Introduction to Computational Fluid Dynamics, An

Chapter 1 Introduction

Chapter 2 Conservation laws of fluid motion and their boundary conditions

Chapter 3 Turbulence and its modelling

Chapter 4 The finite volume method for diffusion problems

Chapter 5 The finite volume method for convection-diffusion problems

Chapter 6 Solution algorithms for pressure-velocity coupling in steady flows

Chapter 7 Solution of systems of discretised equations

Chapter 8 The finite volume method for unsteady flows

Chapter 9 Implementation of boundary conditions

Chapter 10 Uncertainty in CFD modelling

Chapter 11 Methods for dealing with complex geometries

Chapter 12 CFD modelling of combustion

Chapter 13 Numerical calculation of radiative heat transfer

Appendices

References

Index

Texte du rabat

The use of Computational Fluid Dynamics to simulate and predict fluid flows, heat transfer and associated phenomena continues to grow throughout many engineering disciplines. On the back of ever more powerful computers and graphical user interfaces CFD provides engineers with a reliable tool to assist in the design of industrial equipment often reducing or eliminating the need for performing trial-and-error experimentation.

An Introduction to Computational Fluid Dynamics is the ideal text for the newcomer to the area whether they be undergraduates, graduates, or professionals. It provides thorough yet accessible coverage of commercial finite volume based CFD codes within the context of the underlying theory, giving the reader a full appreciation of CFD and its numerous engineering applications.

Key features

• Offers essential support for novice users of commercial CFD codes such as ANSYS CFX, FLUENT, STAR-CD and PHOENICS.
• Covers fluids and turbulence physics together with computational modelling techniques
• Uses a step-by-step approach to introduce the methodology

• Chapter summaries and worked examples throughout to reinforce understanding of the key concepts
  New to this edition

• A new chapter describing unstructured meshing techniques
• A new chapter on CFD uncertainty
• New coverage of the fundamentals of Large-Eddy Simulation (LES) and Direct Numerical Simulation (DNS) techniques
• Summaries of TVD techniques and multi-grid solution techniques
• Added examples of the SIMPLE algorithm for pressure-velocity coupling
• Two new chapters with advanced material covering combustion and radiative heat transfer modelling
  H K Versteeg and W Malalasekera are both senior lecturers in Thermo-Fluids, at Loughborough University.

Résumé
Provides coverage of Computational Fluid Dynamics (CFD) codes within the context of the underlying theory, giving the reader an appreciation of CFD and its numerous engineering applications. This work includes coverage of the fundamentals of Large-Eddy Simulation (LES) and Direct Numerical Simulation (DNS) techniques.

Contenu

Chapter 1 Introduction

Chapter 2 Conservation laws of fluid motion and their boundary conditions

Chapter 3 Turbulence and its modelling

Chapter 4 The finite volume method for diffusion problems

Chapter 5 The finite volume method for convection-diffusion problems

Chapter 6 Solution algorithms for pressure-velocity coupling in steady flows

Chapter 7 Solution of systems of discretised equations

Chapter 8 The finite volume method for unsteady flows

Chapter 9 Implementation of boundary conditions

Chapter 10 Uncertainty in CFD modelling

Chapter 11 Methods for dealing with complex geometries

Chapter 12 CFD modelling of combustion

Chapter 13 Numerical calculation of radiative heat transfer

Appendices

References

Index