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http://dx.doi.org/10.7316/KHNES.2015.26.5.445

Simulation for Possible Coke-Free Operation of a Packed Catalyst Bed Reactor in the Steam-CO2 Reforming of Natural Gas  

LEE, DEUK KI (Dept. of Fire Safety, Gwangju University)
LEE, SANG SOO (Dept. of Civil Engineering, Gwangju University)
SEO, DONG JOO (Hydrogen and Fuel Cell Department, Korea Institute of Energy Research)
YOON, WANG LAI (Hydrogen and Fuel Cell Department, Korea Institute of Energy Research)
Publication Information
Transactions of the Korean hydrogen and new energy society / v.26, no.5, 2015 , pp. 445-452 More about this Journal
Abstract
A tubular packed bed reactor for the steam-$CO_2$ combined reforming of natural gas to produce the synthesis gas of a target $H_2/CO$ ratio 2.0 was simulated. The effects of the reactor dimension, the feed gas composition, and the gas feeding temperature upon the possibility of coke formation across the catalyst bed were investigated. For this purpose, 2-dimensional heterogeneous reactor model was used to determine the local gas concentrations and temperatures over the catalyst bed. The thermodynamic potential distribution of coke formation was determined by comparing the extent of reaction with the equilibrium constant given by the reaction, $CH_4+2CO{\Leftrightarrow}3C+2H_2O$. The simulation showed that catalysts packed in the central region nearer the entrance of the reactor were more prone to coking because of the regional characteristics of lower temperature, lower concentration of $H_2O$, and higher concentration of CO. With the higher feeding temperature, the feed gas composition of the increased $H_2O$ and correspondingly decreased $CO_2$, or the decrease in the reactor diameter, the volume fraction of the catalyst bed subsequent to coking could be diminished. Throughout the simulation, reactor dimension and reaction condition for coking-free operation were suggested.
Keywords
Simulation; Coking; Steam-$CO_2$ reforming; Synthesis gas; Coke-free operation;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
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