Evaluation of The Potential for Renewable Energy Generation from Floating Solar PV at 9 Hydropower Dams in Thailand

Authors

  • Narongsak Jornsanoh College of Innovation Technology and Engineering, Dhurakij Pundit University
  • Suparatchai Vorarat College of Innovation Technology and Engineering, Dhurakij Pundit University
  • Prayuth Rittidatch College of Innovation Technology and Engineering, Dhurakij Pundit University
  • Aumnad Phdungsilp School of Energy, Environment and Material King Mongkut’s University of Technology Thonburi

Keywords:

floating solar PV, Levelized Cost of Electricity, System Advisor Model, electricity generation, carbon emission

Abstract

This research aims to assess the potential of floating solar PV systems on major hydropower dams in Thailand, as outlined in the Alternative Energy Development Plan (AEDP 2018). The research focuses on nine dams under the management of the Electricity Generating Authority of Thailand--EGAT: Sirindhorn, Bhumibol, Sirikit, Srinagarind, Vajiralongkorn, Ubolratana, Chulabhorn, Ratchaprapha, and Bang Lang. The installation of floating solar PV systems must ensure no adverse impact on the existing hydropower facilities while maximizing electricity generation. Energy output was calculated using the System Advisor Model--SAM, considering variables such as solar resource availability, equipment efficiency, and local climate conditions. Upon completion of all projects in 2037, the simulation results indicate that the floating solar systems across the nine dams could produce an estimated 5,716 GWh/year. Bhumibol Dam achieved the highest annual output of 1,649 MWh and the Lowest Levelized Cost of Electricity--LCOE at 1.44 THB/kWh over 25 years. The floating solar PV systems exhibit minimal carbon dioxide (CO2eq) emissions, primarily concentrated in the manufacturing and installation phases. However, once operational, these systems can reduce CO2eq emissions by approximately 3,001,500 tCO2eq/year, contributing to climate change mitigation and promoting sustainable clean energy usage in the future.

References

Amal, D. F., Budiarto, R., & Prakoso, A. B. (2022). Analysis of performance, carbon emission, and economics on the design of floating photovoltaic in Sambinasi Village, East Nusa Tenggara. 2022 International Conference on Technology and Policy in Energy and Electric Power (ICT-PEP) (pp. 277-282). Jakarta: IEEE

Chirwa, D., Goyal, R., & Mulenga, E. (2023). Floating solar photovoltaic (FSPV) potential in Zambia: Case studies on six hydropower plant reservoirs. Renewable Energy Focus, 44, 344-356. https://doi.org/10.1016/j.psep.2025.107082

Cromratie Clemons, S. K., Salloum, C. R., Herdegen, K. G., Kamens, R. M., & Gheewala, S. H. (2021). Life cycle assessment of a floating photovoltaic system and feasibility for application in Thailand. Renewable Energy, 168, 448-462. https://doi.org/10.1016/j.renene.2020.12.082

Department of Alternative Energy and Energy Conservation. (2021). Map showing the locations of hydropower plants in Thailand. In Alternative Energy Development Plan 2018-2037 (AEDP 2018). Retrieved from https://www.egat.co.th/home (in Thai)

Department of Alternative Energy and Energy Conservation. (2020). Alternative Energy Development Plan 2018-2037 (AEDP 2018). Bangkok: Department of Alternative Energy and Energy Conservation (in Thai)

Electricity Generating Authority of Thailand. (2021). Sirindhorn Dam floating solar project. Retrieved from https://www.egat.co.th/home/en/20211103-pre/ (in Thai)

Electricity Generating Authority of Thailand. (2024). Ubon Ratchathani Dam floating solar project. Retrieved from https://www.egat.co.th/home/en/20240306e/ (in Thai)

Goswami, A. (2023). Effect of humidity on the generation capacity of floating solar photovoltaic system. Jordan Journal of Electrical Engineering, 9(1), 31–41. https://doi.org/10.5455/jjee.204-1667584023

Jornsanoh, N., Vorarat, S., Tantawat, W., & Rittidatch, P. (2023). The Bibliometric Analysis of Electricity Generation from Floating Solar, 2023 International Conference on Power, Energy and Innovations (ICPEI 2023) (pp. 107-123). Thailand: IEEE (in Thai)

Lee, N., Grunwald, U., Rosenlieb, E., Mirletz, H., Aznar, A., Spencer, R., & Cox, S. (2020). Hybrid floating solar photovoltaics-hydropower systems: Benefits and global assessment of technical potential. Renewable Energy, 162, 1415–1427. https://doi.org/10.1016/j.renene.2020.08.080

Maraj, A., Kërtusha, X., & Lushnjari, A. (2022). Energy performance evaluation for a floating photovoltaic system located on the reservoir of a hydro power plant under the Mediterranean climate conditions during a sunny day and a cloudy one. Energy Conversion and Management: X, 16, 100275. https://doi.org/10.1016/j.ecmx.2022.100275

Makhija, S. P., Dubey, S. P., Bansal, R. C., & Jena, P. K. (2021). Techno-environ-economical analysis of floating PV/on-ground PV/grid extension systems for electrification of a remote area in India. Technology and Economics of Smart Grids and Sustainable Energy, 6, 1–10. https://repository.up.ac.za/handle/2263/88121

NASA. (2020). Climate change: Evidence and causes. Retrieved from https://climate.nasa.gov/evidence/

National Renewable Energy Laboratory. (2022). System advisor model (Version 2013.12.17). Retrieved from https://sam.nrel.gov/ (in Thai)

Ramasamy, V., & Margolis, R. (2021). Floating photovoltaic system cost benchmark: Q1 2021 installations on artificial water bodies (Report no. NREL/TP-7A40-80695). USA: National Renewable Energy Laboratory.

Sahu, A. K., & Sudhakar, K. (2019). Effect of UV exposure on bimodal HDPE floats for floating solar application. Journal of Materials Research and Technology, 8(1), 147–156. https://doi.org/10.1016/j.jmrt.2017.10.002

Sapthanakorn, P., & Salakij, S. (2021). Evaluating the potential of using floating solar photovoltaic on 12 reservoirs of electricity generation authority of Thailand hydropower plants. 2021 International Conference on Smart City and Green Energy (ICSCGE) (pp. 41-45). China: IEEE

Sarker, S. K., Islam, M. T., & Moniruzzaman, M. (2021). Techno-economic analysis of floating solar PV integrating with hydropower plant in Bangladesh. IEEE Green Technologies Conference (pp. 30-36). USA: IEEE

SunPower Corporation. (2021). SunPower SPR-X22-485-COM: Technical specification datasheet. Retrieved from https://www.sunpower.com

Sungrow Power Supply Co., Ltd. (2021). Sunglow Power SC1725UD-US: Inverter technical specification. Retrieved from https://www.sungrowpower.com

Thailand Greenhouse Gas Management Organization (Public Organization), Carbon Credit Certification Office. (2022). Annual greenhouse gas emission reduction report 2022. Retrieved from https://www.tgo.or.th (in Thai)

World Bank Group, & Solar Energy Research Institute of Singapore. (2019). Where sun meets water: Floating solar handbook for practitioners. Washington, DC: World Bank.

Downloads

Published

2025-04-21

How to Cite

Jornsanoh, N. ., Vorarat, S. ., Rittidatch, P. ., & Phdungsilp, A. . (2025). Evaluation of The Potential for Renewable Energy Generation from Floating Solar PV at 9 Hydropower Dams in Thailand . EAU Heritage Journal Science and Technology (Online), 19(1), 175–190. retrieved from https://he01.tci-thaijo.org/index.php/EAUHJSci/article/view/273660

Issue

Vol. 19 No. 1 (2025): January-April

Section

Research Articles

License

บทความใน “วารสาร EAU HERITAGE” เป็นความเห็นของผู้เขียนโดยเฉพาะ กองบรรณาธิการไม่มีส่วนในความคิดเห็นในข้อความเหล่านั้น