Combustion modelling opportunities and challenges for oxy-coal carbon capture technology

▶ This article provides a comprehensive review of current oxy-coal combustion models. ▶ Review topics include chemical kinetics, turbulence and full system simulation. ▶ The applicability of current models to simulate oxy-coal combustion is examined. ▶ Future areas of model development for oxy-coal...

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Bibliographic Details
Published in:Chemical engineering research & design 2011-09, Vol.89 (9), p.1470-1493
Main Authors: Edge, P., Gharebaghi, M., Irons, R., Porter, R., Porter, R.T.J., Pourkashanian, M., Smith, D., Stephenson, P., Williams, A.
Format: Article
Language:English
Subjects:
Carbon
CFD modelling
Char combustion
Combustion
Computational fluid dynamics
Design engineering
Kinetic modelling
Mathematical models
Modelling
Oxy-coal combustion
Pollutants
Radiative heat transfer
Turbulence
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Summary:▶ This article provides a comprehensive review of current oxy-coal combustion models. ▶ Review topics include chemical kinetics, turbulence and full system simulation. ▶ The applicability of current models to simulate oxy-coal combustion is examined. ▶ Future areas of model development for oxy-coal technology are identified. Oxy-coal combustion is one of the leading technologies for carbon capture and storage. This paper presents a review of the opportunities and challenges surrounding the development of oxy-coal combustion models and discusses historical and recent advances in specific areas related to computational fluid dynamics (CFD), including char oxidation, radiation, pollutant formation and removal (Hg, NO x and SO x ), and the impact of turbulence. CFD can be used to assess and optimise full-scale retrofit designs and to provide data on matching air-fired heat duties. In addition, CFD can also be used to improve combustion efficiency and identify potential reductions in corrosion, slagging, fouling and trace pollutant emissions. Transient simulations are becoming more computationally affordable for coal combustion, providing opportunities for model development. High concentrations of CO 2 and H 2O in oxy-coal can influence chemical kinetic rates, burnout and ash properties. The modelling can be improved by incorporating detailed kinetic mechanisms of gasification reactions. In addition, pollutant formation and removal mechanisms must be understood during oxy-coal firing to aid the selection of flue-gas cleaning strategies. Radiative heat transfer using spectral models for gaseous properties may be necessary in oxy-coal modelling because CO 2 and H 2O molecules have strong emission bands. Finally this review provides a coherent near-term and long-term oxy-coal specific CFD sub-models development strategy to simulate the complex oxy-coal combustion processes, heat transfer and pollutant emissions in power generation systems.
ISSN:0263-8762
DOI:10.1016/j.cherd.2010.11.010