Abstract

Ultra-fast charging infrastructures are gaining increasing interest thanks to their ability to reduce the charging-time of plug-in electric vehicles to values comparable to those of the refueling of traditional vehicles in gas stations. This is a consequence of the increasing rated power of both on-board batteries and charging equipment. On the other hand, the increased values of charging power have led to an increased impact on the power distribution networks, particularly in terms of line currents and bus voltages. In presence of large penetration of ultra-fast charging devices, in fact, both currents and voltages are affected by larger variations whose values can exceed the admissible limits imposed by the technical constraints and by the levels of quality of service. In order to reduce the impact of this typology of vehicles’ charging on the electrical infrastructure, in this paper a methodology is presented which allows managing a microgrid in presence of ultra-fast charging stations by satisfying the constraints of the grid, while preserving the expected short charging-time for electric vehicles. To this end, a proper optimal strategy is proposed which coordinates the demands of electric vehicles and of the other loads of the microgrid with the power provided by the renewable energy generation resources. The proposed approach aims to optimally control the active and reactive power of charging stations and renewable generation units and to minimize the charging time of a fleet of plug-in electric vehicles while satisfying the constraints on the technical aspects and on the quality of service. The proposed approach has been tested on a test system and the results, proposed in the last part of the paper, demonstrate the feasibility of the proposed approach.

Highlights

  • The aim of this paper is to propose a real-time scheduling of microgrids including ultra-fast charging (UFC) stations and renewable-based distributed generation (DG) units

  • J =1 i =1 where ncs is the number of the UFC stations connected to the microgrid, n pev,j,k is the number of plug-in electric vehicles (PEVs) connected at the jth charger at the time interval k, and Ppev,i,j,k is the charging power of the ith PEV connected to the jth UFC station at the kth time interval

  • In this paper a methodology is discussed which allows managing the ultra-fast charge of fleets of plug-in electric vehicles in microgrids

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Summary

Introduction

Thanks to their ability to provide a refueling capability similar to that of traditional combustion engine vehicles, ultra-fast charging (UFC) infrastructures for plug-in electric vehicles (PEVs) are gaining particular interest from researchers. The aim of this paper is to propose a real-time scheduling of microgrids including UFC stations and renewable-based distributed generation (DG) units. The proposed management approach is aimed at minimizing the charging time of the vehicles, avoiding curtailment of the power available to the charging stations, and preserving power quality and secure operation of the network; the real-time procedure allows repeated updating of the schedule of active and reactive power of different resources based on the current conditions. To the best of the authors’ knowledge, none of the papers proposed in the current technical literature has treated the problem of UFC stations in such a comprehensive way considering the network requirements in terms of power quality issues, the vehicles’ requirement in terms of charging speed, and the changing conditions of renewable generation availability and load request.

The Proposed Real-Time Scheduling Strategy
Objective Function
Constraints on the Plug-In Vehicles’ Fleets
Constraints on the Microgrid Buses
Numerical Simulations
Daily profile
Profile ofofthe ofthe thecharging charging power related to the
Profile of the theperiod charging power related to the simulation lasting
11. SoC of the PEVs plugged-in stationatatbus bus in three the three ca
For comparative purposes
Findings
Conclusions

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