Impact mechanics / W.J. Stronge, University of Cambridge.
This second edition of Impact Mechanics offers new analytical methods with examples for the dynamics of low-speed impact.
Saved in:
| Online Access: |
Full Text (via ProQuest) |
|---|---|
| Main Author: | |
| Format: | eBook |
| Language: | English |
| Published: |
Cambridge, United Kingdom ; New York, NY, USA :
University of Cambridge,
2018.
|
| Edition: | Second edition. |
| Subjects: |
Table of Contents:
- Cover; Half-title; Title page; Copyright information; Dedication; Contents; Preface to Second Edition; Preface to First Edition; Acknowledgments; 1 Introduction to Analysis of Low-Speed Impact; 1.1 Terminology of Two-Body Impact; 1.1.1 Configuration of Colliding Bodies; Central or Collinear Impact Configuration; Eccentric Impact Configuration; 1.1.2 Relative Velocity at Contact Point; 1.1.3 Interaction Force; 1.2 Classification of Methods for Analyzing Impact; 1.2.1 Description of ''Rigid Body'' Impact; Underlying Premise of Rigid Body Impact Theory.
- Collisions with Compliant Contact Points of Otherwise ''Rigid'' Bodies1.2.2 Description of Transverse Impact on Flexible Bodies; 1.2.3 Description of Axial Impact on Flexible Bodies; 1.2.4 Applicability of Theories for Low-Speed Impact; 1.3 Principles of Dynamics; 1.3.1 Particle Kinetics; 1.3.2 Kinetics for Set of Particles; 1.3.3 Kinetic Equations for Rigid Body; Translational Momentum and Moment of Momentum; Kinetic Energy; 1.3.4 Rate of Change for Moment of Momentum of System about Point Moving Steadily Relative to Inertial Reference Frame; 1.4 Decomposition of a Vector.
- 1.5 Vectorial and Indicial NotationProblems; 2 Collinear Rigid Body Impact; 2.1 Equation of Relative Motion for Direct Impact; 2.2 Compression and Restitution Phases of Collision; 2.3 Kinetic Energy of Normal Relative Motion; 2.4 Work of Normal Contact Force; 2.5 Coefficient of Restitution and Kinetic Energy Absorbed in Collision; 2.6 Velocities of Contact Points at Separation; 2.7 Partition of Loss of Kinetic Energy into Part for Each Body; Problems; Normal Incidence; Oblique Incidence; 3 Planar or Two-Dimensional Rigid Body Impact; 3.1 Equation of Relative Motion at the Contact Point.
- 3.2 Impact of Smooth Bodies3.3 Friction from Sliding of Rough Bodies; 3.3.1 Amontons-Coulomb Law for Dry Friction; 3.3.2 Equations of Planar Motion for Collision of Rough Bodies; 3.3.3 Contact Processes and Evolution of Sliding during Impact; 3.4 Work of Reaction Impulse; 3.4.1 Total Work Equals Change in Kinetic Energy; 3.4.2 Partial Work by Component of Impulse; 3.4.3 Energetic Coefficient of Restitution; 3.4.4 Terminal Impulse pf for Different Slip Processes; Terminal impulse pf for arbitrary initial conditions; 3.5 Friction in Collinear Impact Configurations.
- 3.6 Friction in Non-Collinear Impact Configurations3.6.1 Planar Impact of Rigid Bar on Rough Half-space; Terminal velocity at Contact Point and Energy Dissipation during Impact; Problems; 4 Three-Dimensional Impact of Rough Rigid Bodies; 4.1 Collision of Two Free Bodies; 4.1.1 Law of Friction for Rough Bodies; 4.1.2 Equation of Motion as Function of Normal Impulse; 4.1.3 Sliding That Halts during Collision; 4.1.4 Terminal Normal Impulse Related to Energetic Coefficient of Restitution; 4.2 Oblique Collision of Rotating Sphere on Rough Half-Space.