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Piezoelectric materials : applications in SHM, energy harvesting and bio-mechanics /
Piezoelectric materials are attracting significant research efforts and resources worldwide. The major thrust areas include structural health monitoring, bio-mechanics, bio-medicine and energy harvesting. Engineering and technological applications of this smart material warrants multi-dimensional th...
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Hoboken, N.J. :
Wiley,
[2017]
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Title Page; Copyright; Preface; Acknowledgements; Contents; 1. Introduction; 1.1 What are 'Smart Materials'?; 1.2 'Smartness' of Piezoelectric Materials; 1.3 Structural Health Monitoring and Non-Destructive Evaluation; 1.4 Piezoelectric Energy Harvesting; 1.5 Extension of SHM Technologies to Bio-mechanics and Bio-medical Engineering; 1.6 Concluding Remarks; 2. Piezo-Transducers for Structural Health Monitoring and Non-Destructive Evaluation; 2.1 Introduction; 2.2 More About Piezoelectric Materials; 2.2.1 Mathematical Formulations; 2.2.2 Practical Aspects.
- 2.3 Piezo-Patch as Dynamic Strain Sensor for SHM2.4 Electro-Mechanical Impedance (EMI) Technique for SHM and NDE; 2.4.1 EMI Technique: Theory; 2.4.2 EMI technique: Practical aspects; 2.5 Development of 2D Impedance Models; 2.6 Structural Impedance Extraction and System Identification; 2.7 EMI Technique: Hardware Related Developments; 2.8 New Variants of EMI Technique; 2.9 Summary and Concluding Remarks; 3. Piezo Bond-Structure Elasto-Dynamic Interaction: Refined Model; 3.1 Introduction; 3.2 Review of Shear Lag Effect and Early Models; 3.3 Refined Model: 1D Case.
- 3.4 Extension of Refined Shear Lag Formulations to 2D3.5 Effect of Inclusion of Adhesive Mass; 3.6 Summary and Concluding Remarks; 4. Piezo-Structure Elasto-Dynamic Interaction: Continuum Model; 4.1 Introduction; 4.2 Admittance Formulations Based on Continuum Approach; 4.3 Experimental Verification; 4.4 Parametric Study Based on Continuum Approach; 4.5 Effect of Adhesive Mass; 4.6 Summary and Concluding Remarks; 5. Fatigue Damage Monitoring in Steel Joints Using Piezo-Transducers; 5.1 Introduction; 5.2 Experimental Details; 5.3 Statistical Analysis of Conductance Signatures.
- 5.4 Fatigue Life Assessment Using Equivalent Stiffness Parameter (ESP) Identified by Piezo-Transducers5.5 Summary and Concluding Remarks; 6. Chloride Induced Rebar Corrosion Monitoring Using Piezo-Transducers; 6.1 Introduction; 6.2 Rebar Corrosion in RC Structures; 6.3 Experimental Study: Specimen Preparation; 6.4 Accelerated Chloride Induced Corrosion Exposure; 6.5 Analysis Based on Equivalent Structural Parameters; 6.6 Calibration of Equivalent Parameters; 6.6.1 Equivalent Stiffness Parameter (ESP); 6.6.2 Equivalent Mass Parameter (EMP) for Corrosion Rates.
- 6.7 Summary and Concluding Remarks7. Carbonation Induced Corrosion Monitoring Using Piezo-Transducers; 7.1 Introduction; 7.2. Accelerated Carbonation Tests: Experimental Procedure; 7.3 Equivalent Stiffness Parameters (ESP); 7.4 Equivalent Mass Parameter (EMP); 7.5 Correlation with Microscopic Image Analysis; 7.6 Summary and Concluding Remarks; 8. Piezoelectric Energy Harvesting: Analytical Models; 8.1 Introduction; 8.2 Evolution and Recent Advances in Piezoelectric Energy Harvesting; 8.3 Piezoelectric Energy Harvesting Devices.