1st Edition
Applied Engineering Mechanics Statics and Dynamics
This is the more practical approach to engineering mechanics that deals mainly withtwo-dimensional problems, since these comprise the great majority of engineering situationsand are the necessary foundation for good design practice. The format developedfor this textbook, moreover, has been devised to benefit from contemporary ideas ofproblem solving as an educational tool. In both areas dealing with statics and dynamics,theory is held apart from applications, so that practical engineering problems, whichmake use of basic theories in various combinations, can be used to reinforce theoryand demonstrate the workings of static and dynamic engineering situations.In essence a traditional approach, this book makes use of two-dimensional engineeringdrawings rather than pictorial representations. Word problems are included in the latterchapters to encourage the student's ability to use verbal and graphic skills interchangeably.SI units are employed throughout the text.This concise and economical presentation of engineering mechanics has been classroomtested and should prove to be a lively and challenging basic textbook for two onesemestercourses for students in mechanical and civil engineering. Applied EngineeringMechanics: Statics and Dynamics is equally suitable for students in the second or thirdyear of four-year engineering technology programs.
Preface
1. Some Basic Concepts of Mechanics
1.1 Introduction
1.2 Fundamental Quantities of Length, Time, and Mass
1.3 Derived Quantities: Velocity and Acceleration
1.4 Newton’s Laws of Motion and Derived Quantity of Force
1.5 The International (SI) System of Units
1.6 Some Additional Basic Concepts and Definitions
2. Point Forces, Moments, and Static Equilibrium
2.1 Introduction
2.2 Force as a Vector
2.3 Resultant of Concurrent Coplanar Forces
2.4 Resolution of Forces
2.5 Static Equilibrium of a particle
2.6 Free-Body Diagram
2.7 Forces Acting on a Rigid Body
2.8 Moment of a Force with Respect to an Axis
2.9 Static Equilibrium of a Rigid Body
2.10 Couples
2.11 Special Cases of Coplanar Force systems
2.12 Resolution of a Force into a Force and a Couple
3 The Free-Body Diagram
3.1 Introduction
3.2 Forces at Supports
3.3 Forces Applied through Cables or Pin-Jointed Members
3.4 Forces Due to Contact with Other Bodies
3.5 Forces Due to Gravity
3.6 Forces Due to Built-in or Rigid supports
4 Friction
4.1 Introduction
4.2 Amontons’ Law
4.3 Rolling Resistance
5 Distributed Forces
5.1 Introduction
5.2 Distributed Loading
5.3 Center of Gravity
5.4 Centroid of Area
5.5 Center of Mass
5.6 Center of Gravity of a Three-Dimensional Body
6 Simple Machines
6.1 Introduction
6.2 Simple Machines
6.3 Lever
6.4 Pulley
6.5 Wheel and Axle
6.6 Inclined Plane
6.7 Wedge
6.8 Screw
7 Trusses and Frames
7.1 Introduction
7.2 Analysis of Trusses
7.3 Frames
8 Mechanisms
8.1 Introduction
8.2 Examples of Mechanisms
9 Beams
9.1 Introduction
9.2 Bending Moments and Shear Forces
9.3 Sign Convention
9.4 Shear-Force and Bending-Moment Diagrams
9.5 Relations Among Load, Shear Force, and Bending Moment
10 Common Problems Involving Friction
10.1 Introduction
10.2 Belt Friction
10.3 Disk Friction
10.4 Wedge
10.5 Screw Threads
11 Hydrostatics
11.1 Introduction
11.2 Pressure Variation in a Liquid
11.3 Hydrostatic Forces on a Submerged Plane
11.4 Second Moment of Area
11.5 Product of Inertia of an Area
12 Kinematics of Particles
12.1 Introduction
12.2 Rectilinear Motion
12.3 Rotational Motion
12.4 Plane Curvilinar Motion
12.5 Motion Along a Circular Path
13 Kinematics of Rigid Bodies (Including Applications to Mechanisms)
13.1 Introduction
13.2 Plane Motion of a Rigid Body
13.3 Velocity of a Point in a Rigid Body
13.4 Acceleration of a Point in a Rigid Body
13.5 Instantaneous Center of Rotation
13.6 Velocity and Acceleration Diagrams
14 Dynamics of Particles
14.1 Introduction
14.2 Equations of Motion
15 Work, Power, and Energy Applied to the Dynamics of Particles
15.1 Introduction
15.2 Work-Energy Equation
15.3 Conservation of Energy
15.4 Work Done by Conservative Forces
15.5 Work Done by Nonconservative Forces
16 Momentum Applied to the dynamics of Particles
16.1 Introduction
16.2 Conservation of Linear Momentum for a Particle
16.3 Conservation of Momentum for a Group of Particles
16.4 Impulse and Impact
17 Dynamics of Rigid Bodies
17.1 Introduction
17.2 Planar motion of a Rigid Body
17.3 Moment of Inertia
17.4 Translation Motion of a Rigid Body
17.5 Rotation of a Rigid Body About a Fixed Axis
17.6 General Planar Motion of a Rigid Body
18 Work, Power, and Energy Applied to the Dynamics of Rigid Bodies
18.1 Introduction
18.2 Kinetic Energy Due to Translation
18.3 Kinetic Energy Due to Rotation
18.4 Total Kinetic Energy of a Rigid Body
18.5 Power
18.6 Potential Energy
19 Momentum Applied to the Dynamics of Rigid Bodies
19.1 Introduction
19.2 Momentum
19.3 Impulse and Impact
20 Some Further Applications
20.1 Geared Systems
20.2 Balancing of Rotating Masses
20.3 Force-Free Undamped Vibrations
20.4Gyroscopic Effects
21 Project in rocketry
21.1 Introduction
21.2 Equation of Motion for a Rocket in vertical Flight
21.3 Engine Performance
21.4 Aerodynamic Forces
21.5 Wind-Tunnel Tests
21.6 Computation of Maximum Altitude
Appendixes
Appendix I: SI system of Units (A Selection of Basic and Derived Quantities)
Appendix II: Properties of Plane Figures
Appendix III: Properties of Homogeneous Solids
Nonenclature
Index
Biography
G. Boothroyd, C. Poll