"Fracture Mechanics: With an Introduction to Micromechanics" by Dietmar Gross, Thomas Seelig
Mechanical Engineering Series, ISSN 0941-5122
Springer-Verlag | 2006 | ISBN: 3540240341 | 323 pages | File type: PDF | 5 mb

This book has evolved from lectures on fracture mechanics and micromechanics which we held for students of engineering and natural sciences over the years. A major part of the book is devoted to linear elastic and elastic-plastic fracture mechanics. Further subjects are creep fracture, dynamic fracture mechanics, damage mechanics, probabilistic fracture mechanics, failure of thin films and fracture of piezoelectric materials.

http://ifile.it/qd284co/FractureMechanicsIntro2Micromech.rar �?| �? http://www.easy-share.com/1912946165/FractureMechanicsIntro2Micromech.rar
http://www.megaupload.com/?d=4YUJOQ71
The book also contains an extensive introduction into micromechanics. Self-contained and well-illustrated, this text serves as a graduate-level text and reference.

Throughout the previous three editions the contents of the book has successively been extended. It originated from a textbook solely on fracture mechanics by the first author alone. In the third edition, it was in collaboration with the second author supplemented with a chapter on micromechanics to account for the increasing utilization of micromechanical modeling in the treatment of fracture problems.

Contents
Introduction
1 Elements of solid mechanics
1.1 Stress
1.1.1 Stress vector
1.1.2 Stress tensor
1.1.3 Equilibrium conditions
1.2 Deformation and strain
1.2.1 Strain tens1.2.2 Strain rate
1.3 Constitutive laws
1.3.1 Elasticity
1.3.2 Viscoelasticity
1.3.3 Plasticity
1.4 Energy principles
1.4.1 Energy balance
1.4.2 Principle of virtual work
1.4.3 Theorems of Clapeyron and Betti
1.5 Plane problems
1.5.1 Plane stress, plane strain, longitudinal shear
1.5.2 Linear elasticity, complex method
1.5.3 Perfectly plastic material, slip line fields
1.6 Further reading
2 Classical fracture and failure hypotheses
2.1 Basic concepts
2.2 Failure hypotheses
2.2.1 Principal stress hypothesis
2.2.2 Principal strain hypothesis
2.2.3 Strain energy hypothesis
2.2.4 Coulomb
-Mohr hypothesis
2.2.5 Drucker-Prager hypothesis
2.3 Deformation behavior during failure
2.4 Further reading
3 Micro and macro phenomena of fracture
3.1 Microscopic aspects
3.1.1 Surface energy, theoretical strength
3.1.2 Microstructure and defects
3.1.3 Crack formation
3.2 Macroscopic aspects
3.2.1 Crack growth
3.2.2 Types of fracture
3.3 Further reading
4 Linear fracture mechanics
4.1 General remarks
4.2 Crack-tip field
4.2.1 Two-dimensional crack-tip fields
4.2.2 Mode-I crack-tip field
4.2.3 Three-dimensional crack-tip field
4.3 K-concept
4.4 K-factors
4.4.1 Examples
4.4.2 Integral equation formulation
4.4.3 Method of weight functions
4.4.4 Crack interaction
4.5 Fracture toughness KIc
4.6 Energy balance
4.6.1 Energy release during crack propagation
4.6.2 Energy release rate
4.6.3 Compliance, energy release rate, and K-factors
4.6.4 Energy balance, Griffith’s fracture criterion
4.6.5 J−integral
4.7 Small-scale yielding
4.7.1 Plastic zone size, Irwin’s crack length correction
4.7.2 Qualitative remarks on the plastic zone
4.8 Stable crack growth
4.9 Mixed-mode loading
4.10 Fatigue crack growth
4.11 Interface cracks
4.12 Piezoelectric materials
4.12.1 Basic principles
4.12.2 The crack in a ferroelectric material
4.13 Further reading
5 Elastic-plastic fracture mechanics
5.1 Introduction
5.2 Dugdale model
5.3 Crack-tip field
5.3.1 Perfectly plastic material
5.3.2 Total strain theory, HRR−field
5.4 Fracture criterion
5.5 Determination of J
5.6 Determination of Jc
5.7 Crack propagation
5.7.1 J–controlled crack growth
5.7.2 Stable crack growth
5.7.3 Steady-state crack growth
5.8 Essential work of fracture
5.9 Further reading
6 Creep fracture
6.1 Introduction
6.2 Fracture of linear viscoelastic materials
6.2.1 Crack-tip field, elastic-viscoelastic analogy
6.2.2 Fracture concept
6.2.3 Crack propagation
6.3 Creep fracture of nonlinear materials
6.3.1 Secondary creep, constitutive law
6.3.2 Stationary crack, crack-tip field, loading parameters
6.3.3 Creep crack growth
6.4 Further reading
7 Dynamic fracture mechanics
7.1 Introduction
7.2 Some foundations of elastodynamics
7.3 Dynamic loading of a stationary crack

[Fast Download]

Copyright Disclaimer:
This site does not store any files on its server. We only index and link to content provided by other sites. Please contact the content providers to delete copyright contents if any and email us, we'll remove relevant links or contents immediately.