Modeling and scheduling of utility-scale energy storage toward high-share renewable coordination

IF 2.6 4区 工程技术 Q3 ENERGY & FUELS Frontiers in Energy Research Pub Date : 2024-09-13 DOI:10.3389/fenrg.2024.1445092
Ran Ding, Xuanyuan Wang, Wei Qiu, Yiming Yao, Haixiang Xu, Yan Geng, Zhihuan Zhuo, Jiayi Han
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Abstract

As the integration of high-proportion renewable energy into the grid increases, the intermittency and uncertainty of renewable energy output significantly affect the safe and stable operation of the power system. Combining utility-scale energy storage technology with renewable coordination is one of the methods to address these issues. Compressed air energy storage (CAES) has garnered extensive attention due to its large capacity, long operational life, and clean, low-carbon advantages. Given the poor compressibility of air and its high critical point, using carbon dioxide as the working fluid in utility-scale energy storage systems can achieve higher energy storage density and cycle efficiency. Accordingly, this paper focuses on the study of utility-scale energy storage system modeling and scheduling methods considering carbon dioxide energy storage. It investigates Compressed Carbon Dioxide Energy Storage (CCES) systems, analyzes the operational framework of typical CCES systems, and sequentially establishes models for the energy storage process, energy release process, hot water tank operation, and gas storage tank operation. Based on this, it explores power system optimization dispatch methods considering CCES, incorporating the established models into an optimization dispatch model for power systems with high wind power penetration. Within the framework of a safe constraint unit commitment study, using the IEEE-30 nodes model, the effectiveness of the established models is validated. The case study results confirm the role of CCES in enhancing the absorption rate of renewable coordination. Moreover, under the same storage conditions, compared to, CCES offers greater charging and discharging power and higher energy storage density.
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公用事业规模储能的建模与调度,实现高份额可再生能源协调
随着高比例可再生能源并入电网的增加,可再生能源输出的间歇性和不确定性极大地影响了电力系统的安全稳定运行。将公用事业级储能技术与可再生能源协调相结合是解决这些问题的方法之一。压缩空气储能(CAES)因其容量大、运行寿命长、清洁低碳等优势而受到广泛关注。鉴于空气的可压缩性差且临界点高,在公用事业规模的储能系统中使用二氧化碳作为工作流体可以实现更高的储能密度和循环效率。因此,本文重点研究了考虑二氧化碳储能的公用事业级储能系统建模和调度方法。本文研究了压缩二氧化碳储能(CCES)系统,分析了典型 CCES 系统的运行框架,并依次建立了储能过程、能量释放过程、热水箱运行和储气罐运行模型。在此基础上,探讨了考虑 CCES 的电力系统优化调度方法,将已建立的模型纳入高风电渗透率电力系统的优化调度模型。在安全约束机组承诺研究的框架内,使用 IEEE-30 节点模型,验证了既定模型的有效性。案例研究结果证实了 CCES 在提高可再生能源协调吸收率方面的作用。此外,在相同的储能条件下,CCES 的充放电功率更大,储能密度更高。
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来源期刊
Frontiers in Energy Research
Frontiers in Energy Research Economics, Econometrics and Finance-Economics and Econometrics
CiteScore
3.90
自引率
11.80%
发文量
1727
审稿时长
12 weeks
期刊介绍: Frontiers in Energy Research makes use of the unique Frontiers platform for open-access publishing and research networking for scientists, which provides an equal opportunity to seek, share and create knowledge. The mission of Frontiers is to place publishing back in the hands of working scientists and to promote an interactive, fair, and efficient review process. Articles are peer-reviewed according to the Frontiers review guidelines, which evaluate manuscripts on objective editorial criteria
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