Optimization of Energy Saving and Fuel-Cell Durability for Range-Extended Electric Vehicle

Journal of Energy Engineering-asce Pub Date : 2023-02-01 DOI:10.1061/jleed9.eyeng-4559

Yan Sun, Changgao Xia, Jiangyi Han

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Abstract

For a fuel cell range-extended electric vehicle (FC-REEV), the fuel cell system can work at a fixed output power point, and it has high durability. However, the differences in output power and start–stop threshold can lead to a significant difference in energy loss and degradation of power sources. Based on the thermostat control strategy (TCS), the state of charge (SOC) of the battery is stabilized within a reasonable range. To obtain the lowest hydrogen consumption rate, the vehicle’s fuel economy is considered in the evaluation function. The artificial bee colony (ABC) optimization algorithm is then used to increase the driving range, and the conventional ABC-TCS (CABC-TCS) is proposed. However, the CABC-TCS leads to many start–stop times for fuel cells. To enhance the durability of the fuel cells, a penalty factor was added to the evaluation function, and a novel optimized ABC-TCS (OABC-TCS) is proposed. Different strategies were tested under federal test procedure (FTP)-72 and worldwide light-duty test procedure (WLTC) driving cycles. The results show that, compared with TCS, the optimized driving range of OABC-TCS in FTP-72 and WLTC conditions increased almost 10.59% and 10.3%. Compared with CABC-TCS, the start–stop times of OABC-TCS in FTP-72 and WLTC conditions decreased by 27.55 and 46.47 times/h, respectively.

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增程电动汽车节能与燃料电池耐久性优化

对于燃料电池增程电动汽车(FC-REEV)来说，燃料电池系统可以在固定的输出功率点下工作，并且具有很高的耐久性。然而，输出功率和启停阈值的差异会导致能量损失和电源退化的显著差异。基于温控器控制策略(TCS)，将电池的荷电状态(SOC)稳定在合理范围内。为了获得最低的氢消耗率，在评价函数中考虑了车辆的燃油经济性。然后采用人工蜂群(ABC)优化算法增加行驶里程，并提出了传统的ABC- tcs (CABC-TCS)算法。然而，CABC-TCS导致燃料电池的许多启停时间。为了提高燃料电池的耐久性，在评价函数中加入惩罚因子，提出了一种新的优化ABC-TCS (OABC-TCS)。在联邦测试程序(FTP)-72和世界轻型测试程序(WLTC)驾驶循环下测试了不同的策略。结果表明，与TCS相比，优化后的OABC-TCS在FTP-72和WLTC条件下的行驶里程分别提高了10.59%和10.3%。与CABC-TCS相比，FTP-72和WLTC条件下OABC-TCS启停次数分别减少27.55次/h和46.47次/h。

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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Journal of Energy Engineering-asce

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