使用超级电容器和直流电机的能量再生制动模型研究

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Alistair Teasdale, Lucky A. Ishaku, C. Amaechi, Ibitoye Adelusi, Abdelrahman Abdelazim
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引用次数: 0

摘要

本研究介绍了能量再生模型和构建再生制动系统所需的一些理论。由于二氧化碳(CO2)排放的影响,全球对电动汽车(EV)、电动自行车、电动自行车、电动公交车和电动飞机的使用越来越感兴趣。为了推广使用电动交通系统,有必要强调净零排放的影响。电动汽车的发展需要再生制动系统。本研究介绍了再生制动的优势。该系统在全球范围内的应用包括电动汽车、有轨电车和火车。本研究将概述设计规范、设计方法、测试配置、Simulink 模型和建议。这项工作的一个独特之处是,在无负载的情况下使用 1.5 安培,在有负载的情况下使用 2.15 安培进行了实际实验。放电电压纯粹来自于连接到电容器组的 22 W 灯泡负载,因为我们的研究仅限于使用 1.5 安培,一个完整的放电周期需要 15 分钟,之后电容器组中就没有电荷了。结果表明,再生制动系统的放电率和充电率是有效的,但还可以改进。本文旨在研究在再生制动应用中,超级电容器如何与电池一起工作。这项研究表明,所使用的超导体可以在需要时提供最大功率。此外,超级电容器还能承受充电或放电电流峰值的升高。将电池与超级电容器结合使用,可将电池上的突发性负载转移到电容器上,从而减少电池上的突发性负载。当这两种组合同时使用时,电池组的耐用性和寿命都会得到提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Study on an Energy-Regenerative Braking Model Using Supercapacitors and DC Motors
This study presents an energy regeneration model and some theory required to construct a regeneration braking system. Due to the effects of carbon dioxide (CO2) emissions, there is increasing interest in the use of electric vehicles (EVs), electric bikes, electric bicycles, electric buses and electric aircraft globally. In order to promote the use of electric transportation systems, there is a need to underscore the impact of net zero emissions. The development of EVs requires regenerating braking system. This study presents the advantages of regenerative braking. This system is globally seen in applications such as electric cars, trams, and trains. In this study, the design specification, design methodology, testing configurations, Simulink model, and recommendations will be outlined. A unique element of this work is the practical experiment that was carried out using 1.5 Amps with no load and 2.15 Amps with a load. The discharge voltage was purely from the 22 W bulb load connected to the capacitor bank as we limited this study to the use of 1.5 Amps and it took 15 min for a full discharge cycle, after which no charge was left in the capacitor bank. The results showed that the discharge rate and charging rate for the regenerative braking system were effective but could be improved. The objective of this paper is to investigate how a supercapacitor works alongside a battery in regenerative braking applications. This study demonstrates that the superconductor used can deliver maximum power when required. Also, it can also withstand elevated peaks in charging or discharging current via the supercapacitor. Combining a battery with a supercapacitor reduces the abrupt load on the battery by shifting it to the capacitor. When these two combinations are used in tandem, the battery pack’s endurance and lifespan are both boosted.
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来源期刊
World Electric Vehicle Journal
World Electric Vehicle Journal Engineering-Automotive Engineering
CiteScore
4.50
自引率
8.70%
发文量
196
审稿时长
8 weeks
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