Optimal Arm Current Reallocation of Modular Multilevel Matrix Converter Dedicated for Power Grid Interconnection

The modular multilevel matrix converter (M 3 C) is the high-power three-phase to three-phase AC/AC converter of the next generation. However, when the M 3 C is applied for power grid interconnection, with equal or close input and output frequency, the current distribution in its nine arms becomes si...

Full description

Saved in:
Bibliographic Details
Published inIEEE transactions on power delivery Vol. 37; no. 5; pp. 3477 - 3490
Main Authors Liu, Shenquan, Zhao, Boyang, Chen, Yongan, Wang, Gang, Wang, Xifan
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
AC/AC conversion
Analytical models
Capacitors
control
Current distribution
Electric power grids
Gold
Matrix converters
Modular multilevel matrix converter
Power grids
Voltage control
Online AccessGet full text

Cover

More Information
Summary:The modular multilevel matrix converter (M 3 C) is the high-power three-phase to three-phase AC/AC converter of the next generation. However, when the M 3 C is applied for power grid interconnection, with equal or close input and output frequency, the current distribution in its nine arms becomes significantly uneven. Furthermore, the current distribution pattern is directly influenced by the randomly changing input-output angle-difference, forcing each arm to be designed based on the highest-possible current, which significantly increases the required semiconductor rating and converter cost. To address this issue, a novel current reallocation is proposed to attenuate the highest-possible arm current of M 3 C. The equal-frequency operation of M 3 C is first modeled and analyzed, and the operation sweet-spot where each arm stays in natural energy balance is located. Then, the current reallocation is analytically derived for sweet-spot operation. By injecting proper circulating current, the highest-possible arm current is reduced by 13.4%, and the required circulating current component is analytically derived. The implementation method into the classic control structure of M 3 C is provided. Performance of the proposed strategy is validated by a simulation benchmark established in MATLAB/Simulink environment in the context of interconnection between two 220 kV/50 Hz power grids.
ISSN:0885-8977
1937-4208
DOI:10.1109/TPWRD.2021.3129539