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Engineering Analysis of Smart Material Systems

ISBN: 978-0-471-68477-0
Hardcover
576 pages
September 2007
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Preface xiii

1 Introduction to Smart Material Systems 1

1.1 Types of Smart Materials, 2

1.2 Historical Overview of Piezoelectric Materials, Shape Memory Alloys, and Electroactive Polymers, 5

1.3 Recent Applications of Smart Materials and Smart Material Systems, 6

1.4 Additional Types of Smart Materials, 11

1.5 Smart Material Properties, 12

1.6 Organization of the Book, 16

1.7 Suggested Course Outlines, 19

1.8 Units, Examples, and Nomenclature, 20

Problems, 22

Notes, 22

2 Modeling Mechanical and Electrical Systems 24

2.1 Fundamental Relationships in Mechanics and Electrostatics, 24

2.1.1 Mechanics of Materials, 25

2.1.2 Linear Mechanical Constitutive Relationships, 32

2.1.3 Electrostatics, 35

2.1.4 Electronic Constitutive Properties of Conducting and Insulating Materials, 43

2.2 Work and Energy Methods, 48

2.2.1 Mechanical Work, 48

2.2.2 Electrical Work, 54

2.3 Basic Mechanical and Electrical Elements, 56

2.3.1 Axially Loaded Bars, 56

2.3.2 Bending Beams, 58

2.3.3 Capacitors, 64

2.3.4 Summary, 66

2.4 Energy-Based Modeling Methods, 67

2.4.1 Variational Motion, 68

2.5 Variational Principle of Systems in Static Equilibrium, 70

2.5.1 Generalized State Variables, 72

2.6 Variational Principle of Dynamic Systems, 78

2.7 Chapter Summary, 84

Problems, 85

Notes, 89

3 Mathematical Representations of Smart Material Systems 91

3.1 Algebraic Equations for Systems in Static Equilibrium, 91

3.2 Second-Order Models of Dynamic Systems, 92

3.3 First-Order Models of Dynamic Systems, 97

3.3.1 Transformation of Second-Order Models to First-Order Form, 98

3.3.2 Output Equations for State Variable Models, 99

3.4 Input–Output Models and Frequency Response, 101

3.4.1 Frequency Response, 103

3.5 Impedance and Admittance Models, 109

3.5.1 System Impedance Models and Terminal Constraints, 113

3.6 Chapter Summary, 118

Problems, 118

Notes, 121

4 Piezoelectric Materials 122

4.1 Electromechanical Coupling in Piezoelectric Devices: One-Dimensional Model, 122

4.1.1 Direct Piezoelectric Effect, 122

4.1.2 Converse Effect, 124

4.2 Physical Basis for Electromechanical Coupling in Piezoelectric Materials, 126

4.2.1 Manufacturing of Piezoelectric Materials, 127

4.2.2 Effect of Mechanical and Electrical Boundary Conditions, 131

4.2.3 Interpretation of the Piezoelectric Coupling Coefficient, 133

4.3 Constitutive Equations for Linear Piezoelectric Material, 135

4.3.1 Compact Notation for Piezoelectric Constitutive Equations, 137

4.4 Common Operating Modes of a Piezoelectric Transducer, 141

4.4.1 33 Operating Mode, 142

4.4.2 Transducer Equations for a 33 Piezoelectric Device, 147

4.4.3 Piezoelectric Stack Actuator, 150

4.4.4 Piezoelectric Stack Actuating a Linear Elastic Load, 152

4.5 Dynamic Force and Motion Sensing, 157

4.6 31 Operating Mode of a Piezoelectric Device, 160

4.6.1 Extensional 31 Piezoelectric Devices, 162

4.6.2 Bending 31 Piezoelectric Devices, 166

4.6.3 Transducer Equations for a Piezoelectric Bimorph, 172

4.6.4 Piezoelectric Bimorphs Including Substrate Effects, 175

4.7 Transducer Comparison, 178

4.7.1 Energy Comparisons, 182

4.8 Electrostrictive Materials, 184

4.8.1 One-Dimensional Analysis, 186

4.8.2 Polarization-Based Models of Electrostriction, 188

4.8.3 Constitutive Modeling, 192

4.8.4 Harmonic Response of Electrostrictive Materials, 196

4.9 Chapter Summary, 199

Problems, 200

Notes, 203

5 Piezoelectric Material Systems 205

5.1 Derivation of the Piezoelectric Constitutive Relationships, 205

5.1.1 Alternative Energy Forms and Transformation of the Energy Functions, 208

5.1.2 Development of the Energy Functions, 210

5.1.3 Transformation of the Linear Constitutive Relationships, 212

5.2 Approximation Methods for Static Analysis of Piezolectric Material Systems, 217

5.2.1 General Solution for Free Deflection and Blocked Force, 221

5.3 Piezoelectric Beams, 223

5.3.1 Cantilevered Bimorphs, 223

5.3.2 Pinned–Pinned Bimorphs, 227

5.4 Piezoelectric Material Systems: Dynamic Analysis, 232

5.4.1 General Solution, 233

5.5 Spatial Filtering and Modal Filters in Piezoelectric Material Systems, 235

5.5.1 Modal Filters, 239

5.6 Dynamic Response of Piezoelectric Beams, 241

5.6.1 Cantilevered Piezoelectric Beam, 249

5.6.2 Generalized Coupling Coefficients, 263

5.6.3 Structural Damping, 264

5.7 Piezoelectric Plates, 268

5.7.1 Static Analysis of Piezoelectric Plates, 269

5.7.2 Dynamic Analysis of Piezoelectric Plates, 281

5.8 Chapter Summary, 289

Problems, 290

Notes, 297

6 Shape Memory Alloys 298

6.1 Properties of Thermally Activated Shape Memory Materials, 298

6.2 Physical Basis for Shape Memory Properties, 300

6.3 Constitutive Modeling, 302

6.3.1 One-Dimensional Constitutive Model, 302

6.3.2 Modeling the Shape Memory Effect, 307

6.3.3 Modeling the Pseudoelastic Effect, 311

6.4 Multivariant Constitutive Model, 320

6.5 Actuation Models of Shape Memory Alloys, 326

6.5.1 Free Strain Recovery, 327

6.5.2 Restrained Recovery, 327

6.5.3 Controlled Recovery, 329

6.6 Electrical Activation of Shape Memory Alloys, 330

6.7 Dynamic Modeling of Shape Memory Alloys for

Electrical Actuation, 335

6.8 Chapter Summary, 341

Problems, 342

Notes, 345

7 Electroactive Polymer Materials 346

7.1 Fundamental Properties of Polymers, 347

7.1.1 Classification of Electroactive Polymers, 349

7.2 Dielectric Elastomers, 355

7.3 Conducting Polymer Actuators, 362

7.3.1 Properties of Conducting Polymer Actuators, 363

7.3.2 Transducer Models of Conducting Polymers, 367

7.4 Ionomeric Polymer Transducers, 369

7.4.1 Input–Output Transducer Models, 369

7.4.2 Actuator and Sensor Equations, 375

7.4.3 Material Properties of Ionomeric Polymer Transducers, 377

7.5 Chapter Summary, 382

Problems, 383

Notes, 384

8 Motion Control Applications 385

8.1 Mechanically Leveraged Piezoelectric Actuators, 386

8.2 Position Control of Piezoelectric Materials, 391

8.2.1 Proportional–Derivative Control, 392

8.2.2 Proportional–Integral–Derivative Control, 396

8.3 Frequency-Leveraged Piezoelectric Actuators, 402

8.4 Electroactive Polymers, 409

8.4.1 Motion Control Using Ionomers, 409

8.5 Chapter Summary, 412

Problems, 413

Notes, 414

9 Passive and Semiactive Damping 416

9.1 Passive Damping, 416

9.2 Piezoelectric Shunts, 419

9.2.1 Inductive–Resistive Shunts, 425

9.2.2 Comparison of Shunt Techniques, 431

9.3 Multimode Shunt Techniques, 432

9.4 Semiactive Damping Methods, 440

9.4.1 System Norms for Performance Definition, 441

9.4.2 Adaptive Shunt Networks, 443

9.4.3 Practical Considerations for Adaptive Shunt Networks, 447

9.5 Switched-State Absorbers and Dampers, 448

9.6 Passive Damping Using Shape Memory Alloy Wires, 453

9.6.1 Passive Damping via the Pseudoelastic Effect, 454

9.6.2 Parametric Study of Shape Memory Alloy Passive Damping, 460

9.7 Chapter Summary, 464

Problems, 465

Notes, 466

10 Active Vibration Control 467

10.1 Second-Order Models for Vibration Control, 467

10.1.1 Output Feedback, 468

10.2 Active Vibration Control Example, 471

10.3 Dynamic Output Feedback, 475

10.3.1 Piezoelectric Material Systems with Dynamic Output Feedback, 480

10.3.2 Self-Sensing Actuation, 483

10.4 Distributed Sensing, 486

10.5 State-Space Control Methodologies, 488

10.5.1 Transformation to First-Order Form, 488

10.5.2 Full-State Feedback, 491

10.5.3 Optimal Full-State Feedback: Linear Quadratic Regulator Problem, 496

10.5.4 State Estimation, 505

10.5.5 Estimator Design, 507

10.6 Chapter Summary, 508

Problems, 509

Notes, 510

11 Power Analysis for Smart Material Systems 511

11.1 Electrical Power for Resistive and Capacitive Elements, 511

11.2 Power Amplifier Analysis, 520

11.2.1 Linear Power Amplifiers, 520

11.2.2 Design of Linear Power Amplifiers, 524

11.2.3 Switching and Regenerative Power Amplifiers, 530

11.3 Energy Harvesting, 533

11.4 Chapter Summary, 542

Problems, 543

Notes, 544

References 545

Index 553

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