Cost Minimization of Charging Stations with Photovoltaics: An Approach with EV Classification (1507.07994v1)

Abstract: This paper proposes a novel electric vehicle (EV) classification scheme for a photovoltaic (PV) powered EV charging station (CS) that reduces the effect of intermittency of electricity supply as well as reducing the cost of energy trading of the CS. Since not all EV drivers would like to be environmentally friendly, all vehicles in the CS are divided into three categories: 1) premium, 2) conservative, and 3) green, according to their charging behavior. Premium and conservative EVs are considered to be interested only in charging their batteries, with noticeably higher rate of charging for premium EVs. Green vehicles are more environmentally friendly, and thus assist the CS to reduce its cost of energy trading by allowing the CS to use their batteries as distributed storage. A different charging scheme is proposed for each type of EV, which is adopted by the CS to encourage more EVs to be green. A basic mixed integer programming (MIP) technique is used to facilitate the proposed classification scheme. It is shown that the uncertainty in PV generation can be effectively compensated, along with minimization of total cost of energy trading to the CS, by consolidating more green EVs. Real solar and pricing data are used for performance analysis of the system. It is demonstrated that the total cost to the CS reduces considerably as the percentage of green vehicles increases, and also that the contributions of green EVs in winter are greater than those in summer.

• The paper minimizes EV charging station costs with photovoltaics using a mixed integer programming method and a novel EV classification based on user behavior.
• Increasing 'green' EVs significantly reduces energy trading costs, with benefits more notable in winter due to less solar generation.
• This research suggests significant cost reduction is possible by incentivizing green EV behavior and provides a sustainable method to integrate PV with EV charging.

Cost Minimization of Charging Stations with Photovoltaics: An Approach with EV Classification

This paper explores the optimization of electric vehicle (EV) charging stations powered by photovoltaics (PV) and aims to minimize the operational costs associated with energy trading. The paper introduces a novel EV classification based on the users' behavior towards environmental consideration, wherein vehicles are categorized into three types: premium, conservative, and green. This classification is fundamental to addressing the intermittency inherent in PV energy generation and aligning charging behaviors with cost reduction strategies.

Key Elements of the Study

1. EV Classification Scheme:
   • Premium EVs: These vehicles charge at the maximum rate permitted by the battery, paying a premium price for rapid charging.
   • Conservative EVs: These vehicles opt for a moderate charging rate aligned with their departure schedules, receiving potentially lower rates based on the average charging rate scheduled.
   • Green EVs: This classification encourages the use of EV batteries as distributed storage, offering economic incentives for charging flexibility and discharge capabilities.
2. Optimization Methodology:
   • A mixed integer programming (MIP) approach is adopted to facilitate decision-making within the proposed EV classification framework. This ensures that the uncertainty in PV generation can be compensated by strategic energy storage and trading.

The paper provides compelling insights into how varying the composition of EV types in the CS can lead to substantial cost reductions. By incorporating real solar radiation data, the paper demonstrates that as the proportion of green EVs increases, the overall costs associated with energy trading decrease. Notably, the efficacy of the model appears more pronounced during winter due to lesser solar generation.

Implications and Future Directions

The implications of this research span practical and theoretical domains. Practically, the findings suggest significant potential for cost reduction when the charging station's user base can be incentivized to engage in energy-trading behaviors classified as 'green.' Additionally, the utilization of PVs paired with flexible EV charging presents a sustainable approach towards achieving lower emissions from both automotive and energy sectors.

Theoretically, the model bridges an important gap in integrating renewable resources with EV grids, providing a basis for future advancements in smart grid technologies. Future work in this domain might involve more robust real-time algorithms that adapt to changing conditions, ensuring that solutions are feasible and optimal amidst uncertainty. Advanced data-driven models could further improve the predictive accuracy for PV generation and EV arrival/departure patterns, enhancing the adaptability of the CS.

Conclusions

This paper provides a structured approach to EV charging station cost minimization through a contextual EV classification and optimization technique. The paper’s methodology and conclusions present an advantageous pathway towards economically viable and environmentally sustainable EV charging infrastructure. The demonstrated numerical simulations indicate considerable cost advantages with higher penetration of green EVs in the network. Such strategies can lead to more resilient and efficient energy systems in the evolving landscape of smart grids and renewable energy technology.