Wind Defiant Morphing Drones

Charalampos Vourtsis; Victor Casas Rochel; Nathan Samuel Müller; William Stewart; Dario Floreano

doi:10.1002/aisy.202200297

Wind Defiant Morphing Drones

Charalampos Vourtsis
, Victor Casas Rochel
, Nathan Samuel Müller
, William Stewart
, Dario Floreano

Mechanical Engineering

Swiss Federal Institute of Technology Lausanne

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Intense winds are a challenge for vertical take-off and landing drones with wings. In particular, in the hovering regime, wings are sensitive to wind currents that can be detrimental to their operational and energetic performances. Tail-sitters are particularly prone to those wind currents because their wings are perpendicular to the incoming wind during hovering. This wind generates a large amount of drag and can displace and destabilize the vehicle, possibly leading to catastrophic failures. Herein, our morphing strategy demonstrates in a custom-built 1.8 kg tail-sitter with morphing wings that can actively resist winds and leverage them to increase its aerodynamic efficiency. It is shown that adaptive wing morphing during hovering in adverse wind conditions can reduce normalized energy consumption up to 85%, increase attitude and positional stability, and leverage wind energy to increase its yaw angular rate up to 200% while decreasing motor saturation levels.

Original language	English
Article number	2200297
Journal	Advanced Intelligent Systems
Volume	5
Issue number	3
DOIs	https://doi.org/10.1002/aisy.202200297
State	Published - Mar 2023

Keywords

UAV
VTOL
drone
morphing
wind

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10.1002/aisy.202200297

Cite this

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title = "Wind Defiant Morphing Drones",

abstract = "Intense winds are a challenge for vertical take-off and landing drones with wings. In particular, in the hovering regime, wings are sensitive to wind currents that can be detrimental to their operational and energetic performances. Tail-sitters are particularly prone to those wind currents because their wings are perpendicular to the incoming wind during hovering. This wind generates a large amount of drag and can displace and destabilize the vehicle, possibly leading to catastrophic failures. Herein, our morphing strategy demonstrates in a custom-built 1.8 kg tail-sitter with morphing wings that can actively resist winds and leverage them to increase its aerodynamic efficiency. It is shown that adaptive wing morphing during hovering in adverse wind conditions can reduce normalized energy consumption up to 85\%, increase attitude and positional stability, and leverage wind energy to increase its yaw angular rate up to 200\% while decreasing motor saturation levels.",

keywords = "UAV, VTOL, drone, morphing, wind",

author = "Charalampos Vourtsis and Rochel, \{Victor Casas\} and M{\"u}ller, \{Nathan Samuel\} and William Stewart and Dario Floreano",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Advanced Intelligent Systems published by Wiley-VCH GmbH.",

year = "2023",

month = mar,

doi = "10.1002/aisy.202200297",

language = "English",

volume = "5",

journal = "Advanced Intelligent Systems",

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TY - JOUR

T1 - Wind Defiant Morphing Drones

AU - Vourtsis, Charalampos

AU - Rochel, Victor Casas

AU - Müller, Nathan Samuel

AU - Stewart, William

AU - Floreano, Dario

PY - 2023/3

Y1 - 2023/3

N2 - Intense winds are a challenge for vertical take-off and landing drones with wings. In particular, in the hovering regime, wings are sensitive to wind currents that can be detrimental to their operational and energetic performances. Tail-sitters are particularly prone to those wind currents because their wings are perpendicular to the incoming wind during hovering. This wind generates a large amount of drag and can displace and destabilize the vehicle, possibly leading to catastrophic failures. Herein, our morphing strategy demonstrates in a custom-built 1.8 kg tail-sitter with morphing wings that can actively resist winds and leverage them to increase its aerodynamic efficiency. It is shown that adaptive wing morphing during hovering in adverse wind conditions can reduce normalized energy consumption up to 85%, increase attitude and positional stability, and leverage wind energy to increase its yaw angular rate up to 200% while decreasing motor saturation levels.

AB - Intense winds are a challenge for vertical take-off and landing drones with wings. In particular, in the hovering regime, wings are sensitive to wind currents that can be detrimental to their operational and energetic performances. Tail-sitters are particularly prone to those wind currents because their wings are perpendicular to the incoming wind during hovering. This wind generates a large amount of drag and can displace and destabilize the vehicle, possibly leading to catastrophic failures. Herein, our morphing strategy demonstrates in a custom-built 1.8 kg tail-sitter with morphing wings that can actively resist winds and leverage them to increase its aerodynamic efficiency. It is shown that adaptive wing morphing during hovering in adverse wind conditions can reduce normalized energy consumption up to 85%, increase attitude and positional stability, and leverage wind energy to increase its yaw angular rate up to 200% while decreasing motor saturation levels.

KW - UAV

KW - VTOL

KW - drone

KW - morphing

KW - wind

UR - https://www.scopus.com/pages/publications/85165828052

U2 - 10.1002/aisy.202200297

DO - 10.1002/aisy.202200297

M3 - Article

AN - SCOPUS:85165828052

SN - 2640-4567

VL - 5

JO - Advanced Intelligent Systems

JF - Advanced Intelligent Systems

IS - 3

M1 - 2200297

ER -

Wind Defiant Morphing Drones

Abstract

Keywords

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