Steam Enhanced Calcination for CO2 Capture with CaO

Champagne, Scott

16 April 2014

Carbon capture and storage technologies are necessary to start lowering greenhouse gas emissions while continuing to utilize existing thermal power generation infrastructure. Calcium looping is a promising technology based on cyclic calcination/carbonation reactions which utilizes limestone as a sorbent. Steam is present in combustion flue gas and in the calciner used for sorbent regeneration. The effect of steam during calcination on sorbent performance has not been extensively studied in the literature. Here, experiments were conducted using a thermogravimetric analyzer (TGA) and subsequently a dual-fluidized bed pilot plant to determine the effect of steam injection during calcination on sorbent reactivity during carbonation. In a TGA, various levels of steam (0-40% vol.) were injected during sorbent regeneration throughout 15 calcination/carbonation cycles. All concentrations of steam were found to increase sorbent reactivity during carbonation. A level of 15% steam during calcination had the largest impact. Steam changes the morphology of the sorbent during calcination, likely by shifting the pore volume to larger pores, resulting in a structure which has an increased carrying capacity. This effect was then examined at the pilot scale to determine if the phase contacting patterns and solids heat-up rates in a fluidized bed were factors. Three levels of steam (0%, 15%, 65%) were injected during sorbent regeneration throughout 5 hours of steady state operation. Again, all levels of steam were found to increase sorbent reactivity and reduce the required sorbent make-up rate with the best performance seen at 65% steam.

Calcium Looping

Carbon Capture and Storage

Fluidized Bed

Oxy-fuel Combustion

Greenhouse Gas Control

Solid-Gas Reaction

Fluidized Bed Combustion

Steam Enhanced Calcination for CO2 Capture with CaO

Champagne, Scott

January 2014

Carbon capture and storage technologies are necessary to start lowering greenhouse gas emissions while continuing to utilize existing thermal power generation infrastructure. Calcium looping is a promising technology based on cyclic calcination/carbonation reactions which utilizes limestone as a sorbent. Steam is present in combustion flue gas and in the calciner used for sorbent regeneration. The effect of steam during calcination on sorbent performance has not been extensively studied in the literature. Here, experiments were conducted using a thermogravimetric analyzer (TGA) and subsequently a dual-fluidized bed pilot plant to determine the effect of steam injection during calcination on sorbent reactivity during carbonation. In a TGA, various levels of steam (0-40% vol.) were injected during sorbent regeneration throughout 15 calcination/carbonation cycles. All concentrations of steam were found to increase sorbent reactivity during carbonation. A level of 15% steam during calcination had the largest impact. Steam changes the morphology of the sorbent during calcination, likely by shifting the pore volume to larger pores, resulting in a structure which has an increased carrying capacity. This effect was then examined at the pilot scale to determine if the phase contacting patterns and solids heat-up rates in a fluidized bed were factors. Three levels of steam (0%, 15%, 65%) were injected during sorbent regeneration throughout 5 hours of steady state operation. Again, all levels of steam were found to increase sorbent reactivity and reduce the required sorbent make-up rate with the best performance seen at 65% steam.

Calcium Looping

Carbon Capture and Storage

Fluidized Bed

Oxy-fuel Combustion

Greenhouse Gas Control

Solid-Gas Reaction

Fluidized Bed Combustion

The Politics of Researching Carbon Trading in Australia

Spash, Clive L.

January 2014

This paper explores the conflicts of interest present in science policy and how claims being made for evidence based science can be used to suppress critical social science research. The specific case presented concerns the attempts to ban and censor my work criticising the economics of carbon emissions trading while I was working for the Commonwealth Scientific Industrial Research Organisation (CSIRO) in Australia. The role of management and the Science Minister are documented through their own public statements. The case raises general issues about the role of epistemic communities in the production of knowledge, the potential for manipulation of information under the guise of quality control and the problems created by claiming a fact-value dichotomy in the science-policy interface. The implications go well beyond just climate change research and challenge how public policy is being formulated in modern industrial societies where scientific knowledge and corporate interests are closely intertwined. (author's abstract) / Series: SRE - Discussion Papers