A Novel Dual-Stator Hybrid Excited Synchronous Wind Generator

Liu, Xiping; Lin, Heyun; Zhu, Z. Q.; Chengfeng, Yang; Fang, Shuhua; Guo, Jian

doi:10.1109/tia.2009.2018969

Cited by 56 publications

(27 citation statements)

References 17 publications

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“…If both the permanent magnets and field windings are mounted in the stator, the stator hybrid excited generator can be achieved [75,76]. Both the stator electrical excited and hybrid excited generators offer the possibility of regulating the flux, in turn the output voltage of the generator.…”

Section: With Stator Permanent Magnet Generatorsmentioning

confidence: 99%

The state of the art of wind energy conversion systems and technologies: A review

Cheng¹,

Zhu²

2014

Energy Conversion and Management

505

205

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Section: With Stator Permanent Magnet Generatorsmentioning

confidence: 99%

The state of the art of wind energy conversion systems and technologies: A review

Cheng¹,

Zhu²

2014

Energy Conversion and Management

505

205

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“…In three and five-phase DSSR-PMG, there is dual flux linkage generated which is in inner and outer stator air gap. The correlation between flux linkage and back emf in PM machine as per equation below: (4) where N is the number of turns, ϕ is the rate of change of magnetix flux and t is the rate of change of time.…”

Section: Back Emf and Flux Linkagementioning

confidence: 99%

Analysis of Three and Five-phase Double Stator Slotted Rotor Permanent Magnet Generator (DSSR-PMG)

Suhairi¹,

Firdaus²,

Shukor³

et al. 2017

IJPEDS

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This paper discusses the performance of three and five-phase double stator slotted rotor permanent magnet generator (DSSR-PMG). The objective of this research is to propose five-phase DSSR-PMG structure that could minimize output voltage ripple compared to three phase. In this research Finite Element Analysis (FEA) is used to simulate the characteristic of the three and five-phase permanent magnet generator at various speeds. The characteristic of back-EMF, flux linkage, cogging torque and flux density for three and five-phase configurations is presented. As a result, five-phase DSSR-PMG shows a lower cogging torque and voltage ripple compared to three-phase. The cogging torque for five-phase is 80% lower than threephase DSSR-PMG and the ripple voltage (peak to peak) of back-EMF in five-phase is 2.3% compared to the three-phase DSSR-PMG which is 55%.

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“…Southeast University proposed a dualstator hybrid excited generator (DSHEG) with PMs placed on the inner stator, which enhances the capability in large speed ranges [51]. They also proposed a flux switching (FS) transverse flux (TF) PM generator with high power density, which can decouple electrical and magnetic loading designs [52].…”

Section: Generatormentioning

confidence: 99%