Olivier Doaré scite author profile

Self-sustained oscillations resulting from fluid-solid instabilities, such as the flutter of a flexible flag in axial flow, can be used to harvest energy if one is able to convert the solid energy into electricity. Here, this is achieved using piezoelectric patches attached to the surface of the flag, which convert the solid deformation into an electric current powering purely resistive output circuits. Nonlinear numerical simulations in the slender-body limit, based on an explicit description of the coupling between the fluid-solid and electric systems, are used to determine the harvesting efficiency of the system, namely the fraction of the flow kinetic energy flux effectively used to power the output circuit, and its evolution with the system's parameters. The role of the tuning between the characteristic frequencies of the fluid-solid and electric systems is emphasized, as well as the critical impact of the piezoelectric coupling intensity. High fluid loading, classically associated with destabilization by damping, leads to greater energy harvesting, but with a weaker robustness to flow velocity fluctuations due to the sensitivity of the flapping mode selection. This suggests that a control of this mode selection by a careful design of the output circuit could provide some opportunities to improve the efficiency and robustness of the energy harvesting process.

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Piezoelectric coupling in energy-harvesting fluttering flexible plates: linear stability analysis and conversion efficiency

Doaré

Michelin

2011

Journal of Fluids and Structures

178

150

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This paper investigates the energy harvested from the flutter of a plate in an axial flow by making use of piezoelectric materials. The equations for fully-coupled linear dynamics of the fluid-solid and electrical systems are derived. The continuous limit is then considered, when the characteristic length of the plate's deformations is large compared to the piezoelectric patches' length. The linear stability analysis of the coupled system is addressed from both a local and global point of view. Piezoelectric energy harvesting adds rigidity and damping on the motion of the flexible plate, and destabilization by dissipation is observed for negative energy waves propagating in the medium. This result is confirmed in the global analysis of fluttering modes of a finite-length plate. It is finally observed that waves or modes destabilized by piezoelectric coupling maximize the energy conversion efficiency. * Electronic address: olivier.doare@ensta.fr † Electronic address: sebastien.michelin@ladhyx.polytechnique.fr

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Local and Global Instability of Fluid-Conveying Pipes on Elastic Foundations

Doaré

Langre

2002

Journal of Fluids and Structures

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Olivier Doaré

Energy harvesting efficiency of piezoelectric flags in axial flows

Piezoelectric coupling in energy-harvesting fluttering flexible plates: linear stability analysis and conversion efficiency

Local and Global Instability of Fluid-Conveying Pipes on Elastic Foundations

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