Solving Engineering Problems in Dynamics

Takes an analytical approach by using step-by-step universal methodologies to solve problems of motion in mechanical and industrial engineering. This is a very useful guide for students in mechanical and industrial engineering, as well practitioners who need to analyse and solve a variety of problems in dynamics.

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This comprehensive yet compact step-by-step guide to solving real life mechanical engineering problems in dynamics offers all the necessary methodologies and supplemental information—in one place. It includes numerous solutions of examples of linear, non-linear, and two-degree-of-freedom systems. These solutions demonstrate in detail the process of the analytical investigations of actual mechanical engineering problems in dynamics. It is sure to be a very useful guide for students in Mechanical and Industrial Engineering, as well practitioners who need to analyze and solve a variety of problems in dynamics.  Introduction



Differential Equations Of Motion



Analysis Of Forces
Analysis of Resisting Forces
Forces of Inertia
Damping Forces
Stiffness Forces
Constant Resisting Forces
Friction Forces
Analysis of Active Forces
Constant Active Forces
Sinusoidal Active Forces
Active Forces Depending on Time
Active Forces Depending on Velocity
Active Forces Depending on Displacement

Solving Differential Equations of Motion Using Laplace Transforms



Laplace Transform Pairs For Differential Equations of Motion
Decomposition of Proper Rational Fractions
Examples of Decomposition of Fractions
Examples of Solving Differential Equations of Motion
Motion by by Inertia with no Resistance
Motion by Inertia with Resistance of Friction
Motion by Inertia with Damping Resistance
Free Vibrations
Motion Caused by Impact
Motion of a Damped System Subjected to a Tim Depending Force
Forced Motion with Damping and Stiffness
Forced Vibrations

Analysis of Typical Mechanical Engineering Systems



Lifting a Load
Acceleration
Braking
Water Vessel Dynamics
Dynamics of an Automobile
Acceleration
Braking
Acceleration of a Projectile in the Barrel
Reciprocation Cycle of a Spring-loaded Sliding Link
Forward Stroke Due to a Constant Force
Forward Stroke Due to Initial Velocity
Backward Stroke
Pneumatically Operated Soil Penetrating Machine

Piece-Wise Linear Approximation



Penetrating into an Elasto-Plastic Medium
First Interval
Second Interval
Third Interval
Fourth Interval
Non-linear Damping Resistance
First Interval
Second Interval

Dynamics of Two-Degree-of-Freedom Systems



Differential Equations of Motion: A Two-Degree-of-Freedom System
A System with a Hydraulic Link (Dashpot)
A System with an Elastic Link (Spring)
A System with a Combination of a Hydraulic Link (Dashpot) and an Elastic Link (Spring)
Solutions of Differential Equations of Motion for Two-Degree-of-Freedom Systems
Solutions for a System with a Hydraulic Link
Solutions for a System with an Elastic Link
Solutions for a System with a Combination of a Hydraulic and an Elastic Link
A System with a Hydraulic Link where the First Mass Is Subjected to a Constant External Force
A Vibratory System Subjected to an External Sinusoidal Force