先进的逆变器与电网的相互作用

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Power Electronics Magazine Pub Date : 2023-06-01 DOI:10.1109/MPEL.2023.3271619

L. Casey, J. Enslin, G. Joós, Mark Siira, B. Borowy, Chase Sun

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引用次数: 0

摘要

基于先进逆变器的资源（IBR）的发展与其在电力网络中应用的增长密切相关。在这一转变过程中，逆变器的大多数应用是电网跟随（GFL）逆变器。随着IBR在电网应用中逐渐取代旋转同步发电机，低惯性电网的行为、当地对电压支持的需求和穿越要求等问题导致了第一次互联要求。最初的DER标准，即IEEE Std 1547-2003，必须适应新的环境，并导致修订后的标准，即IEEEStd 1547–2018，以及后来的传输IBR系统的IEEEStd 2800–2022。本文介绍了现代逆变器的各种逆变器工作模式和功能。未来几年，需要根据SCC-21先进逆变器工作组制定的支持行业标准的更全面的白皮书，重点比较GFL和电网形成（GFM）逆变器，以减少电力系统的全系统IBR事件。

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Advanced Inverter Interactions With Electric Grids

The evolution of advanced inverter-based resources (IBR) is closely coupled with the growth of their applications in electric power networks. Most applications of inverters during this transition were grid-following (GFL) inverters. As IBRs gradually displaced rotating synchronous generators in electric power grid applications, issues such as the behavior of low-inertia grids, local needs for voltage support, and ride-though requirements led to the first interconnection requirements. The initial DER standard, IEEE Std 1547-2003, had to be adapted to the new context and led to the revised standard, IEEE Std 1547–2018 and later the IEEE Std 2800–2022 for transmission IBR systems. In this article, the various inverter operating modes and functions of modern inverters are described. A focus on the comparison of GFL and grid-forming (GFM) inverters based on a more comprehensive white paper developed by the SCC-21 Task Force on Advanced Inverters supporting industry standards is needed in the next few years to reduce system-wide IBR events on the electric system.

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来源期刊

IEEE Power Electronics Magazine ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

2.80

自引率

4.30%

发文量