Vibration control systems utilizing smart materials actuators /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Choi, Seung-Bok (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York : Nova Publishers, [2016]
Colección:Mechanical engineering theory and applications
Temas:
Vibration.
Damping (Mechanics)
Active noise and vibration control > Materials.
Smart materials.
Actuators.
Amortissement (Mécanique)
Contrôle actif du bruit et des vibrations > Matériaux.
Matériaux intelligents.
Actionneurs.
vibration (physical)
TECHNOLOGY & ENGINEERING > Engineering (General)
TECHNOLOGY & ENGINEERING > Reference.
Actuators
Smart materials
Vibration
Acceso en línea:Texto completo
Tabla de Contenidos:
  • VIBRATION CONTROL SYSTEMS UTILIZING SMART MATERIALS ACTUATORS; VIBRATION CONTROL SYSTEMS UTILIZING SMART MATERIALS ACTUATORS; Library of Congress Cataloging-in-Publication Data; CONTENTS; PREFACE; Chapter 1: A NEW HIGH LOADED MAGNETO-RHEOLOGICAL MOUNT WITH THREE OPERATION MODES FOR VIBRATION CONTROL OF A SHIP ENGINE; ABSTRACT; 1. INTRODUCTION; 2. CONFIGURATION OF THREE MODES BASED MR MOUNT; 2.1. Background of Design; 2.2. Configuration of MR Mount; 3. DESIGN OF MR MOUNT; 3.1. Parametric Model; 3.2. Results of Optimization; 4. EXPERIMENTAL RESULTS AND DISCUSSIONS; CONCLUSION; REFERENCES.
  • Chapter 2: A REVIEW OF MAGNETORHEOLOGICAL DAMPERS UTILIZED IN VIBRATION CONTROL SYSTEMSABSTRACT; 1. INTRODUCTION; 2. CHARACTERISTICS OF THE MR DAMPER; 3. MODELS OF MR DAMPER; 3.1. Parametric Dynamics Models; 3.1.1. Bingham Model; 3.1.2. Nonlinear Biviscous Model; 3.1.3 Viscoelastic Plastic Model; 3.1.4. Bouc-Wen Hysteresis Models; 3.1.5 Hyperbolic Tangent Function-Based Models; 3.2. Non-Parametric Dynamic Models; 3.2.1. Polynomial Model; 3.2.2. Neural Network Model; 3.2.3. Neuro-Fuzzy Model; 4. APPLICATION SYSTEMS; 4.1. Vehicle Suspension Systems with MR Damper.
  • 4.2. Structural Control System with MR Damper4.3. Base Isolation System with MR Damper; CONCLUSION; REFERENCES; Chapter 3: MAGNETO-RHEOLOGICAL ELASTOMERS-BASED SYSTEMS FOR VIBRATION CONTROL; ABSTRACT; 1. INTRODUCTION; 2. MRE SANDWICH STRUCTURES; 3. MRE-BASED VIBRATION ABSORPTION SYSTEMS; 4. MODELING MRE-BASED VIBRATION ISOLATION SYSTEMS; 5. PARAMETER IDENTIFICATION OF MRE VIBRATION ABSORBER MODELS; 6. CONTROL STRATEGIES FOR MRE-BASED DEVICES; SUMMARY AND SUGGESTED FUTURE STUDIES; REFERENCES; Chapter 4: PROTECTING BUILDINGS FROM SEISMIC EVENTS USING STIFFNESS SOFTENING MRE ISOLATORS; ABSTRACT.
  • 1. INTRODUCTION2. DESIGN AND CHARACTERIZATION OF THE STIFFNESS SOFTENING MRE ISOLATOR; 3. EXPERIMENTAL SETUP; 3.1. Design of the Scaled Three Story Building; 3.2. Closed Loop Control System; 4. SIMULATION; 4.1. Modelling the Isolated Building; 4.2. Fuzzy Logic Controller; 4.3. Simulation Results; 5. EXPERIMENTAL RESULTS AND DISCUSSION; CONCLUSION; REFERENCES; Chapter 5: A STATE-OF-THE-ART VIBRATION DAMPING AND CONTROL; ABSTRACT; 1. INTRODUCTION; 2. NEW DAMPING MATERIALS; 2.1. Smart Rheological Fluids; 2.2. Shape Memory Alloys; 2.3. Carbon Nanotubes; 2.4. Particle Impact Damping.
  • 3. EDDY CURRENT DAMPING4. DAMPING IN NONLINEAR SYSTEMS; CONCLUSION; REFERENCES; Chapter 6: ACTIVE CONTROL OF STRUCTURAL VIBRATION USING PIEZOELECTRIC MATERIALS; ABSTRACT; 1. INTRODUCTION; 2. BEAM STRUCTURES; 3. PLATE STRUCTURES; 4. CYLINDRICAL SHELL STRUCTURES; CONCLUSION; REFERENCES; Chapter 7: PIEZOELECTRIC SHUNT DAMPING TECHNIQUES FOR VIBRATION AND NOISE REDUCTION; ABSTRACT; 1. INTRODUCTION; 2. PRINCIPLES OF PIEZOELECTRIC SHUNT DAMPING; 2.1. Resistive Shunt Damping; 2.2. Resonant Shunt Damping; 2.2.1. Mechanical Model; 2.2.2. Electrical Model; 2.2.3. Tuning of Resonant Shunt Damping.

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