Application of Savonius Type Turbine Technology for The Conversion of Low Speed Wind into Electrical Energy at Wong Polo Beach Kota Pari Village Indonesia
DOI:
https://doi.org/10.37385/jaets.v3i2.813Keywords:
Speed, Turbine, Beach, Energy, WindAbstract
Utilization of the potential that exists in tourist attractions aims to increase the savings in expenses that must be borne by the community to manage tourism. The beach is a place that is rich and abundant in wind potential that can be used to drive wind turbines. To take advantage of the existing wind potential, of course, we must know how the wind potential is in the form of wind speed and locations that have wind speed potential and how to use it as energy to drive wind turbines. To obtain the potential of wind energy and utilize it, wind speed measurements are carried out using a digital anemometer and recorded for some time. The position of the measuring instrument installed must be protected from wind obstacles so that it is installed as high as 20 meters above the ground in an open position against the direction of the incoming wind. From the measurement results over a period of one day, the wind speed varies and changes at any time and the maximum value is 6 m/s during the day starting at 10:00 to 04:00. The wind speed profile obtained is analyzed and the type of turbine is determined according to the low wind speed below 10 m/s. From the analysis results, the appropriate turbine is the Savonius VAWT type and can produce electrical energy of approximately 2.43 Watts with a diameter of 0.11 m. The use of turbines for wind at low speeds will still have the potential to generate small-scale electrical energy for communities in coastal areas
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References
Altmimi, A. I., Alaskari, M., Abdullah, O. I., Alhamadani, A., & Sherza, J. S. (2021). Design and Optimization of Vertical Axis Wind Turbines Using QBlade. 1–11.
Chang, T.-L., Tsai, S.-F., & Chen, C.-L. (2021). Optimal Design of Novel Blade Profile for Savonius. https://doi.org/https://doi.org/10.3390/en14123484
Darhmaoui, H., & Sheikh, N. (2017). Savonius Vertical Wind Turbine?: Design , Simulation , and Physical Testing. (May).
Dhote, A. (2015). Design, Analysis And Fabrication of Savonius Vertical Axis Wind Turbine. 2048–2054.
Domingos S.L. Simonetti, ... Flávio D.C. Oliveira. (2018). Doubly Fed Induction Generator in Wind Energy Conversion Systems.
E. Hau. (2015). Wind turbines. In Fluid Mechanics and its Applications. Vol. 109. https://doi.org/https://doi.org/10.1007/978-94-017-9627-9_10
Elmostafa Chetouani, ... Smail Sahnoun. (2021). Maximum power point tracking design using particle swarm optimization algorithm for wind energy conversion system connected to the grid.
Handoko, A. D. W. I. (2019). Semi-Inversed Taper Type For Low Wind Speed. Surya University Faculty of Engineering: Tangerang.
International, Rets. ®. (2004). Clean Energy Project Analysis?: Wind Energy.
Mishra, N., Jain, A., Nair, A., Khanna, B., & Mitra, S. (2020). Numerical and Experimental Investigations on a Dimpled Savonius Vertical Axis Wind Turbine. 10(2).
Mudathir Funsho Akorede. (2022). Design and performance analysis of off-grid hybrid renewable energy systems.
Nurdin, H., & Purwanto, W. (2019). Characteristics of Hemi Savonius Windmill with Multi-Level Blades as a Model of Energy Conversion Systems for Windmill Techno Park on the Coastal Areas. 88–95. https://doi.org/10.9790/1813-0801018895
Patel, M. R. (2005). Wind and solar power systems: Design, analysis, and operation, second edition. Wind and Solar Power Systems: Design, Analysis, and Operation, Second Edition, 1–448. https://doi.org/10.2134/jeq2006.0001br
Patnaik, I. (2009). Wind as a renewable source of energy. (10502038).
Science, E. (2021). Wind energy conversion within agricultural farm using vertical axis turbines of optimized SAVONIUS type Wind energy conversion within agricultural farm using vertical axis turbines of optimized SAVONIUS type. https://doi.org/10.1088/1755-1315/635/1/012015
Shah, M. H., Alsibiani, S. A., & City, Y. I. (2020). Design and construction of savonius rotor. 65–77.
Sharma, S., Sellami, N., Tahir, A. A., & Mallick, T. K. (2021). Performance Improvement of a CPV System?: Experimental. Energies Article.
Soderholm, L. H. (1984). Autonomous and Grid-connected Use of Wind Energy for Structure Heating.
Troen I., P. E. L. . (1989). European Wind Atlas. Risø National Laboratory,.
Wiley, J. (2008). from Large Offshore Wind Farms. (October 2007), 29–43. https://doi.org/10.1002/we.246
Yohana, E., U, M. S. K. T. S., Luhung, B., Reza, M. J., & Zaman, M. B. (2019). Experimental Study of Wind Booster Addition for Savonius Vertical Wind Turbine of Two Blades Variations Using Low Wind Speed. 3(2019).