Abstract
CH4-assisted solid oxide electrolyzer cells (SOECs) can co-electrolyze H2O and CO2 effectively for simultaneous energy storage and CO2 utilization. Compared with conventional SOECs, CH4-assisted SOECs consume less electricity because CH4 in the anode provides part of the energy for electrolysis. As syngas (CO and H2 mixture) is generated from the co-electrolysis process, it is necessary to study its utilization through the subsequent processes, such as Fischer-Tropsch (F-T) synthesis to produce more value-added products. An F-T reactor can convert syngas into hydrocarbons, and thus it is very suitable for the utilization of syngas. In this paper, the combined CH4-assisted SOEC and F-T synthesis system is numerically studied. Validated 2D models for CH4-assisted SOEC and F-T processes are adopted for parametric studies. It is found that the cathode inlet H2O/CO2 ratio in the SOEC significantly affects the production components through the F-T process. Other operating parameters such as the operating temperature and applied voltage of the SOEC are found to greatly affect the productions of the system. This model is important for understanding and design optimization of the combined fuel-assisted SOEC and F-T synthesis system to achieve economical hydrocarbon generation.
Highlights
With the growing attention on global warming, effective CO2 utilization methods are urgently needed [1]
To fill this research gap, in this work, 2D mathematical models are developed for a combined CH4-assisted SOEC and F-T synthesis system for H2O/CO2 co-electrolysis and hydrocarbon fuels generation
CO2 and H2O are used as the feedstock to produce low-carbon fuel through the F-T reactor
Summary
With the growing attention on global warming, effective CO2 utilization methods are urgently needed [1]. Solid oxide electrolyzer cells (SOECs) are high-temperature technologies [2], which are suitable to convert CO2 into chemicals or fuels by utilizing the renewable energy or excessive electricity produced from renewable resources [3]. A system consisting of a CH4-assisted SOEC and an F-T reactor can effectively convert CO2 and generate desired hydrocarbons. Such a hybrid system is very promising for CO2 utilization and hydrocarbon fuels generation. To fill this research gap, in this work, 2D mathematical models are developed for a combined CH4-assisted SOEC and F-T synthesis system for H2O/CO2 co-electrolysis and hydrocarbon fuels generation. Parametric simulations are conducted to understand the characteristics of such a system and the interplay of different physical/chemical processes
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