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An Introduction to the Mechanics of Solids (Second Edition with SI Units)
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An Introduction to the Mechanics of Solids (Second Edition with SI Units)
Authors: Stephen H. Crandall and Thomas Lardner
Publisher: McGraw-Hill Inc.
Date: August 15, 1999
Format: PDF, Paperback, 604 pages
ISBN: 0072380411 / 9780072380415
Dimensions: 6 in Width x 1.3 in Thick
Size on Disk: 78.4 MB
Language: English
Overview
This text is concerned with the mechanics of rigid and deformable solids in equilibrium. It has been prepared by members of the Mechanical Engineering Department at the Massachusetts Institute of Technology for use as a text in the first course in applied mechanics. The central aim has been to treat this subject as an engineering science. To this end the authors have clearly identified three fundamental physical considerations which govern the mechanics of solids in equilibrium, and all discussion and theoretical development has been related to these basic considerations.
Table of contents
Preface to the second edition
Preface to the second edition with SI units
Preface to the first edition
Chapter One: Fundamental Principles of Mechanics
1.1 Introduction
1.2 Generalized procedure
1.3 The fundamental principles of mechanics
1.4 The concept offorce
1.5 The moment of a force
1.6 Conditions for equilibrium
1.7 Engineering applications
1.8 Friction
1.9 Examples
1.10 Hooke's joint
1.11 Final remarks
Problems
Chapter Two: Introduction to Mechanics of Deformable Bodies
2.1 Analysis of deformable bodies
2.2 Uniaxial loading and deformation
2.3 Statically determinate situations
2.4 Statically indeterminate situations
2.5 Computer analysis of trusses
2.6 Elastic energy;Castigliano's theorem
2.7 Summary
Problems
Chapter Three: Forces and Moments Transmitted by Slender Members
3.1 Introduction
3.2 General method
3.3 Distributed loads
3.4 Resultants of distributed loads
3.5 Differential equilibrium relationships
3.6 Singularity functions
3.7 Fluid forces
3.8 Three-dimensional problems
Problems
Chapter Four: Stress and Strain
4.1 Introduction
4.2 Stress
4.3 Plane stress
4.4 Equilibrium of a differential element in plane stress
4.5 Stress components associated with arbitrarily oriented faces in plane stress
4.6 Mohr's circle representation of plane stress
4.7 Mohr's circle representation of a general state of stress
4.8 Analysis of deformation
4.9 Definition of strain components
4.10 Relation between strain and displacement in plane strain
4.11 Strain components associated with arbitrary sets of axes
4.12 Mohr's circle representation of plane strain
4.13 Mohr's circle representation of a general state of stress
4.14 Measurement of strains
4.15 Indicial notation
Problems
Chapter Five: Stress-strain-temperature Relations
5.1 Introduction
5.2 The tensile test
5.3 Idealizations of stress-strain curves
5.4 Elastic stress-strain relations
5.5 Thermal strain
5.6 Complete equations of elasticity
5.7 Complete elastic solution for a thick-walled cylinder
5.8 Strain energy in an elastic body
5.9 Stress concentration
5.10 Composite materials and anisotropic elasticity
5.11 Criteria for initial yielding
5.12 Behavior beyond initial yielding in the tensile test
5.13 Fracture of ductile specimens and structures
5.14 Fracture of brittle specimens and structures
5.15 Fatigue
5.16 Criteria for continued yielding
5.17 Plastic stress-strain relations
5.18 Viscoelasticity
Problems
Chapter Six: Torsion
6.1 Introduction
6.2 Geometry of deformation of a twisted circular shaft
6.3 Stresses obtained from stress-strain relations
6.4 Equilibrium requirements
6.5 Stress and deformation in a twisted elastic circular shaft
6.6 Torsion of elastic hollow circular shafts
6.7 Stress analysis in torsion; combined stresses
6.8 Strain energy due to torsion
6.9 The onset of yielding in torsion
6.10 Plastic deformations
6.11 Residual stresses
6.12 Limit analysis
6.13 Torsion of rectangular shafts
6.14 Torsion of hollow, thin-walled shafts
Problems
Chapter Seven: Stresses Due to Bending
7.1 Introcustion
7.2 Geometry of deformation of a symmetrical beam subjected to pure bending
7.3 Stresses obtained from stress-strain relations
7.4 Equilibrium requirements
7.5 Stress and deformation in symmetrical elastic beams subjected to pure bending
7.6 Stresses in symmetrical elastic beams transmitting both shear force and bending moment
7.7 Stress analysis in bending; combined stresses
7.8 Strain energy due to bending
7.9 The onset of yielding in bending
7.10 Plastic deformations
7.11 Bending of unsymmetrical beams
7.12 Shear flow in thin-walled open sections; shear center
Problems
Chapter Eight: Deflections Due to Bending
8.1 Introduction
8.2 The moment-curvature relation
8.3 Integration of the moment-curvature relation
8.4 Superposition
8.5 The load-deflection differential equation
8.6 Energy methods
8.7 Limit analysis
Problems
Chapter Nine: Stability of Equilibrium: Buckling
9.1 Introduction
9.2 Elastic stability
9.3 Examples of instability
9.4 Elastic stability of flexible columns
9.5 Elastic postbuckling behavior
9.6 Instability as a mode of failure
9.7 Necking of tension members
9.8 Plastic buckling
Problems
Answers to Selected Problems
Index
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