References
- [1] Mehrjou, M.R., Mariun, N., Misron, N., Radzi, M., Musa, S. (2017). Broken rotor bar detection in LSPMSM based on startup current analysis using wavelet entropy features. Applied Sciences, 7 (8), 845.
- [2] Xu, X., Han, Q., Chu, F. (2018). Review of electromagnetic vibration in electrical machines. Energies, 11 (7), 1779.
- [3] Duan, Z., Wang, N., Fu, J., Zhao, W., Duan, B., Zhao, J. (2018). High precision edge detection algorithm for mechanical parts. Measurement Science Review, 18 (2), 65-71.
- [4] Xiaohua, B., Lu, Q. (2013). Review and prospect of airgap eccentricity faults in induction machines. Proceedings of the CSEE, 33 (6), 93-100. (in Chinese)
- [5] Bruzzese, C. (2014). Diagnosis of eccentric rotor in synchronous machines by analysis of split-phase currents - Part I: Theoretical analysis. IEEE Transactions on Industrial Electronics, 61 (8), 4193-4205.
- [6] Bruzzese, C. (2014). Diagnosis of eccentric rotor in synchronous machines by analysis of split-phase currents - Part II: Experimental analysis. IEEE Transactions on Industrial Electronics, 61 (8), 4206-4216.
- [7] Torkaman, H., Afjei, E., Yadegari, P. (2012). Static, dynamic, and mixed eccentricity faults diagnosis in switched reluctance motors using transient finite element method and experiments. IEEE Transactions on Magnetics, 48 (8), 2254-2264.
- [8] Wu, Y., Li, Y. (2016). Diagnosis of short circuit faults within turbogenerator excitation winding based on the expected electromotive force method. IEEE Transactions on Energy Conversion, 31 (2), 706-713.
- [9] Zhang, G.T., Wu, J.Y., Hao, L.L. (2017). Fast calculation model and theoretical analysis of rotor unbalanced magnetic pull for inter-turn short circuit of field windings of non-salient pole generators. Energies, 10 (5), 732.
- [10] Xie, Y., Zhang, T. (2015). A fault diagnosis approach using SVM with data dimension reduction by PCA and LDA method. In Chinese Automation Congress (CAC), Wuhan, China. IEEE, 869-874.
- [11] Glowacz, A. (2019). Fault diagnosis of the single-phase induction motor using acoustic signals. Mechanical Systems and Signal Processing, 117, 65-80.
- [12] Gritli, Y., Rossi, C., Casadei, D., Filippetti, F., Capolino, G.A. (2017). A diagnostic space vector-based index for rotor electrical fault detection in wound-rotor induction machines under speed transient. IEEE Transactions on Industrial Electronics, 64 (5), 3892-3902.
- [13] Ibrahim, R., Watson, S., Djurovic, S., Crabtree, C. (2018). An effective approach for rotor electrical asymmetry detection in wind turbine DFIGs. IEEE Transactions on Industrial Electronics, 65 (11), 8872 - 8881.
- [14] Youn, Y.W., Hwang, D.H., Song, S.J., Kim, Y.H. (2018). Detection and classification of demagnetization and short-circuited turns in permanent magnet synchronous motors. Journal of Electrical Engineering & Technology, 13 (4), 1613-1621.
- [15] Chandra, N.H., Sekhar, A.S. (2016). Fault detection in rotor bearing systems using time frequency techniques. Mechanical Systems & Signal Processing, 72-73, 105-133.
- [16] Li, H., Li, M., Li, C., Li, F., Meng, G. (2017). Multifaults decoupling on turbo-expander using differentialbased ensemble empirical mode decomposition. Mechanical Systems and Signal Processing, 93, 267-280.
- [17] Ebrahimi, R., Ghayour, M., Khanlo, H.M. (2018). Nonlinear dynamic analysis and experimental verification of a magnetically supported flexible rotor system with auxiliary bearings. Mechanism and Machine Theory, 121, 545-562.
- [18] Guo, D., Chu, F., Chen, D. (2002). The unbalanced magnetic pull and its effects on vibration in a threephase generator with eccentric rotor. Journal of Sound and Vibration, 254 (2), 297-312.
- [19] Xiang, C., Liu, F., Liu, H., Han, L., Zhang, X. (2016). Nonlinear dynamic behaviors of permanent magnet synchronous motors in electric vehicles caused by unbalanced magnetic pull. Journal of Sound & Vibration, 371, 277-294.
- [20] Jiang, J.W., Sathyan, A., Dadkhah, H., Bilgin, B., Emadi, A. (2016). Analysis of unbalanced magnetic pull in eccentric interior permanent magnet machines with series and parallel windings. IET Electric Power Applications, 10 (6), 526-538.
- [21] Di, C., Bao, X., Wang, H., Lv, Q., He, Y. (2015). Modeling and analysis of unbalanced magnetic pull in cage induction motors with curved dynamic eccentricity. IEEE Transactions on Magnetics, 51 (8), 8106507.
- [22] Xianguang, L., Yong, Y. (2017). Research on the vibration properties of hob spindle for CNC gear hobbing machine. Journal of Mechanical Engineering, 53 (1), 130-139. (in Chinese)
- [23] Amirat, Y., Benbouzid, M.E.H., Bensaker, B., Wamkeue, R. (2007). Condition monitoring and ault diagnosis in wind energy conversion systems: A review. In IEEE International Electric Machines & Drives Conference, Antalya, Turkey. IEEE, 1434-1439.
- [24] Liu, C.Y., Zheng, F., Wang, L.P. (2018) Vibration transmission mechanical model between the shaft and housing of a high speed motor spindle. Journal of Tsinghua University (Science and Technology), 58 (7), 671-676. (in Chinese)
- [25] Xu, X., Han, Q., Chu, F. (2018). A general electromagnetic excitation model for electrical machines considering the magnetic saturation and rub impact. Journal of Sound and Vibration, 416, 154-171.
- [26] Gu, Y., Ma, Y., Ren, G. (2017). Stability and vibration characteristics of a rotor-gas foil bearings system with high-static-low-dynamic-stiffness supports. Journal of Sound & Vibration, 397, 152-170.
- [27] Miraskari, M., Hemmati, F., Gadala, M.S. (2017). Nonlinear dynamics of flexible rotors supported on journal bearings - Part I: Analytical bearing model. Journal of Tribology, 140 (2), 021704.
- [28] Miraskari, M., Hemmati, F., Gadala, M.S. (2017). Nonlinear dynamics of flexible rotors supported on journal bearings - Part II: Numerical bearing model. Journal of Tribology, 140 (2), 021705.
- [29] Han, X., Palazzolo, A. (2016). Unstable force analysis for induction motor eccentricity. Journal of Sound & Vibration, 370, 230-258.
- [30] Yu-Ling, H., Wei-Qi, D., Bo, P., Meng-Qiang, K., Gui- Ji, T., Shu-Ting, W. (2016). Stator vibration characteristic identification of turbogenerator among single and composite faults composed of static air-gap eccentricity and rotor interturn short circuit. Shock and Vibration, 2016, 5971081.
- [31] Hawwooi, C., Shek, J.K.H. (2018). Calculation of unbalanced magnetic pull in induction machines through empirical method. IET Electric Power Applications, 12 (9),1233-1239.
- [32] Bai, Y., Yang, B., Li, H. (2018). Analysis of nonlinear vibration in permanent magnet synchronous motors under unbalanced magnetic pull. Applied Sciences, 8 (1), 113.
- [33] Li, Y.X., Zhu, Z.Q. (2017). Cogging torque and unbalanced magnetic force prediction in pm machines with axial-varying eccentricity by superposition method. IEEE Transactions on Magnetics, 53 (11), 1400404.
- [34] Megha, S., Abdul, G.S. (2019). Faulty bearing detection, classification and location in a three-phase induction motor based on Stockwell transform and support vector machine. Measurement, 131, 524-533.
- [35] Zhang, S.J., Yu, J.J., To, S., Xiong, Z.W. (2018). A theoretical and experimental study of spindle imbalance induced forced vibration and its effect on surface generation in diamond turning. International Journal of Machine Tools & Manufacture, 133, 61-71.
- [36] Anandan, K.P., Ozdoganlar, O.B. (2013). Analysis of error motions of ultra-high-speed (UHS) micromachining spindles. International Journal of Machine Tools and Manufacture, 70, 1-14.
- [37] Zhang, P., Chen, Y. (2018). Analysis of error motions of axial locking-prevention hydrostatic spindle. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, 233 (1), 3-17.
- [38] Nishiguchi, T., Sato, R., Shirase, K. (2017). Evaluation of axial displacement caused by rotary axis motion direction change in five-axis controlled machining centers. Journal of the Japan Society for Precision Engineering, 83 (9), 893-898.
- [39] Huang, S., Huang, K., Chao, K. (2016). Fault analysis and diagnosis system for induction motors. Computers & Electrical Engineering, 54, 195-209.