Synchronized charge extraction in galloping piezoelectric energy harvesting

Journal of Intelligent Material Systems and Structures

Volumn 27, Issue 4, 2016, Pages 453-468

  Zhao, Liya ^a   Tang, Lihua ^b   Yang, Yaowen ^a  

^a NANYANG TECHNOLOGICAL UNIVERSITY   (Singapore)

^b UNIVERSITY OF AUCKLAND   (New Zealand)

Author keywords

galloping; Piezoelectric energy harvesting; synchronized charge extraction; wind energy

Indexed keywords

AEROELASTICITY; EXTRACTION; IMPEDANCE MATCHING (ELECTRIC); PIEZOELECTRIC DEVICES; PIEZOELECTRICITY; RECONFIGURABLE HARDWARE; SYNCHRONIZATION; WIND POWER;

AEROELASTIC INSTABILITIES; CHARGE EXTRACTION; DISPLACEMENT AMPLITUDES; EQUIVALENT CIRCUIT MODEL; GALLOPING; PIEZOELECTRIC ENERGY HARVESTERS; PIEZOELECTRIC ENERGY HARVESTING; WIRELESS SENSING NETWORKS;

ENERGY HARVESTING;

EID: 84957805656     PISSN: 1045389X     EISSN: 15308138     Source Type: Journal    
DOI: 10.1177/1045389X15571384     Document Type: Article

References (46)

1. Abdelkefi A, Hajj MR, Nayfeh AH, (2012) Power harvesting from transverse galloping of square cylinder. Nonlinear Dynamics 70: 1355-1363.
2. Abdelkefi A, Yan Z, Hajj MR, (2013) Modeling and nonlinear analysis of piezoelectric energy harvesting from transverse galloping. Smart Materials and Structures 22: 025016.
3. Akaydin HD, Elvin N, Andreopoulos Y, (2012) The performance of a self-excited fluidic energy harvester. Smart Materials and Structures 21: 025007.
4. Anton SR, Sodano HA, (2007) A review of power harvesting using piezoelectric materials (2003-2006). Smart Materials and Structures 16: R1.
5. Barrero-Gil A, Alonso G, Sanz-Andres A, (2010) Energy harvesting from transverse galloping. Journal of Sound and Vibration 329: 2873-2883.
6. Bibo A, Daqaq M, (2013) Investigation of concurrent energy harvesting from ambient vibrations and wind using a single piezoelectric generator. Applied Physics Letters 102: 243904.
7. Bryant M, Garcia E, (2011) Modeling and testing of a novel aeroelastic flutter energy harvester. Journal of Vibration and Acoustics 133: 011010.
8. Castagnetti D, (2012) Experimental modal analysis of fractal-inspired multi-frequency structures for piezoelectric energy converters. Smart Materials and Structures 21: 094009.
9. Cook-Chennault K, Thambi N, Sastry A, (2008) Powering MEMS portable devices-a review of non-regenerative and regenerative power supply systems with special emphasis on piezoelectric energy harvesting systems. Smart Materials and Structures 17: 043001.
10. De Marqui C, Erturk A, (2013) Electroaeroelastic analysis of airfoilbased wind energy harvesting using piezoelectric transduction and electromagnetic induction. Journal of Intelligent Material Systems and Structures. 24: 846-854.
11. Elvin NG, Elvin AA, (2009) A general equivalent circuit model for piezoelectric generators. Journal of Intelligent Material Systems and Structures 20: 3-9.
12. Erturk A, Vieira W, De Marqui C Jr, et al. (2010) On the energy harvesting potential of piezoaeroelastic systems. Applied Physics Letters 96: 184103.
13. Guyomar D, Badel A, Lefeuvre E, et al. (2005) Toward energy harvesting using active materials and conversion improvement by nonlinear processing. IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control 52: 584-595.
14. Jung H-J, Lee S-W, (2011) The experimental validation of a new energy harvesting system based on the wake galloping phenomenon. Smart Materials and Structures 20: 055022.
15. Lallart M, Guyomar D, (2008) An optimized self-powered switching circuit for non-linear energy harvesting with low voltage output. Smart Materials and Structures 17: 035030.
16. Lefeuvre E, Badel A, Richard C, et al. (2005) Piezoelectric energy harvesting device optimization by synchronous electric charge extraction. Journal of Intelligent Material Systems and Structures 16: 865-876.
17. Lefeuvre E, Badel A, Richard C, et al. (2006) A comparison between several vibration-powered piezoelectric generators for standalone systems. Sensors and Actuators A: Physical 126: 405-416.
18. Lefeuvre E, Badel A, Richard C, et al. (2007) Energy harvesting using piezoelectric materials: case of random vibrations. Journal of Electroceramics 19: 349-355.
19. Liang J, Liao W-H, (2009) An improved self-powered switching interface for piezoelectric energy harvesting. In: IEEE international conference on information and automation, Zhuhai, China, 22-24 June, vol. 1, pp. 945-950. New York: IEEE.
20. Liang J, Liao W-H, (2012) Improved design and analysis of self-powered synchronized switch interface circuit for piezoelectric energy harvesting systems. IEEE Transactions on Industrial Electronics 59: 1950-1960.
21. Lien I, Shu Y, Wu W, et al. (2010) Revisit of series-SSHI with comparisons to other interfacing circuits in piezoelectric energy harvesting. Smart Materials and Structures 19: 125009.
22. Ottman GK, Hofmann HF, Lesieutre GA, (2003) Optimized piezoelectric energy harvesting circuit using step-down converter in discontinuous conduction mode. IEEE Transactions on Power Electronics 18: 696-703.
23. Ottman GK, Hofmann HF, Bhatt AC, et al. (2002) Adaptive piezoelectric energy harvesting circuit for wireless remote power supply. IEEE Transactions on Power Electronics 17: 669-676.
24. Païdoussis MP, Price SJ, De Langre E, (2011) Fluid-Structure Interactions: Cross-Flow-Induced Instabilities. New York: Cambridge University Press.
25. Paradiso JA, Starner T, (2005) Energy scavenging for mobile and wireless electronics. IEEE Pervasive Computing 4: 18-27.
26. Pobering S, Ebermeyer S, Schwesinger N, (2009) Generation of electrical energy using short piezoelectric cantilevers in flowing media. IN: Proceeding SPIE 7288, Active and Passive Smart Structures and Integrated Systems, 2009, San Diego, CA, 8-12 March, p. 728807. Bellingham, WA: International Society for Optics and Photonics.
27. Richard C, Guyomar D, Lefeuvre D, (2007) Self-powered electronic breaker with automatic switching by detecting maxima or minima of potential difference between its power electrodes. Patent PCT/FR2005/003000 (publication number: WO/2007/063194).
28. Roundy S, Wright PK, (2004) A piezoelectric vibration based generator for wireless electronics. Smart Materials and Structures 13: 1131.
29. Shu YC, Lien IC, (2006) Analysis of power output for piezoelectric energy harvesting systems. Smart Materials and Structures 15: 1499-1512.
30. Shu Y, Lien I, Wu W, (2007) An improved analysis of the SSHI interface in piezoelectric energy harvesting. Smart Materials and Structures 16: 2253.
31. Sirohi J, Mahadik R, (2011) Piezoelectric wind energy harvester for low-power sensors. Journal of Intelligent Material Systems and Structures. 22: 2215-2228.
32. Sirohi J, Mahadik R, (2012) Harvesting wind energy using a galloping piezoelectric beam. Journal of Vibration and Acoustics 134: 011009.
33. Tang L, Yang Y, (2011) Analysis of synchronized charge extraction for piezoelectric energy harvesting. Smart Materials and Structures 20: 085022.
34. Tang L, Yang Y, Soh CK, (2013) Broadband vibration energy harvesting techniques. In: Elvin N, Erturk A, (eds) Advances in Energy Harvesting Methods. New York: Springer, pp. 17-61.
35. Tang L, Yang Y, Tan YK, et al. (2011) Applicability of synchronized charge extraction technique for piezoelectric energy harvesting. In: Proceeding SPIE 7977, Active and Passive Smart Structures and Integrated Systems, 2011, San Diego, CA, 6-10 March, p. 79770I. Bellingham, WA: International Society for Optics and Photonics.
36. Tang L, Zhao L, Yang Y, et al. (2014) Equivalent circuit representation and analysis of galloping-based wind energy harvesting. IEEE/ASME Transactions on Mechatronics 20: 834-844.
37. Wang Y, Inman DJ, (2013) Experimental validation for a multifunctional wing spar with sensing, harvesting, and gust alleviation capabilities. IEEE/ASME Transactions on Mechatronics 18: 1289-1299.
38. Wickenheiser AM, Reissman T, Wu W-J, et al. (2010) Modeling the effects of electromechanical coupling on energy storage through piezoelectric energy harvesting. IEEE/ASME Transactions on Mechatronics 15: 400-411.
39. Wu W, Wickenheiser A, Reissman T, et al. (2009) Modeling and experimental verification of synchronized discharging techniques for boosting power harvesting from piezoelectric transducers. Smart Materials and Structures 18: 055012.
40. Wu Y, Badel A, Formosa F, et al. (2014) Self-powered optimized synchronous electric charge extraction circuit for piezoelectric energy harvesting. Journal of Intelligent Material Systems and Structures 25: 2165-2176.
41. Xiang T, Chi Z, Li F, et al. (2013) Powering indoor sensing with airflows: a trinity of energy harvesting, synchronous duty-cycling, and sensing. In: The 11th ACM conference on embedded networked sensor systems, Rome, Italy, 11-15 November, paper no. 16. 73.
42. Yang Y, Tang L, (2009) Equivalent circuit modeling of piezoelectric energy harvesters. Journal of Intelligent Material Systems and Structures 20: 2223-2235.
43. Yang Y, Zhao L, Tang L, (2013) Comparative study of tip cross-sections for efficient galloping energy harvesting. Applied Physics Letters 102: 064105.
44. Zhao L, Tang L, Yang Y, (2013) Comparison of modeling methods and parametric study for a piezoelectric wind energy harvester. Smart Materials and Structures 22: 125003.
45. Zhao L, Tang L, Yang Y, (2014) Enhanced piezoelectric galloping energy harvesting using 2 degree-of-freedom cut-out cantilever with magnetic interaction. Japanese Journal of Applied Physics 53: 060302.
46. Zhu L, Chen R, Liu X, (2012) Theoretical analyses of the electronic breaker switching method for nonlinear energy harvesting interfaces. Journal of Intelligent Material Systems and Structures 23: 441-451.