In this work, the vacuum membrane distillation (VMD) technology has been ap
plied to the removal of chloroform from a dilute aqueous stream. Microporou
s polypropylene hollow fiber membranes were used to immobilize the liquid-v
apor interface-The influence of the following operational variables was exp
erimentally studied: (i) initial chloroform concentration in the feed (212-
2012 mg/l), (ii) feed flow rate in the laminar flow regime (0.23-0.98 l/min
) and in the transition to the turbulent flow regime (2.7-8 l/min), (iii) t
emperature (5-47.5 degrees C) and vacuum pressure in the permeate side (7 a
nd 14 mm Hg). The mathematical model proposed to describe the kinetic resul
ts includes the mass balance to the feed tank and the mass balance to the V
MD module. In the laminar regime the solution of the continuity mass conser
vation equation makes the diffusion coefficient of chloroform in the aqueou
s phase the only parameter needed to describe the separation rates. In the
turbulent flow regime, a macroscopic mass balance including an overall mass
transfer coefficient that accounts both for Liquid film diffusion and memb
rane mass transport was developed. It was found that only at higher Reynold
s numbers within the turbulent flow regime the resistance to mass transfer
in the membrane had influence on the overall mass transfer coefficient. (C)
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