LAUSR

The thermomechanical response of solid oxide fuel cell will endanger its structural reliability. In this study, the effects of non‐planar interface and electrode parameters are investigated by building a cosine anode‐electrolyte interface with amplitude A and wavelength λ. Results show that the planar interface model cannot completely reflect the stress state of solid oxide fuel cells. Non‐planar interface can stimulate high normal stress Sn and shear stress St at the interface, but these stresses are zero at the planar interface. Cosine interface causes approximately cosinoidal Sn and sinusoidal St. The bigger the ratio of amplitude to wavelength A/λ is, the more serious the Sn fluctuates. Electrode parameter analysis shows that increasing initial porosity of oxidized anode can reduce the maximum Sn but increases the maximum St and the cell deflection. Parameter study show that initial porosity between 0.15 and 0.25 is suitable. The effect of anode thickness on the maximum Sn and St is weak, while the electrolyte thickness has a relatively strong effect when the electrolyte thickness is less than 12 μm. A NiO volume fraction between 0.52 to 0.58 is recommended to avoid overlarge Sn, St, and deflection.