Engineering Mechanics

Submitted by tushar pramanick on Tue, 07/05/2011 - 17:03

Contents


1. Fundamentals of Mechanics  

  • 1.1 Introduction   
  • 1.2 Basic Dimensions and Units  of Mechanics,   
  • 1.3 Secondary Dimensional Quantities
  • 1.4 Law of Dimensional Homogeneity
  • 1.5 Dimensional Relation between  Force and Mass   
  • 1.6 Units of Mass   
  • 1.7 Idealizations of Mechanics   
  • 1.8 Vector and Scalar Quantities   
  • 1.9 Equality and Equivalence  of Vectors   
  • 1.10 Laws of Mechanics

 

2. Elements of vector Algebra

  • 2.1  Introduction   
  • 2.2 Magnitude and Multiplication of a Vector by a Scalar
  • 2.3 Addition and Subtraction of Vectors
  • 2.4 Resolution of Vectors; Scalar Components
  • 2.5 Unit Vectors 
  • 2.6 Useful Ways of Representing Vectors
  • 2.7 Scalar or Dot Product of Two Vectors
  • 2.8 Cross Product of Two Vectors
  • 2.9 Scalar Triple Product
  • 2.10 A Note on Vector Notation

 

3. Important vector Quantities

  • 3.1 Position Vector
  • 3.2 Moment of a Force about a Point
  • 3.3 Moment of a Force about an Axis
  • 3.4 The Couple and Couple Moment
  • 3.5 The Couple Moment as a Free Vector
  • 3.6 Addition and Subtraction of Couples
  • 3.7 Moment of a Couple About a Line 
     

 

4. Equivalent Force Systems

  • 4.1 Introduction
  • 4.2 Translation of a Force to a Parallel Position
  • 4.3 Resultant of a Force System
  • 4.4 Simplest Resultants of Special Force Systems
  • 4.5 Distributed Force Systems
     

 

5. Equations of Equilibrium

  • 5.1 Introduction 
  • 5.2 The Free-body Diagram
  • 5.3 Free Bodies Involving Interior Sections
  • 5.4 Looking Ahead?Control Volumes
  • 5.5 General Equations of Equilibrium
  • 5.6 Problems of Equilibrium I 
  • 5.7 Problems of Equilibrium II 
  • 5.8 Two Point Equivalent Loading
  • 5.9 Problems Arising from Structures
  • 5.10 Static Indeterminacy
     

 

6.   Introduction to structural Mechanics

Part A: Trusses

  • 6.1 The Structural Model
  • 6.2 The Simple Truss
  • 6.3 Solution of Simple Trusses
  • 6.4 Method of Joints
  • 6.5 Method of Sections
  • 6.6 Looking Ahead?Deflection of a Simple, Linearly Elastic Truss

Part B: Section Forces in Beams

  • 6.7 Introduction
  • 6.8 Shear Force, Axial Force, and Bending Moment
  • 6.9 Differential Relations for Equilibrium

Part C: Chains and Cables

  • 6.10 Introduction
  • 6.11 Coplanar Cables; Loading is a Function of x
  • 6.12 Coplanar Cables: Loading is the Weight of the Cable Itself


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7. Friction Forces

  • 7.1 Introduction
  • 7.2 Laws of Coulomb Friction
  • 7.3 A Comment Concerning the Use of Coulomb's Law
  • 7.4 Simple Contact Friction Problems
  • 7.5 Complex Surface Contact Friction Problems
  • 7.6 Belt Friction
  • 7.7 The Square Screw Thread
  • 7.8 Rolling Resistance
     

 

8.   Properties of Surfaces

  • 8.1 Introduction
  • 8.2 First Moment of an Area and theCentroid
  • 8.3 Other Centers
  • 8.4 Theorems of Pappus-Guldinus
  • 8.5 Second Moments and the Product of Area of a Plane Area
  • 8.6 Tranfer Theorems
  • 8.7 Computations Involving Second Moments and Products of Area
  • 8.8 Relation Between Second Moments and Products of Area
  • 8.9 Polar Moment of Area
  • 8.10 Principal Axes
     

9.    Moments and Products of Inertia

  • 9.1 Introduction
  • 9.2 Formal Definition of Inertia Quantities
  • 9.3 Relation Between Mass-Inertia Terms and Area-Inertia Terms
  • 9.4 Translation of Coordinate Axes
  • 9.5 Transformation Properties of the Inertia Terms
  • 9.6 Looking Ahead?Tensors
  • 9.7 The Inertia Ellipsoid and Principal Moments of Inertia

 

10.   Methods of Virtual Work and Stationary Potential Energy

  • 10.1    Introduction

Part A: Method of Virtual Work

  • 10.2 Principle of Virtual Work for a Particle
  • 10.3 Principle of Virtual Work for Rigid Bodies
  • 10.4 Degrees of Freedom and the Solution of Problems
  • 10.5    Looking Ahead?Deformable Solids

Part B: Method of Total Potential Energy

  • 10.6 Conservative Systems
  • 10.7 Condition of Equilibrium for a Conservative System
  • 10.8 Stability
  • 10.9 Looking Ahead?More on Total Potential Energy


11. Kinematics of a Particle?Simple Relative Motion

  • 11.1    Introduction

Part A: General Notions

  • 11.2    Differentiation of a Vector with Respect to Time

Part B: Velocity and Acceleration Calculations

  • 11.3 Introductory Remark
  • 11.4 Rectangular Components
  • 11.5 Velocity and Acceleration in Terms of Path Variables
  • 11.6 Cylindrical Coordinates

Part C: Simple Kinematical Relations and Applications

  • 11.7 Simple Relative Motion
  • 11.8 Motion of a Particle Relative to a Pair of Translating Axes
     


12. Particle Dynamics

  • 12.1    Introduction

Part A: Rectangular Coordinates; Rectilinear Translation

  • 12.2 Newton's Law for Rectangular Coordinates
  • 12.3 Rectilinear Translation
  • 12.4 A Comment

Part B: Cylindrical Coordinates; Central Force Motion

  • 12.5 Newton's Law for Cylindrical Coordinates
  • 12.6 Central Force Motion? An Introduction
  • 12.7 Gravitational Central Force Motion
  • 12.8 Applications to Space Mechanics

Part C: Path Variables

  • 12.9    Newton's Law for Path Variables

Part D: A System of Particles

  • 12.10 The General Motion of a System of Particles

 

13.    Energy Methods for Particles

Part A: Analysis for a Single Particle

  • 13.1 Introduction
  • 13.2 Power Considerations
  • 13.3 Conservative Force Field
  • 13.4 Conservation of Mechanical Energy
  • 13.5 Alternative Form of Work-Energy Equation

Part B: Systems of Particles

  • 13.6 Work-Energy Equations
  • 13.7 Kinetic Energy Expression Based on Center of Mass
  • 13.8 Work-Kinetic Energy Expressions Based on Center of Mass
     

14. Methods of Momentum for Particles

Part A: Linear Momentum

  • 14.1 Impulse and Momentum Relations for a Particle
  • 14.2 Linear-Momentum Considerations for a System of Particles
  • 14.3 Impulsive Forces
  • 14.4 Impact
  • 14.5 Collision of a Particle with a Massive Rigid Body

Part B: Moment of Momentum

  • 14.6 Moment-of-Momentum Equation for a Single Particle
  • 14.7 More on Space Mechanics
  • 14.8 Moment-of-Momentum Equation for a System of Particles
  • 14.9 Looking Ahead?Basic Laws of Continua


 
15. Kinematics of Rigid Bodies; Relative Motion

  • 15.1 Introduction
  • 15.2 Translation and Rotation of Rigid Bodies
  • 15.3 Chasles'Theorem
  • 15.4 Derivative of a Vector Fixed in a Moving Reference
  • 15.5 Applications of the Fixed-Vector Concept
  • 15.6 General Relationship Between Time Derivatives of a Vector for Different References
  • 15.7 The Relationship Between Velocities of a Particle for Different References
  • 15.8 Acceleration of a Particle for Different References
  • 15.9 A New Look at Newton's Law
  • 15.10 The Coriolis Force


 16. Kinetics of Plane Motion of Rigid Bodies

  • 16.1 Introduction
  • 16.2 Moment-of-Momentum Equations
  • 16.3 Pure Rotation of a Body of Revolution About its Axis of Revolution
  • 16.4 Pure Rotation of a Body with Two Orthogonal Planes of Symmetry
  • 16.5 Pure Rotation of Slablike Bodies
  • 16.6 Rolling Slablike Bodies
  • 16.7 General Plane Motion of a Slablike Body
  • 16.8 Pure Rotation of an Arbitrary Rigid Body
  • 16.9 Balancing

17. Energy and Impulse-Momentum Methods for Rigid Bodies 

  • 17.1      Introduction

Part A: Energy Methods 

  • 17.2 Kinetic Energy of a Rigid Body  
  • 17.3 Work-Energy Relations  

Part B: Impulse-Momentum Methods 

  • 17.4 Angular Momentum of a Rigid Body About Any Point in the Body
  • 17.5 Impulse-Momentum Equations
  • 17.6 Impulsive Forces and Torques: Eccentric Impact 
     

18. Dynamics of General Rigid-Body Motion

  • 18.1 Introduction
  • 18.2 Euler's Equations of Motion
  • 18.3 Application of Euler's Equations
  • 18.4 Necessary and Sufficient Conditions for Equilibrium of a Rigid Body
  • 18.5 Three-Dimensional Motion About a Fixed Point; Euler Angles
  • 18.6 Equations of Motion Using Euler Angles
  • 18.7 Torque-Free Motion
     

19. Vibrations

  • 19.1 Introduction
  • 19.2 Free Vibration 
  • 19.3 Torsional Vibration 
  • 19.4 Examples of Other Free-Oscillating Motions 
  • 19.5 Energy Methods 
  • 19.6 Linear Restoring Force and a Force Varying Sinusoidally with Time 
  • 19.7 Linear Restoring Force with Viscous Damping
  • 19.8 Linear Restoring Force, Viscous Damping, and a Harmonic Disturbance 
  • 19.9 Oscillatory Systems with Multi-Degrees of Freedom

 

 

 

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