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    The high operating temperature (OT) enables solid oxide fuel cells (SOFCs) to have a superior efficiency of energy conversion while accompanying concerns such as degradation of materials because of undesirable reactions between components.  Structural durability of SOFC is affected by the thermal stresses due to thermal mismatch between components.  Excessive thermal stresses may lead to fracture of components endangering the mechanical integrity of an SOFC stack.  Therefore, a systematic investigation of thermal stress distribution and mechanical properties of components at room temperature (RT) and OT is essential for development of a reliable SOFC stack.

    The first objective of this study is using finite element analysis (FEA) to calculate the thermal stress distribution in a 3-cell planar SOFC stack.  The simulated model was constructed based on a stack design of compressive sealing being developed at the Institute of Nuclear Energy Research (INER).  Two temperature profiles were applied to evaluate the effect of thermal gradient on the critical stresses in the components.  Simulation results indicate that the effect of thermal gradient could be neglected for the given two temperature profiles.

    The second objective is to determine the mechanical properties of a potential anode material, Slip-81, developed at INER.  Biaxial flexural strength and Young¡¦s modulus were determined at RT and a high temperature of 800 ^oC by biaxial flexural ring-on-ring testing.  The measured mechanical properties were applied to the aforementioned FEA modeling of thermal analysis.  The critical stresses of all components were lower than the corresponding fracture strength by the use of Slip-81 anode.

    The third purpose in the current study is to investigate the joint strength between the glass-ceramic and metallic interconnect.  The utilized materials were the GC-9 glass-ceramic developed at INER and the Crofer 22 H which is a commercial ferritic stainless steel.  A methodology of evaluating the joint strength was developed by testing two types of sandwich-like specimens under tensile and shear loading.  The shear strength at RT and 800 ^oC and tensile strength at RT were measured.  The effect of sintering temperature on the joint strength was studied.  The measured tensile and shear strength of the specimens sintered at 900 ^oC were greater than those of the ones sintered at 850 ^oC at both testing temperatures of RT and 800 ^oC.  Apparently, an increase of sintering temperature could improve the joining performance due to a better wetting behavior of glass-ceramic. 

    The effect of pre-oxidization of metallic interconnect on the joint strength was also evaluated.  The pre-oxidization treatment degraded the shear strength of the specimens sintered at 850 ^oC.  However, it enhanced the shear strength of the specimens sintered at 900 ^oC.  Through the analysis of interfacial microstructure, fracture modes of the joint were correlated with the measured strength.  Three types of fracture modes were identified for the joint specimens.  Firstly, the lowest joint strength was accompanied with delamination at the interface between the glass-ceramic substrate and an adjacent oxide layer, chromate (BaCrO₄).  Secondly, delamination at the interface between the metal substrate and the oxide layer of the metal, chromia (Cr₂O₃), accompanied with a medium joint strength.  Thirdly, the fracture might take place in the glass-ceramic layer for a larger joint strength.

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