A Deep Learning Dependent Controller for Advanced Ultracapacitor SoC Concept to Increase Battery Life Span of Electric Vehicles

Energy Storage Pub Date : 2024-11-05 DOI:10.1002/est2.70072
Vijay Kumar, Vaibhav Jain
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引用次数: 0

Abstract

On a global scale, significant progress is being made in the field of battery technology for Electric Vehicle (EV) applications, driven by the need to combat carbon emissions and mitigate the effects of global warming. Accurately determining critical parameters, making sure battery storage system diagnosis, and functioning are correct are critical to the feasibility of EVs. However, insufficient supervision and safety measures for these storage systems may lead to serious problems like a thermal runaway, overcharging, overheating, cell imbalances, and fire hazards. To tackle these challenges, the presence of an efficient battery management system becomes paramount. By facilitating accurate monitoring, managing heat dissipation, regulating charging-discharging procedures, guaranteeing battery safety, and offering protection measures, this system is essential to maximizing battery performance. The key intention of this innovative approach is to improve the longevity of EV batteries during extended periods of operation. By assessing vehicle velocity, remaining battery energy, and State of Charge (SoC), the proposed method effectively manages SoC in both the battery and ultracapacitor. This control is accomplished through a two-stage convolutional neural network-based system known as the Charge Sustain-CNN Controller and the Charge Deplete-CNN Controller. These controllers are fine-tuned using the Fractional Latrans-Hunt optimization (FLHO) algorithm to optimize the performance. The evaluation criteria encompass the battery and ultracapacitor's energy efficiency, as well as vehicle velocity. This novel approach significantly improves the energy storage system in EVs, leading to enhanced energy efficiency and prolonged battery life. Ultimately, experimental results validate the practicality and effectiveness of this developed method. Specifically, the proposed approach attained the Battery's SoC of 72.47%, 91.99%, and 82.88% for the different drive cycles including the FTP75, J1015, and UDDS, respectively.

用于先进超级电容器 SoC 概念的深度学习相关控制器,可提高电动汽车的电池寿命
在全球范围内,电动汽车(EV)应用的电池技术领域正在取得重大进展,其驱动力是应对碳排放和减轻全球变暖的影响。准确确定关键参数,确保电池存储系统的诊断和功能正确,对于电动汽车的可行性至关重要。然而,如果对这些存储系统的监控和安全措施不足,可能会导致热失控、过充电、过热、电池失衡和火灾等严重问题。为了应对这些挑战,高效的电池管理系统变得至关重要。通过促进精确监控、管理散热、调节充放电程序、保证电池安全并提供保护措施,该系统对于最大限度地提高电池性能至关重要。这种创新方法的主要目的是延长电动汽车电池的使用寿命。通过评估车辆速度、电池剩余能量和充电状态(SoC),所提出的方法可有效管理电池和超级电容器中的 SoC。这种控制是通过一个基于卷积神经网络的两级系统来实现的,该系统被称为 "充电持续-CNN 控制器 "和 "充电耗尽-CNN 控制器"。这些控制器采用分数拉特兰-亨特优化(FLHO)算法进行微调,以优化性能。评估标准包括电池和超级电容器的能效以及车辆速度。这种新方法大大改善了电动汽车的储能系统,提高了能源效率,延长了电池寿命。实验结果最终验证了这一方法的实用性和有效性。具体而言,在不同的驱动循环(包括 FTP75、J1015 和 UDDS)中,所提出的方法分别实现了 72.47%、91.99% 和 82.88% 的电池 SoC。
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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