Horizontal and Vertical Axis Wind Turbines: Comparisons in Design and Application

1. Horizontal and Vertical Axis Wind Turbines:Comparisons in Design and Application Term Paper Presentation Robert Ty

2. Outline • Introduction • General Aspects of Wind Turbines • History • Basis of Power Generation • VAWT Design Studies • HAWT Design Studies • Pros and Cons of Each Design • Conclusion

3. Introduction • Wind power is the generation of useful energy (usually electricity) from wind energy • Represents an alternative to fossil fuel combustion as a source of energy • In 2001, energy needs of 20 million people were met by global wind power, and estimated to grow to 200 million people by 2020

4. Introduction (2) [Alihan et al., 2009]

5. Wind Power History • 5000 years ago: Sails for boating vessels in Egypt • 900 AD: Windmills, rotating about a vertical axis, used to grind grain and pump water in Persia (Iran) • Middle Ages: Development of horizontal axis windmills in Europe

6. Wind Power History (2) • 1882: First wind turbine used to generate electricity, developed by Charles Brush • 1920’s: 3-bladed turbine produced by Marcellus Jacobs, which has become the standard design of most wind turbines today

7. Wind Power History (3) [Charles F. Brush – Wikipedia, Accessed 02/03/2010] [Jacobs Wind Generator Systems, Accessed 07/03/2010]

8. Wind Power History (4) • 1922: Savonius rotor VAWT, invented by S. J. Savonius • 1931: Darrieus rotor VAWT, invented by Georges Darrieus [Eriksson et al., 2008]

9. Basis of Power Generation • Wind turbines convert the kinetic energy in wind into electric potential energy • P = power (W) • ρ = air density (kg m-3) • A = swept rotor area (m2) • C = wind speed (m s-1) P = 0.5×ρ×A×C3 [Alihan et al., 2009]

10. Basis of Power Generation (2) • Theoretical limit of power capture from wind is 59.3% (Betz Limit) • Inefficiencies due to friction and other losses further reduce the power captured • Coefficient of Performance (Cp) incorporated to reflect the energy captured by the wind turbine P = 0.5×Cp×ρ×A×C3

11. VAWT #1: Savonius Rotor • Savonius Rotor • Two or three ‘scoop’ blades attached to a vertical shaft • Drag force responsible for blade rotation [Islam et al., 2008]

12. VAWT #1: Savonius Rotor (2) • Kamoji et al., 2009 • Improve Cp in Savonius rotors by optimizing overlap ratio (m/D), aspect ratio (H/D), blade arc angle (ψ) and blade shape factor (p/q) [Kamoji et al., 2009]

13. VAWT #1: Savonius Rotor (3) • Tip Speed Ratio (TSR or λ) is the ratio of the speed of the blade’s tip to the speed of incoming wind = ωD/2U [Kamoji et al., 2009]

14. VAWT #1: Savonius Rotor (4) [Kamoji et al., 2009]

15. VAWT #1: Savonius Rotor (5) • Simple Savonius Rotors have low torque at certain rotor angles, causing rotor to not start • Introduction of helical structure can reduce this effect, but efficiency is reduced [Kamoji et al., 2009] [Kamoji et al., 2009b]

16. VAWT #2: Savonius-Darrieus Rotor • Darrieus Rotor • Curved blades forming an egg-beater shape • Lift force responsible for blade rotation • Suffers from low starting torque • Can attach Savonius blades to improve torque [Islam et al., 2008]

17. VAWT #2: Savonius-Darrieus Rotor (2) • Gupta et al., 2008 • Improve Cp in Savonius rotors by combining with a Darrieus rotor • Overlap ratio in Savonius component varied to determine highest Cp [Gupta et al., 2008]

18. VAWT #2: Savonius-Darrieus Rotor (3) Savonius rotor, overlap ratio of zero Savonius-Darrieus rotor, overlap ratio of zero [Gupta et al., 2008]

19. VAWT #2: Savonius-Darrieus Rotor (4) • Overlap ratio of zero produces the highest Cp for the Savonius-Darrieus combination • Higher efficiencies than pure Savonius • Higher starting torque than pure Darrieus [Gupta et al., 2008]

20. HAWT #1: Mie Vanes • Horizontal axis wind turbine • Generally two or three blades • Most common turbine design • Lift force responsible for blade rotation [Basic Aerodynamic Operating Principles of Wind Turbines, Accessed 05/03/2010]

21. HAWT #1: Mie Vanes (2) • Shimizu et al., 2003 • Attach Mie vanes to the blade tips to improve Cp • Determine the effect of number of blades, blade aspect ratio and presence of Mie vanes on Cp [Shimizu et al., 2003]

22. HAWT #1: Mie Vanes (3) • Three-bladed rotor produced a marginally higher maximum Cp, but was smaller at higher λ values • Addition of Mie vanes to a two-bladed rotor increases Cp by 8.75% [Shimizu et al., 2003]

23. HAWT #1: Mie Vanes (4) • Aspect Ratio: (blade length)2/(blade area) • Mie vanes more effective at lower AR’s [Shimizu et al., 2003]

24. HAWT #2: Double-Pitch • Lanzafame and Messina, 2009 • Numerical study to improve upon the design of a HAWT blade • Two current designs • Non-twisted • Twisted [Lanzafame and Messina, 2009]

25. HAWT #2: Double-Pitch (2) • New blade design proposed: two subdivisions in blade • Root section: 12.8° pitch angle • Tip section: 3.8° pitch angle • Sections connected by a winglet [Lanzafame and Messina, 2009]

26. HAWT #2: Double-Pitch (3) • Simulated data vs. past experimental data of the twisted blade design shows a good fit [Lanzafame and Messina, 2009]

27. HAWT #2: Double-Pitch (4) • Simulated results of new blade design shows that it generally performs better than the non-twisted model, but worse than the twisted model • Experimental tests have not been done to validate results [Lanzafame and Messina, 2009]

28. Advantages of VAWT’s/HAWT’s • VAWT’s • Omni-directional • Easier installation and maintenance (components can be built closer to ground) • Simpler safety features • Small VAWT’s suitable for urban areas • Less noise pollution • Lower risk to birds and bats

29. Advantages of VAWT’s/HAWT’s (2) • HAWT’s • Produce more energy (blades can access high-altitude winds) • Generally have greater power efficiencies (0.40 to 0.50) • Can be built offshore (does not use guy wires) • Well-known design: Lower cost of production

30. Conclusions • Wind power has been a useful source of energy for thousands years • Efforts have been made to improve turbine power efficiency • VAWT: Optimization of Savonius and Savonius-Darrieus rotors • HAWT: Mie vanes and Double-pitch blades • HAWT/VAWT designs may be suitable for different size scales and applications

31. End • References • Ahilan, T., Mohammed, K. P., and Arumugham, S. (2009). "A critical review of global wind power generation." American Journal of Applied Sciences, 6(2), 204-213. • Charles F. Brush. <http://en.wikipedia.org/wiki/Charles_F._Brush> Accessed 02/03/2010. • Eriksson, S., Bernhoff, H., and Leijon, M. (2008). "Evaluation of different turbine concepts for wind power." Renewable and Sustainable Energy Reviews, 12(5), 1419-1434. • Gupta, R., Biswas, A., and Sharma, K. K. (2008). "Comparative study of a three-bucket Savonius rotor with a combined three-bucket Savonius-three-bladed Darrieus rotor." Renewable Energy, 33(9), 1974-1981. • Islam, M., Ting, D. S. K., and Fartaj, A. (2008). "Aerodynamic models for Darrieus-type straight-bladed vertical axis wind turbines." Renewable and Sustainable Energy Reviews, 12(4), 1087-1109. • Jacobs Wind Generator Systems. <http://www.wincharger.com/jacobs/index.htm> Accessed 07/03/2010. • Kamoji, M. A., Kedare, S. B., and Prabhu, S. V. (2009). "Experimental investigations on single stage modified Savonius rotor." Applied Energy, 86(7-8), 1064-1073. • Kamoji, M. A., Kedare, S. B., and Prabhu, S. V. (2009b). "Performance tests on helical Savonius rotors." Renewable Energy, 34(3), 521-529. • Lanzafame, R., and Messina, M. (2009). "Design and performance of a double-pitch wind turbine with non-twisted blades." Renewable Energy, 34(5), 1413-1420. • Shimizu, Y., Ismaili, E., Kamada, Y., and Maeda, T. (2003). "Rotor configuration effects on the performance of a HAWT with tip-mounted Mie-type vanes." Journal of Solar Energy Engineering, Transactions of the ASME, 125(4), 441-447.