直接从直流地铁接触网充电的机会，没有存储

Q3 Engineering

AUS Pub Date : 2023-03-29 DOI:10.1109/ESARS-ITEC57127.2023.10114818

I. Diab, G. C. Mouli, P. Bauer

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引用次数: 0

摘要

收集铁路车辆多余制动能量的典型方法是使用存储系统。然而，将电动汽车充电器等智能负载集成到牵引网络的研究势头正在增长，这可以为收集制动能量提供更高效、更经济的解决方案。本文研究了阿姆斯特丹地铁电网的一个部分，其中两个350kW集成直流机会充电器用于从牵引电网为电动公交车充电。在被调查的充电事件中，没有一次打破了电网的最低线路电压要求。根据充电持续时间的不同，他们成功地抵消了每天高达1212千瓦时的成功回收所造成的任何额外线路损失。在这四项计划中，每天约有22.8%的公交车充电能量来自收集地铁制动能量，否则会被浪费掉。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Opportunity Charging of Electric Buses Directly from a DC Metro Catenary and Without Storage

A typical approach to harvesting the excess braking energy of a railway car has been to use a storage system. However, research momentum has been growing in the direction of integrating smart loads like EV chargers into traction networks, and this can offer a more efficient and economical solution to the harvesting of braking energy. This paper examines the case study of a segment of the Amsterdam metro grid with two 350kW integrated DC opportunity chargers for charging electric buses from the traction grid. Of the charging episodes investigated, none of them broke the minimum line voltage requirements of the grid. They managed to greatly offset any additional line losses that they had caused by a successful recuperation of up to 1212kWh per day, depending on the charging duration. In all four schemes, about 22.8% of the picked-up charging energy of the buses per day came from harvesting otherwise-wasted metro braking energy.

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来源期刊

AUS Engineering-Architecture

CiteScore

0.40

自引率

0.00%

发文量

期刊介绍： Revista AUS es una publicación académica de corriente principal perteneciente a la comunidad de investigadores de la arquitectura y el urbanismo sostenibles, en el ámbito de las culturas locales y globales. La revista es semestral, cuenta con comité editorial y sus artículos son revisados por pares en el sistema de doble ciego. Periodicidad semestral.