Vapor−liquid equilibrium (VLE) data for aqueous systems in the presence of electrolytes have many industrial applications. VLE data for water + monoethylene glycol (MEG) mixtures in the presence of sodium chloride at low pressures are important to describe the effects of composition, temperature, and pressure on a MEG (gas hydrate inhibitor) regeneration unit. A modified version of the Othmer ebulliometer was applied to measure reliable VLE data for water + MEG + NaCl at 101.325, 65, and 35 kPa. Binary systems (water + MEG and MEG + NaCl) were also experimentally studied. Vapor pressures for water and MEG were determined and compared with the selected literature data via Antoine correlation. The electrolyte nonrandom twoliquid and universal quasi-chemical activity coefficient models were successfully parameterized to describe the VLE behavior for water + MEG + NaCl systems. Thermodynamic consistence of the data sets was also checked. Interaction parameter estimation followed a systematic strategy: (1) water−MEG, (2) water−NaCl, and finally (3) MEG−NaCl with the experimental data of MEG + NaCl and ternary data. MEG + NaCl solutions presented an inverted colligative property, that is, the addition of salt decreases the boiling point. VLE data indicated that water separation is less efficient due to the addition of salt. The parameterized models allow an evaluation of the MEG regeneration process as a function of temperature, pressure, and composition.
Monoethylene
glycol (MEG) is a gas hydrate inhibitor widely applied
for natural gas flow assurance. A series of density and electrical
conductivity measurements of water + MEG + NaCl mixtures are reported,
allowing the supervision of the MEG regeneration unit. Density (509
data points) and electrical conductivity (212 data points) measurements
were performed in wide ranges of temperature, T =
278.15–363.15 K, and concentration of solvents and NaCl up
to almost saturation. The theory of solutions was applied for density
description using excess volume, which was correlated with the Redlich–Kister
equation. The resulting absolute and relative mean deviations are
0.00127 g·cm–3 and 0.12%, indicating accurate
representation. A semiempirical correlation with 15 adjustable parameters
was considered for electrical conductivity of water + MEG + NaCl mixtures.
The obtained absolute and relative mean deviations are 1.49 mS·cm–1 and 5.70%. The properties functions presented an
approximately orthogonal behavior to each other, allowing the determination
of mixture composition from experimental density and electrical conductivity
data. The Matlab environment was found to be robust in solving the
nonlinear system of two equations with constraints. The proposed methodology
was extensively tested, and deviations less than 0.0060 and 0.0011
in solvents and NaCl mass fractions were obtained, respectively, demonstrating
the required accuracy for industrial application.
Monoethylene glycol (MEG) is used to prevent hydrate formation in subsea pipelines of natural gas production. MEG is recovered at an offshore regeneration unit. Sodium chloride is the predominant salt in the water−MEG streams. Thus, knowledge of NaCl solubilities in the process conditions is relevant for the design and operation of a MEG regeneration unit. Six isotherms of NaCl solubility were measured (76 data points) from T = (293.15 to 403.15) K in the whole solvent concentration range. The analytical method for salt solubility was based on the reproducibility of the concentration of two successive samples. Density measurements were accurately applied for these analyses. The temperature dependence on NaCl solubility is relatively weak. A reverse behavior with increasing temperature was observed for MEG contents higher than 90 wt %. Salt solubilities were successfully correlated with Redlich−Kister expansion (AADw NaCl = 0.0006 and Δw NaCl = 0.47%). Electrical conductivity of NaClsaturated solutions were measured (44 data points) at T = (293.15 to 363.15) K and correlated with a semiempirical model. A large difference in electrical conductivity for the two solvents was observed. The correlation adequately represented the data set (AADκ = 5.67 mS•cm −1 and Δκ = 5.94%). NaCl solubilities and electrical conductivities were accurately determined and are useful for the MEG regeneration process.
Monoethylene glycol (MEG) has been applied as an inhibitor of hydrate formation in natural gas exploitation. The recovery unit of MEG presents salt scale issues that promote operational problems. A literature survey and analysis of salt solubility data in water-MEG mixtures have been performed, revealing that experimental studies are available for eight electrolyte species (NaCl, NaHCO 3 , KCl, Na 2 SO 4 , KI, KBr, K 2 SO 4 , and CaSO 4 ), in total 616 data points. This work aimed at the development of a calculation methodology using Pitzer-Lorimer approach for salt solubility in mixed solvents. Python language was properly used to design the computational tool, which is freely available. The results demonstrated the feasibility of the salt solubility description in mixed solvents, and relative deviations less than 5% were obtained for the eight studied salts. Furthermore, the developed tool can be easily applied for parameter estimation and salt solubility prediction of other electrolyte systems.
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