PC-Aided Numerical Heat Transfer and Convective Flow

IntroductionBackgroundPC-Aided Numerical Heat TransferOutline of the BookGoverning Equations for Flow and Heat TransferTransformation From the System Form to the Control Volume FormEquation of ContinuityMomentum EquationEnergy EquationComplete Set of Governing Equations and Their Simplified FormGeneral Transport EquationAnalytical Treatments for Boundary Layer EquationsNumerical Integration of Ordinary Differential EquationsTransient Conduction in a Semi-Infinite SolidBoundary Layer Approximation for Heat and Fluid FlowForced Convection From Concentrated Heat SourcesLaminar Forced Convection From Plane BodiesLaminar Forced Convection From Axisymmetric BodiesAsymptotic Solutions for Forced Convection of Small and Large Prandtl Number FluidsIntegral Method for Laminar Forced ConvectionLaminar Free Convection From Plane BodiesIntegral Method for Laminar Free ConvectionTransport Equations for Modeling TurbulenceReynolds-Averaged Navier-Stokes Equation and Energy EquationEffective Viscosity Formulation and Mixing Length ModelsWall Laws for Turbulent Shear FlowsTurbulent Free jetsReynolds Stress Transport EquationTurbulence Kinetic Energy Transport Equation and Two-Equation ModelLow Reynolds Number Model and High Reynolds Number ModelConvective Flows in Porous MediaDarcy's LawModified Darcy's LawsVolume-Averaged Navier-Stokes EquationVolume-Averaged Energy EquationEffects of Channeling and Thermal DispersionMagnitude Analysis on Boundary Layer Equations for Porous MediaDarcy-Forchheimer Boundary Layer EquationsSimple Flow Cases: Isothermal Flat PlatesModified Peclet Number and Flow Regime MapUnified Treatment for Darcy-Forchheimer Boundary Layer EquationsForced Convection RegimeDarcy Free Convection RegimeForchheimer Free Convection RegimeIntermediate Flow RegimesConvective Flows Over an Impermeable Horizontal SurfaceBuoyancy-Induced Flows From Concentrated Heat SourcesBoundary Layer Flow and Heat Transfer in Highly Porous MediaDescription of Numerical Solution ProcedureBasic Concept of DiscretizationGoverning Equations and Auxiliary RelationshipsGeneral Form of Governing Equations: General Transport EquationCoordinate System and NormalizationDiscretization of General Transport EquationStaggered Grid and Discretized Momentum EquationsPressure Correction Procedure: SIMPLEHigh Flux Modification: Hybrid Difference SchemeSolution of Discretized EquationsPC Program "SAINTS" For Conduction and Convection ProblemsOverall Aspect of the Program "SAINTS"Classification of BoundariesSpecification of Non-Zero Boundary Values Along the Known-Velocity BoundaryDescription of the Program "SAINTS"Input Procedure: Input Data and Problem-Dependent SubprogramsLayout of OutputIllustrative Applications of "SAINTS"Applications of the SAINTS Load Module "Wind Tunnel Simulator"Illustrative Applications to Conduction ProblemsFurther Application of SAINTS to Complex Turbulent FlowsApplications to Convection Problems in Porous MediaConcluding RemarksAppendicesImportant Dimensionless NumbersPotential Flow Analysis Based on Source-and-Sink MethodListing of Program "SAINTS"Listing of Problem Dependent Subroutine "USERIN"Input Data for Forced Convection in a TubeSample Output of Program "SAINTS"Program InstructionsReferencesIndex