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Mechanical Design of Piezoelectric Energy Harvesters Generating Electricity from Human Walking

Xu Qingsong Tam, Lap Mou
Heftet / 2021 / Engelsk

Produktdetaljer

ISBN
9780128233641
Publisert
2021-10-27
Utgiver
Vendor
Academic Press Inc
Vekt
410 gr
Høyde
229 mm
Bredde
152 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Heftet
Antall sider
288

Forfatter
Xu Qingsong
Tam, Lap Mou

Biographical note

Dr. Qingsong Xu is a Professor in the Department of Electromechanical Engineering at the Faculty of Science and Technology, University of Macau, and has served as the Director of the Smart and Micro/Nano Systems Laboratory since 2010. His research focuses on intelligent micro/nanosystems, precision robotics, and biomedical applications. He currently serves as an Associate Editor for IEEE Transactions on Robotics (T-RO). Previously, he was a Technical Editor for IEEE/ASME Transactions on Mechatronics (T-MECH) and an Associate Editor for both IEEE Transactions on Automation Science and Engineering (T-ASE) and IEEE Robotics and Automation Letters (RA-L). Prof. Xu has received more than ten best paper awards from international conferences and multiple Macao Science and Technology Awards from Macao SAR, China. Since 2019, he has been recognized among the top 2% of the world's scientists by Stanford University. He is also a Fellow of ASME. Prof. Lap Mou TAM has been working in the area of heat transfer, energy systems, and chaos for 30 years. He has published over 100 peer-reviewed papers in journals and conferences in related domains.

Mechanical Design of Piezoelectric Energy Harvesters Generating Electricity from Human Walking

Xu Qingsong Tam, Lap Mou
Heftet / 2021 / Engelsk
Xu Qingsong Tam, Lap Mou
Heftet / 2021 / Engelsk
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Mechanical Design of Piezoelectric Energy Harvesters: Generating Electricity from Human Walking provides the state-of-the-art, recent mechanical designs of piezoelectric energy harvesters based on piezoelectric stacks. The book discusses innovative mechanism designs for energy harvesting from multidimensional force excitation, such as human walking, which offers higher energy density. Coverage includes analytical modeling, optimal design, simulation study, prototype fabrication, and experimental investigation. Detailed examples of their analyses and implementations are provided. The book's authors provide a unique perspective on this field, primarily focusing on novel designs for PZT Energy harvesting in biomedical engineering as well as in integrated multi-stage force amplification frame. This book presents force-amplification compliant mechanism design and force direction-transmission mechanism design. It explores new mechanism design approaches using piezoelectric materials and permanent magnets. Readers can expect to learn how to design new mechanisms to realize multidimensional energy harvesting systems.
Les mer
1. Introduction 2. Energy Harvesting Materials and Circuits 3. Survey on Mechanical Designs of Piezoelectric Energy Harvester 4. Review of Energy Harvesting from Human Walking 5. Design of a New Piezoelectric Energy Harvester Based on Compound Two-Stage Force Amplification Frame 6. Design of a New Piezoelectric Energy Harvesting Handrail with Vibration and Force Excitations 7. Design of a Novel Piezoelectric Energy Harvester Based on Integrated Multi-Stage Force Amplification Frame 8. Design and Testing of a Novel Bidirectional Energy Harvester with Single Piezoelectric Stack 9. Design and Testing of a Novel 2-D Energy Harvester with Single Piezoelectric Stack 10. Design of a Novel 2-D Piezoelectric Energy Harvester with Permanent Magnets and Multi-Stage Force Amplifier 11. Design and Testing of a New Dual-Axial Underfloor Piezoelectric Energy Harvester 12. Design, Fabrication and Testing of a Novel 3-D Energy Harvester 13. Conclusions
Les mer
Provides state-of-the-art, recent mechanical designs of piezoelectric energy harvesters based on piezoelectric stacks
Provides new mechanical designs of piezoelectric energy harvesters for multidimensional force excitation Contains both theoretical and experimental results Fully supported with real-life examples on design, modeling and implementation of piezoelectric energy harvesting devices
Les mer

Relaterte produkter

Mechanical Design of Piezoelectric Energy Harvesters: Generating Electricity from Human Walking provides the state-of-the-art, recent mechanical designs of piezoelectric energy harvesters based on piezoelectric stacks. The book discusses innovative mechanism designs for energy harvesting from multidimensional force excitation, such as human walking, which offers higher energy density. Coverage includes analytical modeling, optimal design, simulation study, prototype fabrication, and experimental investigation. Detailed examples of their analyses and implementations are provided. The book's authors provide a unique perspective on this field, primarily focusing on novel designs for PZT Energy harvesting in biomedical engineering as well as in integrated multi-stage force amplification frame. This book presents force-amplification compliant mechanism design and force direction-transmission mechanism design. It explores new mechanism design approaches using piezoelectric materials and permanent magnets. Readers can expect to learn how to design new mechanisms to realize multidimensional energy harvesting systems.
Les mer
1. Introduction 2. Energy Harvesting Materials and Circuits 3. Survey on Mechanical Designs of Piezoelectric Energy Harvester 4. Review of Energy Harvesting from Human Walking 5. Design of a New Piezoelectric Energy Harvester Based on Compound Two-Stage Force Amplification Frame 6. Design of a New Piezoelectric Energy Harvesting Handrail with Vibration and Force Excitations 7. Design of a Novel Piezoelectric Energy Harvester Based on Integrated Multi-Stage Force Amplification Frame 8. Design and Testing of a Novel Bidirectional Energy Harvester with Single Piezoelectric Stack 9. Design and Testing of a Novel 2-D Energy Harvester with Single Piezoelectric Stack 10. Design of a Novel 2-D Piezoelectric Energy Harvester with Permanent Magnets and Multi-Stage Force Amplifier 11. Design and Testing of a New Dual-Axial Underfloor Piezoelectric Energy Harvester 12. Design, Fabrication and Testing of a Novel 3-D Energy Harvester 13. Conclusions
Les mer
Provides state-of-the-art, recent mechanical designs of piezoelectric energy harvesters based on piezoelectric stacks
Provides new mechanical designs of piezoelectric energy harvesters for multidimensional force excitation Contains both theoretical and experimental results Fully supported with real-life examples on design, modeling and implementation of piezoelectric energy harvesting devices
Les mer

Produktdetaljer

ISBN
9780128233641
Publisert
2021-10-27
Utgiver
Vendor
Academic Press Inc
Vekt
410 gr
Høyde
229 mm
Bredde
152 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Heftet
Antall sider
288

Forfatter
Xu Qingsong
Tam, Lap Mou

Biographical note

Dr. Qingsong Xu is a Professor in the Department of Electromechanical Engineering at the Faculty of Science and Technology, University of Macau, and has served as the Director of the Smart and Micro/Nano Systems Laboratory since 2010. His research focuses on intelligent micro/nanosystems, precision robotics, and biomedical applications. He currently serves as an Associate Editor for IEEE Transactions on Robotics (T-RO). Previously, he was a Technical Editor for IEEE/ASME Transactions on Mechatronics (T-MECH) and an Associate Editor for both IEEE Transactions on Automation Science and Engineering (T-ASE) and IEEE Robotics and Automation Letters (RA-L). Prof. Xu has received more than ten best paper awards from international conferences and multiple Macao Science and Technology Awards from Macao SAR, China. Since 2019, he has been recognized among the top 2% of the world's scientists by Stanford University. He is also a Fellow of ASME. Prof. Lap Mou TAM has been working in the area of heat transfer, energy systems, and chaos for 30 years. He has published over 100 peer-reviewed papers in journals and conferences in related domains.

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