Effect of steam on the barium sulfate reduction by methane

•Steam can oxidize the deposited carbon generated by thermal decomposition of methane.•The effect of operational parameters on the reduction by methane was investigated.•The effect of impurity on the reaction using barite ore and natural gas was investigated.•The intrinsic kinetic parameters were ob...

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Bibliographic Details
Published in:Thermochimica acta 2023-12, Vol.730, p.179610, Article 179610
Main Authors: Rostamizadeh, M. Ali, Afsahi, M. Mehdi, Mousavi, Mehdi
Format: Article
Language:English
Subjects:
activation energy
Barium sulfate
carbon
Methane
Reaction kinetics
Reduction
Shrinking core model
Steam
temperature
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Summary:•Steam can oxidize the deposited carbon generated by thermal decomposition of methane.•The effect of operational parameters on the reduction by methane was investigated.•The effect of impurity on the reaction using barite ore and natural gas was investigated.•The intrinsic kinetic parameters were obtained using the shrinking unreacted core model.•At high temperatures and methane concentrations, steam enhanced the reduction rate. Methane gas decomposes at high temperatures and produces carbon as a result. The deposited carbon causes problems during the process. In this study, the reduction of barium sulfate powder using methane was studied and steam was used to remove the carbon produced during the reaction. The effect of temperature and methane concentration on the reaction rate was investigated at two different conditions, using 20 vol % steam and without steam at operating temperatures in the range 850–1000 °C. When steam was used, methane concentration was selected in the range 19–40 vol %, while it was 21–78 % in the absence of steam. The experimental data was interpreted using the "shrinking unreacted core model" and intrinsic kinetic parameters of the reactions were determined. The reaction order and activation energy were calculated to be 1 and 145.5 kJ/mol in the absence of steam and 1.5 and 179.6 kJ/mol in its presence, respectively. From the obtained rate equations, it was found that the reaction rate without steam was always faster than the reaction rate in the presence of steam.
ISSN:0040-6031
1872-762X
DOI:10.1016/j.tca.2023.179610