A Pole Pair Segment of Oil-cooling Air-Core Stator for a 2 MW Direct-Drive High Temperature Superconducting Wind Power Generator

A 2 MW direct-drive (DD) high temperature superconducting (HTS) wind power generator with HTS wires in the rotor field windings and copper transposed conductor in the stator coils was explored for the wind turbine application in this study. An oil-cooling air-core stator with non-magnetic teeth of t...

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Bibliographic Details
Published inJournal of electrical engineering & technology Vol. 16; no. 6; pp. 3145 - 3155
Main Authors Zhou, Yong, Dong, Qi, Niu, Xiao-Jun, Xu, Hong, Xiong, Qi, Su, Hao, Zheng, Jun
Format Journal Article
LanguageEnglish
Published Singapore Springer Singapore 01.11.2021
대한전기학회
Subjects
Electrical Engineering
Electrical Machines and Networks
Electronics and Microelectronics
Engineering
Instrumentation
Original Article
Power Electronics
전기공학
High temperature superconducting generator
Temperature distribution
Oil-cooling
Air-core stator
Transposed conductor
Wind turbine
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Summary:A 2 MW direct-drive (DD) high temperature superconducting (HTS) wind power generator with HTS wires in the rotor field windings and copper transposed conductor in the stator coils was explored for the wind turbine application in this study. An oil-cooling air-core stator with non-magnetic teeth of the 2 MW DD HTS generator was designed because the high flux density generated by the HTS wires wound result in larger dissipation in iron teeth, and the process of that could be summarized as follows. First, a 2 MW DD HTS wind power generator was designed, and the electromagnetic (EM), loss, EM force, and insulation of the DD HTS generator were analyzed and developed, respectively. Second, the thermal and mechanical of the one pole pair oil-cooling air-gap armature was analyzed by the finite element analysis. Then, a pole pair segment of the oil-cooling air-core stator with the same structure as the 2 MW generator was designed and manufactured to identify potential challenges, obtain practical knowledge before production, and then reduce the development risk of the 2 MW DD HTS generator. Furthermore, a test system with converter, oil-cooling system, and data acquisition equipment was developed simultaneously to test the temperature distribution of the slotless stator. The performance test results show that the maximum temperature rise of the one pole pair oil-cooling stator under rated conditions is about 81.4 K, which satisfies the design requirements of the 2 MW DD HTS generator.
ISSN:1975-0102
2093-7423
DOI:10.1007/s42835-021-00852-z