Dynamic Power Tracking Performance and Small Signal Stability Analysis of Integrated Wind-to-Hydrogen System

IF 8.6 1区工程技术 Q1 ENERGY & FUELS

IEEE Transactions on Sustainable Energy Pub Date : 2024-07-02 DOI:10.1109/TSTE.2024.3422133

Han Mu;Dongsheng Yang;Yin Sun;Lucia Beloqui Larumbe

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Abstract

To achieve the 2050 global climate target, offshore wind will increase to meet the growing demand of direct and indirect electrification (e.g. green hydrogen production for the hard-to-abate sector). To keep up with the rapid increase of offshore wind generation, the energy balancing challenges due to the intermittency nature of wind and the network congestion/capacity challenges resulting from structural network capacity planning latency are to be addressed with system integration technology. In this paper, it is proposed that the hydrogen electrolysis plant be co-located with the wind farm, where the power consumption is controlled to track the wind generation profile accurately to cancel the intermittency of wind generation, reduce the required grid connection capacity, and thereby avoid expensive grid expansion. However, this power tracking controller introduces a cross-plant feedback path from the wind farm to the hydrogen plant, posing challenges for partitioning the power tracking loop completely for stability analysis, which also makes it difficult to make a good trade-off between the tracking performance and stability margins. To address this issue, this paper proposes an equivalent transformation to eliminate the cross-plant feedback path. Then, the criteria for choosing the optimal partition method are proposed and examined for different types of partition methods, which are mathematically proven to be equivalent in terms of stability conditions but provide different insights. An optimal partition method is then proposed in this paper, which not only provides clear insight on the ideal and non-ideal power tracking performances but also can also identify the stability issues of different minor loops individually. Finally, the proposed optimal partition method and its valuable insights into power tracking performance and stability analysis are validated through time-domain simulations of a 180 MW integrated wind-to-hydrogen plant with a realistic complexity.

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风制氢集成系统的动态功率跟踪性能和小信号稳定性分析

为实现 2050 年全球气候目标，海上风力发电量将增加，以满足日益增长的直接和间接电气化需求（例如，为难以消减的行业生产绿色氢气）。为了跟上海上风力发电的快速增长，需要利用系统集成技术来解决风力间歇性所带来的能源平衡挑战，以及结构性网络容量规划延迟所带来的网络拥塞/容量挑战。本文建议将电解制氢厂与风电场共建，通过控制电能消耗来精确跟踪风力发电曲线，以消除风力发电的间歇性，减少所需的并网容量，从而避免昂贵的电网扩容。然而，这种功率跟踪控制器引入了一条从风电场到制氢厂的跨厂反馈路径，给完全分割功率跟踪环路进行稳定性分析带来了挑战，同时也难以在跟踪性能和稳定性裕度之间做出很好的权衡。针对这一问题，本文提出了一种等效变换来消除跨电厂反馈路径。然后，针对不同类型的分区方法，提出了最优分区方法的选择标准，并对其进行了研究，从数学角度证明了这些方法在稳定性条件方面是等效的，但却提供了不同的启示。然后，本文提出了一种最优分区方法，它不仅能清晰地揭示理想和非理想功率跟踪性能，还能单独识别不同小环路的稳定性问题。最后，通过对一个具有现实复杂性的 180 兆瓦综合风力制氢发电厂进行时域仿真，验证了所提出的优化分区方法及其对功率跟踪性能和稳定性分析的宝贵见解。

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 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.