Improved inverter parallel control strategy based on instantaneous current-sharing control

被引：0

作者：

Ma J.-J. ^{[1
]}

Wang X.-D. ^{[1
]}

Jin N.-Z. ^{[1
]}

Bai Y.-L. ^{[1
]}

Wang G. ^{[1
]}

机构：

[1] School of Electrical and Electronic Engineering, Harbin University of Science and Technology, Harbin

来源：

Dianji yu Kongzhi Xuebao/Electric Machines and Control | 2019年 / 23卷 / 07期

关键词：

Current feed-forward; Current-sharing regulation; Droop control; Instantaneous closed-loop control; Parallel controller;

D O I：

10.15938/j.emc.2019.07.008

中图分类号：

学科分类号：

摘要：

For the issue that the voltage of the inverter parallel system changes greatly with the output load dynamic changes, an improved current-sharing control method was proposed. Based on the traditional inverter model with output voltage feed-forward and double close-loop control method, the load-current feed-forward control method was added. The effect of load-current feed-forward control on the dynamic performance was analyzed in two different ways. Besides, based on the instantaneous closed-loop controller, the proposed regulator of the parallel system was designed according to the droop characteristic of the current circulation. Finally, a parallel system with 6×20 kVA inverters was established. The experimental results show that with the proposed control method, the current-sharing error of the system is greatly decreased. Compared with the traditional method by the hardware signals, this method is not susceptible to interference. And the results also show that the proposed method has good steady-state and dynamic performance. © 2019, Harbin University of Science and Technology Publication. All right reserved.

引用

页码：63 / 71

页数：8

共 15 条

[1] Nutkani I.U., Loh P.C., Wang P., Et al., Cost-prioritized droop schemes for autonomous AC microgrids, IEEE Transactions on Power Electronics, 30, 2, (2015)
[2] Wu D., Tang F., Dragicevic T., Et al., A control architecture to coordinate renewable energy sources and energy storage systems in islanded microgrids, IEEE Transactions on Smart Grid, 6, 3, (2015)
[3] Bojoi R.I., Limongi L.R., Roiu D., Et al., Enhanced power quality control strategy for single-phase inverters in distributed generation systems, IEEE Transactions on Power Electronics, 26, 3, (2011)
[4] Orfanoudakis G.I., Yuratich M.A., Sharkh S.M., Hybrid modulation strategies for eliminating low-frequency neutral-point voltage oscillations in the neutral-point-clamped converter, IEEE Transactions on Power Electronics, 28, 8, (2013)
[5] Jiao Y., Lee F.C., Lu S., Space vector modulation for three-level NPC converter with neutral point voltage balance and switching loss reduction, IEEE Transactions on Power Electronics, 29, 10, (2014)
[6] Nutkani I.U., Loh P.C., Wang P., Et al., Decentralized economic dispatch scheme with online power reserve for microgrids, IEEE Transactions on Smart Grid, 8, 1, (2017)
[7] Mahmood H., Michaelson D., Jiang J., Accurate reactive power sharing in an islanded microgrid using adaptive virtual impedances, IEEE Transactions on Power Electronics, 30, 3, (2015)
[8] Han H., Liu Y., Sun Y., Et al., An improved droop control strategy for reactive power sharing in islanded microgrid, IEEE Transactions on Power Electronics, 30, 6, (2015)
[9] Chen T.P., Zero-sequence circulating current reduction method for parallel HEPWM inverters between AC bus and DC bus, IEEE Transactions on Industrial Electronics, 59, 1, (2012)
[10] Hou C.C., A multicarrier PWM for parallel three-phase active front-end converters, IEEE Transactions on Power Electronics, 28, 6, (2013)

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