MODELING OF SOLID OXIDE FUEL CELL SYSTEM: MULTISCALE MODELING AND SIMULATION OF THERMALFLUID AND ELECTROCHEMICAL TRANSPORT IN ,Used

MODELING OF SOLID OXIDE FUEL CELL SYSTEM: MULTISCALE MODELING AND SIMULATION OF THERMALFLUID AND ELECTROCHEMICAL TRANSPORT IN ,Used

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SKU: DADAX3639235878
Brand: VDM Verlag
Condition: New
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Solid oxide fuel cells (SOFCs) are expected to be widely applicable for both small and largescale power generation systems. The reason is that the SOFC is simple, highly efficient, tolerant to impurities, and can at least partially internally reform hydrocarbon fuels. A multiphysics, multiscale model structure is proposed by integrating three submodels, i.e., a macrocontinuum model, a microscale model (random walk model) and an atomisticlevel model. This multiscale model has the capability of handling transport mechanisms on different length scales at the same time. The coarsest macrocontinuum model is first proposed to simulate all energy transport processes in an electrolyte/anodesupported SOFC. Then a novel microlevel model (random walk model) is developed to investigate the electrochemical performance in a composite electrode. Finally, a multiscale model by combining the developed macrolevel model and microlevel model is proposed for a lower temperature SOFC. Based on this multiscale model, the dependence of electrochemical performance on the global parameters and microstructures is assessed for the entire fuel cell stack.

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