Abstract
Vibration signal analysis is an efficient online transformer fault diagnosis method for improving the stability and safety of power systems. Operation in harsh interference environments and the lack of fault samples are the most challenging aspects of transformer fault diagnosis. High-precision performance is difficult to achieve when using conventional fault diagnosis methods. Thus, this study proposes a transformer fault diagnosis method based on the adaptive transfer learning of a two-stream densely connected residual shrinkage network over vibration signals. First, novel time-frequency analysis methods (i.e., Synchrosqueezed Wavelet Transform and Synchrosqueezed Generalized S-transform) are proposed to convert vibration signals into different images, effectively expanding the samples and extracting effective features of signals. Second, a Two-stream Densely Connected Residual Shrinkage (TSDen2NetRS) network is presented to achieve a high accuracy fault diagnosis under different working conditions. Furthermore, the Residual Shrinkage layer (RS layer) is applied as a nonlinear transformation layer to the deep learning framework to remove unimportant features and enhance anti-interference performance. Lastly, an adaptive transfer learning algorithm that can automatically select the source data set by using the domain measurement method is proposed. This algorithm accelerates the training of the deep learning network and improves accuracy when the number of samples is small. Vibration experiments of transformers are conducted under different operating conditions, and their results show the effectiveness and robustness of the proposed method.
Highlights
With the rapid development of digital power grids, research on intelligent, efficient, and comprehensive fault diagnosis methods guarantees the building of future power grids
The signals acquired are divided into several segments by the sliding window method, and the segmented data is transformed into timefrequency images via the Synchrosqueezed Wavelet Transform (SWT) and Synchrosqueezed Wavelet Transform (SSGST) combined method
The multiple SWT and Synchrosqueezed Generalized S-transform (SSGST) time-frequency images are divided into testing data set, validation data set, and training data set, which are the inputs of the Two-stream Densely Connected Residual Shrinkage (TSDen2NetRS) network
Summary
With the rapid development of digital power grids, research on intelligent, efficient, and comprehensive fault diagnosis methods guarantees the building of future power grids. Transformers are the most important electrical equipment in power grid systems; their failure causes considerable economic losses [1]. As is known to all, the fault diagnosis methods of transformers primarily include Dissolved Gas Analysis (DGA) [4], Short-circuit Reactance (SCR) [5], Infrared Thermography (IRT) [6,7], Frequency Response Analysis (FRA) [8,9], and so on. These traditional diagnostic methods are hysteretic and cannot diagnose faults before they occur
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