A design and experimental verification methodology for an energy harvester skin structure

Smart Materials and Structures

Volumn 20, Issue 5, 2011, Pages

  Lee, Soobum ^a   Youn, Byeng D ^b  

^a University of Notre Dame   (United States)

^b Seoul National University   (South Korea)

Author keywords

[No Author keywords available]

Indexed keywords

BUILDING AUTOMATION; CLAMPING CONDITIONS; CONDENSING UNITS; DESIGN IMPROVEMENTS; DESIGN METHODOLOGY; ENERGY HARVESTER; ENERGY LOSS; ENGINEERED SYSTEMS; EXPERIMENTAL VERIFICATION; OUTDOOR UNITS; PIEZOELECTRIC ENERGY HARVESTING; PIEZOELECTRIC PATCH; PROOF MASS; PZT MATERIALS; SKIN STRUCTURE; VIBRATING STRUCTURES; WIRELESS SENSOR;

DESIGN; ENERGY DISSIPATION; INTELLIGENT BUILDINGS; NANOCANTILEVERS; PIEZOELECTRIC DEVICES; PIEZOELECTRIC MATERIALS; PIEZOELECTRICITY; SHAPE OPTIMIZATION; STRUCTURAL HEALTH MONITORING;

ENERGY HARVESTING;

EID: 79960622719     PISSN: 09641726     EISSN: 1361665X     Source Type: Journal    
DOI: 10.1088/0964-1726/20/5/057001     Document Type: Review

References (40)

1. Bai H, Atiquzzaman M and Lilja D 2004 Wireless sensor network for aircraft health monitoring BroadNets' 04: Proc. 1st Int. Conf. on Broadband Networks (San Jose, CA, Oct. 2004) ed B Werner (Los Alamitos, CA: IEEE Computer Society) pp748-50 (Pubitemid 40731198)
2. Roundy S, Wright P K and Rabaey J 2003 A study of low level vibrations as a power source for wireless sensor nodes Comput. Commun. 26 1131-44
3. Park G, Rosing T, Todd M D, Farrar C R and Hodgkiss W 2008 Energy harvesting for structural health monitoring sensor networks J. Infrastruct. Syst. 14 64-79 (Pubitemid 351279604)
4. ITP Sensors and Automation: Low-Cost Vibration Power Harvesting for Wireless Sensors US Department of Energy Energy Efficiency and Renewable Energy (cited 2008 Dec. 4) available from http://www1.eere.energy.gov/industry/sensors- automation/pdfs/kcf-vibrationpower.pdf
5. Roundy S, Wright P K and Rabaey J M 2004 Energy Scavenging for Wireless Sensor Networks: With Special Focus on Vibrations (Berlin: Springer)
6. Glynne-Jones P, Beeby S P and White N M 2001 Towards a piezoelectric vibration-powered microgenerator IEE Sci., Meas. Technol. 148 68-72 (Pubitemid 32944443)
7. Sterken T, Baert K, Van Hoof C, Puers R, Borghs G and Fiorini P 2004 Comparative modelling for vibration scavengers Proc. IEEE Sensors 2004 (Vienna, Oct. 2004) ed D Rocha, P M Sarro and M J Vellekoop pp1249-52 (Pubitemid 41668184)
8. Silk M G 1984 Ultrasonic Transducers for Nondestructive Testing (Bristol: Hilger)
9. Elvin N, Elvin A and Choi D H 2003 A self-powered damage detection sensor J. Strain Anal. Eng. Des. 38 115-24
10. Nuffer J and Bein T 2006 Applications of piezoelectric materials in transportation industry TRANSFAC' 06: Proc. Global Symp. on Innovative Solutions for the Advancement of the Transport Industry (San Sebastian, Oct. 2006) ed J Gõi, G Lilly, I Inzunza, E Erauzkin, C Mereveille, C Elizetxea, N Markaide and B Mishra
11. Anton S R and Sodano H A 2007 A review of power harvesting using piezoelectric materials (2003-2006) Smart Mater. Struct. 16 R1-21
12. Granstrom J, Feenstra J, Sodano H A and Farinholt K 2007 Energy harvesting from a backpack instrumented with piezoelectric shoulder straps Smart Mater. Struct. 16 1810-20 (Pubitemid 351291544)
13. Leland E S, Lai E M and Wright P K 2004 A self-powered wireless sensor for indoor environmental monitoring Proc. WNCG Conf. (Austin, TX, Oct. 2004)
14. Shenck N S and Paradiso J A 2001 Energy scavenging with shoe-mounted piezoelectrics IEEE MICRO 21 30-42 (Pubitemid 32583362)
15. Mateu L and Moll F 2005 Optimum piezoelectric bending beam structures for energy harvesting using shoe inserts J. Intell. Mater. Syst. Struct. 16 835-45 (Pubitemid 41498484)
16. Goldschmidtboeing F and Woias P 2008 Characterization of different beam shapes for piezoelectric energy harvesting J. Micromech. Microeng. 18 104013
17. Roundy S, Leland E S, Baker J, Carleton E, Reilly E, Lai E, Otis B, Rabaey J M, Wright P K and Sundararajan V 2005 Improving power output for vibration-based energy scavengers IEEE Pervasive Comput. 4 28-36 (Pubitemid 40495603)
18. Zheng B, Chang C J and Gea H C 2009 Topology optimization of energy harvesting devices using piezoelectric materials Struct. Multidiscip. Optim. 38 17-23
19. Silva E C N 2009 Comment on 'Topology optimization of energy harvesting devices using piezoelectric materials' Struct. Multidiscip. Optim. 39 337-8
20. Erturk A and Inman D J 2008 Issues in mathematical modeling of piezoelectric energy harvesters Smart Mater. Struct. 17 065016
21. Rupp C J, Evgrafov A, Maute K and Dunn M L 2009 Design of piezoelectrc energy harvesting systems: a topology optimization approach based on multilayer plates and shells J. Intell. Mater. Syst. Struct. 20 1923
22. Kim H, Tadesse Y and Priya S 2009 Piezoelectric energy harvesting Energy Harvesting Technologies ed S Priya and D J Inman (New York: Springer) pp9-16
23. Shen D, Choe S Y and Kim D J 2007 Analysis of piezoelectric materials for energy harvesting devices under high-g vibrations Japan. J. Appl. Phys. 46 6755-60 (Pubitemid 47575207)
24. Sodano H A, Inman D J and Park G 2004 A review of power harvesting from vibration using piezoelectric materials Shock Vib. Digest 36 197-206
25. Anton S R and Sodano H A 2007 A review of power harvesting using piezoelectric materials (2003-2006) Smart Mater. Struct. 16 R1
26. Lam K Y and Ng T Y 1999 Active control of composite plates with integrated piezoelectric sensors and actuators under various dynamic loading conditions Smart Mater. Struct. 8 223-37
27. Song G, Sethi V and Li H N 2006 Vibration control of civil structures using piezoceramic smart materials: a review Eng. Struct. 28 1513-24 (Pubitemid 44057699)
28. Park G, Sohn H, Farrar C R and Inman D J 2003 Overview of piezoelectric impedance-based health monitoring and path forward Shock Vib. Digest 35 451-64
29. Lee S, Youn B D and Jung B C 2009 Robust segment-type energy harvester and its application to a wireless sensor Smart Mater. Struct. 18 095021
30. Bohn: The Cold Standard (cited 2009 8 Sept.) available from http://www.thecoldstandard.com/
31. Lee S, Youn B D and Giraud M 2010 Designing energy harvesting skin structure utilizing outdoor unit vibration IDETC: Proc. Int. Design Engineering Technical Conferences (Montreal, Aug. 2010)
32. Xie Y M and Steven G P 1997 Evolutionary Structural Optimization (Berlin: Springer)
33. Xie Y M and Steven G P 1996 Evolutionary structural optimization for dynamic problems Comput. Struct. 58 1067-73 (Pubitemid 126386016)
34. Kim H, Querin O M, Steven G P and Xie Y M 2000 A method for varying the number of cavities in an optimized topology using evolutionary structural optimization Struct. Multidiscip. Optim. 19 140-7
35. Chen S N, Wang G J and Chien M C 2006 Analytical modeling of piezoelectric vibration-induced micro power generator Mechatronics 16 379-87
36. Lu F, Lee H P and Lim S P 2004 Modeling and analysis of micro piezoelectric power generators for micro-electromechanical-systems applications Smart Mater. Struct. 13 57-63
37. Erturk A, Tarazaga P A, Farmer J R and Inman D J 2009 Effect of strain nodes and electrode configuration on piezoelectric energy harvesting from cantilevered beams J. Vib. Acoust. 131 011010
38. HyperWorks 2008 (Altair Engineering Inc.) http://www.altairhyperworks.com
39. Arms S W, Townsend C P, Churchill D L, Galbreath J H and Mundell S W 2005 Power management for energy harvesting wireless sensors Proc. SPIE 5763 267-75 (Pubitemid 41351591)
40. Echoflex 43-160 Wireless Self Powered Photo Sensor (cited 2010 5 March) available from http://www.energyharvestingjournal.com/articles/mobile-kinetic- energy-harvester-00001457.asp