Abstract
The traditional solar photovoltaic fault diagnosis system needs two to three sets of sensing elements to capture fault signals as fault features and many fault diagnosis methods cannot be applied with real time. The fault diagnosis method proposed in this study needs only one set of sensing elements to intercept the fault features of the system, which can be real-time-diagnosed by creating the fault data of only one set of sensors. The aforesaid two points reduce the cost and fault diagnosis time. It can improve the construction of the huge database. This study used Matlab to simulate the faults in the solar photovoltaic system. The maximum power point tracker (MPPT) is used to keep a stable power supply to the system when the system has faults. The characteristic signal of system fault voltage is captured and recorded, and the dynamic error of the fault voltage signal is extracted by chaos synchronization. Then, the extension engineering is used to implement the fault diagnosis. Finally, the overall fault diagnosis system only needs to capture the voltage signal of the solar photovoltaic system, and the fault type can be diagnosed instantly.
Highlights
In 2013, Hsieh and Shiu proposed a new method of the photovoltaic system fault diagnosis based on chaotic signal synchronization [1]
In terms of the solar photovoltaic system maximum power point tracker (MPPT), this paper proposes the extension incremental conductance method (EICM) and compares it with the general fixed step incremental conductance method (FICM) and the variable step incremental conductance method (VICM)
Its diagnosis is very fast in comparison with general neural diagnosis. This method proposed in this paper only needs one set of sensors to capture a voltage signal, which is imported into the chaos synchronization system
Summary
In 2013, Hsieh and Shiu proposed a new method of the photovoltaic system fault diagnosis based on chaotic signal synchronization [1]. It is an offline fault diagnostic scheme. In order to improve the defect, this paper proposes the intelligent solar photovoltaic system real-time fault diagnostic device. Manual detection is replaced by the intelligent solar photovoltaic system real time fault diagnostic device. In the spacious solar photovoltaic array, as long as the output end of the array is measured and compared with previously created diagnostic data, the type of fault can be real time quickly diagnosed without manual inspection. This paper aims to research and develop an intelligent solar photovoltaic system real-time fault diagnostic device
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