Direct Torque Control of T-NPC Inverters-Fed Double-Stator-Winding PMSM Drives With SVM

• Published in: IEEE transactions on power electronics Vol. 33; no. 2; pp. 1541 - 1553
• Main Authors: Wang, Zheng, Wang, Xueqing, Cao, Jiawei, Cheng, Ming, Hu, Yihua
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.02.2018; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Back electromotive force; Circuits; Coils (windings); Double-stator-winding permanent magnet synchronous machine (PMSM) drives; Dynamic response; Fault tolerance; fault-tolerant control; Harmonic analysis; Inverters; Magnetic separation; Production planning; Space vector modulation; space vector modulation (SVM); Stator windings; Step voltage; Switches; Switching; Synchronous machines; T-type neutral-point-clamping (T-NPC) three-level inverters; Torque; vector space decomposition (VSD); Winding; Windings
• ISSN: 0885-8993; 1941-0107
• DOI: 10.1109/TPEL.2017.2689008

This paper studies and proposes the vector space decomposition-based direct torque control (DTC) scheme for the T-type neutral-point-clamping (T-NPC) three-level inverters-fed double-stator-winding permanent magnet synchronous machine (PMSM) drive, which provides an effective solution for high-power high-reliability applications. The key is to propose a simple but effective space vector modulation (SVM) for DTC of T-NPC double-stator-winding drives-based two-step voltage vector synthesis, in such a way that good dynamic response and harmonic performance are obtained. The closed-loop controllers on harmonic subspace are incorporated to suppress the possible harmonics induced from back electromotive force and unbalanced parameters in phase windings of electrical machine. Furthermore, a hybrid current control is proposed for fault-tolerant operation of the T-NPC double-stator-winding PMSM drives under one-phase open-circuit conditions. In the hybrid current controller, the healthy winding still uses the SVM-DTC control while the faulty winding uses the closed-loop current controller to track the optimized current references. Both simulation and experimental results are presented to verify the performance of the proposed switching strategies and control schemes.