Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants
S. Krauter, J. Bendfeld, Energies 17 (2024).
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Abstract
<jats:p>The market for microinverters is growing, especially in Europe. Driven by rising electricity prices and an easing in legislation since 2024, the number of mini-photovoltaic energy systems (mini-PVs) being installed is increasing substantially. Indoor and outdoor studies of microinverters have been carried out at Paderborn University since 2014. In the indoor lab, conversion efficiencies as a function of load have been measured with high accuracy and ranked according to Euro and CEC weightings; the latest rankings from 2024 are included in this paper. In the outdoor lab, energy yields have been measured using identical and calibrated crystalline silicon PV modules; until 2020, measurements were carried out using 215 Wp modules. Because of increasing PV module power ratings, 360 Wp modules were used from 2020 until 2024. In 2024, the test modules were upgraded to 410 Wp modules, taking into account the increase from 600 W to 800 W of inverter power limits, which is suitable for simplified operation permission (“plug-in”) in many European countries within a homogenised legislation area for such mini-photovoltaic energy systems or “balcony power plants”. This legislation for simplified operation also covers overpowered mini-plants, although the maximum AC output remains limited to 800 W. Presently, yield assessments are being carried out in the outdoor lab, which will take at least a year to be valid and comparable. Kits consisting of PV modules, inverters, and mounting systems are also being evaluated. Yield rankings sometimes differ from efficiency rankings due to the use of different MPPT algorithms with different MPP approach speeds and accuracies. To accelerate yield assessment, we developed a novel, simple formula to determine energy yield for any module and inverter configuration, including overpowered systems. This is a linear approach, determined by just two coefficients, a and b, which are given for several inverters. To reduce costs, inverters will be integrated into the module frame or the module terminal box in the future.</jats:p>
Publishing Year
Journal Title
Energies
Volume
17
Issue
22
Article Number
5551
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Cite this
Krauter S, Bendfeld J. Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants. Energies. 2024;17(22). doi:10.3390/en17225551
Krauter, S., & Bendfeld, J. (2024). Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants. Energies, 17(22), Article 5551. https://doi.org/10.3390/en17225551
@article{Krauter_Bendfeld_2024, title={Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants}, volume={17}, DOI={10.3390/en17225551}, number={225551}, journal={Energies}, publisher={MDPI AG}, author={Krauter, Stefan and Bendfeld, Jörg}, year={2024} }
Krauter, Stefan, and Jörg Bendfeld. “Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants.” Energies 17, no. 22 (2024). https://doi.org/10.3390/en17225551.
S. Krauter and J. Bendfeld, “Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants,” Energies, vol. 17, no. 22, Art. no. 5551, 2024, doi: 10.3390/en17225551.
Krauter, Stefan, and Jörg Bendfeld. “Efficiency Ranking of Photovoltaic Microinverters and Energy Yield Estimations for Photovoltaic Balcony Power Plants.” Energies, vol. 17, no. 22, 5551, MDPI AG, 2024, doi:10.3390/en17225551.