Optimal Siting and Sizing of Electric Vehicle Energy Supplement Infrastructure in Highway Networks

IF 2.1 Q2 ENGINEERING, MULTIDISCIPLINARY

Inventions Pub Date : 2023-09-15 DOI:10.3390/inventions8050117

Ding Jin, Huayu Zhang, Bing Han, Gang Liu, Fei Xue, Shaofeng Lu

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Abstract

The electric vehicle (EV) market is expanding rapidly to achieve the future goal of eco-friendly transportation. The scientific planning of energy supplement infrastructures (ESIs), with appropriate locations and capacity, is imperative to develop the EV industry. In this research, a mixed integer linear programming (MILP) model is proposed to optimize the location and capacity of ESIs, including vehicle charging stations (VCSs), battery swapping stations (BSSs), and battery charging stations (BCSs), in highway networks. The objective of this model is to minimize the total cost with the average waiting time for EVs being constrained. In this model, battery swapping and transportation behaviors are optimized such that the EV average waiting time can be reduced, and the average queue and service process waiting time is estimated by the M/M/1 model. Real-world data, i.e., from the London M25 highway network system, are used as a case study to test the effectiveness of the proposed method. The results show that considering battery transportation behaviors is more cost efficient, and the results are sensitive to the EV average waiting time tolerance, battery cost, and charging demand.

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公路网电动汽车能源补充基础设施的最优选址与规模

电动汽车(EV)市场正在迅速扩大，以实现环保交通的未来目标。科学规划合适的位置和容量的能源补充基础设施是发展电动汽车产业的必要条件。本文提出了一种混合整数线性规划(MILP)模型，用于优化公路网络中车辆充电站(VCSs)、电池交换站(bss)和电池充电站(BCSs)的位置和容量。该模型的目标是在限制电动汽车平均等待时间的情况下使总成本最小化。在该模型中，对换电池行为和运输行为进行优化，使电动汽车平均等待时间减少，并通过M/M/1模型估计平均排队和服务过程等待时间。真实世界的数据，即来自伦敦M25高速公路网系统，被用作一个案例研究，以测试所提出的方法的有效性。结果表明，考虑电池运输行为更具成本效益，且结果对电动汽车平均等待时间容限、电池成本和充电需求较为敏感。

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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