Current advances and future prospects of in-situ desulfurization processes in oxy-fuel combustion reactors

Eun Sol Go, Lih Jie Jester Ling, Bhanupratap S. Solanki, Hyungwoong Ahn, Pau Loke Show, See Hoon Lee*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

Oxy-fuel circulating fluidized bed combustion is known as one of the most potent fuel combustion technologies that capture ultra-low greenhouse gases and pollutant emissions. While many investigations have been conducted for carbon capturing, the associated in-situ desulfurization process using calcium-based sorbents should also be underlined. This paper critically reviews the effects of changes in the operating environment on in-situ desulfurization processes compared to conventional air combustion. A comprehensive understanding of the process, encompassing hydrodynamic, physical and chemical aspects can be a guideline for designing the oxy-fuel combustion process with effective sulfur removal, potentially eliminating the need of a flue gas desulfurization unit. Results from thermogravimetric analyzers and morphological changes of calcium-based materials were presented to offer an insight into the sulfation mechanisms involved in the oxy-fuel circulating fluidized beds. Recently findings suggested that in-situ direct desulfurization is influenced not only by the desulfurization kinetics but also by the fluidization characteristics of calcium-based materials. Therefore, a complex reaction analysis that incorporated oxy-combustion reactions, computational fluid dynamics modeling, in-situ desulfurization reaction models and particle behavior can provide a thorough understanding of desulfurization processes across the reactor. Meanwhile, machine learning as a robust tool to predict desulfurization efficiency and improve operational flexibility should be applied with consideration of environmental improvement and economic feasibility.
Original languageEnglish
Article number119982
JournalEnvironmental Research
Early online date11 Sept 2024
DOIs
Publication statusE-pub ahead of print - 11 Sept 2024

Keywords / Materials (for Non-textual outputs)

  • Oxy-fuel combustion
  • Circulating fluidized bed
  • Limestone
  • In-situ desulfurization
  • Computational fluid dynamics

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