Unsteady Load Mitigation through Passive Pitch

TL;DR

This study demonstrates that passive pitching significantly reduces lift fluctuations in fluid-structure systems, offering a potential passive control strategy for turbines and vehicles subjected to flow unsteadiness.

Contribution

The paper provides new insights into the effectiveness of passive pitching in mitigating unsteady lift loads, with quantitative analysis showing substantial reduction in force fluctuations.

Findings

Lift amplitude reduced by at least two-thirds

Efficacy weakly depends on pitching axis location

Optimal pitching axis is upstream near the foil's axis

Abstract

Mitigation of load fluctuations due to flow unsteadiness is critical in a broad range of applications, including wind/tidal turbines, and aerial/underwater vehicles. While the use of active control systems is an established practice in engineering, passive systems are not well understood, and the limits of their efficacy are yet to be ascertained. To this end, the present study aims to provide new insights into the effectiveness of passive pitching in the mitigation of lift fluctuations in the most demanding case of fast, high-amplitude variations of the free stream speed and direction. We perform fluid-structure interaction simulations of a two-dimensional free-to-pitch rigid foil. Our study reveals that the lift amplitude of the force fluctuations can be decreased by at least two-thirds through passive pitching. The efficacy of the unsteady load mitigation is only weakly dependent on the exact pitching axis location, and the optimal position is upstream and close to the axis of the foil. These results may inform the design of passive control systems of wind/tidal turbines and aerial/underwater vehicles and provide new insights into interpreting the control strategy of natural flyers such as insects and birds.