Q1 v713 Flow near cylinder
___ NZ = 1
___ computes heat transfer
___ fiinit(prps) = -1, so use PIL properties for domain fluid
___ material indices set via SPEDAT
___ cartesian grid

Contents