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Development of a dynamic still for measuring low pressure vapour-liquid-liquid equilibria : systems of partial liquid miscibility.Ndlovu, Mkhokheli. January 2005 (has links)
The dynamic still originally designed by Raal (Raal and Muhlbauer [1998]) has been transformed into a valuable still that can now be used for measuring both low pressure vapour-liquid equilibria (VLE) for systems that are completely miscible and vapour-liquid-liquid equilibria (VLLE) for systems that are partially miscible. The resultant equilibrium data are important in the design and analysis of distillation and allied separation process equipment, with VLLE data, in particular, being useful in the design of heterogeneous azeotropic distillation columns. The original Raal still was based on the designs of Heertjies [1960] and Yerazunis [1964], who successfully used a packed equilibrium chamber where the liquid and vapour phases are forced downward co-currently to achieve rapid and dynamic equilibrium (Joseph et al [2001]). Direct analysis of the vapour composition prior to condensation through a new heated valving system with superheated sample conveyance to a gas chromatograph, a modification incorporated into the Raal still, ensured that accurate and reproducible equilibrium data were obtained. This new arrangement dispenses with the impossible task of getting the actual vapour composition that would result were the vapours allowed to condense and form two liquid phases. The initial testing of the still which established the operating procedures was conducted on two previously measured systems - the first which was homogeneous and the second heterogeneous. For the homogeneous system the new vapour sampling system was tested by comparing the measured composition to that of a condensed sample sent manually to the GC using a gas-tight syringe. In order to completely describe the VLLE for the systems studied, the liquid-liquid equilibrium (LLE) data for these systems were also measured. The LLE measurements were conducted in a newly-developed small jacketed glass cell with temperatures maintained constant by circulating water from a bath maintained at the desired temperatures. The main focus of this project was thus the development of an apparatus and procedures for measuring low pressure vapour-liquid-liquid equilibria. The project also went on to measuring and modeling VLE, VLLE and LLE data for selected binary and ternary systems. Both the Gamma-Phi and the Phi-Phi methods of VLE analysis were carried out on the measured data. The NRTL, Wilson, TK-Wi1son and UNIQUAC activity coefficient models were used in the Gamma- Phi method together with the Virial equation of state for vapour phase non-idealities. In the Phi-Phi method, The Peng and Robinson Equation of State (EOS), the Soave Redlich-Kwong EOS and the Stryjek and Vera modified Peng and Robinson EOS were all used, first with the classical mixing rules and then with the theoretically correct Wong and Sandler [1992] mixing rules. Ternary LLE binodal curves were correlated to the Hlavaty correlation, the beta function and the log gamma function while the corresponding tie-lines were fitted to the NRTL model. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2005.
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High pressure vapour-liquid equilibrium data of fluorochemical systems for various temperatures using a new static apparatus.Tshibangu, Mulamba Marc. January 2010 (has links)
The thermodynamic knowledge of accurate phase equilibrium data plays an important role in the design and optimization of separation processes in chemical and engineering industries. Vapour-liquid equilibrium data are essential for the design of efficient separation processes such as distillation. The presented research study is mainly focused on the vapour-liquid equilibrium data measurement of fluorochemical and hydrocarbon binary systems at various temperatures and at high pressures. A new static analytical apparatus was constructed and commissioned for the measurement of accurate and precise vapour-liquid equilibrium data at temperatures and absolute pressures ranging from low temperatures to 323.15 K and 0 to 10 MPa respectively. The new apparatus incorporates the ROLSI TM sampler, a sampling technique developed by the CEP/TEP laboratory in Fontainebleau, France. Isothermal high pressure VLE data were measured for three binary systems comprising of hexafluoroethane (R116) + propane, HFPO + propane and ethane + octafluoropropane (R218). The R116 + propane system at 263.15 K was measured as a test system using the new static apparatus. These measurements helped to confirm the functioning of the experimental apparatus. The reliability and the reproducibility of the experimental procedure were also checked. The data obtained were in excellent agreement with data in the literature. Thereafter, measurements of previously unmeasured systems were undertaken. Isothermal vapour-liquid equilibrium data measurements for the ethane + octafluoropropane system were performed at five isotherms with temperatures and pressures ranging from 264.05 to 308.04 K and 0.298 to 4.600 MPa respectively. The five isotherms constitute new experimental data. The HFPO + propane system was also investigated and vapour-liquid equilibrium data were measured at three isotherms (283.05, 303.05 and 323.05 K) with pressures ranging from 0.437 to 2.000 MPa. The data measured also constitute a set of a new HPVLE data. The uncertainties in the measurement for both systems were within ± 0.09 K, ± 0.0016 MPa and less than 2% for temperatures, pressures and mole fractions, respectively. All experimental data were correlated via the direct method using the Peng-Robinson equation of state with the Mathias-Copeman alpha function and the Wong-Sandler mixing rules incorporating the NRTL activity coefficient model. The consistency of the measured VLE data was tested using the Van Ness point test which yielded few points of difference between the measured and calculated data, suggesting a low error rate. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2010.
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Vapour-liquid equilibria and infinite dilution activity coefficient measurements of systems involving diketones.Soni, Minal. January 2003 (has links)
Acetylpropionyl (2,3-pentanedione) and diacetyl (2,3-butanedione) are by-products of sugar manufacture. Both diketones have many uses, mainly food related. Vapour-liquid equilibrium data and infinite dilution activity coefficients are required to design purification processes for these chemicals. A review of available experimental methods revealed that the vapour and liquid recirculating still is most appropriate when both isobaric and isothermal VLE are required. The low-pressure dynamic still of Raal and Muhlbauer (1998) used in this study incorporates many features to ensure that measurements are of excellent quality (as demonstrated by Joseph et al., 2001). VLE measurements were made for the following systems:
• Acetone with diacetyl at 30 C, 40 C, 50 C and 40 kPa
• Methanol with diacetyl at 40 C, 50 C, 60 C and 40 kPa
• Diacetyl with 2,3-pentanedione at 60 C, 70 C, 80 C and 40 kPa
• Acetone with 2,3-pentanedione at 50 C, 30 kPa and 40 kPa.
All the systems, except for methanol with diacetyl, displayed close to ideal behaviour. This was expected as they are mixtures of ketones. Solution thermodynamics allows one to perform data reduction of the measured VLE data to ensure accurate extrapolation and interpolation of the measurements. Furthermore, the quality of the data can be judged using thermodynamic consistency tests. The data were represented by the
Gamma-Phi approach to VLE (the preferred method for low-pressure VLE computations). The two-term virial equation of state was used to account for vapour phase non-ideality. Second virial coefficients were calculated by the method of Hayden and 0'Connell (1975). The liquid phase non-ideality was accounted for by the Wilson, NRTL or UNIQUAC models. The best fit models are proposed for each system, as are parameters as functions of temperature for the isobaric data. The data were judged to be of high thermodynamic consistency by the stringent point test (Van Ness and Abbott, 1982) and the direct test (Van Ness, 1995) for thermodynamic consistency. The data sets were rated, at worst, "3" on the consistency index proposed by Van Ness (1995). A rating of "I" is given for a perfectly consistent data set and "10" for an unacceptable data set. For the system acetone with 2,3-pentanedione, isobars at 30 kPa and 40 kPa were measured. The results from the reduction of the 30 kPa set were used to
accurately predict the 40 kPa data set. Infinite dilution activity coefficients were measured by the inert gas stripping method (based on the principle of exponential dilution). In order to specify the appropriate dilutor flask height (to ensure equilibrium is achieved), mass transfer considerations were made. These computations ensured that the gas phase was in equilibrium with the liquid phase at the gas exit point. The following infinite dilution activity coefficients were measured:
• Acetone in diacetyl at 30 C
• Methanol in diacetyl at 40 C
• Diacetyl in 2,3-pentanedione at 60°C
• Acetone in 2,3-pentanedione at 50 C.
The ketone mixtures, once again, displayed close to ideal behaviour. / Thesis (M.Sc.)-University of Natal, Durban, 2003.
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Vapour-liquid equilibria studies for binary systems containing 1-hexene and n-hexaneJanuary 2009 (has links)
Experimental vapour-liquid equilibria (VLE) data is required for the design of separation / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2009.
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Binary vapour-liquid equilibria for oxygen-containing compounds.Pillay, Jeremy Clive. January 2009 (has links)
In this study, there was a need for VLE data for systems of oxygen-containing organic compounds. Experimental VLE data are presented for the following binary systems: a) 2-propanone (1) + 2-butanol (2) at 333.15K, 353.15K and 373.15K b) 2-propanone (1) + n-propanoic acid (2) at 333.15K, 353.15K and 373.15K c) 1-propanol (1) + n-butanoic acid (2) at 333.15K and 353.15K A test system (cyclohexane + ethanol at 323.15K) was measured to confirm the accuracy of the method and apparatus. With the exception of the test system, data for all the other binary systems investigated in this study are currently not available in the open literature. The dynamic recirculating stills of Joseph (2001) and Reddy (2006) were utilised to undertake the measurements. The experimental vapour pressure data measured in this study and the results obtained for the highly non-ideal test system were in excellent agreement with the literature data. It was thus concluded that the apparatus and operating procedures used were capable of producing highly accurate VLE data and confidence in the new data measured was obtained. Thermodynamic consistency testing was performed on the experimental VLE data using the point test (Van Ness et al., 1973), which provided an indication of the data’s quality and reliability. The data were thereafter subjected to data correlation to enable interpolation of the data and extrapolation to conditions other than those measured. Appropriate thermodynamic models (taking into account vapour-phase association in particular) were correlated to the data using the combined approach to VLE ( - method). For the calculation of the fugacity coefficients, three methods were used viz. the virial EOS and the Hayden-O’Connell correlation (1975); chemical theory and the Nothnagel et al. Formulation (1973); and the VPA/IK-CAPE EOS (Abbott and Van Ness, 1992). Three activity coefficients models were also used viz. the Wilson (1964) model; the NRTL model (Renon and Prausnitz, 1968); and the UNIQUAC model (Abrams and Prausnitz, 1975). In general, the models fitted the data well and the model parameters that were acquired are included. Theoretical developments involving associating components are ongoing. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2009.
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Batch separation of tetrafluoroethylene, hexafluoropropylene and octafluorocyclobutaneConradie, Francois Jacobus 10 October 2012 (has links)
This dissertation details research aimed at designing a small batch distillation column to purify tetrafluoroethylene and hexafluoropropylene from a mixture containing tetrafluoroethylene, hexafluoropropylene and octafluorocyclobutane. As no vapour-liquid equilibrium data are available for these chemicals in this mixture, new vapour-liquid equilibrium data were experimentally generated and modelled for use in the design of the batch distillation column. The data were fitted to the Peng-Robinson equation of state, utilizing the Mathias-Copeman alpha function. The model was used with the Wong- Sandler mixing rules alongside the NRTL alpha function. The model was fitted with mean relative deviations lower than 1.2 %, indicating an acceptably accurate description of the VLE data gathered by the model. The experimental data and the model also passed the thermodynamic consistency test for all the systems and isotherms. The design simulations were completed by means of the Aspen Batch Distillation, a module of the Aspen Technologies package. The results show that the optimum design for recovering high-purity products requires six equilibrium stages in the column. The batch column should consist of a still pot, also functioning as a reboiler, a packed column section and a total condenser. The total condenser and the reboiler both count as equilibrium stages. Using this design, a TFE product purity of 99.999 % is predicted with a recovery of 96 %. An HFP product purity of 99 % is predicted at a recovery of 68 %. The recovery of the HFP product can be increased, but entails a significant loss of product purity. The minimum column diameter required to achieve the flow rates suggested in the simulation is 29 mm. The column diameter was selectedas 1¼ ″ (or 31.75 mm) on the basis of the standard pipe diameters available in the industry. Pall ring packing is suggested for use in the column, with an estimated maximum HETP of 0.5 m. As there are five equilibrium stages in the column itself, the column has to be at least 2.5 m high. Copyright / Dissertation (MEng)--University of Pretoria, 2011. / Chemical Engineering / unrestricted
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Thermodynamic modelling of hydrocarbon-chains and light-weight supercritical solventsLombard, James Edward 03 1900 (has links)
Thesis (MEng)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: Long-chain hydrocarbons are of value to numerous lucrative industries. Due to the low
volatility and close melting and boiling points of these solutes, traditional fractionation
methods lack the required selectivity for separation and cause thermal degradation of the
product.
This project investigates the feasibility of Supercritical Fluid Extraction (SFE) for processing
these systems, with the primary objective of modelling the high-pressure vapour-liquid
equilibrium (VLE) properties of hydrocarbon solutes with a light-weight solvent using a semiempirical
equation of state (EOS). Pure component vapour pressures and saturated liquid
volumes are also investigated.
A thorough investigation into the phase behaviour of the n-alkanes, 1-alcohols, carboxylic
acids and esters in light weight supercritical solvents CO2, ethane and propane revealed that
the solute structure and temperature largely influence the solute solubility and process
feasibility. Good selectivity amongst the various solutes was observed for all three solvents,
but very high pressures were required for complete miscibility using CO2 (exceeding 30
MPa). The quadrapole moment of CO2 further leads to complexities in phase behaviour such
as temperature and density inversions (CO2/alkanes and CO2/alcohols) and 3-phase regions
within the operating range. Simple linear trends in pressure vs. carbon number and
temperature were observed for all the considered series using ethane and propane and these
solvents were thus selected for conducting the modelling for this study.
A thorough review of semi-emperical EOS models from literature revealed that the simple
cubic equations of state (CEOSs) provide a promising modelling approach for SFE
applications due to their simplicity, flexibility and reliability.
The simple Peng-Robinson (PR) and Soave-Redlich-Kwong (SRK) EOSs provide good
correlation of vapour pressure (%AAD below 5 %) for all the series over a large carbon
number range (up to nC20), provided a two parameter alpha function is used. A 3rd parameter
in the volume dependence for Patel-Teja (PT) EOS provides considerable improvement over
the PR and SRK EOSs for satureate liquid volume correlations of the non-polar solutes
(alkanes and esters), but offers virtually no advantage for the more polar alcohols and acids.
The CEOSs therefore suffer clear limitations in simultaneous representation of these
saturation properties (vapour pressure and liquid molar volume) for the systems of interest.
Good correlations of high pressure binary VLE data were obtained using CEOSs available in
the Aspen Plus ® simulator (% AAD in P, T and X2 generally below 1 % and ranging from 4 to 12 % for Y2 for all series) provided that two binary interaction parameters (BIPs) are used
in the model mixing rules, irrespective of the model used. Aspen Plus ® was further validated
as a reliable thermodynamic tool by comparing model fits using the RK-ASPEN model with
parameters obtained from the Aspen Plus ® data regression routine and computational
methods used in self-developed MATLAB software. Very similar results were obtained for
both computational methods, which encourages the use of Aspen Plus ® for process
modelling in SFE applications.
A statistical sensitivity analysis into the relative effect and interactions between 6 modelling
factors in applying the CEOSs revealed that the mixing rules, temperature and solute structure
had the largest effect on the correlation of the high pressure VLE, with the pure component
limit having negligible effect once BIPs are fitted to data. A significant interaction was,
however, observed between the pure component model and the solute structure and
temperature, which suggest that accurate correlation of mixture VLE does not solely rely on
appropriate mixing rule selection, but also the pure model.
Binary interaction parameters (BIPs) in model mixing rules were found to become
intercorrelated when more than one are used, greatly impeding the development of
generalized correlations. BIPs were also found to be sensitive to the pure component limit
(alpha function and pure constants used), the temperature, the combining rules used and
possibly the fluid density. These factors should all be taken into account systematically for
developing generalized correlations which therefore fell outside the scope of this study.
Recommendations were, however, made on how the MATLAB software developed in this
study can be used to both expand the size of the statistical analysis already conducted into
relevant modelling factors and to develop new generalized correlations for BIPs and new
mixing rules. / AFRIKAANSE OPSOMMING: Lang-ketting koolwaterstowwe is van waarde in talle winsgewende industriële toepassings.
Vanweë die lae vlugbaarheiden ooreenstemmende kook- en smeltpunte van hierdie
molekules, toon tradisionele fraktioneringsmetodes nie die nodige selektiwiteit vir ekstraksie
nie en veroorsaak bonop termiese degradering van die produk.
Hierdie projek ondersoek dus die lewensvatbaarheid van superkritiese ekstraksie vir die
prosesering van hierdie sisteme, met primêre fokus op die modellering van die hoë-druk
damp-vloeistof ewewig eienskappe van koolwaterstowwe opgelos in ‘n lae-massa
oplosmiddel met gebruik van ‘n semi-empiriese toestandsvergelyking. Suiwer-komponent
dampdrukke en versadigde vloeistof volumes word ook ondersoek.
‘n Deeglike ondersoek na die fasegedrag van die n-alkane, 1-alkohole, korboksiel-sure asook
esters in lae-massa superkritiese oplosmidds CO2, etaan en propaan toon dat die struktuur van
die opgeloste stof en die temperatuur ‘n groot invloed het op die oplosbaarheid en proses
lewensvatbaarheid. Goeie selektiwiteit tussen die verskillende koolwaterstowwe was
waargeneem vir al drie oplosmiddels, alhoewel baie hoë drukke nodig was vir totale
vermenging van die fases in CO2 (hoër as 30 MPa). Die quadrupool moment van CO2
veroorsaak verder ongewenste kompleksiteite in fase gedrag soos temperatuuren digtheid
inversies (CO2/alkane en CO2/alkohole) en 3-fase-gebiede in die bedryfs-kondisies.
Eenvoudige lineêre tendense in druk tenoor die koolstofnommer van die opgeloste stof asook
die temperatuur was waargeneem vir al die ondersoekte koolwaterstof reekse in etaan en
propaan en hierdie oplosmiddels was dus gekies vir die modellering vir hierdie studie.
'n Deeglike oorsig van semi-empiriese toestandsvergelykings uit die literatuur het getoon dat
die eenvoudige kubiese toestandsvergelykings ‘n belowende modelleringsbenadering bied vir
superkritiese ekstraksie toepassings vanweë hul eenvoudigeid, buigsaamheid
enbetroubaarheid.
Die eenvoudige Peng-Robinson (PR) en Soave-Redlich-Kwong (SRK) toestandsvergelykings
bied goeie korrelasie van suiwer dampdruk (foute laer as 5 %) vir alle koolwaterstowwe oor
‘n groot koolstofnommer gebied (tot by nC20), met die voorwaarde dat ‘n 2 parameter alpha
funksie gebruik word. ‘n 3rde parameter in die volume afhanklikheid van die Patel-Teja (PT)
toestandsvergelyking bied ‘n beduidende verbetering in die passing van die versadigde
vloeistof volume vir die nie-polêre koolwaterstowwe (n-alkane en die esters), maar bied geen
voordeel vir die meer polêre alkohole en karkoksiel sure nie. Die kubiese modelle toon dus
duidelike beperkings vir die gelyktydige voorstelling van hierdie versadigingde eienskappe
(dampdruk en vloeistof volume) vir die sisteme van belang.
Goeie korrelasie van hoë druk binêre damp-vloeistof ewewig data was verkry deur gebruik
van die kubiese toestandsvergelykings beskikbaar inAspen Plus ® (fout in P, T en X2 tipies
laer as 1 % en van 4 tot 12 % vir Y2 vir alle sisteme), met die voorwaarde dat 2 binêre
interaksie parameters gebuik word in die model mengreëls, onafhanklik van die model. Aspen
Plus ® was verder bekraktig as ‘n betroubare termodinamiese hulpmiddel deur model
passings te vergelyk met die RK-ASPEN model tussen gevalle waar parameters verkry is deur
die beskikbare regressie metode in Aspen Plus ® en metodes gebruik in self-ontwikkelde
MATLAB sagteware. Eenderse resultate was verkry vir beide berekeningsmetodes, wat die
gebruik van Aspen Plus ® vir prosesmodellering in superkritiese ekstrasie toepassings
aanmoedig.
‘n Satistiese sensitiwiteits analise op die relatiewe effek en interaksies tussen 6
modelleringsfaktore in die toepassing van die kubiese toestandsvergelykings het gevind dat
die mengreëls, temperatuur en die stuktuur van die opgeloste stof die grootste effek op die
korrelasie van hoë druk binêre damp-vloeistof ewewig het, met ‘n weglaatbare effek vandie
suiwerkomponent limiet waargeneem sodra binêre interaksie parameters gepas is aan data. ‘n
Beduidende interaksie was wel waargeneem tussen die suiwerkomponent model en die
struktuur van die opgeloste stof asook die temperatuur, wat daarop dui dat akurate korrelasie
van mengsel damp-vloeistof ewewig nie slegs afhanklink is van ‘n gepaste keuse van
mengreëls nie, maar ook die suiwer-komponent model.
Binêre interaksie parameters in die model mengreëls ondergaan inter-korrelasie wanneer
meer as een interaksie parameter gebruik word, wat die ontwikkeling van algemeen toepaslike
korrelasies grotendeels belemmer. Binêre interaksie parameters was ook bevind om sensitief
te wees tot die suiwer component limiet (alpha funksie en suiwer konstantes wat gebruik is),
die temperatuur, die kombineringsreëls en moontlik die vloeistof digtheid. Hierdie faktore
moet dus almal sistematies in ag geneem word wanneer algemeen toepaslike korrelasies
ontwikkel word, wat dus buite die omvang van die huidge studie val. Aanbevelings was wel
gemaak vir hoe die MATLAB sagteware ontwikkel vir hierdie studie gebruik kan word om
beide die betaande statistiese analise uit te brei, asook nuwe korrelasies vir binêre interaksies
parameters en nuwe mengreëls te ontwikkel.
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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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Ionic liquids as solvents in separation processes.Warren, David Mercer. January 2003 (has links)
Due to the ever increasing need for sustainable development, the chemical and allied industries have been at the focus of much change. Decreasing tolerances on pollution via waste streams has resulted in a re-examination of many chemical processes. This has ushered in the era of 'green chemistry' which incorporates the synthesis of a process in both a sustainable and economically viable manner. In the petroleum and chemical industries, this has led to the search for alternatives to volatile organic compounds. Ionic liquids provide one such alternative. With a wide liquid phase and no measurable vapour pressure, ionic liquids have been found to be successful as a medium for reactions. Ionic liquids differ from high-temperature molten salts in that they have a significantly lower melting point. This work investigates the use of ionic liquids as solvents in separations. The work focuses on the separation of alpha-olefins from complex mixtures. The ionic liquids used in this study were: • l-methyl-3-octyl-imidazolium chloride • 4-methyl-N-butyl-pyridinium tetrafluoroborate • trihexyl-tetradecyl-phosphonium chloride Three experimental techniques used to evaluate ionic liquids were: • gas-liquid chromatography • liquid-liquid equilibria measurements • vapour-liquid equilibria measurements l-Methyl-3-octyl-imidazolium chloride ((MOIM)C1) was used as a stationary phase in gas-liquid chromatography. The solutes used were: • Alkanes: n-Pentane; n-Hexane; n-Heptane; n-Octane • Alkenes: 1-Hexene; 1-Heptene; l-Octene • Alkynes: l-Hexyne; l-Heptyne; 1-0ctyne • Cycloalkanes: Cyclopentane; Cyclohexane; Cycloheptane • Aromatics: Benzene; Toluene Activity coefficients at infinite dilution were measured at temperatures (298.15, 308.15 and 318.15) K. Values at 298.15 K ranged from 1.99 for benzene to 26.1 for n-octane. From the temperature dependence of the activity coefficients, the partial excess molar enthalpies at infinite dilution were calculated. These range from 2.0 kJ.mol'l for l-octyne to 7.3 kJ.mol·1 for n-pentane. (MOIM)C1 shows reasonable ability to separate 1-hexene from the longer n-alkanes and aromatics. 4-Methyl-N-butyl-pyridinium tetrafluoroborate (BuMePyBF) was used as a solvent in liquid-liquid equilibria measurements. The following systems were measured at 298.2 K: • LLE System 1: BuMePyBF4 + 1-Hexene + Toluene • LLE System 2: BuMePyBF4 + 1-Hexene + Ethanol • LLE System 3: BuMePyBF4 + 1-Hexene + 2-Butanone • LLE System 4: BuMePyBF4 + 1-0ctene + Ethanol LLE System 1 is a type 11 system and the other systems being type I. All systems exhibit a large two-phase region. LLE System 1 shows low distribution. LLE System 3 show almost equal distribution between phases resulting in a distribution ratio of close to 1. LLE Systems 2 and 4 show high distribution ratios at low concentrations of solute. LLE Systems 1 and 3 show low to moderate selectivity of the solvent towards the solute. LLE Systems 2 and 4 show high to moderate selectivity, but decrease exponentially with increasing solute concentration in the organic phase. For all systems investigated, the solvent shows no miscibility with feed solutions of low to medium solute concentration. The binodial curves were correlated to the Hlavaty equation, the beta function and the log gamma function. The correlations yielded acceptable results for LLE Systems 2, 3 and 4. The tie-lines were correlated to the NRTL model, with LLE systems 2 and 4 giving acceptable results and LLE systems 1 and 3 give excellent results. The following binary vapour-liquid equilibrium systems were measured: • Acetone + Methanol at 99,4 kPa • l-Hexene + 2-Butanone at 74.8 kPa The acetone + methanol system exhibits a minimum boiling azeotrope at 0.78 mole fraction acetone. The l-hexene + 2-butanone system exhibits a minimum boiling azeotrope at 0.83 mole fraction l-hexene. Trihexyl-tetradecyl-phosphonium chloride (CJ3C1PhCl was then added to the above systems in order to evaluate it as a solvent in extractive distillation. (CJ3C1PhCI shifts the azeotrope of the acetone + methanol system to a higher acetone concentration, but does not remove it altogether. (CJ3C1PhCI has a negative effect on the relative volatility of the l-hexene + 2-butanone, thus rendering it ineffective as an extractive distillation solvent for this system. Another aspect that was considered in this work was the production of an ionic liquid. Synthesis steps and experimental considerations were discussed. A major factor in the use of ionic liquids is the cost of the ionic liquid itself. The major problem associated with ionic liquids is the general lack of available information that is necessary for them to be implemented in a process. Ionic liquids show potential as solvents in liquid-liquid extraction for a number of systems. Their potential as solvents in extractive distillation is probably limited, due to their miscibility/immiscibility properties, to systems involving slightly polar to highly polar compounds. / Thesis (M.Sc.Eng.)-University of Natal, Durban, 2003.
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Low-pressure vapour-liquid equilibrium and molecular simulation of carboxylic acids.Clifford, Scott Llewellyn. January 2004 (has links)
No abstract available. / Thesis (M.Sc.Eng.)-University of Natal, Durban, 2004.
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