Abstract
Electric vehicles (EV) are becoming increasingly popular due to their efficiency and potentials to reduce greenhouse gas emission. However, penetration of a very large number of EVs can have negative impacts on power systems. This study proposes optimal vehicle-to-grid (V2G) models to incorporate the EV penetration by minimizing multiple objectives including the peak demand, the variance of load profile, the battery degradation cost and the EV charging/discharging cost based on real-time pricing (RTP). The proposed models incorporate EV driving patterns including driving distance, driving periods, and charging/discharging levels and locations. A nonlinear battery degradation cost function is linearized and incorporated into the optimal models. In addition, a distributed control algorithm is developed to implement the optimal models. One-day simulation results show that the proposed approach can reduce the peak demand and the variance of the load profile by 7.8% and 81.9%, which can significantly improve power system stability and energy efficiency. In addition, the sum of EV charging/discharging cost and battery degradation cost is decreased from $251 to -$153. In fact, 100 EVs earn $153 in the day from the V2G program. The approaches can be used by a load aggregator or a utility to effectively incorporate EV penetration to power systems to unlock V2G opportunities and mitigate negative impacts.
Highlights
V2G features with bi-directional power flow and two-way communication, which allows Electric vehicles (EV) act as both controllable loads under demand response (DR) and distributed energy resources [1], [2]
Multiple objectives were proposed to minimize the peak demand, the variance of load profile, the battery degradation cost and the EV charging/ discharging cost based on real-time pricing (RTP)
Two optimal V2G approaches are developed to minimize multiple objectives including the peak demand, the variance of load profile, the battery degradation cost and the charging/discharging cost based on RTP. 2
Summary
V2G features with bi-directional power flow and two-way communication, which allows EVs act as both controllable loads under demand response (DR) and distributed energy resources [1], [2]. Proposed to minimize the peak demand, the variance of load profile, the battery degradation cost and the EV charging/ discharging cost based on RTP. 1. Two optimal V2G approaches are developed to minimize multiple objectives including the peak demand, the variance of load profile, the battery degradation cost and the charging/discharging cost based on RTP. The second term in the objective function represents the battery degradation cost from EV charging/discharging. Model 2 minimizes the variance of the load profile, the battery degradation cost and the charging/discharging cost based on RTP. Var(·) represents the variance of the load profile, and the second term is the battery degradation cost. The average degradation cost was $0.2395, the minimum was $0.1384, the maximum was $0.9804, and the variance was $0.0175
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