Abstract

This research aims to improve the operational efficiency and security of electric power systems at high renewable penetration by exploiting the envisioned controllability or flexibility of electric vehicles (EVs); EVs interact with the grid through grid-to-vehicle (G2V) and vehicle-to-grid (V2G) services to ensure reliable and cost-effective grid operation. This research provides a computational framework for this decision-making process. Charging and discharging strategies of EV aggregators are incorporated into a security-constrained optimal power flow (SCOPF) problem such that overall energy cost is minimized and operation within acceptable reliability criteria is ensured. Particularly, this SCOPF problem has been formulated for Jeju Island in South Korea, in order to lower carbon emissions toward a zero-carbon island by, for example, integrating large-scale renewable energy and EVs. On top of conventional constraints on the generators and line flows, a unique constraint on the system inertia constant, interpreted as the minimum synchronous generation, is considered to ensure grid security at high renewable penetration. The available energy constraint of the participating EV associated with the state-of-charge (SOC) of the battery and market price-responsive behavior of the EV aggregators are also explored. Case studies for the Jeju electric power system in 2030 under various operational scenarios demonstrate the effectiveness of the proposed method and improved operational flexibility via controllable EVs.

Highlights

  • Many efforts to lower carbon emissions and respond to climate change have been conducted by the electricity and transportation sectors

  • This paper focuses on the charging/discharging strategy of Electric vehicles (EVs) aggregators while considering stored energy in EV batteries in order to support the high penetration of Renewable energy sources (RES) and enhance the operational flexibility of electric power system

  • In w/o Control, all EV batteries are charged without any control, while the EVs in Group 2 are controlled by EV aggregators in Controls 2 to 4

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Summary

Introduction

Many efforts to lower carbon emissions and respond to climate change have been conducted by the electricity and transportation sectors. Renewable energy sources (RES) such as wind power and solar power have been developed to replace fossil-fuel-combustion electricity-generating units. Electric vehicles (EVs), which are powered by electricity from charged batteries, are referred to as an alternative to traditional petroleum fuel vehicles [1,2,3]. The controllability of EVs (i.e., battery energy in EVs) could help balance intermittent RES and facilitate the integration of RES into a power system [4,5,6]. The EV aggregator plays an important role in the integration of the EV fleet into the power system by managing the charging of batteries and participating in the electricity market [9,10,11,12]. EV batteries can have three modes according to system price: waiting mode, charging

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