Synergistic effects of mixtures of iron ores and copper ores as oxygen carriers in chemical-looping combustion

Iron ore is a cheap and nontoxic oxygen carrier in chemical-looping combustion (CLC). However, it performs good recyclability while low reactivity in the CLC of solid fuels. Copper ore exhibits very high reactivity and oxygen uncoupling behavior, while suffers from tendency towards sintering and agglomeration during consecutive redox cycles at a higher temperature (e.g., 900-1000 degrees C). In this work, mixtures of hematite and copper ore were used as oxygen carriers for CLC of syngas and coal. Through the isothermal redox experiments at 950 degrees C in a thermogravimetric analyzer, it is found that there are synergistic effects between iron ore and copper ore, and copper ore could be more efficiently utilized when the mixing ratio of copper ore is maintained 10-20 wt%. As the mixing ratio of copper ore is 20 wt%, the reduction reaction of the mixer OC is no longer endothermic, which is beneficial to the controllability of the fuel-reactor temperature. The fluidized-bed experiments were carried out to verify the reactivity of the mixing ore OCs at 950 degrees C. It is observed that the mixing OC with 20 wt% copper ore has a better reactivity with the gasification products (especially H-2) of low-volatile anthracite than the pure hematite, and leads to a higher fuel conversion rate and CO2 yield. The mixtures of iron ore and copper ore are expected to address simultaneously reactivity, recyclability, cost and environmental concerns of oxygen carriers. (C) 2014 The Combustion Institute. Published by Elsevier Inc. All rights reserved.