Optimization of manifold design for 1 kW-class flat-tubular solid oxide fuel cell stack operating on reformed natural gas

This study focuses on optimizing the manifold design for a 1 kW-class flat-tubular solid oxide fuel cell stack by performing extensive three-dimensional numerical simulations on numerous manifold designs. The stack flow uniformity and the standard flow deviation indexes are implemented to characteri...

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Bibliographic Details
Published in:Journal of power sources 2016-09, Vol.327, p.638-652
Main Authors: Rashid, Kashif, Dong, Sang Keun, Khan, Rashid Ali, Park, Seung Hwan
Format: Article
Language:English
Subjects:
Computational fluid dynamics calculations
Electrochemical reaction
Flat tubular solid oxide fuel cell
Flow uniformity
Manifold optimization
Stack performance
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Summary:This study focuses on optimizing the manifold design for a 1 kW-class flat-tubular solid oxide fuel cell stack by performing extensive three-dimensional numerical simulations on numerous manifold designs. The stack flow uniformity and the standard flow deviation indexes are implemented to characterize the flow distributions in the stack and among the channels of FT-SOFC's, respectively. The results of the CFD calculations demonstrate that the remodeled manifold without diffuser inlets and 6 mm diffuser front is the best among investigated designs with uniformity index of 0.996 and maximum standard flow deviation of 0.423%. To understand the effect of manifold design on the performance of stack, both generic and developed manifold designs are investigated by applying electrochemical and internal reforming reactions modeling. The simulation results of the stack with generic manifold are validated using experimental data and then validated models are adopted to simulate the stack with the developed manifold design. The results reveal that the stack with developed manifold design achieves more uniform distribution of species, temperature, and current density with comparatively lower system pressure drop. In addition, the results also showed ∼8% increase in the maximum output power due to the implementation of uniform fuel velocity distributions in the cells. •CFD tools are utilized to optimize the manifold design for FT-SOFC stack.•Remodeled manifold showed improvement in flow uniformity and pressure drop.•Electrochemical and internal reforming modeling applied on 1 kW FT-SOFC stacks.•Developed manifold stack exhibited uniform distributions.•Developed manifold stack demonstrated an enhanced stack output power.
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2016.07.077