An Innovative Floating System with a Savonius Rotor as a Horizontal-Axis Wind Turbine

1 Dymarski P. Design of jack-up platform for 6 MW wind turbine: Parametric analysis based dimensioning of platform legs. Polish Maritime Research 26:183-197, 2019. DOI: 10.2478/pomr-2019-00382. Search in Google Scholar

2 Żywicki J, Dymarski P, Ciba E, Dymarski C. Design of structure of tension leg platform for 6 MW offshore wind turbine based on FEM analysis. Polish Maritime Research 24(s1):230-241, 2017. DOI: 10.1515/pomr-2017-00433. Search in Google Scholar

3 Dymarski P, Dymarski C, Ciba E. Stability analysis of the floating offshore wind turbine support structure of cell spar type during its installation. Polish Maritime Research 26, 4(104):109-116, 2019. DOI: 10.2478/pomr-2019-0072. Search in Google Scholar

4 Ciba E, Dymarski P, Grygorowicz M. Analysis of the hydrodynamic properties of the 3-column spar platform for offshore wind turbines. Polish Maritime Research 29:35-42, 2022. DOI: 10.2478/pomr-2022-0015. Search in Google Scholar

5 Santhakumar S, Palanivel I, Venkatasubramanian K. A study on the rotational behaviour of a Savonius wind turbine in low rise highways during different monsoons. Energy for Sustainable Development 40:1-10, 2017. Search in Google Scholar

6 Jia R, Xia H, Zhang S, Su W, Xu S. Optimal design of Savonius wind turbine blade based on support vector regression surrogate model and modified flower pollination algorithm. Energy Conversion and Management 270(5):116247, 2022, DOI: 10.1016/j.enconman.2022.116247. Search in Google Scholar

7 Naik S K, Sachar S, Ianakiev A. Performance analysis of low Reynolds number vertical axis wind turbines using low-fidelity and mid-fidelity methods and wind conditions in the city of Nottingham. Energy. 279:127904, 2023, DOI: 10.1016/j. energy.2023.127904127904. Search in Google Scholar

8 Al-Bahadly I. Building a wind turbine for rural home. Energy for Sustainable Development 13(3):159-165, 2009. Search in Google Scholar

9 Akwa J V, Alves da Silva Jr. G, Prisco Petry A. Discussion on the verification of the overlap ratio influence on performance coefficients of a Savonius wind rotor using computational fluid dynamics. Renewable Energy 38(1):141-149, 2012. DOI: 10.1016/j.renene.2011.07.013. Search in Google Scholar

10 Sukanta R, Antoine Ducoin D. Unsteady analysis on the instantaneous forces and moment arms acting on a novel Savonius-style wind turbine. Energy Conversion and Management 121:281-296, 2016. DOI: /10.1016/j. enconman.2016.05.044. Search in Google Scholar

11 Doerffer K, Telega J, Doerffer P, Hercel P, Tomporowski A. Dependence of power characteristics on Savonius rotor segmentation. Energies 14:2912, 2021. DOI: 10.3390/ en14102912. Search in Google Scholar

12 Sachar S, Doerffer P, Flaszynski P, Kotus J, Doerffer K, Grzelak J. Correlation between the generated noise and effectiveness for a vertical axis Savonius type rotor. In AIAA SCITECH 2023 Forum, p. 0611, 2023. DOI: 10.2514/6.2023-0611. Search in Google Scholar

13 Doerffer P, Doerffer K, Ochrymiuk T, Telega J. Variable size twin-rotor wind turbine. Energies 12:2543, 2019. DOI:10.3390/en12132543. Search in Google Scholar

14 A traditional Savonius rotor. Retrieved from https://www.researchgate.net/figure/A-traditional-Savonius-rotor-46_fig8_322845539. Search in Google Scholar

15 Betz A. Introduction to the theory of flow machines. (D. G. Randall, Trans.). Pergamon Press; 1966. Search in Google Scholar

16 Journee J M M, Massie W W. Offshore hydromechanics. Delft University of Technology; 2001. Search in Google Scholar

17 Beyer W H (Ed.). CRC standard mathematical tables, 28th ed. CRC Press; 1987. Search in Google Scholar

18 Comstock J. Principles of naval architecture. Society of Naval Architects and Marine Engineers; 1967. Search in Google Scholar

19 Haas A E. Introduction to theoretical physics. Van Nostrand; 1928. Search in Google Scholar

20 Jurdziński M. Planowanie Kotwiczenia Dużych Statków Na Głębokich Kotwicowiskach. Zeszyty Naukowe Akademii Morskiej w Gdyni, nr 92, 2015. [Anchor Planning for Large Vessels in Deep Anchorages - Scientific Notebooks] Search in Google Scholar

21 Rules for the classification and construction of sea-going ships, Part III: Hull equipment. PRS; 2023. Search in Google Scholar

22 KIM Liny i Zawiesia. Retrieved from https://linystalowe.pl/oferta/łańcuchy/. [Ropes and slings] Search in Google Scholar

23 Sheldahl, R.E., Feltz, L.V., Blackwell, B.F., 1978. Wind tunnel performance data for two- and three-bucket Savonius rotors. J. Energy 2:160-164. https://doi.org/10.2514/3.47966. Search in Google Scholar