Abstract
The design of the flow field is highly responsible for the performance of the Proton Exchange Membrane Fuel Cell (PEMFC). In this study, pin type flow channel is numerically analyzed by arranging carbon made porous material in uniform and zigzag manner on the rib surface of the flow field. The study focuses on enhancing the performance of PEMFC by reducing liquid flooding in the interface between the rib and Gas Diffusion Layer (GDL). A single PEMFC having an active area of 25 cm2, with three flow channel designs (conventional serpentine, pin type flow channel with 2 mm cubical porous inserts in zigzag and uniform pattern) are modeled for the numerical analysis. The effect of porosity of the carbon inserts on the cell performance is studied by varying its value from 0.6 to 0.9. The results show that the performance of the flow channel with zigzag and uniformly positioned porous inserts is more than the conventional serpentine flow channel by 20.36% and 16.87% respectively. The reason for this increase is the removal of the accumulated water from the rib surface due to the capillary action of the porous carbon inserts. This helps in eliminating the stagnant water regions under the rib and thereby helps in reducing liquid flooding.
Highlights
IntroductionHow to cite this paper: Pal, V., Karthikeyan, P. and Anand, R. (2015) Performance Enhancement of the Proton Exchange Membrane Fuel Cell Using Pin Type Flow Channel with Porous Inserts
With the increasing problem of environmental degradation due to the harmful emissions from the existing fuelsHow to cite this paper: Pal, V., Karthikeyan, P. and Anand, R. (2015) Performance Enhancement of the Proton Exchange Membrane Fuel Cell Using Pin Type Flow Channel with Porous Inserts
The performance of the uniform and zigzag pattern with porous carbon inserts is analyzed by varying the porosity from 0.6 to 0.9
Summary
How to cite this paper: Pal, V., Karthikeyan, P. and Anand, R. (2015) Performance Enhancement of the Proton Exchange Membrane Fuel Cell Using Pin Type Flow Channel with Porous Inserts. The higher pressure fall in these two patterns promote the under rib convection which helps in the removal of water and increases the efficiency of the PEMFC [15] [16] For solving this problem of cathode flooding, different researchers have suggested different techniques. Nguyen [17] initially studied the interdigitated flow field pattern and found that the dead end profile of the flow channel forced the gases to go through the GDL and gas pushed out the water droplets entrapped in the layers of electrode This increased the amount of reactants reaching the catalyst layer from the channels leading to increase in performance and the problem of flooding was reduced. The porosity of carbon inserts have been varied and its influence on the PEMFC’s performance has been analysed
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