Tunable energy harvesting from ambient vibrations

ASME 2010 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, SMASIS 2010

Volumn 1, Issue , 2010, Pages 529-534

  Rhimi, Mohamed ^a   Lajnef, Nizar ^a  

^a Michigan State University   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

FREQUENCY DOMAIN ANALYSIS; INTELLIGENT MATERIALS; INTELLIGENT SYSTEMS; LEAD ZIRCONATE TITANATE; PIEZOELECTRIC DEVICES; PIEZOELECTRICITY; STRESS ANALYSIS;

COMPRESSIVE AXIAL LOADINGS; EXPERIMENTAL VERIFICATION; HAMILTONIAN PRINCIPLE; OPERATING FREQUENCY; ORDERS OF MAGNITUDE; PIEZOELECTRIC BIMORPHS; PIEZOELECTRIC ENERGY; TIME AND FREQUENCY DOMAINS;

ENERGY HARVESTING;

EID: 84859551865     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1115/smasis2010-3740     Document Type: Conference Paper

References (16)

1. Elfrink R., Kamel T.M., Goedbloed M., Matova S., Hohlfeld D., van Schaijk R., et al, 2008, "Vibration energy harvesting with aluminum nitridebased piezoelectric devices," Proceedings of the power MEMS, Sendai, November 10-11, p. 249-52.
2. Finkel P., Lofland S.E., Garrity E., 2009, "Magnetoelastic/ piezoelectric laminated structures for tunable remote contactless magnetic sensing and energy harvesting," Appl. Phys. Lett., 94, 07250.
3. Goldschmidtboeing F. and Woias P., 2008, "Characterization of different beam shapes for piezoelectric energy harvesting," J. Micromech. Microeng., 18, 104013.
4. Kim H., Priya S., Stephanou H. and Uchino K., 2007, "Consideration of impedance matching techniques for efficient piezoelectric energy harvesting," IEEE Trans. Ultrason. Ferroelectr. Freq. Control, 54, p. 1851-1859.
5. Shu, Y. C., Lien, I. C., and Wu, W. J., 2007, "An improved analysis of the SSHI interface in piezoelectric energy harvesting," J. Smart Materials and Structures, 16, p. 2253-2264. (Pubitemid 350175553)
6. Liao Y. and Sodano H.A., 2009, "Optimal Parameters and Power Characteristics of Piezoelectric Energy Harvesters with an RC Circuit," Smart Materials and Structures, 18, 045011.
7. Challa V. R., Prasad M. G. and Fisher F. T., 2009, "A coupled piezoelectric-electromagnetic energy harvesting technique for achieving increased power output through damping matching," J. Smart Materials and Structures, 18, 095029.
8. Leland E. and Wright P.K., 2006, "Resonance Tuning of Piezoelectric Vibration energy Scavenging Generators using Compressive Axial Preload," J. Smart Materials and Structures, 15, p. 1-8.
9. Hu Y., Xue H. and Hu H., 2007, "A piezoelectric power harvester with adjustable frequency through axial preloads," J. Smart Materials and Structures, 16, 1961.
10. Eichhorn C., Goldschmidtboeing F. and Woias P., 2009, "Bidirectional frequency tuning of a piezoelectric energy converter based on a cantilever beam," J. Micromech. Microeng., 19, 094006.
11. Morris D. J., Youngsman J. M., Anderson M. J. and Bahr D. F., 2008, "A resonant frequency tunable, extensional mode piezoelectric vibration harvesting mechanism," J. Smart Materials and Structures, 17, 065021.
12. Challa V. R., Prasad M. G., Shi Y. and Fisher F. T., 2008, "A vibration energy harvesting device with bidirectional resonance frequency tenability," J. Smart Materials and Structures, 17, 015035.
13. Peters C., Maurath D., Schock W. and Manoli Y., 2008, "Novel electrically tunable mechanical resonator for energy harvesting," Proceedings of the power MEMS, Sendai, November 9-12, pp 253-256.
14. Sodano H.A., Park G. and Inman D.J., 2004, "Estimation of Electric Charge Output for Piezoelectric Energy Harvesting," Journal of Strain, 40, p. 49-58.
15. Bazant Z. P. and Cedolin L., 1991, "Stability of Structure: Elastic, Inelastic, Fracture and Damage Theories," Oxford University Press, New York.
16. Elvin N., Lajnef N. and Elvin A., 2006, "Feasibility of Structural Monitoring With Vibration Powered Sensors," J. Smart Materials and Structures, 15, p. 977-986. (Pubitemid 44102055)