Operational Optimisation of Grid-Connected Microgrids Incorporating Hybrid Energy Storage and Demand Response

IF 1.9 4区工程技术 Q4 ENERGY & FUELS

Energy Exploration & Exploitation Pub Date : 2023-09-26 DOI:10.1177/01445987231174907

Azizat O Gbadegesin, Yanxia Sun, Nnamdi I Nwulu

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Abstract

Storage systems are needed to boost the reliability of intermittent solar and wind resources in power networks. Rather than focus on one storage system or one hybrid energy storage system (HESS), this work models the operation of six HESS configurations in a Renewable Energy (RE) based grid-tied network. The objective is to minimise the daily operational costs of the microgrid while prolonging the storage lifetime by considering storage degradation costs. The influence of fixed tariffs and time-of-use (TOU) tariffs on the optimal operational of the HESS configurations have also been investigated; as well as deferrable demand satisfaction, charge-discharge pattern of different HESS and availability of the power-dense storage system within the microgrid. Results show that the lead-acid battery and hydrogen fuel cell (HFC) HESS incurs the highest operational costs, while the supercapacitor-lead-acid battery HESS incurs the lowest operational costs. The supercapacitor-lead acid battery and the supercapacitor-HFC HESS incur the highest annual storage degradation costs. The grid expenses were seen to be the same for all HESS under each tariff scheme. Lastly, decreasing the minimum storage level further by 10% from the 30% in the base case, led to an increase in the number of hours of availability of the power-dense storage system of five of the six HESS. These results have given a deeper understanding to the operation of HESS systems and can inform better decision making of the suitable HESS to be deployed in different operating scenarios.

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结合混合储能和需求响应的并网微电网运行优化

需要存储系统来提高电网中间歇性太阳能和风能资源的可靠性。这项工作不是关注一个存储系统或一个混合能源存储系统(HESS)，而是在基于可再生能源(RE)的并网网络中模拟六种HESS配置的运行。目标是最小化微电网的日常运营成本，同时通过考虑存储退化成本来延长存储寿命。研究了固定电价和分时电价对HESS优化运行的影响;以及微电网内不同HESS的可延需求满足度、充放电模式和功率密集储能系统的可用性。结果表明，铅酸电池和氢燃料电池(HFC) HESS的运行成本最高，而超级电容器-铅酸电池HESS的运行成本最低。超级电容器-铅酸电池和超级电容器- hfc HESS的年存储退化成本最高。在每个电价方案下，所有HESS的电网费用都是相同的。最后，将最低存储水平从基准情况的30%进一步降低10%，导致6个HESS中5个功率密集存储系统的可用小时数增加。这些结果使人们对HESS系统的运行有了更深入的了解，并可以为在不同的操作场景中部署合适的HESS提供更好的决策。

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

Energy Exploration & Exploitation 工程技术-能源与燃料

CiteScore

5.40

自引率

3.70%

发文量

审稿时长

3.9 months

期刊介绍： Energy Exploration & Exploitation is a peer-reviewed, open access journal that provides up-to-date, informative reviews and original articles on important issues in the exploration, exploitation, use and economics of the world’s energy resources.