Savonius wind turbine with Bach-profile blades is considered in this study. Previous studies have shown that a rotor with the Bach-profile blade produces better performance than a standard Savonius turbine. This study focuses on the blade shape factor variations of the Bach-profile blade to give the best performance. Two-dimensional unsteady simulations are performed with moving mesh. The configuration being tested is the Savonius rotor with Bach-profile blades with an arc angle of 135◦ . The blade shape factor is varied 0.2, 0.3, 0.4 at a constant freestream velocity of 4 m/s, with a corresponding Reynolds number of 20,000. The k-ω Shear Stress Transport turbulence model was used, with secondorder discretization schemes for the pressure and momentum equations. The boundary conditions were set as velocity inlet for the inlet, outflow for the outlet, and walls for the blade surfaces. The top and bottom sides were set as symmetric. Results showed that the configuration with a shape factor of 0.4 gave the best performance among the others. This configuration gave a higher moment coefficient and power coefficient of about 6.8% and 7.3%, respectively. Results extracted from the simulation includes the flow structure, and the distribution of the pressure coefficients along the blade surface.

D. Siswanto and S. Mujiyanto, Indonesia Energy Out look. Secretariat General National Energy Council, 2019. [2] R. Mulyana, Energi Baru Terbarukan dan Konservasi Energi 2019. Ditjen EBTKE Kementrian ESDM, 2019.

J. V. Akwa, H. A. Vielmo, and A. P. Petry, “A review on the performance of Savonius wind turbines,” Re newable and sustainable energy reviews, vol. 16, no. 5, pp. 3054–3064, 2012.

M. Kamoji, S. B. Kedare, and S. Prabhu, “Experimen tal investigations on single stage modified Savonius rotor,” Applied Energy, vol. 86, no. 7-8, pp. 1064– 1073, 2009.

A. Kumar and R. Saini, “Performance analysis of a single stage modified Savonius hydrokinetic turbine having twisted blades,” Renewable Energy, vol. 113, pp. 461–478, 2017.

R. Sarath Kumar, T. Micha Premkumar, S. Seralathan, and T. Mohan, “Numerical investigation of modified Bach type vertical axis wind turbine,” in Applied Me chanics and Materials, vol. 852, pp. 551–557, Trans Tech Publ, 2016.

V. S. Djanali, Z. Fathurrahman, B. A. Dwiyantoro, and N. Ikhwan, “Numerical study of Savonius wind turbines with standard and Bach-profile blade vari ations,” in AIP Conference Proceedings, vol. 2187, p. 020041, AIP Publishing LLC, 2019.

K. Kacprzak, G. Liskiewicz, and K. Sobczak, “Nu merical investigation of conventional and modified Savonius wind turbines,” Renewable energy, vol. 60, pp. 578–585, 2013.

K. Kacprzak and K. Sobczak, “Numerical analysis of the flow around the Bach-type Savonius wind turbine,” in Journal of Physics: Conference Series, vol. 530, p. 012063, IOP Publishing, 2014.

T. Yuwono, G. Sakti, F. N. Aulia, and A. C. Wijaya, “Improving the performance of Savonius wind tur bine by installation of a circular cylinder upstream of returning turbine blade,” Alexandria Engineering Journal, vol. 59, no. 6, pp. 4923–4932, 2020.

H. A. H. Saeed, A. M. N. Elmekawy, and S. Z. Kassab, “Numerical study of improving Savonius turbine power coefficient by various blade shapes,” Alexan dria Engineering Journal, vol. 58, no. 2, pp. 429–441, 2019.

N. Alom, B. Borah, and U. K. Saha, “An insight into the drag and lift characteristics of modified Bach and Benesh profiles of Savonius rotor,” Energy Procedia, vol. 144, pp. 50–56, 2018.