3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing

P. Huang, Mi-Ching Tsai, I. Jiang

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Due to the features of high efficiency, high torque, and without using permanent magnets, the synchronous reluctance motors (SynRMs) have become popular in industry. Such advantages are contributed by the design of the rotor barriers and ribs that the flux flow path are arranged as shown in Fig. 1(a). However, the requirements of motors usually are not just high efficiency but some other more operation capabilities such as low vibration and easy start. Unfortunately, as compared with the industrial most commonly used induction motors (IMs), position sensors are additionally required for initiating starting of SynRMs [1] [2]. Moreover, the barriers and ribs of SynRMs may increase the risk of structure deformation as rotation. Hence, this paper proposes a novel design of applying the 3D bionic structure in the SynRMs with new flux path design to solve the said problems. Further, the additive manufacturing (3D printing) is adopted to fabricate the complicated prototype of the rotor.

Original languageEnglish
Title of host publication2018 IEEE International Magnetic Conference, INTERMAG 2018
PublisherInstitute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)9781538664254
DOIs
Publication statusPublished - 2018 Oct 24
Event2018 IEEE International Magnetic Conference, INTERMAG 2018 - Singapore, Singapore
Duration: 2018 Apr 232018 Apr 27

Publication series

Name2018 IEEE International Magnetic Conference, INTERMAG 2018

Conference

Conference2018 IEEE International Magnetic Conference, INTERMAG 2018
CountrySingapore
CitySingapore
Period18-04-2318-04-27

Fingerprint

reluctance
Reluctance motors
Synchronous motors
printing
Printing
Melting
melting
Lasers
lasers
3D printers
Rotors
rotors
Fluxes
Bionics
bionics
induction motors
Induction motors
Permanent magnets
Torque
permanent magnets

All Science Journal Classification (ASJC) codes

  • Electronic, Optical and Magnetic Materials
  • Instrumentation

Cite this

Huang, P., Tsai, M-C., & Jiang, I. (2018). 3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing. In 2018 IEEE International Magnetic Conference, INTERMAG 2018 [8508376] (2018 IEEE International Magnetic Conference, INTERMAG 2018). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/INTMAG.2018.8508376
Huang, P. ; Tsai, Mi-Ching ; Jiang, I. / 3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing. 2018 IEEE International Magnetic Conference, INTERMAG 2018. Institute of Electrical and Electronics Engineers Inc., 2018. (2018 IEEE International Magnetic Conference, INTERMAG 2018).
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Huang, P, Tsai, M-C & Jiang, I 2018, 3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing. in 2018 IEEE International Magnetic Conference, INTERMAG 2018., 8508376, 2018 IEEE International Magnetic Conference, INTERMAG 2018, Institute of Electrical and Electronics Engineers Inc., 2018 IEEE International Magnetic Conference, INTERMAG 2018, Singapore, Singapore, 18-04-23. https://doi.org/10.1109/INTMAG.2018.8508376

3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing. / Huang, P.; Tsai, Mi-Ching; Jiang, I.

2018 IEEE International Magnetic Conference, INTERMAG 2018. Institute of Electrical and Electronics Engineers Inc., 2018. 8508376 (2018 IEEE International Magnetic Conference, INTERMAG 2018).

Research output: Chapter in Book/Report/Conference proceedingConference contribution

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N2 - Due to the features of high efficiency, high torque, and without using permanent magnets, the synchronous reluctance motors (SynRMs) have become popular in industry. Such advantages are contributed by the design of the rotor barriers and ribs that the flux flow path are arranged as shown in Fig. 1(a). However, the requirements of motors usually are not just high efficiency but some other more operation capabilities such as low vibration and easy start. Unfortunately, as compared with the industrial most commonly used induction motors (IMs), position sensors are additionally required for initiating starting of SynRMs [1] [2]. Moreover, the barriers and ribs of SynRMs may increase the risk of structure deformation as rotation. Hence, this paper proposes a novel design of applying the 3D bionic structure in the SynRMs with new flux path design to solve the said problems. Further, the additive manufacturing (3D printing) is adopted to fabricate the complicated prototype of the rotor.

AB - Due to the features of high efficiency, high torque, and without using permanent magnets, the synchronous reluctance motors (SynRMs) have become popular in industry. Such advantages are contributed by the design of the rotor barriers and ribs that the flux flow path are arranged as shown in Fig. 1(a). However, the requirements of motors usually are not just high efficiency but some other more operation capabilities such as low vibration and easy start. Unfortunately, as compared with the industrial most commonly used induction motors (IMs), position sensors are additionally required for initiating starting of SynRMs [1] [2]. Moreover, the barriers and ribs of SynRMs may increase the risk of structure deformation as rotation. Hence, this paper proposes a novel design of applying the 3D bionic structure in the SynRMs with new flux path design to solve the said problems. Further, the additive manufacturing (3D printing) is adopted to fabricate the complicated prototype of the rotor.

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Huang P, Tsai M-C, Jiang I. 3D structure line start synchronous reluctance motor design based on selective laser melting of 3D printing. In 2018 IEEE International Magnetic Conference, INTERMAG 2018. Institute of Electrical and Electronics Engineers Inc. 2018. 8508376. (2018 IEEE International Magnetic Conference, INTERMAG 2018). https://doi.org/10.1109/INTMAG.2018.8508376