IBR Power Plant Frequency Control Design Consideration

IF 8.6 1区 工程技术 Q1 ENERGY & FUELS
Lingling Fan;Zhixin Miao;Deepak Ramasubramanian
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Abstract

Voltage control is often time provided at the plant-level control of inverter-based resources (IBR). Addition of energy storage systems in an IBR power plant makes it feasible to have frequency control at the power plant level. While frequency control appears as a simple frequency-power droop control to adjust real power commands to inverter-level controls with measured frequency as an input, care must be taken to avoid interactions among the plant frequency control with communication delays, inverter-level control effects, and the frequency sensor, usually a phase-locked-loop (PLL). This paper present two types of interaction scenarios that makes frequency control design challenging. The first interaction scenario may occur if the frequency control's gain is large, while the second interaction scenario may occur at a small control gain if the plant-level PLL lacks sufficient damping. We contribute to the fundamental understanding of the causation of stability issues due to plant frequency control through the derivation of a simplified feedback system focusing on the frequency and power relationship, and the follow-up frequency-domain analysis for gaining insights. For validation, we also design a data-driven approach to obtain models from data generated from an electromagnetic transient (EMT) simulation testbed. The findings from analysis have all been validated by EMT simulation. Finally, we contribute to mitigating strategies and also the understanding of the role of additional proportional integration power feedback control. This addition has been demonstrated as an efficient stability enhancement strategy to mitigate the effect of communication delay.
IBR 发电厂频率控制设计考虑因素
电压控制通常是在逆变器资源(IBR)的电厂级控制中提供的。在 IBR 发电厂中增加储能系统后,就可以在发电厂一级进行频率控制。虽然频率控制看似是一种简单的频率-功率下垂控制,用于将实际功率指令调整为以测量频率为输入的逆变器级控制,但必须注意避免电厂频率控制与通信延迟、逆变器级控制效果以及频率传感器(通常为锁相环 (PLL))之间的相互作用。本文介绍了两种使频率控制设计面临挑战的交互情况。第一种交互情况可能发生在频率控制增益较大的情况下,而第二种交互情况可能发生在控制增益较小的情况下,如果厂级 PLL 缺乏足够的阻尼。我们通过推导一个简化的反馈系统,重点关注频率与功率的关系,并通过后续的频域分析来深入了解工厂频率控制导致稳定性问题的原因,从而为从根本上理解这一问题做出贡献。为了进行验证,我们还设计了一种数据驱动方法,从电磁瞬态(EMT)模拟试验台生成的数据中获取模型。所有分析结果均已通过 EMT 仿真验证。最后,我们对缓解策略以及对附加比例积分功率反馈控制作用的理解做出了贡献。这一附加功能已被证明是一种有效的稳定性增强策略,可减轻通信延迟的影响。
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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来源期刊
IEEE Transactions on Sustainable Energy
IEEE Transactions on Sustainable Energy ENERGY & FUELS-ENGINEERING, ELECTRICAL & ELECTRONIC
CiteScore
21.40
自引率
5.70%
发文量
215
审稿时长
5 months
期刊介绍: The IEEE Transactions on Sustainable Energy serves as a pivotal platform for sharing groundbreaking research findings on sustainable energy systems, with a focus on their seamless integration into power transmission and/or distribution grids. The journal showcases original research spanning the design, implementation, grid-integration, and control of sustainable energy technologies and systems. Additionally, the Transactions warmly welcomes manuscripts addressing the design, implementation, and evaluation of power systems influenced by sustainable energy systems and devices.
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