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Impact of large-scale freestream turbulence on a pitching airfoil

Impact of large-scale freestream turbulence on a pitching airfoil
Impact of large-scale freestream turbulence on a pitching airfoil

This paper investigates the impact of large-scale turbulence on the aerodynamic characteristics of a pitching wind turbine blade at Reynolds number 135 000, whose cross-section is a NACA0012 airfoil with constant chord length. Large-eddy simulations at reduced frequencies, k red = 0.05 and 0.1, were validated against reference data from the literature. An efficient method capable of generating synthetic large-scale turbulence at the inlet was applied by using two streamwise integral length scales L x = 1c and 1.5c, which represent energetic turbulence eddies at the height where the wind turbine operates. For k red = 0.1, the change in the maximum lift coefficient at the dynamic stall angle near the maximum angle of attack is on average 20 % lower and during the downstroke it is on average 22 % lower, compared with the smooth inflow. A higher reduced frequency (k red = 0.2) apparently does not further change the lift, drag and moment coefficients, and the inflow turbulence disordered leading-edge vortices. The turbulent shear stress and the phase-averaged dispersive shear stress in the wake are of the same magnitude, but with negative and positive signs, respectively, suggesting that the large-scale phase-averaged fluctuations transfer momentum in the opposite direction compared with the turbulent fluctuations, reducing the drag on the suction-side flow, and subsequently increasing the averaged lift coefficient. This demonstrates the critical importance of the large-scale non-turbulent unsteadiness in the wake of a pitching wing.

Pitching blade wake, Dynamic stall, Large-eddy simulation, Integral length-scale, Dispersive shear stress
2633-4259
Boye, ThankGod Enatimi
1b12570e-8220-474c-8bf6-0d951cff1fe3
Djidjeli, Kamal
94ac4002-4170-495b-a443-74fde3b92998
Xie, Zheng-Tong
98ced75d-5617-4c2d-b20f-7038c54f4ff0
Boye, ThankGod Enatimi
1b12570e-8220-474c-8bf6-0d951cff1fe3
Djidjeli, Kamal
94ac4002-4170-495b-a443-74fde3b92998
Xie, Zheng-Tong
98ced75d-5617-4c2d-b20f-7038c54f4ff0

Boye, ThankGod Enatimi, Djidjeli, Kamal and Xie, Zheng-Tong (2024) Impact of large-scale freestream turbulence on a pitching airfoil. Flow, 4, [E3]. (doi:10.1017/flo.2024.2).

Record type: Article

Abstract

This paper investigates the impact of large-scale turbulence on the aerodynamic characteristics of a pitching wind turbine blade at Reynolds number 135 000, whose cross-section is a NACA0012 airfoil with constant chord length. Large-eddy simulations at reduced frequencies, k red = 0.05 and 0.1, were validated against reference data from the literature. An efficient method capable of generating synthetic large-scale turbulence at the inlet was applied by using two streamwise integral length scales L x = 1c and 1.5c, which represent energetic turbulence eddies at the height where the wind turbine operates. For k red = 0.1, the change in the maximum lift coefficient at the dynamic stall angle near the maximum angle of attack is on average 20 % lower and during the downstroke it is on average 22 % lower, compared with the smooth inflow. A higher reduced frequency (k red = 0.2) apparently does not further change the lift, drag and moment coefficients, and the inflow turbulence disordered leading-edge vortices. The turbulent shear stress and the phase-averaged dispersive shear stress in the wake are of the same magnitude, but with negative and positive signs, respectively, suggesting that the large-scale phase-averaged fluctuations transfer momentum in the opposite direction compared with the turbulent fluctuations, reducing the drag on the suction-side flow, and subsequently increasing the averaged lift coefficient. This demonstrates the critical importance of the large-scale non-turbulent unsteadiness in the wake of a pitching wing.

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Submitted date: 2 April 2023
Accepted/In Press date: 14 February 2024
Published date: 11 April 2024
Keywords: Pitching blade wake, Dynamic stall, Large-eddy simulation, Integral length-scale, Dispersive shear stress

Identifiers

Local EPrints ID: 477320
URI: http://eprints.soton.ac.uk/id/eprint/477320
DOI: doi:10.1017/flo.2024.2
ISSN: 2633-4259
PURE UUID: 91b256cd-ceb3-479d-be8c-1db63df319d9
ORCID for Zheng-Tong Xie: ORCID iD orcid.org/0000-0002-8119-7532

Catalogue record

Date deposited: 02 Jun 2023 17:22
Last modified: 30 Apr 2024 04:01

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Contributors

Author: ThankGod Enatimi Boye
Author: Kamal Djidjeli
Author: Zheng-Tong Xie ORCID iD

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