Sulfur dioxide (A) is being absorbed into water in a packed column, where bulk conditions are 50°C, 2 atm, yAb= 0.08, and XAb = 0.001, whereas the liquid concentration is estimated to be 55 kmol/m. Experimental values of the mass transfer coefficients are: ke=0.18 m/hr, kg=0.04 kmol/ (hr-m2-kPa). The equilibrium data for the system is plotted as in Fig.-Q1: %3D 0.09 0.08 007 0.06 y 00s 004 002 x 103 Figure-Q1: Equilibrium concentration of (A) in water i- Considering dilute solution, convert the values given for the mass transfer coefficients into k , and k ii- Estimate the mole fractions at the interface (i.e. Xu and Va). iii- Calculate the overall mass transfer coefficient (K). iv- Calculate the percent resistance in the liquid phase and the flux N.

Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
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Chapter1: Introduction
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Sulfur dioxide (A) is being absorbed into water in a packed column, where bulk conditions
are 50°C, 2 atm, yAb= 0.08, and xAb = 0.001, whereas the liquid concentration is estimated
to be 55 kmol/m'. Experimental values of the mass transfer coefficients are: k=0.18 m/hr,
%0.04 kmol/ (hr-m²-kPa). The equilibrium data for the system is plotted as in Fig.-Q1:
8.09
007
006
y 00s
004
002-
x 103
Figure-QI: Equilibrium concentration of (A) in water
i- Considering dilute solution, convert the values given for the mass transfer coefficients
into k and k
ii- Estimate the mole fractions at the interface ( i.e. Xu and Va).
iii- Calculate the overall mass transfer coefficient (K',).
iv- Calculate the percent resistance in the liquid phase and the flux N1.
Transcribed Image Text:Sulfur dioxide (A) is being absorbed into water in a packed column, where bulk conditions are 50°C, 2 atm, yAb= 0.08, and xAb = 0.001, whereas the liquid concentration is estimated to be 55 kmol/m'. Experimental values of the mass transfer coefficients are: k=0.18 m/hr, %0.04 kmol/ (hr-m²-kPa). The equilibrium data for the system is plotted as in Fig.-Q1: 8.09 007 006 y 00s 004 002- x 103 Figure-QI: Equilibrium concentration of (A) in water i- Considering dilute solution, convert the values given for the mass transfer coefficients into k and k ii- Estimate the mole fractions at the interface ( i.e. Xu and Va). iii- Calculate the overall mass transfer coefficient (K',). iv- Calculate the percent resistance in the liquid phase and the flux N1.
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