Resistance and Deformation of Solid Media

Preface

Introduction

Concepts and Definitions

The Particulate and the Continuum

Chapter 1 Elasticity

1-1 Coulomb's Law

1-2 Electrostatic Repulsion

1-3 Small Deformations, Hooke's Law

1-4 Stress and Strain

1-5 Bulk Modulus B

1-6 Ionic Crystals

1-7 Lateral Contraction: Poisson's Ratio

1-8 Bulk Modulus B and Young's Modulus E

1-9 Anisotropy of E: The Quasi-Isotropy

1-10 Shear Modulus G

1-11 Modulus of Elasticity and Periodic Table

1-12 Work of Deformation and Elastic Energy

1-13 Concluding Remarks

1-14 Problems

Chapter 2 Plasticity

2-1 Perfect Crystals

2-2 Defective Crystal: Dislocation

2-3 Strain Hardening

2-4 Mechanism of Slip in Uniaxial Tension

2-5 Relation between Shear Strain and Axial Strain

2-6 Relation between Shear Stress and Axial Stress

2-7 Plastic Stress-Strain Diagram

2-8 Actual Stress-Strain Diagram

2-9 Conventional and True Stress

2-10 Work of Deformation

2-11 The Dissipative and Recoverable Components

of Work of Deformation

2-12 Concluding Remarks

2-13 Problems

Chapter 3 Viscosity and Creep

3-1 Laminar Flow and Newton's Law of Viscosity

3-2 Coefficient of Viscosity

3-3 Poise and Centipoise

3-4 Range of Variation

3-5 Effect of Temperature

3-6 Coefficient of Fluidity: Kinematic Viscosity

3-7 Illustrative Example

3-8 Non-Newtonian Liquids

3-9 Viscoelasticity

3-10 Stress Relaxation: Relaxation Time

3-11 Illustrative Examples

3-12 Recoverable Creep (Delayed Elasticity)

3-13 Permanent Creep

3-14 Power of Deformation

3-15 Concluding Remarks

3-16 Problems

Chapter 4 Basic Principles

4-1 Principles of Equilibrium of Forces and Moments

4-2 Principle of Continuity of Deformation

4-3 Assumption of Small Deformations

4-4 Problems

Chapter 5 Homogeneous State

5-1 Stress at a Point: Macroscopic Approach

5-2 Prismatic Bars Under Axial Loading

5-3 Statically Determinate and Statically Indeterminate Structures

5-4 Illustration of a Statically Indeterminate Structure

5-5 Composite Bars

5-6 Thermal Stresses in Bars

5-7 Thin-Wall Pressure Vessels

5-8 Spherical Pressure Vessels

5-9 Torsion of Thin-Wall Tubes

5-10 Problems

Chapter 6 Uniaxial State: Plane Bending

6-1 Pure Bending

6-2 Bernouilli's Hypothesis

6-3 Equilibrium of Forces and Moments

6-4 Elastic Bending

6-5 Viscous Bending

6-6 Viscoelastic Bending

6-7 Recoverable Creep in Bending

6-8 Incipient Plastic Deformation

6-9 Distortion of the Cross Section: Anticlastic Surface

6-10 Bending by Transverse Forces

6-11 Bending by Distributed Forces

6-12 Illustrative Examples

6-13 Beams of Variable Cross Section

6-14 Deflection of Beams

6-15 Work of Deformation in Bending

6-16 Virtual Work in Bending

6-17 Virtual Work and Beam Deflection

6-18 Virtual Work and Statically Indeterminate Beams

6-19 Problems

Chapter 7 Uniaxial State (Continued): Torsion of Circular Cylinders

7-1 Stresses and Angle of Twist

7-2 Work of Deformation in Torsion

7-3 Virtual Work

7-4 Problems

Chapter 8 Uniaxial State (Concluded): Linear Beam Theory

8-1 General Expression of Bernouilli's Hypothesis

8-2 Conditions of Equilibrium

8-3 Elastic Deformation

8-4 Unsymmetrical Bending: Principal Axes and Moments of Inertia

8-5 The Most Economical Utilization of a Beam in Bending

8-6 Deflection in Unsymmetrical Bending

8-7 Thermal Stresses

8-8 Composite Beam

8-9 Problems

Chapter 9 Biaxial State of Stress

9-1 Notations

9-2 Sign Convention

9-3 Stresses at a Point

9-4 Reciprocity of Shear Stresses

9-5 Principal Planes: Directions and Stresses

9-6 Mohr Circle of Stress

9-7 Sign of the Shear Stress

9-8 Maxima and Minima of the Normal and Shear Stresses: Invariants

9-9 Illustrative Examples

9-10 Stress Tensor

9-11 Illustrative Example: Tensor of Moment of Inertia

9-12 Problems

Chapter 10 Biaxial State of Strain

10-1 Notations

10-2 Strain at a Point

10-3 Tensor of Strain

10-4 Principal Directions and Strains

10-5 Use of the Mohr Circle of Strain

10-6 Shear Strain ?xy and Distortion Angle ?xy

10-7 Sign Convention

10-8 Maximum Shear Strain

10-9 Problems

Chapter 11 Elementary Application of a Biaxial State of Stress and Strain

11-1 States of Stress and Strain near the Surface the Triplet of Mohr Circles

11-2 Uniaxial Tension

11-3 Torsion of Circular Shafts

11-4 Shear Stresses in Bending

11-5 Combined Shear and Bending

11-6 Combined Torsion and Bending

11-7 Problems

Chapter 12 Three-Dimensional State of Stress

12-1 Notations

12-2 Three-Dimensional Stress Tensor

12-3 Principal Stresses and Directions

12-4 Magnitude and Directions of Any Stress Vector in Terms of Principal Stresses

12-5 Any Normal Stress in Terms of Principal Stresses

12-6 Total Shear Stress ?nn in Plane n

12-7 Maximum and Minimum Values of the Normal Stress

12-8 Maximum Value of the Shear Stress

12-9 Octahedral Stresses

12-10 Existence of Principal Stresses and Direction

12-11 Uniqueness of the Principal Stresses

12-12 Problems

Chapter 13 Three-Dimensional State of Strain and Strain Rate

13-1 Tensor of Strain

13-2 Any Strain Vector in Terms of Principal Strains

13-3 Any Normal Strain in Terms of Principal Strains

13-4 Total Shear Strain and Distortion Angle

13-5 Maximum and Minimum Values of Normal Strain

13-6 Principal Values of the Distortion Angle

13-7 Octahedral Strain and Distortion Angle

13-8 Mohr Circle of Strain

13-9 Tensor of Strain Rate

13-10 Problems

Chapter 14 Stress-Strain Relations

14-1 Generalized Hooke's Law

14-2 Generalized Newton's Law of Viscosity

14-3 Viscoelasticity

14-4 Problems

Chapter 15 Stress-Strain (Strain-Rate) Relations in Plastic Fields

15-1 Criterion of Yielding

15-2 Plasticity Laws

15-3 Problems

Chapter 16 Stress-Strain Relations in Monotonically Increasing Plastic Fields

16-1 True Stress and Strain

16-2 Stress-Strain Relations

16-3 Illustrative Examples

16-4 Relations Between Linear and Natural Strain Components

16-5 Problems

Chapter 17 Particular Solutions of Three-Dimensional Heterogeneous States of Stress and Strain: Thick-Wall Cylinders

17-1 Types of Deformation in Pressure Vessels

17-2 Compatibility of Strains and Strain Rates

17-3 Equilibrium of Forces

17-4 Elastic Vessel

17-5 Viscous Vessel

17-6 Plastic Vessel

17-7 Partly Plastic Tube

17-8 Problems

Chapter 18 Structural Instability

18-1 The Snap-Through Instability

18-2 Tensile Plastic Instability

18-3 Elastic

18-4 Critical Buckling Stress

18-5 Effect of Initial Eccentricity

18-6 Incidence of Plastic Deformation

18-7 Strain Hardening

18-8 Viscous Column

18-9 Viscoelastic Column

18-10 Recoverable Creep in Buckling

18-11 Plastic Instability of Thin-Wall Pressure Vessels

18-12 Plastic Instability of Thick-Wall Pressure Vessels: No Strain Hardening

18-13 Problems

Chapter 19 Material Instability and Fracture

19-1 Theoretical Fracture Stress

19-2 Brittle Fracture

19-3 Incipient Plastic Deformation

19-4 Fatigue Fracture

References

Index