汽车燃料电池空气管理系统的多变量滑模预测控制方法

Duo Yang, Hanwen Fu, Junjun Li, Siyu Wang
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摘要

质子交换膜燃料电池气体控制一直是燃料电池管理系统中的一个关键环节。空气管理系统的复杂性和耦合性使其难以实现精确的进气调节。本文提出了一种精确的空气流量和压力调节联合控制方法。建立了描述空气管理系统输出特性和状态变化的非线性数学模型。在此基础上,提出了反馈线性化方法,以获得控制变量与被控变量之间的直接对应关系。此外,为了解决控制变量不能直接测量的问题,采用扩展状态观测器对堆阴极压力进行估计。提出了滑模预测控制方法,同时控制氧过剩比和阴极压力。利用系统的相对阶数设计了滑模曲面,并建立了相应的预测模型。仿真实验结果表明,通过解耦,压力和质量流量之间的相互影响很小。通过对比实验验证了该算法精度高、响应速度快、鲁棒性好。
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A multivariable sliding mode predictive control method for the air management system of automotive fuel cells
The proton exchange membrane fuel cell gas control has been one key point in fuel cell management systems. The complexity and coupling of the air management system make it difficult to achieve precise air intake adjustment. In this paper, an accurate joint control method for the air flow and pressure regulation is proposed. The nonlinear mathematical model of the air management system is developed to describe the output characteristic and state change. Based on this, the feedback linearization method is proposed to obtain the direct correspondence between control variables and controlled variables. In addition, to solve the problem that the controlled variables cannot be measured directly, an extended state observer is applied to estimate the stack cathode pressure. The sliding mode predictive control method is proposed to control the oxygen excess ratio and cathode pressure simultaneously. The relative order of the system is used to design the sliding mode surface, and the corresponding predictive model is proposed. The results obtained by simulation experiments show that pressure and mass flow have little effect on each other through decoupling. The proposed algorithm has been verified to have high precision, fast response, and robustness through comparative experiments.
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