Atmospheric turbulence is an unsolved problem for aviation impairing economy, safety and comfort. Current efforts to predict turbulence more accurately in order to avoid it by rerouting result in higher fuel consumption and CO2 emissions as well as reduced traffic volumes.

Objective

In the future it should be possible to fly through atmospheric turbulences directly and reliably. The SmartWings research project at MPEI is investigating methods and technologies that are able to reduce the disturbance effects of turbulence, such as vertical accelerations, by as much as 80%.

Approach

Smart wing structures measuring turbulences in front of the wing and actively adjusting their shape can suppress disturbance effects of atmospheric turbulences in flight. Calculating optimum flight control outputs from the measured data is a particular control engineering challenge. It is solved by a combination of model-based feedforward and feedback control.

Highly dynamic lift control: Through the application of direct lift control, the wing lift can be varied very quickly. A novel control procedure prevents secondary short-period oscillation and thus considerably increases the lifting effect that can be achieved.

Phase compensation: Using anticipating sensors, such as pressure measurements in front of the wing or wind LiDAR, it is possible to compensate system-related time delays and the disturbances precisely at the right moment.

Adaptive structures: Innovative materials and manufacturing methods enable the use of adaptive wing structures (morphing wings) in order to adapt the wing shape specifically to the external flow field.

Applications

Active Turbulence Suppression may be applied to fixed-wing airplanes of different sizes – from micro UAV to long-haul aircraft. An essential prerequisite for implementation is a digital flight control and technical equipment on the wing in order to vary the lift quickly. For this purpose, conventional wing flaps or, in the future, novel wing structures with adaptive elements may be used.

Related Publications

Journal articles

• A. Galffy, R. Gaggl, R. Mühlbacher, D. Frank, J. Schlarp, and G. Schitter, Turbulence load prediction for manned and unmanned aircraft by means of anticipating differential pressure measurements, CEAS Aeronautical Journal, vol. 12, 2021. [Download (PDF)]
• A. Galffy, M. Böck, and A. Kugi, Nonlinear 3D path following control of a fixed-wing aircraft based on acceleration control, Control Engineering Practice, vol. 86, p. 56–69, 2019. [Download (PDF)]

Conference papers

• A. Galffy, J. Schlarp, D. Frank, R. Mühlbacher, and G. Schitter, Turbulence prediction for aircraft by means of high-dynamic differential pressure measurements, in Proceedings of the Aerospace Europe Conference AEC2020, 2020. [Download (PDF)]
• A. Galffy, F. Car, and G. Schitter, Calibration and flight test of a 3D printed 5-hole probe for high-dynamic wind measurements for UAV, in Proceedings of the International Workshop on Research, Education and Development on Unmanned Aerial Systems, 2019. [Download (PDF)]

Project Partners

Turbulence Solutions GmbH
T.I.P.S. Messtechnik GmbH
Actaron GmbH

Press Release

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Funding

Funded under the program Take Off of the Austrian Federal Ministry for Transport, Innovation and Technology (bmvit)