Micro-tubular solid oxide fuel cells (MT-SOFCs) are a much smaller version of larger tubular SOFCs. They are operational within seconds and allow a higher power density per volume than the larger version. Hence they are a potential technology for automotive, auxiliary and small scale power supply devices. In this study a commercially available computational fluid dynamic (CFD) software program was used to predict a MT-SOFCs performance when located inside a high temperature wind tunnel experimental apparatus. In Part I, experimentally measured temperature profiles were recorded via thermo-graphic analyses and I/V curves. These measurements were used in this study to establish the predictability and validity of the CFD code and furthermore understand the MT-SOFC attributes measured in Part I. A maximum 4% I/V curve deviation and 6 K temperature deviation between the experimentally measured and model predicted results was observed. Thus, the model predicted the MT-SOFCs performance in the experimental environment very accurately. A very critical observation was the current density and temperature profile across the MT-SOFC that was strongly dependent on the distance from the hydrogen/fuel inlet. Not only was the model validated but also a grid and quantitative solution analysis is explicitly shown and discussed. This resulted in the optimum grid density and the indication that a normally undesirable high grid aspect ratio is acceptable for similar MT-SOFC modeling. These initial simulations and grid/solution analysis are the prerequisite before performing a further study including multiple MT-SOFCs within a stack using different fuels is also envisaged.
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December 2011
This article was originally published in
Journal of Fuel Cell Science and Technology
Research Papers
The Use of a High Temperature Wind Tunnel for MT-SOFC Testing—Part II: Use of Computational Fluid Dynamics Software in Order to Study Previous Measurements
V. Lawlor,
V. Lawlor
Dept. Eco-Energy, Upper Austrian University of Applied Science, A-4600 Wels, Austria; Department of Manufacturing and Mechanical Engineering,
e-mail: vlawlor@gmail.com
Dublin City University
, Dublin 9, Ireland
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C. Hochenauer,
C. Hochenauer
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
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S. Griesser,
S. Griesser
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
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G. Zauner,
G. Zauner
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
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G. Buchinger,
G. Buchinger
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
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D. Meissner,
D. Meissner
Dept. Eco-Energy, Upper Austrian University of Applied Science, A-4600 Wels, Austria;
Tallinn Technical University
, Ehitajate tee 5, Tallinn 19086, Estonia
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A. G. Olabi,
A. G. Olabi
Department of Manufacturing and Mechanical Engineering,
Dublin City University
, Dublin 9, Ireland
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K. Klein,
K. Klein
eZelleron GmbH
, Collenbuschstr. 22, 01324 Dresden, Germany
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S. Kuehn,
S. Kuehn
eZelleron GmbH
, Collenbuschstr. 22, 01324 Dresden, Germany
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S. Cordiner,
S. Cordiner
Dipartimento di Ingegneria Meccanica -
Università di Roma Tor Vergata
, Rome, Italy
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A. Mariani
A. Mariani
Dipartimento di Ingegneria Meccanica -
Università di Roma Tor Vergata
, Rome, Italy
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V. Lawlor
Dept. Eco-Energy, Upper Austrian University of Applied Science, A-4600 Wels, Austria; Department of Manufacturing and Mechanical Engineering,
Dublin City University
, Dublin 9, Ireland
e-mail: vlawlor@gmail.com
C. Hochenauer
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
S. Griesser
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
G. Zauner
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
G. Buchinger
Dept. Eco-Energy,
Upper Austrian University of Applied Science
, A-4600 Wels, Austria
D. Meissner
Dept. Eco-Energy, Upper Austrian University of Applied Science, A-4600 Wels, Austria;
Tallinn Technical University
, Ehitajate tee 5, Tallinn 19086, Estonia
A. G. Olabi
Department of Manufacturing and Mechanical Engineering,
Dublin City University
, Dublin 9, Ireland
K. Klein
eZelleron GmbH
, Collenbuschstr. 22, 01324 Dresden, Germany
S. Kuehn
eZelleron GmbH
, Collenbuschstr. 22, 01324 Dresden, Germany
S. Cordiner
Dipartimento di Ingegneria Meccanica -
Università di Roma Tor Vergata
, Rome, Italy
A. Mariani
Dipartimento di Ingegneria Meccanica -
Università di Roma Tor Vergata
, Rome, Italy
J. Fuel Cell Sci. Technol. Dec 2011, 8(6): 061019 (12 pages)
Published Online: October 3, 2011
Article history
Received:
May 23, 2011
Revised:
June 23, 2011
Published:
September 30, 2011
Online:
October 3, 2011
Citation
Lawlor, V., Hochenauer, C., Griesser, S., Zauner, G., Buchinger, G., Meissner, D., Olabi, A. G., Klein, K., Kuehn, S., Cordiner, S., and Mariani, A. (October 3, 2011). "The Use of a High Temperature Wind Tunnel for MT-SOFC Testing—Part II: Use of Computational Fluid Dynamics Software in Order to Study Previous Measurements." ASME. J. Fuel Cell Sci. Technol. December 2011; 8(6): 061019. https://doi.org/10.1115/1.4004507
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