[关键词]
[摘要]
采用平均磁链定向控制多台永磁同步风电机组进而构造分频发电系统是未来陆上尤其是海上风电的汇集方案之一,但对该模式下多台风电机组间稳定性的研究鲜有文献涉及。针对此问题,基于特征值分析法,研究了平均磁链定向控制的永磁同步风电机组之间的小干扰稳定性。首先,基于高压大容量直驱式永磁同步风电机组的分频集电系统拓扑结构,建立了适用于小干扰稳定分析的风电系统的数学模型;其次,通过辨识振荡模态并分析模态参与因子确定了影响系统振荡的主控因素,通过绘制根轨迹分析了主控因素参数变化对系统振荡的影响,并发现系统振荡受发电机电感、电阻和直流电容参数的影响最大;最后,通过时域仿真验证了研究结论的正确性
[Key word]
[Abstract]
The use of average flux orientation control of multiple permanent magnet synchronous wind turbines and thus the construction of fractional frequency wind power systems, is one of the potential future options for onshore and offshore wind power. Nonetheless, the study of the stability among multiple wind turbines in this mode is rarely covered in the literature. To address this problem, the stability of small disturbances among permanent magnet synchronous wind turbines with average flux orientation control is investigated based on the eigenvalue analysis method. Firstly, based on the topology of the crossover collector system of high-voltage and large-capacity direct-drive permanent magnet synchronous wind turbines, a mathematical model of the wind power system applicable to the analysis of small disturbances stability is established. Secondly, the primary factors affecting system oscillations are determined by identifying the oscillatory modes and analyzing the modal participation factors, and the impact of parameter variations on the oscillatory of the system is examined by plotting the trajectories of the roots. It is concluded that the system oscillations are most affected by the generator inductance, resistance, and direct current capacitance parameters. Finally, the correctness of the findings is verified by time domain simulations.
[中图分类号]
[基金项目]
国家自然科学基金面上项目(51977220)