Floating Photovoltaic Solar Systems: Component Selection, Design, Installation, Operation, and Maintenance

Razeghi Jahromi, Dorsa; Gordali, Mohammad Mahdi; Gholami, Aslan; Zandi, Majid

doi:10.22034/jrenew.2025.206117

Floating Photovoltaic Solar Systems: Component Selection, Design, Installation, Operation, and Maintenance

Document Type : Review Article

Authors

Dorsa Razeghi Jahromi ¹

Mohammad Mahdi Gordali ²

Aslan Gholami ³

Majid Zandi ³

¹ B.Sc., Faculty of Mechanical Engineering, Sharif University of Technology, Tehran, Iran

² B.Sc., Faculty of Mechanical and Energy Engineering, Shahid Beheshti University, Tehran, Iran

³ Faculty of Mechanical and Energy Engineering, Shahid Beheshti University, Tehran, Iran

https://doi.org/10.22034/jrenew.2025.206117

Abstract

For installation and the sustainable development of floating solar photovoltaic systems, it is essential to understand their components and possible designs for implementation. Moreover, their proper performance in terms of energy, economic, and environmental factors should be ensured as well as optimized. These types of systems operate in different environments. As a result, selecting components for these systems, and designing as well as implementing their various structures all have their own challenges that either directly or indirectly influence power output, durability, cost, and environmental impact. Even though floating systems are located on the surface of water sources and reservoirs, different cleaning techniques may not be applicable due to the need for high-quality water or certain environmental conditions. This study, therefore, provides a comprehensive guide to selecting components, designing and installing floating photovoltaic solar systems, as well as the necessary conditions for maintenance and different cleaning methods for these systems, by reviewing related research and various implementation plans. By using content analysis, previous studies in this field were reviewed, classified, and evaluated, and the results were prepared for researchers and decision-makers.

Keywords

Solar energy

Photovoltaic

Floating System

Floating Platform

Cleaning Methods

Cleaning Schedule

Subjects

Renewable Energy

- مراجع

[1] A. Aryanfar, A. Gholami, M. Pourgholi, and M. Zandi, Multicriteria wind potential assessment using fuzzy logic in decision making: A case study of Iran, Wind Energy, No. February, p. we.2640, 2021.

[2] A. Aryanfar et al., Multi-criteria prioritization of the renewable power plants in Australia using the fuzzy logic in decision-making method (FMCDM), Clean Energy, Vol. 6, No. 1, pp. 16–34, 2022.

[3] Y. Gholami, A. Gholami, M. Ameri, and M. Zandi, Investigation of Applied Methods of Using Passive Energy In Iranian Traditional Urban Design, Case Study of Kashan, in 4th International Conference on Advances In Mechanical Engineering: ICAME 2018, 2018, pp. 3–12.

[4] E. Akrami, I. Khazaee, and A. Gholami, Comprehensive analysis of a multi-generation energy system by using an energy-exergy methodology for hot water, cooling, power and hydrogen production, Applied Thermal Engineering, Vol. 129, pp. 995–1001, 2018.

[5] A. Minoofar et al., Renewable energy system opportunities: A sustainable solution toward cleaner production and reducing carbon footprint of large-scale dairy farms, Energy Conversion and Management, Vol. 293, p. 117554, 2023.

[6] A. Aryanfar, A. Gholami, M. Pourgholi, S. Shahroozi, M. Zandi, and A. Khosravi, Multi-criteria photovoltaic potential assessment using fuzzy logic in decision-making: A case study of Iran, Sustainable Energy Technologies and Assessments, Vol. 42, No. April, p. 100877, 2020.

[7] S. Eslami, A. Gholami, A. Bakhtiari, M. Zandi, and Y. Noorollahi, Experimental investigation of a multi-generation energy system for a nearly zero-energy park: A solution toward sustainable future, Energy Conversion and Management, Vol. 200, No. May, p. 112107, 2019.

[8] A. Pasandideh, F. Nezakati Rezapour, M. Gholami, and A. Gholami, Analysis of the Discourse of Renewable Electricity Generation in Iran, Global Media Journal-Persian Edition, Vol. 16, No. 1, pp. 101–122, 2022. (in Persian)

[9] R. Cazzaniga, M. Cicu, M. Rosa-Clot, P. Rosa-Clot, G. M. Tina, and C. Ventura, Floating photovoltaic plants: Performance analysis and design solutions, Renewable and Sustainable Energy Reviews, Vol. 81, pp. 1730–1741, 2018.

[10] M. T. Chaichan, H. A. Kazem, N. W. Alnaser, A. Gholami, A. H. A. A. Al-Waeli, and W. E. Alnaser, Assessment Cooling of Photovoltaic Modules Using Underground Water, Arab Gulf Journal of Scientific Research, Vol. 39, No. 2, pp. 151–169, 2021.

[11] M. Kumar, H. Mohammed Niyaz, and R. Gupta, Challenges and opportunities towards the development of floating photovoltaic systems, Solar Energy Materials and Solar Cells, Vol. 233, p. 111408, 2021.

[12] M. Kumar, A. Kumar, and R. Gupta, Comparative degradation analysis of different photovoltaic technologies on experimentally simulated water bodies and estimation of evaporation loss reduction, Progress in Photovoltaics: Research and Applications, Vol. 29, No. 3, pp. 357–378, 2021.

[13] M. Ameri, A. Minoofar, A. Gholami, A. Gholami, S. Eslami, and M. Zandi, Energy Efficiency and Solar Energy Implementation Opportunities for Dairy Farms, in 11th Global Conference on Global Warming (GCGW-2023), 2023, pp. 1–4.

[14] F. Bella, A. Lamberti, S. Bianco, E. Tresso, C. Gerbaldi, and C. F. Pirri, Floating, Flexible Polymeric Dye-Sensitized Solar-Cell Architecture: The Way of Near-Future Photovoltaics, Advanced Materials Technologies, Vol. 1, No. 2, 2016.

[15] W. Huang, K. Zhou, K. Sun, and Z. He, Effects of wind flow structure, particle flow and deposition pattern on photovoltaic energy harvest around a block, Applied Energy, Vol. 253, No. June, p. 113523, 2019.

[16] H. Rauf, M. S. Gull, and N. Arshad, Integrating Floating Solar PV with Hydroelectric Power Plant: Analysis of Ghazi Barotha Reservoir in Pakistan, Energy Procedia, Vol. 158, pp. 816–821, 2019.

[17] M. Acharya and S. Devraj, Floating solar photovoltaic (FSPV): a third pillar to solar PV sector, The Energy and Resources Institute (TERI), 2019.

[18] A. Aryanfar, A. Gholami, M. Pourgholi, M. Zandi, and A. Khosravi, A Type-2 Fuzzy-based Multi-criteria Decision-making Method for Sustainable Development of Wind Power Plants in Iran, Renewable Energy Research and Application, Vol. 2, No. 2, pp. 147–155, 2021.

[19] A. Gholami, M. Ameri, M. Zandi, R. G. Ghoachani, S. Eslami, and S. Pierfederici, Photovoltaic Potential Assessment and Dust Impacts on Photovoltaic Systems in Iran: Review Paper, IEEE Journal of Photovoltaics, Vol. 10, No. 3, pp. 824–837, 2020.

[20] K. Wanghe et al., FRESF model: An ArcGIS toolbox for rapid assessment of the supply, demand, and flow of flood regulation ecosystem services, Ecological Indicators, Vol. 143, p. 109264, 2022.

[21] H. A. Kazem, M. T. Chaichan, A. H. A. Al-Waeli, and A. Gholami, A systematic review of solar photovoltaic energy systems design modelling, algorithms, and software, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, Vol. 44, No. 3, pp. 6709–6736, 2022.

[22] A. Gholami, M. Ameri, M. Zandi, R. Gavagsaz Ghoachani, and H. A. Kazem, Predicting solar photovoltaic electrical output under variable environmental conditions: Modified semi-empirical correlations for dust, Energy for Sustainable Development, Vol. 71, pp. 389–405, 2022.

[23] A. Gholami, M. Ameri, M. Zandi, and R. Gavagsaz Ghoachani, Electrical, thermal and optical modeling of photovoltaic systems: Step-by-step guide and comparative review study, Sustainable Energy Technologies and Assessments, Vol. 49, p. 101711, 2022.

[24] A. Gholami, M. Ameri, M. Zandi, and R. Gavagsaz Ghoachani, A single-diode model for photovoltaic panels in variable environmental conditions: Investigating dust impacts with experimental evaluation, Sustainable Energy Technologies and Assessments, Vol. 47, No. October, p. 101392, 2021.

[25] A. Gholami, M. Ameri, M. Zandi, R. Gavagsaz Ghoachani, and M. Gholami, A Fast and Precise Double-Diode Model for Predicting Photovoltaic Panel Electrical Behavior in Variable Environmental Conditions, International Journal of Ambient Energy, Vol. 44, No. 1, 2022.

[26] S. Eslami, A. Gholami, H. Akhbari, M. Zandi, and Y. Noorollahi, Solar-based multi-generation hybrid energy system; simulation and experimental study, International Journal of Ambient Energy, Vol. 43, No. 1, pp. 2963–2975, 2022.

[27] A. Gholami et al., Impact of harsh weather conditions on solar photovoltaic cell temperature: Experimental analysis and thermal-optical modeling, Solar Energy, Vol. 252, pp. 176–194, 2023.

[28] A. Hoorsun, M. Gandomzadeh, A. Yaghoubi, A. Parsay, A. Gholami, and M. Zandi, Insights and Research Trends of Dust and Cleaning in Solar Energy: A Bibliometric Review Study, in 9th International Conference on Technology and Energy Management (ICTEM 2024 ), 2024, pp. 1–5.

[29] S. A. Alenabi, A. Mansouri, A. Gholami, and R. Gavagsaz-Ghoachani, Simulation of wind flow effect on the cooling of solar panels (in Tehran), in 11th Iranian Conference on Renewable Energy and Distribution Generation (ICREDG), 2024, pp. 1–4.

[30] H. A. Kazem, M. T. Chaichan, A. H. A. Al-Waeli, R. Al-Badi, M. A. Fayad, and A. Gholami, Dust impact on photovoltaic/thermal system in harsh weather conditions, Solar Energy, Vol. 245, No. July, pp. 308–321, 2022.

[31] R. Cazzaniga, Chapter 4 - Floating PV Structures, in: M. Rosa-Clot and G. M. Tina (Eds.), Floating PV Plants, pp. 4.33–4.45, Academic Press, 2020.

[32] D. Chirwa, R. Goyal, and E. Mulenga, Floating solar photovoltaic (FSPV) potential in Zambia: Case studies on six hydropower power plant reservoirs, Renewable Energy Focus, Vol. 44, pp. 344–356, 2023.

[33] M. Rezvani, A. Gholami, R. Gavagsaz-Ghoachani, M. Phattanasak, and M. Zandi, A review of the factors affecting the utilization of solar photovoltaic panels, in 2022 Research, Invention, and Innovation Congress: Innovative Electricals and Electronics (RI2C), 2022, pp. 62–69.

[34] A. Gholami, A. A. Alemrajabi, and A. Saboonchi, Experimental study of self-cleaning property of titanium dioxide and nanospray coatings in solar applications, Solar Energy, Vol. 157, pp. 559–565, 2017.

[35] A. Gholami, S. Eslami, T. Aryan, M. Ameri, R. Gavagsaz-Ghoachani, and M. Zandi, A Review of the Effect of Dust on the Performance of Photovoltaic Panels, Iranian Electric Industry Journal of Quality and Productivity, Vol. 8, No. 15, pp. 93–102, 2019.

[36] A. Gholami, I. Khazaee, S. Eslami, M. Zandi, and E. Akrami, Experimental investigation of dust deposition effects on photo-voltaic output performance, Solar Energy, Vol. 159, pp. 346–352, 2018.

[37] A. Gholami, A. Saboonchi, and A. A. Alemrajabi, Experimental study of factors affecting dust accumulation and their effects on the transmission coefficient of glass for solar applications, Renewable Energy, Vol. 112, pp. 466–473, 2017.

[38] A. Gholami, M. Ameri, M. Zandi, and R. Gavagsaz-Ghoachani, A Review on Dust Activities in Iran and Parameters Affecting Dust Accumulation on Photovoltaic Panels, Journal of Renewable and New Energy, Vol. 8, No. 2, pp. 146–158, 2021.

[39] K. K. Agrawal, S. K. Jha, R. K. Mittal, and S. Vashishtha, Assessment of floating solar PV (FSPV) potential and water conservation: Case study on Rajghat Dam in Uttar Pradesh, India, Energy for Sustainable Development, Vol. 66, pp. 287–295, 2022.

[40] D. Razeghi Jahromi, A. Minoofar, G. Ghorbani, A. Gholami, M. Ameri, and M. Zandi, Harnessing Sunlight on Water: A Comprehensive Analysis of Floating Photovoltaic Systems and their Implications Compared to Terrestrial, Journal of Renewable Energy and Environment, 2023.

[41] D. Dirnberger, G. Blackburn, B. Müller, and C. Reise, On the impact of solar spectral irradiance on the yield of different PV technologies, Solar Energy Materials and Solar Cells, Vol. 132, pp. 431–442, 2015.

[42] R. Rüther and J. Livingstone, Seasonal variations in amorphous silicon solar module outputs and thin film characteristics, Solar Energy Materials and Solar Cells, Vol. 36, No. 1, pp. 29–43, 1995.

[43] M. Rezvani, A. Gholami, R. Gavagsaz-Ghoachani, and M. Zandi, A Review on The Effect of Dust Properties on Photovoltaic Solar Panels’ Performance, Journal of Renewable and New Energy, Vol. 10, No. 1, pp. 198–211, 2023.

[44] H. A. Kazem, A. H. A. Al-Waeli, M. T. Chaichan, K. Sopian, A. Gholami, and W. E. Alnaser, Dust and cleaning impact on the performance of photovoltaic: an outdoor experimental study, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, Vol. 45, No. 1, pp. 3107–3124, 2023.

[45] S. C. S. Costa, A. S. A. C. Diniz, and L. L. Kazmerski, Solar energy dust and soiling R&D progress: Literature review update for 2016, Renewable and Sustainable Energy Reviews, Vol. 82, No. September, pp. 2504–2536, 2018.

[46] D. Deb and N. L. Brahmbhatt, Review of yield increase of solar panels through soiling prevention, and a proposed water-free automated cleaning solution, Renewable and Sustainable Energy Reviews, Vol. 82, No. October, pp. 3306–3313, 2018.

[47] A. Gholami et al., Dust Accumulation On Photovoltaic Modules: A Review On The Effective Parameters, Sigma Journal of Engineering and Natural Sciences, Vol. 39, No. 1, pp. 45–57, 2021.

[48] J. L. Gómez-Amo, M. D. Freile-Aranda, J. Camarasa, V. Estellés, M. P. Utrillas, and J. A. Martínez-Lozano, Empirical estimates of the radiative impact of an unusually extreme dust and wildfire episode on the performance of a photovoltaic plant in Western Mediterranean, Applied Energy, Vol. 235, pp. 1226–1234, 2019.

[49] S. Cai et al., Parameters optimization of the dust absorbing structure for photovoltaic panel cleaning robot based on orthogonal experiment method, Journal of Cleaner Production, Vol. 217, pp. 724–731, 2019.

[50] R. Zahedi, P. Ranjbaran, G. B. Gharehpetian, F. Mohammadi, and R. Ahmadiahangar, Cleaning of Floating Photovoltaic Systems: A Critical Review on Approaches from Technical and Economic Perspectives, Energies, Vol. 14, No. 7, p. 2018, 2021.

[51] A. Gholami, S. H. Eslami, A. Tajik, M. Ameri, R. Gavagsaz Ghoachani, and M. Zandi, A review of dust removal methods from the surface of photovoltaic panels, Mechanical Engineering, Sharif Journal, Vol. 35, No. 2, pp. 117–127, 2019. (in Persian)

[52] M. G. Hudedmani, G. Joshi, R. M. Umayal, and A. Revankar, A Comparative Study of Dust Cleaning Methods for the Solar PV Panels, Advanced Journal of Graduate Research, Vol. 1, No. 1, pp. 24–29, 2017.

[53] A. Al-Otaibi, A. Al-Qattan, F. Fairouz, and A. Al-Mulla, Performance evaluation of photovoltaic systems on Kuwaiti schools’ rooftop, Energy Conversion and Management, Vol. 95, pp. 110–119, 2015.

[54] A. Al Baloushi, M. Saeed, S. Marwan, S. AlGghafri, and Y. Moumouni, Portable robot for cleaning photovoltaic system: Ensuring consistent and optimal year-round photovoltaic panel performance, in Advances in Science and Engineering Technology International Conferences (ASET), 2018, pp. 1–4.

[55] N. Li, Z. Yang, Q. Zhang, R. Feng, and Y. Wu, Numerical Study on Windbreaks with Different Porosity in Photovoltaic Power Plants, Energy Procedia, Vol. 158, pp. 577–582, 2019.

[56] P. Vasiljev, S. Borodinas, R. Bareikis, and A. Struckas, Ultrasonic system for solar panel cleaning, Sensors and Actuators, A: Physical, Vol. 200, pp. 74–78, 2013.

[57] K. Rahbar, S. Eslami, R. Pouladian-Kari, and L. Kirchner, 3-D numerical simulation and experimental study of PV module self-cleaning based on dew formation and single axis tracking, Applied Energy, Vol. 316, No. March, p. 119119, 2022.

[58] A. Pouladian-Kari, S. Eslami, A. Tadjik, L. Kirchner, R. Pouladian-Kari, and A. Golshanfard, A novel solution for addressing the problem of soiling and improving performance of PV solar systems, Solar Energy, Vol. 241, pp. 315–326, 2022.

[59] A. Skomedal, H. Haug, and E. S. Marstein, Endogenous Soiling Rate Determination and Detection of Cleaning Events in Utility-Scale PV Plants, IEEE Journal of Photovoltaics, Vol. 9, No. 3, pp. 858–863, 2019.

[60] S. Jiang, K. Wang, H. Zhang, Y. Ding, and Q. Yu, Encapsulation of PV Modules Using Ethylene Vinyl Acetate Copolymer as the Encapsulant, Macromolecular Reaction Engineering, Vol. 9, No. 5, pp. 522–529, 2015.

[61] A. A. Hegazy, Effect of dust accumulation on solar transmittance through glass covers of plate-type collectors, Renewable Energy, Vol. 22, No. 4, pp. 525–540, 2001.

[62] W. Al-Kouz, S. Al-Dahidi, B. Hammad, and M. Al-Abed, Modeling and Analysis Framework for Investigating the Impact of Dust and Temperature on PV Systems’ Performance and Optimum Cleaning Frequency, Applied Sciences, Vol. 9, No. 7, p. 1397, 2019.

[63] A. A. Yaghoubi, M. Gandomzadeh, A. Gholami, R. Gavagsaz Ghoachani, M. Zandi, and H. A. Kazem, Optimize photovoltaic panels cleaning scheduling framework based on variations of hourly-based active electricity pricing in the market, Solar Energy, Vol. 275, No. May, p. 112633, 2024.

[64] A. Kimber, L. Mitchell, S. Nogradi, and H. Wenger, The Effect of Soiling on Large Grid-Connected Photovoltaic Systems in California and the Southwest Region of the United States, in IEEE 4th World Conference on Photovoltaic Energy Conference, 2006, pp. 2391–2395.

[65] N. F. Jones, L. Pejchar, and J. M. Kiesecker, The Energy Footprint: How Oil, Natural Gas, and Wind Energy Affect Land for Biodiversity and the Flow of Ecosystem Services, BioScience, Vol. 65, No. 3, pp. 290–301, 2015.

[66] M. Fathi, M. Abderrezek, and M. Friedrich, Reducing dust effects on photovoltaic panels by hydrophobic coating, Clean Technologies and Environmental Policy, Vol. 19, No. 2, pp. 577–585, 2017.

[67] M. Al-Housani, Y. Bicer, and M. Koç, Experimental investigations on PV cleaning of large-scale solar power plants in desert climates: Comparison of cleaning techniques for drone retrofitting, Energy Conversion and Management, Vol. 185, No. September 2018, pp. 800–815, 2019.

[68] R. K. Jones et al., Optimized Cleaning Cost and Schedule Based on Observed Soiling Conditions for Photovoltaic Plants in Central Saudi Arabia, IEEE Journal of Photovoltaics, Vol. 6, No. 3, pp. 730–738, 2016.

[69] B. Hammad et al., Modeling and analysis of dust and temperature effects on photovoltaic systems’ performance and optimal cleaning frequency: Jordan case study, Renewable and Sustainable Energy Reviews, Vol. 82, No. April 2017, pp. 2218–2234, 2018.