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Mechanics of Materials 4th Edition by Roy Craig, Eric Taleff ISBN 1119612384 9781119612384

Name: Mechanics of Materials 4th Edition by Roy Craig, Eric Taleff ISBN 1119612384 9781119612384
SKU: EB-18242
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Authors:Ferdinand Beer; Jr. Johnston, E. Russell; John Dewolf; David Mazurek , Series:Mechanical engineering [40] , Tags:Technology & Engineering; Materials Science; Civil; General , Author sort:Beer, Ferdinand & Jr. Johnston, E. Russell & Dewolf, John & Mazurek, David , Ids:9780073380285 , Languages:Languages:eng , Published:Published:Jan 2011 , Publisher:McGraw-Hill Education , Comments:Comments:Beer and Johnston’s Mechanics of Materials is the uncontested leader for the teaching of solid mechanics. Used by thousands of students around the globe since its publication in 1981, Mechanics of Materials, provides a precise presentation of the subject illustrated with numerous engineering examples that students both understand and relate to theory and application. The tried and true methodology for presenting material gives your student the best opportunity to succeed in this course. From the detailed examples, to the homework problems, to the carefully developed solutions manual, you and your students can be confident the material is clearly explained and accurately represented. If you want the best book for your students, we feel Beer, Johnston’s Mechanics of Materials, 6th edition is your only choice.

SKU: EB-18242 Category: eBook PDF Tags: Eric Taleff, Materials 4th, Mechanics, Roy Craig

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ISBN 10: 1119612384
ISBN 13: 978-1119612384
Author: Roy R. Craig, Eric M. Taleff

The fourth edition of Mechanics of Materials is an in-depth yet accessible introduction to the behavior of solid materials under various stresses and strains. Emphasizing the three key concepts of deformable-body mechanics–equilibrium, material behavior, and geometry of deformation–this popular textbook covers the fundamental concepts of the subject while helping students strengthen their problem-solving skills. Throughout the text, students are taught to apply an effective four-step methodology to solve numerous example problems and understand the underlying principles of each application.

Focusing primarily on the behavior of solids under static-loading conditions, the text thoroughly prepares students for subsequent courses in solids and structures involving more complex engineering analyses and Computer-Aided Engineering (CAE). The text provides ample, fully solved practice problems, real-world engineering examples, the equations that correspond to each concept, chapter summaries, procedure lists, illustrations, flow charts, diagrams, and more. This updated edition includes new Python computer code examples, problems, and homework assignments that require only basic programming knowledge.

Mechanics of Materials 4th Table of contents:

Chapter 1: Introduction to Mechanics of Materials

Problems
Readings
1.1 What is Mechanics of Materials?
1.2 The Fundamental Equations of Deformable‐Body Mechanics
1.3 Problem‐Solving Procedures
1.4 Review of Static Equilibrium; Equilibrium of Deformable Bodies
Chapter Review – Introduction to Mechanics of Materials

Chapter 2: Stress and Strain; Introduction to Design

Problems
Readings
2.1 Introduction
2.2 Normal Stress
2.3 Extensional Strain; Thermal Strain
2.4 Stress‐Strain Diagrams; Mechanical Properties of Materials
2.5 Elasticity and Plasticity; Temperature Effects
2.6 Linear Elasticity; Hooke’s Law and Poisson’s Ratio
2.7 Shear Stress and Shear Strain; Shear Modulus
2.8 Introduction to Design—Axial Loads and Direct Shear
2.9 Stresses on an Inclined Plane in an Axially Loaded Member
2.10 Saint‐Venant’s Principle
2.11 Hooke’s Law for Plane Stress; The Relationship Between E and G
2.12 General Definitions of Stress and Strain
*2.13 Cartesian Components of Stress; Generalized Hooke’s Law for Isotropic Materials
*2.14 Mechanical Properties of Composite Materials
Chapter Review – Stress and Strain; Introduction to Design

Chapter 3: Axial Deformation

Problems
Readings
3.1 Introduction
3.2 Basic Theory of Axial Deformation
3.3 Examples of Nonuniform Axial Deformation
3.4 Statically Determinate Structures
3.5 Statically Indeterminate Structures
3.6 Thermal Effects on Axial Deformation
3.7 Geometric “Misfits”
3.8 Displacement‐Method Solution of Axial‐Deformation Problems
*3.9 Force‐Method Solution of Axial‐Deformation Problems
*3.10 Introduction to the Analysis of Planar Trusses
*3.11 Inelastic Axial Deformation
Chapter Review – Axial Deformation

Chapter 4: Torsion

Problems
Readings
4.1 Introduction
4.2 Torsional Deformation of Circular Bars
4.3 Torsion of Linearly Elastic Circular Bars
4.4 Stress Distribution in Circular Torsion Bars; Torsion Testing
4.5 Statically Determinate Assemblages of Uniform Torsion Members
4.6 Statically Indeterminate Assemblages of Uniform Torsion Members
*4.7 Displacement‐Method Solution of Torsion Problems
4.8 Power‐Transmission Shafts
*4.9 Thin‐Wall Torsion Members
*4.10 Torsion of Noncircular Prismatic Bars
*4.11 Inelastic Torsion of Circular Rods
Chapter Review – Torsion

Chapter 5: Equilibrium of Beams

Problems
Readings
5.1 Introduction
5.2 Equilibrium of Beams Using Finite Free‐Body Diagrams
5.3 Equilibrium Relationships Among Loads, Shear Force, and Bending Moment
5.4 Shear‐Force and Bending‐Moment Diagrams: Equilibrium Method
5.5 Shear‐Force and Bending‐Moment Diagrams: Graphical Method
*5.6 Discontinuity Functions to Represent Loads, Shear, and Moment
Chapter Review – Equilibrium of Beams

Chapter 6: Stresses in Beams

Problems
Readings
6.1 Introduction
6.2 Strain‐Displacement Analysis
6.3 Flexural Stress in Linearly Elastic Beams
6.4 Design of Beams for Strength
6.5 Flexural Stress in Nonhomogeneous Beams
*6.6 Unsymmetric Bending
*6.7 Inelastic Bending of Beams
6.8 Shear Stress and Shear Flow in Beams
6.9 Limitations on the Shear‐Stress Formula
6.10 Shear Stress in Thin‐Wall Beams
6.11 Shear in Built‐Up Beams
*6.12 Shear Center
Chapter Review – Stresses in Beams

Chapter 7: Deflection of Beams

Problems
Readings
7.1 Introduction
7.2 Differential Equations of the Deflection Curve
7.3 Slope and Deflection by Integration — Statically Determinate Beams
7.4 Slope and Deflection by Integration — Statically Indeterminate Beams
*7.5 Use of Discontinuity Functions to Determine Beam Deflections
7.6 Slope and Deflection of Beams: Superposition Method
*7.7 Slope and Deflection of Beams: Displacement Method
Chapter Review – Deflection of Beams

Chapter 8: Transformation of Stress and Strain; Mohr’s Circle

Problems
Readings
8.1 Introduction
8.2 Plane Stress
8.3 Stress Transformation for Plane Stress
8.4 Principal Stresses and Maximum Shear Stress
8.5 Mohr’s Circle for Plane Stress
8.6 Triaxial Stress; Absolute Maximum Shear Stress
8.7 Plane Strain
8.8 Transformation of Strains in a Plane
8.9 Mohr’s Circle for Strain
8.10 Measurement of Strain; Strain Rosettes
*8.11 Analysis of Three‐Dimensional Strain
Chapter Review – Transformation of Stress and Strain; Mohr’s Circle

Chapter 9: Pressure Vessels; Stresses Due to Combined Loading

Problems
Readings
9.1 Introduction
9.2 Thin‐Wall Pressure Vessels
9.3 Stress Distribution in Beams
9.4 Stresses Due to Combined Loads
Chapter Review – Pressure Vessels; Stresses Due to Combined Loads

Chapter 10: Buckling of Columns

Problems
Readings
10.1 Introduction
10.2 The Ideal Pin‐Ended Column; Euler Buckling Load
10.3 The Effect of End Conditions on Column Buckling
*10.4 Eccentric Loading; The Secant Formula
*10.5 Imperfections in Columns
*10.6 Inelastic Buckling of Ideal Columns
10.7 Design of Centrally Loaded Columns
Chapter Review – Buckling of Columns

Chapter 11: Energy Methods

Problems
Readings
11.1 Introduction
11.2 Work and Strain Energy
11.3 Elastic Strain Energy for Various Types of Loading
11.4 Work‐Energy Principle for Calculating Deflections
11.5 Castigliano’s Second Theorem; The Unit‐Load Method
*11.6 Virtual Work
*11.7 Strain‐Energy Methods
*11.8 Complementary‐Energy Methods
*11.9 Dynamic Loading; Impact
Chapter Review – Energy Methods

Chapter 12: Special Topics Related to Design

Problems
Readings
12.1 Introduction
12.2 Stress Concentrations
*12.3 Failure Theories
*12.4 Fatigue and Fracture
Chapter Review – Special Topics Related to Design

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