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关于电动汽车充电技术、类型及充电站模式的全面综述。

A comprehensive review on charger technologies, types, and charging stations models for electric vehicles.

作者信息

Saraswathi V N, Ramachandran Vijaya Priya

机构信息

School of Electrical Engineering, Vellore Institute of Technology, Vellore, 632014, India.

出版信息

Heliyon. 2024 Oct 9;10(20):e38945. doi: 10.1016/j.heliyon.2024.e38945. eCollection 2024 Oct 30.

DOI:10.1016/j.heliyon.2024.e38945
PMID:39640677
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11620053/
Abstract

Electric vehicles (EVs) are popular now due to zero carbon emissions. Hence, with the advancement of EVs, charging station (CS) design also plays a vital role. CS is generally called a charge or power supply point and delivers power to the EVs. Usually, CSs are either of the direct current (DC) type, as the EVs need a DC supply or in some cases of the alternating current (AC) type, as the traditional power grid delivers AC power. Usually, on-board chargers (on-BCs) and off-board chargers (off-BCs) are used to charge the EV batteries. Due to heavy loads, size, and budget constraints, many on-BC facilities have power limits, which can be overcome by designing the on-BC with an electrical motor. In different types of off- and on-BCs, the power flow can be in one or two directions. Uni-directional power flow reduces hardware needs and makes connecting problems easier, whereas bi-directional power flow allows battery energy to be injected back into the grid. The primary issue with EVs is the charging time as well as the need for charging infrastructure. The infrastructure for fast charging makes on-board energy storage less expensive and more essential. This paper details various charging technologies, including wired and wireless methods. Also, numerous on-board and off-board charging topologies are summarized in the literature. Different EV battery charging standards and levels are also discussed. The paper also delineates several alternative CS topologies based on architecture, energy storage, and renewable energy sources. Considering the present scenario, having a sophisticated quick EV charging network is crucial to ensure maximum EV charging with renewable power and reduce grid strain.

摘要

电动汽车(EVs)因其零碳排放而广受欢迎。因此,随着电动汽车的发展,充电站(CS)设计也起着至关重要的作用。充电站通常被称为充电或供电点,为电动汽车供电。通常,充电站要么是直流(DC)类型,因为电动汽车需要直流电源,要么在某些情况下是交流(AC)类型,因为传统电网输送交流电。通常,车载充电器(on-BCs)和非车载充电器(off-BCs)用于为电动汽车电池充电。由于负载重、尺寸大以及预算限制,许多车载充电器设施存在功率限制,这可以通过设计带有电动机的车载充电器来克服。在不同类型的非车载和车载充电器中,功率流可以是单向或双向的。单向功率流减少了硬件需求,使连接问题更容易解决,而双向功率流允许电池能量回馈到电网中。电动汽车的主要问题是充电时间以及对充电基础设施的需求。快速充电基础设施使车载储能成本降低且更为必要。本文详细介绍了各种充电技术,包括有线和无线方式。此外,文献中还总结了众多车载和非车载充电拓扑结构。还讨论了不同的电动汽车电池充电标准和级别。本文还基于架构、储能和可再生能源描述了几种替代的充电站拓扑结构。考虑到当前的情况,拥有一个复杂的快速电动汽车充电网络对于确保使用可再生能源实现最大程度的电动汽车充电并减轻电网压力至关重要。

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本文引用的文献

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An enhanced proportional resonance controller design for the PMSM based electric vehicle drive system.一种用于基于永磁同步电机(PMSM)的电动汽车驱动系统的增强型比例谐振控制器设计。
Heliyon. 2024 Jul 27;10(15):e35244. doi: 10.1016/j.heliyon.2024.e35244. eCollection 2024 Aug 15.