增强微电网中的虚拟惯性控制:基于存储系统的新型频率响应模型

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY Batteries Pub Date : 2024-01-03 DOI:10.3390/batteries10010018
Adrián Criollo, L. I. Minchala-Ávila, D. Benavides, Paul Arévalo, M. Tostado‐Véliz, Daniel Sánchez-Lozano, F. Jurado
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引用次数: 0

摘要

在孤立系统中整合可再生资源,会因其间歇性而导致电网不稳定。在当今缺乏同步发电的微电网中,物理惯性被惯性模拟所取代。迄今为止,最有效的方法仍然是频率导数控制技术。然而,在这种方法的设计中,提供虚拟下垂的能力往往被忽视,这可能导致在可再生能源渗透率高、阻尼低的系统中发展不足。为解决这一问题,本文介绍了虚拟惯性控制的创新设计和分析方法,以同时模拟微电网中的下垂和惯性特性。通过仿真分析了无可再生能源渗透和有可再生能源渗透时的动态频率响应。拟议的虚拟惯性控制采用导数技术来测量惯性模拟过程中频率斜率的变化率。还进行了灵敏度映射,以仔细研究其对动态频率响应的影响。最后,昆卡大学微电网的物理电池存储系统被用作运行条件下的案例研究。
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Enhancing Virtual Inertia Control in Microgrids: A Novel Frequency Response Model Based on Storage Systems
The integration of renewable resources in isolated systems can produce instability in the electrical grid due to its intermintency. In today’s microgrids, which lack synchronous generation, physical inertia is substituted for inertia emulation. To date, the most effective approach remains the frequency derivative control technique. Nevertheless, within this method, the ability to provide virtual drooping is often disregarded in its design, potentially leading to inadequate development in systems featuring high renewable penetration and low damping. To address this issue, this paper introduces an innovative design and analysis of virtual inertia control to simultaneously mimic droop and inertia characteristics in microgrids. The dynamic frequency response without and with renewable energy sources penetration is comparatively analyzed by simulation. The proposed virtual inertia control employs a derivative technique to measure the rate of change of frequency slope during inertia emulation. Sensitivity mapping is conducted to scrutinize its impact on dynamic frequency response. Finally, the physical battery storage system of the University of Cuenca microgrid is used as a case study under operating conditions.
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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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