How to Extract Energy from Turbulence in Flight by Fast Tracking

TL;DR

This paper proposes a method for flight vehicles to harvest energy from turbulence by fast tracking, leading to increased mean velocities and reduced energy consumption through a novel inertia rescaling technique.

Contribution

It introduces a new forcing method to simulate effective inertia, enabling energy harvesting from turbulence and optimizing flight performance in turbulent conditions.

Findings

Up to 10% net energy savings compared to quiescent flight.

Mean velocities increased by up to 40%.

The effective operating range of fast tracking is expanded tenfold.

Abstract

We analyze a way to make flight vehicles harvest energy from homogeneous turbulence by fast tracking in the way that falling inertial particles do. Mean airspeed increases relative to flight through quiescent fluid when turbulent eddies sweep particles and vehicles along in a productive way. Once swept, inertia tends to carry a vehicle into tailwinds more often than headwinds. We introduce a forcing that rescales the effective inertia of rotorcraft in computer simulations. Given a certain thrust and effective inertia, we find that flight energy consumption can be calculated from measurements of mean particle settling velocities and acceleration variances alone, without need for other information. In calculations using a turbulence model, we optimize the balance between the work performed to generate the forcing and the advantages induced by fast tracking. The results show net energy reductions of up to about 10% relative to flight through quiescent fluid and mean velocities up to 40% higher. The forcing expands the range of conditions under which fast tracking operates by a factor of about ten. We discuss how the mechanism can operate for any vehicle, how it may be even more effective in real turbulence and for fixed-wing aircraft, and how modifications might yield yet greater performance.