Ageing Estimation of Lithium-Ion Batteries Applied to a Three-Wheel PHEV Roadster

2013 IEEE Vehicle Power and Propulsion Conference (VPPC) Pub Date : 2013-11-21 DOI:10.1109/VPPC.2013.6671663

J. Nadeau, M. Dubois, A. Desrochers, N. Denis

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引用次数: 9

Abstract

Predicting the ageing behaviour of a lithium-ion battery is a challenging difficulty in plug-in hybrid electric vehicles applications. Invoking the expensive price of the energy density linked with considerable performances degradation over cycling, it is worth considering a battery lifetime optimization in the design process. The degradation will materialize by a capacity loss and an increase of the internal resistance. Capacity loss will affect the autonomy of the vehicle while an increase of the internal resistance will lead to an increase of the battery power losses and overheating. In the paper, the lifetime of a PHEV roadster battery pack is estimated by applying a real-life current discharge pattern, instead of the common ageing experiments based on constant current discharge patterns. A current cycle corresponding to a roadster power load has been used as input. This work involves an accelerated ageing experiment of individual LiFePO4 battery cells through cycling. The cycle applied is derived from a speed cycle comprised of three parts: urban roads, rural roads and highways. For more than 1400 cycles, the capacity, internal resistance, voltage, current and temperature have been monitored.

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应用于三轮PHEV跑车的锂离子电池的老化估计

在插电式混合动力汽车应用中，预测锂离子电池的老化行为是一个具有挑战性的难题。由于能量密度的昂贵代价与循环过程中相当大的性能下降有关，因此在设计过程中考虑电池寿命优化是值得的。这种退化将通过容量损失和内阻的增加来实现。容量损失将影响车辆的自主性，而内阻的增加将导致电池功率损失的增加和过热。本文采用实际的电流放电模式对插电式混合动力跑车电池组的寿命进行了估算，而不是采用基于恒流放电模式的常规老化实验。一个电流周期对应于一个跑车功率负载已被用作输入。这项工作包括通过循环对单个磷酸铁锂电池进行加速老化实验。所采用的循环源于由三部分组成的速度循环:城市道路，农村道路和高速公路。在1400多个循环中，对容量、内阻、电压、电流和温度进行了监测。

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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2013 IEEE Vehicle Power and Propulsion Conference (VPPC)

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