Pressurized chemical-looping combustion of coal using an iron ore as oxygen carrier in a pilot-scale unit

► The feasibility of pressurized CLC of coal was examined in continuous reactors. ► A pilot-scale PCLC unit of coal was firstly established. ► The effects of operation pressure on performance of this unit were evaluated. ► A new design of the continuous reactors was applied to the pilot-scale PCLC u...

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Bibliographic Details
Published in:International journal of greenhouse gas control 2012-09, Vol.10, p.363-373
Main Authors: Xiao, Rui, Chen, Liangyong, Saha, Chiranjib, Zhang, Shuai, Bhattacharya, Sankar
Format: Article
Language:English
Subjects:
Carbon dioxide
CO2 capture
Coal
Iron ore oxygen carrier
Pilot-scale study
Pressurized chemical-looping combustion
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Summary:► The feasibility of pressurized CLC of coal was examined in continuous reactors. ► A pilot-scale PCLC unit of coal was firstly established. ► The effects of operation pressure on performance of this unit were evaluated. ► A new design of the continuous reactors was applied to the pilot-scale PCLC unit. ► The potential of iron ore as a low-cost OC was examined. Chemical looping combustion (CLC) of coal is established as a new concept for inherent CO2 separation with the advantages of low cost and high conversion efficiency. A pilot-scale unit consisting of two fluidized bed reactors was constructed and operated to study the performance of pressurized chemical-looping combustion (PCLC). Experiments were conducted using Shenhua bituminous coal as fuel and MAC iron ore as oxygen carrier at three different operation pressures (0.1, 0.3 and 0.5MPa) and the unit has been operated for totally 19h with steady coal-feeding, about 13.5h of which were realized under stable operation. The results showed that PCLC of coal demonstrated many remarkable advantages over the conventional CLC of coal, in terms of the improvement of carbon conversion in the fuel reactor, CO2 concentration of exhaust gas and combustion efficiency. At the operating pressure of 0.5MPa, the CO2 concentration, carbon conversion and combustion efficiency reached very high values of 97.2, 84.7 and 95.5% respectively. The potential of low-cost iron ore as oxygen carrier for commercial coal-fueled CLC unit was also examined. The loss of oxygen carrier due to fine particles leaving the reactors increased with the increase of operation pressure and no agglomeration of oxygen carrier particles occurred during these tests. The oxygen carrier used in PCLC tests were also characterized by SEM-EDX and BET analysis to further emphasis on the effects of operation pressures and runtime.
ISSN:1750-5836
1878-0148
DOI:10.1016/j.ijggc.2012.07.008