Creation of a computational framework for the European transmission grid with Power-to-Gas

A. Mazza, A. Rogin, Shaghayegh Zalzar, A. Estebsari, E. Bompard
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引用次数: 3

Abstract

The presence of high penetration of Variable Renewable Energy Sources (VRES) is one of the key aspects of the modern electricity system. The new challenges to be faced require novel technologies which enhance the flexibility of the transmission system. In this paper, the exploitation of the power-to-gas technology (PtG) is considered as a solution for the flexibility challenges, allowing to absorb the excess of electricity produced by VRES and at the same time, producing synthetic natural gas (SNG). This work presents a computational framework based on DC Optimal Power Flow capable to simulate the day-ahead market and the following intra-day market, applied to a simplified European transmission network, by considering different scenarios for both load and generation. PtG plants model are modelled based on the real measurements of a 2-MW Alkaline (AEC) electrolyser. The results of a given PtG placement configuration, applied to a current scenario (2017) and two future scenarios (2030&2040) show that the fast response of PtG units improves the system performance and reduces the VRESs’ imbalance up to ~90% in terms of imbalance time duration and ~40% in terms of peak imbalance power. These results lead to further investigations, about the optimal PtG units’ placement and sizing, as well as their economic and technical consequences on the transmission network operation.
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为欧洲输电网建立电转气计算框架
可变可再生能源(VRES)的高渗透率是现代电力系统的关键方面之一。面对新的挑战,需要新的技术来提高输电系统的灵活性。在本文中,开发电制气技术(PtG)被认为是解决灵活性挑战的一种解决方案,可以吸收VRES产生的多余电力,同时生产合成天然气(SNG)。这项工作提出了一个基于直流最优潮流的计算框架,能够模拟前一天市场和随后的日内市场,应用于简化的欧洲输电网络,考虑负载和发电的不同情况。PtG装置模型是基于一个2mw碱性(AEC)电解槽的实际测量建立的。将给定的PtG放置配置应用于当前场景(2017年)和两个未来场景(2030年和2040年)的结果表明,PtG单元的快速响应提高了系统性能,并将VRESs的不平衡减少了90%(不平衡持续时间)和40%(峰值不平衡功率)。这些结果导致了进一步的研究,关于最佳的PtG单元的放置和尺寸,以及它们对输电网运行的经济和技术影响。
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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