Mechanics of Solids, 2nd Edition / Mubeen, Abdul.

Format:

Book

Author/Creator:

Mubeen, Abdul, author.

Language:

English

Subjects (All):

Mechanics, Applied--Textbooks.

Mechanics, Applied.

Strength of materials.

Structural analysis (Engineering).

Physical Description:

1 online resource (659 pages)

Edition:

2nd edition

Place of Publication:

Pearson India, 2011.

System Details:

text file

Summary:

Mechanics of Solids is designed to fulfill the needs of the mechanics of solids or strength of materials courses that are offered to undergraduate students of mechanical, civil, aeronautics and chemical engineering during the second and third semesters. The book has been thoroughly revised with multiple-choice questions, examples and exercises to match the syllabi requirement of various universities across the country.

Contents:

Cover

Preface to the Second Edition

Preface to the First Edition

Contents

About the Author

Chapter 1: Analysis of Stress

1.1 Introduction

1.2 Classification of Load

1.3 Stress

1.4 Concept of Stress at a Point

1.5 State of Plane Stress

1.6 Principal Stresses

1.7 Mohr's Circle

1.8 Stress Concentration

Problems

Objective Questions

Answers

Chapter 2: Analysis of Strain

2.1 Concept of Strain

2.2 Direct and Shearing Strain

2.2.1 Shearing Strain

2.3 State of Strain at a Point

2.4 State of Plane Strain

2.5 Strain Gauge

2.6 Strain Gauge Application

Chapter 3: Stress-Strain Relationship

3.1 Hooke's Law

3.2 Three Dimensional Hooke's Law

3.3 Stress-Strain Relationships for Plane Stress

3.4 Stress-Strain Relationships for Plane Strain

3.5 Bulk Modulus

3.6 Relation Between E and G

3.7 Generalized Hooke's Law

3.8 Relationship Among Elastic Constants for an Isotropic Homogeneous Elastic Material

Chapter 4: Axial Loading

4.1 Introduction

4.2 Stress and Strain Under Axial Load

4.3 Static Properties of Materials

4.4 Elastic Stress-Strain Relationship

4.5 Mechanical Strengths

4.6 Strain Hardening

4.7 Yielding, Yield Strength and Proof Stress

4.8 Fracture Mode

4.9 Strain Energy

4.10 Resilience and Toughness

4.11 Deformation of Axially Loaded Members

4.12 Bars of Varying Cross-Section

4.13 Factor of Safety

4.14 Temperature Effects

4.15 Statically Indeterminate Axially Loaded Members

4.16 Composite Bars

Chapter 5: Thin-Walled Pressure Vessels

5.1 Introduction

5.2 Stresses in Thin Cylinders

5.3 Strain and Change in Volume

5.4 Strengthening of Thin Cylinders.

5.4.1 Strapped Cylinder

5.4.2 Wire Winding

5.4.3 Laminated Cylinder

5.5 Joints in Cylinders

5.6 Thin Spherical Shell

5.7 Volume Change in Spherical Shell

Chapter 6: Torsion

6.1 Torsional Shearing Stress and Strain

6.1.1 Torsional Displacements

6.1.2 Shearing Stress

6.2 State of Stress at a Point in a Shaft

6.3 Power Transmission

6.4 Composite Shafts-Series Connection

6.5 Statically Indeterminate Torsion Members

6.6 Strain Energy in Torsion

6.7 Torsion of Thin Walled Tubes

6.7.1 Angle of Twist for thin Walled Member

6.8 Torsion of a Tapered Shaft

6.9 Combined Axial and Torsional Load

6.10 Flanged Coupling

Chapter 7: Beams and Bending-Shear Force and Bending Moment

7.1 Classification of Beams

7.2 Shear Force and Bending Moment in a Beam

7.3 Concept of Bending Stress

7.4 Signs for Shearing Force and Bending Moment

7.5 Shearing Force and Bending Moment Equations

7.6 Shear Force and Bending Moment Diagrams

7.7 Relationships between Loading Rate, Shear Force and Bending Moment

Chapter 8: Beams and Bending-Stresses

8.1 Simple Bending Theory

8.1.1 Flexural Strain

8.1.2 Flexural Stress

8.2 Moment of Inertia of Section

8.2.1 Rectangular Section

8.2.2 I and T-Sections

8.2.3 Circular Section

8.3 Shearing Stress in Beams

8.4 Distribution of Shearing Stress

8.4.1 Application to Rectangular Section

8.4.2 Application to I-Section

8.5 Composite Beams

8.5.1 Reinforced-Concrete Beams

Chapter 9: Deflection of Beams

9.1 Introduction

9.2 Equation to Elastic Curve

9.3 A Cantilever Beam

9.4 A Simply Supported Beam

9.5 Rate of Loading and Elastic Curve.

9.6 Macaulay's Method

9.7 A Couple Acting Upon A Simply Supported Beam

Chapter 10: Beam Deflection-Moment Area Method

10.1 Slope and Deflection from Bending Moment Diagram

10.2 Parts of BM Diagrams

10.3 Statically Indeterminate Beams

10.4 Fixed Beams

10.4.1 A Fixed Beam Under UDL

10.5 A Fixed Beam with Sinking Supports

10.6 BM Diagram for a Fixed Beam

10.7 Maximum Deflection

10.8 Continuous Beam

10.9 Advantages and Disadvantages

Chapter 11: Strain Energy

11.1 Strain Energy due to Normal Stresses

11.2 Strain Energy due to Shearing Stress

11.3 Strain Energy under General State of Stress

11.4 Strain Energy due to Distortion

11.5 Strain Energy in Tension

11.6 Strain Energy of a Beam

11.7 Strain Energy in Torsion

11.8 Castigliano's Theorem

11.9 Tension due to Impact Load

11.10 Theories of Failure

11.11 Maximum principal stress theory

11.12. Maximum principal strain theory

11.13 Maximum Shearing Stress Theory

11.14 Strain energy theory

11.15 Distortion Energy Theory

Chapter 12: Springs

12.1 Introduction

12.2 Close-Coiled Helical Spring-Axial Load Stress

12.3 Close-Coiled Helical Spring-Axial Torque

12.4 Strain Energy

12.5 Combination of Springs

12.6 Open Coiled Helical Spring

12.7 Laminated Spring

12.8 Flat Spiral Spring

Chapter 13: Columns and Struts

13.1 Introduction`

13.2 Combined Bending and Direct Stress

13.3 Rectangular Section-Middle Third Rule

13.4 Middle Quarter Rule for Circular Section

13.5 Strut with Both Ends Pinned or Pivoted

13.6 Strut Fixed at One End and Free at the Other

13.7 Strut with One End Fixed and Other Pinned.

13.8 Strut Fixed at Both Ends (Ends Direction Fixed)

13.9 Euler Theory and Experimental Results

13.10 Rankine-Gordon Formula

13.11 Other Formulae

13.12 A Strut with Eccentric Load

13.13 Laterally Loaded Struts

Chapter 14: Thick Cylinders and Spheres

14.1 Stresses in Thick Cylinders

14.2 Lame's Equations

14.3 Special Case of Solid Shaft

14.4 Strains and Displacements, Compound Cylinders

14.5 Thick Spherical Shells

Chapter 15: Rotating Rings, Discs and Cylinders

15.1 Rotating Ring

15.2 Rotating Disc

15.3 Special Cases of Rotating Disc

15.4 Disc of Uniform Strength

15.5 Rotating Cylinder

15.6 Axial Stress in Rotating Cylinder-Hollow Cylinder

15.7 Axial Stress in Solid Rotating Cylinder

Chapter 16: Curved Beams

16.1 Introduction

16.2 Stresses in Curved Beams

16.3 Determination of Eccentricity

16.4 Rings Under Load

16.4.1 Deflection of Rings in the Direction of Load

16.4.2 Deflection of Ring Under Transverse Load

16.5 Stresses in Rings

16.6 Chain Link

Answer

Chapter 17: Vibrations

17.1 Vibrations Types

17.2 Simple Harmonic Motion

17.3 Linear Vibration

17.4 Transverse Vibration

17.4.1 Inertia of the Bar

17.5 Transverse Vibration of a Shaft Under its Own Weight

17.5.1 Several Loads on a Beam

17.6 Torsional Vibration

17.7 Torsional Vibration of Shaft Under Two Rotors

17.8 Helical Spring Under Torsion

17.9 Whirling of Shaft

17.9.1 Shaft Carrying a Single Rotor with Eccentricity

Appendix: Theory of Elasticity

A-1 Differential Equation of Equilibrium

A.2. Solving Equations of Equilibrium

A.3 Strain Components.

A.4. Compatibility Equations

A.5 Stress Function

Multiple Choice Questions

Index.

Notes:

Online resource; Title from title page (viewed April 18, 2011)

ISBN:

9789332501218

9332501211

OCLC:

951672150