修订版继续沿用原教材的基本内容和编写体系,可见该教材深受美国业内人士的广泛认同和欢迎。书中内容涵盖了设计过程、工程力学与材料、静载荷与动载荷下的防止失效、典型机械零部件设计等内容,提供了大量解决工程实际问题的方法和实例。该教材一直受到我国从事机械设计教学和研究人员的重视。作为国外权威性教材,高等教育出版社曾组织该书第三版(1980年)和第四版(1988年)的翻译出版工作,从而使国内同行深入了解和掌握美国机械设计相关课程的教学内容、体系、方法和发展,取得了很好的效果。机械工业出版社于2002年出版了该书(第六版)的英文影印版,为国内机械设计课程的双语教学起到了积极的推动作用。

为了加快培养具有国际竞争力的高水平技术人才,加快我国高等教育改革的步伐,教育部近来出台了一系列倡导高校开展英语或双语教学、引进原版教材的政策。引进国外**原版教材,在有条件的学校推动开展���语授课或双语教学,自然也引进了先进的教学思想和教学方法,这对提高我国自编教材的水平,加强学生的英语实际应用能力,使我国的高等教育尽快与国际接轨,必将起到积极的推动作用。
Mechanical Engineering Design为美国密歇根大学Joseph E.Shigley教授等著,是美国大学广泛使用的一本机械工程设计教材,具有极高的权威性。1956年,Joseph E.Shigley教授独自开始编写机械工程设计教材,后逐渐发展成为目前的机械工程设计教材。Joseph E.Shigley于1994年5月去世,其合作者仍然以Joseph E.Shigley教授的名义出版修订版至目前的第七版。修订版继续沿用原教材的基本内容和编写体系,可见该教材深受美国业内人士的广泛认同和欢迎。书中内容涵盖了设计过程、工程力学与材料、静载荷与动载荷下的防止失效、典型机械零部件设计等内容,提供了大量解决工程实际问题的方法和实例。该教材一直受到我国从事机械设计教学和研究人员的重视。作为国外权威性教材,高等教育出版社曾组织该书第三版(1980年)和第四版(1988年)的翻译出版工作,从而使国内同行深入了解和掌握美国机械设计相关课程的教学内容、体系、方法和发展,取得了很好的效果。机械工业出版社于2002年出版了该书(第六版)的英文影印版,为国内机械设计课程的双语教学起到了积极的推动作用。

1 Introduction
1-1 Design
1-2 Mechanical Engineering Design
1-3 Interaction between Design Process Elements
1-4 Design Tools and Resources
1-5 The Design Engineer's Professional Responsibilities
1-6 Codes and Standards
1-7 Economics
1-8 Safety and Product Liability
1-9 The Adequacy Assessment
1-10 Uncertainty
1-11 Stress and Strength
1-12 Design Factor and Factor of Safety
1-13 Reliability
1-14 Units and Preferred Units
1-15 Calculations and Significant Figures
Problems

2 Failture Resulting from Static Loading
2-1 Static Strength
2-2 Stress Concentration
2-3 Failure Theories
2-4 Maximum-Shear-Stress Theory for Ductile Materials
2-5 Distortion-Energy Theory for Ductile Materials
2-6 Coulomb-Mohr Theory for Ductile Materials
2-7 Failure of Ductile Materials Summary
2-8 Maximum-Normal-Stress Theory for Brittle Materials
2-9 Modifications of the Mohr Theory for Brittle Materials
2-10 Failure of Brittle Materials Summary
2-11 Selection of Failure Criteria
2-12 Static or Quasi-Static Loading on a Shaft
2-13 Introduction to Fracture Mechanics
2-14 Stochastic Analysis
Problems

3 Fatigue Failture Resulting from Variable Loading
3-1 Introduction to Fatigue in Metals
3-2 Approach to Fatigue Failure in Analysis and Design
3-3 Fatigue-Life Methods
3-4 The Stress-Life Method
3-5 The Strain-Life Method
3-6 The Linear-Elastic Fracture Mechanics Method
3-7 The Endurance Limit
3-8 Fatigue Strength
3-9 Endurance Limit Modifying Factors
3-10 Stress Concentration and Notch Sensitivity
3-11 Characterizing Fluctuating Stresses
3-12 Fatigue Failure Criteria for Fluctuating Stress
3-13 Torsional Fatigue Strength under Fluctuating Stresses
3-14 Combinations of Loading Modes
3-15 Varying, Fluctuating Stresses; Cumulative Fatigue Damage
3-16 Surface Fatigue Strength
3-17 Stochastic Analysis
Problems

4 Flexible Mechanical Elements
4-1 Belts
4-2 Flat-and Round-Beh Drives
4-3 V Belts
4-4 Timing Belts
4-5 Roller Chain
4-6 Wire Rope
4-7 Flexible Shafts
Problems

5 Gears——Force Analysis
5-1 Force Analysis——Spur Gearing
5-2 Force Analysis——Bevel Gearing
5-3 Force Analysis——Helical Gearing
5-4 Force Analysis——Worm Gearing
Problems

6 Spur and Helical Gears
6-1 The Lewis Bending Equation
6-2 Surface Durability
6-3 AGMA Stress Equations
6-4 AGMA Strength Equations
6-5 Geometry Factors I and J
6-6 The Elastic Coefficient
6-7 Dynamic Factor K
6-8 Overload Factor Ko
6-9 Surface Condition Factor C,
6-10 Size Factor K
6-11 Load-Distribution Factor K
6-12 Hardness-Ratio Factor
6-13 Stress Cycle Life Factors Y and Z
6-14 Reliability Factor K2 ( Yz )
6-15 Temperature Factor KT (Y2)
6-16 Rim-Thickness Factor K
6-17 Safety Factors S and Ss
6-18 Analysis
6-19 Design of a Gear Mesh
Problems

7 Bevel and Worm Gears
7-1 Bevel Gearing-General
7-2 Bevel-Gear Stresses and Strengths
7-3 AGMA Equation Factors
7-4 Straight-Bevel Gear Analysis
7-5 Design of a Straight-Bevel Gear Mesh
7-6 Worm Gearing——AGMA Equation
7-7 Worm-Gear Analysis
7-8 Designing a Worm-Gear Mesh
7-9 Buckingham Wear Load
Problems

8 Lubrication and Journal Bearings
8-1 Types of Lubrication
8-2 Viscosity
8-3 Petroff's Equation
8-4 Stable Lubrication
8-5 Thick-Film Lubrication
8-6 Hydrodynamic Theory
8-7 DEsign Considerations
8-8 The Relations of the Variables
8-9 Steady-State Conditions in Self-Contained Bearings
8-10 Clearance
8-11 Pressure-Fed Bearings
8-12 Loads and Materials
8-13 Bearing Types
8-14 Thrust Bearings
8-15 Boundary-Lubricated Bearings
Problems

9 Rolling-Contact Bearings
9-1 Bearing Types
9-2 Bearing Life
9-3 Bearing Load Life at Rated Reliability
9-4 Bearing Survival: Reliability versus Life
9-5 Relating Load, Life, and Reliability
9-6 Combined Radial and Thrust Loading
9-7 Variable Loading
9-8 Selection of Ball and Cylindrical Roller Bearings
9-9 Selection of Tapered Roller Bearings

10 Shafts and Axles
11 Screws, Fasteners, and the Design of Nonpermanent Joints
12 Clutches, Brakes, Couplings, and Flywheels
13 Mechanical Springs
Appendix A Useful Tables
Appendix B Answers to Selected Problems
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