Enabling LVRT Compliance of Electrolyzer Systems Using Energy Storage Technologies

IF 4.6 4区化学 Q2 ELECTROCHEMISTRY

Batteries Pub Date : 2023-10-24 DOI:10.3390/batteries9110527

Pankaj Saha, Weihao Zhao, Daniel-Ioan Stroe, Florin Iov, Stig Munk-Nielsen

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Abstract

This paper presents a comprehensive techno-economic analysis of different energy storage systems (ESSs) in providing low-voltage ride-through (LVRT) support for power electronics-based electrolyzer systems. A framework for analyzing the performance of a grid-integrated electrolyzer-ESS system is developed, taking into account realistic scenarios and accurate models. The system components consist of a 500 kW alkaline electrolyzer module integrated with a medium-voltage grid and three different commercially available ESSs based on Li-ion battery, Li-ion capacitor, and supercapacitor technology, respectively. The performance of these ESSs is extensively studied for three LVRT profiles, with a primary focus on the upcoming Danish grid code. In order to perform simulation studies, the system is implemented on the MATLAB®/Simulink®-PLECS® platform. The results demonstrate that all three energy storage technologies are capable of supporting the electrolyzer systems during low-voltage abnormalities in the distribution grid. The study also reveals that the supercapacitor-based technology seems to be more appropriate, from a techno-economic perspective, for fault ride-through (FRT) compliance.

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利用储能技术实现电解槽系统的LVRT合规性

本文对不同的储能系统(ess)在为电力电子电解槽系统提供低压穿越(LVRT)支持方面进行了全面的技术经济分析。提出了一种考虑实际场景和精确模型的并网式电解槽- ess系统性能分析框架。该系统组件包括一个500kw碱性电解槽模块，集成了一个中压电网和三种不同的商用ess，分别基于锂离子电池、锂离子电容器和超级电容器技术。针对三种LVRT配置文件广泛研究了这些ess的性能，主要关注即将发布的丹麦网格代码。为了进行仿真研究，系统在MATLAB®/Simulink®-PLECS®平台上实现。结果表明，这三种储能技术都能够在配电网低压异常时支持电解槽系统。研究还表明，从技术经济角度来看，基于超级电容器的技术似乎更适合于故障穿越(FRT)合规性。

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

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