The inconsistency of the wind flow considered as one of the factors which tend to decrease the performance of the wind turbine. This paper proposes a further analysis of the initial rotation characteristic of a hybrid Savonius - Darrieus wind turbine. The addition of the Darrieus blade intends to increase the aerodynamic stability of the overlapping Savonius turbine. This study implements 2D CFD transient analysis using the 6DOF methods in 0⁰, 30⁰, 60⁰, and 90⁰ Darrieus blade position along with 2 m/s, 4 m/s, and 6 m/s wind speed variations. The results of the aerodynamic analysis show that the location of the Darrieus 30⁰ turbine provides the greatest initial repulsion, especially when the turbine rotation is above 90⁰, the position of the Darrieus blade can provide additional impulse force when the Savonius turbine tends to be passive. This effect occurs more significant at higher wind speeds. Savonius with 3-blade modification has a more stable level of force distribution than the 2-blade modification, although the value is smaller. This shows that the 3-blade Savonius provide a higher stability of angular velocity development.

N. Halsey, “Geometry of the Twisted Savonius Wind Turbine,” Geometrically Modeling the Twisted Savonius Wind Turbine. [Online]. Available:

http://celloexpressions.com/ts/dynamic-documentation/intro/. [diakses: Mei 2019]

M. Óskarsdóttir “A General Description and Comparison of Horizontal Axis Wind Turbines and Vertical Axis Wind Turbines,” University of Iceland, 2014.

M. H. Ali. "Experimental Comparison Study for Savonius Wind Turbine of Two & Three Blades At Low Wind Speed." International Journal of Modern Engineering Research (IJMER). vol. 3, no. 5, pp-2978-2986, 2013.

D. Ashwin, and V. Bankar. "Design, Analysis And Fabrication Of Savonius Vertical Axis Wind Turbine." International Research Journal of Engineering and Technology (IRJET). vol. 02 no. 03,2015

B. Purwono, A. Walid, and Mt, Maskuri. "Simulasi Pengaruh Kecepatan Angin, Putaran Poros dan Variasi Sudu terhadap Daya Listrik Model Pembangkit Listrik Tenaga Bayu (PLTB) Tipe Turbin Angin Vertikal dengan NACA 2412." 2015.

B. Purwono, Masroni, and A. Muqit. "STRATEGI PEMANFAATAN KINCIR ANGIN SUMBU VERTIKAL TIPE NACA 3412." 2017.

A. Murdani et al., "Flexural Properties and Vibration Behavior of Jute/Glass/Carbon Fiber Reinforced Unsaturated Polyester Hybrid Composites for Wind Turbine Blade", Key Engineering Materials, vol. 748, pp. 62-68, 2017.

G. J. Herbert, S. Iniyan, E. Sreevalsan, and S. Rajapandian, “A review of wind energy technologies,” Renewable and Sustainable Energy Reviews, vol.11, no. 6, pp. 1117–1145, 2007.

K. Pope, I. Dincer, and G. Naterer, “Energy and exergy efficiency comparison of horizontal and vertical axis wind turbines,” Renewable Energy, vol. 35, no. 9, pp. 2102–2113, 2010

Wang, Xin & Luo, Xianwu & Zhuang, Baotang & Yu, Weiping & Xu, Hongyuan. "6-DOF Numerical Simulation of the Vertical-Axis Water Turbine." ASME-JSME-KSME 2011 Joint Fluids Engineering Conference, 2011.

F. Thönnißen, M. Marnett, B. Roidl, and W. Schröder, “A numerical analysis to evaluate Betz's Law for vertical axis wind turbines,” Journal of Physics: Conference Series, vol. 753, pp. 022056, 2016.

K. Witono, Moh. Nasir, E. Faizal, H. Wicaksono, B. Pranoto. "Pengaruh Model Sudu Overlap dan Helix pada Proses Inisiasi Putaran Turbin Savonius." Jurnal Otopro. vol. 15, no. 1, pp. 27-31, 2019.