A voltage level based predictive direct power control for modular multilevel converter

•A voltage level based predictive direct power control scheme for grid-connected modular multilevel converter is proposed.•The proposed control scheme is based on model predictive control and sorting algorithm.•It is simple without inner current loop and synchronous dq transformation.•Comparative st...

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Bibliographic Details
Published in:Electric power systems research 2017-07, Vol.148, p.97-107
Main Authors: Lee, Sze Sing, Heng, Yeh En
Format: Article
Language:English
Subjects:
Algorithms
Capacitor voltage balancing
Circulating current control
Classification
Computer simulation
Controllers
Converters
Direct power control
Electric potential
Electricity distribution
Modular multilevel converter (MMC)
Phase control
Power control
Predictive control
Simulation
Sorting algorithms
Strategy
Studies
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Summary:•A voltage level based predictive direct power control scheme for grid-connected modular multilevel converter is proposed.•The proposed control scheme is based on model predictive control and sorting algorithm.•It is simple without inner current loop and synchronous dq transformation.•Comparative studies are presented against an existing predictive current control technique.•Superior performance of the proposed scheme is guaranteed in terms of the power ripples, power tracking accuracy, current harmonics and switching frequency. This paper proposes a novel voltage level-based predictive direct power control (PDPC) strategy integrated with voltage sorting algorithm for a three phase grid-connected modular multilevel converter (MMC). The main advantage of the proposed control strategy, compared with the predictive current controllers, is that it does not need angular information of grid parameters. Therefore, it is simpler and able to get rid of rotary transformation and inner current loop. Contrary to the phase-by-phase control in predictive current controllers, the proposed control scheme advocates three-phase control. As a result, it achieves significant improvement in terms of smaller power ripples, more accurate tracking of power references, and less current harmonics. Further study reveals that the proposed voltage level-based PDPC exhibits less switching frequency irrespective of the magnitude of power references and power angles. Meanwhile, the capability of capacitor voltage balancing control and circulating current control in the proposed PDPC is as good as in the predictive current controllers. Some in-depth simulation comparisons with one of the existing predictive current controllers are given to validate the effectiveness of the proposed strategy.
ISSN:0378-7796
1873-2046
DOI:10.1016/j.epsr.2017.03.023