A robust load shedding strategy for microgrid islanding transition

Guodong Liu, B. Xiao, M. Starke, O. Ceylan, K. Tomsovic
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引用次数: 13

Abstract

A microgrid is a group of interconnected loads and distributed energy resources. It can operate in either gridconnected mode to exchange energy with the main grid or run autonomously as an island in emergency mode. However, the transition of microgrid from grid-connected mode to islanded mode is usually associated with excessive load (or generation), which should be shed (or spilled). Under this condition, this paper proposes an robust load shedding strategy for microgrid islanding transition, which takes into account the uncertainties of renewable generation in the microgrid and guarantees the balance between load and generation after islanding. A robust optimization model is formulated to minimize the total operation cost, including fuel cost and penalty for load shedding. The proposed robust load shedding strategy works as a backup plan and updates at a prescribed interval. It assures a feasible operating point after islanding given the uncertainty of renewable generation. The proposed algorithm is demonstrated on a simulated microgrid consisting of a wind turbine, a PV panel, a battery, two distributed generators (DGs), a critical load and a interruptible load. Numerical simulation results validate the proposed algorithm.
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微电网孤岛化转型的鲁棒减载策略
微电网是一组相互连接的负荷和分布式能源。它既可以在并网模式下与主电网交换能量,也可以在应急模式下作为孤岛自主运行。然而,微电网从并网模式向孤岛模式的过渡,往往伴随着负荷过大(或发电量过大),需要进行分流(或溢出)。在此情况下,本文提出了一种考虑微网可再生能源发电不确定性,保证孤岛后负荷与发电量平衡的微网孤岛转型鲁棒减载策略。建立了一个鲁棒优化模型,使总运行成本最小,包括燃料成本和减载惩罚。提出的鲁棒减载策略作为备份计划,并按规定的时间间隔更新。考虑可再生能源发电的不确定性,保证了孤岛后的可行工作点。该算法在一个由风力涡轮机、光伏板、电池、两台分布式发电机(dg)、临界负载和可中断负载组成的模拟微电网上进行了验证。数值仿真结果验证了该算法的有效性。
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