Advances in numerical heat transfer

This is the first volume in the series. It analyzes several fundamental methodology issues in numerical heat transfer and fluid flow and identifies certain areas of active application. The finite-volume approach is presented with the finite-element methods as well as with energy balance analysis. Applications include the latest development in turbulence modeling and current approaches to inverse problems.

1.Bounded Higher-Order Upwind Multidimensional Finite-Volume Convection-Diffusion Algorithms 2. Advances in Computation of Heat Transfer, Fluid Flow, and Solid Body Deformation Using Finite Volume Approaches 3.Control-Volume Finite Element Methods for Fluid Flow and Heat Transfer 4.General Algorithms for the Finite Element Solution of Incompressible Flow Proteins Using Primitive Variables 5.Two-Equation and Second-Moment Turbulence Models for Convective Heat Transfer 6.Multi-Resolution Computation for Fluid Flow and Heat/Mass Transfer 7.Multigrid Methods for Internal Flows and Heat Transfer 8.An Overview of Recent Advances and Computational Methods for Thermal Problems 9.An Overview of Numerical Methods for Solving Phase Change Problems 10.Inverse Shape and Boundary Condition Problems and Organization in Heat Conduction 11.Index

This volume discusses the advances in numerical heat transfer modeling by applying high-performance computing resources, striking a balance between generic fundamentals, specific fundamentals, generic applications, and specific applications.

1.High-Perfomance Computing for Fluid Flow and Heat Transfer 2.Unstructured Finite Volume Methods for Multi-Mode Heat Transfer 3.SpectralElement Methods for Unsteady Fluid Flow and Heat Transfer in Complex Geometries:Methodology and Applications 4.Finite-Volume Method for Radiation Heat Transfer 5.Boundary Element Methods for Heat Conduction 6.Molecular Dynamics Method for Microscale Heat Transfer 7.Numerical Methods in Microscale Heat Transfer:Modeling of Phase-Change and Laser Interactions with Materials 8.Current Status of the Use of Parallel Computing in Turbulent Reacting Flows:Computations Involving Sprays, Scalar Monte Carlo Probability Density Function and Unstructured Grids 9.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Forced Convection and Multiphase Heat Transfer 10.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Natural and Mixed Convection 11.Recent Progress and Some Challenges in Thermal Modeling of Electronic Systems 12.Index