物理
机械
箔法
流量(数学)
非线性系统
可靠性(半导体)
质子交换膜燃料电池
燃料效率
粘度
功率(物理)
刚度
总压比
热力学
推力比油耗
等熵过程
核工程
气动弹性
可压缩流
数学模型
旋转(数学)
氢
压缩性
发电
氦
优化设计
计算流体力学
控制理论(社会学)
作者
Ting Shi,Jieshuai Sun,Renzheng Wang,Huaiyu Wang,Xueyuan Peng
摘要
A gas foil bearings-rotor system is a performance-critical subsystem in proton exchange membrane fuel cells, while it currently faces reliability challenges, especially in the harsh operating conditions of hydrogen vehicles. Therefore, a mathematical model considering compressible viscous flow in the micro-scale is presented. The quantitative influence of critical factors on the aeroelasticity performance of the system is investigated by the mathematical model. The optimal system with higher capacity, stiffness, and lower power consumption is identified by nonlinear regression analysis and genetic algorithm. The results demonstrate that the load capacity and stiffness of the optimal system are increased by 25.4% and 5.2%, respectively, while the viscous power consumption is reduced by 11.6%. Furthermore, the optimal system is verified by air supply system experiments. The largest values of temperature rise, standard flow rate, and pressure ratio are identified as 176.9 °C, 433.19m3/h, and 3.49 at the rotation speed of 90 000 rpm, respectively, while the maximum isentropic efficiency is obtained as 74.6% at 60 000 rpm. These findings can be utilized to enhance the reliability of fuel cells.
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