Active and Passive Vibration Damping
This book is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author - a noted expert on the topic - presents the basic principles and reviews the potential application...
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| Main Author | |
|---|---|
| Format | eBook Book |
| Language | English |
| Published |
Hoboken, N.J
John Wiley & Sons
2019
Wiley John Wiley & Sons, Incorporated Wiley-Blackwell |
| Edition | 1 |
| Subjects | |
| Online Access | Get full text |
| ISBN | 9781118481929 1118481925 |
| DOI | 10.1002/9781118537619 |
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| Abstract | This book is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author - a noted expert on the topic - presents the basic principles and reviews the potential applications of passive and active vibration damping technologies. The text presents a combination of the associated physical fundamentals, governing theories and the optimal design strategies of various configurations of vibration damping treatments. The text presents the basics of various damping effective treatments such as constrained layers, shunted piezoelectric treatments, electromagnetic and shape memory fibers. Classical and new models are included as well as aspects of viscoelastic materials models that are analyzed from the experimental characterization of the material coefficients as well as their modeling. The use of smart materials to augment the vibration damping of passive treatments is pursued in depth throughout the book. |
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| AbstractList | A practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author - a noted expert on the topic - presents the basic principles and reviews the potential applications of passive and active vibration damping technologies. The text presents a combination of the associated physical fundamentals, governing theories and the optimal design strategies of various configurations of vibration damping treatments. The text presents the basics of various damping effective treatments such as constrained layers, shunted piezoelectric treatments, electromagnetic and shape memory fibers. This book is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author - a noted expert on the topic - presents the basic principles and reviews the potential applications of passive and active vibration damping technologies. The text presents a combination of the associated physical fundamentals, governing theories and the optimal design strategies of various configurations of vibration damping treatments. The text presents the basics of various damping effective treatments such as constrained layers, shunted piezoelectric treatments, electromagnetic and shape memory fibers. Classical and new models are included as well as aspects of viscoelastic materials models that are analyzed from the experimental characterization of the material coefficients as well as their modeling. The use of smart materials to augment the vibration damping of passive treatments is pursued in depth throughout the book. A guide to the application of viscoelastic damping materials to control vibration and noise of structures, machinery, and vehicles Active and Passive Vibration Damping is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author - a noted expert on the topic - presents the basic principles and reviews the potential applications of passive and active vibration damping technologies. The text presents a combination of the associated physical fundamentals, governing theories and the optimal design strategies of various configurations of vibration damping treatments. The text presents the basics of various damping effective treatments such as constrained layers, shunted piezoelectric treatments, electromagnetic and shape memory fibers. Classical and new models are included as well as aspects of viscoelastic materials models that are analyzed from the experimental characterization of the material coefficients as well as their modeling. The use of smart materials to augment the vibration damping of passive treatments is pursued in depth throughout the book. This vital guide: Contains numerical examples that reinforce the understanding of the theories presented Offers an authoritative text from an internationally recognized authority and pioneer on the subject Presents, in one volume, comprehensive coverage of the topic that is not available elsewhere Presents a mix of the associated physical fundamentals, governing theories and optimal design strategies of various configurations of vibration damping treatments Written for researchers in vibration damping and research, engineers in structural dynamics and practicing engineers, Active and Passive Vibration Damping offers a hands-on resource for applying passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. A guide to the application of viscoelastic damping materials to control vibration and noise of structures, machinery, and vehiclesActive and Passive Vibration Damping is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. The author — a noted expert on the topic — presents the basic principles and reviews the potential applications of passive and active vibration damping technologies. The text presents a combination of the associated physical fundamentals, governing theories and the optimal design strategies of various configurations of vibration damping treatments.The text presents the basics of various damping effective treatments such as constrained layers, shunted piezoelectric treatments, electromagnetic and shape memory fibers. Classical and new models are included as well as aspects of viscoelastic materials models that are analyzed from the experimental characterization of the material coefficients as well as their modeling. The use of smart materials to augment the vibration damping of passive treatments is pursued in depth throughout the book. This vital guide:Contains numerical examples that reinforce the understanding of the theories presentedOffers an authoritative text from an internationally recognized authority and pioneer on the subjectPresents, in one volume, comprehensive coverage of the topic that is not available elsewherePresents a mix of the associated physical fundamentals, governing theories and optimal design strategies of various configurations of vibration damping treatmentsWritten for researchers in vibration damping and research, engineers in structural dynamics and practicing engineers, Active and Passive Vibration Damping offers a hands-on resource for applying passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures, machinery and vehicles. |
| Author | Baz Amr M |
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| Notes | Includes bibliographical references and index |
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| Snippet | This book is a practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of... A guide to the application of viscoelastic damping materials to control vibration and noise of structures, machinery, and vehiclesActive and Passive Vibration... A practical guide to the application of passive as well as actively treated viscoelastic damping materials to control vibration and noise of structures,... A guide to the application of viscoelastic damping materials to control vibration and noise of structures, machinery, and vehicles Active and Passive Vibration... |
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| SubjectTerms | Civil Engineering & Construction Materials Damping (Mechanics) Mechanics & Mechanical Engineering Structural Engineering Vibration |
| TableOfContents | Title Page
List of Symbols
Abbreviations
Preface
Table of Contents
1. Vibration Damping
2. Viscoelastic Damping
3. Characterization of the Properties of Viscoelastic Materials
4. Viscoelastic Materials
5. Finite Element Modeling of Viscoelastic Damping by Modal Strain Energy Method
6. Energy Dissipation in Damping Treatments
7. Vibration Damping of Structures Using Active Constrained Layer Damping
8. Advanced Damping Treatments
9. Vibration Damping with Shunted Piezoelectric Networks
10. Vibration Control with Periodic Structures
11. Nanoparticle Damping Composites
12. Power Flow in Damped Structures
Glossary
Appendix A: Complex Modulus of Typical Damping Treatments
Index Intro -- Title Page -- Copyright Page -- Contents -- Preface -- List of Symbols -- Abbreviations -- Part I Fundamentals of Viscoelastic Damping -- Chapter 1 Vibration Damping -- 1.1 Overview -- 1.2 Passive, Active, and Hybrid Vibration Control -- 1.2.1 Passive Damping -- 1.2.1.1 Free and Constrained Damping Layers -- 1.2.1.2 Shunted Piezoelectric Treatments -- 1.2.1.3 Damping Layers with Shunted Piezoelectric Treatments -- 1.2.1.4 Magnetic Constrained Layer Damping (MCLD) -- 1.2.1.5 Damping with Shape Memory Fibers -- 1.2.2 Active Damping -- 1.2.3 Hybrid Damping -- 1.2.3.1 Active Constrained Layer Damping (ACLD) -- 1.2.3.2 Active Piezoelectric Damping Composites (APDC) -- 1.2.3.3 Electromagnetic Damping Composites (EMDC) -- 1.2.3.4 Active Shunted Piezoelectric Networks -- 1.3 Summary -- References -- Chapter 2 Viscoelastic Damping -- 2.1 Introduction -- 2.2 Classical Models of Viscoelastic Materials -- 2.2.1 Characteristics in the Time Domain -- 2.2.2 Basics for Time Domain Analysis -- 2.2.3 Detailed Time Response of Maxwell and Kelvin-Voigt Models -- 2.2.4 Detailed Time Response of the Poynting-Thomson Model -- 2.3 Creep Compliance and Relaxation Modulus -- 2.3.1 Direct Laplace Transformation Approach -- 2.3.2 Approach of Simultaneous Solution of a Linear Set of Equilibrium, Kinematic, and Constitutive Equations -- 2.4 Characteristics of the VEM in the Frequency Domain -- 2.5 Hysteresis and Energy Dissipation Characteristics of Viscoelastic Materials -- 2.5.1 Hysteresis Characteristics -- 2.5.2 Energy Dissipation -- 2.5.3 Loss Factor -- 2.5.3.1 Relationship Between Dissipation and Stored Elastic Energies -- 2.5.3.2 Relationship Between Different Strains -- 2.5.4 Storage Modulus -- 2.6 Fractional Derivative Models of Viscoelastic Materials -- 2.6.1 Basic Building Block of Fractional Derivative Models -- 2.6.2 Basic Fractional Derivative Models Part II Advanced Damping Treatments 3.5.2 Split Hopkinson Pressure Bar Method -- 3.5.2.1 Overview -- 3.5.2.2 Theory of 1D SHPB -- 3.5.2.3 Complex Modulus of a VEM from SHPB Measurements -- 3.5.3 Wave Propagation Method -- 3.5.4 Ultrasonic Wave Propagation Method -- 3.5.4.1 Overview -- 3.5.4.2 Theory -- 3.5.4.3 Measurement of the Phase Velocity and Attenuation Factor -- 3.5.4.4 Typical Attenuation Factors -- 3.6 Summary -- References -- 3.A Convolution Theorem -- Problems -- Chapter 4 Viscoelastic Materials -- 4.1 Introduction -- 4.2 Golla-Hughes-McTavish (GHM) Model -- 4.2.1 Motivation of the GHM Model -- 4.2.2 Computation of the Parameters of the GHM Mini-Oscillators -- 4.2.3 On the Structure of the GHM Model -- 4.2.3.1 Other Forms of GHM Structures -- 4.2.3.2 Relaxation Modulus of the GHM Model -- 4.2.4 Structural Finite Element Models of Rods Treated with VEM -- 4.2.4.1 Unconstrained Layer Damping -- 4.2.4.2 Constrained Layer Damping -- 4.3 Structural Finite Element Models of Beams Treated with VEM -- 4.3.1 Degrees of Freedom -- 4.3.2 Basic Kinematic Relationships -- 4.3.3 Stiffness and Mass Matrices of the Beam/VEM Element -- 4.3.4 Equations of Motion of the Beam/VEM Element -- 4.4 Generalized Maxwell Model (GMM) -- 4.4.1 Overview -- 4.4.2 Internal Variable Representation of the GMM -- 4.4.2.1 Single-DOF System -- 4.4.2.2 Multi-Degree of Freedom System -- 4.4.2.3 Condensation of the Internal Degrees of Freedom -- 4.4.2.4 Direct Solution of Coupled Structural and Internal Degrees of Freedom -- 4.5 Augmenting Thermodynamic Field (ATF) Model -- 4.5.1 Overview -- 4.5.2 Equivalent Damping Ratio of the ATF Model -- 4.5.3 Multi-degree of Freedom ATF Model -- 4.5.4 Integration with a Finite Element Model -- 4.6 Fractional Derivative (FD) Models -- 4.6.1 Overview -- 4.6.2 Internal Degrees of Freedom of Fractional Derivative Models -- 4.6.3 Grunwald Approximation of Fractional Derivative 4.6.4 Integration Fractional Derivative Approximation with Finite Element -- 4.6.4.1 Viscoelastic Rod -- 4.6.4.2 Beam with Passive Constrained Layer Damping (PCLD) Treatment -- 4.7 Finite Element Modeling of Plates Treated with Passive Constrained Layer Damping -- 4.7.1 Overview -- 4.7.2 The Stress and Strain Characteristics -- 4.7.2.1 The Plate and the Constraining Layers -- 4.7.2.2 The VEM Layer -- 4.7.3 The Potential and Kinetic Energies -- 4.7.4 The Shape Functions -- 4.7.5 The Stiffness Matrices -- 4.7.6 The Mass Matrices -- 4.7.7 The Element and Overall Equations of Motion -- 4.8 Finite Element Modeling of Shells Treated with Passive Constrained Layer Damping -- 4.8.1 Overview -- 4.8.2 Stress-Strain Relationships -- 4.8.2.1 Shell and Constraining Layer -- 4.8.2.2 Viscoelastic Layer -- 4.8.3 Kinetic and Potential Energies -- 4.8.4 The Shape Functions -- 4.8.5 The Stiffness Matrices -- 4.8.6 The Mass Matrices -- 4.8.7 The Element and Overall Equations of Motion -- 4.9 Summary -- References -- Problems -- Chapter 5 Finite Element Modeling of Viscoelastic Damping by Modal Strain Energy Method -- 5.1 Introduction -- 5.2 Modal Strain Energy (MSE) Method -- 5.3 Modified Modal Strain Energy (MSE) Methods -- 5.3.1 Weighted Stiffness Matrix Method (WSM) -- 5.3.2 Weighted Storage Modulus Method (WSTM) -- 5.3.3 Improved Reduction System Method (IRS) -- 5.3.4 Low Frequency Approximation Method (LFA) -- 5.4 Summary of Modal Strain Energy Methods -- 5.5 Modal Strain Energy as a Metric for Design of Damping Treatments -- 5.6 Perforated Damping Treatments -- 5.6.1 Overview -- 5.6.2 Finite Element Modeling -- 5.6.2.1 Element Energies -- 5.6.2.2 Topology Optimization of Unconstrained Layer Damping -- 5.6.2.3 Sensitivity Analysis -- 5.7 Summary -- References -- Problems -- Chapter 6 Energy Dissipation in Damping Treatments -- 6.1 Introduction 6.2 Passive Damping Treatments of Rods -- 6.2.1 Passive Constrained Layer Damping -- 6.2.1.1 Equation of Motion -- 6.2.1.2 Energy Dissipation -- 6.2.2 Passive Unconstrained Layer Damping -- 6.3 Active Constrained Layer Damping Treatments of Rods -- 6.3.1 Equation of Motion -- 6.3.2 Boundary Control Strategy -- 6.3.3 Energy Dissipation -- 6.4 Passive Constrained Layer Damping Treatments of Beams -- 6.4.1 Basic Equations of Damped Beams -- 6.4.2 Bending Energy of Beams -- 6.4.3 Energy Dissipated in Beams with Passive Constrained Layer Damping -- 6.5 Active Constrained Layer Damping Treatments of Beams -- 6.6 Passive and Active Constrained Layer Damping Treatments of Plates -- 6.6.1 Kinematic Relationships -- 6.6.2 Energies of the PCLD and ACLD Treatments -- 6.6.2.1 The Potential Energies -- 6.6.2.2 The Kinetic Energy -- 6.6.2.3 Work Done -- 6.6.3 The Models of the PCLD and ACLD Treatments -- 6.6.4 Boundary Control of Plates with ACLD Treatments -- 6.6.5 Energy Dissipation and Loss Factors of Plates with PCLD and ACLD Treatments -- 6.7 Passive and Active Constrained Layer Damping Treatments of Axi-Symmetric Shells -- 6.7.1 Background -- 6.7.2 The Concept of the Active Constrained Layer Damping -- 6.7.3 Variational Modeling of the Shell/ACLD System -- 6.7.3.1 Main Assumptions of the Model -- 6.7.3.2 Kinematic Relationships -- 6.7.3.3 Stress-Strain Relationships -- 6.7.3.4 Energies of Shell/ACLD System -- 6.7.3.5 The Model -- 6.7.4 Boundary Control Strategy -- 6.7.4.1 Overview -- 6.7.4.2 Control Strategy -- 6.7.4.3 Implementation of the Boundary Control Strategy -- 6.7.4.4 Transverse Compliance and Longitudinal Deflection -- 6.7.5 Energy Dissipated in the ACLD Treatment of an Axi-Symmetric Shell -- 6.8 Summary -- References -- 6.A Basic Identities -- 6.B Piezoelectricity -- 6.B.1 Piezoelectric Effects -- 6.B.2 Basic Constitutive Equations -- Problems 2.6.3 Other Common Fractional Derivative Models -- 2.7 Viscoelastic Versus Other Types of Damping Mechanisms -- 2.8 Summary -- References -- 2.A Initial and Final Value Theorems -- 2.B Fractional Calculus -- 2.B.1 Fractional Integration -- 2.B.2 Convolution Theorem -- 2.B.3 Fractional Derivatives -- 2.B.4 Laplace Transform of Fractional Derivatives -- 2.B.5 Grunwald-Letnikov Definition of Fractional Derivatives -- Problems -- Chapter 3 Characterization of the Properties of Viscoelastic Materials -- 3.1 Introduction -- 3.2 Typical Behavior of Viscoelastic Materials -- 3.3 Frequency Domain Measurement Techniques of the Dynamic Properties of Viscoelastic Material -- 3.3.1 Dynamic, Mechanical, and Thermal Analyzer -- 3.3.2 Oberst Test Beam Method -- 3.3.2.1 Set-Up and Beam Configurations -- 3.3.2.2 Parameter Extraction -- 3.4 Master Curves of Viscoelastic Materials -- 3.4.1 The Principle of Temperature-Frequency Superposition -- 3.4.2 The Use of the Master Curves -- 3.4.3 The Constant Temperature Lines -- 3.5 Time-Domain Measurement Techniques of the Dynamic Properties of Viscoelastic Materials -- 3.5.1 Creep and Relaxation Measurement Methods -- 3.5.1.1 Testing Equipment -- 3.5.1.2 Typical Creep and Relaxation Behavior -- 3.5.1.3 Time-Temperature Superposition -- 3.5.1.4 Boltzmann Superposition Principle -- 3.5.1.5 Relationship Between the Relaxation Modulus and Complex Modulus -- 3.5.1.6 Relationship Between the Creep Compliance and Complex Compliance -- 3.5.1.7 Relationship Between the Creep Compliance and Relaxation Modulus -- 3.5.1.8 Alternative Relationship Between the Creep Compliance and Complex Compliance -- 3.5.1.9 Alternative Relationship Between the Relaxation Modulus and Complex Modulus -- 3.5.1.10 Summary of the Basic Interconversion Relationship -- 3.5.1.11 Practical Issues in Implementation of Interconversion Relationships |
| Title | Active and Passive Vibration Damping |
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