A Computational Leakage Model for Solid Oxide Fuel Cell Compressive Seals

One of the key obstacles precluding the maturation and commercialization of planar solid oxide fuel cells has been the absence of a robust sealant. A computational model has been developed in conjunction with leakage experiments at Oak Ridge National Laboratory. The aforementioned model consists of three components: a macroscopic model, a microscopic model, and a mixed lubrication model. The macroscopic model is a finite element representation of a preloaded metal-metal seal interface, which is used to ascertain macroscopic stresses and deformations. The microscale contact mechanics model accounts for the role of surface roughness in determining the mean interfacial gap at the sealing interface. In particular, a new multiscale fast Fourier transform-based model is used to determine the gap. An averaged Reynolds equation derived from mixed lubrication theory is then applied to approximate the leakage flow across the rough annular interface. The composite model is applied as a predictive tool for assessing how certain physical parameters (i.e., seal material composition, compressive applied stress, surface finish, and elastic thermophysical properties) affect seal leakage rates. The leakage results predicted by the aforementioned computational leakage model are then compared with experimental results.

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Modeling Leakage With Mica-Based Compressive Seals for Solid Oxide Fuel Cells

Tribology ◽

10.1115/imece2006-15264 ◽

2006 ◽

Cited By ~ 1

Author(s):

Christopher K. Green ◽

Jeffrey L. Streator ◽

Comas Haynes

Keyword(s):

Finite Element ◽

Fuel Cells ◽

Finite Element Model ◽

Solid Oxide Fuel Cells ◽

Element Model ◽

High Energy ◽

Solid Oxide ◽

Physical Parameters ◽

Oxide Fuel ◽

Predictive Tool

Fuel cells represent a promising energy alternative to the traditional combustion of fossil fuels. In particular, solid oxide fuel cells (SOFCs) have been of interest due to their high energy densities and potential for stationary power applications. One of the key obstacles precluding the maturation and commercialization of planar SOFCs has been the lack of a robust sealant. This paper presents a computational model of leakage with the utilization of mica-based compressive seals. A finite element model is developed to ascertain the macroscopic stresses and deformations in the interface. In conjunction with the finite element model is a microscale contact mechanics model that accounts for the role of surface roughness in determining the mean interfacial gap at the interface. An averaged Reynolds equation derived from mixed lubrication theory is applied to model the leakage flow across the rough, annular interface. The composite model is applied as a predictive tool for assessing how certain physical parameters (i.e., seal material composition, compressive applied stress, surface finish, and interfacial conformity) affect seal leakage rates.

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A 2-D model for Intermediate Temperature Solid Oxide Fuel Cells Preliminarily Validated on Local Values

Catalysts ◽

10.3390/catal9010036 ◽

2019 ◽

Vol 9 (1) ◽

pp. 36 ◽

Cited By ~ 9

Author(s):

Bruno Conti ◽

Barbara Bosio ◽

Stephen John McPhail ◽

Francesca Santoni ◽

Davide Pumiglia ◽

...

Keyword(s):

Fuel Cells ◽

Operating Conditions ◽

Solid Oxide ◽

Intermediate Temperature ◽

Physical Parameters ◽

Local Concentration ◽

Oxide Fuel ◽

Molten Carbonate ◽

Experimental Apparatus ◽

Set Up

Intermediate Temperature Solid Oxide Fuel Cell (IT-SOFC) technology offers interesting opportunities in the panorama of a larger penetration of renewable and distributed power generation, namely high electrical efficiency at manageable scales for both remote and industrial applications. In order to optimize the performance and the operating conditions of such a pre-commercial technology, an effective synergy between experimentation and simulation is fundamental. For this purpose, starting from the SIMFC (SIMulation of Fuel Cells) code set-up and successfully validated for Molten Carbonate Fuel Cells, a new version of the code has been developed for IT-SOFCs. The new release of the code allows the calculation of the maps of the main electrical, chemical, and physical parameters on the cell plane of planar IT-SOFCs fed in co-flow. A semi-empirical kinetic formulation has been set-up, identifying the related parameters thanks to a devoted series of experiments, and integrated in SIMFC. Thanks to a multi-sampling innovative experimental apparatus the simultaneous measurement of temperature and gas composition on the cell plane was possible, so that a preliminary validation of the model on local values was carried out. A good agreement between experimental and simulated data was achieved in terms of cell voltages and local temperatures, but also, for the first time, in terms of local concentration on the cell plane, encouraging further developments. This numerical tool is proposed for a better interpretation of the phenomena occurring in IT-SOFCs and a consequential optimization of their performance.

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One-Dimensional Macroscopic Model of Solid Oxide Fuel Cell Anode with Analytical Modeling of H2/CO Electrochemical Co-oxidation

Electrochimica Acta ◽

10.1016/j.electacta.2014.04.106 ◽

2014 ◽

Vol 134 ◽

pp. 426-434 ◽

Cited By ~ 12

Author(s):

Cheng Bao ◽

Xinxin Zhang

Keyword(s):

Fuel Cell ◽

Solid Oxide Fuel Cell ◽

Co Oxidation ◽

Analytical Modeling ◽

Solid Oxide ◽

Macroscopic Model ◽

Oxide Fuel ◽

One Dimensional ◽

Cell Anode ◽

Fuel Cell Anode

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Application of an Anode Model to Investigate Physical Parameters in an Internal Reforming Solid-Oxide Fuel Cell

Journal of Fuel Cell Science and Technology ◽

10.1115/1.1895925 ◽

2005 ◽

Vol 2 (2) ◽

pp. 136-140 ◽

Cited By ~ 8

Author(s):

Eric S. Greene ◽

Maria G. Medeiros ◽

Wilson K. S. Chiu

Keyword(s):

Fuel Cell ◽

Solid Oxide Fuel Cell ◽

Structural Parameters ◽

Porous Electrode ◽

Cell Voltage ◽

Solid Oxide ◽

Physical Parameters ◽

Oxide Fuel ◽

Internal Reforming ◽

Porous Anode

A one-dimensional model of chemical and mass transport phenomena in the porous anode of a solid-oxide fuel cell, in which there is internal reforming of methane, is presented. Macroscopically averaged porous electrode theory is used to model the mass transfer that occurs in the anode. Linear kinetics at a constant temperature are used to model the reforming and shift reactions. Correlations based on the Damkohler number are created to relate anode structural parameters and thickness to a nondimensional electrochemical conversion rate and cell voltage. It is shown how these can be applied in order to assist the design of an anode.

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Leakage Studies With Seals for Solid-Oxide Fuel Cells

ASME/STLE 2007 International Joint Tribology Conference, Parts A and B ◽

10.1115/ijtc2007-44243 ◽

2007 ◽

Author(s):

Christopher K. Green ◽

Jeffrey L. Streator ◽

Comas Haynes ◽

Edgar Lara-Curzio

Keyword(s):

Fuel Cells ◽

Solid Oxide Fuel Cells ◽

Steel Substrate ◽

Vertical Direction ◽

Solid Oxide ◽

Physical Parameters ◽

Oxide Fuel ◽

Element Analysis ◽

Gas Leakage ◽

Interfacial Gap

This research seeks to characterize the gas leakage of a mica-based compressive seal assembly in planar solid-oxide fuel cells through modeling and experiment. In particular, it is of interest to assess how certain physical parameters (i.e., seal material composition, compressive applied stress, and surface finish) affect leakage rates. Finite element analysis is used to determine the macroscopic stresses and deformations in the sealing interface, while a microscale contact mechanics analysis is employed to model the role of surface roughness on the mean interfacial gap at the interface. An averaged Reynolds equation from mixed lubrication theory is applied to model the leakage flow across the sealed interface, which is of nanometer to micrometer dimensions in the vertical direction. In conjunction with the mathematical modeling, leakage results are reported. For these tests, an annular Inconel tube was pressed against a stainless steel substrate, creating an annular sealing zone. The inside of the tube is pressurized with a test gas, the mass of which is monitored during the leakage experiment. Test results are compared to model predictions.

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Glass-to-Metal Seal Interfacial Analysis using Electron Probe Microscopy for Reliable Solid Oxide Fuel Cells

Journal of the American Ceramic Society ◽

10.1111/j.1551-2916.2008.02902.x ◽

2009 ◽

Vol 92 (4) ◽

pp. 781-786 ◽

Cited By ~ 20

Author(s):

Scarlett J. Widgeon ◽

Erica L. Corral ◽

Michael N. Spilde ◽

Ronald E. Loehman

Keyword(s):

Fuel Cells ◽

Solid Oxide Fuel Cells ◽

Electron Probe ◽

Solid Oxide ◽

Oxide Fuel ◽

Probe Microscopy ◽

Metal Seal ◽

Interfacial Analysis

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Influence of Processing Parameters on the Manufacturing of Anode-Supported Solid Oxide Fuel Cells by Different Wet Chemical Routes

Materials Science Forum ◽

10.4028/www.scientific.net/msf.638-642.1098 ◽

2010 ◽

Vol 638-642 ◽

pp. 1098-1105 ◽

Cited By ~ 3

Author(s):

Norbert H. Menzler ◽

Wolfgang Schafbauer ◽

Hans Peter Buchkremer

Keyword(s):

Fuel Cells ◽

Solid Oxide Fuel Cells ◽

Process Parameters ◽

Tape Casting ◽

Solid Oxide ◽

Physical Parameters ◽

Substrate Thickness ◽

Oxide Fuel ◽

Wet Chemical ◽

Substrate Types

Anode-supported solid oxide fuel cells (SOFC) are manufactured at Forschungszentrum Jülich by different wet chemical powder processes and subsequent sintering at high temperatures. Recently, the warm pressing of Coat-Mix powders has been replaced by tape casting as the shaping technology for the NiO/8YSZ-containing substrate in order to decrease the demand for raw materials due to lower substrate thickness and in order to increase reproducibility and fabrication capacities (scalable process). Different processing routes for the substrates require the adjustment of process parameters for further coating with functional layers. Therefore, mainly thermal treatment steps have to be adapted to the properties of the new substrate types in order to obtain high-performance cells with minimum curvature (for stack assembly). In this presentation, the influence of selected process parameters during cell manufacturing will be characterized with respect to the resulting physical parameters such as slurry viscosity, green tape thickness, relative density, substrate strength, electrical conductivity, and shrinkage of the different newly developed substrate types. The influencing factors during manufacturing and the resulting characteristics will be presented and possible applications for the various substrates identified.

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