Abstract
This work proposes an automated reconfiguration system to manage two types of faults in any position inside the solar arrays. The faults studied are the short-circuit to ground and the open wires in the string. These faults were selected because they severely affect power production. By identifying the affected panels and isolating the faulty one, it is possible to recover part of the power loss. Among other types of faults that the system can detect and locate are: diode short-circuit, internal open-circuit, and the degradation of the internal parasitic serial resistance. The reconfiguration system can detect, locate the above faults, and switch the distributed commutators to recover most of the power loss. Moreover, the system can return automatically to the previous state when the fault has been repaired. A SIMULINK model has been built to prove this automatic system, and a simulated numerical experiment has been executed to test the system response to the faults mentioned. The results show that the recovery of power is more than 90%, and the diagnosis accuracy and sensitivity are both 100% for this numerical experiment.
Highlights
We have presented an automated fault management system composed of three main parts: the diagnosis algorithm, the reconfiguration algorithm, and the distributed switching matrix
The automated fault management (AFM) system was tested using a solar array composed of 16 × 3 PV modules and 19 events that use 5 electrical faults
The simulated faults have different severity levels, and for the short-circuit to the ground or an open-wire, the AFM system recovers more than 90% of the power loss with a diagnosis accuracy and sensitivity of 100% for the planned experiments
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Several investigations about dynamic reconfiguration systems (DRSs) in photovoltaic (PV) arrays focus on reducing the electrical incompatibilities or mismatches among the solar panels. Studies such as [1,2,3] aim to compensate the losses in the delivered power by the solar installation as fast as possible when mismatching or partial shading occurs
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