ESO-based FTC strategy via dual-loop compensations for 5-phase PMSG integrated tidal applications

Zhuo Liu; Azeddine Houari; Mohamed Machmoum; Mohamed-Fouad Benkhoris; Tianhao Tang

doi:10.1587/elex.18.20210177

This article has now been updated. Please use the final version.

ESO-based FTC strategy via dual-loop compensations for 5-phase PMSG integrated tidal applications

Zhuo Liu, Azeddine Houari, Mohamed Machmoum, Mohamed-Fouad Benkhoris, Tianhao Tang

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Keywords: Tidal stream applications, five-phase PMSG, fault-tolerant control, dual-loop compensation

JOURNAL FREE ACCESS Advance online publication

Article ID: 18.20210177

DOI https://doi.org/10.1587/elex.18.20210177

The final version of this article is now available: Vol. 18 (2021), No. 20 pp. 20210177-20210177

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Abstract

Using multiphase permanent magnet synchronous generators (PMSG) is able to strengthen whole reliabilities of the tidal stream energy systems. Even so, advanced fault-tolerant control designs are also needed for a further enhancement of multiphase PMSG integrated tidal stream turbine under harsh sea water environments. Thus, extended state observers are used to develop a fault-tolerant control strategy towards a trapezoidal five-phase PMSG incorporated tidal stream application. This FTC strategy considers open circuit of a phase and a switch in the five-phase PMSG and its connected converter. To attenuate influences due to these faults, a dual-loop compensation mechanism is performed via extended state observers. System adaptation to swell effects of the tidal stream and feasibility of the proposed FTC strategy are verified through a 1.5 MW simulation setup.

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