Design of PZT–Pt functionally graded piezoelectric material for low-frequency actuation applications

Patel, Satyanarayan; Vaish, Rahul

doi:10.1177/1045389x14525491

Cited by 7 publications

(1 citation statement)

References 21 publications

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“…[1][2][3] Several approaches have been proposed, which aim at increasing the harvestede nergy near the resonance frequenciesb yu sing piezoelectric energy harvesters. [4][5][6][7][8][9][10][11][12][13][14][15] One method to increase the harvested energyi st he use of triangular-o rt rapezoidal-profile piezoelectric beams. Initial research by Mateu and Moll [11] on piezoelectric cantilever type energy harvesters proved mathematically that atriangularc antileverw ith base and height dimensionse qual to the base and length dimensions of ar ectangularb eam will have ah igher strain andm aximumd eflection for ag iven load.…”

Section: Introductionmentioning

confidence: 99%

Finite‐Element Analysis of a Varying‐Width Bistable Piezoelectric Energy Harvester

Kumar

Chauhan

et al. 2015

Energy Tech

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In this study, a finite‐element analysis of a varying‐width piezoelectric energy harvester (PEH) has been presented. A varying‐width piezoelectric energy harvester (cantilever type) has variation in the width at definite intervals along its length. To harvest the energy over the wide frequency range of environmental vibrations, nonlinearity is introduced in the stiffness by mean of two neodymium magnets. The width of the proposed varying‐width cantilever PEH is calculated using block pulse functions (BPFs). The objective of applying BPFs is to proximate a triangular PEH (with fixed base) into a proposed varying‐width PEH with three rectangular sections along length. The use of BPFs enable the use of rectangular patches of lead zirconate titanate (PZT‐5A). This leads to a reduction in cost as machining PZT at other than straight cuts results in an extensive increase in the production costs. The varying‐width piezoelectric cantilever beam is subjected to harmonic base excitations by applying a vertical acceleration of 0.2 g (g=9.81 m s−2). Numerical study indicates that the bistable varying‐width PEH generates at least two times the average power than that generated by a bistable uniform‐width PEH for the same volume of piezoelectric material and for the same linear natural frequency. Furthermore, the bistable varying‐width PEH is optimized using a genetic algorithm technique to maximize the mean power density.

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