Optimal Sizing of Electric Vehicle Charging Stations Considering Urban Traffic Flow for Smart Cities

Achieving high penetration of electric vehicles (EVs) is one of the objectives proposed by the scientific community to mitigate the negative environmental impact caused by conventional mobility. The limited autonomy and the excessive time to recharge the battery discourage the final consumer from opting for new environmentally friendly mobility alternatives. Consequently, it is essential to provide the urban road network with charging infrastructure (CI) to ensure that the demand generated by EV users is met. The types of terminals to be considered in charging stations (CS) are fast and ultra-fast. The high energy requirements in these types of terminals could stress the electrical systems, reducing the quality of service. To size and forecast the resources needed in CI, it is of great interest to model and predict the maximum number of EVs, in each hour, that each CS will have to serve according to the geographic area in which they are located. Our proposal is not based on an assumed number of vehicles to be served by each CS, but rather it is based on the analysis of vehicular traffic in geo-referenced areas, so that the load managers can design the topology of the CS. The maximum vehicular concentration is determined by some considerations such as the road system, direction of the route, length of the road segment, the intersections, and the economic zone to which it belongs. The topology of the road map is freely extracted from OpenStreetMap to know the latitude and longitude coordinates. Vehicular traffic will be modeled through the topology obtained from OpenStreetMap and other microscopic variables to understand the traffic engineering constraints. In addition, the Hungarian algorithm is used as a minimum cost decision tool to allocate demand to the CS by observing vehicular traffic as a cost variable. The multi commodity flow problem (MCFP) algorithm aims to make commodities flow through the road network with the minimum cost without exceeding the capacities of the road sections. Therefore, it is proposed to solve the transportation problem by directing the vehicular flow to the CS while minimizing the travel time. This situation will contribute significantly to the design of the topology of each CS, which will be studied in future research.

[1]  Fariborz Jolai,et al.  A multi-commodity network flow model for railway capacity optimization in case of line blockage , 2019, International Journal of Rail Transportation.

[2]  Esteban Inga,et al.  Optimal Placement of Universal Data Aggregation Points for Smart Electric Metering based on Hybrid Wireless , 2017, SSN.

[3]  Prasad K. Yarlagadda,et al.  A multi commodity flow model incorporating flow reduction functions , 2019, Flexible Services and Manufacturing Journal.

[4]  Michela Robba,et al.  An Optimization Model For Electrical Vehicles Routing with time of use energy pricing And partial Recharging , 2018 .

[5]  Mohamed A. Ahmed,et al.  Two-Stage Fuzzy Logic Inference Algorithm for Maximizing the Quality of Performance under the Operational Constraints of Power Grid in Electric Vehicle Parking Lots , 2020 .

[6]  Yang Yue,et al.  Multimodal-Transport Collaborative Evacuation Strategies for Urban Serious Emergency Incidents Based on Multi-Sources Spatiotemporal Data (Short Paper) , 2018, GIScience.

[7]  Esteban Inga,et al.  Optimal Allocation of Public Charging Stations based on Traffic Density in Smart Cities , 2019, 2019 IEEE Colombian Conference on Applications in Computational Intelligence (ColCACI).

[8]  Hong Liu,et al.  Multi-objective planning of charging stations considering vehicle arrival hot map , 2017, 2017 IEEE Conference on Energy Internet and Energy System Integration (EI2).

[9]  Wei Gu,et al.  Coordinated allocation of distributed generation resources and electric vehicle charging stations in distribution systems with vehicle-to-grid interaction , 2020 .

[10]  Ying Zhang,et al.  Integrated Route and Charging Planning for Electric Vehicles Considering Nonlinear Charging Functions , 2018, 2018 IEEE 22nd International Conference on Computer Supported Cooperative Work in Design ((CSCWD)).

[11]  Michela Robba,et al.  An optimization model for electrical vehicles scheduling in a smart grid , 2018 .

[12]  Hussain Shareef,et al.  Analysis of an Optimal Planning Model for Electric Vehicle Fast-Charging Stations in Al Ain City, United Arab Emirates , 2021, IEEE Access.

[13]  Jun Wu,et al.  The output planning model of the electric vehicle charging stations based on game theory , 2016, 2016 IEEE PES Asia-Pacific Power and Energy Engineering Conference (APPEEC).

[14]  Jean-Sébastien Tancrez,et al.  Assessing the environmental benefits of horizontal cooperation using a location-inventory model , 2020, Central Eur. J. Oper. Res..

[15]  Chau Yuen,et al.  Electric Vehicle Charging Station Placement for Urban Public Bus Systems , 2017, IEEE Transactions on Intelligent Transportation Systems.

[16]  Yutong Zhao,et al.  Charging Load Allocation Strategy of EV Charging Station Considering Charging Mode , 2019, World Electric Vehicle Journal.

[17]  Suzhi Bi,et al.  Distributed Routing and Charging Scheduling Optimization for Internet of Electric Vehicles , 2019, IEEE Internet of Things Journal.

[18]  Esteban Inga,et al.  Scalable Route Map for Advanced Metering Infrastructure Based on Optimal Routing of Wireless Heterogeneous Networks , 2017, IEEE Wireless Communications.

[19]  Petros A. Ioannou,et al.  Integrated control of highway traffic flow , 2018 .

[20]  S. Travis Waller,et al.  Range-Constrained Traffic Assignment with Multi-Modal Recharge for Electric Vehicles , 2019, Networks and Spatial Economics.

[21]  Bernard Nacke,et al.  Application of Rechargeable Batteries of Electrical Vehicles as Time Dependent Storage Resource for the Public Electricity Grid , 2018 .

[22]  Giuseppe Musolino,et al.  Sustainable mobility and energy resources: A quantitative assessment of transport services with electrical vehicles , 2019, Renewable and Sustainable Energy Reviews.

[23]  M. Brenna,et al.  Optimal Locating of Electric Vehicle Charging Stations by Application of Genetic Algorithm , 2018 .

[24]  Xin Zhang,et al.  Intelligent Energy Management Algorithms for EV-charging Scheduling with Consideration of Multiple EV Charging Modes , 2019, Energies.

[25]  Lina Kattan,et al.  Variable speed limit: A microscopic analysis in a connected vehicle environment , 2015 .

[26]  Liu Guang,et al.  Location planning of charging station for electric vehicle based on urban traffic flow , 2016, 2016 China International Conference on Electricity Distribution (CICED).

[27]  Ashkan Hafezalkotob,et al.  Uncertain multi-objective multi-commodity multi-period multi-vehicle location-allocation model for earthquake evacuation planning , 2019, Appl. Math. Comput..

[28]  Esteban Inga,et al.  Capacitated Multicommodity Flow Problem for Heterogeneous Smart Electricity Metering Communications Using Column Generation , 2019, Energies.

[29]  Jing Qiu,et al.  Charging Station and Power Network Planning for Integrated Electric Vehicles (EVs) , 2019, Energies.

[30]  Mohamed A. Ahmed,et al.  Fuzzy Logic Weight Based Charging Scheme for Optimal Distribution of Charging Power among Electric Vehicles in a Parking Lot , 2020, Energies.

[31]  Xiangyang Zhao,et al.  Planning of Electric Vehicle Charging Station Based on Real Time Traffic Flow , 2016, 2016 IEEE Vehicle Power and Propulsion Conference (VPPC).

[32]  Xiaoying Gan,et al.  Fast-Charging Station Deployment Considering Elastic Demand , 2020, IEEE Transactions on Transportation Electrification.

[33]  Yih-Fang Huang,et al.  Stochastic Dynamic Pricing for EV Charging Stations With Renewable Integration and Energy Storage , 2018, IEEE Transactions on Smart Grid.

[34]  Yan Wang,et al.  Performance Status Evaluation of an Electric Vehicle Charging Infrastructure Based on the Fuzzy Comprehensive Evaluation Method , 2019, World Electric Vehicle Journal.

[35]  Aris A. Syntetos,et al.  Vehicle Routing Problem: Past and Future , 2019, Contemporary Operations and Logistics.

[36]  Nikolaos Efthymiopoulos,et al.  Sizing of electric vehicle charging stations with smart charging capabilities and quality of service requirements , 2021, Sustainable Cities and Society.

[37]  Krzysztof Malecki,et al.  Applying Multi-Criteria Analysis of Electrically Powered Vehicles Implementation in Urban Freight Transport , 2019, KES.

[38]  Mehdi Bagheri,et al.  An Improved Multicriteria Optimization Method for Solving the Electric Vehicles Planning Issue in Smart Grids via Green Energy Sources , 2020, IEEE Access.

[39]  Behnam Vahdani,et al.  Development and optimization of a horizontal carrier collaboration vehicle routing model with multi-commodity request allocation , 2019, Journal of Cleaner Production.

[40]  Peng Wang,et al.  Nodal Impact Assessment and Alleviation of Moving Electric Vehicle Loads: From Traffic Flow to Power Flow , 2016, IEEE Transactions on Power Systems.