Flow Control of Air Compressor in Fuel Cell System Based on Adaptive Look-Up Table Algorithm

2010 ◽  
Author(s):  
Zhou Su ◽  
Shen Xiao-yan ◽  
Chen Feng-xiang
Keyword(s):  
Fuel Cell ◽  
Flow Control ◽  
Cell System ◽  
Fuel Cell System ◽  
Air Compressor ◽  
Look Up Table

Proton Exchange Membrane (PEM) Fuel Cell System Model for Automotive Vehicle Simulation and Control

2001 ◽  
Author(s):  
Daisie D. Boettner ◽  
Gino Paganelli ◽  
Yann G. Guezennec ◽  
Giorgio Rizzoni ◽  
Michael J. Moran
Keyword(s):  
Fuel Cell ◽  
Proton Exchange Membrane ◽  
Pem Fuel Cell ◽  
Cell System ◽  
Proton Exchange ◽  
System Model ◽  
System Efficiency ◽  
Fuel Cell System ◽  
Air Compressor ◽  
Exchange Membrane

Abstract This paper describes a Proton Exchange Membrane (PEM) fuel cell system model for automotive applications that includes an air compressor, cooling system, and other auxiliaries. The fuel cell system model has been integrated into a vehicle performance simulator that determines fuel economy and allows consideration of control strategies. Significant fuel cell system efficiency improvements may be possible through control of the air compressor and other auxiliaries. Fuel cell system efficiency results are presented for two limiting air compressor cases: ideal control and no control. Extension of the present analysis to hybrid configurations consisting of a fuel cell system and battery is currently under study.

Robust Control of Hydrogen Flow for an Automotive Fuel Cell System via Model Reference Adaptive Control

2019 ◽  
Author(s):  
Janghwan Hwang ◽  
Sangseok Yu
Keyword(s):  
Adaptive Control ◽  
Fuel Cell ◽  
Flow Control ◽  
Control Algorithm ◽  
Cell System ◽  
Pi Control ◽  
Pwm Control ◽  
Fuel Cell System ◽  
Hydrogen Flow ◽  
Automotive Fuel

Abstract Efficient hydrogen flow control is of great importance to ensure the reliable operation of an automotive fuel cell system because it is closely associated with the safety and the economic efficiency. In this study, an effective hydrogen flow control algorithm for hydrogen excess ratio control is addressed by pointing out the recovery speed and overshoot response. Unlike previous studies on the hydrogen management systems of an automotive fuel cell, this study presents an analytic hydrogen tank model which can present the characteristics of the discharge and charge of hydrogen from a type 4 hydrogen tank. To this end, a mode reference adaptive control (MRAC) based on proportional-integral (PI) control is introduced, to ensure robust hydrogen flow during the dynamic operation of fuel cell system. The MRAC was compared with the nominal PI control and PWM control in the hydrogen management system of an automotive fuel cell operating within normal conditions, under steady-state responses and transient. Based on these result, it can further demonstrate that the MRAC algorithm shows better recovery speed and tracking performance than the nominal PI, and PWM control algorithm with respect to the transient behaviors.

Analysis and development of a roots-type air compressor with fixed internal compression for fuel cell system

2021 ◽  
pp. 095765092110300
Author(s):  
Linfen Xing ◽  
Jianmei Feng ◽  
Zhilong He ◽  
Xueyuan Peng
Keyword(s):  
Fuel Cell ◽  
Electric Vehicles ◽  
Polymer Electrolyte Membrane ◽  
Volume Ratio ◽  
Cell System ◽  
Fuel Cell System ◽  
Air Compressor ◽  
Electrolyte Membrane ◽  
Wrap Angle ◽  
Isentropic Efficiency

The air compressor is a key component in the polymer electrolyte membrane (PEM) fuel cell system and its performance has great impact on the electric power output from the system. Here, analysis was conducted firstly on the Roots-type compressor with fixed internal compression based on the volume reduction created by helical rotors. The built-in volume ratio variations with the wrap angle and the lobe numbers were calculated and discussed. Then a prototype of the Roots-type air compressor with 6 lobes was developed according to the outcomes of the research. The volumetric and isentropic efficiency of the prototype were measured under the discharge pressures from 0.11 MPa to 0.25 MPa while the rotation speeds from 10000 to 14000 rpm. Under the design conditions, the volumetric efficiency and isentropic efficiency of the Roots-type air compressor were 75.8% and 53.9% respectively. It was concluded that this kind of Roots-type air compressor is especially suitable for the fuel cell systems applied in the range extended electric vehicles.

Proton Exchange Membrane Fuel Cell System Model for Automotive Vehicle Simulation and Control

2002 ◽  
Vol 124 (1) ◽  
pp. 20-27 ◽  
Author(s):  
Daisie D. Boettner ◽  
Gino Paganelli ◽  
Yann G. Guezennec ◽  
Giorgio Rizzoni ◽  
Michael J. Moran
Keyword(s):  
Fuel Cell ◽  
Proton Exchange Membrane ◽  
Cell System ◽  
Proton Exchange ◽  
System Model ◽  
System Efficiency ◽  
Fuel Cell System ◽  
Air Compressor ◽  
Vehicle Simulation ◽  
Exchange Membrane

This paper describes a proton exchange membrane (PEM) fuel cell system model for automotive applications that includes an air compressor, cooling system, and other auxiliaries. The fuel cell system model has been integrated into a vehicle performance simulator that determines fuel economy and allows consideration of control strategies. Significant fuel cell system efficiency improvements may be possible through control of the air compressor and other auxiliaries. Fuel cell system efficiency results are presented for two limiting air compressor cases: ideal control and no control. Extension of the present analysis to hybrid configurations consisting of a fuel cell system and battery is currently under study.

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