The Effect of Nacelle Shape and Blade Geometryon the Performance of Small Scale Wind Turbine-Journal of Sustainability Research-CSCIED科技核心评价数据库-手机版

The Effect of Nacelle Shape and Blade Geometryon the Performance of Small Scale Wind Turbine

The Effect of Nacelle Shape and Blade Geometryon the Performance of Small Scale Wind Turbine

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DOI	10.20900/jsr.20240035
刊名	Journal of Sustainability Research JSR
年，卷(期)	2024, 6(2)
作者	Ahmed M. Daabo*,Shahad S. Ibrahim,Ahmed Khalid,Ali Alkhabbaz,Hudhaifa Hamzah,Ali Basem,Haider K. Easa,Ali Hassan,
作者单位	1 Mining Engineering Department, College of Petroleum and Mining Engineering, The University of Mosul, Mosul 41200, Iraq; 2 Mechanical Engineering Department, College of Engineering, The University of Mosul, Mosul 41200, Iraq; 3 Air Conditioning Engineering Department, Faculty of Engineering, Warith Al-Anbiyaa University, Karbala 56001, Iraq; 4 Department of Computer Engineering Techniques, College of Engineering Technology, Al-Kitab University, Kirkuk 36015, Iraq; 5 School of Computing, Engineering and Digital Technologies, Teesside University, Middlesbrough TS1 3BX, UK
Abstract	In recent years, there has been a significant increase in research efforts aimed at enhancing the efficiency of clean and renewable energy sources, particularly in the field of wind turbine energy. In order to reduce drag forces and maximise power output, a comprehensive analysis was conducted in the current study to investigate the impact of various geometric factors on Small Scale Wind Turbine (SSWT) performance. The effects of blade chamfer shape, pitch angle between blades, nacelle shape, and blade aspect ratio were examined. The analysis was conducted by varying wind speed values while keeping temperatures and atmospheric pressure constant. The Reynoldsaveraged Navier-Stokes (RANS) equations, together with the continuity and momentum equations, are solved using the commercial Computational Fluid Dynamics (CFD) algorithm in Ansys software. The study revealed that the blade chamfer form had the greatest impact on the turbine power output, with the blade pitch angle being the second most critical factor, particularly at higher wind speeds. Moreover, at a velocity of 3 meters per second, the SSWT model demonstrated its peak power output when utilizing a chamfer ratio of 0.25. Conversely, when the wind speed increased to 10 meters per second, the turbine’s maximum power output was observed at a chamferratio of 0.28. These findings demonstrated the significance of using this technology in wind turbines. The model’s achieved power was similarly influenced by the nacelle form and blade aspect ratio, but to a lesser degree.
KeyWord	small scale wind turbine; 3D numerical analysis; parametrical study; nacelle shape; aspect ratio; chamber ratio; pitch angle
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Ahmed M. Daabo*,Shahad S. Ibrahim,Ahmed Khalid,Ali Alkhabbaz,Hudhaifa Hamzah,Ali Basem,Haider K. Easa,Ali Hassan. The Effect of Nacelle Shape and Blade Geometryon the Performance of Small Scale Wind Turbine, Journal of Sustainability Research. 2024; 6; (2). https://doi.org/10.20900/jsr.20240035.

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