Axial Distribution of Oxygen Concentration in Different Airlift Bioreactor Scales: Mathematical Modeling and Simulation

Axial Distribution of Oxygen Concentration in Different Airlift Bioreactor Scales: Mathematical Modeling and Simulation

Steady and unsteady state oxygen concentration distributions in the liquid and gas phases along the axial direction of different airlift bioreactor scales have been simulated for various gas flow rates and oxygen consumption rates by applying the axial dispersion model to the riser and the downcomer...

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Bibliographic Details
Published in:Chemical engineering & technology Vol. 29; no. 9; pp. 1042 - 1047
Main Authors: Znad, H., Tokumura, M., Kawase, Y.
Format: Journal Article Conference Proceeding
Language:English
Published: Weinheim WILEY-VCH Verlag 01-09-2006
WILEY‐VCH Verlag
Wiley-VCH
Subjects:
Airlift
Applied sciences
Biological and medical sciences
Bioreactors
Biotechnology
Chemical engineering
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
Heat and mass transfer. Packings, plates
Methods. Procedures. Technologies
Modeling
Others
Reactors
Reactors, Airlift
Various methods and equipments
Airlift reactor
Mixing
Scale effect
Saturation
Unsteady state
Axial mixing
Modeling
Mass transfer
Overflow
Extrapolation
Bioreactor
Dissolved oxygen
Riser
Separator
Concentration distribution
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Summary:Steady and unsteady state oxygen concentration distributions in the liquid and gas phases along the axial direction of different airlift bioreactor scales have been simulated for various gas flow rates and oxygen consumption rates by applying the axial dispersion model to the riser and the downcomer, and a complete mixing model for the top (separator) and the bottom sections of the bioreactor. The results show that the dissolved oxygen concentration is very low at the lower part of the downcomer when the rate of oxygen consumption by microorganisms is very high. Furthermore, the shorter (small) bioreactor shows relatively more uniform axial dissolved oxygen concentrations than the longer (large) bioreactor, due to the effect of the hydrostatic pressure along the bioreactor. One of the most important geometric factors for mass transfer is the reactor height, which dominates the mean pressure and thus influences the saturation concentration and mass transfer driving force. The presented model can be applied for modeling and scale‐up of practical airlift bioreactors. Steady and unsteady state oxygen concentration distributions along the axial direction of different airlift bioreactors have been simulated by applying the axial dispersion model to the riser and the downcomer and complete the mixing model for the top and the bottom sections of the bioreactor.
Bibliography:ArticleID:CEAT200600146
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ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0930-7516
1521-4125
DOI:10.1002/ceat.200600146