Residence Time Distribution Studies in Microfluidic Mixing Structures

The residence time distribution (RTD) characteristics of three microreactors containing different passive mixing structures, namely, a three dimensional serpentine structure, a split‐and‐recombine structure and a staggered herringbone structure, were investigated and compared. An experimental input‐...

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Bibliographic Details
Published in:Chemical engineering & technology 2011-03, Vol.34 (3), p.361-370
Main Authors: Bošković, D., Loebbecke, S., Gross, G. A., Koehler, J. M.
Format: Article
Language:English
Subjects:
Applied sciences
Chemical engineering
Exact sciences and technology
Microreactors
Mixing
Modeling
Reactors
Residence time distribution
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Summary:The residence time distribution (RTD) characteristics of three microreactors containing different passive mixing structures, namely, a three dimensional serpentine structure, a split‐and‐recombine structure and a staggered herringbone structure, were investigated and compared. An experimental input‐response technique was applied which required deconvolution of the measured data by modeling of the RTD. The proposed technique provides useful information on optimized application and operation of microfluidic devices. The serpentine reactor and the split‐and‐recombine reactor show improvement in RTD behaviour, i.e., narrowing of RTD curves, at Re‐numbers > 30 due to effective transversal mixing and therefore reduced axial dispersion. In the case of the staggered herringbone structure, dead volumes could be observed which considerably affect the RTD. The residence time distribution characteristics of three microreactors containing different passive mixing structures were investigated by an experimental input‐response technique. The proposed technique provides useful information on axial dispersion for optimized application and operation of microfluidic devices in an appropriate flow range.
ISSN:0930-7516
1521-4125
DOI:10.1002/ceat.201000352