This textbook is intended for the first course of engineering dynamics for undergraduate students. Engineering dynamics is a rigorous topic that typically involves the intensive use of vector mathematics and calculus. This book, however, uses plain language with less vector mathematics and calculus to introduce these topics of mathematics to students with a high school physics background. Numerous practical examples are provided with their step-by-step worked out solutions, as well as case studies to reflect the interests of new engineering and applied engineering students. The topics covered in the Fundamentals of Engineering (FE) examination are presented throughout the text. It also includes roadway dynamics to incorporate engineering dynamics and transportation engineering for civil engineering.
Features:
- Discusses theory using easy-to-understand language with less vector mathematics and calculus
- Includes practical case studies and numerous realistic step-by-step solved examples
- Includes exercise problems for students’ practice
- Provides numerous sample examples related to the Fundamentals of Engineering (FE) exam
- Includes a solutions manual and PowerPoint slides for adopting instructors
Engineering Dynamics: Fundamentals and Applications serves as a useful resource for students across several engineering degree programs, such as civil, mechanical, aerospace, automotive, chemical, and electrical engineering. It is also appropriate for engineering technology and applied science students as well.
Author(s): M. Rashad Islam, A. K. M. Monayem H. Mazumder, Mahbub Ahmed
Publisher: CRC Press
Year: 2022
Language: English
Pages: 320
City: Boca Raton
Cover
Half Title
Title Page
Copyright Page
Table of Contents
Preface
Authors
Chapter 1 Introduction
1.1 Mechanics
1.2 Principal of Mechanics
1.3 Basic Quantities
1.4 Basics of Units
1.4.1 Types of Units
1.4.2 Systems of Units
1.5 Rounding Off
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 1.1
FE Problem 1.2
FE Problem 1.3
FE Problem 1.4
FE Problem 1.5
FE Problem 1.6
Chapter 2 Kinematics of Particles
2.1 Analytical Analysis of Particle’s Rectilinear Motion in Surface
2.2 Graphical Analysis of Particle’s Rectilinear Motion
2.2.1 Graphical System
2.2.2 Displacement versus Time Graph
2.2.3 Velocity versus Time Graph
2.2.4 Acceleration versus Time Graph
2.3 Motion of Falling Particles
2.4 Particle’s Projectile Motion
2.5 Particle’s Horizontal Projectile Motion
2.6 Planar Curvilinear Motion
2.6.1 Background
2.6.2 Rectangular Components of Curvilinear Motion
2.6.3 Tangential and Normal Components of Curvilinear Motion
2.6.4 Radial and Transverse Components of Curvilinear Motion
2.7 Relative Motion
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 2.1
FE Problem 2.2
FE Problem 2.3
FE Problem 2.4
FE Problem 2.5
FE Problem 2.6
FE Problem 2.7
FE Problem 2.8
FE Problem 2.9
FE Problem 2.10
FE Problem 2.11
FE Problem 2.12
FE Problem 2.13
FE Problem 2.14
FE Problem 2.15
FE Problem 2.16
FE Problem 2.17
Practice Problems
Chapter 3 Kinetics of Particles
3.1 General
3.2 Concept of Force
3.3 Types of Forces
3.4 Newton’s Second Law of Motion
3.5 Applications of Newton’s Law of Motion
3.6 Work and Energy of Particles
3.6.1 Work
3.6.2 Energy
3.6.2.1 Definitions
3.6.2.2 Kinetic Energy (T)
3.6.2.3 Work-Energy Theorem
3.6.2.4 Potential Energy
3.6.2.5 Conservation of Energy
3.7 Impulsive Force
3.8 Application of Impulsive Force
3.9 Conservation of Linear Momentum
3.10 Impact
3.11 Angular Momentum and Angular Impulse
3.12 Conservation of Angular Momentum and Angular Impulse
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 3.1
FE Problem 3.2
FE Problem 3.3
FE Problem 3.4
FE Problem 3.5
FE Problem 3.6
FE Problem 3.7
FE Problem 3.8
FE Problem 3.9
FE Problem 3.10
FE Problem 3.11
FE Problem 3.12
FE Problem 3.13
FE Problem 3.14
FE Problem 3.15
FE Problem 3.16
FE Problem 3.17
Practice Problems
Chapter 4 Kinematics of a Rigid Body
4.1 General
4.2 Translation
4.3 Rotation about an Arbitrary Fixed Axis
4.3.1 Angular Displacement
4.3.2 Angular Velocity
4.3.3 Angular Acceleration
4.3.4 For Constant Acceleration
4.3.5 Non-constant Acceleration
4.4 General Plane Motion
4.5 Rotation about Instantaneous Axis
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 4.1
FE Problem 4.2
FE Problem 4.3
FE Problem 4.4
FE Problem 4.5
FE Problem 4.6
FE Problem 4.7
FE Problem 4.8
FE Problem 4.9
FE Problem 4.10
Practice Problems
Chapter 5 Kinetics of a Rigid Body
5.1 General
5.2 Mass Moment of Inertia
5.3 Radius of Gyration
5.4 Angular Momentum
5.5 Torque or Moment of a Force
5.6 Relationship between Torque and Angular Acceleration
5.7 Kinetic Energy
5.8 Work, Power, and Efficiency
5.8.1 Work
5.8.2 Work Done in Spring
5.8.3 Work Done on a Strained Body
5.8.4 Work Done by Couple Moment
5.8.5 Power
5.8.6 Efficiency
5.9 Principal of Work and Energy
5.10 Impulse and Momentum
5.11 Conservation of Impulse and Momentum
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 5.1
FE Problem 5.2
FE Problem 5.3
FE Problem 5.4
FE Problem 5.5
FE Problem 5.6
FE Problem 5.7
FE Problem 5.8
FE Problem 5.9
FE Problem 5.10
Practice Problems
Chapter 6 Dynamics in Roadways
6.1 General
6.2 Resistances
6.2.1 Air Resistance
6.2.2 Surface or Rolling Resistance
6.2.3 Grade Resistance
6.3 Effective Tractive Force
6.4 Maximum Tractive Effort
6.5 Stopping Distances
6.5.1 Theoretical Distance
6.5.2 Practical Stopping Distance
6.6 Vehicle Dynamics in Horizontal Curves
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 6.1
FE Problem 6.2
FE Problem 6.3
FE Problem 6.4
FE Problem 6.5
FE Problem 6.6
FE Problem 6.7
FE Problem 6.8
FE Problem 6.9
FE Problem 6.10
FE Problem 6.11
FE Problem 6.12
FE Problem 6.13
FE Problem 6.14
FE Problem 6.15
FE Problem 6.16
FE Problem 6.17
FE Problem 6.18
FE Problem 6.19
Practice Problems
References
Chapter 7 Vibration
7.1 General
7.2 Undamped-Free Linear Vibration
7.3 Undamped-Free Torsional Vibration
7.4 Undamped Forced Vibration
7.4.1 Periodic Force
7.4.2 Periodic Support Displacement
7.5 Viscous Damped Free Vibration
7.6 Viscous Damped Forced Vibration
Fundamentals of Engineering (FE) Exam Style Questions
FE Problem 7.1
FE Problem 7.2
FE Problem 7.3
FE Problem 7.4
FE Problem 7.5
FE Problem 7.6
FE Problem 7.7
Practice Problems
Appendix: Second-Order Linear Homogeneous Differential Equations with Constant Coefficients
Index
