CO2 Capture Capacity of CaO in Long Series of Carbonation/Calcination Cycles

Calcium oxide can be an effective sorbent to separate CO2 at high temperatures. When coupled with a calcination step to produce pure CO2, the carbonation reaction is the basis for several high-temperature CO2 capture systems. The evolution with cycling of the capture capacity of CaO derived from nat...

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Bibliographic Details
Published in:Industrial & engineering chemistry research 2006-12, Vol.45 (26), p.8846-8851
Main Authors: Grasa, Gemma S, Abanades, J. Carlos
Format: Article
Language:English
Subjects:
Applied sciences
Chemical engineering
Exact sciences and technology
Online Access:Get full text
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Summary:Calcium oxide can be an effective sorbent to separate CO2 at high temperatures. When coupled with a calcination step to produce pure CO2, the carbonation reaction is the basis for several high-temperature CO2 capture systems. The evolution with cycling of the capture capacity of CaO derived from natural limestones is experimentally investigated in this work. Long series of carbonation/calcination cycles (up to 500) varying different variables affecting sorbent capacity have been tested in a thermogravimetric apparatus. Calcination temperatures above T > 950 °C and very long calcination times accelerate the decay in sorption capacity, while other variables have a comparatively modest effect on the overall sorbent performance. A residual conversion of about 7−8% that remains constant after many hundreds of cycles and that seems insensitive to process conditions has been found. This residual conversion makes very attractive the carbonation/calcination cycle, by reducing (or even eliminating) sorbent purge rates in the system. A semiempirical equation has been proposed to describe sorbent conversion with the number of cycles based on these new long data series.
ISSN:0888-5885
1520-5045
DOI:10.1021/ie0606946