Since the 19th century, the use of electric motors continues to grow. Nowadays electric motors have been widely used in various fields of industry. One type of electric motor that is often used is an induction motor. Induction motors work in the presence of induced currents due to the relative difference in rotor rotation with rotating magnetic fields. Induction motors are preferred for industrial purposes because of low cost, easy to maintain, and high efficiency. Induction motors that are used continuously can experience several types of fault. The existence of fault can affect the performance of the induction motor. One of the fault that often occurs in induction motor is the result of stator inter-turn fault. This fault is caused by the gradual deterioration of insulation in the stator winding which cause a short-circuit. Sooner or later, this fault can cause damage to the induction motor in a short time if left unchecked. So, it is very important to monitor the fault in real-time. Therefore, this research proposes a fault estimation method on induction motor. The design of fault estimation based on particle filtering and extended state space equations is used to estimate the stator inter-turn fault. The effectiveness of this approach is validated by use of a computer simulation with using two fault signal represented by η_cc ramp and step signal. The performances of this fault estimation are measured by RMSE and with using 500 particles has smallest RMSE value, which are 0.0112 and 0.0124 for dq current fault when using η_cc ramp signal and 0.2373 and 0.2367 for dq current fault when using η_cc step signal.

Induction Motor; Particle Filtering; Stator Inter-Turn Fault

T. Yektaniroumand, M. N. Azari, and M. Gholami, “Optimal Rotor Fault Detection in Induction Motor Using Particle-Swarm Optimization Optimized Neural Network,” Int. J. Eng., vol. 31, no. 11, pp. 1876–1882, 2018.

G. B. Kliman, W. J. Premerlani, R. A. Koegl, and D. Hoeweler, “A new approach to on-line turn fault detection in AC motors,” pp. 687–693, 2002.

J. Yun, K. Lee, K. W. Lee, S. Bin Lee, and J. Y. Yoo, “Detection and classification of stator turn faults and high-resistance electrical connections for induction machines,” IEEE Trans. Ind. Appl., vol. 45, no. 2, pp. 666–675, 2009.

S. Williamson and K. Mirzoian, “Analysis of Cage Induction Motors with Stator Winding Faults Line-End Coils of Induction Motors,” no. July, pp. 50–51, 1985.

C. Andrieu, A. Doucet, and S. S. Singh, “Particle Methods for Change Detection , System Identification , and Control,” Proc. IEEE, vol. 92, no. 3, pp. 423–438, 2004.

T. F. Chan and K. Shi, Applied Intelligent Control of Induction Motor Drives. 2011.

E. Schaeffer and S. Bachir, “Modeling Induction Machine Winding Faults for Diagnosis,” in Electrical Machine Diagnosis, 2013, pp. 23–68.

K. Ogata, Modern Control Engineering, 3rd ed. New Jersey: Prentice Hall, 1997.

K. Indriawati, T. Agustinah, and A. Jazidie, “Robust Observer-Based Fault Tolerant Tracking Control for Linear Systems with Simultaneous Actuator and Sensor Faults: Application to a DC Motor System,” Int. Rev. Model. Simulations, vol. 8, pp. 410–417, 2020.

N. K. Ki and E. J. Delp, “New Models For Real-Time Tracking Using Particle Filtering,” Proc. SPIE, vol. 7257, 2009.

N. J. Gordon, D. J. Salmond, and A. F. M. Smith, “Novel approach to nonlinear/non-Gaussian Bayesian state estimation,” IEE Proc. F - Radar Signal Process., vol. 140, pp. 107–113, 1993.

T. B. Schön, “Solving Nonlinear State Estimation Problems Using Particle Filters - An Engineering Perspective Abstract,” 2010.

S. Allaoui, K. Chafaa, Y. Laamari, and B. Athamena, “Induction Motor State Estimation using Tuned Extended Kalman Filter,” 2015 4th Int. Conf. Electr. Eng., pp. 1–5, 2015.