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[2] Fang, W., Huang, Q., Huang, S., Yang, J., Meng, E. & Li, Y., Optimal sizing of utility-scale photovoltaic power generation complementarily operating with hydropower: A case study of the world’s largest hydro-photovoltaic plant. Energy Conversion and Management, 136, pp. 161–172, 2017. [Crossref]
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Open Access
Research article

Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential

Jair Arone Maués
Petrobras Gas & Power Area, Brazil
International Journal of Energy Production and Management
|
Volume 4, Issue 1, 2019
|
Pages 40-52
Received: N/A,
Revised: N/A,
Accepted: N/A,
Available online: N/A
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Abstract:

Photovoltaic (PV) solar farms and hydropower stations can create a plant that do more than the two resources acting independently as long as, with the addition of a solar project, hydroelectric plants increase its annual availability of power and economic efficiency, taking advantage of the storage capacity of energy that a hydroelectric reservoir can provide. The objective of this paper is to investigate the potential of Brazilian hydropower plants regarding these issues using the large amount of available data recorded. There exists a potential increase in the energy production of 53.3 TWh per year based on the proposed optimized solution for the Brazilian hydropower stations with significant water storage capacities assessed in this paper. This energy is equivalent to an additional capacity factor of approximately 20% to the original 31.5 GW installed hydro capacity or almost 10% of the Brazilian electricity demand in 2018. This result would be at the expenses of a huge deployment of 34 GW of solar PV floating power plants installed close to the reservoir dams that must yet prove to be economically feasible. However, on the other hand, this proposal can create a virtuous cycle for the solar industry in Brazil and speed up the viability of solar cell costs, since setting up and connecting the PV plants are greatly simplified when done in existing hydropower stations facilities.

Keywords: energy storage, floating photovoltaic, hybrid power plant, hydropower
Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

References
[1] Chamber of Commercialization of Electric Energy - CCEE. Market Information. Consolidated Data. http://www.ccee.org.br/ (accessed 15 January 2019).
[2] Fang, W., Huang, Q., Huang, S., Yang, J., Meng, E. & Li, Y., Optimal sizing of utility-scale photovoltaic power generation complementarily operating with hydropower: A case study of the world’s largest hydro-photovoltaic plant. Energy Conversion and Management, 136, pp. 161–172, 2017. [Crossref]
[3] Energy Research Company. Statistical Yearbook of electricity. http://www.epe.gov.br/ (accessed 15 January 2019).
[4] Electrical System National Operator - ONS. Operational History. http://www.ons.org.br/ (accessed 25 January 2019).
[5] Farfan, J. & Breyer, C., Combining floating solar photovoltaic power plants and hydropower reservoirs: A virtual battery of great global potential. Energy Procedia, 155, pp. 403–411, 2018. [Crossref]
[6] Perez, M., Perez, R., Ferguson, C.R. & Schlemmer, J., Deploying effectively dispatch- able PV on reservoirs: Comparing floating PV to other renewable technologies. Solar Energy, 174, pp. 837–847, 2018. [Crossref]
[7] Solarplaza International BV, https://www.solarplaza.com/channels/top-10s/?page=2
[8] International Energy Agency – IEA. Technology Roadmap, Solar Thermal Electricity, 2014.
[9] Lemos, L.F.L., Starke, A.R., Boland, J., Cardemil, J.M., Machado, R.D. & Colle, S., Assessment of solar radiation components in Brazil using the BRL model. Renewable Energy, 108, pp. 569–580, 2017. [Crossref]
[10] NREL - National Renewable Energy Laboratory - U.S. Department of Energy, https:// maps.nrel.gov/swera/
[11] Lopez-Garcia, J. & Tony Sample, T., Evolution of measured module characteristics versus labelled module characteristics of crystalline silicon based PV modules. Solar Energy, 160, pp. 252–259, 2018. [Crossref]
[12] International Finance Corporation - IFC. A Project Developer’s Guide to Utility-scale Solar Photovoltaic Power Plants, 2015.
[13] International Energy Agency - IEA. Photovoltaic Power Systems Program - Energy from the Desert: Very Large Scale PV Power Plants for Shifting to Renewable Energy Future. External Final Report IEA-PVPS, 2015.
[14] Technical Bulletin ONS. 2nd Quarterly Revision of Electric Demand Forecasting in the National Interconnected System 2018–2022.
[15] Electrical System National Operator - ONS. Energy Operating Plan 2018/2022.
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Maués, J. A. (2019). Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential. Int. J. Energy Prod. Manag., 4(1), 40-52. https://doi.org/10.2495/EQ-V4-N1-40-52
J. A. Maués, "Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential," Int. J. Energy Prod. Manag., vol. 4, no. 1, pp. 40-52, 2019. https://doi.org/10.2495/EQ-V4-N1-40-52
@research-article{Maués2019FloatingSP,
title={Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential},
author={Jair Arone MauéS},
journal={International Journal of Energy Production and Management},
year={2019},
page={40-52},
doi={https://doi.org/10.2495/EQ-V4-N1-40-52}
}
Jair Arone MauéS, et al. "Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential." International Journal of Energy Production and Management, v 4, pp 40-52. doi: https://doi.org/10.2495/EQ-V4-N1-40-52
Jair Arone MauéS. "Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential." International Journal of Energy Production and Management, 4, (2019): 40-52. doi: https://doi.org/10.2495/EQ-V4-N1-40-52
MAUÉS J A. Floating Solar PV—Hydroelectric Power Plants in Brazil: Energy Storage Solution with Great Application Potential[J]. International Journal of Energy Production and Management, 2019, 4(1): 40-52. https://doi.org/10.2495/EQ-V4-N1-40-52