作者:傅小明,蒋萍主编
页数:306页
出版社:南京大学出版社
出版日期:2017
ISBN:9787305195754
电子书格式:pdf/epub/txt
内容简介
本书是材料成型及控制工程系列规划教材之一。内容包括:金属的液态成形、塑性成形和焊接成形;非金属材料成型;表面工程技术以及其他成形工艺方法。通过本书的学习可以使读者全面地了解和掌握材料工程的全貌,为以后的专业课程学习和工程实践打下基础。
作者简介
博士,副教授。主要从事粉末冶金和纳米金属材料的研究。现任宿迁学院材料工程系主任、宿迁学院新材料研究中心主任等职。作为主研人员参与完成了国家自然基金项目和上海市纳米专项基金项目各1项。
目录
Chapter 1 Introduction
1.1 Historical Perspective
1.2 Definition of Materials
1.3 Definition of Engineerin9
1.4 Materials and Engineering
1.5 Selection of Materials
1.5.1 Service Requirements
1.5.2 Fabrication Requirements
1.5.3 Economic Requirements
1.5.4 Materials That Are Available to the Engineer
Part Ⅰ Foundation of Material Engineering
Chapter 2 Foundation of Fluid Mechanics
2.1 Characteristics of Flow
2.1.1 A Method to DeserVe Fluid Motion
2.1.2 Laminar and Turbulent Flows
2.1.3 Steady and Unsteady Flows
2.1.4 Temporal Mean
2.1.5 Uniform and Nonuniform Flows
2.1.6 Rotational and Irrotational Flows
2.2 Concepts of Flow
2.2.1 Flow Dimensionality
2.2.2 Path Line and Streamline
2.2.3 Stream Tube, Ministream Tube and Total Flow
2.2.4 Cross Section, Flow Rate and Average Velocity
2.3 Reynolds Transport Equation
2.3.1 System
2.3.2 Control Volume
2.3.3 Reynolds Transport Equation
2.3.4 Application of the Reynolds Transport Equation
2.4 Continuity Equation
2.4.1 Steady Flow Continuity Equation of One-Dimeasinnal Ministream Tube
2.4.2 Total Flow Continuity Equation for One-Dimensional Steady Flow
2.4.3 Three-Dimensional Differential Continuity Equation
2.5 Bernoulli Equation
2.5.1 Enler’s Equation in One-Dimensional Flow for Ideal Fluid
2.5.2 Bernoulli’s Equation
2.5.3 Geometry Expression of Bernoulli’s Equation
2.6 Flow Losses and Steady Flow Energy Equation
2.6.1 Reversible and Irreversible Processes
2.6.2 Energy Equation ha Differential Form for a Steady Flow
2.6.3 Energy Equation for a Reversible Process
2.6.4 Energy Equation for an Irreversible Process
2.6.5 Bernoulli’s Equation for Real System
2.7 Application of the Energy Equation to Steady Fluid-Flow Situations …
2.7.1 Gradually Varied Flow
2.7.2 BernouUi’s Equation for the Real-Fluid Total Flow
2.7.3 Applications of Bernoulli’s Equation
2.8 Applications of the Linear-Momentum Equation
Chapter 3 Foundation of Heat Transfer
3.1 Introduction
3.2 Conduction Heat Transfer
3.3 Thermal Conductivity
3.4 Convection Heat Transfer
3.5 Radiation Heat Transfer
Chapter 4 Diffusion Theory
4.1 Introduction
4.2 Diffusion Mechanisms
4.2.1 Vacancy Diffusion
4.2.2 Interstitial Diffusion
4.3 Steady-State Diffusion
4.4 Nonsteady-State Diffusion
4.5 Factors That Influence Diffusion
4.5.1 Diffusing Species
4.5.2 Temperature
Part Ⅱ Design and Simulation of Materials
Part Ⅲ Preduction and Processing of Materials
Part Ⅳ Measurement and Analysis of Materials
Part Ⅴ Application of Materials
Main References
1.1 Historical Perspective
1.2 Definition of Materials
1.3 Definition of Engineerin9
1.4 Materials and Engineering
1.5 Selection of Materials
1.5.1 Service Requirements
1.5.2 Fabrication Requirements
1.5.3 Economic Requirements
1.5.4 Materials That Are Available to the Engineer
Part Ⅰ Foundation of Material Engineering
Chapter 2 Foundation of Fluid Mechanics
2.1 Characteristics of Flow
2.1.1 A Method to DeserVe Fluid Motion
2.1.2 Laminar and Turbulent Flows
2.1.3 Steady and Unsteady Flows
2.1.4 Temporal Mean
2.1.5 Uniform and Nonuniform Flows
2.1.6 Rotational and Irrotational Flows
2.2 Concepts of Flow
2.2.1 Flow Dimensionality
2.2.2 Path Line and Streamline
2.2.3 Stream Tube, Ministream Tube and Total Flow
2.2.4 Cross Section, Flow Rate and Average Velocity
2.3 Reynolds Transport Equation
2.3.1 System
2.3.2 Control Volume
2.3.3 Reynolds Transport Equation
2.3.4 Application of the Reynolds Transport Equation
2.4 Continuity Equation
2.4.1 Steady Flow Continuity Equation of One-Dimeasinnal Ministream Tube
2.4.2 Total Flow Continuity Equation for One-Dimensional Steady Flow
2.4.3 Three-Dimensional Differential Continuity Equation
2.5 Bernoulli Equation
2.5.1 Enler’s Equation in One-Dimensional Flow for Ideal Fluid
2.5.2 Bernoulli’s Equation
2.5.3 Geometry Expression of Bernoulli’s Equation
2.6 Flow Losses and Steady Flow Energy Equation
2.6.1 Reversible and Irreversible Processes
2.6.2 Energy Equation ha Differential Form for a Steady Flow
2.6.3 Energy Equation for a Reversible Process
2.6.4 Energy Equation for an Irreversible Process
2.6.5 Bernoulli’s Equation for Real System
2.7 Application of the Energy Equation to Steady Fluid-Flow Situations …
2.7.1 Gradually Varied Flow
2.7.2 BernouUi’s Equation for the Real-Fluid Total Flow
2.7.3 Applications of Bernoulli’s Equation
2.8 Applications of the Linear-Momentum Equation
Chapter 3 Foundation of Heat Transfer
3.1 Introduction
3.2 Conduction Heat Transfer
3.3 Thermal Conductivity
3.4 Convection Heat Transfer
3.5 Radiation Heat Transfer
Chapter 4 Diffusion Theory
4.1 Introduction
4.2 Diffusion Mechanisms
4.2.1 Vacancy Diffusion
4.2.2 Interstitial Diffusion
4.3 Steady-State Diffusion
4.4 Nonsteady-State Diffusion
4.5 Factors That Influence Diffusion
4.5.1 Diffusing Species
4.5.2 Temperature
Part Ⅱ Design and Simulation of Materials
Part Ⅲ Preduction and Processing of Materials
Part Ⅳ Measurement and Analysis of Materials
Part Ⅴ Application of Materials
Main References
