The impact of trailing edge flap on the aerodynamic performance of small-scale horizontal axis wind turbine

The impact of trailing edge flap on the aerodynamic performance of small-scale horizontal axis wind turbine

•Integration of fixed trailing edge flap in HAWT blade profile is investigated.•Blade element momentum and CFD approaches were utilized in the study.•Power coefficient of the new blade profile is found 8.3% higher.•HAWT with the new blade profile provides 566 kWh/year higher annual yield. Despite th...

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Bibliographic Details
Published in:Energy conversion and management Vol. 256; p. 115396
Main Authors: Mansi, Aktham, Aydin, Devrim
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 15-03-2022
Elsevier Science Ltd
Subjects:
Aerodynamics
Blade element momentum (BEM)
Computational fluid dynamics
Computational fluid dynamics (CFD)
Computer applications
Design
Drag coefficients
Fluid dynamics
Horizontal Axis Wind Turbines
Hydrodynamics
Performance enhancement
QBlade
Three dimensional analysis
Tip speed
Trailing edge flap
Trailing edge flaps
Turbines
Weibull distribution
Wind power
Wind speed
Wind turbine
Blade element momentum (BEM)
QBlade
Trailing edge flap
Wind turbine
Computational fluid dynamics (CFD)
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Summary:•Integration of fixed trailing edge flap in HAWT blade profile is investigated.•Blade element momentum and CFD approaches were utilized in the study.•Power coefficient of the new blade profile is found 8.3% higher.•HAWT with the new blade profile provides 566 kWh/year higher annual yield. Despite the significant progress in the wind energy field, there is always space for new blade profiles to improve the efficiency and the energy extracted of HAWTs. To improve the performance of small-scale HAWTs, a new blade profile design using a fixed trailing-edge flap was investigated using blade element momentum (BEM) approach and validated using computational fluid dynamics (CFD) approach. The aim of this study is to obtain a new blade profile which has higher lift-to-drag coefficient for wind turbine by integrating a trailing-edge flap into a reference blade design. To determine the optimal blade profile, the annual yield based on the Weibull distribution is used. The full three-dimensional CFD analyses were performed on the new blade profile only. The BEM results show that at the design tip speed ratio of 7, the power coefficient of the new blade profile is 8.3% higher than the reference design. According to the new blade profile, the CFD method over-predicts the power coefficient compared with the BEM method. According to wind speed distribution in Turkey, the annual yield of the wind turbine with the reference blade profile and the new blade profile was found as 6378 kWh/year and 6944 kWh/year, respectively.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2022.115396