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Experimental and modelling approach to the design of chemical absorption columns with fast gas-liquid reaction: A case-study on flue-gas desulfurization with H2O2 oxidative solutions.

Authors :
Flagiello, D.
Di Natale, F.
Lancia, A.
Sebastiani, I.
Nava, F.
Milicia, A.
Erto, A.
Source :
Chemical Engineering Research & Design: Transactions of the Institution of Chemical Engineers Part A. Jun2023, Vol. 194, p425-438. 14p.
Publication Year :
2023

Abstract

In this work, we propose a methodology to approach the design of chemical absorption columns with fast gas-liquid reactions by an experimental and modelling study, which accounts for thermodynamic (solubility) data, mass-transfer phenomena, and the reaction kinetics contribution. As a reference case, the SO 2 absorption in aqueous solution of H 2 O 2 at different concentrations, which oxidizes SO 2 to sulfuric acid, is considered. A lab-scale fed-batch bubble column is used to evaluate SO 2 solubility dataset in absorbing solutions of distilled water containing different dosages of H 2 O 2. A thermodynamic model is developed and validated in a Thermodynamic Flash block of ASPEN PLUS®, allowing to describe the experimental results with optimum agreement. For kinetic experiments, a lab-scale falling-film absorber is used to investigate both SO 2 mass-transfer rates and the fundamental kinetic aspects of an absorption process with chemical reaction. The physical contribution to the mass-transfer rate is evaluated through a set of dedicated experiments, which allowed determining gas-side (k G a) and liquid-side (k L a) coefficients in the falling-film absorber. Subsequently, the Enhancement factor (E L) of the SO 2 oxidative absorption is evaluated for the oxidizing reaction (SO 2 + H 2 O 2 → H 2 SO 4) under the explored experimental conditions, using the equilibrium dataset and the mass transfer coefficients previously obtained. Finally, E L is correlated to the Hatta number (Ha) with the Danckwerts kinetic model as a pseudo-mth-nth-order non-reversible reaction type and the model kinetic parameters are calculated. • This work provides an experimental and modelling approach to the design of reactive absorption columns. • The thermodynamic model developed in ASPEN PLUS provides a proper estimation of the SO 2 -H 2 O 2 solubility dataset. • The kinetic experiments allowed assessment of the reaction kinetic parameters in the gas absorption of SO 2 into H 2 O 2. • The kinetic model based on the Danckwerts equation provides a proper estimation of the Enhancement factors. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
02638762
Volume :
194
Database :
Academic Search Index
Journal :
Chemical Engineering Research & Design: Transactions of the Institution of Chemical Engineers Part A
Publication Type :
Academic Journal
Accession number :
164348090
Full Text :
https://doi.org/10.1016/j.cherd.2023.04.040