Three-Phase Pole-Changing Winding with Ratio of Poles 4:6

Yıl 2024, Cilt: 3 Sayı: 1, 38 - 47, 28.05.2024

Makhsud Bobojanov Dauletbek Rismukhamedov Furkat Tuychiev Khusniddin Shamsutdinov

Öz

The development and analysis of a new pole-changing winding with pole ratio 2p1/2p2=4/6, as well as the experimental research of a two-speed induction motor with this winding, involved the use of modernized methods such as Discretely Specified Spatial Function (DSSF). These methods have been used to develop pole-changing winding designs for two-speed induction motors with improved electromagnetic properties, closely resembling conventional windings. The new pole-changing winding could be aviable alternative to conventional two-layer windings, as it offers similar electromagnetic properties. Furthermore, the new pole-changing winding was analyzed using ANSYS/Maxwell and tested on an induction motor built on the base of a 1,5 kW/1500 rpm induction motor in frame 4A80U3, developing 1,1 kW/0,7 kW rated power for 2p1/2p2=4/6 poles, respectively. Overall, this research demonstrates the potential for developing advanced pole-changing windings with improved electromagnetic properties and their application in practical induction motors.

Anahtar Kelimeler

Induction motor, pole-changing winding, discretely specified spatial function, winding factor

Teşekkür

The group of authors of the article expresses its gratitude to the staff of the Department of Electric Power Supply and the rector of the Tashkent State Technical University for the support provided during scientific research, as well as to the Organizing Committee of the Congress for their help and support.

Kaynakça

• M. van Werkhoven, C. U. Brunner, “Policy Guidelines for Motor Driven Units,” 4E Electric Motor Systems Annex (EMSA), Part 2, 2018, https://www.iea-4e.org/wp-content/uploads/ 2020/12/PGMdu_Final_250418.
• N. I. Bogatyrev, A. S. Kreymer, V. N. Vanurin, K. A. Dganibekov, “Modulated stator windings of the motor for fan drives,” Polythematic Online Scientific Journal of Kuban State Agrarian University, vol. 118, no. 4, pp. 1441-1458, 2016.
• M. Bobojanov, D. Rismuxamedov, F. Tuychiev, Kh. Shamsutdinov, Kh. Magdiev, “Pole-changing motor for lift installation,” E3S Web of Conference, Kazan, Russia, 2020, vol. 216, pp.1-5.
• H. Auinger, “Polumschaltbare dreiphasenwicklung mit 6 klemmen ubersicht zum stand der technik,” Bulletin des Schweizerischen Elektrotechnischen Vereins, vol. 69, no. 17, pp. 926-932, 1978.
• J. H. H. Alwash, K. S. Ismail, J. F. Eastham, “A novel 16/6 phase modulated winding,” IEEE Trans. on Energy Conversion, vol. 15, no. 2, pp. 188–190, Jun. 2000.
• C. Kovacs, “Pole-changing windings for close ratio and 1:N ratio using the 3//Y/3//Y method,” Advances in Science, Technology and Engineering Systems Journal, vol. 3, no. 4, pp. 241-253, 2018.
• J. Portos, M. P. Reddy, D. Eaton, “Application and advantages of PAM multi speed motors in petroleum and chemical industries,” 2010 Record of Conference Papers Industry Applications Society 57th Annual Petroleum and Chemical Industry Conference (PCIC), San Antonio, TX, USA, Sep. 2010, pp. 1-10.
• L. M. Melcescu, M. V. Cistelecan, O. Craiu, H. B. Cosan, “A new 4/6 pole-changing double layer winding for three phase electrical machines,” The XIX International Conference on Electrical Machines (ICEM), Rome, Italy, Sep. 2010, pp. 1-6.
• A. R. W. Broadway, K. S. Ismail, “Phase modulated 3-phase pole changing windings,” IEE Proceedings B (Electric Power Applications), vol. 133, no. 2, pp. 61-70, Mar. 1986.
• H. Liu, J. Wang, Z. Zhang, “Performance analysis of variable speed multiphase induction motor with pole phase modulation,” Archives of electrical engineering, vol. 65, no. 3, pp. 425-436, 2016.
• D. A. Popov, S. D. Popov, “Three-Phase Pole-Changing Winding with a Pole Pair Ratio p1:p2 = 1:2,” RF patent №2012981, 15 May 1994.
• Kh. G. Karimov, A. Tupoguz, “Method for designing electrically aligned windings in ac machines,” Electricity, vol. 9, pp. 29-38, 1987.
• M. Bobojanov, “Electrical Machines with Pole-changing Windings Using with Aim of Energy and Resource Saving,” Tashkent, Uzbekistan, Fan va texnologiyalar markazi, 2012.
• D. Rismuhamedov, F. Tuychiev, S. Rismuhamedov, “Pole-changing windings for turbomechanism engines,” IOP Conference Series: Materials Science and Engineering, Tashkent, 2020, pp. 1-8.
• M. Bobojanov, “Induction machine with pole-changing winding for turbomechanisms,” Archives of Electrical Engineering, vol. 72, no. 2, pp. 415 –428, Jun. 2023.
• F. N. Tuychiev, “Three-phase pole-changing winding for asynchronous machines on the fan drive,” AIP Conf. Proc., Jan. 2023, vol. 2552, no. 1, p. 030013.
• M. Caruso, A. O. Di Tommaso, F. Marignetti, R. Miceli, G. R. Galluzzo, “A general procedure for the construction of gorges polygons for multi-phase windings of electrical machines,” Thirteenth International Conference on Ecological Vehicles and Renewable Energies (EVER), Monte Carlo, Monaco, Apr. 2018, pp. 1-7.
• J. W. Kelly, E. G. Strangas, J. M. Miller, “Control of a continuously operated pole-changing induction machine,” IEMDC’03, Madison, WI, USA, Jun. 2003, pp. 211-217.
• D. Rismukhamedov, Kh. Shamsutdinov, S. Ganiev, Kh. Magdiev, Sh. Khusanov, “New pole-changing winding for electric drive of ball mills,” E3S Web of Conf., Apr. 2023, vol. 384, pp. 1-6.
• М. K. Bobojanov, D. A. Rismukhamedov, F. N. Tuychiev, H. F. Shamsutdinov, “Development of new pole-changing winding for lifting and transport mechanisms,” E3S Web of Conf., Jan. 2023, vol. 365, pp. 1-10.