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CLC number: TM315

On-line Access: 2024-08-27

Received: 2023-10-17

Revision Accepted: 2024-05-08

Crosschecked: 2015-03-06

Cited: 0

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Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Heng Nian

http://orcid.org/0000-0003-4816-084X

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Frontiers of Information Technology & Electronic Engineering  2015 Vol.16 No.4 P.321-334

http://doi.org/10.1631/FITEE.1400170


Multiple target implementation for a doubly fed induction generator based on direct power control under unbalanced and distorted grid voltage


Author(s):  Heng Nian, Yi-peng Song

Affiliation(s):  College of Electrical Engineering, Zhejiang University, Hangzhou 310027, China

Corresponding email(s):   nianheng@zju.edu.cn

Key Words:  Direct power control, Doubly fed induction generator, Unbalanced and distorted grid voltage, Vector proportional and integral resonant regulator, Parameter deviation


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Heng Nian, Yi-peng Song. Multiple target implementation for a doubly fed induction generator based on direct power control under unbalanced and distorted grid voltage[J]. Frontiers of Information Technology & Electronic Engineering, 2015, 16(4): 321-334.

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Abstract: 
This paper presents a multiple target implementation technique for a doubly fed induction generator (DFIG) under unbalanced and distorted grid voltage based on direct power control (DPC). Based on the mathematical model of DFIG under unbalanced and distorted voltage, the proportional and integral (PI) regulator is adopted to regulate the DFIG average active and reactive powers, while the vector PI (VPI) resonant regulator is used to achieve three alternative control targets: (1) balanced and sinusoidal stator current; (2) smooth instantaneous stator active and reactive powers; (3) smooth electromagnetic torque and instantaneous stator reactive power. The major advantage of the proposed control strategy over the conventional method is that neither negative and harmonic sequence decomposition of grid voltage nor complicated control reference calculation is required. The insensitivity of the proposed control strategy to DFIG parameter deviation is analyzed. Finally, the DFIG experimental system is developed to validate the availability of the proposed DPC strategy under unbalanced and distorted grid voltage.

The paper discusses a directly control strategy for DFIG under non-idea grid. The work seems interesting and research quite valuable. Specially good is the experimental validation.

不平衡及谐波电网下基于直接功率控制的双馈风力发电机组多目标控制策略

目的:改善运行于不平衡及谐波电网下的双馈风力发电机组运行性能,所采用的三个控制目标分别为DFIG输出定子电流三相对称且正弦、DFIG输出定子有功功率及无功功率平稳和DFIG电磁转矩与输出无功功率平稳。
创新点:采用的直接目标控制策略,无需对定子电压或电流分量进行负序及谐波分量提取,此外,也无需对各个控制目标进行参考值计算,因此能够简化控制策略结构,有利于控制系统快速动态响应能力。
方法:首先,简述双馈风力发电机组在不平衡及谐波畸变电网条件下的数学模型。然后,提出此条件下的直接目标控制策略,分别直接对三个目标中的待控制分量进行调节,其中PI调节器确保DFIG输出有功功率及无功功率的平均值,而VPI调节器确保实现三个控制目标中的任意一个。此外,当实现控制目标定子输出有功功率及无功功率平稳时,对定子电流中的三次谐波分量进行理论角度的定量分析;且对所提基于VPI调节器的闭环控制进行针对DFIG电机参数偏移的鲁棒性分析。最终,通过MATLAB/Simulink进行仿真分析验证,并搭建实验硬件平台系统进行实验验证,最终证明所提控制策略的有效性与可行性。
结论:提出改善运行于不平衡及谐波电网下的双馈风力发电机组运行性能的控制策略,所采用的三个控制目标分别为DFIG输出定子电流三相对称且正弦、DFIG输出定子有功功率及无功功率平稳和DFIG电磁转矩与输出无功功率平稳。所提控制策略相比于传统控制策略具有如下优点:无需对定子电压或电流进行负序及谐波分量提取且无需对各个控制目标进行参考值计算。

关键词:直接功率控制;双馈风力发电机组;不平衡及谐波畸变电网;VPI调节器;电机参数偏移

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Reference

[1]Cardenas, R., Pena, R., Alepuz, S., et al., 2013. Overview of control systems for the operation of DFIGs in wind energy applications. IEEE Trans. Ind. Electron., 60(7):2776-2798.

[2]Hu, J., He, Y., 2009. Reinforced control and operation of DFIG-based wind-power-generation system under unbalanced grid voltage conditions. IEEE Trans. Energy Conv., 24(4):905-915.

[3]Hu, J., He, Y., Xu, L., et al., 2009. Improved control of DFIG systems during network unbalance using PI–R current regulators. IEEE Trans. Ind. Electron., 56(2):439-451.

[4]Hu, J., Xu, H., He, Y., 2013. Coordinated control of DFIG’s RSC and GSC under generalized unbalanced and distorted grid voltage conditions. IEEE Trans. Ind. Electron., 60(7):2808-2819.

[5]Iwanski, G., Koczara, W., 2008. DFIG-based power generation system with UPS function for variable-speed applications. IEEE Trans. Ind. Electron., 55(8):3047-3054.

[6]Jabr, H.M., Kar, N.C., 2007. Effects of main and leakage flux saturation on the transient performances of doubly-fed wind driven induction generator. Electr. Power Syst. Res., 77(8):1019-1027.

[7]Lascu, C., Asiminoaei, L., Boldea, I., et al., 2007. High performance current controller for selective harmonic compensation in active power filters. IEEE Trans. Power Electron., 22(5):1826-1835.

[8]Lascu, C., Asiminoaei, L., Boldea, I., et al., 2009. Frequency response analysis of current controllers for selective harmonic compensation in active power filters. IEEE Trans. Ind. Electron., 56(2):337-347.

[9]Liu, C., Blaabjerg, F., Chen, W., et al., 2012. Stator current harmonic control with resonant controller for doubly fed induction generator. IEEE Trans. Power Electron., 27(7):3207-3220.

[10]Luna, A., Lima, F.K.A., Santos, D., et al., 2011. Simplified modeling of a DFIG for transient studies in wind power applications. IEEE Trans. Ind. Electron., 58(1):9-20.

[11]Martinez, M.I., Susperregui, A., Tapia, G., et al., 2013. Sliding-mode control of a wind turbine-driven double-fed induction generator under non-ideal grid voltages. IET Renew. Power Gener., 7(4):370-379.

[12]Nian, H., Song, Y., 2014. Direct power control of doubly fed induction generator under distorted grid voltage. IEEE Trans. Power Electron., 29(2):894-905.

[13]Nian, H., Song, Y., Zhou, P., et al., 2011. Improved direct power control of a wind turbine driven doubly fed induction generator during transient grid voltage unbalance. IEEE Trans. Energy Conv., 26(3):976-986.

[14]Pena, R., Cardenas, R., Reyes, E., et al., 2011. Control of doubly fed induction generator via an indirect matrix converter with changing DC voltage. IEEE Trans. Ind. Electron., 58(10):4664-4674.

[15]Xu, H., Hu, J., He, Y., 2012a. Operation of wind-turbine-driven DFIG systems under distorted grid voltage conditions: analysis and experimental validations. IEEE Trans. Power Electron., 27(5):2354-2366.

[16]Xu, H., Hu, J., He, Y., 2012b. Integrated modeling and enhanced control of DFIG under unbalanced and distorted grid voltage conditions. IEEE Trans. Energy Conv., 27(3):725-736.

[17]Xu, L., Wang, Y., 2007. Dynamic modeling and control of DFIG-based wind turbines under unbalanced network conditions. IEEE Trans. Power Syst., 22(1):314-323.

[18]Xu, L., Zhi, D., Williams, B.W., 2009. Predictive current control of doubly fed induction generators. IEEE Trans. Ind. Electron., 56(10):4143-4153.

[19]Zhou, P., He, Y., Sun, D., 2009. Improved direct power control of a DFIG-based wind turbine during network unbalance. IEEE Trans. Power Electron., 24(11):2465-2474.

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