传热与流体流动的数值计算

作　者：	苏哈斯·V 帕坦卡
出版社：	世界图书出版有限公司
丛编项：
版权说明：	本书为公共版权或经版权方授权，请支持正版图书
标　签：	暂缺

ISBN	出版时间	包装	开本	页数	字数
未知	暂无	暂无	未知	0	暂无

作者简介

　　苏哈斯·V. 帕坦卡（Suhas V. Patankar，1941年2月22日－）是拥有印度、美国双重国籍的机械工程学家，明尼苏达大学荣誉退休教授，专长于计算流体力学。

内容简介

To illustrate the application of the material，problems are given at the end of some chapters. Most of the problems can be solved by using a pocket calculator，although some of them should be programmed for a digital computer.The problems are not meant for testing the student reader，but are included primarily for extending and enriching the learning process. They suggest alternative techniques and present additional material. At times，in my attempt to give a hint for the problem solution，I almost disclose the full answer. In such cases，arriving at the correct answer is not the main objective;the reader should focus on the message that the problem is designed to convey.This book carries the description of the numerical method to a point where the reader could begin to write a computer program. Indeed，the reader should be able to construct computer programs that generate the kind of results presented in the final chapter of the book. A range of computer programs of varying generality can be designed depending...

图书目录

Preface

1 INTRODUCTION

1．1 Scope of the Book

1．2 Methods of Prediction

1．2-1 Experimental Investigation

1．2-2 Theoretical Calculation

1．2-3 Advantages of a Theoretical Calculation

1．2-4 Disadvantages of a Theoretical Calculation

1．2-5 Choice of Prediction Method

1．3 Outline of the Book

2 MATHEMATICAL DESCRIPTION OF PHYSICAL PHENOMENA

2．1 Governing Differential Equations

2．1-1 Meaning of a Differential Equation

2．1-2 Conservation of a Chemical Species

2．1-3 The Energy Equation

2．1-4 A Momentum Equation

2．1 5 The Time-Averaged Equations for Turbulent Flow

2．1-6 The Turbulence-Kinetic-Energy Equation

2．1-7 The General Differential Equation

2．2 Nature of Coordinates

2．2-1 Independent Variables

2．2-2 Proper Choice of Coordinates

2．2-3 One-Way and Two-Way Coordinates

Problems

3 DISCRETIZATION METHODS

3．1 The Nature of Numerical Methods

3，1-1 The Task

3，1 2 The Discretization Concept

3．1-3 The Structure of the Discretization Equation

3．2 Methods of Deriving the Discretization Equations

3．2-1 Taylor-Series Formulation

3．2-2 Variational Formulation

3．2-3 Method of Weighted Residuals

3．2-4 Control-Volume Formulation

3．3 An Illustrative Example

3．4 The Four Basic Rules

3．5 Closure

Problems

4 HEAT CONDUCTION

4．1 Objectives of the Chapter

4．2 Steady One-dimensional Conduction

4．2-1 The Basic Equations

4．2-2 The Grid Spacing

4．2-3 The Interface Conductmty

4．2-4 Nonlinearity

4．2-5 Source-Term Linearization

4．2-6 Boundary Conditions

4．2-7 Solution of the Linear Algebraic Equations

4．3 Unsteady One-dimensional Conduction

4．3-1 The General Discretization Equation

4．3-2 Explicit， Crank-Nicolson， and Fully Implicit Schemes

4．3-3 The Fully Implicit Discretization Equation

4．4 Two- and Three-dimensional Situations

4．4-1 Discretization Equation for Two Dimensions

4．4-2 Discretization Equation for Three Dimensions

4．4-3 Solution of the Algebraic Equations

4．5 Overrelaxation and Underrelaxation

4．6 Some Geometric Considerations

4．6-1 Location of the Control-Volume Faces

4．6-2 Other Coordinate Systems

4．7 Closure

Problems

5 CONVECTION AND DIFFUSION

5．1 The Task

5．2 Steady One-dimensional Convection and Diffusion

5．2-1 A Preliminary Derivation

5．2-2 The Upwind Scheme

5．2-3 The Exact Solution

5．2-4 The Exponential Scheme

……

6 CALCULATION OF THE FLOW FIELD

7 FINISHING TOUCHES

8 SPECIAL TOPICS

9 ILLUSTRATIVE APPLICATIONS

Nomenclature

References

Index