Linear and Nonlinear Aeroelastic Energy Harvesting Using Electromagnetic Induction

Anicézio, Marcela de Melo; Ertürk, Alper; Marqui, Carlos De; Inman, Daniel J.

doi:10.1115/smasis2011-5171

Cited by 2 publications

(1 citation statement)

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“…Particularly, Sousa et al [124] and Anicézio et al [125] studied the EH system with the combination of the two nonlinearities via piezoelectric and magnetic transduction, respectively. This combination of two nonlinearities was also studied by Bae et al [88] and Wu et al [115].…”

Section: Limit Cycle Oscillations Of Wing Sectionsmentioning

confidence: 99%

Energy harvesting by means of flow-induced vibrations on aerospace vehicles

Ronch

et al. 2016

Progress in Aerospace Sciences

140

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This paper reviews the design, implementation, and demonstration of energy harvesting devices that exploit flow-induced vibrations as the main source of energy.Starting with a presentation of various concepts of energy harvesters that are designed to benefit from a general class of flow-induced vibrations, specific attention is then given at those technologies that may offer, today or in the near future, a potential benefit to extend the operational capabilities and to monitor critical parameters of

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Section: Limit Cycle Oscillations Of Wing Sectionsmentioning

confidence: 99%

Energy harvesting by means of flow-induced vibrations on aerospace vehicles

Ronch

et al. 2016

Progress in Aerospace Sciences

140

View full text Add to dashboard Cite

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Aeroelastic characteristics of linear and nonlinear piezo-aeroelastic energy harvester

Bae

Inman

2013

Journal of Intelligent Material Systems and Structures

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In the present study, a piezo-aeroelastic energy harvester using nonlinear aeroelastic behaviors is proposed, and their characteristics and performance are investigated. The energy harvester is modeled by a two-dimensional typical section airfoil. The nondimensional parameters of the harvester are introduced, and the nondimensional piezo-aeroelastic equations are formulated. For the piezo-aeroelastic analysis, the root-locus method and time-integration method are used, and the present method is verified with experimental and analytical results. The iterative method is introduced to calculate the frequency response functions of a nonlinear piezo-aeroelastic energy harvester. The aeroelastic characteristics of a linear piezo-aeroelastic energy harvester and the effects of parameters are investigated. The results show that the linear piezo-aeroelastic energy harvester can be used to generate electricity only at the vicinity of flutter speed. It is assumed that the nonlinear piezo-aeroelastic energy harvester has free play and cubic hardening in pitch. For free play, nonlinear aeroelastic results show that stable limit cycle oscillations are observed in the wide range of air speed below flutter speed when the frequency ratio is 1.3, and unstable limit cycle oscillations are observed at air speeds over flutter speed when the frequency ratio is 0.3. For cubic hardening, unstable limit cycle oscillations are observed at air speeds below flutter speed when the frequency ratio is 0.3, and stable limit cycle oscillations are observed at air speeds over flutter speed when the frequency ratio is 1.3. Finally, the authors discussed how to use these aeroelastic responses for piezo-aeroelastic energy harvesting.

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Linear and Nonlinear Aeroelastic Energy Harvesting Using Electromagnetic Induction

Cited by 2 publications

References 0 publications

Energy harvesting by means of flow-induced vibrations on aerospace vehicles

Energy harvesting by means of flow-induced vibrations on aerospace vehicles

Aeroelastic characteristics of linear and nonlinear piezo-aeroelastic energy harvester

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