This new guide 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 analyze and solve a variety of problems in dynamics. It emphasizes the importance of linear differential equations of motion, using LaPlace Transform, in the process of investigating actual problems. It includes numerous examples for composing differential equations of motion.
This new guide 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 analyze and solve a variety of problems in dynamics. It emphasizes the importance of linear differential equations of motion, using LaPlace Transform, in the process of investigating actual problems. It includes numerous examples for composing differential equations of motion.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Michael B. Spektor taught for many years at Oregon Institute of Technology, and before retiring he was the director of the manufacturing engineering technology bachelor degree program at Boeing in Seattle. He has an undergraduate degree in mechanical engineering from Kiev Polytechnic University and a Ph. D. in mechanical engineering from Kiev Construction University. He has worked in both industry and higher education in the United States, Israel, and the former Soviet Union. Spektor holds five U.S. Patents and two U.S.S.R. Inventor’s Certificates. Some of his career highlights include: chief designer of an automobile crane; the design and development of vibratory and impact machines; an analysis of the dynamics of construction safety harnesses that directly led to their improvement; developer of the theory and engineering calculations for the optimization of soil-working vibratory processes for minimum energy consumption; analytical investigations of media deformation under dynamic loading that improved the methodologies for measuring and interpreting experimental data; and the publication of numerous scientific articles on dynamics.
Inhaltsangabe
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
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
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