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Analysis and optimization of solid oxide fuel cell system with anode and cathode off gas recirculation

Xinmiao Wei, Shivom Sharma, Jan Van herle, François Maréchal

2024Renewable and Sustainable Energy Reviews15 citationsDOIOpen Access PDF

Abstract

Solid oxide fuel cell technology shows great potential in generating electricity. However, insufficient steam in the stack can result in carbon deposition, accelerating cell degradation over prolonged operation. To prevent this, ensuring an adequate supply of external water is necessary, yet resulting in a larger external water purification unit and a greater need for heat for water evaporation. Anode-off gas, which comprises unreacted fuel, steam and CO 2 from the stack, can be strategically recirculated to the external reformer inlet, preventing carbon deposition in the reformer and stack. Further, solid oxide fuel cell system offers the potential to supply high-temperature heat to industrial applications, embodying the concept of combined heat and power plants. To maximize heat availability, cathode-off gas can partially be blended with the fresh air entering the stack. Various anode-off gas and cathode-off gas recirculation configurations are possible, and they have to be systematically analysed and compared. This study models all possible system configurations using different types of anode-off gas (no, cold, warm, hot) and cathode-off gas (no, warm, hot) recirculations. Multi-objective optimization has been conducted, and system performance has been analysed and compared using electrical efficiency, freshwater consumption, thermal efficiency, design complexity, heat availability and heat valorization potential. Further, an in-depth analysis of the impact of decision variables on the objective functions has been performed for different system configurations. These valuable insights serve as a guide to engineers and decision-makers, enabling informed decisions for solid oxide fuel cell system design. • Evaluating solid oxide fuel cell systems with the anode (AOG) and cathode off gas (COG) recirculation modules. • Modelling, optimization and comparing twelve SOFC systems with AOG/COG modules. • AOG recirculation influences electrical efficiency, freshwater consumption and system design. • COG recirculation affects electrical and thermal efficiencies and fresh air consumption. • This study presents the availability of high-quality heat and heat valorization potential.

Topics & Concepts

AnodeCathodeSolid oxide fuel cellMaterials scienceFuel cellsOxideChemical engineeringNuclear engineeringChemistryElectrodeMetallurgyEngineeringPhysical chemistryAdvancements in Solid Oxide Fuel CellsFuel Cells and Related MaterialsCatalysis and Oxidation Reactions