Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations

Minh Doan; Yuriko Kai; Takuya Kawata; Ivan Alayeto; Shinnosuke Obi

doi:10.1115/FEDSM2021-61338

Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations

Minh Doan, Yuriko Kai, Takuya Kawata, Ivan Alayeto, Shinnosuke Obi

機械工学科

研究成果: Conference contribution

抄録

In 2011, John Dabiri proposed the use of counter-rotating vertical-axis wind turbines to achieve enhanced power output per unit area of a wind farm. Since then, various studies in the wind energy and marine hydrokinetic (MHK) literature have been dedicated to pairs of vertical axis turbines in both co-rotating and counter-rotating configurations, in terms of their power production, wake characterization, and optimal array design. Previous experimental works suggest an enhancement of up to 27.9% in the system power coefficient of pair configurations compared to a single turbine. Additionally, previous numerical studies have indicated that the increased power output is correlated with higher torque on the turbine blades which correspondingly produces a stronger leading edge vortex. This paper presents an extended investigation into a pair of laboratory scaled cross-flow hydrokinetic turbines in counter-rotating configurations. Experiments were conducted to observe, compare, and discuss the leading edge vortex shedding from the turbine blades during their positive torque phase. The turbines operated in a small water flume at the diameter-based Reynolds number of 22,000 with a 0.316 m/s freestream velocity and 4% turbulent intensity. Using a monoscopic particle image velocimetry setup, multiple realizations of the water flow around each blade at their positive torque phase were recorded and phase-averaged. Results show consistent leading vortex shedding at these turbine angles while a correlation between the turbine power performance and the vortex size and strength was observed.

本文言語	English
ホスト出版物のタイトル	Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow
出版社	American Society of Mechanical Engineers (ASME)
ISBN（電子版）	9780791885307
DOI	https://doi.org/10.1115/FEDSM2021-61338
出版ステータス	Published - 2021
イベント	ASME 2021 Fluids Engineering Division Summer Meeting, FEDSM 2021 - Virtual, Online 継続期間: 2021 8月 10 → 2021 8月 12

出版物シリーズ

名前	American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM
巻	3
ISSN（印刷版）	0888-8116

Conference

Conference	ASME 2021 Fluids Engineering Division Summer Meeting, FEDSM 2021
City	Virtual, Online
Period	21/8/10 → 21/8/12

ASJC Scopus subject areas

機械工学

UN SDG

この成果は、次の持続可能な開発目標に貢献しています

文献へのアクセス

10.1115/FEDSM2021-61338

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引用スタイル

Doan, M., Kai, Y., Kawata, T., Alayeto, I., & Obi, S. (2021). Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations. In Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow 記事 A030 (American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM; Vol. 3). American Society of Mechanical Engineers (ASME). https://doi.org/10.1115/FEDSM2021-61338

Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations. / Doan, Minh; Kai, Yuriko; Kawata, Takuya その他.
Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow. American Society of Mechanical Engineers (ASME), 2021. A030 (American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM; Vol. 3).

研究成果: Conference contribution

Doan, M, Kai, Y, Kawata, T, Alayeto, I & Obi, S 2021, Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations. in Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow., A030, American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM, vol. 3, American Society of Mechanical Engineers (ASME), ASME 2021 Fluids Engineering Division Summer Meeting, FEDSM 2021, Virtual, Online, 21/8/10. https://doi.org/10.1115/FEDSM2021-61338

Doan M, Kai Y, Kawata T, Alayeto I, Obi S. Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations. In Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow. American Society of Mechanical Engineers (ASME). 2021. A030. (American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM). doi: 10.1115/FEDSM2021-61338

Doan, Minh ; Kai, Yuriko ; Kawata, Takuya その他. / Observation and discussion of leading edge vortex shedding from laboratory-scaled cross-flow hydrokinetic turbines in counter-rotating configurations. Fluid Mechanics; Micro and Nano Fluid Dynamics; Multiphase Flow. American Society of Mechanical Engineers (ASME), 2021. (American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FEDSM).

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abstract = "In 2011, John Dabiri proposed the use of counter-rotating vertical-axis wind turbines to achieve enhanced power output per unit area of a wind farm. Since then, various studies in the wind energy and marine hydrokinetic (MHK) literature have been dedicated to pairs of vertical axis turbines in both co-rotating and counter-rotating configurations, in terms of their power production, wake characterization, and optimal array design. Previous experimental works suggest an enhancement of up to 27.9% in the system power coefficient of pair configurations compared to a single turbine. Additionally, previous numerical studies have indicated that the increased power output is correlated with higher torque on the turbine blades which correspondingly produces a stronger leading edge vortex. This paper presents an extended investigation into a pair of laboratory scaled cross-flow hydrokinetic turbines in counter-rotating configurations. Experiments were conducted to observe, compare, and discuss the leading edge vortex shedding from the turbine blades during their positive torque phase. The turbines operated in a small water flume at the diameter-based Reynolds number of 22,000 with a 0.316 m/s freestream velocity and 4% turbulent intensity. Using a monoscopic particle image velocimetry setup, multiple realizations of the water flow around each blade at their positive torque phase were recorded and phase-averaged. Results show consistent leading vortex shedding at these turbine angles while a correlation between the turbine power performance and the vortex size and strength was observed.",

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note = "Funding Information: (counter-rotating and overlapping tower), the high tower is offset transversely on the support plate for an additional short tower with another turbine assembly (Fig. 2). Beside the turbine shaft, the short tower includes a neutral shaft and a drivetrain system. Both shafts were supported by a pair of radial ball bearings and a thrust roller bearing. The turbine shaft on the short tower was linked to the neutral shaft via a pair of identical aluminum spur gears. The neutral shaft was then connected to the turbine shaft on the high tower by a pair of timing pulleys and an S2M timing belt. This drivetrain allowed the 2 turbine assemblies to rotate in opposite directions at a synchronized speed. As shown in Fig. 2, the only difference between the counter-rotating and overlapping tower variation was the separation distance between the turbine centers: 1.25Dt and 1.00Dt respectively, where Dt is the rotor Publisher Copyright: {\textcopyright} 2021 American Society of Mechanical Engineers (ASME). All rights reserved.; ASME 2021 Fluids Engineering Division Summer Meeting, FEDSM 2021 ; Conference date: 10-08-2021 Through 12-08-2021",

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N1 - Funding Information: (counter-rotating and overlapping tower), the high tower is offset transversely on the support plate for an additional short tower with another turbine assembly (Fig. 2). Beside the turbine shaft, the short tower includes a neutral shaft and a drivetrain system. Both shafts were supported by a pair of radial ball bearings and a thrust roller bearing. The turbine shaft on the short tower was linked to the neutral shaft via a pair of identical aluminum spur gears. The neutral shaft was then connected to the turbine shaft on the high tower by a pair of timing pulleys and an S2M timing belt. This drivetrain allowed the 2 turbine assemblies to rotate in opposite directions at a synchronized speed. As shown in Fig. 2, the only difference between the counter-rotating and overlapping tower variation was the separation distance between the turbine centers: 1.25Dt and 1.00Dt respectively, where Dt is the rotor Publisher Copyright: © 2021 American Society of Mechanical Engineers (ASME). All rights reserved.

PY - 2021

Y1 - 2021

N2 - In 2011, John Dabiri proposed the use of counter-rotating vertical-axis wind turbines to achieve enhanced power output per unit area of a wind farm. Since then, various studies in the wind energy and marine hydrokinetic (MHK) literature have been dedicated to pairs of vertical axis turbines in both co-rotating and counter-rotating configurations, in terms of their power production, wake characterization, and optimal array design. Previous experimental works suggest an enhancement of up to 27.9% in the system power coefficient of pair configurations compared to a single turbine. Additionally, previous numerical studies have indicated that the increased power output is correlated with higher torque on the turbine blades which correspondingly produces a stronger leading edge vortex. This paper presents an extended investigation into a pair of laboratory scaled cross-flow hydrokinetic turbines in counter-rotating configurations. Experiments were conducted to observe, compare, and discuss the leading edge vortex shedding from the turbine blades during their positive torque phase. The turbines operated in a small water flume at the diameter-based Reynolds number of 22,000 with a 0.316 m/s freestream velocity and 4% turbulent intensity. Using a monoscopic particle image velocimetry setup, multiple realizations of the water flow around each blade at their positive torque phase were recorded and phase-averaged. Results show consistent leading vortex shedding at these turbine angles while a correlation between the turbine power performance and the vortex size and strength was observed.

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