An experimentally validated double-mass piezoelectric cantilever model for broadband vibration-based energy harvesting

Journal of Intelligent Material Systems and Structures

Volumn 23, Issue 2, 2012, Pages 117-126

  Ou, Qing ^a   Chen, Xiaoqi ^a   Gutschmidt, Stefanie ^a   Wood, Alan ^a   Leigh, Nigel ^b   Arrieta, Andres F ^c  

^a UNIVERSITY OF CANTERBURY   (New Zealand)

^b Commtest Instruments Ltd ^*  (New Zealand)

^c DARMSTADT UNIVERSITY OF TECHNOLOGY   (Germany)

Author keywords

broadband vibration based energy harvesting; dynamic modeling; piezoelectric; self powered sensors

Indexed keywords

CONTINUUM MODEL; CONTROL ELECTRONICS; DYNAMIC MODELING; EFFECTIVE BANDWIDTH; ENERGY HARVESTER; EQUATION OF MOTION; FREQUENCY RESPONSE FUNCTIONS; HAMILTON'S PRINCIPLE; LEAD ZIRCONATE TITANATE; MODE SHAPES; MOVING PARTS; NARROW BANDWIDTH; OUTPUT VOLTAGES; PIEZOELECTRIC; PIEZOELECTRIC CANTILEVER BEAMS; PIEZOELECTRIC CANTILEVERS; RELATIVE DISPLACEMENT; SELF-POWERED; SINUSOIDAL BASE EXCITATION; TRANSITION CONDITIONS; VIBRATION ENERGIES; VIBRATION-BASED ENERGY HARVESTING;

CANTILEVER BEAMS; CONTINUUM MECHANICS; EIGENVALUES AND EIGENFUNCTIONS; EQUATIONS OF MOTION; FREQUENCY RESPONSE; MODAL ANALYSIS; NANOCANTILEVERS; PIEZOELECTRICITY; SEMICONDUCTING LEAD COMPOUNDS;

ENERGY HARVESTING;

EID: 84859386337     PISSN: 1045389X     EISSN: 15308138     Source Type: Journal    
DOI: 10.1177/1045389X11431746     Document Type: Article

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