Abstract
The design of a PV system is crucial, primarily based on the solar resources available at the site. The operating factor of a PV module is a design factor for the PV system which depends on solar radiation, the temperature of the panel, dust accumulated on the panel, and mismatch factor. Generally, the Opv of the PV module is considered a constant of 0.75. However, this research work aims to model the Opv parameter and design a PV/battery/supercapacitor water pumping system using the varying operating factor of the PV module (Opv) throughout a year. The tilted radiation on the PV module, the module’s temperature, and module efficiency, the operating factor of the module for different months, the PV module size, and the loss of load probability (LLP) are simulated in MATLAB environment presented. A comparison of the system design with constant Opv (0.75) and the yearly average Opv (0.65) is illustrated. A PV size of 40 Wp with LLP of 0 is reported for Opv of 0.65. However, the PV size with Opv 0.75 is undersized. The study recommends that Opv is site-specific, and proper modeling is necessary for a particular site for a PV system installation.
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References
Santra P (2021) Performance evaluation of solar PV pumping system for providing irrigation through micro-irrigation techniques using surface water resources in hot arid region of India. Agric Water Manag 245:106554
Rathore PKS, Das SS, Chauhan DS (2018) Perspectives of solar photovoltaic water pumping for irrigation in India. Energ Strat Rev 22:385–395
Benghanem M, Daffallah KO, Joraid AA, Alamri SN, Jaber A (2013) Performances of solar water pumping system using helical pump for a deep well: a case study for Madinah, Saudi Arabia. Energy Conv Manage 65:50–56
Rawat R, Kaushik SC, Lamba R (2016) A review on modeling, design methodology and size optimization of photovoltaic based water pumping, standalone and grid connected system. Renew Sustain Energy Rev 57:1506–1519
Khatib T, Ibrahim IA, Mohamed A (2016) A review on sizing methodologies of photovoltaic array and storage battery in a standalone photovoltaic system. Energy Convers Manage 120:430–448
Rana J, Kamruzzaman M, Oliver MH, Akhi K (2021) Financial and factors demand analysis of solar powered irrigation system in Boro rice production: a case study in Meherpur district of Bangladesh. Renew Energy 167:433–439
Labed S, Lorenzo E (2004) The impact of solar radiation variability and data discrepancies on the design of PV systems. Renew Energy 29(7):1007–1022
Yesilata B, Firatoglu ZA (2008) Effect of solar radiation correlations on system sizing: PV pumping case. Renew Energy 33(1):155–161
Abdulkarim HT, Sansom CL, Patchigolla K, King P (2020) Statistical and economic analysis of solar radiation and climatic data for the development of solar PV system in Nigeria. Energy Rep 6:309–316
Guentri H, Allaoui T, Mekki M, Denai M (2021) Power management and control of aphotovoltaic system with hybrid battery-supercapacitor energy storage basedonHeuristicsmethods. J Energy Storage 39:102578
Cabrane Z, Kim J, Yoo K, Ouassaid M (2021) HESS-based photovoltaic/batteries/supercapacitors: energy management strategy and DC bus voltage stabilization. Sol Energy 216:551–563
Masaki MS, Zhang L, Xia X (2018) Hierarchical power flow control of a grid-tied photovoltaic plant using a battery-supercapacitor energy storage system. Energy Procedia 145:32–37
Jaszczur M, Hassan Q (2020) An optimisation and sizing of photovoltaic system with supercapacitor for improving self-consumption. Appl Energy 279:115776
Cabrane Z, Ouassaid M, Maaroufi M (2016) Analysis and evaluation of battery-supercapacitor hybrid energy storage system for photovoltaic installation. Int J Hydrogen Energy 41(45):20897–20907
Das M, Mandal R (2018) A comparative performance analysis of direct, with battery, supercapacitor, and battery-supercapacitor enabled photovoltaic water pumping systems using centrifugal pump. Sol Energy 171:302–309
Das M, Mukherjee D, Chaudhuri SRB (2017) An approach to study the performance of photovoltaic water pumping using supercapacitor. Mater Today Proc 4(9):10400–10406
Lopez Ramirez I (2017) Operating correction factor of PV system: effects of temperature, angle of incidence and invertor in PV system performance
Solanki CS (2008) Renewable energy technologies: a practical guide for beginners. PHI Learning Pvt. Ltd.
Modi V, Sukhatme SP (1979) Estimation of daily total and diffuse insolation in India from weather data. Sol Energy 22(5):407–411
Garg HP, Garg SN (1985) Correlation of monthly-average daily global, diffuse and beam radiation with bright sunshine hours. Energy Conv Manage 25(4):409–417
Liu B, Jordan R (1961) Daily insolation on surfaces tilted towards equator. ASHRAE J (United States) 10
Solanki CS (2015) Solar photovoltaics: fundamentals, technologies and applications. Phi learning Pvt. Ltd.
Kumar BS, Sudhakar K (2015) Performance evaluation of 10 MW grid connected solar photovoltaic power plant in India. Energy Rep 1:184–192
Singh VP, Kumar D, Ravindra B, Performance assessment of 5 MW grid connected photovoltaic plant in Western Region of India
Van Sark WGJHM, Reich NH, Müller B, Armbruster A, Kiefer K, Reise C (2012) Review of PV performance ratio development. In: World renewable energy congress. Denver CO, USA, pp 4795–4800
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Das, M., Mandal, R. (2022). Design of a PV-Battery-Supercapacitor Water Pumping System Based on the Varying Operating Factor of the PV Module. In: Chong, P.H.J., Kalam, A., Pascoal, A., Bera, M.K. (eds) Emerging Electronics and Automation. Lecture Notes in Electrical Engineering, vol 937. Springer, Singapore. https://doi.org/10.1007/978-981-19-4300-3_10
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