Particle scale modeling of CuFeAlO4 during reduction with CO in chemical looping applications

•Experimental study of key operational variable influence on reduction behavior.•Kinetic particle scale modeling of CuFeAlO4 OC reduction with coal derived syngas component, CO.•Multi-interface Grainy pellet model for multi-phase reduction mechanism.•Product gas, CO2, reversibility accounted for by...

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Bibliographic Details
Published in:Applied energy 2019-10, Vol.251 (C), p.113178, Article 113178
Main Authors: Riley, Jarrett, Siriwardane, Ranjani, Tian, Hanjing, Benincosa, William, Poston, James
Format: Article
Language:English
Subjects:
Carbon monoxide
Chemical looping combustion
Copper-ferri-aluminate
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Oxygen carriers
Particle scale modeling
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Summary:•Experimental study of key operational variable influence on reduction behavior.•Kinetic particle scale modeling of CuFeAlO4 OC reduction with coal derived syngas component, CO.•Multi-interface Grainy pellet model for multi-phase reduction mechanism.•Product gas, CO2, reversibility accounted for by linking front progression to reaction equilibria.•Catalytic Effects of the Boudouard reaction linked to the model description. Particle scale models that couple reaction phenomena to changes in the solid-state chemistry of an oxygen carrier system are critical to the advancement of the chemical looping concept by allowing for a means to assess process scale up. This work presents an analysis of the reduction for a CuFeAlO4 oxygen carrier with Carbon Monoxide (CO). The analysis was utilized to aid in the application of particle scale model representation of the carrier system. An experimentally driven study was conducted to provide an array of operational/parametric data sets for the analysis and their impact accessed. Quantification of the cubic spinel oxide phase and changes due to lattice oxygen depletion from reduction were explored to link the solid-state chemistry changes to the reaction progression. Reduction occurred in a multistep process as oxygen was depleted from the structure. Oxygen bound to Cu cations were the first to react with CO. As oxygen was depleted further phase re-orientation occurred resulting in an iron based aluminate (FeAl2O4) with discrete metallic copper present. FeAl2O4 was further depleted of oxygen to metallic Fe and alumina. The multistep process was emulated through the use of a multi-interface Grainy pellet model. To add to the utility of the model, the effects of product gas, CO2, on the reaction progression were incorporated into the description. In addition, the catalytic effects of the Boudouard reaction were examined and incorporated into the representation adding to the novelty of the work.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2019.04.174