Probabilistic Optimal Power Flow Calculation of AC/DC Hybrid Distribution Network with Photovoltaic Power and Electric Vehicles

R. Zhong, Yufei Teng, Xiaoru Wang, Yuzhao Zhu, Han Zhang
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引用次数: 3

Abstract

The AC-DC hybrid distribution network provides DC interfaces for electric vehicle charging stations, photovoltaic power stations, battery storage, and reduces redundant power conversion links and energy loss. The incorporating of the active DC distribution network into AC grid has added complexity into the optimal power flow problem, yet the intermittence of PV output and the randomness of electric vehicles loads lead to a significant increase in the uncertainty and complexity of AC-DC hybrid power system. At present, the study of optimal power flow (OPF) for AC/DC systems containing DC distribution network is still in its infancy and none of them have taken the uncertainties of PV power generation and EV loads into account. This paper firstly establishes the DC grid connected power function for photovoltaic power and electric vehicles by Monte Carlo simulation; secondly the power functions are used to build a probabilistic optimal power flow (POPF) model for an AC/DC hybrid distribution network case consisting of voltage source converters (VSC), DC distribution network and traditional AC network. At last the three-point estimation method (3PEM) using the center distance information of random variables is applied based on existing deterministic optimal power flow algorithm in order to realize the POPF calculation. The results show that the mathematical model and 3PEM used in this paper can take the uncertainties of photovoltaic power generation and electric vehicle load into consideration effectively on the basis of traditional static power flow optimization and the results obtained are of high accuracy and low computational burden. The obtained POPF results reflect more actual operation status of the power grid than static optimal power flow results so it could be used as the planning and operation theoretical basis of AC/DC hybrid distribution network and it could be a useful reference for the further development of electric vehicles.
光伏+电动汽车交直流混合配电网的概率最优潮流计算
交直流混合配电网为电动汽车充电站、光伏电站、蓄电池提供直流接口,减少冗余的电源转换环节和能量损耗。有功直流配电网并入交流电网增加了最优潮流问题的复杂性,而光伏输出的间歇性和电动汽车负荷的随机性使得交直流混合电力系统的不确定性和复杂性显著增加。目前,包含直流配电网的交直流系统最优潮流(OPF)的研究还处于起步阶段,尚未考虑光伏发电和电动汽车负荷的不确定性。本文首先通过蒙特卡罗仿真建立了光伏电源和电动汽车的直流并网功率函数;其次,利用功率函数建立了由电压源变流器(VSC)、直流配电网和传统交流网络组成的交直流混合配电网的概率最优潮流(POPF)模型;最后,在现有的确定性最优潮流算法的基础上,利用随机变量中心距离信息的三点估计方法(3PEM)实现了POPF的计算。结果表明,本文所采用的数学模型和3PEM在传统静态潮流优化的基础上,有效地考虑了光伏发电和电动汽车负荷的不确定性,所得结果精度高,计算量小。所得POPF结果比静态最优潮流结果更能反映电网的实际运行状况,可作为交直流混合配电网规划和运行的理论依据,并可为电动汽车的进一步发展提供有益的参考。
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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