| Fundamentals / Part 1: |
| Mechanical Engineering Design in Broad Perspective / Chapter 1: |
| An Overview of the Subject / 1.1: |
| Safety Considerations / 1.2: |
| Ecological Considerations / 1.3: |
| Societal Considerations / 1.4: |
| Overall Design Considerations / 1.5: |
| Systems of Units / 1.6: |
| Methodology for Solving Machine Component Problems / 1.7: |
| Work and Energy / 1.8: |
| Power / 1.9: |
| Conservation of Energy / 1.10: |
| Load Analysis / Chapter 2: |
| Introduction / 2.1: |
| Equilibrium Equations and Free-Body Diagrams / 2.2: |
| Beam Loading / 2.3: |
| Locating Critical Sections--Force Flow Concept / 2.4: |
| Load Division Between Redundant Supports / 2.5: |
| Force Flow Concept Applied to Redundant Ductile Structures / 2.6: |
| Materials / Chapter 3: |
| The Static Tensile Test--"Engineering" Stress-Strain Relationships / 3.1: |
| Implications of the "Engineering" Stress-Strain Curve / 3.3: |
| The Static Tensile Test--"True" Stress-Strain Relationships / 3.4: |
| Energy-Absorbing Capacity / 3.5: |
| Estimating Strength Properties from Penetration Hardness Tests / 3.6: |
| Use of "Handbook" Data for Material Strength Properties / 3.7: |
| Machinability / 3.8: |
| Cast Iron / 3.9: |
| Steel / 3.10: |
| Nonferrous Alloys / 3.11: |
| Plastics / 3.12: |
| Statie Body Stresses / Chapter 4: |
| Axial Loading / 4.1: |
| Direct Shear Loading / 4.3: |
| Torsional Loading / 4.4: |
| Pure Bending Loading, Straight Beams / 4.5: |
| Pure Bending Loading, Curved Beams / 4.6: |
| Transverse Shear Loading in Beams / 4.7: |
| Induced Stresses, Mohr Circle Representation / 4.8: |
| Combined Stresses--Mohr Circle Representation / 4.9: |
| Stress Equations Related to Mohr's Circle / 4.10: |
| Three-Dimensional Stresses / 4.11: |
| Stress Concentration Factor (K) / 4.12: |
| Importance of Stress Concentration / 4.13: |
| Residual Stresses Caused by Yielding--Axial Loading / 4.14: |
| Residual Stresses Caused by Yielding--Bending and Torsional Loading / 4.15: |
| Thermal Stresses / 4.16: |
| Importance of Residual Stresses / 4.17: |
| Elastic Strain, Deflection, and Stability / Chapter 5: |
| Strain Definition, Measurement, and Mohr Circle Representation / 5.1: |
| Analysis of Strain--Equiangular Rosettes / 5.3: |
| Analysis of Strain--Rectangular Rosettes / 5.4: |
| Elastic Stress-Strain Relationships and Three-Dimensional Mohr Circles / 5.5: |
| Deflection and Spring Rate--Simple Cases / 5.6: |
| Beam Deflection / 5.7: |
| Determining Elastic Deflections by Castigliano's Method / 5.8: |
| Redundant Reactions by Castigliano's Method / 5.9: |
| Euler Column Buckling--Elastic Instability / 5.10: |
| Effective Column Length for Various End Conditions / 5.11: |
| Column Design Equations--J. B. Johnson Parabola / 5.12: |
| Eccentric Column Loading--the Secant Formula / 5.13: |
| Equivalent Column Stresses / 5.14: |
| Other Types of Buckling / 5.15: |
| Finite Element Analysis / 5.16: |
| Failure Theories, Safety Factors, and Reliability / Chapter 6: |
| Types of Failure / 6.1: |
| Fracture Mechanics--Basic Concepts / 6.3: |
| Fracture Mechanics--Applications / 6.4: |
| The "Theory" of Static Failure Theories / 6.5: |
| Maximum-Normal-Stress Theory / 6.6: |
| Maximum-Shear-Stress Theory / 6.7: |
| Maximum-Distortion-Energy Theory (Maximum-Octahedral-Shear-Stress Theory) / 6.8: |
| Modified Mohr Theory / 6.9: |
| Selection and Use of Failure Theories / 6.10: |
| Safety Factors--Concept and Definition / 6.11: |
| Safety Factors--Selection of a Numerical Value / 6.12: |
| Reliability / 6.13: |
| Normal Distributions / 6.14: |
| Interference Theory of Reliability Prediction / 6.15: |
| Impact / Chapter 7: |
| Stress and Deflection Caused by Linear and Bending Impact / 7.1: |
| Stress and Deflection Caused by Torsional Impact / 7.3: |
| Effect of Stress Raisers on Impact Strength / 7.4: |
| Fatigue / Chapter 8: |
| Basic Concepts / 8.1: |
| Standard Fatigue Strengths (S) for Rotating Bending / 8.3: |
| Fatigue Strengths for Reversed Bending and Reversed Axial Loading / 8.4: |
| Fatigue Strength for Reversed Torsional Loading / 8.5: |
| Fatigue Strength for Reversed Biaxial Loading / 8.6: |
| Influence of Surface and Size on Fatigue Strength / 8.7: |
| Summary of Estimated Fatigue Strengths for Completely Reversed Loading / 8.8: |
| Effect of Mean Stress on Fatigue Strength / 8.9: |
| Effect of Stress Concentration with Completely Reversed Fatigue Loading / 8.10: |
| Effect of Stress Concentration with Mean Plus Alternating Loads / 8.11: |
| Fatigue Life Prediction with Randomly Varying Loads / 8.12: |
| Effect of Surface Treatments on the Fatigue Strength of a Part / 8.13: |
| Mechanical Surface Treatments--Shot Peening and Others / 8.14: |
| Thermal and Chemical Surface-Hardening Treatments (Induction Hardening, Carburizing, and Others) / 8.15: |
| Surface Damage / Chapter 9: |
| Corrosion: Fundamentals / 9.1: |
| Corrosion: Electrode and Electrolyte Heterogeneity / 9.3: |
| Design for Corrosion Control / 9.4: |
| Corrosion Plus Static Stress / 9.5: |
| Corrosion Plus Cyclic Stress / 9.6: |
| Cavitation Damage / 9.7: |
| Types of Wear / 9.8: |
| Adhesive Wear / 9.9: |
| Abrasive Wear / 9.10: |
| Fretting / 9.11: |
| Analytical Approach to Wear / 9.12: |
| Curved-Surface Contact Stresses / 9.13: |
| Surface Fatigue Failures / 9.14: |
| Closure / 9.15: |
| Applications / Part 2: |
| Threaded Fasteners and Power Screws / Chapter 10: |
| Thread Forms, Terminology, and Standards / 10.1: |
| Power Screws / 10.3: |
| Static Screw Stresses / 10.4: |
| Threaded Fastener Types / 10.5: |
| Fastener Materials and Methods of Manufacture / 10.6: |
| Bolt Tightening and Initial Tension / 10.7: |
| Thread Loosening and Thread Locking / 10.8: |
| Bolt Tension with External Joint-Separating Force / 10.9: |
| Bolt (or Screw) Selection for Static Loading / 10.10: |
| Bolt (or Screw) Selection for Fatigue Loading: Fundamentals / 10.11: |
| Bolt (or Screw) Selection for Fatigue Loading: Using Special Test Data / 10.12: |
| Increasing Bolted-Joint Fatigue Strength / 10.13: |
| Rivels, Welding, and Bonding / Chapter 11: |
| Rivets / 11.1: |
| Welding Processes / 11.3: |
| Welded Joints Subjected to Static Axial and Direct Shear Loading / 11.4: |
| Welded Joints Subjected to Static Torsional and Bending Loading / 11.5: |
| Fatigue Considerations in Welded Joints / 11.6: |
| Brazing and Soldering / 11.7: |
| Adhesives / 11.8: |
| Springs / Chapter 12: |
| Torsion Bar Springs / 12.1: |
| Coil Spring Stress and Deflection Equations / 12.3: |
| Stress and Strength Analysis for Helical Compression Springs--Static Loading / 12.4: |
| End Designs of Helical Compression Springs / 12.5: |
| Buckling Analysis of Helical Compression Springs / 12.6: |
| Design Procedure for Helical Compression Springs--Static Loading / 12.7: |
| Design of Helical Compression Springs for Fatigue Loading / 12.8: |
| Helical Extension Springs / 12.9: |
| Beam Springs (Including Leaf Springs) / 12.10: |
| Torsion Springs / 12.11: |
| Miscellaneous Springs / 12.12: |
| Lubrication and Sliding Bearings / Chapter 13: |
| Types of Lubricants / 13.1: |
| Types of Sliding Bearings / 13.2: |
| Types of Lubrication / 13.3: |
| Basic Concepts of Hydrodynamic Lubrication / 13.4: |
| Viscosity / 13.5: |
| Temperature and Pressure Effects on Viscosity / 13.6: |
| Petroff's Equation for Bearing Friction / 13.7: |
| Hydrodynamic Lubrication Theory / 13.8: |
| Design Charts for Hydrodynamic Bearings / 13.9: |
| Lubricant Supply / 13.10: |
| Heat Dissipation, and Equilibrium Oil Film Temperature / 13.11: |
| Bearing Materials / 13.12: |
| Hydrodynamic Bearing Design / 13.13: |
| Boundary and Mixed-Film Lubrication / 13.14: |
| Thrust Bearings / 13.15: |
| Elastohydrodynamic Lubrication / 13.16: |
| Rolling-Element Bearings / Chapter 14: |
| Comparison of Alternative Means for Supporting Rotating Shafts / 14.1: |
| History of Rolling-Element Bearings / 14.2: |
| Rolling-Element Bearing Types / 14.3: |
| Design of Rolling-Element Bearings / 14.4: |
| Fitting of Rolling-Element Bearings / 14.5: |
| "Catalogue Information" for Rolling-Element Bearings / 14.6: |
| Bearing Selection / 14.7: |
| Mounting Bearings to Provide Properly for Thrust Load / 14.8: |
| Spur Gears / Chapter 15: |
| Introduction and History / 15.1: |
| Geometry and Nomenclature / 15.2: |
| Interference and Contact Ratio / 15.3: |
| Gear Force Analysis / 15.4: |
| Gear-Tooth Strength / 15.5: |
| Basic Analysis of Gear-Tooth-Bending Stress (Lewis Equation) / 15.6: |
| Refined Analysis of Gear-Tooth-Bending Strength: Basic Concepts / 15.7: |
| Refined Analysis of Gear-Tooth-Bending Strength: Recommended Procedure / 15.8: |
| Gear-Tooth Surface Durability--Basic Concepts / 15.9: |
| Gear-Tooth Surface Fatigue Analysis--Recommended Procedure / 15.10: |
| Spur Gear Design Procedures / 15.11: |
| Gear Materials / 15.12: |
| Gear Trains / 15.13: |
| Helical, Bevel, and Worm Gears / Chapter 16: |
| Helical-Gear Geometry and Nomenclature / 16.1: |
| Helical-Gear Force Analysis / 16.3: |
| Helical-Gear-Tooth-Bending and Surface Fatigue Strengths / 16.4: |
| Crossed Helical Gears / 16.5: |
| Bevel Gear Geometry and Nomenclature / 16.6: |
| Bevel Gear Force Analysis / 16.7: |
| Bevel-Gear-Tooth-Bending and Surface Fatigue Strengths / 16.8: |
| Bevel Gear Trains; Differential Gears / 16.9: |
| Worm Gear Geometry and Nomenclature / 16.10: |
| Worm Gear Force and Efficiency Analysis / 16.11: |
| Worm-Gear-Bending and Surface Fatigue Strengths / 16.12: |
| Worm Gear Thermal Capacity / 16.13: |
| Shafts and Associated Parts / Chapter 17: |
| Provision for Shaft Bearings / 17.1: |
| Mounting Parts onto Rotating Shafts / 17.3: |
| Rotating-Shaft Dynamics / 17.4: |
| Overall Shaft Design / 17.5: |
| Keys, Pins, and Splines / 17.6: |
| Couplings and Universal Joints / 17.7: |
| Clutches and Brakes / Chapter 18: |
| Disk Clutches / 18.1: |
| Disk Brakes / 18.3: |
| Energy Absorption and Cooling / 18.4: |
| Cone Clutches and Brakes / 18.5: |
| Short-Shoe Drum Brakes / 18.6: |
| External Long-Shoe Drum Brakes / 18.7: |
| Internal Long-Shoe Drum Brakes / 18.8: |
| Band Brakes / 18.9: |
| Miscellaneous Power Trausmission Components / 18.10: |
| Flat Belts / 19.1: |
| V-Belts / 19.3: |
| Toothed Belts / 19.4: |
| Roller Chains / 19.5: |
| Inverted-Tooth Chains / 19.6: |
| History of Hydrodynamic Drives / 19.7: |
| Fluid Couplings / 19.8: |
| Hydrodynamic Torque Converters / 19.9: |
| Machine Component Interrelationships--A Case Study / Chapter 20: |
| Description of Original Hydra-Matic Transmission / 20.1: |
| Free-Body Diagram Determination of Gear Ratios and Component Loads / 20.3: |
| Gear Design Considerations / 20.4: |
| Brake and Clutch Design Considerations / 20.5: |
| Miscellaneous Design Considerations / 20.6: |
| Units / Appendix A: |
| Conversion Factors for British Gravitational, English, and SI Units / A-1a: |
| Conversion Factor Equalities Listed by Physical Quantity / A-1b: |
| Standard SI Prefixes / A-2a: |
| SI Units and Symbols / A-2b: |
| Suggested SI Prefixes for Stress Calculations / A-3: |
| Suggested SI Prefixes for Linear-Deflection Calculations / A-4: |
| Suggested SI Prefixes for Angular-Deflection Calculations / A-5: |
| Properties of Sections and Solids / Appendix B: |
| Properties of Sections / B-1a: |
| Dimensions and Properties of Steel Pipe and Tubing Sections / B-1b: |
| Mass and Mass Moments of Inertia of Homogeneous Solids / B-2: |
| Material Properties and Uses / Appendix C: |
| Physical Properties of Common Metals / C-1: |
| Tensile Properties of Some Metals / C-2: |
| Typical Mechanical Properties and Uses of Gray Cast Iron / C-3a: |
| Mechanical Properties and Typical Uses of Mallcable Cast Iron / C-3b: |
| Average Mechanical Properties and Typical Uses of Ductile (Nodular) Iron / C-3c: |
| Mechanical Properties of Selected Carbon and Alloy Steels / C-4a: |
| Typical Uses of Plain Carbon Steels / C-4b: |
| Properties of Some Water-Quenched and Tempered Steels / C-5a: |
| Properties of Some Oil-Quenched and Tempered Carbon Steels / C-5b: |
| Properties of Some Oil-Quenched and Tempered Alloy Steels / C-5c: |
| Effect of Mass on Strength Properties of Steel / C-6: |
| Mechanical Properties of Some Carburizing Steels / C-7: |
| Mechanical Properties of Some Wrought Stainless Steels / C-8: |
| Mechanical Properties of Some Iron-Based Superalloys / C-9: |
| Mechanical Properties, Characteristics, and Typical Uses of Some Wrought Aluminum Alloys / C-10: |
| Tensile Properties, Characteristics, and Typical Uses of Some Cast-Aluminum Alloys / C-11: |
| Temper Designations for Aluminum and Magnesium Alloys / C-12: |
| Mechanical Properties of Some Copper Alloys / C-13: |
| Mechanical Properties of Some Magnesium Alloys / C-14: |
| Mechanical Properties of Some Nickel Alloys / C-15: |
| Mechanical Properties of Some Wrought-Titanium Alloys / C-16: |
| Mechanical Properties of Some Zinc Casting Alloys / C-17: |
| Representative Mechanical Properties of Some Common Plastics / C-18a: |
| Properties of Some Common Glass-Reinforced and Unreinforced Thermoplastic Resins / C-18b: |
| Typical Applications of Common Plastics / C-18c: |
| Material Classes and Selected Members of Each Class / C-19: |
| Shear, Moment, and Deflection Equations for Beams / Appendix D: |
| Cantilever Beams / D-1: |
| Simply Supported Beams / D-2: |
| Beams with Fixed Ends / D-3: |
| BASIC Program for Determining Elastic Deflections of Stepped Shafts / D-4: |
| Fits and Tolerances / Appendix E: |
| Fits and Tolerances for Holes and Shafts / E-1: |
| Index |
図書
