TY - JOUR
T1 - Process-engineering characterization of small-scale bubble columns for microbial process development
AU - Weuster-Botz, D.
AU - Altenbach-Rehm, J.
AU - Hawrylenko, A.
N1 - Funding Information:
Present address: D. Weuster-Botz Αnstitute of Biochemical Engineering, Munich Θniversity of Technology, 8Β748 Γarching, Γermany The authors are deeply indebted to Prof. Dr. C. Wandrey, Αnsti-tute of Biotechnology, Research Center Jülich, Γermany for the excellent support of this work. The financial support of this work by the Ζederal Ministry of Education and Science (BMBΖ), Γermany by grant no. BCT 0Β47 2 is gratefully acknowledged.
PY - 2001
Y1 - 2001
N2 - Volumetric oxygen transfer rates and power inputs were estimated by a model of the formation of primary gas bubbles at the static sparger (sinter plate) of small-scale bubble columns and a common mass-transfer correlation for bubbles rising in a non-coalescent Newtonian electrolyte solution of low viscosity. Estimations were used to assess the dimensioning and possibilities of small-scale bubble column application with an height/diameter ratio of about 1. Estimations of volumetric oxygen transfer rates (<0.16 s-1) and power inputs (<100 W m-3) with a mean pore diameter of the static sparger of 13 μm were confirmed as function of the superficial air velocity (<0.6 cm s-1) by measurements using an Escherichia coli fermentation medium. Small-scale bubble columns are thus to be classified between shaking flasks and stirred-tank reactors with respect to the oxygen transfer rate, but the maximum volumetric power input is more than one magnitude below the power input in shaking flasks, which is of the same order of magnitude as in stirred-tank reactors. A small-scale bubble columns system was developed for microbial process development, which is characterized by handling in analogy to shaking flasks, high oxygen transfer rates and simultaneous operation of up to 16 small-scale reactors with individual gas supply in an incubation chamber.
AB - Volumetric oxygen transfer rates and power inputs were estimated by a model of the formation of primary gas bubbles at the static sparger (sinter plate) of small-scale bubble columns and a common mass-transfer correlation for bubbles rising in a non-coalescent Newtonian electrolyte solution of low viscosity. Estimations were used to assess the dimensioning and possibilities of small-scale bubble column application with an height/diameter ratio of about 1. Estimations of volumetric oxygen transfer rates (<0.16 s-1) and power inputs (<100 W m-3) with a mean pore diameter of the static sparger of 13 μm were confirmed as function of the superficial air velocity (<0.6 cm s-1) by measurements using an Escherichia coli fermentation medium. Small-scale bubble columns are thus to be classified between shaking flasks and stirred-tank reactors with respect to the oxygen transfer rate, but the maximum volumetric power input is more than one magnitude below the power input in shaking flasks, which is of the same order of magnitude as in stirred-tank reactors. A small-scale bubble columns system was developed for microbial process development, which is characterized by handling in analogy to shaking flasks, high oxygen transfer rates and simultaneous operation of up to 16 small-scale reactors with individual gas supply in an incubation chamber.
UR - http://www.scopus.com/inward/record.url?scp=0034786593&partnerID=8YFLogxK
U2 - 10.1007/s004490100222
DO - 10.1007/s004490100222
M3 - Article
AN - SCOPUS:0034786593
SN - 1615-7591
VL - 24
SP - 3
EP - 11
JO - Bioprocess and Biosystems Engineering
JF - Bioprocess and Biosystems Engineering
IS - 1
ER -