Experimental method for observing the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow: Creation of state diagram

Experimental method for observing the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow: Creation of state diagram

•A method for determining gaseous and aerosol H2SO4 in flue gas is developed.•A state diagram is created to reveal the fate of H2SO4 in a cooling flue gas flow.•Models for predicting acid dew-point are evaluated in virtue of the state diagram. The condensation behavior of sulfur trioxide/sulfuric ac...

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Veröffentlicht in:Fuel (Guildford) 2019-08, Vol.249, p.449-456
Hauptverfasser: Li, Yuzhong, Zhu, Qingwu, Yi, Qiujie, Zuo, Wujun, Feng, Yupeng, Chen, Shouyan, Dong, Yong
Format: Artikel
Sprache:eng
Schlagworte:
Acid dew point
Aerosols
Condensation
Dew point
Experimental methods
Flue gas
Gas flow
Gas temperature
Research methodology
Sodium
Sodium chloride
State (computer science)
State diagram
Sulfur
Sulfur trioxide
Sulfur trioxide (SO3)
Sulfuric acid
Sulfuric acid (H2SO4)
Sulfuric aerosol
Temperature effects
Wool
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container_end_page 456
container_issue
container_start_page 449
container_title Fuel (Guildford)
container_volume 249
creator Li, Yuzhong
Zhu, Qingwu
Yi, Qiujie
Zuo, Wujun
Feng, Yupeng
Chen, Shouyan
Dong, Yong
description •A method for determining gaseous and aerosol H2SO4 in flue gas is developed.•A state diagram is created to reveal the fate of H2SO4 in a cooling flue gas flow.•Models for predicting acid dew-point are evaluated in virtue of the state diagram. The condensation behavior of sulfur trioxide/sulfuric acid (SO3/H2SO4) in flue gas is closely related to corrosion, aerosol formation, and blue plume discharge. Thus, it has become a hot issue in energy and environmental fields. However, no accurate method is currently available to observe this condensation behavior. In this work, an experimental method was developed to explore the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow among the range of 260 °C–40 °C. A novel sampling unit with quartz wool and sodium chloride (NaCl) layer in series was adopted to accomplish the task of collecting aerosol and gaseous H2SO4, respectively, from flue gas. Bench scale experiments were performed to verify the reliability of the method. A state diagram was created according to the experimental results to reveal the fate evolution of H2SO4 as the flue gas temperature dropped. On the basis of the state diagram, the existing empirical models for predicting acid dew point (ADP) were evaluated. The predicted ADP values were found to deviate from the definition, falling within the temperature range in which H2SO4 condensed rapidly instead of the point in which H2SO4 was beginning to condense. The state diagram derived in this work can reveal slight acid condensation behavior better than other methods could.
doi_str_mv 10.1016/j.fuel.2019.03.130
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The condensation behavior of sulfur trioxide/sulfuric acid (SO3/H2SO4) in flue gas is closely related to corrosion, aerosol formation, and blue plume discharge. Thus, it has become a hot issue in energy and environmental fields. However, no accurate method is currently available to observe this condensation behavior. In this work, an experimental method was developed to explore the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow among the range of 260 °C–40 °C. A novel sampling unit with quartz wool and sodium chloride (NaCl) layer in series was adopted to accomplish the task of collecting aerosol and gaseous H2SO4, respectively, from flue gas. Bench scale experiments were performed to verify the reliability of the method. A state diagram was created according to the experimental results to reveal the fate evolution of H2SO4 as the flue gas temperature dropped. On the basis of the state diagram, the existing empirical models for predicting acid dew point (ADP) were evaluated. The predicted ADP values were found to deviate from the definition, falling within the temperature range in which H2SO4 condensed rapidly instead of the point in which H2SO4 was beginning to condense. 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The condensation behavior of sulfur trioxide/sulfuric acid (SO3/H2SO4) in flue gas is closely related to corrosion, aerosol formation, and blue plume discharge. Thus, it has become a hot issue in energy and environmental fields. However, no accurate method is currently available to observe this condensation behavior. In this work, an experimental method was developed to explore the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow among the range of 260 °C–40 °C. A novel sampling unit with quartz wool and sodium chloride (NaCl) layer in series was adopted to accomplish the task of collecting aerosol and gaseous H2SO4, respectively, from flue gas. Bench scale experiments were performed to verify the reliability of the method. A state diagram was created according to the experimental results to reveal the fate evolution of H2SO4 as the flue gas temperature dropped. On the basis of the state diagram, the existing empirical models for predicting acid dew point (ADP) were evaluated. The predicted ADP values were found to deviate from the definition, falling within the temperature range in which H2SO4 condensed rapidly instead of the point in which H2SO4 was beginning to condense. The state diagram derived in this work can reveal slight acid condensation behavior better than other methods could.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.fuel.2019.03.130</doi><tpages>8</tpages><orcidid>https://orcid.org/0000-0002-2554-0631</orcidid></addata></record>
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subjects Acid dew point
Aerosols
Condensation
Dew point
Experimental methods
Flue gas
Gas flow
Gas temperature
Research methodology
Sodium
Sodium chloride
State (computer science)
State diagram
Sulfur
Sulfur trioxide
Sulfur trioxide (SO3)
Sulfuric acid
Sulfuric acid (H2SO4)
Sulfuric aerosol
Temperature effects
Wool
title Experimental method for observing the fate of SO3/H2SO4 in a temperature-decreasing flue gas flow: Creation of state diagram
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