On implementation of primary frequency control in MMC-HVDC transmission systems

2017 IEEE PES Innovative Smart Grid Technologies Conference Europe (ISGT-Europe) Pub Date : 2017-09-01 DOI:10.1109/ISGTEurope.2017.8260239

Y. Rink, L. Held, S. Wenig, M. Suriyah, T. Leibfried

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引用次数: 2

Abstract

This paper investigates methodologies for the utilization of modular multilevel HVDC transmission (MMC-HVDC) for primary frequency control. In contrast to conventionally used average voltage source converter (VSC) models for frequency support system studies, advanced MMC models provide a different dynamic behaviour due to their decoupled ac and dc current control. Following the underlying converter and dynamic ac grid models, four different methods for primary frequency support by MMCs are presented in this paper. The individual control designs differ in their required input signals, controller characteristics in terms of proportional or PI structures and potential applications with respect to ac system properties. To prove the overall functionality and to highlight differences in the respective dynamic system responses as well as recovered steady-state conditions after occuring active power imbalances, a comparison using numerical simulations is carried out for a point-to-point MMC-HVDC transmission system connecting two non-synchronous areas.

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MMC-HVDC输电系统一次频率控制的实现

本文研究了利用模块化多级高压直流输电(MMC-HVDC)进行一次频率控制的方法。与用于频率支持系统研究的传统平均电压源转换器(VSC)模型相比，先进的MMC模型由于其交流和直流电流的解耦控制而提供了不同的动态行为。在基础变换器和动态交流电网模型的基础上，本文提出了四种不同的mmc支持一次频率的方法。各个控制设计的不同之处在于它们所需的输入信号、比例或PI结构方面的控制器特性以及与交流系统特性相关的潜在应用。为了证明整体功能，并突出各自动态系统响应以及发生有功功率不平衡后恢复稳态条件的差异，使用数值模拟对连接两个非同步区域的点对点MMC-HVDC输电系统进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 IEEE PES Innovative Smart Grid Technologies Conference Europe (ISGT-Europe)

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