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Vapour-liquid equilibrium measurements using a static total pressure apparatus.

A novel static total pressure apparatus was designed, built and commissioned for the
measurement of VLE data at low to moderate pressures and temperatures. The apparatus of
Fischer and Gmehling [1994] was used as a basis for the current design. The continuous-dilution
technique (Gibbs and Van Ness [1972]) for sample introduction has been incorporated in our
apparatus, so that the full composition range of a mixture can be covered in two runs. This
procedure has the considerable advantage of speed. If the liquid is properly degassed, the main
limitation of the method is the accuracy with which one can establish overall compositions from
metered volumes. Accurate injection of the two components is accomplished with a patented
dual-action piston-injector (Raal [1999]). In the micromode the pump can accurately dispense
submicrolitre volumes and the apparatus is thus particularly suited for VLE measurement in the
very dilute region, and thus for determining limiting activity coefficients. r~ calculated using
the method proposed by Maher and Smith [1979] ranged from about 3.8 to 59. The estimated
accuracy of the injected volumes is ± 0.002 cm3
; this was obtained from calibration with distilled
water. The estimated accuracies of the equilibrium temperature and pressure are ± 0.2 °C and ±
0.01 kPa respectively. The pure liquids were degassed for at least 8 hours according to the
procedure proposed by Van Ness and Abbott [1978]. The static assembly and experimental
procedure have been tested via pure component vapour pressure and binary vapour-liquid
equilibrium measurements for a range of test systems (Water (1) + I-Propanol (2) at 313.17 K,
Water (1) + 2-Butanol (2) at 323.18 K, n-Hexane (1) + 2-Butanol at 329.22 K). The test systems
data compared well with literature data and a high degree of confidence was then placed on the
equipment set-up and experimental procedure. New vapour-liquid equilibrium (VLE) data were
measured for the following binary systems:
• I-Propanol (1) + n-Dodecane at 342.83K and 352.68 K
• 2-Butanol (1) + n-Dodecane at 342.83 K and 352.68 K
• Water (1) + o-Cresol at 342.83 K
The VLE measurements of the new systems were very challenging because of the large boiling
point differences between the systems' constituents.
An accurate new method for determining the net interior volume of the cell V cell was tested and
P. -p J gave excellent linear plots of cumulative volume of injected liquid, vt against 1 Po 0 , with
the sIot pe representing. Vcell
The VLE data for all the systems measured were modeled using the combined (r - ¢ ) method.
The Barker's method of data reduction was implemented to convert the number of moles of each
component injected into the cell to mole fraction of the vapour and liquid phase (Uusi-Kyyny et
al. [2002]). Different Gibbs excess models namely NRTL, T-K Wilson and Van Laar together
with the virial equation of state for vapour phase non-idealities were used. The T -K Wilson and
NRTL gave the best fit. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, 2006.

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:ukzn/oai:http://researchspace.ukzn.ac.za:10413/9033
Date January 2006
CreatorsMotchelaho, A. M. Megne.
ContributorsRamjugernath, Deresh D., Raal, Johan David.
Source SetsSouth African National ETD Portal
Languageen_ZA
Detected LanguageEnglish
TypeThesis

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