Wound Field Synchronous Machines with Enhanced Saliency, Performance
- 技術優勢
- Enhanced saliencyMaximum torque capability increaseReduced copper/iron loss during both part load and high speed operationNo need to increase reactive current for field weakeningSimilar in size and volume to existing rotors
- 技術應用
- Motor and generator manufacturing; hybrid/electric vehicles
- 詳細技術說明
- Permanent magnet (PM) machines are used in today’s hybrid and electric vehicles due to their ideal performance characteristics. However, due to cost uncertainty and overseas sourcing, other types of machines are being explored to determine if they can offer similar performance without the need for permanent magnets.Salient pole wound field synchronous machines (WFSMs) are a potential alternative. Traditionally used in generators, they share the same operating principles as PM machines, offer similar torque capabilities and are free of permanent magnet material. They also offer potential advantages in variable speed applications such as traction, i.e., hybrid and electric vehicles. However, there are disadvantages to this type of machine, namely slip rings and brushes.Improving saliency could expand the end applications of WFSMs into the hybrid/electric motor space and replace high cost PM machines.UW–Madison researchers have designed a modified rotor structure for salient pole WFSMs that enhances saliency and leads to better performance (peak motoring power/torque capability) using the same amount of input current. Compared to conventional designs, the new rotor structure features a flux barrier gap made of a low cost polymer that enlarges the reactance Xd - Xq, differential between rotor axes. Based on the particular end use, three different barrier designs could be employed (single barrier, multilayer barrier or axial laminated).
- *Abstract
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The Wisconsin Alumni Research Foundation (WARF) is seeking commercial partners interested in developing a modified rotor structure for salient pole WFSMs that improves output power and torque production while reducing loss.
- *Principal Investigation
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Name: Thomas Lipo
Department:
Name: Wenbo Liu
Department:
- 其他
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- 國家/地區
- 美國
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