Abstract
Wind energy is increasingly becoming a major discussion amongst renewable energy sources due to its sustainability, reduced impact on the environment, and being significantly cheaper than conventional fossil fuels. Researchers have been particularly concerned with studying improved design and optimization using computational technique and experimentation. This research aims at designing blades for a small horizontal axis wind turbine for low Reynolds number using blade element momentum theory and using computational fluid dynamics (cfd) and experiment to analyze its performance. Two airfoils (SG6050 and SG6043) were selected for different regions of the blade span. Four turbulent models were used in predicting its performance. The performance was analyzed for wind speeds between 2 m/s and 7 m/s. Studies showed that the blade is capable of generating power up to 241 W with a power coefficient of 34.3% at a speed of 6 m/s. The computed power coefficient is in good agreement with experimental results of 33.7%.
Issue Section:
Alternative Energy Sources
Keywords:
rotor blade,
tip speed ratio,
blade element momentum theory,
cfd,
3D printing,
alternative energy sources,
renewable energy
Topics:
Airfoils,
Blades,
Rotors,
Wind velocity,
Horizontal axis wind turbines,
Design,
Momentum,
Turbulence
References
1.
World Energy Scenarios
, 2019
, “Pathways, Exploring Innovation,” World Energy Scenarios Report
.2.
Drachmann
, A. G.
, 1961
, “Heron’s Windmill
,” Centaurus
, 7
(1
), pp. 7
–145
.3.
al-Hassan
, A. Y.
, and Hill
, D. R.
, 1992
, Islamic Technology: An Illustrated History
, Cambridge University Press
, Cambridge, UK
, p. 54
.4.
Hill
, D. R.
, 1991
, “Mechanical Engineering in the Medieval Near East
,” Sci. Am.
, 264
(5
), pp. 64
–69
.5.
Morthorst
, P. E.
, Redlinger
, R. Y.
, and Andersen
, P. H.
, 2002
, Wind Energy in the 21st Century: Economics, Policy, Technology and the Changing Electricity Industry
, Palgrave
, Houndmills, Basingstoke, Hampsh
.6.
Price
, T. J.
, 2004
, Blyth, James (1839–1906)
, Oxford University Press
, Great Clarendon Street, Oxford
.7.
Wyatt
, A.
, 1986
, Electric Power: Challenges and Choices
, Book Press
, Toronto, Ontario
.8.
Anon
, 2010
, Costa Head Experimental Wind Turbine
, Orkney Sustainable Energy Ltd.
, Orkney Sustainable Energy Website
.9.
Giguere
, P.
, Selig
, M. S.
, Giguere
, P.
, and Selig
, M. S.
, 1997
, “Low Reynolds Number Airfoils for Small Horizontal Axis Wind Turbines
,” Wind Engineering
, 21
(6
), pp. 367
–380
.10.
Giguere
, P.
, and Selig
, M. S.
, 1998
, “New Airfoils for Small Horizontal Axis Wind Turbines
,” J. Sol. Ener. Eng.
, 120
(2
), pp. 108
–114
.11.
Gupta
, R. K.
, Warudkar
, V.
, Purohit
, R.
, and Rajpurohit
, S. S.
, 2018
, “Modeling and Aerodynamic Analysis of Small Scale, Mixed Airfoil Horizontal Axis Wind Turbine Blade
,” Mater. Today Proc.
, 4
(4
), pp. 5370
–5384
. 10.1016/j.matpr.2017.05.04912.
Chaudhary
, U.
, Mondal
, P.
, Tripathy
, P.
, Nayak
, S. K.
, and Saha
, U. K.
, 2014
, “Modeling and Optimal Design of Small HAWT Blades for Analyzing the Starting Torque Behavior
,” Eighteenth National Power Systems Conference (NPSC)
, Indian Institute of Technology Guwahati, Guwahati
, India, Dec. 18–20
, pp. 1
–6
.13.
Kody
, S.
, Alpman
, E.
, and Yilmaz
, B.
, 2014
, “Computational Studies of Horizontal Axis Wind Turbines Using Advanced Turbulence Models Özet 2-Turbine Geometry
,” Fen Bilimleri Dergisi
, 26
(2
), pp. 36
–46
. 10.7240/mufbed.0051314.
Bouhelal
, A.
, and Smaili
, A.
, 2016
, “Numerical Study of a Horizontal Axis Wind Turbine Rotor: Assessments of Turbulence Modeling
,” 10èmes Journées de Mécanique de l’EMP (JM’10–EMP)
, Bordj el Bahri
, Algeria, Apr. 12–13
.15.
Koç
, E.
, 2016
, “Comparison of Qblade and CFD Results for Small-Scaled Horizontal Axis Wind Turbine Analysis
,” IEEE International Conference on Renewable Energy Research and Applications (ICRERA)
, Birmingham, UK, Nov. 20-23
.16.
Muiruri
, P. I.
, and Motsamai
, O. S.
, 2018
, “Three Dimensional CFD Simulations of a Wind Turbine Blade Section; Validation
,” J. Eng. Sci. Technol. Rev.
, 11
(1
), pp. 138
–145
. 10.25103/jestr.111.1617.
Mosavati
, B.
, Mosavati
, M.
, and Kowsary
, F.
, 2013
, “Solution of Radiative Inverse Boundary Design Problem in a Combined Radiating-Free Convecting Furnace ☆
,” Int. Commun. Heat Mass Transf.
, 45
(1
), pp. 130
–136
. 10.1016/j.icheatmasstransfer.2013.04.01118.
Mosavati
, B.
, Mosavati
, M.
, and Kowsary
, F.
, 2016
, “Inverse Boundary Design Solution in a Combined Radiating-Free Convecting Furnace Filled With Participating Medium Containing Specularly Reflecting Walls
,” Int. Commun. Heat Mass Transf.
, 76
(1
), pp. 69
–76
. 10.1016/j.icheatmasstransfer.2016.04.02919.
Poole
, S.
, and Phillips
, R.
, 2015
, “Rapid Prototyping of Small Wind Turbine Blades Using Additive Manufacturing
,” Pattern Recognition Association of South Africa and Robotics and Mechatronics International Conference (PRASA-RobMech)
, Nelson Mandela Metropolitan University, Port Elizabeth, South Africa
, Nov. 26–27
, pp. 189
–194
.20.
Lipian
, M.
, and Kulak
, M.
, 2019
, “Fast Track Integration of Computational Methods With Experiments in Small Wind Turbine Development
,” Energies
, 12
(9
), pp. 1625
–1625
.21.
Manwell
, J.
, McGowan
, J.
, and Rogers
, A.
, 2002
, Wind Energy Explained: Theory, Design and Application
, John Wiley & Sons
, Hoboken, NJ
.22.
23.
24.
Menter
, F. R.
, 1992
, “Performance of Popular Turbulence Models for Attached and Separated Adverse Pressure Gradient Flows
,” AIAA J.
, 30
(8
), pp. 2066
–2072
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