Abstract
With the increasing environmental concerns, a paradigm shift towards electric and hybrid electric vehicles is expected. Switched Reluctance Motors (SRMs) have emerged as a viable competitor to other established electrical machines. SRMs are known for their simple construction, robustness, inherent fault tolerant structure and low production and maintenance costs. Moreover, the machine has gained interest due to the absence of permanent magnets or windings in the rotor structure, which significantly reduces production costs when compared to other electric motors. The SRM, however, present some known drawbacks, such as increased torque ripple and acoustic noise production, as well as a highly nonlinear behavior. Through the use of adequate control strategies, however, the main challenges of the machine can be overcome. Thus, this paper presents a state-of-the-art review of the advanced control of SRMs, encompassing current regulation strategies, torque control strategies and vibration suppression techniques. First, two categories of current controllers are reviewed: model-independent and model-based. Next, indirect and direct torque control methods are explored. Then, three approaches to vibration suppression are discussed, namely active cancellation, current profiling and direct instantaneous force control. Lastly, a summary of each topic is presented and suggestions of future research topics are listed.
Highlights
Due to the increasing concerns surrounding fossil fuels and global warming, significant efforts have been made in recent years towards transportation electrification
Switched Reluctance Motors (SRMs) FUNDAMENTALS The switched reluctance motor presents a simple structure, composed of a double salient structure, with concentrated windings mounted on the stator slots
To mitigate the radial force and torque ripple simultaneously, [195], [196] rearranged the radial force reference for the two conducting phases during the commutation period to reduce the torque ripple, at the cost of increased root mean square (RMS) current value when compared to the conventional method
Summary
Due to the increasing concerns surrounding fossil fuels and global warming, significant efforts have been made in recent years towards transportation electrification. The development of high-performance electric drives that do not rely on rare-earth magnets has received great attention in recent years [7]–[10] In this context, switched reluctance motors (SRMs) stand out as a solid competitor for already established electrical machines, being a rare-earth-free alternative. Independent concentrated windings are mounted on stator slots, making the machine inherently fault tolerant In addition to these features, the SRM is capable of operating over a wide range of speed and temperature [6]. Poor tracking can lead to increased torque ripple as well as acoustic noise production [30] These characteristics should not prevent the wide use of SRMs. In order to overcome these challenges, many advanced control strategies have been proposed in literature.
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