Tan Wee Choon
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Tan Wee Choon
Official Name
Tan, Wee Choon
Alternative Name
Choon, Tan Wee
Tan, W. C.
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Scopus Author ID
54891879100

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  • Publication
    Numerical analysis on the anode active thickness using quasi-three-dimensional solid oxide fuel cell model
    (Elsevier, 2023)
    Tan Wee Choon
    ;
    Lim Eng Aik
    ;
    Hamimah Abd Rahman
    ;
    Abdullah Abdul Samat
    ;
    Cheen Sean Oon
    A quasi-three-dimensional solid oxide fuel cell (SOFC) model reduces the computational cost by strategically ignoring the thinnest direction in an SOFC by incorporating a charge-transfer current density model to represent its active thickness in electrodes to represent its complex phenomenon in an electrode. Therefore, high accuracy of this charge-transfer current density model is required. The concentration loss is mathematically related to the charge-transfer current density based on the dusty-gas model together with activation and ohmic losses in this work. The numerical results from this study are validated with the experimental results. The influence of anode's thickness towards anode active thickness is studied with the anode thickness of 5, 10, 50, 100, 500 and 1000 μm. It is found that the quasi-three-dimensional SOFC model is capable of analysing SOFC with a sufficiently thick electrode. Also, a thick electrode and a high average current density result in a thin active thickness.
      3  44
  • Publication
    Numerical analysis of the effect of pore size toward the performance of solid oxide fuel cell
    (Springer Science and Business Media Deutschland GmbH, 2022-01-01)
    Tan Wee Choon
    ;
    Lim Eng Aik
    ;
    Cheng Ee Meng
    ;
    Tan Wei Hong
    The effect of the anode pore size is numerically investigated with the aids of artificial solid oxide fuel cell (SOFC) microstructure information. The standalone effect of the pore size is impossible to be realized by the experimental approach. Additionally, the complete real microstructure information is also limited in the open literature as it required sub-micron 3D imaging equipment. The dusty-gas model is implemented into the developed quasi-3D SOFC model for the gas diffusion in the anode. The model with real microstructure information is successfully validated. The actual anode pore radius of 0.283 Î¼m is artificially replaced with a radius of 0.025, 0.050, 0.250, 0.500, and 2.500 Î¼m. Decrement of area-specific reactant (ASR) for the anode concentration is found with the increment of pore radius. Also, such increment promotes a small increment of ASRs for the anode activation and the anode ohmic loss.
      2  4