基于变系数PI控制的双馈风电机组自适应转速恢复策略

doi:10.19595/j.cnki.1000-6753.tces.220852

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摘要针对现有的双馈风电机组转速恢复策略无法兼顾抑制频率二次跌落和转速恢复性能的问题,提出一种基于变系数PI控制的转速恢复策略。首先,揭示转速恢复策略启动时刻、有功减载量对频率二次跌落和转速恢复性能的影响机制;其次,提出基于定系数PI控制的双馈风电机组转速恢复策略,初步实现有功减载量以“先抑后扬”的输出方式进行转速恢复;然后,针对基于定系数PI控制的转速恢复策略的不足,根据不同运行工况,将PI控制系数与风机转速建立耦合关系,提出基于变系数PI控制的自适应转速恢复策略,实现了在兼顾抑制频率二次跌落的同时,保障转速恢复性能;最后,通过EMTP-RV软件搭建不同扰动、风电渗透率的电力系统模型,验证了所提策略的有效性。

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关键词 ：双馈风电机组, 自适应转速恢复, 频率二次跌落, PI控制

Abstract：Doubly-fed induction generator (DFIG) participates in frequency regulation to support the reduced system inertia. After frequency regulation, the rotor speed is lower than the optimal speed. It is necessary to regain the rotor speed, otherwise, the rate of wind energy utilization would be reduced, or stalling of DFIG even be caused. The existing rotor speed recovery methods only unilaterally improved the performance of speed recovery or reduced the size of frequency secondary drop. To address these issues, this paper suggests a variable-coefficient-PI-control speed recovery strategy.
Firstly, this paper revealed the influence mechanism of the amount of the active power reduction and the invitation of the recovery strategy on the frequency secondary drop and the speed recovery performance; secondly, a recovery strategy of the DFIG based on fixed-PI-coefficient control was proposed, the reduction output power with “rise after restrain” manner had been preliminarily constructed to speed recovery. Then, to solve the shortcomings of the recovery strategy with fixed-PI-coefficient, this paper established the coupling relationship between rotor speed of the doubly-fed induction generators and PI control coefficients according to different operating conditions, and then constructed an adaptive recovery strategy based on variable-PI-coefficient to ensure the speed recovery performance while suppressing the frequency secondary drop. Finally, power system model with various wind power penetrations and disturbances was modeled based on an EMTP-RV to investigate the effectiveness of the proposed rotor speed recovery strategy.
Simulation results on the different speed recovery strategies illustrate that, under the disturbance of 90 MW with the wind power penetration of 20%, since the DFIG directly removed the frequency support control strategy, it caused a sudden power change of 0.116(pu) so as to result in a frequency secondary drop of 49.69 Hz; the DFIG absorbed more kinetic energy during the short period, the rotor speed regained to the initial value at 95 s; when the DFIG used the fixed-coefficient-PI-control speed recovery strategy, the sudden power variation was reduced by 0.082(pu), the frequency secondary nadir was improved by 0.030 Hz, however, the time for the speed recovery was extended to 120 s; the use of variable-coefficient-PI-control speed recovery strategy started speed recovery without sudden power variation, as a result, no frequency secondary drop was caused, the amount of the active power reduction increase leaded to faster speed recovery during the latter period. When the disturbances increased to 150 MW, the variable-PI-coefficient speed recovery strategy could still maintain the better speed recovery performance and avoid secondary frequency drop. In the case of a large disturbance with a high wind penetration level, the frequency secondary drops for the direct rotor speed recovery and fixed-PI-coefficient speed recovery strategy were lower than the first frequency nadir caused by the disturbance, however, the variable-PI-coefficient speed recovery strategy could guarantee the speed recovery performance without causing a second frequency drop.
The following conclusions can be drawn from the simulation analysis: (1) In specific cases, the fixed-coefficient-PI-control speed recovery strategy can preliminarily constructed the “rise after restrain” manner of the active power reduction so as to mitigate the size of frequency secondary drop and ensure speed recovery performance by reasonably employing the parameters of PI controller. (2) The proposed variable-coefficient-PI-control speed recovery strategy can achieve the counterbalance between frequency secondary dip and rotor speed recovery performance compared to constant- coefficient-PI-control speed recovery strategy since the reduction output power with “rise after restrain” manner had been constructed to during the rotor speed recovery period.

Key words： Doubly-fed induction generator (DFIG) adaptive rotor speed recovery frequency secondary drop PI control

收稿日期: 2022-05-18

PACS:

TM614

基金资助:东北电力大学博士科研启动基金资助项目（BSJXM-2021209）

通讯作者: 杨德健男,1990年生,博士,讲师,研究方向为可再生能源联网控制技术。E-mail：yangdejian@neepu.edu.cn

作者简介: 王鑫男,1999年生,硕士研究生,研究方向为可再生能源联网控制技术。E-mail： 1954592617@qq.com

引用本文:

王鑫, 杨德健. 基于变系数PI控制的双馈风电机组自适应转速恢复策略[J]. 电工技术学报, 2023, 38(15): 4120-4129. Wang Xin, Yang Dejian. Adaptive Speed Recovery Strategy of Doubly-Fed Induction Generator Based on Variable PI Control Coefficient. Transactions of China Electrotechnical Society, 2023, 38(15): 4120-4129.

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