Experimental study on rapid cold start-up performance of PEMFC system

The cold start-up of a proton exchange membrane fuel cell is considered one of the main factors affecting the commercialization of fuel cell vehicles. In this study, an automotive fuel cell system was designed and tested for cold start-up at low temperatures. In the absence of PTC (Positive Temperature Coefficient) heating device, the stack was directly loaded to generate heat, which provided the cold start-up characteristics of system at low temperatures. Cold start-up process and purging control strategies were analyzed at-20 & DEG;C and-30 & DEG;C. It was found that the fuel cell system could produce 50% power in 25 s at-20 & DEG;C, the coolant temperature's heating rate was 0.78 & DEG;C/s, the coolant outlet temperature could reach 20 & DEG;C within 40 s and no apparent low voltage of single cell occurred. While, the cell close to the end plate had low cell voltage and reverse polar phenomena throughout the-30 & DEG;C cold start-up process. The heating rate of the coolant temperature was 0.44 & DEG;C/s, and the temperature of coolant outlet reached 20 & DEG;C within 90 s. The purging time ranged from 180 to 260 s according to the voltage drop value of stack and the ohmic resistance of stack was 360-470 mU after the high-volume air purging at different tests. After 30 cold start-up tests, the rated point performance of the stack declined by about 1%, and the consistency of cell voltages did not change significantly. Future work will focus on optimizing cold start-up strategy and speeding up purging time to minimize the performance impact of the cold start-up.& COPY; 2023 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

In this study, a automotive fuel cell system was designed and tested for cold start-up at low temperatures. The system showed good cold start-up characteristics, providing 50% power in 25 seconds at -20°C and reaching a coolant outlet temperature of 20°C within 40 seconds. However, issues such as low cell voltage and reverse polar phenomena were observed during the -30°C cold start-up process. Future work will focus on optimizing cold start-up strategy and purging time to minimize performance impact.