CO₂ quality control through scrubbing in oxy-fuel combustion: rate limitation due to S(IV) oxidation in sodium solutions in scrubbers and prior to waste disposal

Liu, Dunyu; Wall, Terry; Stanger, Rohan

Title: CO₂ quality control through scrubbing in oxy-fuel combustion: rate limitation due to S(IV) oxidation in sodium solutions in scrubbers and prior to waste disposal
Creator: Liu, Dunyu; Wall, Terry; Stanger, Rohan
Relation: International Journal of Greenhouse Gas Control Vol. 39, Issue August 2015, p. 148-157
Publisher Link: http://dx.doi.org/10.1016/j.ijggc.2015.05.015
Publisher: Elsevier
Resource Type: journal article
Date: 2015
Description: Oxy-fuel combustion is a promising CCS technology which is being demonstrated prior to commercialization. While the flue gas in oxy-fuel combustion is concentrated in CO₂, it contains impurities such as SO₂. The reduction of SO₂ prior to compression by a scrubber is a common feature of oxy-fuel systems. These scrubbers use sodium solutions. The products of the sodium-based scrubber after capture of SO₂ contain Na₂SO₃ and NaHSO₃. In the presence of O₂ in the gas phase, sulphur related species (i.e., SO₃²⁻ and HSO₃⁻) in liquid phase will be irreversibly oxidized to sulphate. These sulphur related species are noted as S(IV). The oxidation of S(IV) could vary along the height of a spray tower due to changes in pH. The study of the S(IV) oxidation rate at different pH is helpful in evaluating the oxidation extent of S(IV) and understanding the impacts of S(IV) on the absorption rate of SO₂. Both the heterogeneous oxidation and the homogeneous oxidation of S(IV) were studied here using two types of experimental reactors (Gas liquid reactor and liquid reactor). Heterogeneous experiments were conducted in the gas liquid reactor. In experiments, liquid phase pH and exit SO₂ were recorded continuously. Liquids were also taken for sulphate analysis after certain time period (30–60 min). For homogenous experiments, pH was monitored continuously and dissolved oxygen (DO) levels were manually recorded. For the heterogeneous oxidation, the oxidation of S(IV) results in reduction in pH, at pH 5.48, SO₂ starts to be desorbed. With this reduction in pH, the oxidation rate of S(IV) changes accordingly. The oxidation of 0.01 M S(IV) stays stable at pH > 5.48. The oxidation rate of S(IV) drops by 44.5% at pH < 5.48. For the homogeneous oxidation, there are three regions of oxidation rate. In region 1 (i.e., pH > 5.6), the oxidation rate of S(IV) does not change with pH; in region 2 (i.e., 4.53 < pH < 5.6), the oxidation rate of S(IV) decreases dramatically with the decrease in pH. The oxidation rate of S(IV) at pH 4.53 is two magnitudes lower than the rate at the pH 5.6. In region 3 (i.e., pH < 4.53), the oxidation rate of S(IV) does not seem to change. The oxidation of S(IV) is presumably due to the oxidation of SO₃²⁻. Results have implications on the disposal of waste sodium solutions after absorption. The oxidation of S(IV) in discharged solutions results in a final pH of about 4 which may be neutralized to form Na₂SO₃ prior to disposal.
Subject: oxy-fuel combustion; S(IV) oxidation; scrubber; waste disposal
Identifier: http://hdl.handle.net/1959.13/1314771
Identifier: uon:22821
Identifier: ISSN:1750-5836
Language: eng
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