Stochastic energy management of a multi-microgrid system with battery/ supercapacitor energy storages considering demand response and transactive energy

IF 4.2 Q2 ENERGY & FUELS

Renewable Energy Focus Pub Date : 2023-12-20 DOI:10.1016/j.ref.2023.100531

S.R. Seyednouri , A. Safari , A. Quteishat , M.A. Younis , J. Salehi , S. Najafi , N. Taghizadegan

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引用次数: 0

Abstract

This paper proposes stochastic energy management for an electrical system consisting of a multi-microgrid and a distribution company (DISCO). The objective function aims at finding an optimal day-ahead energy schedule of dispatchable resources, energy storages, and demand response in the presence of intermittent renewable energy sources. Two different energy storage devices, i.e., battery and supercapacitor (SC), are modeled in the system to provide both high power and energy density. Wind speed, solar irradiation, and electrical demand uncertainties have been modeled using probability density functions of uncertain parameters, and the number of scenarios has been decreased using mixed-integer linear programming (MILP) based scenario reduction with a novel characteristic. In the proposed model, the DISCO, as a leader, attempts to maximize its profit while the microgrids (MGs), as followers, tend to minimize their operational costs. Karush-Kuhn-Tucker, strong duality, and Fortuny-Amat transformation are used to convert the non-linear bi-level problem into a linear single-level problem. The proposed model was tested on a hypothetical distribution system and the results showed the efficiency of the model in reducing operational costs of MGs by 7.5%, increasing the DISCO profit by 6.9%, and improving the reliability of the system by reducing the energy not supplied.

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带电池/超级电容器储能器的多微网系统的随机能源管理（考虑需求响应和交互式能源

本文针对由多微网和配电公司（DISCO）组成的电力系统提出了随机能源管理方案。目标函数的目的是在存在间歇性可再生能源的情况下，找到可调度资源、储能设备和需求响应的最优日前能源计划。系统中模拟了两种不同的储能设备，即电池和超级电容器（SC），以提供高功率和高能量密度。利用不确定参数的概率密度函数对风速、太阳辐照度和电力需求的不确定性进行建模，并利用基于混合整数线性规划（MILP）的场景缩减功能减少场景数量。在所提出的模型中，作为领导者的电力公司试图实现利润最大化，而作为追随者的微电网（MGs）则倾向于使其运营成本最小化。卡鲁什-库恩-塔克（Karush-Kuhn-Tucker）、强对偶性和福图尼-阿马特（Fortuny-Amat）转换被用来将非线性双级问题转换为线性单级问题。在一个假定的配电系统上对所提出的模型进行了测试，结果表明该模型能有效降低制动单元的运营成本 7.5%，增加电力公司利润 6.9%，并通过减少未供应的能源来提高系统的可靠性。

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来源期刊

Renewable Energy Focus Renewable Energy, Sustainability and the Environment

CiteScore

7.10

自引率

8.30%

发文量

审稿时长

48 days