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Home > Vol 16, No 3 (2020) > Klabklay

Effect of Closing the Blade Tip on Downwind Thai Sail Windmill

Teerawat Klabklay, Wikanda Sridech

Abstract


Thai sail windmill has been a traditional wind turbine of Thailand, which is a type of horizontal axis wind turbine and now used for pumping the seawater into the salt farms widely in the Samut- Songkhram province for the sea salt production. Currently, the efficiency of the conventional Thai sail windmill is typically quite low that is only approximately 10 percent. Actually, the efficiency of wind turbines depends on many parameters such as blade shape, pitch angle, solidity, wind speed, tip loss, etc. However, this study focused on the tip loss reduction by using technique of closing the blade tip in order to be a guideline for enhancing efficiency. The objective of this study was to investigate the effect of employing technique of closing the blade tip on the efficiency of Thai sail windmill in the fashion of downwind rotor. For experiments, the small scale of 4-blade and 6-blade rotor in the pattern of downwind Thai sail windmill was built and used as a prototype to experiment by using the tow testing method. As a result, the use of technique of closing the blade tip could help the 4-blade rotor increase maximum efficiency from 17 percent into 22 percent at the tip speed ratio of 2.2 and help the 6-blade rotor increase maximum efficiency from 25 percent into 35 percent at the tip speed ratio of 2.0.

Keywords

Thai sail windmill; Wind turbine efficiency; Downwind rotor; Closing the blade tip


[1] P. Mukhia, Performance and Aerodynamic Analysis of The Thai Four Bladed Wooden Rotor Coupled to A Ladder Pump, Master Thesis, Asian Institute of Technology, Thailand. 1981.
[2] T. Klabklay, W. Sridech and T. Chitsomboon, Blade Element Momentum Theory for Estimating Efficiency of Thai sail windmill, The journal of industrial Technology, 2019, 15(3), 93-103. (in Thai).
[3] T. Klabklay and T. Chitsomboon, Efficiency of Upwind and Downwind Thai Sail Windmill, Journal of Engineering and Science Research, 2017, 1(2), 1-6.
[4] R. Thepwong, Design Improvements of Thai Sail Windmill for Water Pumping, Ph.D. Thesis, School of Civil Engineering, Rajamangala University of Technology Rattanakosin. 2013.
[5] T. Klabklay, Optimum Pitch Angle of Downwind Thai Sail Windmill for Maximum Annual Energy Production, Songklanakarin Journal of Science and Technology, 2017, 40(6), 1473-1478.
[6] C. Kress, N. Chokani and R.S. Abhari, Downwind Wind turbine Yaw Stability and Performance, Renewable Energy, 2015, 83, 1157-1165.
[7] A.D. Spera, Wind Turbine Technology: Fundamental Concepts of Wind Turbine Engineering, 2nd ed., ASME Press, NY, USA, 1998.
[8] M.D. Maughmer, Optimization and Characteristics of a Sailwing Windmill Rotor, Final Report/AMS Report No. 1297, Princeton University, New Jersey, USA, 1976.
[9] Q. Song, Design, Fabrication and Testing of A New Small Wind Turbine Blade, Master Thesis, The University of Guelpe, Ontario, Canada, 2012.
[10] L. Prandtl and A. Betz, Vier Abhandlungen zur Hydrodynamik und Aerodynamik, Göttinger Nachr, Göttingen, 1927, 88–92.
[11] W.H. Hucho and G. Sovran, Aerodynamics of Road Vehicles, Annual Review of Fluid Mechanics, 1993, 25, 485-537.
[12] E. Branlard, K. Dixon and M. Gaunaa, Vortex Methods to Answer the Need for Improved Understanding and Modeling of Tip-Loss Factor, IET Renewable Power Generation, 2013, 7(4), 311-320.
[13] T. Klabklay and T. Chitsomboon (2015) Prediction of Thai Sail Windmill Performance by A Blade Element Momentum Theory, The 29th Conference of Mechanical Engineering Network of Thailand, Proceedings, 713-717. (in Thai).
[14] J.L. Tangler, and J.D. Kocurek, Wind Turbine Post-Stall Airfoil Performance Characteristics Guidelines for Blade-element Momentum Methods, Technical Report NREL/CP-500-36900, National Renewable Energy Laboratory, Colorado. 2005.
[15] P.D. Fleming and S.D. Probert, Power Augmentation of Cheap, Sail-Type, Horizontal-Axis Wind-Turbines, Applied Energy, 1982, 12(1), 53-70.
[16] P.D. Fleming, S.D. Probert and S. Arithoppah, Design Optimisation of Cheap Power-Augmentation Devices for a Flexible-Sail, Horizontal-Axis Wind-Turbine, Applied Energy, 1984, 17(3), 169-180.
[17] J. Johensen and N.N. Sorensen, Aerodynamic Investigation of Winglets on Wind Turbine Blades Using CFD, Riso Report Riso-R-1543(EN), Riso National Laboratory, Roskilde, Denmark, 2006.
[18] P.D. Fleming and S.D. Probert, Design and Performance of A Small Shrouded Cretan Wind Wheel, Applied Energy, 1982, 10(2), 121-139.
[19] J.F. Manwell, J.G. McGowan and A.L. Rogers, Wind Energy Explained, 2nd ed., John Wiley & Son, UK, 2009.
[20] Y.A. Cengel, M.A. Boles and M. Kanoglu, Thermodynamics: An Engineering Approach, 9th ed., McGrawHill Education, NY, USA, 2019.

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DOI: 10.14416/j.ind.tech.2020.12.008

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