The Gravitational Water Vortex Power Plant (GWVPP) is a small-scale hydroelectric power generator that makes use of the energy generated from a vortex flow to turn turbine blades and generate electricity. In this research study, the focus was on the numerical analysis of the basin design of the GWVPP, which is divided into three sections: vortex generator section, transformer section, and turbine section. To support the transformation process from tangential vortex speed to axial vortex speed in the transformer section, a damper plate was installed to direct the rotating flow. The effect of the nozzle in accelerating the flow for optimizing the basin design was also studied to reduce blockage caused by the transformation process. The numerical results indicate that designs with nozzle have lower velocity outputs due to blockage from the rotating flow. At flow rate of 0.1 m3/s, the presence of damper plate reduces the maximum flow rotation, but at flow rate of 0.2 m3/s, it prevents flow leakage on the surface. The basin design without damper plate and nozzle is the optimal variation for flow rates of 0.1 m3/s, while the design with damper plate but without nozzle is optimal for flow rates of 0.2 m3/s.

Gravitational water vortex power plant (GWVPP); transformer section; damper plate; nozzle

BPS, “Rata-rata harian aliran sungai, tinggi aliran, dan volume air di beberapa sungai yang daerah pengalirannya lebih dari 100 km persegi.” pp. 6–8, 2015. https://www.bps.go.id/statictable/2017/11/14/1984/.

K. Brown, “Power generating method and apparatus,” 1968.

A. B. Timilsina, S. Mulligan, and T. R. Bajracharya, “Water vortex hydropower technology: a state-ofthe-art review of developmental trends,” Clean Technologies and Environmental Policy, vol. 20, no. 8, pp. 1737–1760, 2018.

S. Wanchat, R. Suntivarakorn, S. Wanchat, K. Tonmit, and P. Kayanyiem, “A parametric study of a gravitation vortex power plant,” in Advanced Materials Research, vol. 805–806, pp. 811–817, Trans Tech Publ, May 2013.

C. Power, A. McNabola, and P. Coughlan, “A parametric experimental investigation of the operating conditions of gravitational vortex hydropower (GVHP),” Journal of Clean Energy Technologies, vol. 4, no. 2, pp. 112–119, 2016.

S. Dhakal, A. B. Timilsina, R. Dhakal, D. Fuyal, T. R. Bajracharya, H. P. Pandit, N. Amatya, and A. M. Nakarmi, “Comparison of cylindrical and conical basins with optimum position of runner: Gravitational water vortex power plant,” Renewable and Sustainable Energy Reviews, vol. 48, pp. 662–669, Aug. 2015.

R. Dhakal, S. Shrestha, H. Neupane, S. Adhikari, and T. Bajracharya, “Inlet and outlet geometrical condition for optimal installation of gravitational water vortex power plant with conical basin structure,” in Recent Advances in Mechanical Infrastructure: Proceedings of ICRAM 2019, pp. 163–174, Springer, Nov. 2020.

E. M. Wardhana, A. Santoso, and A. R. Ramdani, “Analysis of gottingen 428 airfoil turbine propeller design with computational fluid dynamics method on gravitational water vortex power plant,” International Journal of Marine Engineering Innovation and Research, vol. 3, no. 3, 2019.

D. Powalla, S. Hoerner, O. Cleynen, N. Müller, J. Stamm, and D. Thévenin, “A computational fluid dynamics model for a water vortex power plant as platform for etho-and ecohydraulic research,” Energies, vol. 14, no. 3, p. 639, 2021.

H. K. Versteeg, W. Malalasekera, G. Orsi, J. H. Ferziger, A. W. Date, and J. D. Anderson, “An introduction to computational fluid dynamics: the finite volume method.” Harlow Essex: Longman Group Ltd., 1995.

ANSYS Fluent, ANSYS Fluent Theory Guide, Nov. 2013. ANSYS Inc., USA, pp. 724–746.