电力系统自动化
電力繫統自動化
전력계통자동화
AUTOMATION OF ELECTRIC POWER SYSTEMS
2012年
5期
29-34
,共6页
微电网%分布式发电%孤岛运行%并网运行%下垂控制%电压源逆变器控制%PQ控制
微電網%分佈式髮電%孤島運行%併網運行%下垂控製%電壓源逆變器控製%PQ控製
미전망%분포식발전%고도운행%병망운행%하수공제%전압원역변기공제%PQ공제
microgrid%distributed generation%isolated island operation%grid-connected operation%droop control%voltage source inverter control%PQ control
根据微电网的特点,对微电网2种运行模式采取的不同控制策略进行设计。微电网孤岛运行时,分布式发电单元采用电压源逆变器控制,使用电压—相角下垂控制实现按预定比例分配负荷功率,该下垂控制较电压—频率下垂控制可以提供更好的频率支撑。微电网并网运行时,分布式发电单元采用PQ控制,按照功率设定值输出功率。通过设计对应电压—相角下垂控制的同步控制器实现了微电网运行模式的无缝转换。利用MATLAB/Simulink对微电网运行模式转换和微电网孤岛运行时使用的2种下垂控制进行对比仿真分析,验证了电压—相角下垂控制策略的可行性和有效性。
根據微電網的特點,對微電網2種運行模式採取的不同控製策略進行設計。微電網孤島運行時,分佈式髮電單元採用電壓源逆變器控製,使用電壓—相角下垂控製實現按預定比例分配負荷功率,該下垂控製較電壓—頻率下垂控製可以提供更好的頻率支撐。微電網併網運行時,分佈式髮電單元採用PQ控製,按照功率設定值輸齣功率。通過設計對應電壓—相角下垂控製的同步控製器實現瞭微電網運行模式的無縫轉換。利用MATLAB/Simulink對微電網運行模式轉換和微電網孤島運行時使用的2種下垂控製進行對比倣真分析,驗證瞭電壓—相角下垂控製策略的可行性和有效性。
근거미전망적특점,대미전망2충운행모식채취적불동공제책략진행설계。미전망고도운행시,분포식발전단원채용전압원역변기공제,사용전압—상각하수공제실현안예정비례분배부하공솔,해하수공제교전압—빈솔하수공제가이제공경호적빈솔지탱。미전망병망운행시,분포식발전단원채용PQ공제,안조공솔설정치수출공솔。통과설계대응전압—상각하수공제적동보공제기실현료미전망운행모식적무봉전환。이용MATLAB/Simulink대미전망운행모식전환화미전망고도운행시사용적2충하수공제진행대비방진분석,험증료전압—상각하수공제책략적가행성화유효성。
Based on microgrid features,different control strategies are designed for two operation modes of microgrid.When the microgrid is on isolated island operation mode,distributed generation units adopt voltage source inverter control,using voltage amplitude and phase angle droop control to share load power according to predetermined proportion.This droop control can provide better frequency support than voltage amplitude and frequency droop control.When the microgrid is on grid-connected operation mode,distributed generation units adopt PQ control so as to output power according to given values.Microgrid operation modes can achieve seamless transition by using synchronization controller corresponding to voltage amplitude and phase angle droop control.Microgrid transition between operation modes and comparison between two kinds of droop control when microgrid operates on isolated island operation mode are analyzed.MATLAB/Simulink simulation shows that voltage amplitude and phase angle droop control strategy is feasible and effective.
