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Bayesian graphical model based optimal decision-making for fault diagnosis of critical induction motors in industrial applications

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Języki publikacji
EN
Abstrakty
EN
In an effort to achieve an optimal availability time of induction motors via fault probabilities reduction and improved prediction or diagnostic tools responsiveness, a conditional probabilistic approach was used. So, a Bayesian network (BN) has been developed in this paper. The objective will be to prioritize predictive and corrective maintenance actions based on the definition of the most probable fault elements and to see how they serve as a foundation for the decision framework. We have explored the causes of faults for an induction motor. The influence of different power ranges and the criticality of the electric induction motor are also discussed. With regard to the problem of induction motor faults monitoring and diagnostics, each technique developed in the literature concerns one or two faults. The model developed, through its unique structure, is valid for all faults and all situations. Application of the proposed approach to some machines shows promising results on the practical side. The model developed uses factual information (causes and effects) that is easy to identify, since it is best known to the operator. After that comes an investigation into the causal links and the definition of the a priori probabilities. The presented application of Bayesian networks is the first of its kind to predict faults of induction motors. Following the results of the inference obtained, prioritizations of the actions can be carried out.
Rocznik
Strony
467--476
Opis fizyczny
Bibliogr. 32 poz., rys., tab.
Twórcy
autor
  • Department of Mechanical Engineering, Mohamed Cherif Messaadia University, P.O. Box 1553, Souk-Ahras, 41000, Algeria
Bibliografia
  • [1] Y. Zhongming and W. Bin, “A Review on Induction Motor Online Fault Diagnosis”, in Proceedings IPEMC. The Third International Power Electronics and Motion Control Conference, Beijing, China, 2000.
  • [2] C.P. Salomon, et al., “A Study of Fault Diagnosis Based on Electrical Signature Analysis for Synchronous Generators Predictive Maintenance in Bulk Electric Systems”, Energies 12, 1506 (2019).
  • [3] P.A. Delgado-Arredondo, et al., “Methodology for fault detection in induction motors via sound and vibration signals”, Mech. Syst. Signal Process. 83, 568–589 (2017).
  • [4] L. Weidong and K.M. Chris, “Detection of Induction Motor Faults: A Comparison of Stator Current, Vibration and Acoustic Methods”, J. Vib. Control 12(2), 165–188 (2016).
  • [5] A. Głowacz and Z. Głowacz, “Recognition of rotor damages in a DC motor using acoustic signals”, Bull. Pol. Ac.: Tech. 65(2), 187‒194 (2017).
  • [6] G. Singh and V.N.A. Naikan, “Infrared thermography based diagnosis of inter-turn fault and cooling system failure in three phase induction motor”, Infrared Phys. Technol. 87, 134–138 (2017).
  • [7] P.C.M, Lamim Filho, R. Pederiva and J.N. Brito, “Detection of stator winding faults in induction machines using flux and vibration analysis”, Mech. Syst. Sig. Process. 42, 377–387 (2014).
  • [8] A.Y. Ben Sasi, G. Fengshou, L. Yuhua, and A.D. Ball, “A validated model for the prediction of rotor bar failure in squirrel-cage motors using instantaneous angular speed”, Mech. Syst. Sig. Process. 20, 1572–1589 (2006).
  • [9] C. Hong-Chan, L. Shang-Chih, K. Cheng-Chien, and L. Chun-Yu, “Fuzzy Theory-Based Partial Discharge Technique for Operating State Diagnosis of High-Voltage Motor”, Int. J. Fuzzy Syst. 18, 1092–1103 (2016).
  • [10] A.M. da Silva, R.J. Povinelli, and N.A.O. Demerdash, “Rotor Bar Fault Monitoring Method Based on Analysis of Air-Gap Torques of Induction Motors”, IEEE Trans. Ind. Inf. 9, 2274–2283 (2013).
  • [11] F. Filippetti, M. Martelli, G. Franceschini, and C. Tassoni, “Development of expert system knowledge base to on-line diagnosis of rotor electrical faults of induction motors”, Conference Record of the 1992 IEEE Industry Applications Society Annual Meeting, 1992, pp. 92‒99.
  • [12] G.H. Bazan, P.R. Scalassara, W. Endo, A. Goedtel, W.F. Godoy, and R.H. Cunha Palácios, “Stator fault analysis of three-phase induction motors using information measures and artificial neural networks”, Electr. Power Syst. Res. 143, 347–356 (2017).
  • [13] A.K. Verma, S. Sarangi, and M. Kolekar, “Misalignment Faults Detection in an Induction Motor Based on Multi-scale Entropy and Artificial Neural Network”, Electr. Power Compon. Syst. 44, 916‒927 (2016).
  • [14] C. Hong-Chan, L. Shang-Chih, K. Cheng-Chien, and H. Cheng-Fu, “Induction Motor Diagnostic System Based on Electrical Detection Method and Fuzzy Algorithm”, Int. J. Fuzzy Syst. 18, 732–740 (2016).
  • [15] A.G.A. Cruz, R.D. Gomes, F.A. Belo, and A.C.A. Lima Filho, “Hybrid System Based on Fuzzy Logic to Failure Diagnosis in Induction Motors”, IEEE Lat. Am. Trans. 15, 1480–1489 (2017).
  • [16] R. Dash and B. Subudhi, “Stator inter-turn fault detection of an induction motor using neuro-fuzzy techniques”, Arch. Control Sci. 20(LVI), 363–376 (2010).
  • [17] M. Moghadasian, S.M. Shakouhi, and S.S. Moosavi, “Induction motor fault diagnosis using ANFIS based on vibration signal spectrum analysis”, 3rd International Conference on Frontiers of Signal Processing (ICFSP), Paris, France, 2017.
  • [18] A. Widodo, B-S. Yang, and T. Han, “Combination of independent component analysis and support vector machines for intelligent faults diagnosis of induction motors”, Expert Syst. Appl. 32, 299–312 (2007).
  • [19] H. Razik, M.B. de Rossiter Correa, and E.R.C. da Silva, “A Novel Monitoring of Load Level and Broken Bar Fault Severity Applied to Squirrel-Cage Induction Motors Using a Genetic Algorithm”, IEEE Trans. Ind. Electron. 56, 4615–4626 (2009).
  • [20] M.Y. Kaikaa, M. Hadjami, and A. Khezzar, “Effects of the simultaneous presence of static eccentricity and broken rotor bars on the stator current of induction machine”, IEEE Trans. Ind. Electron. 61, 2452–2463 (2014).
  • [21] B. Cai, L. Huang, and M. Xie, “Bayesian Networks in Fault Diagnosis”, IEEE Trans. Ind. Inf. 13, 2227–2240 (2017).
  • [22] A. Lakehal, Z. Chelli, and Y. Djeghader, “A Hybrid Bayesian Network Based Method to Assess and Predict Electrical Power Network Reliability”, 4th World Conference on Complex Systems (WCCS), Morocco, 2019.
  • [23] A. Lakehal and F. Tachi, “Bayesian Duval Triangle Method for Fault Prediction and Assessment of Oil Immersed Transformers”, Meas. Control 50, 103–109 (2017).
  • [24] Y. Zheng, S. Mao, S. Liu, D.S.H. Wong, and Y.W. Wang, “Normalized Relative RBC-Based Minimum Risk Bayesian Decision Approach for Fault Diagnosis of Industrial Process”, IEEE Trans. Ind. Electron. 63, 7723–7732 (2016).
  • [25] IEEE 493‒1997 – IEEE Recommended Practice for the Design of Reliable Industrial and Commercial Power Systems (Gold Book)
  • [26] A.H. Bonnett and C. Yung, “Increased efficiency versus increased reliability”, IEEE Ind. Appl. Mag. 1077–2618 (2008).
  • [27] S.A.S.A. Kazzaz and G.K. Singh, “Experimental investigations on induction machine condition monitoring and fault diagnosis using digital signal processing techniques”, Electr. Power Syst. Res. 65, 197–221 (2013).
  • [28] ISO 10816, Mechanical vibration – Evaluation of machine vibration by measurements on non-rotating parts. https://www.iso.org.
  • [29] S. Karmakar, S. Chattopadhyay, M. Mitra, and S. Sengupta, “Induction Motor Fault Diagnosis – Approach through Current Signature Analysis”, Springer Science Business Media Singapore, 2016.
  • [30] A. Lakehal, A. Ramdane, and F. Tachi, “Probabilistic Reasoning for Improving the Predictive Maintenance of Vital Electrical Machine: Case Study,” Journal of Advanced Engineering and Computation 2, 9‒17 (2018).
  • [31] A. Ramdane, A. Lakehal, R. Kelaiaia, and S. Saad, “A Bayesian Information System for Predicting Stator Faults in Induction Machines,” Acta Universitatis Sapientiae Electrical and Mechanical Engineering 10, 67‒76 (2018).
  • [32] A. Lakehal and A. Ramdane, “Fault prediction of induction motor using Bayesian network model,” International Conference on Electrical and Information Technologies (ICEIT), Rabat, 2017, pp. 1‒5.
Uwagi
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Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
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Bibliografia
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