A surface-renewal model of cross-flow microfiltration

A surface-renewal model of cross-flow microfiltration

A mathematical model using classical cake-filtration theory and the surface-renewal concept is formulated for describing cross-flow microfiltration under dynamic and steady-state conditions. The model can predict the permeate flux and cake buildup in the filter. The three basic parameters of the mod...

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Main Authors: A. Hasan, C. R. Peluso, T. S. Hull, J. Fieschko, S. G. Chatterjee
Format: Article
Language:English
Published: Brazilian Society of Chemical Engineering 2013-03-01
Series:Brazilian Journal of Chemical Engineering
Subjects:
Membrane filtration
Surface-renewal model
Critical-flux model
Microfiltration
Online Access:http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322013000100019
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spelling doaj-674b327d364649408e991f096bab6e0a2020-11-25T00:46:43ZengBrazilian Society of Chemical EngineeringBrazilian Journal of Chemical Engineering0104-66321678-43832013-03-01301167186A surface-renewal model of cross-flow microfiltrationA. HasanC. R. PelusoT. S. HullJ. FieschkoS. G. ChatterjeeA mathematical model using classical cake-filtration theory and the surface-renewal concept is formulated for describing cross-flow microfiltration under dynamic and steady-state conditions. The model can predict the permeate flux and cake buildup in the filter. The three basic parameters of the model are the membrane resistance, specific cake resistance and rate of surface renewal. The model is able to correlate experimental permeate flow rate data in the microfiltration of fermentation broths in laboratory- and pilot-scale units with an average root-mean-square (RMS) error of 4.6%. The experimental data are also compared against the critical-flux model of cross-flow microfiltration, which has average RMS errors of 6.3, 5.5 and 6.1% for the cases of cake filtration, intermediate blocking and complete blocking mechanisms, respectively.http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322013000100019Membrane filtrationSurface-renewal modelCritical-flux modelMicrofiltration
collection DOAJ
language English
format Article
sources DOAJ
author A. Hasan
C. R. Peluso
T. S. Hull
J. Fieschko
S. G. Chatterjee
spellingShingle A. Hasan
C. R. Peluso
T. S. Hull
J. Fieschko
S. G. Chatterjee
A surface-renewal model of cross-flow microfiltration
Brazilian Journal of Chemical Engineering
Membrane filtration
Surface-renewal model
Critical-flux model
Microfiltration
author_facet A. Hasan
C. R. Peluso
T. S. Hull
J. Fieschko
S. G. Chatterjee
author_sort A. Hasan
title A surface-renewal model of cross-flow microfiltration
title_short A surface-renewal model of cross-flow microfiltration
title_full A surface-renewal model of cross-flow microfiltration
title_fullStr A surface-renewal model of cross-flow microfiltration
title_full_unstemmed A surface-renewal model of cross-flow microfiltration
title_sort surface-renewal model of cross-flow microfiltration
publisher Brazilian Society of Chemical Engineering
series Brazilian Journal of Chemical Engineering
issn 0104-6632
1678-4383
publishDate 2013-03-01
description A mathematical model using classical cake-filtration theory and the surface-renewal concept is formulated for describing cross-flow microfiltration under dynamic and steady-state conditions. The model can predict the permeate flux and cake buildup in the filter. The three basic parameters of the model are the membrane resistance, specific cake resistance and rate of surface renewal. The model is able to correlate experimental permeate flow rate data in the microfiltration of fermentation broths in laboratory- and pilot-scale units with an average root-mean-square (RMS) error of 4.6%. The experimental data are also compared against the critical-flux model of cross-flow microfiltration, which has average RMS errors of 6.3, 5.5 and 6.1% for the cases of cake filtration, intermediate blocking and complete blocking mechanisms, respectively.
topic Membrane filtration
Surface-renewal model
Critical-flux model
Microfiltration
url http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0104-66322013000100019
work_keys_str_mv AT ahasan asurfacerenewalmodelofcrossflowmicrofiltration
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AT sgchatterjee asurfacerenewalmodelofcrossflowmicrofiltration
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