Cover
Title Page
Copyright Page
Contents
Preface
Acknowledgments
1 Conservation Laws in Thermal-Fluid Sciences
1.1 Conservation Laws in Integral Form
1.2 Conservation Laws in Differential Form
1.3 Special Cases
1.4 General Form of the Conservation Laws
1.5 Cartesian, Cylindrical, and Spherical Coordinates
2 Introduction to Computational Fluid Dynamics Using the Finite Volume Method
2.1 What Is Computational Fluid Dynamics?
2.2 The Building Blocks of a CFD Solution Method
2.3 Numerical Representation of the Domain
2.4 The Finite Volume Method
2.5 Solving of the Linear System of Equations
2.6 Integration in Time for Unsteady Flow
2.7 The Navier-Stokes Equations
2.8 Boundary Conditions
2.9 Solution Verification
3 Two-Dimensional Steady State Laminar Incompressible Fluid Flow
3.1 Introduction
3.2 Problem Statement
3.3 Governing Equations and Boundary Conditions
3.4 Modeling Using Fluent
3.5 Verification
4 Three-Dimensional Steady State Turbulent Incompressible Fluid Flow
4.1 Introduction to Turbulence
4.2 Turbulence Modeling
4.3 Problem Statement
4.4 Governing Equations and Boundary Conditions
4.5 Modeling Using Fluent
4.6 Verification
5 Convection Heat Transfer for Two-Dimensional Steady State Incompressible Flow
5.1 Introduction to Heat Transfer
5.2 Problem Statement
5.3 Governing Equations and Boundary Conditions
5.4 Modeling Using Fluent
5.5 Verification
6 Three-Dimensional Fluid Flow and Heat Transfer Modeling in a Heat Exchanger
6.1 Introduction to Heat Exchangers
6.2 Problem Statement
6.3 Modeling Using Fluent
6.4 Verification
7 Three-Dimensional Fluid Flow and Heat Transfer Modeling in a Heat Sink
7.1 Introduction to Heat Sinks
7.2 Problem Statement
7.3 Modeling using Fluent
7.4 Verification
References
A Upwind Schemes to Evaluate the Advection Term
B Time Integration Schemes
C Instructions to Download ANSYS
D SpaceClaim Tutorials
Index.