@Article{ee.2025.067027,
AUTHOR = {Ziqiang Man, Lei Zhao, Zheng Tao, Shiming Cheng, Wei Yan, Gaoyue Zhong, Yu Lu, Wenming Zhang, Li Zhang},
TITLE = {A Low Common-Mode Voltage Virtual Space Vector Modulation of Three-Level Converters for Doubly-Fed Variable-Speed Pumped Storage Systems},
JOURNAL = {Energy Engineering},
VOLUME = {122},
YEAR = {2025},
NUMBER = {9},
PAGES = {3555--3572},
URL = {http://www.techscience.com/energy/v122n9/63462},
ISSN = {1546-0118},
ABSTRACT = {With the rapid integration of renewable energy sources, modern power systems are increasingly challenged by heightened volatility and uncertainty. Doubly-fed variable-speed pumped storage units (DFVS-PSUs) have emerged as promising technologies for mitigating grid oscillations and enhancing system flexibility. However, the excitation converters in DFVS-PSUs are prone to significant issues such as elevated common-mode voltage (CMV) and neutral-point voltage (NPV) fluctuations, which can lead to electromagnetic interference and degrade transient performance. To address these challenges, an optimized virtual space vector pulse width modulation (OVSVPWM) strategy is proposed, aiming to suppress CMV and NPV simultaneously through coordinated multi-objective control. Specifically, a dynamic feedback mechanism is introduced to adjust the balancing factor of basic vectors in the synthesized virtual small vector in real-time, achieving autonomous balancing of the NPV. To address the excessive switching actions introduced by the OVSVPWM strategy, a phase duty ratio-based sequence reconstruction method is adopted, which reduces the total number of switching actions to half of the original. A zero-level buffering scheme is employed to reconstruct the single-phase voltage-level output sequence, achieving peak CMV suppression down to udc/6. Simulation results demonstrate that the proposed strategy significantly improves electromagnetic compatibility and operational stability while maintaining high power quality.},
DOI = {10.32604/ee.2025.067027}
}