Deactivation Kinetics Model of H2S Removal over Mesoporous LaFeO3/MCM-41 Sorbent during Hot Coal Gas Desulfurization

Deactivation Kinetics Model of H2S Removal over Mesoporous LaFeO3/MCM-41 Sorbent during Hot Coal Gas Desulfurization

The improved deactivation kinetic model over mesoporous LaFeO3/MCM-41 sorbents for hot coal gas desulfurization was established with mass-transfer correlation based on elementary stoichiometric equation, which consisted of both the spatial and the time partial differential equations. MATLAB software...

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Bibliographic Details
Published in:Energy & fuels Vol. 28; no. 9; pp. 6012 - 6018
Main Authors: Hong, Yong Son, Zhang, Z. F, Cai, Z. P, Zhao, X. H, Liu, B. S
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 18-09-2014
Subjects:
Applied sciences
Energy
Energy. Thermal use of fuels
Exact sciences and technology
Fuels
Desulfurization
Kinetic model
Coal gas
Deactivation
Hot gas
Sorbent
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Summary:The improved deactivation kinetic model over mesoporous LaFeO3/MCM-41 sorbents for hot coal gas desulfurization was established with mass-transfer correlation based on elementary stoichiometric equation, which consisted of both the spatial and the time partial differential equations. MATLAB software was used to solve partial differential equations by means of forward finite differential method and to estimate kinetic parameters via nonlinear least-squares fitting. The rate constants k a and k d were obtained via aforementioned kinetic model over different LaFeO3/MCM-41 sorbents. The calculated results were in accordance with experimental data under various operating conditions. The kinetic model can be used successfully to predict the distributions of H2S concentration at different times and spatial positions within fixed-bed layers, compared to unreacted shrinking core model, random pore model, or grain model. It is of very great significance to obtain basical chemical engineering data for the design of new reactor. For 50%LF2/MCM-41 sorbent, the calculated apparent activation energy (E a) and deactivation energy (E d) for chemical reaction of LaFeO3 active sites are 32.1 and 15.1 kJ·mol–1, respectively, based on the experimental data of desulfurization process.
ISSN:0887-0624
1520-5029
DOI:10.1021/ef5008825