配电网中电动汽车自主需求侧管理

M. Ireshika, M. Preißinger, P. Kepplinger
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引用次数: 9

摘要

随着电动汽车数量的增加,电力需求的增加对电网特别是配电网的运行提出了新的挑战。现有的电网基础设施可能不足以满足电动汽车一体化带来的新需求。因此,电动汽车充电可能会导致可靠性和稳定性问题,特别是在需求高峰时期。需求侧管理(DSM)是减轻由此产生的影响的一种潜在和有希望的方法。在这项工作中,我们开发了一种自主的DSM策略来优化电动汽车的充电,以最大限度地降低充电成本,并进行了模拟研究来评估对电网运行的影响。所提议的方法只需要一种单向的沟通激励。来自奥地利移动行为研究的真实概况用于模拟电动汽车的使用。此外,采用真实的智能电表数据来模拟家庭基本负荷分布,并在负荷流模拟中考虑了真实的低压电网拓扑。利用日前电力股票市场价格作为激励来驱动优化。确定了最优充电策略的结果,并与不受控制的电动汽车充电进行了比较。结果表明,与不受控制的电动汽车充电相比,最优充电策略的潜在成本节约约30.8%。尽管电动汽车自主需求侧管理实现了负荷的转移,但配电网的运行可能会受到很大的影响。我们表明,在实时价格驱动运行的情况下,电压下降和峰值至平均功率的升高是由于车辆在有利的时间段同时充电。
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Autonomous Demand Side Management of Electric Vehicles in a Distribution Grid
The electricity demand due to the increasing number of EVs presents new challenges for the operation of the electricity network, especially for the distribution grids. The existing grid infrastructure may not be sufficient to meet the new demands imposed by the integration of EVs. Thus, EV charging may possibly lead to reliability and stability issues, especially during the peak demand periods. Demand side management (DSM) is a potential and promising approach for mitigation of the resulting impacts. In this work, we developed an autonomous DSM strategy for optimal charging of EVs to minimize the charging cost and we conducted a simulation study to evaluate the impacts to the grid operation. The proposed approach only requires a one way communicated incentive. Real profiles from an Austrian study on mobility behavior are used to simulate the usage of the EVs. Furthermore, real smart meter data are used to simulate the household base load profiles and a real low voltage grid topology is considered in the load flow simulation. Day-ahead electricity stock market prices are used as the incentive to drive the optimization. The results for the optimum charging strategy is determined and compared to uncontrolled EV charging. The results for the optimum charging strategy show a potential cost saving of about 30.8% compared to uncontrolled EV charging. Although autonomous DSM of EVs achieves a shift of load as pursued, distribution grid operation may be substantially affected by it. We show that in the case of real time price driven operation, voltage drops and elevated peak to average powers result from the coincident charging of vehicles during favourable time slots.
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