Analysis of a Multiport DC/DC Converter Used for Energy Extraction from a Photovoltaic system

https://doi.org/10.58571/CNCA.AMCA.2023.070

Resumen: In this paper, a simulation analysis of a multiport DC/DC converter with Boost topology has been carried out. The converter topology consists of two inputs and one output. This analysis aims to obtain the first version to cope with partial shading in a PV system using a multiport converter. The analysis shows the multiport converter’s functionality to track the maximum power point of the two PV panels using the Perturb and Observe (P&O) algorithm in normal irradiance conditions and partial shading situations. A switching time of the switches was established to perform individual power extraction from each panel connected to each port individually. These findings will contribute to the feasibility of the proposed methodology for efficient energy extraction using multiport converters as another alternative to cope with partial shading.

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de los Reyes-Suárez, Lázaro Ibrahel; Mares-Gardea, Arturo Ernesto; García Morales, Jarniel; Adam-Medina, Manuel; Cervantes-Bobadilla, Marisol; Guerrero-Ramírez, Gerardo. Analysis of a Multiport DC/DC Converter Used for Energy Extraction from a Photovoltaic system. Memorias del Congreso Nacional de Control Automático, pp. 254-259, 2023. https://doi.org/10.58571/CNCA.AMCA.2023.070

Palabras clave

Sistemas Eléctricos de Potencia; Sistemas Electrónicos de Potencia; Control de Procesos

• Ali, A., Almutairi, K., Padmanaban, S., Tirth, V., Algarni, S., Irshad, K., Islam, S., Zahir, M. H., Shafiullah, M., & Malik, M. Z. (2020). Investigation of MPPT techniques under uniform and non-uniform solar irradiation condition–a retrospection. Ieee Access, 8, 127368-127392.
• Granda-Gutiérrez, E., Orta, O., Díaz-Guillén, J., Jimenez, M., Osorio, M., & González, M. (2013). Modelado y simulación de celdas y paneles solares. Congreso Internacional de Ingeniería Electrónica, Güney, T. (2019). Renewable energy, non-renewable energy and sustainable development. International Journal of Sustainable Development & World Ecology, 26(5), 389-397.
• Karami, N., Moubayed, N., & Outbib, R. (2017). General review and classification of different MPPT Techniques. Renewable and Sustainable Energy Reviews, 68, 1-18.
• Kebede, A. B., & Worku, G. B. (2020). Comprehensive review and performance evaluation of maximum power point tracking algorithms for photovoltaic system. Global Energy Interconnection, 3(4), 398-412.
• Park, J., Kim, H.-g., Cho, Y., & Shin, C. (2014). Simple modeling and simulation of photovoltaic panels using Matlab/Simulink. Advanced Science and Technology Letters, 73(14), 147-155.
• Petreuş, D., Fărcaş, C., & Ciocan, I. (2008). Modelling and simulation of photovoltaic cells. Acta Technica Napocensis-Electronics and Telecommunications, 49(1), 42-47.
• Pukhrem, S. (2013). A photovoltaic panel model in matlab/simulink. Dublin Institute of Technology, Faculty of Electrical Engineering.
• Rehman, Z., Al-Bahadly, I., & Mukhopadhyay, S. (2015). Multiinput DC–DC converters in renewable energy applications–An overview. Renewable and Sustainable Energy Reviews, 41, 521-539.
• Sarvi, M., & Azadian, A. (2022). A comprehensive review and classified comparison of MPPT algorithms in PV systems. Energy Systems, 13(2), 281-320.
• SENER, M. (2022). Programa para el Desarrollo del Sistema Eléctrico Nacional 2022-2036. Anexo 2 Reporte de Avance de Energías Limpias. https://www.cenace.gob.mx/Paginas/SIM/Prodesen.aspx
• Zhu, Y., & Xiao, W. (2020). A comprehensive review of topologies for photovoltaic I–V curve tracer. Solar Energy, 196, 346-357.
• Congreso Nacional de Control Automático 2023, 25-27 de Octubre, 2023. Acapulco, Guerrero, México. 259