报告题目:Low Inertia Systems: Complex Frequency and Simple Control
报 告 人:Prof.Federico Milano
会议时间:5月9日(周二)16:00
会议地点:腾讯会议 820-434-734
主办单位:重庆大学、输配电装备及系统安全与新技术国家重点实验室、重庆大学溧阳智慧城市研究院
协办单位:四川大学、电子科技大学、西南交通大学、成都理工大学、成都中医药大学、四川师范大学、亚洲bet356体育APP下载、西南科技大学、西南大学、重庆邮电大学、重庆科技学院
Personal Profile:
Federico Milano received from the University of Genoa, Italy, the Electrical Engineer degree and the Ph.D. in Electrical Engineering in March 1999 and June 2003, respectively. In June 2013, he joined the UCD School of Electrical and Electronic Engineering, where he is currently Full Professor of Power Systems Control and Protections. Since 2012, he is an editor of the IEEE Transactions on Power Systems. In January 2016. he was elevated to IEEE Fellow for his contributions to power system modelling and simulation. In December 2017, he was elevated to IET Fellow. Since January 2020 is a member of the IEEE PES Distinguished Lecturer Program. Since 2022, he is Co-Editor in Chief of the IET Generation, Transmission & Distribution and, since 2023, he is Senior Editor of the IEEE Transactions on Power Systems and a member of the Cigre Irish National Committee. He is also the Chair of the Technical Programme Committee of the Power System Computation Conference (PSCC) 2024. His research interests include power system modelling, control and stability analysis.
Abstract:
The conventional power system model for transient stability analysis assumes of quasi-steady-state phasors for voltages and currents. This model is appropriate if only synchronous machines regulate the system frequency through standard primary and secondary frequency regulators. In recent years, however, an increasing number of devices other than synchronous machines are expected to provide frequency regulation. There is thus, from a modeling point of view, the need to define with accuracy the local frequency at every bus of the network. The talk first presents the definition of “complex frequency and poses the basis of a set of equations that link this new quantity with the active and reactive power injections at network buses. Then, leveraging on the concept of complex frequency, the talk discusses the coupling of frequency and voltage control of Distributed Energy Resources (DERs) in low-inertia systems. A general approach to define the ability of these devices to modify the frequency at their point of connection is discussed. A variety of examples of coupled frequency/voltage controllers are presented and shown to be more effective than conventional decoupled active and reactive power controllers.
