Academic Press Elasticity Theory Applications and Numerics 4th Edition by Martin Sadd 0128159871 9780128159873

1 – Foundations and elementary applications

1 – Mathematical preliminaries

1.1 Scalar, vector, matrix, and tensor definitions

1.2 Index notation

1.3 Kronecker delta and alternating symbol

1.4 Coordinate transformations

1.5 Cartesian tensors

1.6 Principal values and directions for symmetric second-order tensors

1.7 Vector, matrix, and tensor algebra

1.8 Calculus of Cartesian tensors

1.8.1 Divergence or Gauss theorem

1.8.2 Stokes theorem

1.8.3 Green’s theorem in the plane

1.8.4 Zero-value or localization theorem

1.9 Orthogonal curvilinear coordinates

References

1 . Exercises

2 – Deformation: displacements and strains

2.1 General deformations

2.2 Geometric construction of small deformation theory

2.3 Strain transformation

2.4 Principal strains

2.5 Spherical and deviatoric strains

2.6 Strain compatibility

2.7 Curvilinear cylindrical and spherical coordinates

References

2 . Exercises

3 – Stress and equilibrium

3.1 Body and surface forces

3.2 Traction vector and stress tensor

3.3 Stress transformation

3.4 Principal stresses

3.5 Spherical, deviatoric, octahedral, and von Mises stresses

3.6 Stress distributions and contour lines

3.7 Equilibrium equations

3.8 Relations in curvilinear cylindrical and spherical coordinates

References

3 . Exercises

4 – Material behavior—linear elastic solids

4.1 Material characterization

4.2 Linear elastic materials—Hooke’s law

4.3 Physical meaning of elastic moduli

4.3.1 Simple tension

4.3.2 Pure shear

4.3.3 Hydrostatic compression (or tension)

4.4 Thermoelastic constitutive relations

References

4 . Exercises

5 – Formulation and solution strategies

5.1 Review of field equations

5.2 Boundary conditions and fundamental problem classifications

5.3 Stress formulation

5.4 Displacement formulation

5.5 Principle of superposition

5.6 Saint–Venant’s principle

5.7 General solution strategies

5.7.1 Direct method

5.7.2 Inverse method

5.7.3 Semi-inverse method

5.7.4 Analytical solution procedures

Power series method

Fourier method

Integral transform method

Complex variable method

5.7.5 Approximate solution procedures

Ritz method

5.7.6 Numerical solution procedures

Finite difference method

Finite element method

Boundary element method

5.8 Singular elasticity solutions

References

5 . Exercises

6 – Strain energy and related principles

6.1 Strain energy

6.2 Uniqueness of the elasticity boundary-value problem

6.3 Bounds on the elastic constants

6.3.1 Uniaxial tension

6.3.2 Simple shear

6.3.3 Hydrostatic compression

6.4 Related integral theorems

6.4.1 Clapeyron’s theorem

6.4.2 Betti/Rayleigh reciprocal theorem

6.4.3 Integral formulation of elasticity—Somigliana’s identity

6.5 Principle of virtual work

6.6 Principles of minimum potential and complementary energy

6.7 Rayleigh–Ritz method

References

6 . Exercises

7 – Two-dimensional formulation

7.1 Plane strain

7.2 Plane stress

7.3 Generalized plane stress

7.4 Antiplane strain

7.5 Airy stress function

7.6 Polar coordinate formulation

References

7 . Exercises

8 – Two-dimensional problem solution

8.1 Cartesian coordinate solutions using polynomials

8.2 Cartesian coordinate solutions using Fourier methods

8.2.1 Applications involving Fourier series

8.3 General solutions in polar coordinates

8.3.1 General Michell solution

8.3.2 Axisymmetric solution

8.4 Example polar coordinate solutions

8.4.1 Pressurized hole in an infinite medium

8.4.2 Stress-free hole in an infinite medium under equal biaxial loading at infinity

8.4.3 Biaxial and shear loading cases

8.4.4 Quarter-plane example

8.4.5 Half-space examples

8.4.6 Half-space under uniform normal stress over x≤0

8.4.7 Half-space under concentrated surface force system (Flamant problem)

8.4.8 Half-space under a surface concentrated moment

8.4.9 Half-space under uniform normal loading over −a≥x≥a

8.4.10 Notch and crack problems

8.4.11 Pure bending example

8.4.12 Curved cantilever under end loading

8.5 Simple plane contact problems

References

8 . Exercises

9 – Extension, torsion, and flexure of elastic cylinders

9.1 General formulation

9.2 Extension formulation

9.3 Torsion formulation

9.3.1 Stress–stress function formulation

9.3.2 Displacement formulation

9.3.3 Multiply connected cross-sections

9.3.4 Membrane analogy

9.4 Torsion solutions derived from boundary equation

9.5 Torsion solutions using Fourier methods

9.6 Torsion of cylinders with hollow sections

9.7 Torsion of circular shafts of variable diameter

9.8 Flexure formulation

9.9 Flexure problems without twist

References

9 . Exercises

2 – Advanced applications

10 – Complex variable methods

10.1 Review of complex variable theory

10.2 Complex formulation of the plane elasticity problem

10.3 Resultant boundary conditions

10.4 General structure of the complex potentials

10.4.1 Finite simply connected domains

10.4.2 Finite multiply connected domains

10.4.3 Infinite domains

10.5 Circular domain examples

10.6 Plane and half-plane problems

10.7 Applications using the method of conformal mapping

10.8 Applications to fracture mechanics

10.9 Westergaard method for crack analysis

References

10 . Exercises

11 – Anisotropic elasticity

11.1 Basic concepts

11.2 Material symmetry

11.2.1 Plane of symmetry (monoclinic material)

11.2.2 Three perpendicular planes of symmetry (orthotropic material)

11.2.3 Axis of symmetry (transversely isotropic material)

11.2.4 Cubic symmetry

11.2.5 Complete symmetry (isotropic material)

11.3 Restrictions on elastic moduli

11.4 Torsion of a solid possessing a plane of material symmetry

11.4.1 Stress formulation

11.4.2 Displacement formulation

11.4.3 General solution to the governing equation

11.5 Plane deformation problems

11.5.1 Uniform pressure loading case

11.6 Applications to fracture mechanics

11.7 Curvilinear anisotropic problems

11.7.1 Two-dimensional polar-orthotropic problem

11.7.2 Three-dimensional spherical-orthotropic problem

References

11 . Exercises

12 – Thermoelasticity

12.1 Heat conduction and the energy equation

12.2 General uncoupled formulation

12.3 Two-dimensional formulation

12.3.1 Plane strain

12.3.2 Plane stress

12.4 Displacement potential solution

12.5 Stress function formulation

12.6 Polar coordinate formulation

12.7 Radially symmetric problems

12.8 Complex variable methods for plane problems

References

12 . Exercises

13 – Displacement potentials and stress functions: applications to three-dimensional problems

13.1 Helmholtz displacement vector representation

13.2 Lamé’s strain potential

13.3 Galerkin vector representation

13.4 Papkovich–Neuber representation

13.5 Spherical coordinate formulations

13.6 Stress functions

13.6.1 Maxwell stress function representation

13.6.2 Morera stress function representation

References

13 . Exercises

14 – Nonhomogeneous elasticity

14.1 Basic concepts

14.2 Plane problem of a hollow cylindrical domain under uniform pressure

14.3 Rotating disk problem

14.4 Point force on the free surface of a half-space

14.5 Antiplane strain problems

14.6 Torsion problem

References

14 . Exercises

15 – Micromechanics applications

15.1 Dislocation modeling

15.2 Singular stress states

15.3 Elasticity theory with distributed cracks

15.4 Micropolar/couple-stress elasticity

15.4.1 Two-dimensional couple-stress theory

15.5 Elasticity theory with voids

15.6 Doublet mechanics

15.7 Higher gradient elasticity theories

References

15 . Exercises

16 – Numerical finite and boundary element methods

16.1 Basics of the finite element method

16.2 Approximating functions for two-dimensional linear triangular elements

16.3 Virtual work formulation for plane elasticity

16.4 FEM problem application

16.5 FEM code applications

16.6 Boundary element formulation