《计算流体动力学导论:有限体积法》是2010年世界图书出版公司出版的图书，作者是费斯泰赫(H.K.Versteeg)。

• 中文名 计算流体动力学导论:有限体积法
• 定价 69.00元
• 出版社 世界图书出版公司
• 作者 费斯泰赫(H.K.Versteeg)
• 出版时间 2010年4月1日

内容简介

　　《计算流体动力学导论:有限体积法(第2版)(英文版)》内容简介:We were pleasantly surprised by the ready acceptance of the first edition of our book by the CFD commun治斗挥病数群齐敌造确受ity and by the amount of positive feedback received over a 此处互准period of 10 years. To us this has provided justification of our original plan, whi来自ch was to provide an accessible introduction to this fast-growing topic to support teaching at senior undergraduate level, post- graduate research and new industrial users of commercial CFD codes. Our second edition see鲁老围任远秋终伯ks to enhance and update. The structure a360百科nd didactic approach of the first edition have been retained without change, but aug- mented by a selection of the 干愿章目补张most important developmen裂注全除训ts in CFD.

图书目录

　　Preface

　　Acknowledgements

　　1 Introduct朝苦仍滑ion

　　1.1 What is CFD?

　　1.2 How does a CFD code work?

　　1.3 Problem solving with CFD

　　1.4 Scope of this book

　　2 Conservat图ion laws of fluid motion and boundary conditions

　素具鸡机爱科　2.1 Governing equations of fluid flow and heat transfer

　　2.2 Equations of state

　　2.3 N曲流还引要煤阶星avier-Stokes equations for a Newtonian fluid

　　2.4 Conservative form of the governing equations of fluid flow

　　2.5 Differential and integral forms of the general transport equations

　　2.6 Classification of physical behaviours

　　2.7 The role of characteristics in hyperbolic equat免没省ions

　　2.8 Classification method for simple PDEs

　　2.9 Classification of fluid flow equations

　　2.10 Auxiliary conditions for viscous fluid flow equations

　　2.好11 Problems in 力度特行土transonic and supersonic compressible flows

　　2.12 Summary

　　3 Turbulence and its 府钱料孩断半modelling

　　3.1 What is turbulence?

　　3.2 Transition from laminar to tur士湖绿德和套自吗提部过bulent }low

　　3.3 万足出置盐Descriptors of tu可朝包茶零践孔随rbulent flow

　　3.4 Characteristics of simple turbulent flows

　　3.5 The effect of turbulent fluctuati述罗举拿据么特ons on properties of the mean flow

　　3.6 Turbulent flow calculations

　　3.7 Reynolds-averaged Navier-Stokes equatio感好一地怕异ns and classical turbulence models

　　3.8 Large eddy simulation

　　3.9 Direct numerical simulation

　　3.10 Summary

　　4 The finite volume method for diffusion problems

　　4.1 Introduction

　　4.2 Finite volume method for one-dimensional steady state diffusion

　　4.3 Worked examples: one-dimensional steady state diffusion

　　4.4 Finite volume method for two-dimensional diffusion problems

　　4.5 Finite volume method for three-dimensional diffusion problems

　　4.6 Summary

　　5 The finite volume method for convection-diffusion problems

　　5.1 Introduction

　　5.2 Steady one-dimensional convection and diffusion

　　5.3 The central differencing scheme

　　5.4 Properties of discretisation schemes

　　5.5 Assessment of the central differencing scheme for convectiondiffusion problems

　　5.6 The upwind differencing scheme

　　5.7 The hybrid differencing scheme

　　5.8 The power-law scheme

　　5.9 Higher-order differencing schemes for convection-diffusion problems

　　5.10 TVD schemes

　　5.11 Summary

　　6 Solution algorithms for pressure-velocity

　　6.1 Introduction

　　6.2 The staggered grid

　　6.3 The momentum equations

　　6.4 The SIMPLE algorithm

　　6.5 Assembly ora complete method

　　6.6 The SIMPLER algorithm

　　6.7 The SIMPLEC algorithm

　　6.8 The PISO algorithm

　　6.9 General comments on SIMPLE, SIMPLER, SIMPLEC and PISO

　　6.10 Worked examples of the SIMPLE algorithm

　　6.11 Summary

　　7 Solution of discretised equations

　　7.1 Introduction

　　7.2 The TDMA

　　7.3 Application of the TDMA to two-dimensional problems

　　7.4 Application of the TDMA to three-dimensional problems

　　7.5 Examples

　　7.6 Point4terative methods

　　7.7 Multigrid techniques

　　7.8 Summary

　　8 the finite volume method for unsteady flows

　　8.1 Introduction

　　8.2 One-dimensional unsteady heat conduction

　　8.3 Illustrative examples

　　8.4 Implicit method for two- and three-dimensional problems

　　8.5 Discretisation of transient convection-diffusion equation

　　8.6 Worked example of transient convection-diffusion using QUICK differencing

　　8.7 Solution procedures for unsteady flow calculations

　　8.8 Steady state calculations using the pseudo-transient approach

　　8.9 A brief note on other transient schemes

　　8.10 Summary

　　9 Implementation of boomfary confftions

　　9.1 Introduction

　　9.2 Inlet boundary conditions

　　9.3 Outlet boundary conditions

　　9.4 Wall boundary conditions

　　9.5 The constant pressure boundary condition

　　9.6 Symmetry boundary condition

　　9.7 Periodic or cyclic boundary condition

　　9.8 Potential pitfalls and final remarks

　　10 Errors and uncertainty in CFD modelling

　　10.1 Errors and uncertainty in CFD

　　10.2 Numerical errors

　　10.3 Input uncertainty

　　10.4 Physical model uncertainty

　　10.5 Verification and validation

　　10,6 Guidelines for best practice in CFD

　　10.7 Reporting/documentation of CFD simulation inputs and results

　　10.8 Summary

　　11 Methods for dealing with complex geometries

　　11.1 Introduction

　　11.2 Body-fitted co.ordinate grids for complex geometries

　　11.3 Catesian vs. curvilinear grids - an example

　　11.4 Curvilinear grids - difficulties

　　11.5 Block-structured grids

　　11.6 Unstructured grids

　　11.7 Discretisation in unstructured grids

　　11.8 Discretisafion of the diffusion term

　　11.9 Discretisafion of the convective term

　　11.10 Treatment of source terms

　　11.11 Assembly of discretised equations

　　11.12 Example calculations with unstructured grids

　　11.13 Pressure-velocity coupling in unstructured meshes

　　11.14 Staggered vs. co-located grid arrangements

　　11.15 Extension of the face velocity interpolation method to unstructured meshes

　　11.16 Summary

　　12 CFD modelling of combustion

　　12.1 Introduction

　　12.2 Application of the first law of thermodynamics to a combustion system

　　12.3 Enthalpy of formation

　　12.4 Some important relationships and properties of gaseous mixtures

　　12.5 Stoichiometry

　　12.6 Equivalence ratio

　　12.7 Adiabatic flame temperature

　　12.8 Equilibrium and dissociation

　　12.9 Mechanisms of combustion and chemical kinetics

　　12.10 Overall reactions and intermediate reactions

　　12.11 Reaction rate

　　12.12 Detailed mechanisms

　　12.13 Reduced mechanisms

　　12.14 Governing equations for combusting flows

　　12.15 The simple chemical reacting system (SCRS)

　　12.16 Modelling of a laminar diffusion flame - an example

　　12.17 CFD calculation of turbulent non-premixed combustion

　　12.18 SCRS model for turbulent combustion

　　12.19 Probability density function approach

　　12.20 Beta pdf

　　12.21 The chemical equilibrium model

　　12.22 Eddy break-up model of combustion

　　12.23 Eddy dissipation concept

　　12.24 Laminar flamelet model

　　12.25 Generation oflaminar, flamelet libraries

　　12.26 Statistics of the non-equilibrium parameter

　　12.27 Pollutant formation in combustion

　　12.28 Modelling of thermal NO formation in combustion

　　12.29 Flamelet-based NO modelling

　　12.30 An example to illustrate laminar flamelet modelling and NO modelling of a turbulent flame

　　12.31 Other models for non-premixed combustion

　　12.32 Modelling ofpremixed combustion

　　12.33 Summary

　　13 Numedcal calculation of radiative heat transfer

　　13.1 Introduction

　　13.2 Governing equations of radiative heat transfer

　　13.3 Solution methods

　　13.4 Four popular radiation calculation techniques suitable for CFD

　　13.5 Illustrative examples

　　13.6 Calculation of radiative properties in gaseous mixtures

　　13.7 Summary

　　Appendix A Accuracy of a flow simulation

　　Appendix B Non-uniform grids

　　Appendix C Calculation of source terms

　　Appendix D Limiter functions used in Chapter 5

　　Appendix E Derivation of one-dimensional governing equations for steady, incompressible flow through a planar nozzle

　　Appendix F Alternative derivation for the term (n . grad Ai) in Chapter 11

　　Appendix G Some examples

　　Bibliography

　　Index