A Cooling design for an end cell in fuel-cell stack using forced air flow in metal foam: Modelling and Experiment

Air-breathing fuel cells have a great potential as power sources for various electronic devices. They differ from conventional fuel cells in which the cells take up oxygen from ambient air by active or passive methods. The air flow occurs through the channels due to concentration and temperature gradient between the cell and the ambient conditions. However developing a stack is very difficult as the individual cell performance may not be uniform. In order to make such a system more realistic, an open-cathode forced air-breathing stacks were developed by making appropriate channel dimensions for the air flow for uniform performance in a stack. At CFCT-ARCI (Centre for Fuel Cell Technology-ARC International) we have developed forced air-breathing fuel cell stacks with varying capacity ranging from 50 watts to 1500 watts. The performance of the stack was analysed based on the air flow, humidity, stability, and so forth, The major advantage of the system is the reduced number of bipolar plates and thereby reduction in volume and weight. However, the thermal management is a challenge due to the non-availability of sufficient air flow to remove the heat from the system during continuous operation. These results will be discussed in this paper.

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Application of Metal Foam as a Flow Field for PEM Fuel Cell Stack

Fuel Cells ◽

10.1002/fuce.201700180 ◽

2018 ◽

Vol 18 (2) ◽

pp. 123-128 ◽

Cited By ~ 10

Author(s):

M. Kim ◽

C. Kim ◽

Y. Sohn

Keyword(s):

Fuel Cell ◽

Flow Field ◽

Metal Foam ◽

Pem Fuel Cell ◽

Fuel Cell Stack

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The Effect of the Geometric Parameters on the Air Flow Distrib ution Uniformity within the Protonic Ceramic Fuel Cell Stack

International Journal of Electrochemical Science ◽

10.20964/2021.10.52 ◽

2021 ◽

pp. ArticleID:211052

Author(s):

J Q. Dai ◽

Keyword(s):

Fuel Cell ◽

Air Flow ◽

Geometric Parameters ◽

Fuel Cell Stack ◽

Ceramic Fuel Cell ◽

Ceramic Fuel

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Cooling Design for PEM Fuel-Cell Stacks Employing Air and Metal Foam: Simulation and Experiment

Energies ◽

10.3390/en14092687 ◽

2021 ◽

Vol 14 (9) ◽

pp. 2687

Author(s):

Ali A. Hmad ◽

Nihad Dukhan

Keyword(s):

Fuel Cells ◽

Fuel Cell ◽

Metal Foam ◽

Air Flow ◽

Pem Fuel Cells ◽

Proton Exchange ◽

Total Output ◽

Pumping Power ◽

Maximum Heat ◽

Simulation And Experiment

A new study investigating the cooling efficacy of air flow inside open-cell metal foam embedded in aluminum models of fuel-cell stacks is described. A model based on a commercial stack was simulated and tested experimentally. This stack has three proton exchange membrane (PEM) fuel cells, each having an active area of 100 cm2, with a total output power of 500 W. The state-of-the-art cooling of this stack employs water in serpentine flow channels. The new design of the current investigation replaces these channels with metal foam and replaces the actual fuel cells with aluminum plates. The constant heat flux on these plates is equivalent to the maximum heat dissipation of the stack. Forced air is employed as the coolant. The aluminum foam used had an open-pore size of 0.65 mm and an after-compression porosity of 60%. Local temperatures in the stack and pumping power were calculated for various air-flow velocities in the range of 0.2–1.5 m/s by numerical simulation and were determined by experiments. This range of air speed corresponds to the Reynolds number based on the hydraulic diameter in the range of 87.6–700.4. Internal and external cells of the stack were investigated. In the simulations, and the thermal energy equations were solved invoking the local thermal non-equilibrium model—a more realistic treatment for airflow in a metal foam. Good agreement between the simulation and experiment was obtained for the local temperatures. As for the pumping power predicted by simulation and obtained experimentally, there was an average difference of about 18.3%. This difference has been attributed to the poor correlation used by the CFD package (ANSYS) for pressure drop in a metal foam. This study points to the viability of employing metal foam for cooling of fuel-cell systems.

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