A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability
This article investigates a permanent magnet vernier machine (PMVM) equipped with positive-mutual-coupling (PMC) winding. The conventional winding layout typically presents negative-mutual-coupling (NMC) among the three-phase windings due to the 120° spatial phase shift. It is illustrated that in th...
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sg-ntu-dr.10356-1822592025-01-20T01:44:12Z A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability Xie, Shuangchun Lee, Christopher Ho Tin School of Electrical and Electronic Engineering Engineering Field weakening Inductance This article investigates a permanent magnet vernier machine (PMVM) equipped with positive-mutual-coupling (PMC) winding. The conventional winding layout typically presents negative-mutual-coupling (NMC) among the three-phase windings due to the 120° spatial phase shift. It is illustrated that in the conventional NMC winding, the negative phase-mutual inductance leads to increasing q-Axis inductance and amplifying armature reaction. On the contrary, the investigated PMC winding exhibits positive phase-mutual inductance, cancellation effect on the q-Axis flux linkage, and brings the characteristic current closer to the current limit. This contributes to suppressing armature reaction, improving the power factor, reducing the terminal voltage, and enhancing the field-weakening performance. The generic design methodology to obtain PMC winding is presented and exemplified on a 24-slot, 5-Armature pole pair, and 19-rotor pole pair PMVM. Finite element analysis shows that the proposed PMC PMVM could improve the rated power factor and widen the constant torque region. With reduced terminal voltage and more voltage margins, the PMC PMVM can employ a higher q-Axis current to generate torque, thus significantly enhancing the output torque and power factor during field-weakening operations. As a result, the output power capability and constant power speed range (CPSR) are improved dramatically. Finally, a PMC PMVM prototype is manufactured to validate the efficacy of PMC winding in improving field-weakening and power factor. 2025-01-20T01:44:12Z 2025-01-20T01:44:12Z 2024 Journal Article Xie, S. & Lee, C. H. T. (2024). A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability. IEEE Transactions On Industrial Electronics. https://dx.doi.org/10.1109/TIE.2024.3497215 0278-0046 https://hdl.handle.net/10356/182259 10.1109/TIE.2024.3497215 2-s2.0-85210736838 en IEEE Transactions on Industrial Electronics © 2024 IEEE. All rights reserved. |
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Engineering Field weakening Inductance Xie, Shuangchun Lee, Christopher Ho Tin A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
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This article investigates a permanent magnet vernier machine (PMVM) equipped with positive-mutual-coupling (PMC) winding. The conventional winding layout typically presents negative-mutual-coupling (NMC) among the three-phase windings due to the 120° spatial phase shift. It is illustrated that in the conventional NMC winding, the negative phase-mutual inductance leads to increasing q-Axis inductance and amplifying armature reaction. On the contrary, the investigated PMC winding exhibits positive phase-mutual inductance, cancellation effect on the q-Axis flux linkage, and brings the characteristic current closer to the current limit. This contributes to suppressing armature reaction, improving the power factor, reducing the terminal voltage, and enhancing the field-weakening performance. The generic design methodology to obtain PMC winding is presented and exemplified on a 24-slot, 5-Armature pole pair, and 19-rotor pole pair PMVM. Finite element analysis shows that the proposed PMC PMVM could improve the rated power factor and widen the constant torque region. With reduced terminal voltage and more voltage margins, the PMC PMVM can employ a higher q-Axis current to generate torque, thus significantly enhancing the output torque and power factor during field-weakening operations. As a result, the output power capability and constant power speed range (CPSR) are improved dramatically. Finally, a PMC PMVM prototype is manufactured to validate the efficacy of PMC winding in improving field-weakening and power factor. |
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School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Xie, Shuangchun Lee, Christopher Ho Tin |
| format |
Article |
| author |
Xie, Shuangchun Lee, Christopher Ho Tin |
| author_sort |
Xie, Shuangchun |
| title |
A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| title_short |
A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| title_full |
A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| title_fullStr |
A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| title_full_unstemmed |
A new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| title_sort |
new design concept for permanent magnet vernier machine: positive-mutual-coupling for improved power factor and higher field-weakening capability |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182259 |
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1821833198918696960 |