Design and modeling of large-scale cross-current multichannel Fischer-Tropsch reactor using channel decomposition and cell-coupling method. Park, S., Jung, I., Lee, U., Na, J., Kshetrimayum, K., S., Lee, Y., Lee, C., & Han, C. Chemical Engineering Science, 2015.
doi  abstract   bibtex   
© 2015. Design and modeling of a micro channel Fischer-Tropsch reactor was considered in this study. A cross-current heat-exchange reactor was modeled using a new method, in which all the process and cooling channels are decomposed into a number of unit cells. Each neighboring process and cooling channel unit cells are coupled to set up material and energy balance equations, including heat-transfer equations for the entire reactor domain, which are then solved simultaneously. The model results were compared with the experimental data for a pilot-scale reactor described in the literature, and were found to be in good agreement. Several case studies were performed to see the effect of variables such as catalyst loading ratio, coolant flow rate, and channel layout on design of a reactor with state-of-the-art Fischer-Tropsch catalyst. The developed model could handle more than 5800 process channels, 7500 cooling channels, and 130 layers, with implementation of six complex reaction kinetics.
@article{
 title = {Design and modeling of large-scale cross-current multichannel Fischer-Tropsch reactor using channel decomposition and cell-coupling method},
 type = {article},
 year = {2015},
 keywords = {Distributed parameter model,Fischer-Tropsch,Gas-to-liquid process,Micro channel reactor,Reactor design},
 volume = {134},
 id = {43924bd5-68af-3799-a8a3-5f5fbc97dbda},
 created = {2021-03-23T08:23:13.805Z},
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 last_modified = {2021-03-23T08:50:12.999Z},
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 abstract = {© 2015. Design and modeling of a micro channel Fischer-Tropsch reactor was considered in this study. A cross-current heat-exchange reactor was modeled using a new method, in which all the process and cooling channels are decomposed into a number of unit cells. Each neighboring process and cooling channel unit cells are coupled to set up material and energy balance equations, including heat-transfer equations for the entire reactor domain, which are then solved simultaneously. The model results were compared with the experimental data for a pilot-scale reactor described in the literature, and were found to be in good agreement. Several case studies were performed to see the effect of variables such as catalyst loading ratio, coolant flow rate, and channel layout on design of a reactor with state-of-the-art Fischer-Tropsch catalyst. The developed model could handle more than 5800 process channels, 7500 cooling channels, and 130 layers, with implementation of six complex reaction kinetics.},
 bibtype = {article},
 author = {Park, S and Jung, I and Lee, U and Na, J and Kshetrimayum, K S and Lee, Y and Lee, C.-J. and Han, C},
 doi = {10.1016/j.ces.2015.05.057},
 journal = {Chemical Engineering Science}
}
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