Mechanics of Materials 7th Edition by Ferdinand Beer, Russell Johnston, John DeWolf, David Mazurek ISBN 0073398233 9780073398235

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Product details:

ISBN 10:       0073398233
ISBN 13: 978-0073398235
Author:         Ferdinand P. Beer, E. Russell Johnston Jr., John T. DeWolf, David F. Mazurek

Mechanics of Materials is the uncontested leader for the teaching of solid mechanics. Used by thousands of students around the globe since publication, 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 students the best opportunity to succeed in this course. From the detailed examples, to the homework problems, to the carefully developed solutions manual, instructors and students can be confident the material is clearly explained and accurately represented.

McGraw-Hill’s Connect, is also available as an optional, add on item. Connect is the only integrated learning system that empowers students by continuously adapting to deliver precisely what they need, when they need it, how they need it, so that class time is more effective. Connect allows the professor to assign homework, quizzes, and tests easily and automatically grades and records the scores of the student’s work. Problems are randomized to prevent sharing of answers an may also have a “multi-step solution” which helps move the students’ learning along if they experience difficulty.

Mechanics of Materials 7th Table of contents:

Chapter 1: Introduction to Mechanics of Materials

1.1 Introduction
1.2 Stress and Strain
1.3 Types of Stress
1.4 Types of Strain
1.5 Engineering Stress-Strain Diagram
1.6 Hooke’s Law
1.7 Units and Conventions
1.8 Deformation of Solids

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Chapter 2: Axial Loading

2.1 Introduction to Axial Loading
2.2 Normal Stress and Strain
2.3 Deformation of Axially Loaded Members
2.4 Poisson’s Ratio
2.5 Relationship Between Elastic Constants
2.6 The Modulus of Resilience
2.7 Thermal Strain
2.8 Axial Load in Structural Elements
2.9 Applications in Real-Life Problems

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Chapter 3: Torsion

3.1 Introduction to Torsion
3.2 Torsional Stress and Strain
3.3 Deformation of Shafts Under Torsion
3.4 Power Transmission by Shafts
3.5 Angle of Twist
3.6 Thin-Walled Tubes and Shafts
3.7 Shaft Design Based on Torsion
3.8 Applications of Torsion in Engineering

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Chapter 4: Bending

4.1 Introduction to Bending
4.2 Normal Stress in Bending
4.3 Bending Stress Distribution
4.4 Flexural Formula
4.5 Deformation Due to Bending
4.6 Shear Stress in Bending
4.7 Neutral Axis and Moment of Inertia
4.8 Applications of Bending

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Chapter 5: Transverse Shear

5.1 Shear Stress in Beams
5.2 Shear Flow and Shear Center
5.3 Shear Stress Distribution in a Beam
5.4 Shear in Solid and Thin-Walled Beams
5.5 Strain Energy due to Shear
5.6 Applications of Shear Stress in Beams

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Chapter 6: Combined Loading

6.1 Introduction to Combined Loading
6.2 Axial Load and Bending
6.3 Axial Load and Torsion
6.4 Bending and Torsion in Structural Members
6.5 General Stress Transformation
6.6 Mohr’s Circle for Plane Stress
6.7 Applications of Combined Loading

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Chapter 7: Stress and Strain Transformations

7.1 Introduction to Stress Transformation
7.2 Normal and Shear Stress on an Inclined Plane
7.3 Principal Stresses and Strains
7.4 Maximum Shear Stress and Maximum Normal Stress
7.5 Mohr’s Circle for Stress and Strain
7.6 Applications of Stress and Strain Transformations

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Chapter 8: Deflection of Beams

8.1 Introduction to Beam Deflection
8.2 The Equation of the Elastic Curve
8.3 Methods for Calculating Deflection: Integration, Moment Area
8.4 The Superposition Principle
8.5 Virtual Work Method for Beam Deflection
8.6 Applications of Beam Deflection

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Chapter 9: Statically Indeterminate Structures

9.1 Introduction to Statically Indeterminate Structures
9.2 Methods of Analysis: Compatibility and Force Methods
9.3 Displacement Method
9.4 The Conjugate Beam Method
9.5 The Flexibility Method
9.6 Applications to Statically Indeterminate Systems

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Chapter 10: Column Buckling

10.1 Introduction to Column Buckling
10.2 Critical Load for Column Buckling
10.3 Buckling of Slender Columns
10.4 Effective Length Factor
10.5 Lateral-Torsional Buckling
10.6 Applications of Column Buckling

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Chapter 11: Combined Stress

11.1 Introduction to Combined Stress
11.2 The General State of Stress
11.3 Principal Stresses and Mohr’s Circle
11.4 Theories of Failure
11.5 Combined Axial and Bending Stress
11.6 Stress Concentrations
11.7 Applications of Combined Stress Analysis

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Chapter 12: Fatigue and Fracture

12.1 Introduction to Fatigue
12.2 Fatigue of Materials
12.3 High-Cycle Fatigue
12.4 Low-Cycle Fatigue
12.5 Stress-Life and Strain-Life Approaches
12.6 Fracture Mechanics
12.7 Applications of Fatigue and Fracture

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Chapter 13: Material Behavior

13.1 Elastic Behavior of Materials
13.2 Plastic Behavior of Materials
13.3 Strain Hardening
13.4 Stress-Strain Curves for Various Materials
13.5 Hardness and Toughness
13.6 Creep and Time-Dependent Behavior
13.7 Materials for Structural Applications

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