Vortex interaction in the wake of a two- And three-bladed wind turbine

Jan Bartl; Thomas H. Hansen; W. Ludwig Kuhn; Franz Mühle; Lars Sætran

doi:10.1088/1742-6596/1669/1/012027

Vortex interaction in the wake of a two- And three-bladed wind turbine

Jan Bartl
, Thomas H. Hansen
, W. Ludwig Kuhn
, Franz Mühle
, Lars Sætran

Chair of Wind Energy

Western Norway University of Applied Sciences
University of Bergen
Norwegian University of Science and Technology

Research output: Contribution to journal › Conference article › peer-review

5 Scopus citations

Abstract

The vortex interaction in the wake behind a two- and three-bladed model scale wind turbine is investigated. The two rotors have equal solidity, and produce similar power and thrust at the design tip speed ratio. Phase-averaged quantities of the wake flow from one to four rotor diameters behind the turbines are measured in a wind tunnel. It is found that the two-bladed turbine has slower wake recovery than the three-bladed turbine, and a larger velocity deficit is produced in the far wake. The tip vortices behind the two-bladed turbine is more stable than behind the three-bladed turbine, and the vortex structures exist further downwind. In a wind farm, this could reduce the power production and increase fatigue loads for the turbines operating in the wake flow, especially during stable atmospheric conditions.

Original language	English
Article number	012027
Journal	Journal of Physics: Conference Series
Volume	1669
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/1669/1/012027
State	Published - 26 Oct 2020
Event	17th Deep Sea Offshore Wind R and D Conference, DeepWind 2020 - Trondheim, Norway Duration: 15 Jan 2020 → 17 Jan 2020

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10.1088/1742-6596/1669/1/012027

Cite this

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title = "Vortex interaction in the wake of a two- And three-bladed wind turbine",

abstract = "The vortex interaction in the wake behind a two- and three-bladed model scale wind turbine is investigated. The two rotors have equal solidity, and produce similar power and thrust at the design tip speed ratio. Phase-averaged quantities of the wake flow from one to four rotor diameters behind the turbines are measured in a wind tunnel. It is found that the two-bladed turbine has slower wake recovery than the three-bladed turbine, and a larger velocity deficit is produced in the far wake. The tip vortices behind the two-bladed turbine is more stable than behind the three-bladed turbine, and the vortex structures exist further downwind. In a wind farm, this could reduce the power production and increase fatigue loads for the turbines operating in the wake flow, especially during stable atmospheric conditions.",

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AU - Bartl, Jan

AU - Hansen, Thomas H.

AU - Ludwig Kuhn, W.

AU - Mühle, Franz

AU - Sætran, Lars

N1 - Publisher Copyright: © Published under licence by IOP Publishing Ltd.

PY - 2020/10/26

Y1 - 2020/10/26

N2 - The vortex interaction in the wake behind a two- and three-bladed model scale wind turbine is investigated. The two rotors have equal solidity, and produce similar power and thrust at the design tip speed ratio. Phase-averaged quantities of the wake flow from one to four rotor diameters behind the turbines are measured in a wind tunnel. It is found that the two-bladed turbine has slower wake recovery than the three-bladed turbine, and a larger velocity deficit is produced in the far wake. The tip vortices behind the two-bladed turbine is more stable than behind the three-bladed turbine, and the vortex structures exist further downwind. In a wind farm, this could reduce the power production and increase fatigue loads for the turbines operating in the wake flow, especially during stable atmospheric conditions.

AB - The vortex interaction in the wake behind a two- and three-bladed model scale wind turbine is investigated. The two rotors have equal solidity, and produce similar power and thrust at the design tip speed ratio. Phase-averaged quantities of the wake flow from one to four rotor diameters behind the turbines are measured in a wind tunnel. It is found that the two-bladed turbine has slower wake recovery than the three-bladed turbine, and a larger velocity deficit is produced in the far wake. The tip vortices behind the two-bladed turbine is more stable than behind the three-bladed turbine, and the vortex structures exist further downwind. In a wind farm, this could reduce the power production and increase fatigue loads for the turbines operating in the wake flow, especially during stable atmospheric conditions.

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U2 - 10.1088/1742-6596/1669/1/012027

DO - 10.1088/1742-6596/1669/1/012027

M3 - Conference article

AN - SCOPUS:85079424457

SN - 1742-6588

VL - 1669

JO - Journal of Physics: Conference Series

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T2 - 17th Deep Sea Offshore Wind R and D Conference, DeepWind 2020

Y2 - 15 January 2020 through 17 January 2020

ER -

Vortex interaction in the wake of a two- And three-bladed wind turbine

Abstract

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