Details
| Original language | English |
|---|---|
| Article number | 224 |
| Journal | Entropy |
| Volume | 24 |
| Issue number | 2 |
| Early online date | 31 Jan 2022 |
| Publication status | Published - Feb 2022 |
Abstract
With its outstanding performance characteristics, the SOFC represents a promising technology for integration into the current energy supply system. For cell development and optimization, a reliable quantitative description of the transport mechanisms and the resulting losses are relevant. The local transport processes are calculated by a 1D model based on the non-equilibrium thermodynamics (NET). The focus of this study is the mass transport in the gas diffusion layers (GDL), which was described as simplified by Fick’s law in a previously developed model. This is first replaced by the Dusty-Gas model (DGM) and then by the thermal diffusion (Soret effect) approach. The validation of the model was performed by measuring U, j-characteristics resulting in a maximum deviation of experimental to simulated cell voltage to up to 0.93%. It is shown that, under the prevailing temperature, gradients the Soret effect can be neglected, but the extension to the DGM has to be considered. The temperature and heat flow curves illustrate the relevance of the Peltier effects. At T = 1123.15 K and j = 8000 A/m2, 64.44% of the total losses occur in the electrolyte. The exergetic efficiency for this operating point is 0.42. Since lower entropy production rates can be assumed in the GDL, the primary need is to investigate alternative electrolyte materials.
Keywords
- Dusty-Gas model (DGM), Entropy production, Exergy efficiency, Non-equilibrium thermodynamics (NET), Solid oxide fuel cell (SOFC), Soret effect, Thermal diffusion
ASJC Scopus subject areas
- Computer Science(all)
- Information Systems
- Mathematics(all)
- Mathematical Physics
- Physics and Astronomy(all)
- Physics and Astronomy (miscellaneous)
- Engineering(all)
- Electrical and Electronic Engineering
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In: Entropy, Vol. 24, No. 2, 224, 02.2022.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Coupled Transport Effects in Solid Oxide Fuel Cell Modeling
AU - Gedik, Aydan
AU - Lubos, Nico
AU - Kabelac, Stephan
N1 - Funding Information: The authors gratefully acknowledge the financial support by the Deutsche Forschungsge-meinschaft (DFG, funding code KA 1211/32-1) for financial support.
PY - 2022/2
Y1 - 2022/2
N2 - With its outstanding performance characteristics, the SOFC represents a promising technology for integration into the current energy supply system. For cell development and optimization, a reliable quantitative description of the transport mechanisms and the resulting losses are relevant. The local transport processes are calculated by a 1D model based on the non-equilibrium thermodynamics (NET). The focus of this study is the mass transport in the gas diffusion layers (GDL), which was described as simplified by Fick’s law in a previously developed model. This is first replaced by the Dusty-Gas model (DGM) and then by the thermal diffusion (Soret effect) approach. The validation of the model was performed by measuring U, j-characteristics resulting in a maximum deviation of experimental to simulated cell voltage to up to 0.93%. It is shown that, under the prevailing temperature, gradients the Soret effect can be neglected, but the extension to the DGM has to be considered. The temperature and heat flow curves illustrate the relevance of the Peltier effects. At T = 1123.15 K and j = 8000 A/m2, 64.44% of the total losses occur in the electrolyte. The exergetic efficiency for this operating point is 0.42. Since lower entropy production rates can be assumed in the GDL, the primary need is to investigate alternative electrolyte materials.
AB - With its outstanding performance characteristics, the SOFC represents a promising technology for integration into the current energy supply system. For cell development and optimization, a reliable quantitative description of the transport mechanisms and the resulting losses are relevant. The local transport processes are calculated by a 1D model based on the non-equilibrium thermodynamics (NET). The focus of this study is the mass transport in the gas diffusion layers (GDL), which was described as simplified by Fick’s law in a previously developed model. This is first replaced by the Dusty-Gas model (DGM) and then by the thermal diffusion (Soret effect) approach. The validation of the model was performed by measuring U, j-characteristics resulting in a maximum deviation of experimental to simulated cell voltage to up to 0.93%. It is shown that, under the prevailing temperature, gradients the Soret effect can be neglected, but the extension to the DGM has to be considered. The temperature and heat flow curves illustrate the relevance of the Peltier effects. At T = 1123.15 K and j = 8000 A/m2, 64.44% of the total losses occur in the electrolyte. The exergetic efficiency for this operating point is 0.42. Since lower entropy production rates can be assumed in the GDL, the primary need is to investigate alternative electrolyte materials.
KW - Dusty-Gas model (DGM)
KW - Entropy production
KW - Exergy efficiency
KW - Non-equilibrium thermodynamics (NET)
KW - Solid oxide fuel cell (SOFC)
KW - Soret effect
KW - Thermal diffusion
UR - http://www.scopus.com/inward/record.url?scp=85123883529&partnerID=8YFLogxK
U2 - 10.3390/e24020224
DO - 10.3390/e24020224
M3 - Article
AN - SCOPUS:85123883529
VL - 24
JO - Entropy
JF - Entropy
SN - 1099-4300
IS - 2
M1 - 224
ER -