Inertia control method of direct drive permanent magnet wind turbine under high wind power permeability

Fangyuan Wang
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Abstract

Direct-drive permanent magnet wind turbine has high power generation efficiency, especially in low wind speed environment, and is widely used for wind power generation. Direct-driven permanent magnet wind turbines show no inertia response to the system through the grid connection of full-power converters, resulting in increased frequency fluctuation, poor response effect and reduced stability time of the system under sudden load and sudden wind speed conditions. Based on this, an inertia control method of direct-drive permanent magnet wind turbine under high wind power penetration is proposed, and the model of direct-drive permanent magnet wind turbine is built by designing functional modules to improve the synchronous control effect under high wind power penetration. The vector control calculation method is used to design the virtual inertia control parameters, and the decoupling quantity is introduced to decouple the parameters with filter inductance, so as to improve the supporting capacity of power grid frequency fluctuation. The simulation results show that the proposed method has a fast frequency response under sudden load change, and it drops to the lowest value of 49.16 Hz at 12.14 s. Under the condition of sudden change of wind speed, the system frequency rises to the highest value of 50.38 Hz at 12.94 s. It is proved that the proposed method has a certain suppression effect on the amplitude of frequency change, effectively shortens the time for the system frequency to return to steady state, and thus has more advantages.
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高导电性直驱永磁风力机惯性控制方法
直驱式永磁风力发电机组发电效率高,特别是在低风速环境下,被广泛应用于风力发电。直驱式永磁风力机通过全功率变流器并网后对系统无惯性响应,导致系统在突然负荷和突然风速条件下频率波动增大,响应效果差,稳定时间缩短。在此基础上,提出了一种大穿透风力直驱永磁风力机的惯性控制方法,并通过设计功能模块建立直驱永磁风力机模型,提高大穿透风力机的同步控制效果。采用矢量控制计算方法设计虚拟惯性控制参数,并引入解耦量与滤波电感进行解耦,提高对电网频率波动的支持能力。仿真结果表明,该方法在负载突变时具有较快的频率响应,在12.14 s时频率响应降至49.16 Hz的最低值。风速突变条件下,系统频率在12.94 s时达到最大值50.38 Hz。实验证明,该方法对频率变化幅度有一定的抑制作用,有效缩短了系统频率恢复稳态的时间,具有更多的优势。
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