Overview
ABSTRACT
Chemical looping combustion (CLC)” is currently being considered to facilitate the capture of CO2 in industries burning carbonaceous compounds. The combustive agent used is a material called an “oxygen carrier”, which circulates between a combustion chamber and a reactor, where it is regenerated. The material can be used for several combustions until it degrades. After defining CLC technology and the context in which it developed, this article describes the general principle of different processes developed around this common concept, highlighting the role of the oxygen-carrying material in each case. The characteristics generally required for selecting an oxygen carrier material are also presented.
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Ludivine FRANCK-LACAZE: Lecturer at the University of Lorraine - Reactions and Process Engineering Laboratory - UMR 7274 CNRS – University of Lorraine, Nancy, France
INTRODUCTION
One of the major challenges facing the environment is the fight against global warming, caused by increasing emissions of greenhouse gases into the atmosphere, particularly carbon dioxide. At world conferences on the environment, industrialized countries undertook to control their carbon dioxide emissions under the Kyoto Protocol, signed in 1997 and ratified in 2005. Since then, considerable efforts have been made to replace carbon-based energies with renewable energies. However, our dependence on fossil fuels is so great, particularly in the energy, industry, transport and residential sectors, that it seems impossible to free ourselves from them in the near future.
In response to the environmental emergency, CO 2 capture and storage technologies have been intensively developed in recent years to equip plants with high carbon dioxide emissions, such as power plants, steelworks, cement plants, oil refineries and so on. The aim being to capture the CO 2 produced, transport it and store it outside the atmosphere in deep saline aquifers, untapped coal seams or similar. It should be noted that a proportion of CO 2 may be exported to plants that consume it, for urea production for example, but this remains a derisory share compared with the total quantity of CO 2 emitted.
Thus, technologies to facilitate the capture of massive CO 2 emissions from industries are currently being developed. They are listed in three main categories, named CO 2 capture processes:
In post-combustion, during which the CO 2 is separated from the other gases contained in the combustion products (flue gases);
In oxycombustion using pure oxygen to produce fumes composed solely of CO 2 and water vapor, easily separated by condensation ;
In pre-combustion, which consists in extracting CO 2 before combustion; to do this, the fuel is transformed into a mixture of H 2 and CO 2 , from which carbon dioxide is isolated, enabling hydrogen to achieve "decarbonized" combustion.
The "Chemical Looping" processes discussed in this article enable CO 2 to be captured in oxycombustion. The combustion carried out can be complete...
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KEYWORDS
combustion | CO2 capture | carbon compounds | oxygen carrier materials
"Chemical Looping
Chemical Looping" technology
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