Preface xi Acknowledgements xiii 1 Introduction 1 1.1 Active and Sensory Materials for Smart Systems 1 1.2 Energy Harvesting Materials 3 1.3 Multifunctional Materials, Devices, Systems and Structures 3 1.4 Piezoelectric, Pyroelectric and Ferroelectric Materials 4 References 5 2 Piezoelectric Fundamentals 7 2.1 Piezoelectric Materials 7 2.2 Ferroelectric Materials 10 2.2.

1 Non-centrosymmetric Unit Cells 10 2.2.2 Lead Zirconate Titanate (Pb(ZrXTi1−x)O3 , Pzt) Ferroelectrics 13 2.2.3 Ferroelectric Domains 14 2.2.4 Poling of Ferroelectric Materials 16 2.3 Pyroelectric Materials 18 2.

4 Piezoelectric Forms: Bulk, Thin Films and Fibre Composites 19 2.4.1 Piezoelectric Composites and Connectivity 19 2.4.2 Active Fibre Composites and Macro-Fibre Composites 20 2.5 Concluding Remarks 22 References 23 3 Properties of Piezoelectric Materials 27 3.1 Introduction 27 3.2 Constitutive Equations 28 3.

2.1 Alternative Single-Axis Formulations 28 3.2.2 Multi-Axis Linear Model 30 3.2.2.1 Example Piezoelectric Element 32 3.2.

3 Coupling Coefficients 34 3.3 Polarisation-Electric Field Response of a Ferroelectric 36 3.4 Strain-Field Response of a Ferroelectric 39 3.5 Material Properties and Selection of Materials 41 3.5.1 Barium Titanate (BaTiO3) 41 3.5.2 Lead Zirconate Titanate (PZT, Pb(Zr,Ti)O3) 42 3.

5.3 Ferroelectric Polymers 48 3.6 Mechanical Depolarisation of Ferroelectric Materials 48 3.7 Creep of Ferroelectric Materials 52 3.8 Strain Limits of Piezoelectric Actuators (Expansion) 54 3.9 Strain Limits of Piezoelectric Actuators (Contraction) 55 3.10 Resonance Behaviour of Piezoelectric Materials and Ceramic Structures 55 3.11 Ageing of Ferroelectrics 57 3.

12 Temperature Limits and Self-Heating 58 3.13 Cyclic Operation - Frequency Effects 58 3.13.1 Self-Heating Due to Ferroelectric Hysteresis 59 3.13.2 Current Requirements During Frequency Cycling 60 3.14 Thermal Expansion Coefficient 61 3.15 Summary 62 References 62 4 Piezoelectric Actuators 65 4.

1 Introduction 65 4.2 Free Displacement and Blocking Force 65 4.3 Single-Layer Actuator 67 4.4 Stack Actuators 71 4.4.1 Actuator Preloading 72 4.4.2 Piezoelectric Stack Actuator Selection Example 73 4.

4.3 Optimum Stack Dimensions 76 4.4.4 Piezoelectric Actuator Stack Sizing Guidelines 77 4.5 Rectangular Bending Actuators (Bimorphs) 79 4.5.1 Bimorph Characteristics 79 4.5.

2 Other Rectangular Benders 83 4.6 Ring Benders 84 4.6.1 Ring Bender Deformation Analysis 84 4.6.2 Ring Bender Free Displacement and Blocking Force 92 4.6.3 Other Circular Benders 95 4.

7 Mechanical Amplification 95 4.8 Complex Actuator Design 97 4.8.1 Motion Accumulation 97 4.8.2 Ultrasonic Motors 98 4.9 Concluding Remarks 99 References 100 5 Sensors 101 5.1 Introduction 101 5.

2 Piezoelectric Accelerometers 101 5.2.1 Accelerometer Modes of Operation (Compressive, Shear and Flexural d33 and d15) 105 5.2.2 Material Selection for Accelerometers 106 5.3 Force and Pressure Sensors 110 5.3.1 High-Frequency Capability 111 5.

3.2 Sensor Sensitivity 111 5.4 Temperature and Thermal Effects 113 5.5 Hydrophones 115 5.5.1 Background to Hydrostatic Coefficients 115 5.5.2 Derivation of Performance Indicators for Hydrophone Materials 116 5.

5.3 Hydrophone Construction 120 5.6 Piezocomposite Sensors 123 5.6.1 Production of Piezoelectric Composites 127 5.7 Conclusions 130 References 130 6 Energy Harvesting 133 6.1 Introduction 133 6.2 Concept of Piezoelectric-Based Energy Harvesting 134 6.

3 Piezoelectric Properties and Performance Figures of Merit (FoMs) 141 6.3.1 Derivation of Harvesting Figures of Merit (FoMs) 142 6.3.2 Mechanical Energy Input 142 6.3.3 Converting the Mechanical (Input) into Electrical Energy (Stored) 145 6.3.

4 Producing an Output from the Stored Electrical Energy 147 6.4 Case Study: Piezoelectric Hydraulic Ripple Energy Harvesting 151 6.5 Pyroelectric Materials and Thermal Energy Harvesting 157 6.5.1 Performance Figures of Merit for Pyroelectric Harvesting and Sensing 159 6.6 Summary 163 References 163 7 Drive Electronics and Control 167 7.1 Introduction 167 7.2 Op-Amp Circuits 167 7.

3 Voltage Amplifiers for Driving Actuators 169 7.4 Charge Amplifiers for Driving Actuators 171 7.5 Regenerative Amplifiers 174 7.6 Position Sensors for Feedback Control 176 7.6.1 Linear Variable Differential Transformer (LVDT) 176 7.6.2 Eddy Current Sensor 177 7.

6.3 Capacitive Sensor 178 7.6.4 Laser Triangulation Sensor 178 7.6.5 Strain Gauge Sensor 178 7.7 Closed-Loop Controllers: Case Study 180 7.8 Signal Conditioning for Piezoelectric Sensors 182 7.

8.1 Op-Amp Filtering Circuits 182 7.8.2 Signal Conditioning in Detail 186 7.9 Concluding Remarks 188 References 188 8 Case Studies 191 8.1 Introduction 191 8.2 Piezoelectric Valve Actuation 191 8.2.

1 Internal Combustion Engine Fuel Injectors 191 8.2.2 Hydraulic Servo Valves 191 8.3 Piezoelectric Pumps 197 8.3.1 Introduction 197 8.3.2 Piezo Pump Example 198 8.

4 Vibration Control of Flexible Structures 201 8.4.1 Smart Structure 201 8.4.2 Dynamic Modelling 203 8.4.3 Derivative Feedback Control 203 8.5 A Case Study of Actuator Self-Heating 205 8.

5.1 Model for Temperature Increase Due to Hysteresis 205 8.5.2 Testing Actuator Self-Heating 207 8.5.3 Comparing Actuator Test Data with Expected Behaviour from Model 209 8.6 Piezoelectric Actuation of Bistable Morphing Structures 211 8.6.

1 Composite Structure Manufacture 213 8.6.2 Actuator Materials and Attachment 214 8.6.3 Change in Laminate Shape in Response to Piezoelectric Actuation 214 8.7 Force Sensors, Shear Sensors and Hydrophones 217 8.7.1 Freeze Casting to Produce Porous Ceramics 217 8.

7.2 Fabrication of Strain Sensor (d31 -Mode) 222 8.7.3 d 33 -Mode and d 15 -Mode Piezocomposite Sensors 223 8.8 Concluding Remarks 225 References 225 Index 229.