Abstract

Abstract Oxy-fuel combustion of fossil fuels produces a CO 2 -rich gas stream with some impurities, such as nitrogen, argon, oxygen, nitrogen oxides, heavy metals and sulphur oxides, whose concentrations vary based on the type of fuel, combustion conditions, plant configuration, and other process related parameters. To control the greenhouse gas (GHG) emissions from these plants and sustain their operational competitiveness in a carbon constrained world, the CO 2 in the flue gas stream has to be captured, cleaned up and compressed to make it suitable for pipeline transport and permanent storage in geological formations. The flue gas CO 2 capture and processing, including integrated multi-pollutant control, provides a feasible and viable technological pathway towards this goal. For oxy-fuel combustion systems, the CO 2 capture is best achieved by physical gas separation through a series of compression and cooling stages to liquefy and separate CO 2 from non-condensable gases in the flue gas stream. The effectiveness of the CO 2 capture and compression system depends on the process design and assessed using removal efficiency, level of purification and energy demand for a unit of captured CO 2 . If the CO 2 capture process can also simultaneously remove other pollutants in the gas stream, then the whole process becomes more efficient and cost-effective. In this case, implementing an elaborate flue gas pre-treatment system will not be necessary. Hence, CO 2 capture technologies that are capable of simultaneously controlling emissions of multiple pollutants offer the potential to achieve emissions reduction at lower cost and reduced footprint, when compared to conventional emission control systems. For the new oxy-coal fired power plants, multi-pollutant control technologies can help designers of these plants select effective and less expensive compliance strategies, compared with compliance choices made when the requirements are addressed individually. CanmetENERGY has developed and successfully implemented an advanced and proprietary CO 2 capture and compression unit (CO 2 CCU) that is capable of capturing and generating a relatively pure CO 2 product stream, while simultaneously removing the pollutants such as nitrogen oxides, sulphur oxides and mercury in the process condensate streams. The pilot-scale unit is currently integrated with the existing 0.3 MWth oxy-fuel Vertical Combustor Research Facility. This advanced CO 2 capture system represents an integrated approach to oxy-fuel combustion with multi-pollutant and CO 2 capture and provides a unique test platform for CO 2 processing. In this paper, we present and discuss the recent pilot-scale test results of CanmetENERGY’s CO 2 CCU. The unit was used to conduct experiments with a broad range of flue gas compositions, including different levels of CO 2 concentrations and a host of impurities in the flue gas stream. The real-time measurements of CO 2 product and vent stream gas compositions as well as the analysis of condensate streams provide insight into the type of chemical reactions that are taking place under different pressure, temperature, and moisture levels. The experimental results help to explain some of the chemical reactions involved in the CO 2 capture and compression for better optimizing the capture process.

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