Modulated Model Predictive Control with Common Voltage Injection for MMCC-STATCOM Under Unbalanced Load
- Resource Type
- Conference
- Authors
- Pan, Xuejiao; Zhang, Li; Li, Yongfei
- Source
- 2021 IEEE 12th International Symposium on Power Electronics for Distributed Generation Systems (PEDG) Power Electronics for Distributed Generation Systems (PEDG), 2021 IEEE 12th International Symposium on. :1-7 Jun, 2021
- Subject
- Components, Circuits, Devices and Systems
Power, Energy and Industry Applications
Transportation
Reactive power
Simulation
Clustering algorithms
Switches
Predictive models
Prediction algorithms
Harmonic analysis
Modulated model predictive control (MMPC)
Branch and bound method (B&B)
Multilevel modular cascaded converter-based STATCOM (MMCC-STATCOM)
- Language
- ISSN
- 2329-5767
This paper presents a novel modulated model predictive control (MMPC) scheme for Modular Multilevel Cascaded Converter-based STATCONs (MMCC-STATCOM) to regulate reactive power flow and compensate unbalanced load current. The method imposes a common mode voltage (CMV) on the three phase-voltages used in the model for predicting the converter phase current. This results in the phase-voltages implemented naturally containing a zero-sequence element with some low-order harmonics. These are effective in rebalancing the phase active power imbalances caused due to MMCC STATCOM compensating unbalanced load currents, hence eliminating drift in the phase cluster voltage. Moreover the harmonics in the imposed CMV reduces the peak converter phase voltage, so extending the range of compensation. Furthermore a modified branch and bound (B&B) algorithm is developed to evaluate the optimal per-phase switch duty ratios for the cost function minimization. The algorithm is computationally efficient compared to Model Predictive Control schemes using switching state selection approach. Simulation results of this method are presented in the paper and compared favorably with the conventional scheme which relies on evaluating and injecting zero sequence voltage at each sample interval.