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Improving the aerodynamic performance of a cycloidal rotor through active compliant morphing

Improving the aerodynamic performance of a cycloidal rotor through active compliant morphing
Improving the aerodynamic performance of a cycloidal rotor through active compliant morphing
Cycloidal rotors are a novel form of propulsion system that can be adapted to various forms of transport such as air and marine vehicles, with a geometrical design differing significantly from the conventional screw propeller. Research on cycloidal rotor design began in the early 1930s and has developed throughout the years to the point where such devices now operate as propulsion systems for various aerospace applications such as micro air vehicles, unmanned air vehicles and compound helicopters. The majority of research conducted on the cycloidal rotor’s aerodynamic performance have not assessed mitigating the dynamic stall effect, which can have a negative impact on the rotor performance when the blades operate in the rotor retreating side. A solution has been proposed to mitigate the dynamic stall effect through employment of active, compliant leading-edge morphing. A review of the current state of the art in this area is presented. A two-dimensional, implicit unsteady numerical analysis was conducted using the commercial computational fluid dynamics software package STAR CCM+, on a two-bladed cycloidal rotor. An overset mesh technique, otherwise known as a chimera mesh, was used to apply complex transient motions to the simulations. Active, compliant leading-edge morphing is applied to an oscillating NACA 0015 aerofoil to attempt to mitigate the dynamic stall whilst maintaining the positive dynamic lift coefficient (Cl) contributions. It was verified that by applying a pulsed input leading-edge rotational morphing schedule, the leading-edge vortex does not fully form and the large flow separation is prevented. Further work in this investigation will focus on coupling the active, leading-edge motion to the cycloidal rotor model with the aim to maximise aerodynamic performance.
0001-9240
901-915
Ferrier, L.
4aae5138-eb37-4082-8c8c-bc1220bab4d4
Vezza, M.
b87017cc-8df4-4ae4-b510-2d74839c63e9
Zare-Behtash, H.
74be9b97-cb09-49c6-9f75-7ec58c0dd16c
Ferrier, L.
4aae5138-eb37-4082-8c8c-bc1220bab4d4
Vezza, M.
b87017cc-8df4-4ae4-b510-2d74839c63e9
Zare-Behtash, H.
74be9b97-cb09-49c6-9f75-7ec58c0dd16c

Ferrier, L., Vezza, M. and Zare-Behtash, H. (2017) Improving the aerodynamic performance of a cycloidal rotor through active compliant morphing. Aeronautical Journal, 121 (1241), 901-915. (doi:10.1017/aer.2017.34).

Record type: Article

Abstract

Cycloidal rotors are a novel form of propulsion system that can be adapted to various forms of transport such as air and marine vehicles, with a geometrical design differing significantly from the conventional screw propeller. Research on cycloidal rotor design began in the early 1930s and has developed throughout the years to the point where such devices now operate as propulsion systems for various aerospace applications such as micro air vehicles, unmanned air vehicles and compound helicopters. The majority of research conducted on the cycloidal rotor’s aerodynamic performance have not assessed mitigating the dynamic stall effect, which can have a negative impact on the rotor performance when the blades operate in the rotor retreating side. A solution has been proposed to mitigate the dynamic stall effect through employment of active, compliant leading-edge morphing. A review of the current state of the art in this area is presented. A two-dimensional, implicit unsteady numerical analysis was conducted using the commercial computational fluid dynamics software package STAR CCM+, on a two-bladed cycloidal rotor. An overset mesh technique, otherwise known as a chimera mesh, was used to apply complex transient motions to the simulations. Active, compliant leading-edge morphing is applied to an oscillating NACA 0015 aerofoil to attempt to mitigate the dynamic stall whilst maintaining the positive dynamic lift coefficient (Cl) contributions. It was verified that by applying a pulsed input leading-edge rotational morphing schedule, the leading-edge vortex does not fully form and the large flow separation is prevented. Further work in this investigation will focus on coupling the active, leading-edge motion to the cycloidal rotor model with the aim to maximise aerodynamic performance.

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More information

Accepted/In Press date: 8 March 2017
e-pub ahead of print date: 11 May 2017

Identifiers

Local EPrints ID: 490949
URI: http://eprints.soton.ac.uk/id/eprint/490949
DOI: doi:10.1017/aer.2017.34
ISSN: 0001-9240
PURE UUID: 12391581-2bec-4ef7-8719-d0dc49c83ef8
ORCID for H. Zare-Behtash: ORCID iD orcid.org/0000-0002-4769-4076

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Date deposited: 10 Jun 2024 16:40
Last modified: 15 Jun 2024 02:11

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Contributors

Author: L. Ferrier
Author: M. Vezza
Author: H. Zare-Behtash ORCID iD

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