A Study on Optimization Design of Hydrogen Supply Integrated
Subsystem for Multi-Stack Fuel Cells 2022-01-7039
The hydrogen supply integrated subsystem is an important part of the proton
exchange membrane fuel cell system. In the multi-stack fuel cell system, the
optimal design and integration of the hydrogen supply subsystem have great
influence on the whole system structure. In this paper, a fuel cell hydrogen
integration subsystem with two hydrogen cycle structures is established based on
an optimized split-stack approach. Firstly, the matching of hydrogen subsystem
is carried out on the basis of multi-stack fuel cell optimization. Then, the
structure of the gas buffering and distribution device and the gas circulation
device is optimized considering the gas circulation and the diversity of the
equipment, and two solutions are proposed: the separate circulation structure
(Structure I) and the common circulation structure (Structure II). Finally, the
multi-stack fuel cell system is built by MATLAB/Simulink software and simulated
under the condition of step and C-WTVC. The hydrogen consumption and parasitic
power consumption of the optimized design of the hydrogen supply subsystem are
compared and analyzed. The results show that the anode inlet pressure
fluctuation in Structure II is smaller than that in Structure I, but the inlet
common rail pipe is needed more to buffer and stabilize the pressure; nitrogen
contaminates the whole anode channel space in Structure II, but its effect is
negligible; and the power consumption of hydrogen circulation pump is 15.5% less
than that in Structure I under C-WTVC conditions. The method of structure
optimization presented in this paper can provide design guidance for high power
multi-stack fuel cell system.
Citation: Zhou, S., Gao, J., Fan, L., Zhang, G. et al., "A Study on Optimization Design of Hydrogen Supply Integrated Subsystem for Multi-Stack Fuel Cells," SAE Technical Paper 2022-01-7039, 2022, https://doi.org/10.4271/2022-01-7039. Download Citation
Author(s):
Su Zhou, Jianhua Gao, Lei Fan, Gang Zhang, Yanda Lu, Jiang Li
Affiliated:
Tongji University
Pages: 13
Event:
SAE 2022 Vehicle Electrification and Powertrain Diversification Technology Forum
ISSN:
0148-7191
e-ISSN:
2688-3627
Related Topics:
Fuel cells
Energy consumption
Optimization
SAE MOBILUS
Subscribers can view annotate, and download all of SAE's content.
Learn More »