Fluidized Bed Combustion with Integrated Carbon Dioxide Capture

The connection between increasing atmospheric CO2 concentrations and climate change is now recognized by a number of international organizations including the United Nations Fran1ework Convention on Climate Change (UNFCCC), the Intergovernmental Panel on Climate Change (White et al, 2003), and the European Union FP6 Framework. The research described in this thesis brings two carbon dioxide capture technologies from concept through to bench scale testing, simulation, and demonstration at pilot scale.;It is shown that high CO2 concentration 10 the calciner is highly detrin1ental to the performance of the sorbent Hydration of the sorbent can greatly improve the capacity of the sorbent when relatively low CO 2 concentrations are present, however, when CO2 concentration is high there is little difference between untreated and hydrated sorbent capacity after 20 cycles. Steam hydration together with pelletization of limestone was used to improve sorbent utilization for in-situ CO 2 capture under operating conditions typical of fluidized bed combustion. The pelletized particles in general showed good performance, comparable to or better than hydrated san1ples.;Attrition of the sorbents has been greater than expected for some of the limestones. The results suggest that multiple carbonation/calcination cycles result in severe attrition during the first one or two calcination periods. Afterwards, the particles attrite at rates similar to what would be expected from a bed of particles continuously subjected to similar forces over an extended period of time. In limestones where material loss is a problem, however, it is clear that partial sulphation can dramatically reduce this loss, albeit with the risk of reduction of CO2 carrying capacity or CaO-CaCO3 looping cycle reversibility.;Sorbent capacity was significantly lower than expected based on previous thermogravimetric analyses. A thin, non-porous shell was formed around the sorbent particles under some of the test conditions at the pilot scale. The causes for the formation of this shell must be verified prior to investing substantially in this technology as the shell greatly reduces the capacity of the sorbent. The fact that the shell was not formed in all tests provides hope that a suitable set of conditions can be found for operation where the shell does not hinder sorbent performance.;Facilities for demonstrating and investigating oxy-fuel circulating fluidized bed combustion with recycled flue gas and and calcium-based sorbent looping cycles are developed and described. The facilities were commissioned with coal and biomass.;The calcium-based sorbent looping cycle process has been demonstrated using the CANMET 75 kWth pilot-scale dual fluidized bed facility and more than 50 hrs operating experience in total has been accumulated. Havelock limestone from eastern Canada was used as the CO2 sorbent, while a synthesis gas mixture of air and CO2 (15%) was employed to simulate combustion flue gas. A high CO2 capture efficiency (> 95%) was achieved for the first several cycles, which decreased to a lower level (> 72%) after more than 25 cycles. Oxy-fuel combustion of biomass and coal was employed in the sorbent regeneration step, in which pure O2 was mixed with recycled flue gas and this, along with the excellent heat transfer characteristics of CFBs, allowed the use of an O2 concentration of 40 vol% in the combustion gas.