Features of Formation of Dynamic Modes of Asynchronous Motors when Started from One Device
Keywords:
Keywords: dynamic modes, asynchronous motor, network connection, starting conditions, motor coasting, transient processes, initial electromagnetic conditions.
Abstract
Abstract. The article solves the problem of forming dynamic modes of induction motors during starting from a single starting device. A mathematical description of the processes of disconnection from the power supply network and coasting of induction motors is performed. An analysis of the shape and magnitude of the voltage on the switching elements during coasting is carried out. An assessment of the influence of motor power on the transient processes of connection to the power supply network is given. Recommendations are given for ensuring favorable conditions for connecting induction motors to the power supply network, taking into account the capabilities of semiconductor starting devices and the use of contact equipment.
References
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9. Wang, S., Lee, F., C., Wyk, J., D. (2016). Inductor winding capacitance cancellation using mutual capacitance concept for noise reduction application. IEEE Transactions on Electromagnetic Compatibility, 48(2), 311-318. doi: 10.1109/TEMC.2006.873867
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11. Boiko, A., A., Besarab, A., N., Sokolov, Y., A., Shapa, L., N. (2019). Improvement of Energy Indicators of Asynchronous Motor under the Conditions of Asymmetric Voltage Supply. Problemele Energeticii Regionale, no. 1–1 (40), 25–35. doi: 10.5281/zenodo.3239133
12. Lekhchine, S., Bahi, T., Laouar, I., Leulmi, R. (2023). Control and Optimization for a Photovoltaic Pumping System Using Induction Motor Vector Control. 14th International Renewable Energy Congress, 307-324. doi: 10.1109/IREC59750.2023.10389517
13. Andryushchko, O., A., Boiko, A., A. Analiz protsesov otklyucheniya ot seti I vybega asinkhronogo dvigatelya [Analysis of the processes of disconnection from the mains and coasting of an asynchronous motor]. – Elektromashinostroenie I elektrooborudovanie – Electrical engineering and electrical equipment, 2012, no. 69, pp. 28-31. (In Russian).
14. Sunal, C., E., Dyo, V., Velisavljevic, V. (2022). Review of Machine Learning Based Fault Detection for Centrifugal Pump Induction Motors. IEEE Access, vol. 10, 71344 – 71355. doi: 10.1109/ACCESS.2022.3187718
15. Rao, Y., R. Current Based Restarting Method for Rotating Sensorless Induction Motor Drive. IEEE Transactions on Energy Conversion, vol. 38, 2239– 2242. doi: 10.1109/TEC.2023.3289065
16. Boiko, A., Naidenko, E., Besarab, A., Maevskaya, E. (2024). Study of Starting and Disconnecting Modes of an Asynchronous Electric Drive of a Centrifugal Pump. E-Journal «Problemele energeticii regionale», № 2 (62), 28 — 37. doi.org/10.52254/1857-0070.2024.2-62.03
17. Lee, К., Lukic, S., Sara, A. (2016). A universal restart strategy for induction machines. IEEE Energy Conversion Congress and Exposition (ECCE), 1344 – 1359. doi: 10.1109/ECCE.2016.7854802
2. Xuesong., Z., Youjie., M., Zhiqiang G., Shaoweiy., Z. (2017). Reactive power compensation in motor. 2017 IEEE International Conference on Mechatronics and Automation (ICMA), 1134-1151. doi: 10.1109/ICMA.2017.8015831
3. Langlang., G., Dezetty., M., Mokhammad,. S., Stieven, N., R. (2020). Transient in Electrical Power System under Large Induction Motor Starting Condition. 2020 2nd International Conference on Cybernetics and Intelligent System (ICORIS), 1-5. doi: 10.1109/ICORIS50180.2020.9]320791
4. Malyar, V., Hamola, O., Maday, V., Vasylchyshyn, I. (2019) Static Characteristics of Asynchronous Motors with Series Reactive Power Compensation. 2019 9th International Conference on Advanced Computer Information Technologies (ACIT), 141-144. doi: 10.1109/ACITT.2019.8780064
5. Wang, D., Zhao, J. (2020). Self-excitation Control of Squirrel-Cage Induction Motor based on Super-Twisting Sliding Mode Algorithm. 2020 IEEE International Conference on Artificial Intelligence and Information Systems (ICAIIS), 500-504. doi: 10.1109/ICAIIS49377.2020.9194868
6. Michaelides, A., Nicolaou, T. (2017). Starting and running the induction motor with a variable capacitor. 2017 14th International Conference on Engineering of Modern Electric Systems (EMES), 87-90. doi: 10.1109/EMES.2017.7980388
7. Guha, A., Narayanan, G. (2018). Impact of Undercompensation and Overcompensation of Dead-Time Effect on Small-Signal Stability of Induction Motor Drive. IEEE Transactions on Industry Applications, 1-1. doi: 10.1109/TIA.2018.2846719
8. Yin, S., Xia, J., Zhao, Z. (2020). Fast Restarting of Free-Running Induction Motors Under Speed-Sensorless Vector Control. IEEE Transactions on Industrial Electronics, vol. 67, 6124 – 6134. doi: 10.1109/TIE.2019.2934077
9. Wang, S., Lee, F., C., Wyk, J., D. (2016). Inductor winding capacitance cancellation using mutual capacitance concept for noise reduction application. IEEE Transactions on Electromagnetic Compatibility, 48(2), 311-318. doi: 10.1109/TEMC.2006.873867
10. Ejiogu, E., C., Tanno, Y. (1993). Capacitor self-excitation braking of the induction motor. Proceedings of IECON Annual Conference of IEEE Industrial Electronics, vol. 2, 891-895. doi: 10.1109/IECON.1993.339157
11. Boiko, A., A., Besarab, A., N., Sokolov, Y., A., Shapa, L., N. (2019). Improvement of Energy Indicators of Asynchronous Motor under the Conditions of Asymmetric Voltage Supply. Problemele Energeticii Regionale, no. 1–1 (40), 25–35. doi: 10.5281/zenodo.3239133
12. Lekhchine, S., Bahi, T., Laouar, I., Leulmi, R. (2023). Control and Optimization for a Photovoltaic Pumping System Using Induction Motor Vector Control. 14th International Renewable Energy Congress, 307-324. doi: 10.1109/IREC59750.2023.10389517
13. Andryushchko, O., A., Boiko, A., A. Analiz protsesov otklyucheniya ot seti I vybega asinkhronogo dvigatelya [Analysis of the processes of disconnection from the mains and coasting of an asynchronous motor]. – Elektromashinostroenie I elektrooborudovanie – Electrical engineering and electrical equipment, 2012, no. 69, pp. 28-31. (In Russian).
14. Sunal, C., E., Dyo, V., Velisavljevic, V. (2022). Review of Machine Learning Based Fault Detection for Centrifugal Pump Induction Motors. IEEE Access, vol. 10, 71344 – 71355. doi: 10.1109/ACCESS.2022.3187718
15. Rao, Y., R. Current Based Restarting Method for Rotating Sensorless Induction Motor Drive. IEEE Transactions on Energy Conversion, vol. 38, 2239– 2242. doi: 10.1109/TEC.2023.3289065
16. Boiko, A., Naidenko, E., Besarab, A., Maevskaya, E. (2024). Study of Starting and Disconnecting Modes of an Asynchronous Electric Drive of a Centrifugal Pump. E-Journal «Problemele energeticii regionale», № 2 (62), 28 — 37. doi.org/10.52254/1857-0070.2024.2-62.03
17. Lee, К., Lukic, S., Sara, A. (2016). A universal restart strategy for induction machines. IEEE Energy Conversion Congress and Exposition (ECCE), 1344 – 1359. doi: 10.1109/ECCE.2016.7854802
Published
2025-10-03
Section
Automated Electromechanical Systems
This work is licensed under a Creative Commons Attribution 4.0 International License.
