Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines
This paper discusses two methods of altering the harmonic content of the spatial air-gap flux density waveform in synchronous machines (generators and motors). First, fractional-conductor windings are analysed for adoption as a replacement for a conventional distributed winding arrangement, their ad...
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| Language: | English |
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Wiley
2019-05-01
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| Series: | The Journal of Engineering |
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| Online Access: | https://digital-library.theiet.org/content/journals/10.1049/joe.2018.8205 |
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doaj-14e906190e754bf181791ad6838dd32e2021-04-02T13:27:10ZengWileyThe Journal of Engineering2051-33052019-05-0110.1049/joe.2018.8205JOE.2018.8205Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machinesChristopher Donaghy-Spargo0Anthony Spargo1Anthony Spargo2Durham UniversityCummins Generator TechnologiesCummins Generator TechnologiesThis paper discusses two methods of altering the harmonic content of the spatial air-gap flux density waveform in synchronous machines (generators and motors). First, fractional-conductor windings are analysed for adoption as a replacement for a conventional distributed winding arrangement, their advantages and disadvantages briefly discussed and an example design scenario presented. Second, analysis and discussion regarding the use of semi-magnetic slot wedges as a replacement for glass-fibre type wedges is presented to complement the choice of winding in synchronous machines. Both methods are shown to benefit machine performance under certain circumstances.https://digital-library.theiet.org/content/journals/10.1049/joe.2018.8205machine insulationAC machinespermanent magnet machinesair gapssynchronous machinesmachine windingsconductors (electric)magnetic fluxfinite element analysissynchronous machinesmachine performancefractional-conductor windingssemimagnetic slot wedgesharmonic contentspatial air-gap flux density waveformgeneratorsmotorsdisadvantages brieflyexample design scenariodiscussionglass-fibre type wedges |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Christopher Donaghy-Spargo Anthony Spargo Anthony Spargo |
| spellingShingle |
Christopher Donaghy-Spargo Anthony Spargo Anthony Spargo Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines The Journal of Engineering machine insulation AC machines permanent magnet machines air gaps synchronous machines machine windings conductors (electric) magnetic flux finite element analysis synchronous machines machine performance fractional-conductor windings semimagnetic slot wedges harmonic content spatial air-gap flux density waveform generators motors disadvantages briefly example design scenario discussion glass-fibre type wedges |
| author_facet |
Christopher Donaghy-Spargo Anthony Spargo Anthony Spargo |
| author_sort |
Christopher Donaghy-Spargo |
| title |
Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| title_short |
Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| title_full |
Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| title_fullStr |
Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| title_full_unstemmed |
Use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| title_sort |
use of fractional-conductor windings and semi-magnetic slot wedges in synchronous machines |
| publisher |
Wiley |
| series |
The Journal of Engineering |
| issn |
2051-3305 |
| publishDate |
2019-05-01 |
| description |
This paper discusses two methods of altering the harmonic content of the spatial air-gap flux density waveform in synchronous machines (generators and motors). First, fractional-conductor windings are analysed for adoption as a replacement for a conventional distributed winding arrangement, their advantages and disadvantages briefly discussed and an example design scenario presented. Second, analysis and discussion regarding the use of semi-magnetic slot wedges as a replacement for glass-fibre type wedges is presented to complement the choice of winding in synchronous machines. Both methods are shown to benefit machine performance under certain circumstances. |
| topic |
machine insulation AC machines permanent magnet machines air gaps synchronous machines machine windings conductors (electric) magnetic flux finite element analysis synchronous machines machine performance fractional-conductor windings semimagnetic slot wedges harmonic content spatial air-gap flux density waveform generators motors disadvantages briefly example design scenario discussion glass-fibre type wedges |
| url |
https://digital-library.theiet.org/content/journals/10.1049/joe.2018.8205 |
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AT christopherdonaghyspargo useoffractionalconductorwindingsandsemimagneticslotwedgesinsynchronousmachines AT anthonyspargo useoffractionalconductorwindingsandsemimagneticslotwedgesinsynchronousmachines AT anthonyspargo useoffractionalconductorwindingsandsemimagneticslotwedgesinsynchronousmachines |
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1721564988036874240 |