电力系统自动化
電力繫統自動化
전력계통자동화
AUTOMATION OF ELECTRIC POWER SYSTEMS
2015年
13期
22-31
,共10页
曾正%邵伟华%冉立%吕志鹏%李蕊
曾正%邵偉華%冉立%呂誌鵬%李蕊
증정%소위화%염립%려지붕%리예
可再生能源%配电网%并网逆变器%虚拟同步发电机%储能%优化配置
可再生能源%配電網%併網逆變器%虛擬同步髮電機%儲能%優化配置
가재생능원%배전망%병망역변기%허의동보발전궤%저능%우화배치
renewable energy resources%distribution network%grid-connected inverter%virtual synchronous generator%energy storage%optimal allocation
为了更好地将可再生能源接入配电网,针对并网逆变器的虚拟同步发电机(VSG)控制技术进行了研究。详细分析了VSG的数学模型和控制策略,在不同惯性和阻尼参数条件下,分过阻尼、欠阻尼和临界阻尼3种情况,提出了VSG附加储能单元优化配置的功率、能量和动态响应时间三大指标参数。结果表明:为了模拟同步发电机的惯性和阻尼,VSG需配置一定量的储能单元,其最小功率需求为所需要平抑的可再生能源波动功率的幅值,而其最小能量需求和动态响应时间均为与VSG惯性和阻尼参数相关的简洁表达式。最后,利用一台50 kVA的VSG样机,验证了所提模型和控制策略的正确性和有效性。
為瞭更好地將可再生能源接入配電網,針對併網逆變器的虛擬同步髮電機(VSG)控製技術進行瞭研究。詳細分析瞭VSG的數學模型和控製策略,在不同慣性和阻尼參數條件下,分過阻尼、欠阻尼和臨界阻尼3種情況,提齣瞭VSG附加儲能單元優化配置的功率、能量和動態響應時間三大指標參數。結果錶明:為瞭模擬同步髮電機的慣性和阻尼,VSG需配置一定量的儲能單元,其最小功率需求為所需要平抑的可再生能源波動功率的幅值,而其最小能量需求和動態響應時間均為與VSG慣性和阻尼參數相關的簡潔錶達式。最後,利用一檯50 kVA的VSG樣機,驗證瞭所提模型和控製策略的正確性和有效性。
위료경호지장가재생능원접입배전망,침대병망역변기적허의동보발전궤(VSG)공제기술진행료연구。상세분석료VSG적수학모형화공제책략,재불동관성화조니삼수조건하,분과조니、흠조니화림계조니3충정황,제출료VSG부가저능단원우화배치적공솔、능량화동태향응시간삼대지표삼수。결과표명:위료모의동보발전궤적관성화조니,VSG수배치일정량적저능단원,기최소공솔수구위소수요평억적가재생능원파동공솔적폭치,이기최소능량수구화동태향응시간균위여VSG관성화조니삼수상관적간길표체식。최후,이용일태50 kVA적VSG양궤,험증료소제모형화공제책략적정학성화유효성。
To better interface renewable energy resources (RERs) with the distribution network,the virtual synchronous generators (VSGs) are highlighted.An insightful analysis on the completely mathematical model and control scheme for the VSG is proposed in different virtual inertia and damping conditions.Additionally,according to the mathematical model,the optimal design of energy storage (ES) device of the VSG is achieved.It is found that,to emulate the inertia and damping features of the synchronous generator,an extra energy storage cell should be embedded in it.Besides,the optimal capacity of the ES is the power fluctuation of RERs VSG should suppress,and the desired energy of the ES is analytically decided by the virtual inertia and damping parameters of the VSG.Furthermore,the desired dynamic response time of ES is also obtained for VSG application.Finally,the experimental results obtained on a 50 kVA VSG prototype have verified the proposed model. This work is supported by National Basic Research Program of China (973 Program)(No.2012CB215200) and Fundamental Research Funds for the Central Universities(No.CDJZR12150074,No.106112015CDJXY150005).
