INTEGRATION OF RESEARCH RESULTS IN THE PRODUCTION OF THE SYNCHRONOUS MOTOR FOR ELECTRIC BUSES

Authors

  • EMIL TUDOR National Research and Development Institute for Electrical Engineering ICPE-CA
  • MARIANA ARSENE UMEB Electromotoren, Bucharest
  • IULIAN BERCA Joule Motors
  • ALEXANDR-IONEL CONSTANTIN National Research and Development Institute for Electrical Engineering ICPE-CA, Bucharest
  • CONSTANTIN DUMITRU National Research and Development Institute for Electrical Engineering ICPE-CA, Bucharest
  • MIHAITA-ALEXANDRU ILIE National Research and Development Institute for Electrical Engineering ICPE-CA, Bucharest

DOI:

https://doi.org/10.36801/

Keywords:

Synchronous motor, Electric bus

Abstract

The historical manufacturer of electric traction machines for trams and trolleybuses, the innovative commercial company UMEB, has initiated a joint project with the National Institute of Research and Development for Electrical Engineering ICPE-CA, to design and produce a new line of electric machines that achieve the desired power, starting torque, speed range, and operating temperatures. Following the requests received by UMEB from the integrators of vehicles for the transport of people, the need arose to produce an electric motor characterized by a high torque density and a wide range of operating speeds. The development team selected the technical solution of a permanent magnet and liquid-cooled synchronous motor, carried out the design theme, motor sizing, numerical simulation validation of the project, motor component design, execution, assembly of the prototype motor, and its testing. The resulting TN-EB 21 prototype engine is presented during this innovative development process.

References

(1) M.J. Soleimani Keshayeh*, S. Asghar Gholamian„Optimum Design of a three - phase permanent magnet synchronous motor for industrial applications, International Journal of Applied Operational Research, 2, 4, pp. 67-86, 2013

(2) *** https://en.engineering-solutions.ru/motorcontrol/pmsm/ Permanent magnet synchronous motor

(3) Phuong Thi Luu, Ji-Young Lee, Ji-Heon Lee, Byung-Chul Woo, Design and analysis of a permanent magnet synchronous motor considering axial asymmetric position of rotor to stator, International Conference on Electrical Machines and Systems (ICEMS), 7–10; pp. 37–40, Jeju-do, South Korea, July 2018.

(4) Dr. A. Sheela, M. Atshaya Mohan, Design of permanent magnet synchronous motor for electric vehicle application using finite element analysis International Journal Of Scientific & Technology Research, 9, 3, March 2020,

(5) M. Obata, S. Morimoto, M. Sanada, Y. Inoue, Characteristics of PMASynRM with ferrite magnets for EV/HEV applications, the 15th International Conference on Electrical Machines and Systems (ICEMS), 2012.

(6) G. PellegriNo, A. Vagati, P. Guglielmi, B. Boazzo, Performance comparison between surface-mounted and interior PM Motor drives for electric vehicle application, IEEE Transactions on Industrial Electronics, 59, 2.

(7) Sekerák Peter, Hrabovcová Valéria, Rafajdus Pavol, Kalamen Lukáš, Onufer Matúš, Effect of permanent magnet rotor designon PMSM properties, Transactions on electrical engineering, 1, 3, 2012.

(8) Ye Zhen-Nan, Luo Wei-Dong Zhang Wen-Ming, Feng Zhi-Xiang - Simulative analysis of traction motor cooling system based on CFD -, School of Mechanical Engineering University of Science and Technology China, 2011.

(9) A. Semon, L. Melcescu, Optimizarea numerică a inductorului unui motor sincron de tracțiune cu magneți permanenți interiori, Simpozionul de maşini electrice SME’, Octombrie 2015;

(10) Yannis L. Karnavas, Ioannis D. Chasiotis, Emmanouil L. Peponakis, Cooling system design and thermal analysis of an electric vehicle’s in-wheel PMSM, XXII International Conference on Electrical Machines (ICEM), September 2016.

(11) C. Mademlis, N. Margaris, J. Xypteras, Magnetic and thermal performance of a synchronous motor under loss minimization control, IEEE Trans. on Energy Conversion, 15, 2, pp. 135- 142, July 2000.

(12) Liu Qinghua, Analysis, design and control of permanent magnet synchronous motors for wide-speed operation, A Thesis Submitted for the Degree of Doctor of Philosophy Department of Electrical Engineering National Uuniversity of Singapore, 2005

(13) Phuong Thi Luu, Ji-Young Lee, Ji-Heon Lee, Byung-Chul Woo, Design and analysis of a permanent magnet synchronous Motor considering Axial asymmetric position of rotor to stator, International Conference on Electrical Machines and Systems (ICEMS); pp. 37–40, Jeju-do, South Korea, July 2018.

(14) Dr.A.Sheela, M.Atshaya Mohan, Design of permanent magnet synchronous motor for electric vehicle application using finite element analysis, International Journal Of Scientific & Technology Research , 9, 3, March 2020,

(15) Gan Zhang, Wenfei Yu, Wei Hua, Ruiwu Cao, Hongbo Qiu, Aili Guo, The design and optimization of an interior, permanent magnet synchronous machine applied inan electric traction vehicle requiring a lowtorque ripple, Appl. Sci.,9, 3634; 2019.

(16) Caifei Wang, Jianxin Shen, Patrick Chi-Kwong Luk, Weizhong Fei, Mengjia Jin, Design issues of an IPM motor for EPS, COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering, 31, 1, pp. 71 – 87, 2011.

(17) M. Obata, S. Morimoto, M. Sanada, Y. Inoue, Characteristics of PMASynRM with ferrite magnets for EV/HEV applications, the 15th International Conference on Electrical Machines and Systems (ICEMS), 2012.

(18) G. PellegriNo, A. Vagati, P. Guglielmi, B. Boazzo, Performance comparison between surface-mounted and interior PM motor drives for electric vehicle application, IEEE Transactions on Industrial Electronics, 59, 2.

(19) SEKERÁK Peter, HRABOVCOVÁ Valéria, RAFAJDUS Pavol, KALAMEN Lukáš, ONUFER Matúš , Effect of permanent magnet rotor designon PMSM properties, Transactions on Electrical Engineering, 1, 2012.

(20) C. Mademlis, N. Margaris, J. Xypteras, Magnetic and thermal performance of a synchronous motor under loss minimization control, IEEE Trans. on Energy Conversion, 15, 2,pp. 135- 142, , July 2000.

(21) V. Navrapescu, D. Anghel, M. Gudumac, M. Popescu, Actionari electrice de curent continuu - Elemente de Proiectare, ICPE, 2001.

(22) ***IEC 60034-1:2017: Electrical machines: Rating and performance.

(23) ***Altair FluxMotor 2020.1 Documentation, https://www.altair.com/fluxmotor/

(24) C.A. Pîrlea, Stand metrologic inteligent pentru determinarea automată a parametirlor funcţionali ai motoarelor electrice asincrone, Facultatea de Inginerie Electrica, Universitatea Politehnica Bucuresti, 2021.

(25) X. Liu, D. Liang, J. Du, Y. Yu, X. Yang, A torque measuring method based on encoder for permanent magnet synchronous machine, 17th International Conference on Electrical Machines and Systems (ICEMS), pp. 1510-1514, 2014.

(26) M. Enache, A. Campeanu, S. Enache, I. Vlad, Testing stand for low - power electrical machines, International Conference on Applied and Theoretical Electricity (ICATE) ,pp. 1-6, 2017

Downloads

Published

09.03.2023

Issue

Vol. 18 No. 1 (2022): APME

Section

ELECTRIC MACHINES

License

Copyright (c) 2023 ELECTRIC MACHINES, MATERIALS AND DRIVES — PRESENT AND TRENDS

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

How to Cite

INTEGRATION OF RESEARCH RESULTS IN THE PRODUCTION OF THE SYNCHRONOUS MOTOR FOR ELECTRIC BUSES. (2023). ELECTRICAL MACHINES, MATERIALS AND DRIVES — PRESENT AND TRENDS, 18(1), 52-61. https://doi.org/10.36801/