Roark's Formulas for Stress and Strain, Ninth Edition /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Budynas, Richard G. (Autor), Sadegh, Ali M. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York, N.Y. : McGraw-Hill Education, [2020].
Edición:Ninth edition.
Temas:
Strength of materials > Tables.
Strains and stresses > Tables.
Strains and stresses.
TECHNOLOGY & ENGINEERING / Mechanical
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Preface to the Ninth Edition
  • Preface to the First Edition
  • List of Tables
  • CHAPTER 1
  • Introduction
  • 1.1 Terminology
  • 1.2 State Properties, Units, and Conversions
  • 1.3 Contents
  • 1.4 References
  • CHAPTER 2
  • Stress and Strain: Important Relationships
  • 2.1 Stress
  • 2.2 Strain and the Stress?Strain Relations
  • 2.3 Stress Transformations
  • 2.4 Strain Transformations
  • 2.5 Mohr?s Circle
  • 2.6 Mohr?s Circles for 3D Stress Analysis
  • 2.7 Tables
  • 2.8 References
  • CHAPTER 3
  • The Behavior of Bodies under Stress
  • 3.1 Methods of Loading
  • 3.2 Elasticity; Proportionality of Stress and Strain
  • 3.3 Factors Affecting Elastic Properties
  • 3.4 Load Deformation Relation for a Body
  • 3.5 Plasticity
  • 3.6 Creep and Rupture under Long-Time Loading
  • 3.7 Criteria of Elastic Failure and of Rupture
  • 3.8 Fatigue
  • 3.9 Brittle Fracture
  • 3.10 Stress Concentration
  • 3.11 Effect of Form and Scale on Strength; Rupture Factor
  • 3.12 Prestressing
  • 3.13 Elastic Stability
  • 3.14 Tables: Mechanical Properties of Materials
  • 3.15 References
  • CHAPTER 4
  • Principles and Analytical Methods
  • 4.1 Equations of Motion and of Equilibrium
  • 4.2 Principle of Superposition
  • 4.3 Principle of Reciprocal Deflections
  • 4.4 Method of Consistent Deformations (Strain Compatibility)
  • 4.5 Energy Methods
  • 4.6 Castigliano?s Theorem
  • 4.7 Dimensional Analysis
  • 4.8 Remarks on the Use of Formulas
  • 4.9 References
  • CHAPTER 5
  • Numerical Methods
  • 5.1 The Finite Difference Method
  • 5.2 The Finite Element Method
  • 5.3 The Boundary Element Method
  • 5.4 Zeroes of Polynomials
  • 5.5 Solution of Differential Equations
  • 5.6 Numerical Integration
  • 5.7 References
  • 5.8 Additional Uncited References for Finite Elements
  • 5.9 Additional Uncited References for Boundary Elements
  • CHAPTER 6
  • Experimental Methods
  • 6.1 Measurement Techniques
  • 6.2 Electrical Resistance Strain Gages
  • 6.3 Detection of Plastic Yielding
  • 6.4 Analogies
  • 6.5 Wheatstone Bridge
  • 6.6 Nondestructive Testing
  • 6.7 Tables
  • 6.8 References
  • CHAPTER 7
  • Tension, Compression, Shear, and Combined Stress
  • 7.1 Bar under Axial Tension (or Compression); Common Case
  • 7.2 Bar under Tension (or Compression); Special Cases
  • 7.3 Composite Members
  • 7.4 Trusses
  • 7.5 Body under Pure Shear Stress
  • 7.6 Cases of Direct Shear Loading
  • 7.7 Combined Stress
  • CHAPTER 8
  • Beams; Flexure of Straight Bars
  • 8.1 Straight Beams (Common Case) Elastically Stressed
  • 8.2 Composite Beams and Bimetallic Strips
  • 8.3 Three-Moment Equation
  • 8.4 Rigid Frames
  • 8.5 Beams on Elastic Foundations
  • 8.6 Deformation Due to the Elasticity of Fixed Supports
  • 8.7 Beams under Simultaneous Axial and Transverse Loading
  • 8.8 Beams of Variable Section
  • 8.9 Slotted Beams
  • 8.10 Beams of Relatively Great Depth
  • 8.11 Beams of Relatively Great Width
  • 8.12 Beams with Wide Flanges; Shear Lag
  • 8.13 Beams with Very Thin Webs
  • 8.14 Beams Not Loaded in Plane of Symmetry; Flexural Center
  • 8.15 Straight Uniform Beams (Common Case); Ultimate Strength
  • 8.16 Plastic, or Ultimate Strength, Design
  • 8.17 Tables
  • 8.18 References
  • CHAPTER 9
  • Curved Beams
  • 9.1 Bending in the Plane of the Curve
  • 9.2 Deflection of Curved Beams
  • 9.3 Circular Rings and Arches
  • 9.4 Elliptical Rings
  • 9.5 Curved Beams Loaded Normal to Plane of Curvature
  • 9.6 Tables
  • 9.7 References
  • CHAPTER 10
  • Torsion
  • 10.1 Straight Bars of Uniform Circular Section under Pure Torsion
  • 10.2 Bars of Noncircular Uniform Section under Pure Torsion
  • 10.3 Effect of End Constraint
  • 10.4 Effect of Longitudinal Stresses
  • 10.5 Ultimate Strength of Bars in Torsion
  • 10.6 Torsion of Curved Bars; Helical Springs
  • 10.7 Tables
  • 10.8 References
  • CHAPTER 11
  • Flat Plates
  • 11.1 Common Case
  • 11.2 Bending of Uniform-Thickness Plates with Circular Boundaries
  • 11.3 Circular-Plate Deflection Due to Shear
  • 11.4 Bimetallic Plates
  • 11.5 Nonuniform Loading of Circular Plates
  • 11.6 Circular Plates on Elastic Foundations
  • 11.7 Circular Plates of Variable Thickness
  • 11.8 Disk Springs
  • 11.9 Narrow Ring under Distributed Torque about Its Axis
  • 11.10 Bending of Uniform-Thickness Plates with Straight Boundaries
  • 11.11 Effect of Large Deflection; Diaphragm Stresses
  • 11.12 Plastic Analysis of Plates
  • 11.13 Ultimate Strength
  • 11.14 Tables
  • 11.15 References
  • CHAPTER 12
  • Columns and Other Compression Members
  • 12.1 Columns; Common Case
  • 12.2 Local Buckling
  • 12.3 Strength of Latticed Columns
  • 12.4 Eccentric Loading; Initial Curvature
  • 12.5 Columns under Combined Compression and Bending
  • 12.6 Thin Plates with Stiffeners
  • 12.7 Short Prisms under Eccentric Loading
  • 12.8 Table
  • 12.9 References
  • CHAPTER 13
  • Shells of Revolution; Pressure Vessels; Pipes
  • 13.1 Circumstances and General State of Stress
  • 13.2 Thin Shells of Revolution under Distributed Loadings Producing Membrane Stresses Only
  • 13.3 Thin Shells of Revolution under Concentrated or Discontinuous Loadings Producing Bending and Membrane Stresses
  • 13.4 Thin Multielement Shells of Revolution
  • 13.5 Thin Shells of Revolution under External Pressure
  • 13.6 Thick Shells of Revolution
  • 13.7 Pipe on Supports at Intervals
  • 13.8 Tables
  • 13.9 References
  • CHAPTER 14
  • Bodies under Direct Bearing and Shear Stress
  • 14.1 Stress Due to Pressure between Elastic Bodies
  • 14.2 Rivets and Riveted Joints
  • 14.3 Miscellaneous Cases
  • 14.4 Table
  • 14.5 References
  • CHAPTER 15
  • Elastic Stability
  • 15.1 General Considerations
  • 15.2 Buckling of Bars
  • 15.3 Buckling of Flat and Curved Plates
  • 15.4 Buckling of Shells
  • 15.5 Tables
  • 15.6 References
  • CHAPTER 16
  • Dynamic and Temperature Stresses
  • 16.1 Dynamic Loadings; General Conditions
  • 16.2 Body in a Known State of Motion
  • 16.3 Impact and Sudden Loading
  • 16.4 Impact and Sudden Loading; Approximate Formulas
  • 16.5 Remarks on Stress Due to Impact
  • 16.6 Vibration
  • 16.7 Temperature Stresses
  • 16.8 Tables
  • 16.9 References
  • CHAPTER 17
  • Stress Concentration
  • 17.1 Static Stress and Strain Concentration Factors
  • 17.2 Stress Concentration Reduction Methods
  • 17.3 Tables
  • 17.4 References
  • CHAPTER 18
  • Fatigue and Fracture
  • 18.1 Fatigue in Materials
  • 18.2 Fatigue Testing
  • 18.3 Fatigue and Crack Growth
  • 18.4 Creep
  • 18.5 Fracture Mechanics
  • 18.6 The Stress Intensity Factor
  • 18.7 Fracture Toughness
  • 18.8 Crack Tip Plasticity
  • 18.9 The Energy Balance Approach of Fracture
  • 18.10 The J Integral
  • 18.11 Tables
  • 18.12 References
  • CHAPTER 19
  • Stresses in Fasteners, Joints, and Gears
  • 19.1 Welding
  • 19.2 Analysis of Welded Joints
  • 19.3 Strength of Welded Joints
  • 19.5 Shearing and Failure Modes in Riveted Joints
  • 19.6 Eccentric Loading of Riveted Joints
  • 19.7 Bolt Strength and Design
  • 19.8 Gearing and Gear Stress
  • 19.9 References
  • CHAPTER 20
  • Composite Materials
  • 20.1 Composite Materials Classifications and Components
  • 20.2 Mechanics of Composite Materials
  • 20.3 Macromechanics of a Layer (Lamina)
  • 20.4 Micromechanics of a Layer (Lamina)
  • 20.5 Failure Criterion for a Layer (Lamina)
  • 20.6 Macromechanics of a Laminate
  • 20.7 Classical Lamination Theory
  • 20.8 Macromechanics of a Laminate: Stress and Strain in a Laminate
  • 20.9 Inversion of Stiffness Equation in a Laminate
  • 20.10 Example of Stresses and Strains in a Laminate
  • 20.11 Strength and Failure Analyses of Laminate
  • 20.12 Composite Sandwich Structures
  • 20.13 Composite Cellular Structures
  • 20.14 Tables
  • 20.15 References
  • CHAPTER 21
  • Solid Biomechanics
  • 21.1 Introduction
  • 21.2 Biomechanics of Bone
  • 21.3 Biomechanics of Articular Cartilage
  • 21.4 Biomechanics of Tendons and Ligaments
  • 21.5 Biomechanics of Muscles
  • 21.6 Biomechanics of Joints
  • 21.7 Biomechanics of the Knee
  • 21.8 Biomechanics of the Hip
  • 21.9 Biomechanics of the Spine
  • 21.10 Biomechanics of the Lumbar Spine
  • 21.11 Biomechanics of the Cervical Spine
  • 21.12 Biomechanics of the Shoulder
  • 21.13 Biomechanics of the Elbow
  • 21.14 Human Factors in Design
  • 21.15 Implants and Prostheses
  • 21.16 Hip Implants
  • 21.17 Knee Implants
  • 21.18 Other Implants
  • 21.19 Biomaterials
  • 21.20 Tables
  • 21.21 References
  • 21.22 Glossary
  • APPENDIX A
  • Properties of a Plane Area
  • APPENDIX B
  • Mathematical Formulas and Matrices
  • APPENDIX C
  • Glossary
  • Index.

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