In order to increase PV penetration and guarantee the grid stability, it is fundamental to accurately predict the power produced from PV plants. This work discusses a comprehensive thermo-electric model accounting for PV module dynamic behavior. Specifically, the thermal part considers five different sections featuring the five layers of the PV module. The electrical behavior of the PV module is described by the five parameters electric equivalent circuit where the operating temperature is calculated within the thermal model. The accuracy of the model is evaluated against the power produced by two monocrystalline silicon modules at the SolarTech Lab of Politecnico di Milano using both actual weather information and the weather forecast. Results highlight that dynamic models adequately characterize the behavior of the modules when actual weather measurements are available; the resulting error indexes WMAE and RMSE for the dynamic model are reduced with respect to steady-state and conventional approaches based on NOCT by 50%. Indeed, the WMAE is approximately 1%, which is comparable to the uncertainty related to measuring instrumentations, whereas the RMSE is included between 3 W and 4 W. When using the long term weather forecast, no advantages in the development of dynamic models can be noted.

Development and experimental validation of a comprehensive thermoelectric dynamic model of photovoltaic modules

MOLINAROLI, LUCA;SIMONETTI, RICCARDO;MANZOLINI, GIAMPAOLO
2017-01-01

Abstract

In order to increase PV penetration and guarantee the grid stability, it is fundamental to accurately predict the power produced from PV plants. This work discusses a comprehensive thermo-electric model accounting for PV module dynamic behavior. Specifically, the thermal part considers five different sections featuring the five layers of the PV module. The electrical behavior of the PV module is described by the five parameters electric equivalent circuit where the operating temperature is calculated within the thermal model. The accuracy of the model is evaluated against the power produced by two monocrystalline silicon modules at the SolarTech Lab of Politecnico di Milano using both actual weather information and the weather forecast. Results highlight that dynamic models adequately characterize the behavior of the modules when actual weather measurements are available; the resulting error indexes WMAE and RMSE for the dynamic model are reduced with respect to steady-state and conventional approaches based on NOCT by 50%. Indeed, the WMAE is approximately 1%, which is comparable to the uncertainty related to measuring instrumentations, whereas the RMSE is included between 3 W and 4 W. When using the long term weather forecast, no advantages in the development of dynamic models can be noted.
2017
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11311/1017420
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