Measurements of the total gas holdup, epsilon, have been made in a 0.15 m d
iameter bubble column operated at pressures ranging from 0.1 up to 1.3 MPa.
The influence of the increasing system pressure is twofold: (1) a shift of
the how regime transition point to higher gas fractions, and (2) a decreas
e of the rise velocity of "large" bubbles in the heterogeneous regime. The
large bubble rise velocity is seen to decrease with the square root of the
gas density, root rho(G). This square root dependence can be rationalized b
y means of a Kelvin-Helmholtz stability analysis. The total gas holdup mode
l of Krishna and Ellenberger (1996, A.I.Ch.E. J. 42, 2627-2634), when modif
ied to incorporate the root rho(G) correction for the large bubble rise vel
ocity,is found to be in good agreement with the experimental results. The i
nfluence of system pressure on the volumetric mass transfer coefficient, k(
L)a, is determined using the dynamic pressure-step method of Linek et al. (
1993, Chem. Engng Sci. 48, 1593-1599). This pressure step method was adapte
d for application at higher system pressures. The ratio (k(L)a/epsilon) is
found to be practically independent of superficial gas velocity and system
pressure up to 1.0 MPa; the value of this ratio is approximately equal to o
ne half This result provides a simple method for predicting k(L)a using the
model developed for estimation of epsilon. (C) 1999 Elsevier Science Ltd.
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