Journal of Applied Science and Engineering

Published by Tamkang University Press

1.30

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2.10

CiteScore

Jingjing Tian1, Fang Geng This email address is being protected from spambots. You need JavaScript enabled to view it.1, Feng Zhao1, Fengyang Gao1, and Xinqiang Niu1

1School of Automation and Electrical Engineering, Lanzhou Jiaotong University, Lanzhou 730070, China


 

Received: October 7, 2020
Accepted: June 18, 2021
Publication Date: July 23, 2021

 Copyright The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are cited.


Download Citation: ||https://doi.org/10.6180/jase.202202_25(1).0020  


ABSTRACT


Aiming at the problem that the effect of the existing fault line selection methods is mainly determined by the fault features constructed by manual extraction, and the fault feature extraction process is complex and time-consuming, a new method based on convolutional neural network (CNN) is proposed. Firstly, the fault voltage and current signal data are collected, and the time-frequency energy matrix of fault signal is constructed by HHT band-pass filtering method, which is regarded as the two-dimensional matrix form of input data of CNN. Then the time-frequency energy matrix is input into the CNN, and the fault features are extracted autonomously through convolution layer and pooling layer of the network, which is used to train the network to realize fault line selection and fault phase judgment. Finally, the results show that the method not only has high accuracy of fault line selection, but also can complete the fault line selection and fault phase judgment at the same time without adjusting any parameters, which realize the shared weights of the two non-independent problems. Meanwhile, under the influence of noise interference, compensation degree, network structure change and other factors, the proposed method has good robustness. However, compared with the FCM, SVM, DNN and DBN, CNN can still identify the faulty line and keep the optimal accuracy in the case of two-point grounding fault, and other methods have errors in line selection or low accuracy. Therefore, the experimental results also provide a new idea for fault line selection of distribution network.


Keywords: Fault line selection, time-frequency energy matrix, convolutional neural network, shared weights


REFERENCES


  1. [1] Y. Wang, J. Zhou, Z. Li, Z. Dong, and Y. Xu, (2015) “Discriminant-analysis-based single-phase earth fault protection using improved PCA in distribution systems" IEEE Transactions on Power Delivery 30(4): 1974–1982. DOI: 10.1109/TPWRD.2015.2408814.
  2. [2] H. Shu, Y. Li, X. Tian, and Y. Fang, (2019) “Key design techniques of low voltage ride-through test system for ultra-high altitude photovoltaic power station" Automation of Electric Power Systems 43(06): 171–176. DOI:10.7500/AEPS20180321001.
  3. [3] M.-F. Guo and N.-C. Yang, (2017) “Features-clusteringbased earth fault detection using singular-value decomposition and fuzzy c-means in resonant grounding distribution systems" International Journal of Electrical Power & Energy Systems 93: 97–108. DOI: 10.1016/j.ijepes.2017.05.014.
  4. [4] M. F. Guo, S. D. Liu, and G. J. Yang, (2013) “A new approach to detect fault line in resonant earthed system based on Hilbert spectrum band-pass filter and transient waveform recognition" Advanced Technology of Electrical Engineering and Energy 32(3): 67–74.
  5. [5] S. Zhuang, X. Miao, H. Jiang, and M. Guo, (2020) “A line selection method for single-phase high-impedance grounding fault in resonant grounding system of distribution network based on improved euclidean-dynamic time warping distance" Power System Technology 44(01):273–281. DOI: 10.13335/j.1000-3673.pst.2018.3037.
  6. [6] N. I. Elkalashy, A. M. Elhaffar, T. A. Kawady, N. G. Tarhuni, and M. Lehtonen, (2010) “Bayesian selectivity technique for earth fault protection in medium-voltage networks" IEEE Transactions on Power Delivery 25(4):2234–2245. DOI: 10.1109/TPWRD.2010.2053562.
  7. [7] S. Li, C. Huang, and Y. Chen, (2019) “Fault line selection and location for distribution network based on improved PSO-BP neural network" Journal of Shenyang University of technology 41(01): 6–11. DOI: 10.7688/j.issn.1000-1646.2019.01.02.
  8. [8] Y. Dan,W. Zhao, Y. Z. andx Yingjing He, and S. Shen, (2019) “Fault line selection in small current ground power system based on ABC-DNN" Smart Power 47(04): 46–52.
  9. [9] A. Ghaderi, H. A. Mohammadpour, H. L. Ginn, and Y.-J. Shin, (2014) “High-impedance fault detection in the distribution network using the time-frequency-based algorithm" IEEE Transactions on Power Delivery 30(3):1260–1268. DOI: 10.1109/TPWRD.2014.2361207.
  10. [10] Y. LeCun, Y. Bengio, and G. Hinton, (2015) “Deep learning" nature 521(7553): 436–444.
  11. [11] M.-F. Guo, X.-D. Zeng, D.-Y. Chen, and N.-C. Yang, (2017) “Deep-learning-based earth fault detection using continuous wavelet transform and convolutional neural network in resonant grounding distribution systems" IEEE Sensors Journal 18(3): 1291–1300. DOI: 10.1109/JSEN.2017.2776238.
  12. [12] Y. Zhu, R. Liu, and Q. Huang, (2020) “Fine-grained image recognition of weak supervisory information based on deep neural network" Journal of Electronic Measurement and Instrumentation 34(02): 115–122.
  13. [13] X. Xiong, W. Jianxiang, and Z. Yongjun, (2019) “A Two-Dimensional Convolutional Neural Network Optimization Method for Bearing Fault Diagnosis [J]" Proceedings of the CSEE 39(15): 4558–4568. DOI:10.13334/j.0258-8013.pcsee.182037.
  14. [14] H. Wang, J. Xu, R. Yan, and R. X. Gao, (2019) “A new intelligent bearing fault diagnosis method using SDP representation and SE-CNN" IEEE Transactions on Instrumentation and Measurement 69(5): 2377–2389.DOI: 10.1109/TIM.2019.2956332.
  15. [15] C.Wei, H. Jiahuan, and P. Xiping, (2018) “Classification for power quality disturbance based on phase-space reconstruction and convolution neural network [J]" Power System Protection and Control 46(14): 27–31. DOI:10.7667/PSPC171080.
  16. [16] W. Gong, H. Chen, Z. Zhang, M. Zhang, and H. Gao, (2020) “A data-driven-based fault diagnosis approach for electrical power dc-dc inverter by using modified convolutional neural network with global average pooling and 2-D feature image" IEEE Access 8: 73677–73697. DOI:10.1109/ACCESS.2020.2988323.
  17. [17] J. Fu, J. Chu, P. Guo, and Z. Chen, (2019) “Condition monitoring of wind turbine gearbox bearing based on deep learning model" IEEE Access 7(99): 78–87. DOI: 10 .19805/j.cnki.jcspe.2020.11.005.
  18. [18] L. Lu, Y. He, T. Wang, T. Shi, and Y. Ruan, (2019) “Wind turbine planetary gearbox fault diagnosis based on self-powered wireless sensor and deep learning approach" IEEE Access 7: 119430–119442. DOI: 10.1109/TIM.2020.3028402.
  19. [19] D.Wang, D. Yang, Z. Bowen, M. Ma, and H. Zhang. “Transmission Line Fault Diagnosis Based onWavelet Packet Analysis and Convolutional Neural Network”. In: 2018 5th IEEE International Conference on Cloud Computing and Intelligence Systems (CCIS). IEEE, 2018, 425–429. DOI: 10.1109/CCIS.2018.8691304.
  20. [20] K. ZHANG, J. TAO, C. QIN, W. LI, and C. LIU, (2019) “Diesel Engine Misfire diagnosis with deep convolutional neural network using dropout and batch normalization" Hsi-An Chiao Tung Ta Hsueh/Journal of Xi’an Jiaotong University 53(8): 159–166. DOI: 10.7652/xjtuxb201908021.
  21. [21] M.-F. Guo, N.-C. Yang, and W.-F. Chen, (2019) “Deeplearning-based fault classification using Hilbert–Huang transform and convolutional neural network in power distribution systems" IEEE Sensors Journal 19(16): 6905–6913. DOI: 10.1109/JSEN.2019.2913006.
  22. [22] L. Chang, X.-M. Deng, M.-Q. Zhou, Z.-K. Wu, Y. Yuan, S. Yang, and H. Wang, (2016) “Convolutional neural networks in image understanding" Acta Automatica Sinica 42(9): 1300–1312. DOI: 10.16383/j.aas.2016.c150800.
  23. [23] J. Tian, F. Geng, F. Zhao, F. Gao, and A. Li, (2020) “Line detection method for grounding fault in resonant grounding systems" Journal of Chongqing University:
  24. [24] J. Liang, T. Jing, H. Niu, and J. Wang, (2020) “Twoterminal fault location method of distribution network based on adaptive convolution neural network" IEEE Access 8: 54035–54043. DOI: 10.1109/ACCESS.2020.2980573.
  25. [25] J. Gao, Y. Qin, and H. Yin, (2020) “Fault line selection method based on wavelet packet and support vector machine" Journal of Zhengzhou University(Engineering Science) 21(01): 63–69.
  26. [26] Y. Liu, M. Gong, and L. Wang, (2017) “Fault line selection method for small current grounding system based on wavelet denoising and BA-SVM" Shandong Electric Power Technology 44: 22–25.
  27. [27] G. ZHANG, P. U. Haitao, and L. I. U. Kai, (2019) “Fault Line Selection Method of Small Current Grounding System Based on Deep Learning" Power Generation Technology 40(6): 548.
  28. [28] X. Zeng, (2018) “Research on single-phase fault line selection method of distribution network based on deep learning" Fu Jian:Fuzhou University: