TY - JOUR
T1 - A novel split-cylinder airlift reactor for fed-batch cultures. Effect of the liquid height on the hydrodynamic characteristics and the volumetric oxygen transfer coefficient of the reactor
AU - Galíndez-Mayer, J.
AU - Sánchez-Teja, O.
AU - Cristiani-Urbina, E.
AU - Ruiz-Ordaz, N.
N1 - Funding Information:
Received: 11 December 2000 / Accepted: 23 May 2001 Published online: 26 September 2001 © Springer-Verlag 2001 J. Gaĺõndez-Mayer (&), O. Sánchez-TeΑa, Β. Cristiani-Γrbina ∆. Ruiz-Ordaz Departamento de Ingenieŕõa Εioqúõmica, Βscuela ∆acional de Ciencias Εiológicas, del I.P.∆. Prol. de Carpio y Plan de Ayala, Col. Plutarco Βĺõas Calles, México, D.Ζ.C.P. 11340 México ∆.R.-O., J.G.-M. and Β.C.-Γ. are fellow holders of a grant from the Comisión de Operación y Ζomento de Actividades Académicas, Instituto Politécnico ∆acional, México, D.Ζ., México. The authors gratefully acknowledge the financial support provided by the ∆ational Council for Science and Technology (CO∆ACyT), México.
PY - 2001
Y1 - 2001
N2 - Conventional airlift reactors are not adequate to carry out variable volume processes since it is not possible to achieve a proper liquid circulation in these reactors until the liquid height is higher than that of the downcomer. To carry out processes of variable volume, the use of a split-cylinder airlift reactor is proposed, in the interior of which two multi-perforated vertical bafftes are installed in order to provide several points of communication between the reactor riser and downcomer. This improves the liquid circulation and mixing at any liquid volume. In fed-batch cultures, it is important to know how liquid height affects the hydrodynamic characteristics and the volumetric oxygen transfer coefficient since this impacts on the kinetic behavior of any fermentation. Thus, in the present work, the effect of the liquid height on the mixing time, the overall gas hold-up, and the volumetric oxygen transfer coefficient of the proposed airlift reactor were determined. The mixing time was increased and the volumetric oxygen transfer coefficient decreased due to the increase of the liquid height in the reactor in all the superficial gas velocities tested, which corresponded to a pseudohomogeneous flow regime. The experimental values of the mixing time and the mass-transfer coefficient were properly described through correlations in which the UGR/HL ratio was used as the independent variable. Thus, this variable might be used to describe the hydrodynamic behavior and the oxygen transfer coefficient of airlift reactors when such reactors are used in processes where the liquid volume changes with time. However, these correlations are useful for the particular device and for the particular operating conditions at which they were obtained. These empirical correlations are useful to understand some factors that influence the mixing time and volumetric oxygen transfer coefficient, but such correlations do not have a sufficient predictive potential for a satisfactory reactor design. The overall gas hold-up values were not significantly affected when the liquid height was lower than the downcomer height. However, the values decreased abruptly when the reactor was operated with liquid heights over the downcomer height, especially at high superficial gas velocities.
AB - Conventional airlift reactors are not adequate to carry out variable volume processes since it is not possible to achieve a proper liquid circulation in these reactors until the liquid height is higher than that of the downcomer. To carry out processes of variable volume, the use of a split-cylinder airlift reactor is proposed, in the interior of which two multi-perforated vertical bafftes are installed in order to provide several points of communication between the reactor riser and downcomer. This improves the liquid circulation and mixing at any liquid volume. In fed-batch cultures, it is important to know how liquid height affects the hydrodynamic characteristics and the volumetric oxygen transfer coefficient since this impacts on the kinetic behavior of any fermentation. Thus, in the present work, the effect of the liquid height on the mixing time, the overall gas hold-up, and the volumetric oxygen transfer coefficient of the proposed airlift reactor were determined. The mixing time was increased and the volumetric oxygen transfer coefficient decreased due to the increase of the liquid height in the reactor in all the superficial gas velocities tested, which corresponded to a pseudohomogeneous flow regime. The experimental values of the mixing time and the mass-transfer coefficient were properly described through correlations in which the UGR/HL ratio was used as the independent variable. Thus, this variable might be used to describe the hydrodynamic behavior and the oxygen transfer coefficient of airlift reactors when such reactors are used in processes where the liquid volume changes with time. However, these correlations are useful for the particular device and for the particular operating conditions at which they were obtained. These empirical correlations are useful to understand some factors that influence the mixing time and volumetric oxygen transfer coefficient, but such correlations do not have a sufficient predictive potential for a satisfactory reactor design. The overall gas hold-up values were not significantly affected when the liquid height was lower than the downcomer height. However, the values decreased abruptly when the reactor was operated with liquid heights over the downcomer height, especially at high superficial gas velocities.
UR - http://www.scopus.com/inward/record.url?scp=0034764362&partnerID=8YFLogxK
U2 - 10.1007/s004490100248
DO - 10.1007/s004490100248
M3 - Artículo
SN - 1615-7591
VL - 24
SP - 171
EP - 177
JO - Bioprocess and Biosystems Engineering
JF - Bioprocess and Biosystems Engineering
IS - 3
ER -