Abstract
In this study, a robust predictive power control (R-PPC) method for an N*3-phase permanent magnet synchronous motor (PMSM) is developed in the field of flywheel energy storage systems application, which can effectively improve robustness against inductance parameter mismatch and compensate for the one-beat delay. Firstly, the mathematical model of the N*3-phase PMSM is illustrated, and the topological structure of the N*3-phase PMSM is established. The R-PPC method of the N*3-phase PMSM is then proposed by using the d–q axis current robust predictive control theory. Robustness factors are adopted to modify the current response values in the proposed robust predictive power controller, which can obtain excellent current control performance under the inductance parameter mismatch. Moreover, the next current predicted value is used to replace the current sampled value in the proposed R-PPC method to eliminate the one-beat delay. Finally, comparative simulation and experimental results verify that the proposed R-PPC method can achieve excellent current track performance and smaller torque ripple under both the charge state and discharge state.
Highlights
With the increasing demand for higher power energy storage motor drives, multiphase permanent magnet synchronous motor (PMSM), commonly used as energy storage motors, are becoming widely used in flywheel energy storage systems due to their strong fault tolerance and high operating efficiency [1,2,3,4]
When the module parallel power electronics converter energy storage system is developed in this train decelerates to enter a station, the N*3-phase PMSM is used as the motor for charging paper
The mismatch of inductance parameters will increase the d- and q-axis response current ripple, which will lead to torque ripple of the N*3-phase PMSM
Summary
With the increasing demand for higher power energy storage motor drives, multiphase PMSMs, commonly used as energy storage motors, are becoming widely used in flywheel energy storage systems due to their strong fault tolerance and high operating efficiency [1,2,3,4]. In [13], an improved deadbeat predictive current control method was proposed to overcome one-step control delay and parameter mismatch. In order to enhance robustness against model parameter mismatch, some improved predictive control methods have been presented [19,20,21,22,23,24,25]. In [21], a novel flux immunity robust predictive current control, based on an incremental model and extended state observer, was presented, and improved inductance robustness to eliminate any predicted errors caused by stator inductance mismatch. PMSM is presented in the field of flywheel energy storage systems application, which can effectively enhance robustness against inductance parameter mismatch and compensate for the influence of the one-beat delay. During the braking state and starting state of the train, the N*3-phase PMSM is respectively as a motor generator
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