Enhancement of magnetic flux distribution in a DC superconducting electric motor
Most motor designs require an air gap between the rotor and stator to enable the armature to rotate freely. The interaction of magnetic flux from rotor and stator within the air gap will provide the thrust for rotational motion. Thus, the understanding of magnetic flux in the vicinity of the air gap...
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2023
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my.uniten.dspace-301952023-12-29T15:45:25Z Enhancement of magnetic flux distribution in a DC superconducting electric motor Hamid N.A. Ewe L.S. Chin K.M. 6604077116 58032789200 55812298900 Electric motors Energy efficiency Magnetic devices Magnetic flux Stators Superconductivity Conventional motors Double pancake Flux densities High flux density Magnetic flux distribution Rotational motion Rotor and stators Superconducting motors design energy efficiency magnetic property performance assessment superconductivity Rotors (windings) Most motor designs require an air gap between the rotor and stator to enable the armature to rotate freely. The interaction of magnetic flux from rotor and stator within the air gap will provide the thrust for rotational motion. Thus, the understanding of magnetic flux in the vicinity of the air gap is very important to mathematically calculate the magnetic flux generated in the area. In this work, a finite element analysis was employed to study the behavior of the magnetic flux in view of designing a synchronous DC superconducting electric motor. The analysis provides an ideal magnetic flux distribution within the components of the motor. From the flux plot analysis, it indicates that flux losses are mainly in the forms of leakage and fringe effect. The analysis also shows that the flux density is high at the area around the air gap and the rotor. The high flux density will provide a high force area that enables the rotor to rotate. In contrast, the other parts of the motor body do not show high flux density indicating low distribution of flux. Consequently, a bench top model of a DC superconducting motor was developed where by motor with a 2-pole type winding was chosen. Each field coil was designed with a racetrack-shaped double pancake wound using DI-BSCCO Bi-2223 superconducting tapes. The performance and energy efficiency of the superconducting motor was superior when compared to the conventional motor with similar capacity. � Published under licence by IOP Publishing Ltd. Final 2023-12-29T07:45:25Z 2023-12-29T07:45:25Z 2013 Conference paper 10.1088/1755-1315/16/1/012051 2-s2.0-84881102961 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84881102961&doi=10.1088%2f1755-1315%2f16%2f1%2f012051&partnerID=40&md5=8d5e7d5c4924180ab6e5cf57ae241609 https://irepository.uniten.edu.my/handle/123456789/30195 16 1 12051 All Open Access; Gold Open Access Institute of Physics Publishing Scopus |
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Electric motors Energy efficiency Magnetic devices Magnetic flux Stators Superconductivity Conventional motors Double pancake Flux densities High flux density Magnetic flux distribution Rotational motion Rotor and stators Superconducting motors design energy efficiency magnetic property performance assessment superconductivity Rotors (windings) |
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Electric motors Energy efficiency Magnetic devices Magnetic flux Stators Superconductivity Conventional motors Double pancake Flux densities High flux density Magnetic flux distribution Rotational motion Rotor and stators Superconducting motors design energy efficiency magnetic property performance assessment superconductivity Rotors (windings) Hamid N.A. Ewe L.S. Chin K.M. Enhancement of magnetic flux distribution in a DC superconducting electric motor |
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Most motor designs require an air gap between the rotor and stator to enable the armature to rotate freely. The interaction of magnetic flux from rotor and stator within the air gap will provide the thrust for rotational motion. Thus, the understanding of magnetic flux in the vicinity of the air gap is very important to mathematically calculate the magnetic flux generated in the area. In this work, a finite element analysis was employed to study the behavior of the magnetic flux in view of designing a synchronous DC superconducting electric motor. The analysis provides an ideal magnetic flux distribution within the components of the motor. From the flux plot analysis, it indicates that flux losses are mainly in the forms of leakage and fringe effect. The analysis also shows that the flux density is high at the area around the air gap and the rotor. The high flux density will provide a high force area that enables the rotor to rotate. In contrast, the other parts of the motor body do not show high flux density indicating low distribution of flux. Consequently, a bench top model of a DC superconducting motor was developed where by motor with a 2-pole type winding was chosen. Each field coil was designed with a racetrack-shaped double pancake wound using DI-BSCCO Bi-2223 superconducting tapes. The performance and energy efficiency of the superconducting motor was superior when compared to the conventional motor with similar capacity. � Published under licence by IOP Publishing Ltd. |
| author2 |
6604077116 |
| author_facet |
6604077116 Hamid N.A. Ewe L.S. Chin K.M. |
| format |
Conference paper |
| author |
Hamid N.A. Ewe L.S. Chin K.M. |
| author_sort |
Hamid N.A. |
| title |
Enhancement of magnetic flux distribution in a DC superconducting electric motor |
| title_short |
Enhancement of magnetic flux distribution in a DC superconducting electric motor |
| title_full |
Enhancement of magnetic flux distribution in a DC superconducting electric motor |
| title_fullStr |
Enhancement of magnetic flux distribution in a DC superconducting electric motor |
| title_full_unstemmed |
Enhancement of magnetic flux distribution in a DC superconducting electric motor |
| title_sort |
enhancement of magnetic flux distribution in a dc superconducting electric motor |
| publisher |
Institute of Physics Publishing |
| publishDate |
2023 |
| _version_ |
1806426616526536704 |
| score |
13.214268 |