TY - GEN
T1 - Steady-State Operating Area Analysis and Full Unit-Circle Realization for Current Source Converter
AU - Song, Zhaoqi
AU - Wei, Xiaoguang
AU - Zhang, Wenwen
AU - An, Ronghui
AU - Shan, Yunhai
AU - Liu, Jinjun
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Current source converter (CSC) with dc fault ride-through capability and low-cost advantages, is attracting lots of attention in high-voltage direct current (HVDC) and renewable energy conversion fields. The steady-state operating area (SSOA) of voltage source converter (VSC) should be designed to achieve the full unit-circle in some utility applications. It's based on proper design of main parameters. But in existing studies on CSC, its main parameters are designed mostly based on unit power factor operation, without considering the full unit-circle realization of SSOA. To fill this gap, first the ranges of key parameters are summarized and then used to derive analytical expressions of SSOA constraints in per unit system for CSC. Second, the conditions for main parameters to realize the full unit-circle SSOA are investigated, revealing the L-C filter parameters' effects on the feasible domain of the rated ac voltage. Finally, while the full unit-circle conditions are satisfied, the minimum capacitor voltage is chosen as the optimization objective in the parameters design. Then the optimized parameters in typical HVDC applications are acquired. It's found that the rated ac voltage designed is relatively high for practical applications, indicating further tradeoffs between full unit-circle SSOA and system cost.
AB - Current source converter (CSC) with dc fault ride-through capability and low-cost advantages, is attracting lots of attention in high-voltage direct current (HVDC) and renewable energy conversion fields. The steady-state operating area (SSOA) of voltage source converter (VSC) should be designed to achieve the full unit-circle in some utility applications. It's based on proper design of main parameters. But in existing studies on CSC, its main parameters are designed mostly based on unit power factor operation, without considering the full unit-circle realization of SSOA. To fill this gap, first the ranges of key parameters are summarized and then used to derive analytical expressions of SSOA constraints in per unit system for CSC. Second, the conditions for main parameters to realize the full unit-circle SSOA are investigated, revealing the L-C filter parameters' effects on the feasible domain of the rated ac voltage. Finally, while the full unit-circle conditions are satisfied, the minimum capacitor voltage is chosen as the optimization objective in the parameters design. Then the optimized parameters in typical HVDC applications are acquired. It's found that the rated ac voltage designed is relatively high for practical applications, indicating further tradeoffs between full unit-circle SSOA and system cost.
KW - capacitor voltage minimization
KW - current source converter (CSC)
KW - full unit-circle
KW - parameters design
KW - steady-state operating area (SSOA)
UR - https://www.scopus.com/pages/publications/85215521108
U2 - 10.1109/ISESC63657.2024.10785354
DO - 10.1109/ISESC63657.2024.10785354
M3 - 会议稿件
AN - SCOPUS:85215521108
T3 - CPSS and ISESC 2024 - 2024 CPSS and IEEE International Symposium on Energy Storage and Conversion
SP - 919
EP - 924
BT - CPSS and ISESC 2024 - 2024 CPSS and IEEE International Symposium on Energy Storage and Conversion
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 CPSS and IEEE International Symposium on Energy Storage and Conversion, CPSS and ISESC 2024
Y2 - 8 November 2024 through 11 November 2024
ER -
