PURIFICATION AND REPOSSESSION OF METHANOL FROM A …
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LAPPEENRANTA-LAHTI UNIVERSITY OF TECHNOLOGY LUT
LUT School of engineering science
Master’s Programme in Biorefineries
Examiners: Professor, D. Sc (Tech) Tuomas Koiranen
Assistant professor, D. Sc (Tech) Kristian Melin
Delivery capability manager, M. Sc (Tech) Juulia Loisa
Vesa Leppänen
PURIFICATION AND REPOSSESSION OF METHANOL FROM A POLYMER SYNTHESIS PROCESS
BY FRACTIONAL DISTILLING
ABSTRACT LAPPEENRANTA-LAHTI UNIVERSITY OF TECHNOLOGY LUT LUT School of engineering science Master's Programme in Biorefineries Vesa Leppänen Purification and repossession of Methanol in a polymer synthesis process by fractional distilling Master's thesis 2021 79 pages, 32 figures, 12 tables, and 11 appendices Examiners: Professor, Dr. Sc (Tech.) Tuomas Koiranen
Assistant professor, Dr. Sc (Tech) Kristian Melin Delivery capability manager, Ms. Sc (Tech) Juulia Loisa
Keywords: solvent recovery, fractional distilling, solvent recycling, methanol purification
___________________________________________________________________________
The purpose of this Master's Thesis was to create a new process protocol for solvents repossession from a polymer synthesis process and to recycle the gained material back into the process in the future phases of the synthesis. This thesis aimed to decrease solvent consumption by refining the material by fractional batch distillation to reduce the quantity of chemical waste and overall expenses, including acquiring and disposing of the chemicals. Basics of fractional distillation were reviewed, including distillation equipment in the literature part. In addition, commercial equipment was reviewed.
A new process protocol is based on the study and the results presented in this thesis. Overall, the study is based on a theoretical review of the chemicals and purification method—the experimental part and the presentation of the purification process results. The success is evaluated upon the reached purity levels and the cost reductions of laboratory management and waste. This thesis was limited to handling only fractional distilling because of the available equipment.
The gas chromatography analysis indicates that reached purity of the methanol sample in the final stage is acceptable. Based on these initial test results, we can engineer a new protocol for solvent
repossession in the polymer process. The new process protocol will decrease the consumption and waste inflicted by the current polymer process. In addition, the chemical acquiring, and waste management costs will decrease in the long run, which will cut costs affiliated with the polymer process.
TIIVISTELMÄ LAPPEENRANNAN-LAHDEN TEKNILLINEN YLIOPISTO LUT LUT School of engineering science Kemiantekniikka Vesa Leppänen Metanolin puhdistus ja takaisinotto polymeerisynteesiprosessista fraktionaalisella tislauksella Diplomityö 2021 79 sivua, 32 kuvaa, 12 taulukkoa ja 11 liitettä Tarkastajat: Professori, D. Sc (Tech.) Tuomas Koiranen
Apulaisprofessori, D. Sc (Tech) Kristian Melin Delivery capability manager, M. Sc (Tech) Juulia Loisa
Hakusanat: liuottimen talteenotto, fraktionaalinen tislaus, liuottimen kierrätys, metanolin puhdistus
___________________________________________________________________________
Työn tarkoituksena oli suunnitella uusi prosessi liuottimien talteenotolle polymeerisynteesiprosessista. Talteenotettu liuotin on tarkoitus jatkokäyttää uudelleen synteesiprosessin eri vaiheissa. Tämän työn pohjalta oli tarkoitus pienentää kemikaalien kulutusta jatkojalostamalla ne käyttöön uudelleen. Puhdistus tehdään fraktionaalisella tislaimella. Liuottimien puhdistus ja jatkojalostus vähentää kemikaalien kokonaiskulutusta. Kulutuksen pienentämäisellä saavutetaan taloudellisia sekä ympäristöllisiä parannuksia. Jatkokäyttö vähentää uusien kemikaalien hankintakuluja sekä käytettyjen kemikaalien jätekustannuksia. Lisäksi, ympäristökuormitus vähenee sekä suoraan että välillisesti.
Työ perustuu kirjalliseen sekä kokeelliseen osaan. Kirjallisessa osassa käydään läpi fraktionaalisen tislaimen laitteisto sekä sen toiminta. Perustana kirjalliselle osalle on tätä tarkoitusta varten hankittu laitteisto. Kirjallisuusosassa on esitelty teoreettinen tarkastelu tislauslaitteiston suunnittelulle ja tarkasteltu tässä työssä käytettävät kemikaalit. Kokeellinen osa koostuu analyysilaitteiden esittelystä sekä työssä suoritettujen kokeellisten testien parametrien esittelystä sekä parametrien varioinnin tuloksista. Tämä työ on rajoitettu koskemaan ainoastaan fraktionaalista tislausta sekä metanolin puhdistusta.
NOMENCLATURE
Greek symbols
ij interaction energy between i and j
x activity coefficient of a substance x, dimensionless
Roman symbols
B bottom product flow, mol/s
C number of chemical components, dimensionless
F degrees of freedom, dimensionless
L total flow rate of liquid, mol/t
n number of moles, mol
P number of phases present, dimensionless
p pressure, Pa
pi partial vapor pressure, Pa
Pi* partial vapor pressure, pure substance, Pa
t time, s
T temperature, K
V volume, m3
V total flow rate of vapor, mol/t
xi mole fraction in the mixture, mol
xD mole fraction in the distillate, mol
xB mole fraction in the bottom product, mol
yi molar fraction in vapor, mol
Table of Contents 1. Introduction .....................................................................................................................................8
1.1. Background and objectives of the thesis .................................................................................8
1.2. Research methods and outline of the thesis............................................................................9
2. Basics of fractional distillation .........................................................................................................9
2.1. Phase diagram ....................................................................................................................... 10
2.2. Distillation system ................................................................................................................. 13
2.2.1. Reboiler ......................................................................................................................... 14
2.2.2. Distillation column ........................................................................................................ 15
2.2.3. Condenser ..................................................................................................................... 18
2.2.4. Reflux ratio .................................................................................................................... 19
2.3. Controlling the batch distillation process ............................................................................. 20
2.4. Vapor-liquid equilibrium ....................................................................................................... 21
2.4.1. McCabe – Thiele method .............................................................................................. 27
2.4.2. Activity models .............................................................................................................. 31
2.4.3. Tray efficiency and HETP ............................................................................................... 35
3. Commercial distilling devices ........................................................................................................ 37
3.1. BR Instruments ...................................................................................................................... 37
3.1.1. BR Instruments software ............................................................................................... 38
3.2. Goel Scientific ........................................................................................................................ 46
3.3. Sigma scientific glass ............................................................................................................. 48
3.4. Comparison of commercial distillation systems ................................................................... 49
4. Experimental section ..................................................................................................................... 50
4.1. Solvents ................................................................................................................................. 50
4.2. Test distillations .................................................................................................................... 50
4.3. Analysis methods .................................................................................................................. 52
4.3.1. Gas chromatography ..................................................................................................... 52
4.3.2. Karl-Fischer titration ...................................................................................................... 53
4.4. Test samples .......................................................................................................................... 55
5. Results ........................................................................................................................................... 57
5.1. Conclusions and future considerations ................................................................................. 63
References ............................................................................................................................................. 65
Appendices ............................................................................................................................................ 68
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1. Introduction
1.1. Background and objectives of the thesis
Initial prestudy showed that the production quantities in the production line in question had
increased steadily over the recent years. The production increase has affected polymer
consumption, and alongside solvent consumption. Increasing material consumption in
production requires an update and upscaling of the polymer synthesis process. The synthesis
process uses different solvents, and the more extensive synthesis process requires a larger
quantity of these solvents. The more significant consumption has created a need to recycle
the solvents to cut back costs, waste and make the process more sustainable. This thesis
studies the purification of these solvents, N-methyl-2-pyrrolidone, and Methanol, focusing on
the latter. The method for purification used in this thesis is fractional distilling.
This thesis aims to purify solvents via fractional batch distillation, a popular solvent
purification method. These devices are readily available on the market, and the one used in
this research is commercially available. A comparison of the lab-scale distillation systems,
which were considered for the purchase, is handled in the literature review. The solvents,
which are purified, will be put back into use, either in the synthesis or other necessary
operations in the laboratory. The purity of the distilled solvents will be verified by different
analysis methods in the experimental section. In addition, this research aims to reach a desired
level of purity in repossessed solvents. The final goal is to have a repossession process in
regular production after this process development.
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1.2. Research methods and outline of the thesis
The study will take place in two segments: a literature review of the basics of distillation and
an experimental part. In the first part, there is a review of the purification method and the
materials. The latter section will focus on empirical testing. We will acquire the waste solvents
organically from the synthesis process; instead of disposing of the solvents, we will receive
these as test material. The collected waste material is then purified with the fractional
distillation device and analyzed by gas chromatography and Karl-Fischer titration.
There are different ways to purify this waste material, but the thesis's outline considers only
fractional batch distillation. This limitation is in place because of available instrumentation. In
addition, the selected solvents for the purification process are the most consumed in this
synthesis process, contributing the most to the waste quantity. Therefore, the thesis is limited
to considering only these solvents.
2. Basics of fractional distillation
Distillation can be defined as a separation of substances drop by drop. The separation
principles have been used for thousands of years, yet the modern distillation process is only
roughly 150 years old. The term distillation describes the separation of two similar substances
with different material qualities by evaporation and condensation. (Krell, 1982)
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2.1. Phase diagram
Each substance has an individual phase diagram. The graph tells us about substances' behavior
and phase changes. An example substance undergoes each phase shift; solid-liquid, liquid-gas.
If the lines were to cross in a different series, e.g., the gas line would cross solid before liquid,
we could conclude that the substance sublimates. The phase transition temperature is also
one thing to consider. The phase shift does not happen straight away but rather slowly while
there are usually two different phases. For example, when water begins to boil at 100°C (atm),
both the liquid and the gas phase are present. (Campbell, 2012)
The phase diagram aims to illustrate a substance's most stable thermodynamic phases at
different temperatures and pressures. There are a few terms, which are crucial to
understanding the phase diagrams:
➢ Triple point – The point where all three phases, solid, liquid, and gas, can be present
at the same time
➢ Critical point – The point where gaseous and liquid phases cannot be identified
➢ Fusion curve (melting or freezing curve) – Transition between liquid and solid-state
➢ Vaporization curve – Transition between liquid and gaseous state
➢ Sublimation curve – Transition between solid and gaseous phase
These graphs are usually presented as pressure as a function of temperature, see Figure 1.
(Zhang, Zhang, et al., 2018)
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Figure 1. An example of a phase diagram. There is a lot of information on the substance in one Figure. (Zhang, Zhang, et al., 2018)
The fusion curve (green) is for most substances going from left to right as water makes an
exception to this phase diagram (dotted green). The green line marks the freezing curve, and
the blue line marks the boiling curve to simplify the Figure. We have a distinct and essential
concept at the phase boundaries considering the distillation process – vapor pressure. The
vapor pressure results from the molecules leaving their liquid phase and causing the increase
in pressure. Vapor pressure depends heavily on temperature, as the molecules require more
energy to escape the initial state. (Atkins, de Paula. 2009)
In the distillation process, two or more equally soluble liquids are separated by evaporation
and condensation. Distillation does not define the number of materials involved in the
process; hence, if we evaporate and condense water, it is also distilling, although no actual
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separation occurs. Simple distillation is the generally understood process when considering
distillation. However, simple distillation cannot achieve desired purities in the actual
separation process and is relatively slow and expensive to use outside the laboratory scale.
(Krell, 1982)
In comparison, batch distillation and continuous distillation with multiple stages are more
convenient and efficient. We utilize a batch distillation with multiple stages in this thesis;
hence the continuous process is neglected. There are minor differences between the
continuous and batch processes, and it is mainly capacity dependent, which one is more
feasible. Figure 2. shows a schematic view of a fractional batch distillation system used in this
thesis. (Divekar, 2011)
Figure 2. Schematic drawing of batch distillation device with multiple stages. (Gorak, Sorensen, 2014)
13
The overall assembly is relatively simple, as seen in figure 2. The device consists of:
➢ Reboiler – the material is heated to its boiling point in the reboiler
➢ Fractionating column – filled with thermodynamical stages
➢ Condenser – condensing the vapor to liquid
➢ Reflux – returns desired fraction of the liquid back to the distillation column
➢ Material collection system – distilled material is led in separate flasks
There are several factors to consider in the distilling process, e.g., the properties of the
substances, boiling points, column, and equipment structure. Simple distillation is feasible if
the materials have significant differences in boiling points, over 50°C, respectively. If the
boiling points are closer, fractional distillation is required. The fractional distilling can separate
materials close to the same boiling point (0.05°C – 0.5°C). The effect of the fractional column
is dependent on chosen materials and column types. In this thesis, the distillate composition
is unknown, but we know that the majority is Methanol. (Krell, 1982) We have acquired this
specific fractional distillation equipment because we don't know the feed composition and
the future development possibilities.
2.2. Distillation system
Here, we consider the different parts of the distillation system. The components are limited
to laboratory equipment. This thesis does not consider industrial scale, as it is not in the scope
nor of interest for us.
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2.2.1. Reboiler
In the distillation system, the material must be heated to vaporize material and achieve
separation, depending on material-specific boiling points. There are a few different types of
reboilers, and it is up to the final process, which is the best available option. The few common
reboilers to mention are jacketed kettle reboiler, thermo-siphon reboiler, and internal boiler.
The latter ones are more common in large-scale industries, such as oil stripping, and are in no
interest for us. In our system, the reboiler is the jacketed heater-type. (Tham, 2016) The
function is relatively simple since it is a resistive heating mantle for the distilling flask, see
figure 2. The operation is done either manually or from the software by hand or automatically
through the programmable recipe. The heat flux is excellent to the glass flask, and heating is
fast.
Figure 3. A schematic view of the heating mantle. (BriskHeat, 2021)
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2.2.2. Distillation column
The distillation column is an essential part of the distillation system since most of the
separation occurs. As the reboiler, the column type and design depend on the final application.
Generally, the fractional distillation industry uses various packing materials in the column. The
packing could be bubble caps, sieve, or valve trays, or anything else for that matter; the only
thing to consider is that the filling must react with the distillate, and it should withhold
temperature. The purpose of this packing is to maximize the surface area on which the vapor
condenses. The column designers use simulation software to determine the column
dimensions and packing. Still, it is possible to do it manually with, e.g., the McCabe-Thiele
method, introduced in the later chapters. In addition to dimension determination, the design
verifies that the column can reach the desired purities in the chosen process. (Tham, 2016)
We will conduct multiple operations on our instrument. The system is designed for a more
complex application, which enabled us to neglect the design part while purchasing the system;
hence the design review is for theoretical review only.
The packed columns are called fractionating columns, and this is the option we are utilizing in
this thesis. The difference with these column types is the possibility to achieve purer distillate
with the fractionating column due to multiple distillations by one process. The column, which
we use is a spinning band column with fifty theoretical plates. The spinning band column
should achieve exceptional results in our application, which is to purify Methanol. Figure 4.
illustrates the theoretical function of fractional distillation. (Tham, 2016)
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Figure 4. Theoretical fractional distillation. (Clark, 2020)
Here, the given substances A and B are distilled. If we boil at point C1, we will reach a mixture
of A and B with roughly the same concentration, C2. If we were to refine that mixture further,
we would reach the point of C3, where the liquid would contain more substance B.
Furthermore, with this example, we could reach even more condensed with substance B. In
this process, there are two theoretical stages (reboiler is considered as one). This is the basic
principle behind fractional distillation.
The mass transfer in distillation takes place at the phase interphases in the column. The reflux
from the condenser inflicts material transfer between liquid and vapor, which is the critical
difference between simple and countercurrent distillation. Figure 5. simplifies the material
17
transfer at the column stages and the reflux from the condenser back to the boiler. (Krell,
1982)
Figure 5. Simple illustration of a packed column in batch distillation. (Krell, 1982)
The mass transfer takes place here in the column as well as in the boiler. In the distilling
process, the concentrations increase in both the vapor and the liquid phases. At the start of
the distillation process, the first vapor, which reaches the condenser, has the same
composition as the boiler. The vapor fully condensates and returns to the boiler through the
column. The vapor in the column holds more of the lighter component. The net transfer is
towards the liquid; as we descend the column, the net transfer shifts towards the more
lightweight component, enriching the vapor with the lighter component. The material
exchange continues until the system reaches equilibrium, and the heavier elements return to
the boiler. (Krell, 1982)
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2.2.3. Condenser
The purpose of the condenser in distillation is to condense the rising vapors back to liquid. The
main difference between these condensers is the design and cooling capabilities, see Figure
6. Various condenser designs are available on the market, such as Graham, Dimroth, and
Friedrichs, all named after their developer. (Krell, 1982)
Figure 6. Different condenser designs. (ChemDraw).
The critical parameters affiliated with the condenser are temperature, heat flow, and material
flow. These parameters will decide whether the cooling capability is adequate for the specific
process. The condenser must remove the heat flow from the rising vapors fast enough for the
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vapor to cool and condense back to liquid before passing the condenser. The material flow
here refers to the cooling material flow; this also affects the cooling capability. The
fundamental difference between the mentioned condensers is the cooling area, which is
specific to each condenser. The pragmatic view here is, the more significant the cooling
surface area, the better the cooling capability, assuming other parameters remain constant.
(Krell, 1982) In addition, the coolant flows direction affects the cooling capacities. We are
using downstream cooling flow, which yields us adequate cooling.
2.2.4. Reflux ratio
The purpose of the reflux flow in distillation is to return the chosen amount of substance to
the distillation column to achieve better separation. The reflux is given as the ratio between
the removed liquid and liquid returned to the distillation column. There are two basic
operations for reflux in the batch process: constant reflux and constant composition reflux.
The difference between these operations is that the constant reflux is held at the same value
throughout the separation process, whereas the constant composition reflux is varied. The
constant composition reflux process requires more input in the process planning as the reflux
ratio must increase steadily as the distillation continues; this explains the latter process. The
overall result will be the same product-wise, but the processing time is shorter when the reflux
ratio is varied. The same product quality is that the constant reflux ratio will be higher than
required at the distillation start and vice versa. Figure 7. illustrates the differences between
these processes, as well as the optimal process. (Gorak, Sorensen, 2014)
20
Figure 7. (a) constant reflux, (b). constant composition, (c). optimal reflux. (Gorak, Sorensen, 2014)
2.3. Controlling the batch distillation process
There are numerous parameters, which affect the overall distillation process. These are, e.g.,
temperatures, pressures, flow rates, and different levels such as reflux ratio. All these affect
one another, hence changing one parameter usually involves at least another parameter. This
study is not involved in the feed's composition or the distillation equipment design, so we are
left with three parameters to adjust the distillation process: process pressure, temperature,
and reflux ratio. Methanol must be distilled at atm because lower pressure would cause
boiling at a lower temperature. Also, the heating should remain calm to give the condenser
time to cool down the vapors, so the reflux ratio is the only parameter to adjust. Since the
process is not time-dependent, we use a constant reflux ratio to keep it simple. (Linninger,
2004)
We initially collected the lighter fractions in the test runs, roughly three to six degrees below
the Methanol's boiling point. After the first fraction, the actual production fraction is collected
using the boiling point from literature + 0.5°C – 1.0°C. (Safety data sheet, Methanol, 2021) The
21
equipment is software controlled, which means that it automatically collects two fractions and
leaves the third in the reboiler. These settings are altered experimentally in the experiment
section. The most important factors to consider during the process are the adequate cooling
of the vapors, flooding of the column, pressure (if low pressures are used), and boiling. The
condenser temperature should be monitored to ensure the total condensing of the vapors.
The passing vapors could harm the system if the chemical reaches, e.g., the vacuum pump,
which is chemical resistant to only some extent. The flooding of the column has a direct effect
on the efficiency of the column. In this system, actual flooding cannot be seen, so the reflux
and the boiling are the key factors to monitor here. There is a tip on the top of the column,
which can be used to check the reflux from the condenser; if the backflow is nice drizzle, the
boiling and the condensing are optimum. The system has two points of temperature
measurement; the boiling flask and at the top of the column. With the VLE-data for this exact
system, we can determine the composition at each point when the pressure is set to constant.
(Linninger, 2004)
2.4. Vapor-liquid equilibrium
In this thesis, we are studying the mixture of polymer synthesis waste. The assumed solution
contains mainly Methanol and NMP. The boiling points for these substances are methanol
64.7°C (Safety data sheet, Methanol, 2021) and n-methyl-pyrrolidone 202°C (Safety data
sheet, n-methyl-pyrrolidone, 2021) at atm. The VLE graphs for such a system are presented in
the following figures. For the initial calculations, the following parameters were used:
Table 1. Antoine's parameters for chosen substances. (Dortmund data bank, 2021)
No. A B C Tmin Tmax
NMP (1) 7.54826 1979.68 222.2 6 206
Methanol (2) 7.9701 1521.23 234 65 214
Antoine Equation Parameters (P in mmHg, T in °C)
22
Table 2. Liquid mole fraction of Methanol. (Dortmund data bank, 2021)
The vapor pressures of this system are calculated with Antoine's equation:
𝑙𝑜𝑔10(𝑝) = 𝐴 − [𝐵
(𝑇+𝐶)] (1)
where p Vapor pressure of a substance
T Temperature, K
P [kPa] xMeOH [mol/mol]
0.4706 0
2.6904 0.05
4.71 0.102
5.03 0.112
6.679 0.148
9.401 0.199
12.37 0.245
12.69 0.251
16.56 0.307
22.27 0.386
30.27 0.479
34.36 0.523
42.95 0.608
46.9 0.643
51.09 0.679
58.71 0.751
62.53 0.781
69.5 0.846
72.59 0.877
75.25 0.902
77.72 0.923
82.931 0.98
84.59 1
23
A, B, and C Substance specific Antoine's constants
Figures 8. And 9. illustrates the system in constant pressure and the temperature change
effects on the composition of vapor and liquid phases in the chosen system. The figures are
presented and calculated in the following graphs according to the experimental data shown
in Table 2. The calculated pressures from Eq (1) are presented in table 3.
Table 3. Calculated pressures for the NMP-methanol system.
T [K] T [°C] P [kPa]xmethanol
[mol/mol]xNMP [mol/mol]
Psat,methanol
[mmHg]Psat,NMP [mmHg] PTot [mmHg]
ymethanol
[mol/mol]yNMP [mol/mol]
475.10 201.95 0.47 0.00 1.00 0.00 1.00 1.00 0 1
428.00 154.85 2.69 0.05 0.95 0.05 0.95 1.00 0.05 0.95
405.83 132.68 4.71 0.10 0.90 0.10 0.90 1.00 0.102 0.898
402.81 129.66 5.03 0.11 0.89 0.11 0.89 1.00 0.112 0.888
393.79 120.64 6.68 0.15 0.85 0.15 0.85 1.00 0.148 0.852
384.32 111.17 9.40 0.20 0.80 0.20 0.80 1.00 0.199 0.801
377.80 104.65 12.37 0.25 0.76 0.25 0.76 1.00 0.245 0.755
377.05 103.90 12.69 0.25 0.75 0.25 0.75 1.00 0.251 0.749
370.89 97.74 16.56 0.31 0.69 0.31 0.69 1.00 0.307 0.693
364.07 90.92 22.27 0.39 0.61 0.39 0.61 1.00 0.386 0.614
357.84 84.69 30.27 0.48 0.52 0.48 0.52 1.00 0.479 0.521
355.36 82.21 34.36 0.52 0.48 0.52 0.48 1.00 0.523 0.477
351.18 78.03 42.95 0.61 0.39 0.61 0.39 1.00 0.608 0.392
349.66 76.51 46.90 0.64 0.36 0.64 0.36 1.00 0.643 0.357
348.18 75.03 51.09 0.68 0.32 0.68 0.32 1.00 0.679 0.321
345.49 72.34 58.71 0.75 0.25 0.75 0.25 1.00 0.751 0.249
344.45 71.30 62.53 0.78 0.22 0.78 0.22 1.00 0.781 0.219
342.36 69.21 69.50 0.85 0.15 0.85 0.15 1.00 0.846 0.154
341.42 68.27 72.59 0.88 0.12 0.88 0.12 1.00 0.877 0.123
340.70 67.55 75.25 0.90 0.10 0.90 0.10 1.00 0.902 0.098
340.10 66.95 77.72 0.92 0.08 0.92 0.08 1.00 0.923 0.077
338.57 65.42 82.93 0.98 0.02 0.98 0.02 1.00 0.98 0.02
338.06 64.91 84.59 1.00 0.00 1.00 0.00 1.00 1 0
24
Figure 8. T-x-y plot for Methanol.
Figure 9. T-x-y plot for NMP.
25
For both substances, the partial pressures in liquid are calculated, as stated previously,
according to Antoine's equation. We can calculate the partial pressure in vapor; here, the total
pressure is set to 760 mmHg. Results are shown in figure 10.
Figure 10. NMP-methanol system.
Figures 11. and 12. show the effect of the total pressure of the NMP-methanol system on each
substance, respectively.
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Figure 11. Effect of total pressure in NMP-methanol system in Methanol's state of matter.
Figure 12. Effect of total pressure in NMP-methanol system in NMP's state of matter.
27
From the VLE data, we can construct a design for a necessary distillation column for the
application – McCabe – Thiele method, which is handled more thoroughly in the next chapter.
2.4.1. McCabe – Thiele method
The design of a distillation process usually requires a rigid simulation for the whole process.
Several programs are available to conduct this task, such as HYSYS, ChemCAD, and Aspen, to
name a few. This software requires detailed knowledge of energy and material balances,
including dynamic equilibrium calculations making these quite complex. A few of these models
are presented for illustration purposes later in this thesis. As mentioned, our instrument is
predefined, so it is not feasible to do rigid simulation at this point. Hence, a simpler McCabe-
Thiele -method is introduced. The technique has a few assumptions, making it easier to
understand and more usable when the mentioned software is unavailable or not desired. We
must make assumptions with the more straightforward method, e.g., binary mixture, constant
pressure, no heat losses. These assumptions suit us, and these parameters are neglected when
constructing the McCabe-Thiele -diagram. Since we have these assumptions, we have a molar
overflow assumption, which means we have constant vapor and liquid streams in both
sections; rectification (over the feed stage) and stripping (under the feed stage). The column
balances are expressed as follows:
𝑅𝑒𝑐𝑡𝑖𝑓𝑦𝑖𝑛𝑔 𝑠𝑒𝑐𝑡𝑖𝑜𝑛: 𝑦 = 𝐿
𝑉 𝑥 +
𝑥𝐷𝐷
𝑉 (2)
𝑆𝑡𝑟𝑖𝑝𝑝𝑖𝑛𝑔 𝑠𝑒𝑐𝑡𝑖𝑜𝑛: 𝑦´ = 𝐿′
𝑉′ 𝑥 −
𝑥𝐵𝐵
𝑉′ (3)
where y mole fraction of component in the vapor, rectifying section, mol
28
y´ mole fraction of component in the vapor, stripping section, mol
x mole fraction of component in the liquid, mol
xD mole fraction of component in the distillate, mol
xB mole fraction of component in the bottom product, mol
D distillate flow, mol/h
L total flow rate in the liquid, rectifying section, mol/h
L´ total flow rate in the liquid, stripping section, mol/h
V total flow rate in the vapor, rectifying section mol/h
V´ total flow rate in the vapor, stripping section, mol/h
The initial phase is to calculate the operating lines for rectifying and stripping sections with
the given equations. Since we do not have exact information about the system, we assumed
a few parameters to conduct the calculations. These are feed composition (q), distillate (XD),
and bottoms product (XB). In this graph, the reflux ratio was set to 0,5, whereas the actual
experiments varied this parameter. The operating lines are in Figure 10. The equilibration data
presented here were acquired from the data in the last chapter. (Górak, Sorensen, 2014)
29
Figure 13. Top and lower operating lines.
The desired bottom product is set to 1.0%, and the distillate purity is 99.0%. We have assumed
a constant composition of 50 mol-% of the more volatile component; hence, ZF is 0.5. The next
step is to determine how many stages the system would require to reach the desired result
with these parameters and assumptions, see Figure 13.
30
Figure 14. Theoretical stages are needed to reach a purity of 99% of Methanol.
The number of ideal stages for this kind of system is 3 – 1 = 2. The first stage is always counted
as the reboiler; hence it is neglected. These calculations are made with assumptions, and the
example is for illustration. The analysis for the number of stages considers the stage efficiency:
the number of theoretical trays/stage efficiency. Also, the feed stage should be regarded as it
depends on whether we have saturated vapor or liquid; this is neglected here because the
system used in the experimental part is set to have fifty theoretical plates, and there is no
possibility to change the feed line, it is the reboiler by default. (Tham, 2016)
A summary for the McCabe-Thiele method is as follows:
➢ Determine x-y diagram for the desired system, add the x = y -line
➢ Find, or assume, the bottom and distillate conditions
31
➢ Add the q-line
➢ Add top and lower operating lines
➢ Add step stages from top to bottom until the bottom is reached.
The McCabe-Thiele method is a pragmatic view to column design and is used here because
the system used in this thesis is predesigned and not made solely for this exact process.
(Górak, Sorensen, 2014)
2.4.2. Activity models
The purpose of this chapter is to give a brief idea of what kind of models could be used in
describing acquired data in the VLE process. Therefore, the chapter is expecting some level of
knowledge on the subject beforehand. In this thesis, we consider only non-ideal binary
mixtures and the models selected for the review, which are the most suitable for this
application. The models are Wilson's equations, the NRTL model, and UNIQUAC. These models
are used in the column and the distillation system design. (Elliot, J. 2012)
Wilson's equation predicts the activity coefficients in binary solutions when experimental data
is not available. The lack of empirical information forces us to estimate the results from
theoretical correlations. Van Laar and Margules equations are like these but require actual
data to get acceptable results. The significant difference, which Wilson proposed was the
concept of local composition, dealt with in the previous chapter. To calculate binary VLE data
using Wilson's method, we need the following equations:
32
The activity coefficient for component 1:
ln 𝑦1 = − ln(𝑥1 + 𝑥2Λ12) + 𝑥2 (Λ12
𝑥1+ 𝑥2Λ12−
Λ21
𝑥1Λ21+ 𝑥2) (4)
The activity coefficient for component 2:
ln 𝑦2 = − ln(𝑥1 Λ21 + 𝑥2) − 𝑥1 (Λ12
𝑥1+ 𝑥2Λ12−
Λ21
𝑥1Λ21+ 𝑥2) (5)
And the calculation for the variables and
Λ12 = 𝑉2
𝑉1exp (
−𝐴12
𝑅𝑇) , Λ21 =
𝑉1
𝑉2exp (
−𝐴21
𝑅𝑇) (6)
where 1 and 2 are the activity coefficients for components 1 and 2
x1 and x2 are the liquid mole fractions of components 1 and 2
V1 and V2 are the molar volumes of components 1 and 2
ij is the interaction energy between i and j
R is the gas constant,
T is the temperature in Kelvin, K
33
The strategy here is to solve parameters 12 and 21 initially, and after, we can solve the
activity coefficients of Wilson's equation. Then, we can achieve partial pressures when we
apply the gained values to the modified Raoult's law. This method is usually utilized through
simulation software, such as Aspen Plus. (Elliot, J., 2012)
The UNIQUAC is a continuum to Wilson's equation, making a few changes in the initial
equation. The first significant difference is that the model depends on surface area rather than
volumes. Wilson's equation assumes that ij = ij, whereas the UNIQUAC model expects the
local composition to depend on a relative surface area of a molecule. For a binary mixture, the
UNIQUAC activity models are as follows. (Elliot, J. 2012)
ln 𝛾1 = ln1
𝑥1+ (1 −
1
𝑥1) − 5 𝑞1 [ln
1
θ 1+ (1 −
1
θ1)] + 𝑞1 [1 − ln(θ1 + θ2𝜏21) −
θ1
θ1+ θ2𝜏21−
θ2𝜏12
θ1𝜏12 + θ2] (7)
ln 𝛾2 = ln2
𝑥2+ (1 −
2
𝑥2) − 5 𝑞2 [ln
2
θ 2+ (1 −
2
θ2)] + 𝑞2 [1 − ln(θ1𝜏21 + θ2) −
θ1 𝜏21
θ1+ θ2𝜏21−
θ2
θ1𝜏12 + θ2] (8)
As seen here, the UNIQUAC model is much more complex than the Wilson model. In the
activity equations, f is molecular volume fractions, and q is the surface fractions. However,
there are two different parameters to adjust in both, and the Wilson equation gives almost as
good predictions as UNIQUAC and is applicable at least in this thesis's practices. The significant
difference here is that the UNIQUAC model is also functional in the liquid-liquid simulations,
whereas the Wilson model is not applicable. (Elliot, J. 2012)
34
The third applicable model for VLE modeling is NRTL (Non-random two liquid). The model is
also widely used in phase equilibria calculations. The model has three separate variables,
which are determined by regression of experimental data. The NRTL model is applicable in VLE
calculations as well as with LLE calculations. The NRTL is comparable to Wilson's equation but
except that NRTL applies to liquid-liquid systems. The activity coefficient calculation with NRTL
is as follows:
ln 𝛾1 = 𝑥22 [
𝜏12𝐺12
(𝑥1𝐺12+ 𝑥2)2 + 𝜏21 ( 𝐺21
x1+ 𝑥2𝐺21)
2
] (9)
ln 𝛾2 = 𝑥12 [
𝜏21𝐺12
(𝑥1+ 𝑥2𝐺21)2 + 𝜏12 ( 𝐺21
x2+ 𝑥1𝐺21)
2
] (10)
The NRTL model neglects thermodynamic integration as there is an assumption that free
energy equals excess Gibbs's energy. The parameter introduced in the final equation is a
literature value with an energy unit. (Elliot, J. 2012)
When applied through the mentioned software, we get the simulated results as in Figure 15.
Here, we can conclude that the NRTL model parameters describe NMP-MeOH -system in the
liquid state, but all three models are similar in the vapor state. Hence, it would be feasible to
use the NRTL model on the system at hand. (Zegeibh, Takache. 2021)
35
Figure 15. UNIQUAC, NRTL, and Wilson's models compared to experimental data.
2.4.3. Tray efficiency and HETP
In the distillation column, the vapor and liquid are in contact. While conducting a theoretical
estimation of a distillation column, such as the McCabe-Thiele method, the assumption is that
the two phases are in equilibrium, and the plates function at maximum efficiency. This is not
the case for most real systems because of not enough contact between phases or not enough
mixing. A few different models are available, which describe the tray efficiency, from simple
models to more complex ones. Height equivalent to theoretical plates (HETP) is used to
consider the height of the packing, which could achieve the same separation as theoretical
plates. The method is mainly in use with packed columns. As we consider the tray column, it
is more feasible to estimate the plate efficiency by, e.g., Murphree's vapor efficiency since it
does not consider what kind of packing is used. The Murphree's vapor efficiency is as follows:
36
𝐸𝑀𝑉 = 𝑦𝑛,𝑖 − 𝑦𝑛−1,𝑖
𝑦𝑛,𝑖∗ − 𝑦𝑛−1,𝑖
(11)
The composition of the vapor phase determines the vapor efficiency as it reaches a plate and
leaves the plate. The term, 𝑦𝑛,𝑖 – 𝑦𝑛−1,𝑖, is the actual change of composition in each tray, and
term 𝑦𝑛,𝑖∗ − 𝑦𝑛−1,𝑖, is the change in equilibrium case. Murphree's method assumes a perfect
mixing on each tray. This model would be a valid model to calculate the actual tray quantity
needed for this separation, but it is not necessary because of the setup used in this thesis.
(Burns, 1969)
Murphree's method is a popular choice for estimating tray efficiency. It is closer to actual cases
than overall efficiency calculation but more straightforward to use than a more precise local
efficiency method. (Geankoplis, 2013)
37
3. Commercial distilling devices
Before this thesis, a batch distillation system had to be acquired to conduct the empirical part
of the study. There are numerous commercial systems readily available on the market. The
starting point for us was the final application. From this initial fact, we knew that we had to
search for a fractional distilling device. Here is an overview of the considered options.
3.1. BR Instruments
BR Instruments has a variety of solutions for distilling applications. The spinning band column
system was our primary focus. The system has a boiler, spinning band column, reflux, and a
condenser. In addition, there is a vacuum system and a chiller as an option. The spinning band
column in the thermodynamical sense has fifty theoretical plates. The spinning band is a
Teflon helix located inside the column. Temperature is measured at the pot and the top of the
column. The system is equipped with software, enabling automatic control of the process from
start to finish. This kind of system is well suited to our needs, as reached purities are >99%,
and ease of use. The system is equipped with two fraction collectors by default, and it is
expandable to four collectors. An illustration of the system is in Figure 16, excluding the
vacuum pump. (Br instruments, 2021)
38
Figure 16. The Br Instrument's fractional distilling device. (Br Instruments, 2021)
3.1.1. BR Instruments software
Automation was one key component when deciding since the distillation would be relatively
long. The chosen instrument has software, which controls the overall setup. This is a
convenient way to use the system, and because of the software, the whole system is semi-
automatic. This will enable the system to work also outside business hours. The software's
front page is shown in Figure 17. (Br Instruments, 2021)
39
Figure 17. Start screen of BR9600. (Br Instruments, 2021)
From the "Manual controls," the user can manually control the system, see Figure 18.
40
Figure 18. Manual controls of the BR9600 instrument. (Br Instrument, 2021)
In the previous Figure, there is shown the parameters, which could be controlled manually.
These are Condenser bath temperature, Band motor, Reflux valve, and vacuum level. The
range for the vacuum is 0 mmHg to 100 mmHg, so the window is relatively narrow. The
"Manage Run Data" -menu lets the user check, change, or create new recipes. The following
Figure shows an example recipe for methanol distillation. (Br Instruments, 2021)
41
Figure 19. The recipe window for Br 9600 instrument. (Br Instruments, 2021)
Here, the user can define the desired distillation recipe. First, the user must specify the run
pressure, heating, equilibration time, number of cuts, and maximum pot temperature. The
parameters are explained next.
Table 4. the parameters from the previous Figure.
1. Run pressure Overall pressure where the distillation is conducted
2. Initial heat Heat in the beginning
3. Equilibration Equilibration time before 1st cut is taken out
4. Number of cuts A user-defined nr. of cuts. We have a maximum of two cuts, limited by the receiver's quantity. Up to eight would be possible
5. Max pot temperature Maximum temperature for the distilling pot will end the process if reached
6. Cut number Number of the cut, which is in process
7. Open cut The temperature where the cut is taken out
8. Close cut The temperature where the cut is finished, if the second one, this will end the process
9. Reflux ratio The reflux ratio - explained in the previous chapters
10. Heat rate The heat rate which heats the distilling pot
11. Condenser Temp. Condenser temperature
42
The last menu will let the user start the distillation, "Start distillation." After choosing this
option, the software forces the user to select the appropriate recipe and check that the
instrument is ready for the start.
Figure 20. Start of the distillation. (Br Instruments, 2021)
After the start of the distillation, the user can see the logged data as in Figure 21.
43
Figure 21. The logged data screen. (Br Instruments, 2021)
In addition to the previous, the software allows the user to see which step is underway, as in
Figure 22.
44
Figure 22. Software show which steps are done. (Br Instruments, 2021)
Figure 19. is the same as shown previously, but here, the run has ended. The dark grey color
indicates which step is done. The data output, which the software records, are as in Figure 21.
45
Figure 23. Methanol distillation with BR9600.
Here, we can see a few of the parameters the system will log. The data is from the methanol
distillation process. The process starts from scratch and will heat the pot to vaporize the
Methanol. The equilibration time is set to four hours to maximize the purity of our product.
The first cut is collected after the equilibration. We can conclude from the data that there is a
relatively small quantity of low boilers, as the system will start the methanol distillation almost
straight after that time, see Figure 21. The change between cuts is so fast that the logging
period cannot record the change. The overall process time was roughly twelve hours, and the
process stopped after the vapor temperature reached the given parameter, 65.5°C.
46
Figure 24. The exact Figure is the nr. 20, but the time scale is shortened to illustrate the change between cuts.
In the data, there are other parameters also, which indicate the different phases of the
process. These are the run mode and cut. The run mode indicates the stage the system is in
at the given moment, and the cut tells the users which cut is under distilling at which point.
(Br Instruments, 2021)
3.2. Goel Scientific
The second option was Goel Scientific. They offer a fractional distilling device with roughly the
same setup as the previous one. However, the total system is somewhat more complicated
47
and more laboratory-like compared to the last. The solvent recovery system's schema is
presented in Figure 25.
Figure 25. Schematic illustration of Goel's instrumentation. (Goel Scientific, 2014)
As stated, the overall system is the same with both, but the Goel system has more piping and
glassware. The column packing or the packing material was not made aware of at the time of
inquiries. The weakness here is the lack of software and software drivability, making this a
non-standalone system. There is also the possibility of collecting two fractions in this system
because of the piping and valve system. (Goel Scientific, 2014)
48
3.3. Sigma scientific glass
The third option was Sigma Scientific, which has various options for distilling processes. The
setup is comparable to the latter one. The same options are available, like a vacuum and
different heating mantles. The column here is a fractionating column, which is the only
information we have about this one. The difference here is the one fraction collection by
default; see Figure 26. The equipment itself would still be valid for our application. There are
still the same features lacking, which the latter system lacks too. The BR Instruments has the
software advantage over their Indian counterparts. The software is a considerable
improvement to the process as the software is programmable for a specific purpose. (Sigma
Scientific Glass, 2021)
Figure 26. The Sigma Scientific's fractional distillation system. (Sigma Scientific Glass, 2021)
49
3.4. Comparison of commercial distillation systems
These were the options, including building the system ourselves. The overall solution,
software, and the response to our application needs were the conclusive factors in this
decision-making. Technical specifications are presented in Table 5.
Table 5. A comparison of the technical data of the systems.
Column Distillation
flask
Condenser Heater Condensing
bath
Reflux Fraction
collector
Br
Instruments
Teflon
spinning
band.
22 dm3 Inner coil +
outer
jacket
Kettle -20 °C – 140
°C
Automatic Up to 8
fractions
Goel
Scientific
Packed
column
20 dm3 A = 0.35
m2
Kettle Optional Manual Manual
Sigma Glass Packed
column
20 dm3 A = 0.35
m2
Jacketed Optional Manual Manual
All systems also had an optional vacuum system, which was essential as we wanted low-
pressure distillation. From a technical point of view, the Br Instrument stands out with a more
automatic system than its rivals. The two latter ones have similar systems in parameters. From
a stand-alone point of view, we decided to purchase the Br Instruments system.
50
4. Experimental section
The experimental study took place at the polymer laboratory of the company in question.
Moreover, the material was acquired from the actual polymer synthesis process from the
precipitation and washing processes. These processes happen in various steps, and the
material was collected from arbitrary phases. Therefore, the material is suspected of
containing Methanol, NMP, and different other unknown salts and chemicals. The goal was to
acquire as pure solvent as possible with the fractional distilling device. The overall distill was
analyzed by a third-party operator since we do not have the facilities available for analysis.
4.1. Solvents
Methanol is toxic alcohol, which is at atm a colorless liquid and withholds a distinct odor. The
chemical is widely used, e.g., as a solvent or anti-freeze substance. The toxicity is caused by
ingesting the substance as the human body will oxidize the chemical to formaldehyde and
carbon dioxide. NMP, on the other hand, is not toxic, although it has been illustrated to affect
the reproductive system in large or long exposures. NMP is also a widely known and used
solvent in the drug and polymer industry. NMP is also set on a watch list by the ECHA, which
is the main reason we want to clean the solvent and decrease the overall consumption. (Safety
data sheet, Methanol. 2021, Safety data sheet, n-methyl-pyrrolidone, 2021)
4.2. Test distillations
The samples are collected from the different process stages, so the solvents should be as dirty
as possible, a worst-case scenario. As mentioned previously, the total content of the waste is
unknown and not interesting in this sense. We know that most waste is Methanol; hence, the
51
test phase purifies the methanol fraction. The test material was collected in a joint container
to get the maximum dissolved material in the distilling pot. The material collection happened
from different batches and different stages of the process. Four separate process tests were
conducted. All processes used different settings for the parameters up for variation; see Table
6. Constant parameters were:
1. Run pressure, 760 mmHg
2. Number of cuts, 2
3. Condenser temperature, 0°C
Table 6. Test run parameters
1st test 2nd test 3rd test 4th test
Equilibration time 10 min 30 min 60 min 240 min
Max. pot temperature 66°C 75°C 75°C 80°C
Open 1st cut 60°C 60°C 62°C 62°C
Close 1st cut 64°C 64°C 64°C 64°C
Reflux ratio, 1st cut 5:1 2:1 2:1 2:1
Open 2nd cut 64°C 64°C 64°C 64°C
Close 2nd cut 65°C 65°C 64.5°C 64.5°C
Reflux ratio, 2nd cut 5:1 3:1 5:1 5:1
The test sequence was constructed with the aid of suppliers' application notes and according
to best guess. The equilibration time is between the start of the boiling and before the 1st cut
is taken out. The cuts are collected automatically by the fraction collector. The overall purpose
was to iterate the process parameters to reach the desired goal – to optimize the process
52
according to purity. In the test runs, the goal was to achieve desired purity for Methanol
(~99%). The results are evaluated in chapter 5.
4.3. Analysis methods
The test run products were analyzed by two different methods: Gas chromatography and Karl-
Fischer titration. The prior one is used in this case to study the content of the sample, and the
latter is to determine the residue water content of the samples. The analysis was conducted
in collaboration with a third party, as we do not have this capability in-house.
4.3.1. Gas chromatography
The purified samples were sent to Gas chromatography analysis; moreover, HS-GC-MS
(Headspace gas chromatography with mass spectrometer). The method is suitable for the
quantification of the selected solvent. The sample is vaporized into the GC's column in the GC
analysis, and the retention time is measured. The overall system is composed of Figure 27.
Figure 27. Schematic illustration of HS-GC-MS. (Emvas et al., 2015)
53
The carrier gas used is usually nitrogen due to its inert nature. In the headspace oven, the
samples are put into a vacuum and vaporized. The sample is taken from the gas phase and
sucked into the GC oven, where the actual column is placed. The column is equipped with a
suitable stationary phase. Different molecules from the headspace reach the detector at
various times; hence it is possible to determine the sample's composition. The retention time
is affected by the molecule's molecular weight and polarity of the molecule. From this
information, we can determine the boiling point of the molecule and its composition. The
concentration is evaluated with an internal standard. This standard is specific for different
types of molecules, and the choice of the standard is crucial for the analysis. If we want to
quantify the sample by looking at the peak area, the response factor must be determined. The
response factor method is the most common way. The response factor tends to vary from
system to system. Because of the variation could be more feasible to use the relative response
factor and internal standard mentioned earlier. This method can be used to determine an
unknown concentration with a known concentration. (Bouchonnet, 2013) Here, further
examination is neglected because the analysis is not in the scope of this thesis.
4.3.2. Karl-Fischer titration
The Karl-Fischer titration (later KFT) is a widely used water content analysis method. The KFT
is applied in multiple disciplines every day, from the food industry to the pulp and chemical
industries. In this thesis, the KFT is used alongside gas chromatography to get a broader view
of the contents of our sample, although the water content should not perturb the solvent
reuse in our application. The KFT is divided into two different sub-categories: volumetric and
coulometric. The process differs between these two, and the major decisive issue is the
expected water content. We expect to have relatively high water content, so the volumetric
54
analysis suits us. For smaller concentrations, below 1 mg/dm3, the coulometric is a better
option. (Rouessac, et al., 2007)
The volumetric KFT is started by measuring the water content of the KFT reagent for a
baseline, respectively. The humidity of the surroundings will interfere with the measurement;
hence the system must be isolated from the environment. The overall setup is as follows:
Figure 28. KFT instrumentation. (Rouessac, et al., 2007)
The KFT cell contains the sample, nitrogen, electrodes, and two different reagents. The overall
purpose is to titrate a reagent to the sample, which reacts with the water to achieve a solution
that does not conduct electricity. The amount of reagent added will determine the water
content. In other words, we measure the amount of reagent used to neutralize the water in
the sample. (Rouessac, et al., 2007)
55
4.4. Test samples
The results were analyzed according to the methods mentioned in the previous chapter—the
initial screening with GC-MS and a composition analysis with FID -detector. In addition, the
water content was analyzed with KFT. The overall test batch quantity was four. All distillations
were conducted in different settings. The settings were mentioned in chapter 4.2. The results
were compared with a pure sample, which acted as a reference measurement. The reference
was obtained straight from the manufacturer's flask and is assumed to be pure Methanol.
Below is a matrix of the test batches.
Table 7. Matrix of the samples and performed measurements.
56
The results showed that there are a few different components present in the samples. The
major components are as in table 8.
Table 8. A matrix of the components of the samples.
As we from the results, there are three additional components with Methanol. The acetone
was concluded to be present because the overall system was washed with acetone after the
actual process. The washing procedure leaves traces of acetone every time this is done. The
acetate, on the other hand, is in the samples because the acetic acid is used in the polymer
scrubbing process. The methyl acetate is a result of the condensation of Methanol in the
presence of acetic acid. The last component, 2,2-dimethoxypropane, is a side product in the
methanol condensation. This substance also requires the presence of acetone, which is there
for the previously mentioned reasons. The 2,2-dimethoxypropane forms when water is
removed, as we do in this distillation. After the distilled Methanol gets wet from the ambient,
it breaks down to Methanol and water. More detailed results are presented in the next
chapter.
57
5. Results
The results were obtained from the analysis services, which indicated the overall composition
of the sample, the quantity of the specific compounds, and the water content. The results
were as follows:
Figure 29. Chromatogram from the first test distillation.
The results show that the quantity of Methanol is proportionally large compared to other
compounds. Here, we see a high peak in the two minutes of retention time caused by the
methanol molecule. The acetone causes the second peak. Also, a small peak is caused by the
methyl-acetate, which is hard to read from the chromatogram. The last peak is from the side
product of the distillation, 2,2-dimethoxypropane. The percentage composition of the sample
was defined with FID-detector. The result was as follows:
58
Table 9. The result of the first distillation.
If we consider the setup and the distillation system, the overall purity of the sample was
relatively low. The result of roughly 94% is not pure enough to be reused in our processes.
Notable here is also the low water content, which would allow the use in future processing.
The acetone quantity is relatively high, which could yield from the instrument purification
done before this distillation.
In the second distillation, the setup was the same as before, and the parameters were
according to table 6. Below is the chromatogram of the second test batch.
59
Figure 30. Chromatogram from the second test distillation.
The result is almost identical to the first test batch. The same substances are present here
compared to the first run. Here, we can conclude that the slightly longer equilibration time
did not influence the result. The overall process time was significantly longer in the first run,
yet as we can see, there is no significant benefit of the higher reflux or, the longer run time.
The content percentages are shown in the table 10.
Table 10. The result of the second distillation.
60
The third test distillation increased the equilibration time even further, and the reflux ratio
was set to 5:1. The result is shown in figure 31.
Figure 31. Chromatogram from the third test distillation.
Here, we see the same peaks as with the previous chromatograms. We can conclude from the
result that the material, which was distilled is from the same batch as there are the same
components present. Table 11. shows the composition after the third distillation
61
Table 11. The result of the third distillation.
Now, we can conclude that the increase of the equilibration time could influence the result.
The distill cut was also decreased to 64°C – 64.5°C, which means that the distill is collected in
a narrower window, and fewer impurities are present. Overall conclusion, according to the
result, is that we were going in the right direction. The purity of Methanol was here already
almost 97%, and other substances with decreasing concentrations.
In the final distillation, the equilibration time was increased substantially. The equilibration
time was set to four hours while keeping other parameters the same as the previous test
batch. Figure 29. shows the chromatogram from the test batch.
62
Figure 32. Chromatogram from the fourth test distillation.
Here, we can conclude that the residues of other substances, besides Methanol, are relatively
low. Also, the methyl acetate peak had disappeared almost entirely. Table 12. shows the
composition of the sample.
Table 12. The result of the fourth distillation.
63
Now, we can conclude that the purity is at an acceptable level. The overall purity of the sample
is almost 99%. The fourth sample's purity is acceptable, and this material can be used for
further processing. We have concluded that the impurities in the last sample are either low or
not disrupting in the polymer synthesis process. The test results are concluded to be reliable
as these are conducted in an accredited laboratory
A reference sample was analyzed as well. The analysis showed a 100% methanol content in
the GC-MS. Also, a KFT analysis was conducted, which showed relatively high water content,
at almost 3%. The chromatogram is shown in appendix 8. The result tells us that the distilled
Methanol is purer than the supplied Methanol, although, the impurities are not present. For
our application, the contaminants do not affect the process; hence, it makes sense to reuse
the recycled solvent back to the process.
5.1. Conclusions and future considerations
In the test distillations, we observed that the increase in equilibration time had a drastic effect
on the purity of the product. In addition, increasing the reflux ratio from 1:2 to 1:5 influenced
the resulting purity when considering the second cut. The overall system is suitable for this
application, as the results show. Still, the fact that the same system is to be used in multiple
different distillations makes it difficult to optimize the equipment for a specific distillation;
hence the system is more complex than it would need to be for refining methanol. The system
is used for laboratory distillation and repossession of different solvents, so widely used design
methods within the industry are not applicable. But we have established a need for further
optimization for the process; even though reached purity of 98.8% is acceptable for our needs,
removing the rest impurities would oppose less risk on reusing the purified solvent. To obtain
an even purer solvent, the test distillations should continue to reach an optimum process
64
protocol for methanol purification. The test batches were limited to four tests within this
thesis, and only a few parameters could be optimized. The window where the distillation
system takes out the product is one of the critical components when considering the purity of
the product. This window should be examined more thoroughly in this process.
Furthermore, the continuation of the purification study will move to the next chemicals used
in the polymer process. The n-methyl-pyrrolidone's distilling holds more interest in the field
of repossession as it is a controlled substance by the ECHA. This thesis was limited to
Methanol's repossession as it was in the scope of interest quantity-wise, but the next step is
to study the purification of NMP. The quantities of used NMP are a fraction of that of Methanol
but still more crucial for us to decrease the consumption because of the aforementioned
reasons. The system, which we have acquired, is suitable for this application as well.
By implementing the suggested purification method, the savings on laboratory operating costs
could be considerable. The amount of saving we will achieve with the new process protocol
remains to be verified. The actual amount of chemicals recycled back to the process depends
heavily on the established process protocol and operator resources. The overall project is still
ongoing in which the protocol is supposed to be implemented. For current various open tasks,
the planning of this processing protocol is not a priority at the moment. The future will show
the actual savings and return on investment in that sense.
65
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68
Appendices
Appendix 1. T-xy-data from Aspen simulation for NRTL graphed in figure 14.
PR
ES
MO
LEFR
AC
ME
THA
-01TOTA
L TEM
PTO
TAL K
VL N
-ME
T-01TO
TAL K
VL M
ETH
A-01
LIQU
ID G
AM
MA
N-M
ET-01LIQ
UID
GA
MM
A M
ETH
A-01
VA
PO
R M
OLE
FRA
C N
-ME
T-01V
AP
OR
MO
LEFR
AC
ME
THA
-01LIQ
UID
MO
LEFR
AC
N-M
ET-01
LIQU
ID M
OLE
FRA
C M
ETH
A-01
in-Hg
C
7600
399,571
13,92761
0,5767461
01
0
7600,02
379,650,784826
11,54350,999885
0,5828970,769129
0,2308710,98
0,02
7600,04
362,8720,63428
9,777280,999528
0,5891320,608909
0,3910910,96
0,04
7600,06
348,6030,525072
8,440540,998908
0,5955040,493567
0,5064330,94
0,06
7600,08
336,3040,443125
7,404060,998007
0,6020410,407675
0,5923250,92
0,08
7600,1
325,5530,379805
6,581750,996805
0,6087630,341825
0,6581750,9
0,1
7600,12
316,0380,32965
5,91590,995281
0,615680,290092
0,7099080,88
0,12
7600,14
307,5210,289082
5,367070,993415
0,6227980,24861
0,751390,86
0,14
7600,16
299,8230,255683
4,907660,991186
0,630120,214774
0,7852260,84
0,16
7600,18
292,8060,22777
4,517940,988573
0,6376480,186771
0,8132290,82
0,18
7600,2
286,3630,204136
4,183460,985553
0,6453840,163309
0,8366910,8
0,2
7600,22
280,4080,1839
3,893440,982105
0,6533280,143442
0,8565580,78
0,22
7600,24
274,8720,166404
3,639720,978206
0,661480,126467
0,8735330,76
0,24
7600,26
269,7020,151145
3,415970,973833
0,6698390,111848
0,8881520,74
0,26
7600,28
264,850,137737
3,217250,968961
0,6784040,0991707
0,9008290,72
0,28
7600,3
260,280,125875
3,039620,963567
0,6871730,0881126
0,9118870,7
0,3
7600,32
255,960,115318
2,879950,957627
0,6961450,078416
0,9215840,68
0,32
7600,34
251,8630,105871
2,735660,951117
0,7053160,0698746
0,9301250,66
0,34
7600,36
247,9670,0973759
2,604670,944012
0,7146830,0623206
0,9376790,64
0,36
7600,38
244,2530,0897043
2,485220,936288
0,7242430,0556166
0,9443830,62
0,38
7600,4
240,7050,0827484
2,375880,92792
0,7339890,049649
0,9503510,6
0,4
7600,42
237,3060,0764171
2,275420,918886
0,7439170,0443219
0,9556780,58
0,42
7600,44
234,040,0706284
2,182840,909162
0,7540170,0395519
0,9604480,56
0,44
7600,46
230,8970,0653213
2,097230,898724
0,7642820,0352735
0,9647270,54
0,46
7600,48
227,8690,060444
2,017850,887553
0,7747010,0314308
0,9685690,52
0,48
7600,5
224,9470,0559522
1,944050,875627
0,7852630,0279761
0,9720240,5
0,5
7600,52
222,1250,0518074
1,875260,86293
0,7959550,0248675
0,9751320,48
0,52
7600,54
219,3980,0479762
1,810980,849443
0,8067610,022069
0,9779310,46
0,54
7600,56
216,7620,0444295
1,750810,835154
0,8176630,019549
0,9804510,44
0,56
7600,58
214,2110,0411417
1,694350,82005
0,8286410,0172795
0,9827210,42
0,58
7600,6
211,7420,0380902
1,641270,804124
0,8396710,0152361
0,9847640,4
0,6
7600,62
209,3520,0352551
1,59130,78737
0,8507290,0133969
0,9866030,38
0,62
7600,64
207,0380,0326188
1,544150,769789
0,8617830,0117427
0,9882570,36
0,64
7600,66
204,7980,0301655
1,499610,751383
0,8728020,0102562
0,9897440,34
0,66
7600,68
202,630,0278811
1,457470,732161
0,8837480,00892196
0,9910780,32
0,68
7600,7
200,5330,0257531
1,417530,712139
0,894580,00772593
0,9922740,3
0,7
7600,72
198,5060,02377
1,379650,691335
0,9052540,00665562
0,9933440,28
0,72
7600,74
196,5470,0219218
1,343650,669776
0,9157180,00569968
0,99430,26
0,74
7600,76
194,6570,0201991
1,309410,647497
0,9259170,00484779
0,9951520,24
0,76
7600,78
192,8360,0185935
1,276810,624538
0,9357910,00409058
0,9959090,22
0,78
7600,8
191,0830,0170974
1,245730,600946
0,9452740,00341948
0,9965810,2
0,8
7600,82
189,3990,0157037
1,216070,57678
0,9542930,00282667
0,9971730,18
0,82
7600,84
187,7850,014406
1,187730,552102
0,9627720,00230498
0,9976950,16
0,84
7600,86
186,2420,0131985
1,160640,526986
0,9706260,0018478
0,9981520,14
0,86
7600,88
184,7710,0120756
1,134720,501513
0,9777670,00144908
0,9985510,12
0,88
7600,9
183,3750,0110323
1,109890,475769
0,98410,00110323
0,9988970,1
0,9
7600,92
182,0550,0100638
1,086080,449851
0,9895250,000805108
0,9991950,08
0,92
7600,94
180,8140,0091658
1,063250,42386
0,9939380,000549948
0,999450,06
0,94
7600,96
179,6540,00833404
1,041320,397904
0,997230,000333362
0,9996670,04
0,96
7600,98
178,5780,00756467
1,020250,372094
0,9992880,000151293
0,9998490,02
0,98
7601
177,590,00685398
0,9999990,346546
10
10
1
69
Appendix 2. T-xy -graph of simulated results for NMP – methanol system using NRTL model
70
Appendix 3. T-xy-data from Aspen simulation for Wilson's model graphed in figure 14.
PR
ES
MO
LEFR
AC
N-M
ET-01
TOTA
L TEM
PTO
TAL K
VL N
-ME
T-01TO
TAL K
VL M
ETH
A-01
LIQU
ID G
AM
MA
N-M
ET-01LIQ
UID
GA
MM
A M
ETH
A-01VA
PO
R M
OLE
FRA
C N
-ME
T-01V
AP
OR
MO
LEFR
AC
ME
THA
-01LIQ
UID
MO
LEFR
AC
N-M
ET-01
LIQU
ID M
OLE
FRA
C M
ETH
A-01
mm
Hg
C
7600
64,53480,00413178
10,721845
10
10
1
7600,02
64,92320,00220949
1,020360,377789
1,004914,41898e-05
0,9999560,02
0,98
7600,04
65,34880,00197003
1,041590,329012
1,008847,88012e-05
0,9999210,04
0,96
7600,06
65,88910,00203031
1,06370,329135
1,008740,000121819
0,9998780,06
0,94
7600,08
66,53640,00221275
1,086760,346193
1,004990,00017702
0,9998230,08
0,92
7600,1
67,27470,00246923
1,110840,371056
0,9982920,000246923
0,9997530,1
0,9
7600,12
68,08960,00278202
1,135980,399959
0,9893420,000333842
0,9996660,12
0,88
7600,14
68,96920,00314353
1,162280,430966
0,9787020,000440094
0,999560,14
0,86
7600,16
69,90450,00355048
1,18980,462928
0,9668270,000568077
0,9994320,16
0,84
7600,18
70,88830,00400173
1,218630,495099
0,9540750,000720311
0,999280,18
0,82
7600,2
71,91540,00449742
1,248880,52697
0,9407280,000899484
0,9991010,2
0,8
7600,22
72,98170,00503858
1,280630,558185
0,9270050,00110849
0,9988920,22
0,78
7600,24
74,08450,00562694
1,314010,588493
0,9130790,00135047
0,998650,24
0,76
7600,26
75,22170,00626482
1,349150,617719
0,8990810,00162885
0,9983710,26
0,74
7600,28
76,39210,00695517
1,386180,645745
0,8851140,00194745
0,9980530,28
0,72
7600,3
77,59490,00770155
1,425270,672495
0,8712570,00231047
0,997690,3
0,7
7600,32
78,83010,00850816
1,466580,697925
0,8575710,00272261
0,9972770,32
0,68
7600,34
80,0980,00937993
1,510320,72202
0,84410,00318918
0,9968110,34
0,66
7600,36
81,39930,0103226
1,556690,744778
0,830880,00371614
0,9962840,36
0,64
7600,38
82,73520,0113428
1,605950,766218
0,8179340,00431027
0,995690,38
0,62
7600,4
84,10710,0124483
1,658370,786365
0,805280,00497932
0,9950210,4
0,6
7600,42
85,51690,0136479
1,714260,805255
0,7929310,00573216
0,9942680,42
0,58
7600,44
86,96680,0149522
1,773970,822928
0,7808940,00657899
0,9934210,44
0,56
7600,46
88,45960,0163731
1,83790,839428
0,7691730,00753164
0,9924680,46
0,54
7600,48
89,99820,0179247
1,906530,854803
0,757770,00860386
0,9913960,48
0,52
7600,5
91,58620,0196234
1,980380,869102
0,7466830,00981174
0,9901880,5
0,5
7600,52
93,22760,0214888
2,060050,882373
0,7359110,0111742
0,9888260,52
0,48
7600,54
94,9270,0235437
2,146280,894666
0,7254510,0127136
0,9872860,54
0,46
7600,56
96,68980,0258153
2,239870,906028
0,7152980,0144565
0,9855430,56
0,44
7600,58
98,52190,0283362
2,341820,916509
0,7054480,016435
0,9835650,58
0,42
7600,6
100,430,0311458
2,453280,926153
0,6958960,0186874
0,9813130,6
0,4
7600,62
102,4230,0342915
2,575630,935005
0,6866360,0212607
0,9787390,62
0,38
7600,64
104,510,0378316
2,710520,943109
0,6776640,0242122
0,9757880,64
0,36
7600,66
106,70,0418381
2,859960,950506
0,6689740,0276131
0,9723870,66
0,34
7600,68
109,0080,0464003
3,02640,957236
0,6605630,0315522
0,9684480,68
0,32
7600,7
111,4480,0516312
3,212860,963336
0,6524260,0361418
0,9638580,7
0,3
7600,72
114,0380,0576746
3,423120,968842
0,644560,0415257
0,9584740,72
0,28
7600,74
116,7980,0647166
3,661960,97379
0,6369630,0478903
0,952110,74
0,26
7600,76
119,7560,0730009
3,93550,97821
0,6296320,0554807
0,9445190,76
0,24
7600,78
122,9430,082853
4,25170,982135
0,6225660,0646253
0,9353750,78
0,22
7600,8
126,3980,0947152
4,621140,985594
0,6157680,0757721
0,9242280,8
0,2
7600,82
130,1720,109202
5,058080,988614
0,6092380,0895452
0,9104550,82
0,18
7600,84
134,3290,127186
5,582270,991222
0,6029820,106837
0,8931640,84
0,16
7600,86
138,9530,14995
6,221740,993443
0,5970070,128957
0,8710430,86
0,14
7600,88
144,1560,179428
7,017530,9953
0,5913230,157897
0,8421030,88
0,12
7600,9
150,0930,218672
8,031960,996816
0,5859430,196804
0,8031960,9
0,1
7600,92
156,9820,272705
9,363890,998013
0,5808870,250889
0,7491110,92
0,08
7600,94
165,1460,350297
11,17870,998911
0,5761790,329279
0,6707210,94
0,06
7600,96
175,0750,467847
13,77170,999528
0,5718440,449133
0,5508670,96
0,04
7600,98
187,5650,658844
17,71670,999885
0,5679090,645667
0,3543330,98
0,02
7601
203,9941
24,25931
0,5643711
01
0
71
Appendix 4. T-xy -graph of simulated results for NMP – methanol system using Wilsons model.
72
Appendix 5. T-xy -data Aspen simulation for UNIQUAC model graphed in figure 14.
PRESMOLEFRAC METHA-01
TOTAL TEMPTOTAL KVL N-MET-01
TOTAL KVL METHA-01LIQUID GAMMA N-MET-01
LIQUID GAMMA METHA-01VAPOR MOLEFRAC N-MET-01
VAPOR MOLEFRAC METHA-01LIQUID MOLEFRAC N-MET-01
LIQUID MOLEFRAC METHA-01
mmHgC
7600
203.9941
20.70241
0.4816231
01
0
7600.02
189.4660.692664
16.05950.999837
0.4954940.67881
0.321190.98
0.02
7600.04
177.6490.502858
12.93140.999335
0.5084770.482744
0.5172570.96
0.04
7600.06
167.8370.379235
10.72530.998469
0.5208480.356481
0.6435190.94
0.06
7600.08
159.5340.294951
9.108060.997221
0.532810.271355
0.7286450.92
0.08
7600.1
152.3890.235209
7.883120.995569
0.5445080.211688
0.7883120.9
0.1
7600.12
146.1490.191444
6.929410.993492
0.5560470.168471
0.8315290.88
0.12
7600.14
140.6290.158476
6.169360.990972
0.5675030.13629
0.863710.86
0.14
7600.16
135.6910.133045
5.551510.98799
0.5789290.111758
0.8882420.84
0.16
7600.18
131.2320.113026
5.040660.984526
0.5903680.0926813
0.9073190.82
0.18
7600.2
127.1730.0969889
4.612040.980564
0.6018460.0775911
0.9224090.8
0.2
7600.22
123.450.083946
4.247830.976085
0.6133840.0654779
0.9345220.78
0.22
7600.24
120.0140.0731976
3.934870.971074
0.6249980.0556302
0.944370.76
0.24
7600.26
116.8260.0642371
3.663330.965514
0.6366960.0475355
0.9524650.74
0.26
7600.28
113.8540.0566907
3.425650.95939
0.6484830.0408173
0.9591830.72
0.28
7600.3
111.070.0502775
3.216020.952688
0.6603630.0351942
0.9648060.7
0.3
7600.32
108.4540.0447834
3.029840.945394
0.6723340.0304527
0.9695470.68
0.32
7600.34
105.9870.0400429
2.863450.937497
0.6843940.0264283
0.9735720.66
0.34
7600.36
103.6540.035926
2.713910.928985
0.6965370.0229927
0.9770070.64
0.36
7600.38
101.4420.0323301
2.578830.919848
0.7087570.0200446
0.9799550.62
0.38
7600.4
99.33920.0291725
2.456240.910078
0.7210450.0175035
0.9824960.6
0.4
7600.42
97.33660.0263868
2.344510.899668
0.7333890.0153043
0.9846960.58
0.42
7600.44
95.42580.0239184
2.242290.888612
0.7457790.0133943
0.9866060.56
0.44
7600.46
93.59970.0217227
2.148410.876906
0.7581990.0117302
0.988270.54
0.46
7600.48
91.8520.0197624
2.061920.864549
0.7706340.0102764
0.9897240.52
0.48
7600.5
90.17750.0180066
1.981990.851538
0.7830660.00900332
0.9909970.5
0.5
7600.52
88.57120.0164293
1.907910.837878
0.7954760.00788606
0.9921140.48
0.52
7600.54
87.02890.0150083
1.839070.823571
0.8078430.00690385
0.9930960.46
0.54
7600.56
85.54720.013725
1.774930.808623
0.8201440.00603904
0.9939610.44
0.56
7600.58
84.12250.0125634
1.715040.793043
0.8323530.00527666
0.9947230.42
0.58
7600.6
82.75230.0115097
1.658990.776841
0.8444450.00460389
0.9953960.4
0.6
7600.62
81.43380.0105519
1.606440.760032
0.856390.00400976
0.995990.38
0.62
7600.64
80.16490.00967996
1.557060.74263
0.8681570.00348479
0.9965150.36
0.64
7600.66
78.94360.00888466
1.510570.724656
0.8797120.00302079
0.9969790.34
0.66
7600.68
77.76830.00815826
1.466750.70613
0.891020.00261064
0.9973890.32
0.68
7600.7
76.63750.00749389
1.425360.687078
0.9020440.00224817
0.9977520.3
0.7
7600.72
75.54990.00688549
1.386210.667526
0.9127430.00192794
0.9980720.28
0.72
7600.74
74.50450.00632772
1.349130.647508
0.9230730.00164521
0.9983550.26
0.74
7600.76
73.50020.00581585
1.313950.627055
0.9329910.0013958
0.9986040.24
0.76
7600.78
72.53640.00534567
1.280540.606206
0.9424470.00117605
0.9988240.22
0.78
7600.8
71.61250.00491345
1.248770.585002
0.9513920.000982691
0.9990170.2
0.8
7600.82
70.7280.00451584
1.218520.563487
0.9597720.000812852
0.9991870.18
0.82
7600.84
69.88270.00414985
1.189690.541707
0.9675330.000663976
0.9993360.16
0.84
7600.86
69.07630.0038128
1.162170.519715
0.9746160.000533791
0.9994660.14
0.86
7600.88
68.30890.00350226
1.135890.497564
0.9809620.000420271
0.999580.12
0.88
7600.9
67.58050.00321607
1.110750.475311
0.9865090.000321607
0.9996780.1
0.9
7600.92
66.89130.00295226
1.08670.453017
0.9911930.000236181
0.9997640.08
0.92
7600.94
66.24160.00270905
1.063660.430744
0.9949490.000162543
0.9998380.06
0.94
7600.96
65.6320.00248484
1.041560.40856
0.9977139.94E-05
0.9999010.04
0.96
7600.98
65.06280.00227817
1.020360.386533
0.9994184.56E-05
0.9999540.02
0.98
7601
64.53480.00208771
10.364735
10
10
1
73
Appendix 6. T-xy -graph of simulated results for NMP – methanol system using UNIQUAC model.
74
Appendix 7. The chromatogram of the 1st distillation.
75
Appendix 8. The chromatogram of the 2nd distillation.
76
Appendix 9. The chromatogram of the 3rd distillation.
77
Appendix 10. The chromatogram of the 4th distillation.
78
Appendix 11. The chromatogram of the reference distillation.
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