Optimal Operation of Energy Hub Systems under Resiliency Response Options

Turkish J. Electr. Eng. Comput. Sci. Pub Date : 2023-01-10 DOI:10.1155/2023/2590362

A. Khodadadi, T. Abedinzadeh, H. Alipour, J. Pouladi

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引用次数: 2

Abstract

The economic and resilient operation of power systems has always been one of the main priorities of energy systems. In spite of improvements in various fields of energy systems, especially power systems, the issue of resilience has become more important. For this purpose, this paper proposes a multiobjective optimization model to improve the economic performance of energy hub systems and improve the resilience of electrical consumers. Also, consumer welfare, which is a function of the energy not supplied index, is maximized over a 24-hour period by considering extreme weather conditions. The ε-constraint method is applied to solve the proposed model by transforming the multiobjective optimization problem into several single-objective optimization problems. The max-min fuzzy method is also used to select the optimal solution among the Pareto solutions. A sample hub system is made up of electrical, thermal, and gas loads, electrical and thermal energy sources, and storage systems employed as a test system. A group of actions is applied to improve the resilience of the system, which may be affected by outages caused by storms under the resilience response program (RRP). The results proved the efficiency of the proposed RRP in improving economics and resilience.

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弹性响应方案下能源枢纽系统的最优运行

电力系统的经济性和弹性运行一直是能源系统的主要优先事项之一。尽管能源系统，特别是电力系统的各个领域都有所改进，但弹性问题变得更加重要。为此，本文提出了一个多目标优化模型，以提高能源枢纽系统的经济绩效，提高电力消费者的弹性。另外，考虑到极端的天气条件，24小时内，以未供给能源指数为函数的消费者福利也会最大化。将多目标优化问题转化为多个单目标优化问题，采用ε约束方法求解该模型。在Pareto解中选择最优解时，采用了最大最小模糊方法。样品轮毂系统由电、热、气负载、电、热能源以及作为测试系统的存储系统组成。在弹性响应计划(RRP)下，应用一组行动来提高系统的弹性，该系统可能受到风暴造成的中断的影响。结果证明了RRP在提高经济效益和弹性方面的有效性。

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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Turkish J. Electr. Eng. Comput. Sci.

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