Page 606 - Modelling in Transport Phenomena A Conceptual Approach
P. 606
Index
Analogy in tube flow, 336
between diffusivities, 25
between transfer coefficients, 54 Biot number (heat transfer), 184
Chilton-Colburn analogy, 57 Biot number (mass transfer), 184
Reynolds analogy, 56 Brinkman number, 373
Annulus Bulk concentration, 66
axial laminar flow, 337 Bulk temperature, 66
flow with inner cylinder moving Chemical reaction
axially, 241 autocatalytic, 146
Antoine equation, 575 Effectiveness factor for, 300
Archimedes number, 74 heterogeneous, 295
Area averaging homogeneous, 295
diffusion and reaction in catalyst, Chilton-Colburn analogy, 57
297 Circular tube, see Tube
fin, 278 Coefficient of volume expansion, 158
forced convection heat transfer, Composite walls, heat conduction in,
362 252
forced convection mass transfer, Conduction, see Heat conduction
386 Conductivity, thermal, see Thermal
unsteady flow in tube, 479 conductivity
Arrhenius rate constant, definition, 146 Conservation of chemical species
Average concentration steady-state, 150
area, 297 unsteady-state, 185
bulk or mixing-cup, 66 Conservation of energy
film, 66 steady-state, 156
Average temperature unsteady-state, 198
Area, 278 Conservation of mass
bulk or mixing-cup, 66 steady-state, 152
film, 66 unsteady-state, 186
Average velocity Conservation of momentum, 194
between parallel plates, 329 Constitutive equation, 2
in annular Couette flow, 243 Conversion factors, 584
in annulus, 339 Couette flow
in falling film, 333 between parallel plates, 238
in plane Couette flow, 241 heat transfer, 283
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