Field measurements of NO<sub>x</sub> and mercury from oxy-fuel compression condensates at the Callide Oxyfuel Project

Stanger, Rohan; Ting, Timothy; Belo, Lawrence; Spero, Chris; Wall, Terry

Title: Field measurements of NO_x and mercury from oxy-fuel compression condensates at the Callide Oxyfuel Project
Creator: Stanger, Rohan; Ting, Timothy; Belo, Lawrence; Spero, Chris; Wall, Terry
Relation: International Journal of Greenhouse Gas Control Vol. 42, p. 485-493
Publisher Link: http://dx.doi.org/10.1016/j.ijggc.2015.08.021
Publisher: Elsevier
Resource Type: journal article
Date: 2015
Description: The Callide Oxyfuel Project (COP) is the world's largest operating oxy-fuel plant and has successfully demonstrated the retrofitting capability for oxy-fuel to capture CO₂. The compression of the raw flue gas at the COP has also demonstrated that NO_x and Hg can also be removed as part of the liquid condensate. This work presents field tests conducted on the condensates to determine the stability of captured NO_x and Hg species when depressurised. These tests involved sampling liquid condensate directly into a customised aeration vessel and measuring the evolved gases over an 8–12 h period. The low-pressure condensate (∼4 bar) showed that 3–18% of captured NO_x species and 0.5–1.2% of the Hg were volatile, while the high-pressure condensate (24 bar) re-emitted 2–68% of captured NO_x and 0.05–12.5% of the captured Hg. These tests showed that volatile Hg was related to volatile NO_x and that this volatility of condensates changed with time as the compression plant operated from start-up. Equilibrium calculations of HNO₂ in the gas and liquid phases supported the volatility measurements, suggesting that the rate of oxidation of HNO₂ to HNO₃ in the condensed phase is slow. Overall, the conditions which favoured NO_x stability in the condensates, namely longer residence and higher pressure also favoured Hg stability. This work has shown that emissions from an oxy-fuel compression plant must include those emanating from depressurised condensates and suggest that the re-emitted species may not the same as in typical combustion flue gas, but the result of higher-pressure conversion.
Subject: oxyfuel; flue gas; compression; NO<sub>x</sub>; mercury
Identifier: http://hdl.handle.net/1959.13/1314278
Identifier: uon:22742
Identifier: ISSN:1750-5836
Language: eng
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Field measurements of NOx and mercury from oxy-fuel compression condensates at the Callide Oxyfuel Project

Field measurements of NO_x and mercury from oxy-fuel compression condensates at the Callide Oxyfuel Project