The Cruising Range Analysis of Heavy-duty Fuel Cell Vehicles with Liquid Hydrogen Storage and Supply Systems Based on Dynamic Programming

2021 IEEE 4th International Electrical and Energy Conference (CIEEC) Pub Date : 2021-05-28 DOI:10.1109/CIEEC50170.2021.9510507

Jiayi Hu, Jianqiu Li, Zunyan Hu, Liangfei Xu, M. Ouyang, Zhidong Qin

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Abstract

Liquid hydrogen provides a prospective solution for the on-board hydrogen storage and supply system of heavy-duty fuel cell vehicles to carry more hydrogen in a smaller volume. The research group develops 32-ton and 49-ton heavy-duty vehicles equipped with fuel cell systems, batteries, liquid hydrogen storage and supply systems, and independent-drive electric wheels. In this study, the two heavy-duty vehicles’ powertrain dynamic model based on experimental data is established. The maximum cruising ranges of two vehicles under constant-speed conditions and China-worldwide transient vehicle cycles (C-WTVCs) are then analyzed, respectively. The dynamic programming algorithm is adopted to find the optimal power distribution between the fuel cell system and the battery. Simulation results show that the 40-km/h cruising range of the 32-ton and 49-ton vehicles can be up to 1283 km and 1717 km with 62.0 kg and 112.2 kg hydrogen depleted completely and battery state of charge sustained. Dynamic programming results show that two vehicles’ cruising range can be 615.3 km and 768.7 km under consecutive C-WTVCs.

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基于动态规划的液氢储供重型燃料电池汽车续航里程分析

液态氢为重型燃料电池汽车的车载储氢和供氢系统提供了一个有前景的解决方案，以更小的体积携带更多的氢。该研究组开发了配备燃料电池系统、电池、液氢储存和供应系统、独立驱动电动车轮的32吨和49吨重型汽车。本文基于实验数据，建立了两种重型汽车的动力总成动力学模型。然后分别分析了两种车辆在等速工况和中国-世界瞬态车辆循环(c - wtvc)下的最大续航里程。采用动态规划算法求解燃料电池系统与蓄电池之间的最优功率分配。仿真结果表明，在62.0 kg和112.2 kg氢气完全耗尽和电池持续充电的情况下，32吨级和49吨级车辆的40公里/小时续航里程可达1283公里和1717公里。动态规划结果表明，在连续c - wtvc工况下，两辆车的续航里程分别为615.3 km和768.7 km。

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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2021 IEEE 4th International Electrical and Energy Conference (CIEEC)

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