On the design and simulation of an airlift loop bioreactor with microbubble generation by fluidic oscillation

Microbubble generation by a novel fluidic oscillator driven approach is analyzed, with a view to identifying the key design elements and their differences from standard approaches to airlift loop bioreactor design. The microbubble generation mechanism has been shown to achieve high mass transfer rat...

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Veröffentlicht in:	Food and bioproducts processing 2009-09, Vol.87 (3), p.215-227
Hauptverfasser:	Zimmerman, William B., Hewakandamby, Buddhika N., Tesař, Václav, Bandulasena, H.C. Hemaka, Omotowa, Olumuyiwa A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Airlift loop bioreactor airlift loop bioreactors bioreactors Biorefineries bubbles diameter energy efficiency energy use and consumption equipment design Fluidic oscillators friction gas distribution system hydrodynamics literature reviews mass transfer Microbubble generation microbubbles nozzles optimization oscillation simulation models temperature Transport phenomena
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creator	Zimmerman, William B. Hewakandamby, Buddhika N. Tesař, Václav Bandulasena, H.C. Hemaka Omotowa, Olumuyiwa A.
description	Microbubble generation by a novel fluidic oscillator driven approach is analyzed, with a view to identifying the key design elements and their differences from standard approaches to airlift loop bioreactor design. The microbubble generation mechanism has been shown to achieve high mass transfer rates by the decrease of the bubble diameter, by hydrodynamic stabilization that avoids coalescence increasing the bubble diameter, and by longer residence times offsetting slower convection. The fluidic oscillator approach also decreases the friction losses in pipe networks and in nozzles/diffusers due to boundary layer disruption, so there is actually an energetic consumption savings in using this approach over steady flow. These dual advantages make the microbubble generation approach a promising component of a novel airlift loop bioreactor whose design is presented here. The equipment, control system for flow and temperature, and the optimization of the nozzle bank for the gas distribution system are presented.
doi_str_mv	10.1016/j.fbp.2009.03.006
format	Article
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Hemaka</creatorcontrib><creatorcontrib>Omotowa, Olumuyiwa A.</creatorcontrib><title>On the design and simulation of an airlift loop bioreactor with microbubble generation by fluidic oscillation</title><title>Food and bioproducts processing</title><description>Microbubble generation by a novel fluidic oscillator driven approach is analyzed, with a view to identifying the key design elements and their differences from standard approaches to airlift loop bioreactor design. The microbubble generation mechanism has been shown to achieve high mass transfer rates by the decrease of the bubble diameter, by hydrodynamic stabilization that avoids coalescence increasing the bubble diameter, and by longer residence times offsetting slower convection. The fluidic oscillator approach also decreases the friction losses in pipe networks and in nozzles/diffusers due to boundary layer disruption, so there is actually an energetic consumption savings in using this approach over steady flow. 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source	ScienceDirect Journals (5 years ago - present)
subjects	Airlift loop bioreactor airlift loop bioreactors bioreactors Biorefineries bubbles diameter energy efficiency energy use and consumption equipment design Fluidic oscillators friction gas distribution system hydrodynamics literature reviews mass transfer Microbubble generation microbubbles nozzles optimization oscillation simulation models temperature Transport phenomena
title	On the design and simulation of an airlift loop bioreactor with microbubble generation by fluidic oscillation
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