Shape-morphing membranes augment the performance of oscillating foil energy harvesting turbines

TL;DR

This study investigates how shape-morphing membranes in oscillating foil turbines improve energy harvesting by enhancing vortex stability and lift, with a focus on the roles of camber and extensibility across various operating conditions.

Contribution

It provides a comprehensive analysis of compliant membrane OFTs over a wide parameter space, clarifying the effects of membrane extensibility and camber on performance and vortex stabilization.

Findings

Optimal frequency of membrane OFT is lower than rigid foil due to LEV stability.

Membrane extensibility influences performance differently at various angles of attack.

Deformation dynamics correlate with improved lift and stall delay at higher angles.

Abstract

Oscillating foil turbines (OFTs) can be used to produce power from rivers and tides by synchronizing their heaving motion with the strong lift force of vortices shed at their leading edge. Prior work has shown that compliant membrane OFTs, which passively camber, exhibit enhanced leading edge vortex (LEV) stability and improved lift and power compared with rigid foil OFTs for specific kinematics. This work seeks to understand a) the performance of compliant membrane OFTs over their full kinematic parameter space and b) separate the roles of membrane camber and extensibility in LEV stabilization. We characterize the performance of a compliant membrane OFT over a wide range of kinematic parameters through prescribed motion experiments in a free-surface water flume. The optimal frequency of the compliant membrane OFT is found to be lower than that of a rigid foil OFT due to the enhanced LEV stability of the membrane. The lift and power of compliant and inextensible membrane foils are then compared to determine whether camber alone is effective for LEV stabilization or if extensibility plays an important stabilizing role. The deformation of the compliant membrane OFT is measured using laser imaging. We observe that the role of extensibility changes for different angles of attack. At low angles of attack, membrane deformation is consistent through the half cycle coinciding with similar performance to the inextensible foil. At higher angles of attack, the compliant foil has a larger deformation and dynamically decambers corresponding with delayed stall and enhanced lift and power.