Capacity Optimization Configuration of Electric Vehicle Swapping-Storage Integrated Station Considering Support Ability to Grid
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摘要:
电动汽车换电站同时作为储能电站,既可实现经济获利,又兼顾电网支撑,但目前缺乏这种储换一体站的容量配置研究. 为此,本文首先分析储换一体站工作模式及电价时段,构建一体站的运行模型;然后,基于用户出行模拟,建立电动汽车换电需求预测模型;接着,建立考虑全寿命周期收益和电网支撑能力的储换一体站容量双层规划模型,外层规划以全寿命周期总收益为目标,实现储换一体站的容量规划,内层规划以对电网支撑能力为目标,实现电池组充放电行为优化,内层获得最优充放电功率并返回外层,实现储换一体站容量最优配置;最后,在 IEEE33 节点系统上验证规划模型的有效性,为储换一体站建设提供理论支撑. 研究结果表明:与其他储换一体站模式相比,储换一体站投资收益率提高 1.51%~2.26%;基于双层规划的容量优化配置方法,在保证一体站经济性的同时,能够对支撑电网电压,使电压日方差降低 20%;随着参与换电的电动汽车数量增加,一体站的经济性进一步提高.
Abstract:Electric vehicle (EV) swapping stations can achieve economic benefits while also supporting the power grid by serving as energy storage stations. However, there is currently a lack of research on the capacity configuration of such EV storage and swapping integrated stations (EVSS-IS). To this end, the working mode and tariff period of EVSS-IS were firstly analyzed to build an operational model. Then, a predictive model for EV swapping demand was developed based on user travel simulations. Next, a bi-level capacity programming model of the EVSS-IS was established, which considered life cycle benefits and grid support capacity. Specifically, the outer planning aimed at the total revenue during the whole life cycle to optimize the capacity of the EVSS-IS; the inner planning aimed at supporting the power grid and optimizing the charging and discharging behaviors; the optimal charging and discharging power from the inner layer was returned to the outer layer to realize the optimal capacity programming of the EVSS-IS. Finally, the effectiveness of the planning model was verified on the IEEE33 node system, which provided theoretical support for the construction of the EVSS-IS. The results show that the return on investment of the EVSS-IS is 1.51%–2.26% higher compared with other models; the capacity optimization allocation method based on bi-level planning can support the grid voltage while ensuring the economy of the station, resulting in a 20% reduction in the daily variance of the voltage; as the number of EVs swapping batteries increases, the economics of the EVSS-IS is further improved.
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图 5 某地10 kV系统典型日负荷曲线及分时电价
Figure 5. Typical daily load curve of a 10 kV system and a time-of-use tariff
图 10 不同换电场景下规划结果
Figure 10. Optimization results under different demand scenarios for battery swapping
表 1 储换一体站参数表
Table 1. Parameters of EVSS-IS
参数 数值 参数 数值 Ebat/(kW·h) 100 CES,E/(元·(kW·h)−1) 1800 CEV,E/(元·(kW·h)−1) 1280 CP/(元·kW−1) 2400 COM/(元·(kW·年)−1) 155 DEV/(元·(kW·h)−1) 1.47 DES,b/(元·(kW·h)−1) 0.15 DEV,b/(元·(kW·h)−1) 0.1 Drt/(元·年−1) 10800 $ {\eta _{\text{c}}}{\text{, }}{\eta _{\text{d}}} $ 0.9 r/% 5 N/a 15 
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表 2 换电需求典型聚类场景统计结果
Table 2. Statistical results of demands for battery swapping on typical clustering scenarios
场景编号 总需求/次 概率 1 20 0.0785 2 25 0.4189 3 30 0.3265 4 35 0.1397 5 40 0.0364
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表 3 接入节点为11、18时不同情景下的规划结果
Table 3. Optimization results for different scenarios with the accessing 11th, 18th nodes
接入
节点方案
编号储能容
量/(MW·h)储能功
率/MW换电容
量/(MW·h)换电功
率/MW年均净
利润/万元电压日
方差年均成
本/万元11 1 10 2.00 3.5 0.60 60.590 6.0303 598.61 2 13.5 2.70 0 0 42.961 5.3699 534.91 3 0 0 3.5 0.61 17.016 5.9595 216.55 4 10.0 2.00 3.5 0.60 53.510 5.6288 621.68 5 7.6981 18 1 2.7 0.54 3.5 0.71 26.159 5.7167 320.57 2 6.2 1.26 0 0 19.885 5.6637 245.51 3 0 0 3.5 0.73 16.318 5.9594 214.94 4 2.7 0.54 3.5 0.71 25.440 5.6904 336.27 5 7.6981
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