Proposed Fault Detection Algorithm with Optimized Hybrid Speed Control-Reference-Cited by-同舟云学术

Proposed Fault Detection Algorithm with Optimized Hybrid Speed Control

Published:2024-04-11 Issue: Volume:19 Page:39-50
ISSN:2224-2856
Container-title:WSEAS TRANSACTIONS ON SYSTEMS AND CONTROL
language:en
Short-container-title:

Author:

Baba Mariem Ahmed¹,Naoui Mohamed²,Abbou Ahmed¹,Cherkaoui Mohamed¹

Affiliation:

1. Engineering for Smart and Sustainable Systems Research Center, Mohammadia School of Engineers, Mohammed V University, BP: 765, Av. Ibn Sina, Agdal - Rabat, MOROCCO

2. Research Unit of Energy Processes Environment and Electrical Systems, National Engineering School of Gabes, University of Gabés, Gabés 6029, TUNISIA

Abstract

The Brushless DC (BLDC) motor is a common choice for industrial applications, particularly in the automotive sector, owing to its high efficiency and robust capabilities. To detect the position of the motor rotor, hall-effect sensors can be used, but these sensors may prevent the system from operating if they fail. Consequently, fault-tolerant control (FTC) has been proposed in several studies to ensure continuity of operation in the event of sensor failure. This paper proposes an innovative method of fault detection in the hall effect sensor for a BLDC motor using combinatorial functions. This paper proposes an innovative method of hall-effect sensor fault detection for a BLDC motor using combinatorial functions. For the speed control of the BLDC under study, a hybrid adaptive neuro-fuzzy inference control (ANFIS) is implemented. In addition, the FTC signal reconstruction technique adopted has been improved to achieve motor start-up despite a fault in one of the sensors, thanks to well-defined fault detection algorithms. Simulation results are presented for each sensor failure case to test the effectiveness of the method used.

Publisher

World Scientific and Engineering Academy and Society (WSEAS)

Reference32 articles.

1. Alsayid, B., Salah, W. A., & Alawneh, Y. (2019). Modeling of censored speed control of BLDC motor using MATLAB/SIMULINK. International Journal of Electrical and Computer Engineering, 9(5), 3333.

2. Singh, B., & Singh, S. (2009). State-of-art on permanent magnet brushless DC motor drives. Journal of power electronics, 9(1), 1- 17.

3. Boldyriev, S., Steshenko, T., Serohina, S., Fomina, S., & Kapelista, I. (2024). Exercise of State Control over Local Self-Government in the Field of Environmental Protection. WSEAS Transactions on Environment and Development, 20, 26-36, DOI: 10.37394/232015.2024.20.4.

4. Godfrey, A. J., & Sankaranarayanan, V. (2018). A new electric braking system with energy regeneration for a BLDC motor-driven electric vehicle. Engineering Science and Technology, an international journal, 21(4), 704-713, https://doi.org/10.1016/j.jestch.2018.05.003.

5. Minh, D. B., Quoc, V. D., & Huy, P. N. (2021). Efficiency Improvement of Permanent Magnet BLDC Motors for Electric Vehicles. Engineering, Technology & Applied Science Research, 11(5), 7615-7618.