THREE-DIMENSIONAL AIR GAP MAGNETIC DENSITY AND ELECTRONIC FORCE ANALYSIS OF NOVEL BILATERAL LINEAR SYNCHRONOUS MOTOR, 42-47.

Yan Jiang, and Wei An

References

1. [1] W. Nie, Z. Wang, L. Yu, and J. Mu, Sensorless control ofpermanent magnet synchronous motor based on optimization ofnon-singular fast terminal sliding mode observer, MechatronicSystems and Control, 50(3), 2022, 138–144.
2. [2] Z. Yang and T. Cai, Research on the vector control of permanentmagnet synchronous motor based on SVPWM, MechatronicSystems and Control, 48(3), 2020, 199–206.
3. [3] X.Z. Huang, H.C. Yu, B. Zhou, L.Y. Li, D. Gerada, C.Gerada, Z.Y. Qian l, Detent-force minimization of double-sidedpermanent magnet linear synchronous motor by shifting oneof the primary components, IEEE Transactions on IndustrialElectronics, 67(1), 2020, 180–191.
4. [4] R. Parvathy, A.E. Daniel, and N. Muhamed, Analysisof extended-state-observer and active-disturbance-rejection-control in the speed control of dc motor system, MechatronicSystems and Control, 47(2), 2019, 63–70.
5. [5] W.S.K.im, S.Y.Jung, H.Y.Choi, H.K.Jung, J.H. Kim, andS.Y.Hahn, Development of a superconducting linear syn-chronous motor, IEEE Transactions on Applied Superconduc-tivity, 12(1), 2002, 842–845.
6. [6] D. Zhang, C. Sun, X. Hu, and J. Zhang, Cross-couplingsynchronous control of double brushless dc motor based onvariable domain fuzzy PID, Mechatronic Systems and Control,49(1), 2021, 9–16.
7. [7] F. Profumo, A. Teneoni, and G. Gianolioete, Design andperformance evaluation of a PM linear synchronous motorwith magnetic guides for industry applications, Proc. Thirty-Fourth IAS Annual Meeting Industry Applications Conference,Phoenix, AZ, USA, 1999, 110–116.
8. [8] G. Stumberger and D. Zakroete, Design and comparisonof linear synchronous motor and linear induction motorfor electromagnetic aircraft launch system, Proc. IEEEInternational Electric Machines and Drives Conference,Madison, WI, USA, 2003, 494–500.
9. [9] F. Profumo, A. Teneoni, and G. Gianolio, Design andrealization of a PM linear synchronous motor with a veryhigh thrust/normal force ratio, Proc. Thirty-Sixth IAS AnnualMeeting. Conference Record of the 2001 IEEE IndustryApplications Conference, Chicago, IL, USA, 2001, 1984–1988.
10. [10] K. Nakamura, K. Saito, and O. Iehinokura, Dynamics analysisof interior permanent magnet motor based on a magneticcircuit model, IEEE Transactions on Magnetics, 39(5), 2003,3250–3252.
11. [11] B. Kwon, K. Woo, D.J. Kim, and S.C. Park, Finite elementanalysis for dynamic characteristics of an inverter-fed PMLSMby a new moving mesh technique, IEEE Transactions onMagnetics, 36(4), 2000, 1574–1577.
12. [12] M. Platen and G. Henneberger, Examination of leakage and endeffects in a 1inear synchronous motor for vertical transportationby means of finite element computation, IEEE Transactionson Magnetics, 37(9), 2001, 3640–3643.
13. [13] J. Lim, J.H. Jeong, C.H. Kim, C.W. Ha, and D.Y. Park,Analysis and experimental evaluation of normal force of linearinduction motor for maglev vehicle, IEEE Transactions onMagnetics, 53(11), 2017, 2–5.
14. [14] I.S. Jung, S.B. Yoon, J.H. Shim, and D.S. Hyun, Analysisof forces in a short primary type and a short secondarytype permanent magnet linear synchronous motor, IEEETransactions on Energy Conversions, 14(4), 1999, 1265–1270.46
15. [15] R.J. Crusise and C.F. Landy, Reduction of cogging forcesin linear synchronous motors, IEEE AFRICON, 2(3), 1999,623–626.
16. [16] W.J. Jeon, S, Katoh, T. Iwamoto, Y, Kamiya, and T. Onuki,Propulsive characteristics of a novel linear hybrid motor withboth induction and synchronous operation, IEEE Transactionson Magnetics, 35(5), 1999, 4025–4027.
17. [17] J. Hur, S.B. Yoon, D.Y. Hwang, and D.S. Hyun, Analysis ofPMLSM using three dimensional equivalent magnetic circuitnetwork method, IEEE Transactions on Magnetics, 33(5),1997, 4143–4145.
18. [18] A.W. van Zyl, R.J. Cruise, and C.F. Landy, Novel secondarydesign for a linear synchronous motor using a split-pole magnetarrangement, Proc. 5th Africon Conference in Africa, CapeTown, South Africa, 1999, 627–630.
19. [19] A. Takahashi, Y. Ito, and S. Fukuda, Thrust and levitationcontrol of permanent magnet linear synchronous motor usingoptimal regulator theory, Proc. The 29th Annual Conference ofthe IEEE Industrial Electronics Society, Roanoke, VA, USA,2003, 683–687.
20. [20] F.J. Lin, S.Y. Chen, L.T. Teng, and H. Chu, Recurrentfunctional-link-based fuzzy neural network controller withimproved particle swarm optimization for a linear synchronousmotor drive, IEEE Transactions on Magnetics, 45(8), 2009,3151–3165.
21. [21] P.C. Khong, R. Leidhold, and P. Mutschler, Magnetic guidanceof the mover in a long-primary linear motor, IEEE Transactionson Industry Applications, 47(3), 2011, 1319–1327.
22. [22] T.R.F. Neto and P. Mutschler, Combined operation of short-primary permanent magnet linear synchronous motor andlinear induction motor in material handling applications,Proc. Twenty-Seventh Annual IEEE Applied Power ElectronicsConference and Exposition, Orlando, FL, USA, 2012, 915–922.
23. [23] W.T. Tseng and R. Hanitsch, Computation of the thrust in apermanent magnet excited transverse flux synchronous linearmotor, Proc. International Conference on Electrical Machinesand Systems, Tokyo, Japan, 2009, 1–4.
24. [24] T. Sakamoto and T. Shiromizu, Propulsion control ofsuperconducting linear synchronous motor vehicle, IEEETransactions on Magnetics, 33(5), 1997, 3460–3462.
25. [25] K. Iwaki, T. Morizane, N. Kimura, and K. Taniguchi,Characteristics of forces of linear induction motor driven bypower source including frequency component synchronous withthe motor speed, Proc. International Conference on ElectricalMachines and Systems, Tokyo, Japan, 2009, 1–5.
26. [26] A. Boduroglu, Y. Demir, B. Cumhur, and M. Aydin, A noveltrack structure of double-sided linear PM synchronous motor forlow cost and high force density applications, IEEE Transactionson Magnetics, 57(2), 2021, 1–5.
27. [27] Z. Zhong, Z. Shao, M. Yang, X. Wang, Q. Xiao, and Y. Wang,Quasi-synchronous operation principle of a variable air-gapdoubly fed linear motor for high-speed maglev application,IEEE Transactions on Transportation Electrification, 9(2),2023, 2929–2940.
28. [28] J. Jin, L. Zheng, W. Xu, Y. Guo, and J. Zhu, Thrust characteris-tics of a double-sided high temperature superconducting linearsynchronous motor with a high temperature superconductingmagnetic suspension system, Journal of Applied Physics,109(7), 2011, 1–4.
29. [29] J. Jin, L. Zheng, W. Xu, Y. Guo, and J. Zhu, Influence ofexternal traveling-wave magnetic field on trapped field of ahigh temperature superconducting bulk magnet used in a linearsynchronous motor, Journal of Applied Physics, 109(11), 2011,113913–113914.
30. [30] L. Zheng and J. Jin, Studying the force characteristics of ahigh temperature superconducting linear synchronous motor,Journal of Applied Physics, 110(4), 2011, 043915–043915.
31. [31] Z. Zhang, Y. Liu, T. Zhou, and G. Lv, Analysis ofelectromechanical characteristics in air-core integrated linearsynchronous motor for EDS maglev train with pitching oper-ation condition, IEEE Transactions on Vehicular Technology,71(7), 2022, 6938–694.

Important Links:

• Abstract
• DOI: 10.2316/J.2024.201-0413
• From Journal (201) Mechatronic Systems and Control - 2024

Go Back