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Studies on phase behaviour and surface properties of polymer systems.Siow, Kok-Siong. January 1972 (has links)
No description available.
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Solid-liquid phase equilibria of the potassium-rubidium and rubidium-cesium alloy systemsDelawarde, Elisabeth M. 01 May 1971 (has links)
Thermal methods of high precision were used to determine the solid-liquid phase equilibria diagrams for the potassium-rubidium and the rubidium-cesium systems. Both form minima in the liquidus curves occurring at 307.00° K with 0.667 mole fraction rubidium in the potassium-rubidium system and 282.85° K with 0.530 mole fraction cesium in the rubidium-cesium system. In the potassium-rubidium system, the liquidus and solidus points are very close together, giving a very narrow temperature range for the two phase region. The freezing point minimum in the potassium-rubidium system occurs at 0.667 mole fraction rubidium, suggesting the possible formation of a KRb2 intermetallic compound.
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High temperature reactions and phase equilibria in the strontium oxide-zirconium oxide system.Simmons, Wilbur C. January 1968 (has links)
No description available.
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Equilibrium relations in the CaO-Al₂O₃-ZrO₂-SiO₂ system, especially in the ternary system CaO-ZrO₂-SiO₂ /Erickson, Thomas David January 1970 (has links)
No description available.
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A theoretical analysis of combined melting and vaporization using the boundary element methodFulakis, Chris 05 September 2009 (has links)
Melting and vaporization of solids occur very often in nature and in man-made processes. Many analytical and numerical solutions exist for solving the temperature field in the liquid and solid regions, but inaccuracies persist in tracking the phase change interfaces and the numerical solution of the temperature field is usually cumbersome. The Boundary Element Method is proposed as an accurate, efficient way to solve for the temperature field and the interface positions in a phase change problem involving combined melting and vaporization. When comparing to specific one-dimensional test cases, accurate results arc obtained when using a sufficiently small time step. A comparison is made to existing data from a laser drilling experiment. The anticipated physical effects which occur on semi-infinite and finite domains arc confirmed. Consequently, this method can be used to model natural and industrial phenomena involving phase change. / Master of Science
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Phase equilibrium studies of sulfolane mixtures containing carboxylic acidsSithole, Nompumelelo Pretty January 2012 (has links)
Submitted in fulfilment of the academic requirements for the Masters Degree in Technology: Chemistry, Durban University of Technology, 2012. / In this work, the thermodynamics of ternary liquid mixtures involving carboxylic acids with sulfolane, hydrocarbons including cycloalkane, and alcohols are presented. In South Africa, Sasol is one of the leading companies that produce synthesis gas from low grade coal. Carboxylic acids together with many other oxygenate and hydrocarbons are produced by Sasol using the Fischer-Tropsch process. Carboxylic acids class is one of the important classes of compounds with great number of industrial uses and applications. The efficient separation of carboxylic acids from hydrocarbons and alcohols from hydrocarbons is of economic importance in the chemical industry, and many solvents have been tried and tested to improve such recovery. This work focussed on the use of the polar solvent sulfolane in the effective separation by solvent extraction and not by more common energy intensive method of distillation.
The first part of the experimental work focussed on ternary liquid-liquid equilibria of mixtures of [sulfolane (1) + carboxylic acid (2) + heptane (3) or cyclohexane or dodecane] at T = 303.15 K, [sulfolane (1) + alcohol (2) + heptane (3)] at T = 303.15 K. Carboxylic acid refers to acetic acid, propanoic acid, butanoic acid, 2-methylpropanoic acid, pentanoic acid and 3-methylbutanoic acid. Alcohol refers to methanol, ethanol, 1- propanol, 2-propanol, 1-butanol, 2-butanol, 2-methyl-1-propanol and 2-methyl-2-propanol. Ternary liquid- liquid equilibrium data are essential for the design and selection of solvents used from liquid- liquid extraction process.
Abstract vi
The separation of carboxylic acids from hydrocarbons and the alcohols from hydrocarbons is commercially lucrative consideration and is an important reason of this study. The separation of carboxylic acids or alcohols from hydrocarbons by extraction with sulfolane was found to be feasible as all selectivity values obtained are greater than 1.
The modified Hlavatý, beta (β) and log equations were fitted to the experimental binodal data measured in this work. Hlavatý gave the best overall fit as compared to beta ( ) and log function.
The NRTL (Non-Random, Two Liquid) and UNIQUAC Universal Quasichemical) model were used to correlate the experimental tie-lines and calculate the phase compositions of the ternary systems. The correlation work served three purposes:
to summarise experimental data
to test theories of liquid mixtures
prediction of related thermodynamics properties.
The final part of the study was devoted to the determination of the excess molar volumes of mixtures of [sulfolane (1) + alcohol (2)] at T = 298.15 K, T = 303.15 K and T = 309.15 K. Density was used to determine the excess molar volumes of the mixtures of [sulfolane (1) + alcohols (2)]. Alcohol refers to methanol, ethanol, 1- propanol, 2-propanol, 1-butanol, 2-butanol, 2-methyl-1-propanol, 2-methyl-2-propanol.
The work was done to investigate the effect of temperature on excess molar volumes of binary mixtures of alcohols and sulfolane, as well as to get some idea of interactions involved between an alcohol and sulfolane. The excess molar volume data for each binary mixture was fitted in the Redlich–Kister equation to correlate the composition dependence of the excess property. / National Research Foundation
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Phase equilibrium studies of sulfolane mixtures containing carboxylic acidsSithole, Nompumelelo Pretty 20 August 2012 (has links)
Submitted in fulfilment of the academic requirements for the Masters Degree in Technology: Chemistry, Durban University of Technology, 2012. / National Research Foundation
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High pressure fluid phase equilibriaDu Rand, Marlie 12 1900 (has links)
Thesis (MScEng)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: Supercritical extraction is being investigated as a possible alternative to the processes
currently used in the fractionation of paraffinic waxes. By removing the lighter carbon
fractions from the wax, the wax hardness will be improved and its melting temperature
range reduced, hence improving the performance of the wax product in certain
applications. In order to evaluate and operate such an extraction process optimally, it is
necessary to have a thermodynamic model that accurately represents the process system.
There are, however, currently no predictive models available for these systems. In order to
fit present models to the systems, accurate phase equilibrium data of the supercritical
solvent - n-alkane systems are needed. Unfortunately, the amount of reliable published
data on these systems in the required operating range is very limited.
A view cell was designed and developed with which these high pressure equilibria could
be studied. The binary phase equilibria of supercritical CO2 with n-CI2, n-CI6, n-C20, n-C24,
n-C28 and n-C36 and of supercritical ethane with n-CI6, n-C24 and n-C28 were measured in
the temperature range 313 - 367 K. It was found that the systems with these two solvents
have very different types of phase behaviour. The n-alkane solubility is much higher in
ethane, but supercritical CO2 will provide a much better degree of control over the
selectivity achieved in an extraction process.
Of the various equations of state investigated, it was found that the Patel Teja equation of
state provided the best fit of the CO2 - n-alkane systems and that the Soave-Redlich-
Kwong equation fitted the ethane - n-alkane systems the best. The interaction parameters
of both these equations of state display a functional relationship with temperature and nalkane
acentric factor, making it possible to determine parameter values for application at
other operating temperatures and with other n-alkane systems.
It was found that the current equations of state were not able to represent the phase
equilibria accurately over the entire range of operating conditions. The poor performance
of the equations of state can be attributed to inherent flaws in the existing equations of
state. / AFRIKAANSE OPSOMMING: Superkritiese ekstraksie word tans ondersoek as 'n moontlike altematief vir die prosesse
wat huidiglik gebruik word om paraffiese wasse te fraksioneer. Die Iigter koolstofwasse
word verwyder om die washardheid te verhoog en die temperatuurgebied waaroor die was
smelt te verklein. Dit verbeter dan die was se kwaliteit en werkverrigting. Modelle wat die
superkritiese ekstraksie proses akkuraat kan voorstel word egter benodig om die ekstraksie
proses te kan evalueer en optimaal te bedryf. Daar is tans geen modelle beskikbaar wat die
proses direk kan voorstel nie. Akkurate fase-ewewigsdata word benodig om bestaande
modelle aan te pas vir gebruik in hierdie sisteme. Daar is egter baie min betroubare faseewewigsdata
vir die superkritiese oplosmiddel - n-alkaan sisteme beskikbaar in die
literatuur.
'n Sig-sel, waarrnee hierdie hoe druk data gemeet kan word, is ontwerp en ontwikkel. Die
volgende binere fase ewewigte is in die temperatuur gebied 313 - 367 K gemeet:
superkritiese CO2 met n-CI2, n-CI6, n-C20, n-C24, n-C28 en n-C36, en superkritiese Etaan met
n-CI6, n-C24 en n-C28. Daar is gevind dat hierdie twee superkritiese oplosmiddelsisteme
verskillende tipes fase-ewewigsgedragte openbaar. Die n-alkane het 'n baie boer
oplosbaarheid in Etaan, maar deur superkritiese C02 in 'n ekstraksie kolom te gebruik, sal
tot beheer oor die selektiwiteit van die ekstraksieproses lei.
Uit die verskillende toestandsvergelykings wat ondersoek is, is daar gevind dat die Patel-
Teja vergelyking die CO2 sisteme die beste kon beskryf en dat die Soave-Redlich-Kwong
vergelyking die beste vergelyking was om die Etaan sisteme mee te modelleer. Beide die
toestandsvergelykings se interaksie parameters het 'n funksionele verband met temperatuur
en die n-alkaan asentrise faktor getoon. Dit is dus moontlik om waardes vir die parameters
vir sisteme by ander temperature en met ander n-alkaan tipes te bepaal.
Daar was gevind dat die bestaande toestandsvergelykings nie die die fase-ewewigte oor die
hele eksperimenele gebied akkuraat kon voorstel nie. Dit kan toegeskryf word aan foute
wat inherent is aan die vergelykings.
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Molecular simulation of vapour-liquid-liquid-equilibrium.Moodley, Suren. January 2008 (has links)
Phase equilibrium data is vital for designing chemical separation equipment. Traditionally, such data is obtained through laboratory experiments by sampling and analysing each phase of an equilibrated chemical mixture. An alternative means of generating such data is via molecular simulations, which also gives insight into the microscopic structure of the phases. This project was undertaken due to the lack of work on molecular simulations in predicting vapour-liquid-liquid equilibrium (VLLE). Gibbs Ensemble Monte Carlo molecular simulations were performed in the isochoricisothermal (NVT) and isobaric-isothermal (NVT) ensembles to determine the ability and limitations of the Transferable Potentials for Phase Equilibria (United-Atom) and Extended Simple Point Charge (SPC-E) force fields in predicting three-phase fluid equilibrium for two binary and three ternary industrially relevant mixtures: n-hexane/water (1), ethane/ethanol (2), methane/n-heptane/water (3), n-butane/1-butene/water (4) and nhexane/ ethanol/water (5). The NPT ensemble proved inadequate for predicting VLLE for binary mixtures, as for both binary mixtures (1 and 2), the simulations reverted to two phases. This was due in part to the unlike-pair interactions between pseudoatoms in different molecules not being accurately predicted at the specified simulation conditions to reproduce experimental mixture densities and vapour pressures. It was also due to the sensitivity of the NPT ensemble to perturbations which probably removed the system from its three-phase trajectory in Gibbs phase space, since specifying even the correct pressure corresponding to the potential models was unsuccessful in obtaining stable VLLE. Furthermore, ternary VLLE could not be obtained for a mixture exhibiting an extremely narrow three-phase region (4) and simulations for a miscible, non-ideal mixture (5) gave mole fractions that were in poor agreement with experiment. Good results were obtained for mixture 3 which exhibits limited mutual solubilities and a large three phase region. The NVT ensemble overcame the shortcomings of the NPT ensemble by producing three stable phases for the binary mixtures, revealing that the three-phase pressures were shifted by as much as 12%. Also, the narrow three-phase region of mixture 4 was overcome by adjusting the total system volume, producing three stable phases. These were also the first successful binary VLLE simulations involving complex polyatomic molecules. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2008.
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Measurements of phase equilibrium for systems containing oxygenated compounds.Nala, Mqondisi Edmund. January 2012 (has links)
Accurate and reliable vapour-liquid equilibrium (VLE) and liquid-liquid equilibrium (LLE) data
are the key to a successful design and simulation of most important industrial separation
processes (traditional distillation, extractive and azeotropic distillation). This work focuses on
measurement of new phase equilibrium data for systems comprising of propan-1-ol, water and
diisopropyl ether which are of important use in the petrochemical industry. In addition, an
investigation of phase equilibrium behavior for systems of interest constituted by solvents and
high added-value oxygenated compounds deriving from lignocelluloses biomasses (bio-fuels)
was conducted at the Ecole des Mines de Paris CEP/TEP laboratories (France).Various data
bases such as Science Direct, ACS publications and Dortmund Data Bank (DDB, 2009) were
used to confirm that no literature data is available for these systems.
The VLE data measurements for the system of propan-1ol + water and propan-1ol + diisopropyl
ether (DIPE) ( 333.15, 353.15 and 373.15 K ) were carried out using a dynamic still of Lilwanth
(2011), with a test system (ethanol + cyclohexane at 40 kPa) undertaken prior measurements to
confirm the accuracy of the method and apparatus.The phase equilibrium (VLE and LLE)
behaviours for furan + n-hexane and furan + Methylbenzene, furfural + n-hexane and furan +
water were determined at 101.3 kPa. The atmospheric dynamic ebulliometry was used to
measure VLE systems at 101.3 kPa. A set of LLE data for furfural + n-hexane and furan + water
systems were obtained using a static analytical method, with a newly commissioned LLE
apparatus. Furfural + n-hexane system was compared used as test system, to verify the reliability
of the new equipment. The NRTL model was used to correlate the LLE data, with Cox-
Herington model used to predict the entire LLE curve for furfural+ n-hexane system. The
experimental VLE data were correlated using the combined y − y method. The vapour phase
non idealities were described using the methods from Nothnagel et al. (1973), Hayden and
O’Connell (1975) and the Peng-Robinson (1976) model. The activity coefficients were
correlated using the NRTL model of Renon and Prausnitz (1968) and the modified UNIQUAC
model of Abrams and Prausnitz (1976).
A propan-1-ol dehydration process was simulated using Aspen to illustrate the use and
importance of thermodynamic models in industrial process design and simulation. The model
used in the simulation was validated with measured VLE and literature LLE data. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2012.
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