4 research outputs found
Synchro-Transient-Extracting Transform for the Analysis of Signals with Both Harmonic and Impulsive Components
Time-frequency analysis (TFA) techniques play an increasingly important role
in the field of machine fault diagnosis attributing to their superiority in
dealing with nonstationary signals. Synchroextracting transform (SET) and
transient-extracting transform (TET) are two newly emerging techniques that can
produce energy concentrated representation for nonstationary signals. However,
SET and TET are only suitable for processing harmonic signals and impulsive
signals, respectively. This poses a challenge for each of these two techniques
when a signal contains both harmonic and impulsive components. In this paper,
we propose a new TFA technique to solve this problem. The technique aims to
combine the advantages of SET and TET to generate energy concentrated
representations for both harmonic and impulsive components of the signal.
Furthermore, we theoretically demonstrate that the proposed technique retains
the signal reconstruction capability. The effectiveness of the proposed
technique is verified using numerical and real-world signals
Multi-Band Frequency Window for Time-Frequency Fault Diagnosis of Induction Machines
[EN] Induction machines drive many industrial processes and their unexpected failure can cause heavy producti on losses. The analysis of the current spectrum can identify online the characteristic
fault signatures at an early stage, avoiding unexpected breakdowns. Nevertheless, frequency domain analysis requires stable working conditions, which is not the case for wind generators, motors driving
varying loads, and so forth. In these cases, an analysis in the time-frequency domain¿such as a spectrogram¿is required for detecting faults signatures. The spectrogram is built using the short time Fourier transform, but its resolution depends critically on the time window used to generate it¿short windows provide good time resolution but poor frequency resolution, just the opposite than
long windows. Therefore, the window must be adapted at each time to the shape of the expected fault harmonics, by highly skilled maintenance personnel. In this paper this problem is solved with the
design of a new multi-band window, which generates simultaneously many different narrow-band current spectrograms and combines them into as single, high resolution one, without the need of
manual adjustments. The proposed method is validated with the diagnosis of bar breakages during the start-up of a commercial induction motor.This research was funded by the Spanish "Ministerio de Ciencia, Innovacion y Universidades (MCIU)", the "Agencia Estatal de Investigacion (AEI)" and the "Fondo Europeo de Desarrollo Regional (FEDER)" in the framework of the "Proyectos I+D+i - Retos Investigacion 2018", project reference RTI2018-102175-B-I00 (MCIU/AEI/FEDER, UE).Burriel-Valencia, J.; Puche-Panadero, R.; Martinez-Roman, J.; Riera-Guasp, M.; Sapena-Bano, A.; Pineda-Sanchez, M. (2019). Multi-Band Frequency Window for Time-Frequency Fault Diagnosis of Induction Machines. Energies. 12(17):1-18. https://doi.org/10.3390/en12173361S118121
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Transient extraction transform based fault location method with enhanced accuracy
The fast determination of internal or external fault for the VSC-MTDC is essential for its safety and continuous operation. As very limited time is permitted in an internal fault, transient-based protection elements are widely applied to locate the fault in a very small-time window. However, with such a short time window, location methods based on the wavelet transform or the mathematical morphology show limited performance balancing the resolution in the time and frequency domains. In recent years, there has been a novel time-frequency domain analysis method, naming the transient extraction transform (TET), with high accuracy in both domains. In this paper, a TET-based fast fault-location method is proposed with enhanced accuracy. Comparison studies are made to highlight the performance of such a method against internal faults for the VSC-MTDC.This work is supported by the National Natural Science Foundation of China under Grant No. 51907069 and the
Natural Science Foundation of Guangdong Province under Grant No. 2021A151501239
Fault Diagnosis of Rotating Equipment Bearing Based on EEMD and Improved Sparse Representation Algorithm
Aiming at the problem that the vibration signals of rolling bearings working in a harsh environment are mixed with many harmonic components and noise signals, while the traditional sparse representation algorithm takes a long time to calculate and has a limited accuracy, a bearing fault feature extraction method based on the ensemble empirical mode decomposition (EEMD) algorithm and improved sparse representation is proposed. Firstly, an improved orthogonal matching pursuit (adapOMP) algorithm is used to separate the harmonic components in the signal to obtain the filtered signal. The processed signal is decomposed by EEMD, and the signal with a kurtosis greater than three is reconstructed. Then, Hankel matrix transformation is carried out to construct the learning dictionary. The K-singular value decomposition (K-SVD) algorithm using the improved termination criterion makes the algorithm have a certain adaptability, and the reconstructed signal is constructed by processing the EEMD results. Through the comparative analysis of the three methods under strong noise, although the K-SVD algorithm can produce good results after being processed by the adapOMP algorithm, the effect of the algorithm is not obvious in the low-frequency range. The method proposed in this paper can effectively extract the impact component from the signal. This will have a positive effect on the extraction of rotating machinery impact features in complex noise environments