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Korean Journal of Chemical Engineering,
Vol.21, No.4, 793-800, 2004
Vol.21, No.4, 793-800, 2004
Temperature Profiles of the Monolith Catalyst in CO2 Reforming of Methane with in-situ Combustion of Methane and Ethane
The temperature profiles in a monolith reactor were measured in CO2 reforming of CH4 with in-situ combustion of methane and ethane in order to find out in what sequence the reactions are occurring. The reaction gas flowed both upward and downward. A hot spot was observed at low furnace temperatures, and it tended to disappear as the furnace temperature increased. This is due to natural extinguishment of the flame caused by the endothermic reforming reactions occurring. The hot spot disappeared at a lower temperature with the up-flow when compared with the down-flow. When the hot spot appears, H2O and CO2 are produced by complete oxidation and accordingly the steam reforming and the CO2 reforming occur competitively in the rear part of the monolith. If the hot spot does not appear, it is considered that the partial oxidation of methane occurs predominantly over the complete oxidation, resulting in more efficient CO2 removal.
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[Cited By]
- Sohrabi M, Moradi F, Sanati M, Korean Journal of Chemical Engineering, 24(4), 583, 2007
- Yanbing L, Baosheng J, Rui X, Korean Journal of Chemical Engineering, 24(4), 688, 2007
- Seo JG, Youn MH, Cho KM, Park S, Lee SH, Lee J, Song IK, Korean Journal of Chemical Engineering, 25(1), 41, 2008
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- Youn MH, Seo JG, Cho KM, Jung JC, Kim H, La KW, Park DR, Park S, Lee SH, Song IK, Korean Journal of Chemical Engineering, 25(2), 236, 2008
- Asadi-Saghandi H, Karimi-Sabet J, Korean Journal of Chemical Engineering, 34(7), 1905, 2017
- Kim JH, Jang YS, Kim JC, Kim DH, Korean Journal of Chemical Engineering, 36(3), 368, 2019
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