Modeling, Simulation and Control Strategy Optimization of Fuel Cell Hybrid Electric Vehicle

IEEE Intelligent Vehicles Symposium. IEEE Intelligent Vehicles Symposium Pub Date : 2023-04-20 DOI:10.3390/vehicles5020026

Umidjon Usmanov, S. Ruzimov, A. Tonoli, A. Mukhitdinov

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引用次数: 1

Abstract

This work represents the development of a Fuel Cell Hybrid Electric Vehicle (FCHEV) model, its validation, and the comparison of different control strategies based on the Toyota Mirai (1st generation) vehicle and its subsystems. The main investigated parameters are hydrogen consumption, and the variation of the state of charge, current, and voltage of the battery. The FCHEV model, which is made up of multiple subsystems, is developed and simulated in MATLAB® Simulink environment using a rule-based control strategy derived from the real system. The results of the model were validated using the experimental data obtained from the open-source Argonne National Laboratory (ANL) database. In the second part, the equivalent consumption minimization strategy is implemented into the controller logic to optimize the existing control strategy and investigate the difference in hydrogen consumption. It was found that the ECMS control strategy outperforms the rule-based one in all drive cycles by 0.4–15.6%. On the other hand, when compared to the real controller, ECMS performs worse for certain considered driving cycles and outperforms others.

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燃料电池混合动力汽车建模、仿真及控制策略优化

这项工作代表了基于丰田Mirai(第一代)汽车及其子系统的燃料电池混合动力汽车(FCHEV)模型的开发、验证以及不同控制策略的比较。研究的主要参数是氢气消耗量、电池的充电状态、电流和电压的变化。该模型由多个子系统组成，采用基于规则的控制策略，在MATLAB®Simulink环境中进行仿真。该模型的结果使用从开源的阿贡国家实验室(ANL)数据库中获得的实验数据进行了验证。第二部分在控制器逻辑中引入等效消耗最小化策略，对现有控制策略进行优化，研究氢消耗差异。结果表明，ECMS控制策略在各工况下均优于基于规则的控制策略0.4 ~ 15.6%。另一方面，与实际控制器相比，ECMS在某些考虑的驾驶周期中表现较差，但优于其他控制器。

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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IEEE Intelligent Vehicles Symposium. IEEE Intelligent Vehicles Symposium

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