基于水利和能源中心多重合作的微电网抵御自然灾害的能力增强

IF 7 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Sattar Shojaeiyan, M. Dehghani, P. Siano
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引用次数: 0

摘要

随着飓风、洪水、地震等自然灾害的发生频率越来越高,弹性微电网(MGs)的想法比以前更受关注。在自然灾害后提供多载波能源供应的机会可以减少电力损失并提高电力弹性和可靠性。通过考虑能源枢纽(EH)系统以及这些多载波系统的优化设计和分配,MG内的关键负载可以根据损坏发生后的网络状况在尽可能短的时间内进行优先排序和恢复。为此,本文旨在解决MGs中的弹性框架,考虑由CHP(热电联产)、锅炉、储能器和海水淡化装置组成的水和EHs(WEH)。本研究的重点是考虑一种有效的弹性方案,在MG发生不可预测事件时,在自然灾害后的短时间内恢复关键负荷。通过应用WEH的思想,将有机会通过在适当的孤岛点使用两组WEH系统来恢复系统,以恢复系统和电力、热力和水的关键负荷。为此,考虑了不同的场景,通过分析未供电(ENS)因素来评估系统对对对网络造成严重破坏的自然灾难性事件的恢复能力。此外,分配的WEH可以在自然灾害发生后的一整天内充分供应电力、水和热需求负荷。为了缓解可再生能源中不可预见的变化,在WEH中设置了一个电池,可以有效地进行最优调度。还引入了一种基于场景的方法来提高MGs在不确定环境(如电力、热力和水的随机需求)中的弹性。在改进的IEEE测试系统上考虑了所提供模型的适当效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microgrids Resiliency Enhancement against Natural Catastrophes Based Multiple Cooperation of Water and Energy Hubs
With the ever-growing frequency of natural catastrophe occurrences such as hurricanes, floods, earthquakes, etc., the idea of resilient microgrids (MGs) has attracted more attention than before. Providing the opportunity for a multi-carrier energy supply after a natural catastrophe can lessen power losses and improve power resiliency and reliability. Critical loads within the MG can be prioritized and restored in the shortest possible time based on the condition of the network after the damaging occurrence by considering the energy hub (EH) systems and the optimum design and allocation of these multi-carrier systems. To this end, this paper aims to address the resilience framework in MGs considering sets of water and EHs (WEHs) consisting of CHP (combined heat and power), a boiler, energy storage, and a desalination unit. This study focused on considering an effective resilient scheme to restore critical loads in a short period after a natural catastrophe when the MG experiences an unpredictable event. By applying the idea of WEHs, there would be a chance of restoring the system by using two sets of WEH systems in the appropriate islanded points to restore the system and critical loads of electricity, heat, and water. For this purpose, different scenarios were considered for assessing the resiliency of the system against a natural catastrophic event that causes serious damage to the network by analyzing the energy-not-supplied (ENS) factor. Moreover, the allocated WEHs can adequately supply the electrical, water, and thermal demand loads throughout the day after the natural catastrophe. To mitigate the unforeseen variations in the renewable sources, a battery is located in the WEH, which can attend to the optimal scheduling effectively. A scenario-based method is also introduced to improve the resiliency of MGs in an uncertain environment such as electrical, heat, and water stochastic demands. The appropriate efficiency of the offered model was considered on a modified IEEE test system.
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来源期刊
Smart Cities
Smart Cities Multiple-
CiteScore
11.20
自引率
6.20%
发文量
0
审稿时长
11 weeks
期刊介绍: Smart Cities (ISSN 2624-6511) provides an advanced forum for the dissemination of information on the science and technology of smart cities, publishing reviews, regular research papers (articles) and communications in all areas of research concerning smart cities. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible, with no restriction on the maximum length of the papers published so that all experimental results can be reproduced.
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