Journal
ENERGY & ENVIRONMENTAL SCIENCE
Volume 11, Issue 1, Pages 136-143Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/c7ee02161e
Keywords
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Funding
- EPSRC Frontier Engineering'' Award [EP/K038656/1]
- UCL Faculty of Engineering Sciences Dean's Scholarship
- EPSRC [EP/L014289/1, EP/K038656/1] Funding Source: UKRI
- Engineering and Physical Sciences Research Council [EP/L014289/1, EP/K038656/1] Funding Source: researchfish
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A lung-inspired approach is employed to overcome reactant homogeneity issues in polymer electrolyte fuel cells. The fractal geometry of the lung is used as the model to design flow-fields of different branching generations, resulting in uniform reactant distribution across the electrodes and minimum entropy production of the whole system. 3D printed, lung-inspired flow field based PEFCs with N = 4 generations outperform the conventional serpentine flow field designs at 50% and 75% RH, exhibiting a similar to 20% and similar to 30% increase in performance (at current densities higher than 0.8 A cm(-2)) and maximum power density, respectively. In terms of pressure drop, fractal flow-fields with N = 3 and 4 generations demonstrate similar to 75% and similar to 50% lower values than conventional serpentine flow-field design for all RH tested, reducing the power requirements for pressurization and recirculation of the reactants. The positive effect of uniform reactant distribution is pronounced under extended current-hold measurements, where lung-inspired flow field based PEFCs with N = 4 generations exhibit the lowest voltage decay (similar to 5 mV h(-1)). The enhanced fuel cell performance and low pressure drop values of fractal flow field design are preserved at large scale (25 cm(2)), in which the excessive pressure drop of a large-scale serpentine flow field renders its use prohibitive.
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