NUMERICAL INVESTIGATION OF SELF-SUSTAINED LIMIT-CYCLE OSCILLATIONS IN A FLAPPING-FOIL ENERGY HARVESTER

Enhao Wang, Kiran Ramesh, Ignazio Maria Viola, Shaun Killen

DOI Number: N/A

Conference number: IFASD-2017-162

Two-degree-of-freedom (2DOF) fully passive motion of a ﬂapping foil at a low Reynolds number Re = 10,000 is studied numerically. The simulations are conducted using open source computational ﬂuid dynamics (CFD) toolbox OpenFOAM. The present research is mainly focused on the self-sustained limit-cycle oscillations of a ﬂapping foil with potential application as a hydro-energy harvester. The effect of different parameters on the onset of linear ﬂutter, the characteristics of the system response, the available power from a ﬂapping foil and the ﬂow patterns are investigated. It is found that given a small initial perturbation, the response of the foil is similar to that of classical linear ﬂutter i.e., the oscillations converged to a constant value at reduced velocities lower than the ﬂutter velocity and limit-cycle oscillations (LCOs) are observed once the reduced velocities are greater than the ﬂutter velocity. The reduced frequency of the LCOs exhibits a decreasing trend with increasing reduced velocity. In contrast, the phase difference between pitch and plunge increases with the increase of the reduced velocity. The feasibility of power extraction is demonstrated and the time-averaged power shows a single peak at an intermediate reduced velocity. Limit-cycle oscillations are found to be inﬂuenced by leading-edge vortex shedding as well as trailing-edge ﬂow separation.

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CFD, ﬂapping wings, ﬂuid structure, interaction energy harvesting, leading edge vortices

In Categories: 1.Events, IFASD 2017, Steady/Unsteady Aerodynamics

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