A robust, self-calibrating model for Maximum Power Point tracking and Hot Spot Suppression

Hot Spot Suppression (HSS) [1] is a method to control a PV module that eliminates the need for bypass diodes but requires a pre-calibrated PV model and a back skin temperature sensor per PV module. This paper describes a new self-calibrated PV model that needs only generic information about the PV m...

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Main Authors: Spanoche, Sorin, Behziz, Behnam
Format: Conference Proceeding
Language:English
Subjects:
Adaptation models
Junctions
Modeling
Photovoltaic cells
Photovoltaic Systems
Power system control
Solar Power Generation
Temperature
Temperature control
Temperature dependence
Temperature measurement
Temperature sensors
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Behziz, Behnam
description Hot Spot Suppression (HSS) [1] is a method to control a PV module that eliminates the need for bypass diodes but requires a pre-calibrated PV model and a back skin temperature sensor per PV module. This paper describes a new self-calibrated PV model that needs only generic information about the PV module and no integrated temperature sensor. The model adapts to light and temperature variations and is used to control Maximum Power Point (MPP) and to define the protection regions for HSS. Theoretical and experimental results show this new model is more accurate than previous temperature based models and is faster than best case Perturb and Observe method while using standard PV module.
doi_str_mv 10.1109/PVSC.2013.6745168
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source IEEE Xplore All Conference Series
subjects Adaptation models
Junctions
Modeling
Photovoltaic cells
Photovoltaic Systems
Power system control
Solar Power Generation
Temperature
Temperature control
Temperature dependence
Temperature measurement
Temperature sensors
title A robust, self-calibrating model for Maximum Power Point tracking and Hot Spot Suppression
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