Abstract

The nonlinear output characteristics of PV arrays and maximum power point tracking (MPPT) techniques bring more difficulties to fault diagnosis. The fault diagnosis model based on electrical transient time-domain analysis is an effective method for solving the above problems. However, existing studies using transient processes usually train their models by extensive labeled datasets, and some approaches apply normalization methods with environmental condition sensors or reference PV panels. Therefore, Fisher discrimination dictionary learning (FDDL) for sparse representation is explored for diagnosing PV array faults, including line-to-line faults (LLF), open-circuit faults (OCF), and partial shading faults (PSF), with a small labeled dataset, and a dynamic normalization method without additional sensors is proposed to process transient data. Moreover, LLF and PSF that have similar characteristics under low mismatch should be further distinguished. The proposed model is designed with two stages. In the first stage, a multiple classifier trained using small labeled datasets with all fault types is applied to diagnose all kinds of studied PV array faults. Then, a dictionary only for PSF and LLF is learned in the second stage to further identify LLF and PSF. Finally, a 1.8 kW rooftop grid-connected PV system with $6\times3$ PV arrays is applied to validate the performance of the proposed model. The comparison result shows the superiority of the proposed model.

Highlights

  • F OSSIL energy is nonrenewable and provides great challenges to the environment [1]

  • To study the characteristics of the electrical transient timedomain, faults are tested on a grid connected PV system with a 6×(in parallel) PV array, including two line-to-line faults (LLF), two open-circuit faults (OCF), and one partial shading faults (PSF)

  • This PV system consists of a PV array with 3 in parallel and 6 in series PV panels

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Summary

INTRODUCTION

F OSSIL energy is nonrenewable and provides great challenges to the environment [1]. seeking alternative renewable energy to replace fossil fuels is necessary [2]. A fault detection technique without additional sensors is proposed in [16], which exploits the rightmost power peak in the output characteristics of the PV array to detect LLF and LGF faults This technology can be integrated into any PV system with an MPPT controller. The electrical transient time domain is employed as input, and a new dynamic normalization method is developed that does not require additional environmental sensors or reference panels. The contribution of this model can be summarized as follows: 1) The FDDL algorithm is used to diagnose PV faults, which can be modeled with a small sample set.

TRANSIENT DATA CHARACTERISTICS UNDER FAULT AND THEIR NORMALIZATION
DYNAMIC NORMALIZATION
SPARSE REPRESENTATION BASED CLASSIFICATION
OPTIMIZATION OF FDDL
EXPERIMENTAL SETUP
GLOBAL CLASSIFIER
CONCLUSIONS

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