Separation Synthesis Learning Outcomes PDF

Summary

This document covers learning outcomes related to separation synthesis. It details different methods for separating mixtures and the importance of separations in chemical plants. It includes information about industrial separation techniques and their underlying principles.

Full Transcript

Separation Synthesis – Learning Outcomes
Explain the importance of separations in a chemical plant.
Define the problem of separation network synthesis.
List common industrial separation methods with their
underlying principles.
Identify and assess various methods for separating a given
multicomponent mixture. Select the best.
List and rationalize heuristic rules for separation network
synthesis.
Use algorithms to sequence networks of distillation-type
columns.

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 cost of separation may outweigh
the value of the product

Separations can Make / Break a Process
Separations separate components, but also ChEs from others.
Form the backbone of most plants.
Represent most of the equipment in a plant.
1-2 reactors, but several columns, drums, separators, exchangers, …
Incur most CAPEX and OPEX (energy) costs.
Control product costs, if feed materials are cheap.
Introduce new materials. Offer multiple alternatives.
Mostly responsible for plant complexity.
Make process optimization critical.
Pose huge simulation challenges, so fluid package is critical.
Nonideal and hence often nonintuitive behaviors are the norm.

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 Separation Network Synthesis: Problem?
Given
Mixture of 𝐼-species (𝐼 1) mixture (Say NG: C1, C2, C3, C4)
P, T, z (overall mixture composition)
Desired separation products (e.g. Gas = C1+C2 & NGL = C2+C3+C4)
Targets: Purity, impurity, recovery, flow, T, P, …
99% recovery of C1, 97% pure C1, 99% recovery for all, 99% purity for all, …
Develop “best” process (PFD) to get desired products & targets.
Separation methods and agents (energy??, mass??, equipment??)
Separation units and their network arrangement
P, T, feeds, and products of each unit
Target for each product (composition, purity, recovery, …)
Define best. Mini/maximize what technoeconomic goal?
Power? Water? Emissions? Heating? CAPEX? Margin? Total cost?
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 Propose Easiest Ways for Following
Two streams from a VL mixture?
What made it possible? density, volatility,
boiling point
temperature

Think of physical properties, external forces, separating agents, …
solid liquid slurry

Two streams from an SL slurry?
What made it possible? filtration process which used the
property of difference in particle size

Three streams from a VLL mixture?
What made it possible? separation through difference
in density of components

What is the general name for all above separations?
It is a key step that most separation methods rely on.
phase
separation
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 Easiest (Most Natural) Separation of All?
electrostatic precipitator : pass the
Method: ???? phase separation gas through electric field and
attracts and removes all the solid
Definition / Description: ??? particles and lets gas go through
Separating a multi-????
phase mixture into individual phase
???? using some
physical property, driving force, and/or separation agent.
cyclone
flash, decanter, filtration, sieve,

separator,
Feed states: VL, GS, LL, SL, SS, VLL cyclone separator: due to
centrifugal force, solids collect
Product states: Individual V, L, S phases and deposit on the side
Physical properties: Density, buoyancy, size, immiscibility,...
Separation agents: Gravity, centrifugal force, electric field,
filter, sieve, membrane, …
Favored operating conditions: ???
Examples: Flash, Settling, Decanting, Centrifugation,
Filtration, Electrostatic separation, …

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 Distillation (Ordinary, Vacuum, Cryogenic)
Definition / Description:
Separating a mixture based on differences in volatility (BP). usually
pressure
high

What determines Ordinary vs Vacuum vs Cryogenic?operating below 0C
above atmospheric usually high
operating below temperatures
pressure and temp temperature
atmoshperic pressure

Feed states: ??? for distillation, feed state has to be either vapour, liquid or vapour-liquid
important
Product states: ??? top product is vapour and bottom product is liquid properties as
distillation relies on

Physical properties: Volatility, density, buoyancy,... used as a driving
phase separation

Separation agents: Energy, G???, p???, … pressure force for allowing gas
flow through the
column from bottom
Favored operating conditions: ??
gravity
to top
low pressure better (higher
pressure
diff across

pressure = higher boiling point)
Examples: Crude oil distillation each stage

Ordinary: Pure water and methanol from water+methanol.
separation is
better in below distillation NOT
lower pressure -> better separation
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atmospheric
pressure
POSSIBLE beyond
critical pressure because
6
conditions but not both liq and gas are
feasible as it is $$$ indistinguishable
 Absorption
Definition / Description: ?? removing a solute from a gas phase using a solvent

Physical & Chemical: ??

Feed states: ? one feed HAS to be gas, other feed (solvent) has to be liquid
solvent + solute is

liquid product flow

Product states: ?? gas and liquid (two product flows) gas product flow has
the solute removed

Physical properties: Solubility, reactivity, volatility, …
Separation agents: Liquid solvent, G???, p???, … (Mass)
Favored operating conditions: ??? MSA - mass
separating agent
low temperatures +
Examples: ?? higher pressures
better for absorption

carbon capture
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 Stripping
Definition / Description: ?? removing a component from the liquid phase based
on volatility

Feed states: ? liquid feed with a gaseous mass separating agent (like air)
Product states: ?? liquid and gas

Physical properties: Volatility, …

Separation agents: Mass (??, ??, ), G???, p???, …
Favored operating conditions: ???
Examples: ?? higher temperatures +
low pressures better
for stripping
petroleum refinery :
removing volatile components
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 Other Separation Methods & Principles
Condensation

Evaporation

Freezing

Sublimation

Desublimation

Drying
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 Other Separation Methods
Precipitation
acid base neutralisation

Leaching / Extraction removing component from solid phase

Caffeine from beans into water or supercritical CO2.
Vegetable oil into hexane

LL extraction
Caffeine from water into dimethyl chloride or ethyl acetate
Small amounts of benzene from water into toluene
Acetic acid from ethyl acetate into water.

Supercritical extraction
extraction in supercritical conditions
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 Azeotropic Distillation
Azeotrope: Constant boiling mixture in which both L-phase
and V-phase have same composition.
because both phase have the same composition

Ordinary distillation cannot separate, so how?
Homogeneous: One L-phase, one V-phase
Water + Ethanol
Heterogeneous: Two immiscible L-phases, one V-phase
Water + Butanol
Minimum boiling: Azeotrope BP < BPs of components
Water + Ethanol
Maximum boiling: Azeotrope BP > BPs of components
Water + HCl
hydrogen bonding mainly
responsible for non-ideality 11
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 Other Distillation Methods
Extractive: Solvent as a mass separating agent.

Reactive: Two definitions exist.
React away one species to eliminate azeotrope.
Perform reaction and distillation together in one column.

Pressure swing (PSD):
Principle: Azeotrope composition changes with pressure.
Change pressure to break or change azeotropic composition
Water + Ethanol by lowering pressure

Salt effect (salted):
Principle: Ionic salt (mass separating agent) in an aqueous mixture changes
volatility or azeotrope composition
Water + Ethanol by adding NaCl, CaCl2, …

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 Other Separation Methods
using solid material for separating agent
Adsorption
Pressure swing (PSA) adsorb at low temp then heat up
so that component is removed
Temperature swing (TSA)
Vacuum swing (VSA)

Chromatography
GC: Gas chromatograph
HPLC: High pressure liquid chromatography
solute removed from solution using crystallisation
Crystallization
Most pharmaceutical processes

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 Other Separation Methods
Membrane pervaporation: Membrane as a separating agent
allow some substances to evaporate through membrane

Membrane permeation: Membrane as a separating agent
particles of different sized are separated
based on their size by a membrane
Reverse osmosis
Example??

Salt precipitation
𝑃𝑏 from aqueous solution of 𝑃𝑏 𝐴𝑔 by adding KCl

Salt substitution
Organics (proteins) from water by an inorganic (ionic) salt
Ethanol from water by adding Na2SO4

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 How to Select & Sequence Separations?
especially if the components
Does mixture have multiple phases? are rich in composition in
different phases
VL, SL, LL, VLL, VLS? multi-phase means phase separation

Heuristic S1: Phase separate a multi-phase mixture, if a
relatively sharp separation exists, otherwise not.
VL: Can it be sharp always? Method?
degree of separation not very good and not guaranteed in VL

SL: Can it be sharp always? Method?
degree of separation is guaranteed

LL: Can it be sharp always? Method?
need to use multi stage phase separation

VLL: Can it be sharp always? Method?

SS: Can it be sharp always? Method?
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 Separating a 1-Phase Mixture
Will the easiest separation help? How much energy?
Can we create multiple phases without much energy?
Will the phases represent a sharp separation?

Heuristic S2: Convert 1-phase mixture into multiple phases,
and phase separate, if a sharp split can be achieved.
V  VL: Method? change temperature - partial condensation
V  VS: Method? desublimation or freezing
L  SL: Method? crystallisation
some liquids may be miscible but beyond
L  LL: Method? a certain temp they become immiscible
V  VS: Method?
L  VL: Method? partial evaporation
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 Separating a Gas/Vapor Mixture
Heuristic S3: Avoid mass as a separating agent (Prefer
energy or equipment (filter, membrane, …).
Why? if mass used then another separation process is
required to remove the separating agent
Why?
adding external material
increases process complexity as
we have to remove, recycle, etc

Heuristic S4: Consider absorption, adsorption, cryogenic
distillation, and membrane separation.

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 Separating a Liquid Mixture
Heuristic S5: Consider ordinary distillation, stripping,
adsorption, extractive distillation, LL extraction, membrane
permeation (ultrafiltration), membrane pervaporation,
crystallization, reverse osmosis, chromatography,
supercritical extraction, and ion exchange resin.

Heuristic S6: If azeotropic, then consider azeotropic,
pressure-swing, salt-effect/salted, and reactive distillation.
Homogeneous: Entrainer dissolves all components fully.
Heterogenous: Entrainer forms an immiscible liquid phase.

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 Separating a Liquid Solution
Heuristic S7: Crystallize via chilling, if solubility decreases
rapidly with temperature.
Keep temperature at most 1 or 2 F below saturation.
Example?
sugar made from sugar cane juice being chilled

Heuristic S8: Crystallize via evaporation, if solubility is not
temperature-sensitive.
Example?
salt separation from water

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 Ease of Separation
Assessing difficulty/ease of a separation is useful in
developing separation networks.
Recall most methods exploit phase separation via two phases.
VL, VS, LL, and SL
Species distribute across two phases in varying degrees.
Relative preference of a species to one phase versus another
can tell us something about ease of separation.
Methanol + Water: Methanol will prefer V-phase in distillation.
Oil seeds: Oil will prefer Hexane-phase in extraction.
Benzene + Water: Benzene will prefer Toluene-phase in LL
extraction.
How to quantify this preference?
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 Define Key Components
Separate a multi-species mixture M = A+B+C+D+E via a
method (e.g. distillation, LL extraction, …)
What phases in distillation? Vapour phase and liquid phase
What phases in LL extraction? F=Feed & MSA=Solvent
MSA = mass
separating agent

Identify physical property behind separation method.
Distillation? Volatility is the property behind distillation
LL extraction?

Arrange species in the order of that physical property.
ABCDE with A most and E least volatile.
ABCDE with A most and E least soluble in MSA phase.
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 Define and Use Key Components
Select two adjacent species as keys to break M into two
phases/products: A&B, B&C, C&D, or D&E.
C&D: C is LK (Light Key) & D is HK in distillation.

Distillation products: V=A+B+C & L=D+E.
Extraction products: MSA=A+B+C & F=D+E.
C & D are distributing across L & MSA. Others are NOT.

If we can quantify the relative preference of C & D for
distributing across two phases, then that will tell us how easy
it is to break M into ABC & DE.

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 Separation Factor for Ease of Separation
Let I & II denote phases. A & B denote keys.
Assume we wish to know preference for I vs II.
SF between A & B is defined as,
𝑆𝐹 /

𝜙 = fugacity coefficient of 𝑖 (A or B) in phase 𝑗 (I or II).
measures how A will distribute in I vs II relative to B.
High means A will distribute much more than B in I.
Consider M = A+B+C+D+D+E.
Higher 𝑆𝐹 means splitting M into A+B+C and D+E is easier.

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 SF for Distillation & Extraction
for an ideal gas, fugacity of

Distillation: V and L are two phases/products.
a component is equal to the
mole fraction of the
component in vapour
Assume V is an ideal gas, and L is an ideal solution. phase

Then, 𝜙 𝑦 and 𝜙 𝑥.
𝑆𝐹 , 𝑦 /𝑥 / 𝑦 /𝑥 𝛼 , is relative volatility.
Relative volatility indicates ease of separation in ideal distillation.
relative volatility only valid for ideal gas and ideal solution

LL extraction: MSA and F are two phases.
By nature immiscibility , these are non-deal solutions.
Let S be solute, and L be liquid in the feed.
Fugacity becomes activity coefficient 𝛾, and 𝑆𝐹 , /
How will you get 𝛾?
using Van Laar, Margules
and Wilson’s equation
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 Columns in Separation Networks
Most separation units give two products from a single feed.
Exception: Crude oil distillation gives multiple products.
How many products from a distillation column with a partial
condenser?

If ordinary distillation can separate a binary feed, then we
need only one column. For non-ideal solutions,
ordinary distillation will
Methanol + Water, Benzene + Toluene NOT work

How many 2-product columns to separate an I-component
mixture into I pure components using ordinary distillation?

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 Columns for a Multicomponent Mixture
Let M = A+B+C. How many ways to split M via keys?

Column Network 1:
Column 1: M  A (V or top) & BC (L or bottom)
Column 2:
Column Network 2:
Sequence 1? M  AB (V or top) & C (L or bottom)
Sequence 2?

Two networks of exist for a ternary M.
How many 2-product columns in each network?
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 Networks for I-Component Mixture
Number of networks increases rapidly.

𝑁 6
𝑁 𝐼 𝑁𝑁 2 𝐼 1 !/𝐼! 𝐼 1 ! 𝑁 14
𝑁 42

Each network uses (I-1) 2-product columns.

How to generate them and decide the best network?
Exhaustive enumeration is time consuming, so heuristics are
common, and systematic optimization methods continue to evolve.
One must define best.

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 Heuristics for Separation Networks
Heuristic S9: Remove thermally unstable, corrosive, or
chemically reactive components earlier.
Rationale? How does early vs late affect the impact of these
properties?
safety, for preserving
quality

Heuristic S10: Remove species one by one as distillate.
 𝐼 1 species are top products, heaviest one is last bottom.
CH4+C2H6+C3H6+C3H8  CH4 & C2H6+C3H6+C3H8
C2H6+C3H6+C3H8  C2H6 & C3H6+C3H8
C3H6+C3H8  C3H6 & C3H8
This is called direct sequence.
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 Heuristics for Separation Networks
Heuristic S11: Remove species one by one as bottoms.
 𝐼 1 species are bottom products, lightest is last top product.
CH4+C2H6+C3H6+C3H8  CH4+C2H6+C3H6 & C3H8
CH4+C2H6+C3H6  CH4+C2H6 & C3H6
CH4+C2H6  CH4 & C2H6
This is called indirect sequence. CO and
CH3OH

Heuristic S12: Perform easier separations earlier.
Consider M = CO+H2+CH3OH+Water. Which split is easiest?
Heuristic S13: Perform difficult separations later.
Consider M = CH4+C2H6+C3H6+C3H8. Which is most difficult?
Network 1: ?? most difficult separation is C3H6
and C3H8 as their boiling points

Network 2: ?? are going to be the closest

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 Heuristics for Separation Networks
Heuristic S14: Remove largest (mol fraction) species first.
A+B+C (10:10:80): ??; A+B+C (10:80:10): ??
Heuristic S15: Remove higher purity-target species last.
How does purity-target affect separation difficulty? higher purity

How does removing other species first affect difficulty? products
require more
difficult
separation

Heuristics often compete with and/or contradict each other.
No clear priority or sequence of one over another.
Difficult to judge best network without doing rigorous
simulation and costing.
Consider product gains/losses in defining best.

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 Heuristics for Separation Networks
Heuristic S16: It is easier to achieve higher purity in top
versus bottom products due to the presence of high boiling
impurities and solids in most industrial mixtures.
Why? Which product gets evaporated?
top product will just be one
component evaporated but
bottom product will contain
impurities with high boiling
point

Heuristic S17: Direct sequence is widely used in the
industry, but indirect is the least desirable.
Can you explain using S16?

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 Example for Separation Heuristics
Hydrocarbon F = C3+iC4+nC4+iC5+nC5
Species flows are 45.4, 136.1, 226.8, 181.4, 317.5 kmol/h.
Desired recoveries are 98% for each species.

s ( ’s) for various splits or key pairs are:
C3/iC4 = 3.6, iC4/nC4 = 1.5, nC4/iC5 = 2.8, iC5/nC5 = 1.35.

S9 does not apply.

S17 rules out indirect sequence.

S15 (Highest purity last) does not apply.
All are high-purity.

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 Apply S10: Direct Sequence

C3
Column 4
F iC4
iC4+nC4+
iC5+nC5 nC4
nC4+ iC5
Column 1
iC5+nC5
iC5
Column 2
+nC5
Column 3
nC5
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 Apply S12: Easiest Separation First

C3 iC4

F iC4+nC4 Column 3
iC4+nC4+ nC4
iC5+nC5 Column 2

Column 1 iC5

iC5+nC5 Column 4

nC5
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 Example for Separation Heuristics
S14 suggests largest species first.
nC5 is the largest component, so F  C3+iC4+nC4+iC5 & nC5.
However, iC5 / nC5 is the most difficult separation, which
contradicts S13: Hardest separation last.

Which of S10 vs S12 is the best?
S12 gives the “best” sequence, but how do you prove?
No easy / clear solution.
Highly qualitative judgements.
No choice, but faith!

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 Most Important Heuristic
Heuristics are not inviolable or infallible laws.
You decide if it makes sense in a given situation.
You can violate them, if situation warrants.

The most important heuristic per Prof Towler is:
Heuristic S18: Never use a heuristic, unless you can
rationalize it and/or derive it.

Heuristics do not give you clear unambiguous solutions.
Highly qualitative suggestions.
Other recent methods offer some quantitative bases.
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 Marginal Vapor Rate Method
Modi & Westerberg (1992) from CMU (USA)
Needs rough simulation, but not complete column designs or costs.
Premise 1: Adding a non-key species complicates separation and
increases cost.
 If B/C are keys, then AB / C is costlier than B / C.
Premise 2: This increase (called marginal annualized cost) is well
measured by marginal increase in molar vapor flow (MV) exiting
the column top.
Heuristic 19: Use network with minimum total MVR.
Consider A and B as key components.
Split A / B has a vapor flow of 𝑉 / kmol/h.
Split A / BC has a vapor flow of 𝑉 / > 𝑉 / kmol/h.
Marginal vapor flow 𝑀𝑉𝑅 / = 𝑉 / 𝑉/.

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 Apply Marginal Vapor Rate Method
F = C3-iC4-nC4-iC5-nC5. Apply S10: Easiest separation.
Separate C3 first. Apply method to A+B+C+D.
Recover at least 99.9% of each component in each column.
Use Short Cut Distillation to get top vapor flows.
Split Top R= Vapor MVR Split Top R= Vapor MVR
Pressure 1.2 Rate Pressure 1.2 Rate
(kPa) 𝑹𝒎𝒊𝒏 (kmol/h) (kPa) 𝑹𝒎𝒊𝒏 (kmol/h)
A/B 680 10.7 1,594 0 B/CD 490 3.06 921 227
A/BC 680 11.9 1,757 163 AB/CD 560 2.11 1,129 435
A/BCD 680 13.2 1,934 340 C/D 210 13.5 2,632 0
B/C 490 2.06 694 0 BC/D 350 6.39 3,017 385
AB/C 560 1.55 925 231 ABC/D 430 4.96 3,245 613
Direct: A/BCD + B/CD + C/D = 340 + 227 = 567 kmol/h
S12: AB/CD + A/B + C/D = 435 kmol/h, hence it is the best.
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 Reflect on Heuristic MVR Method
Is it easy to get top vapor flows? What do you need to do?

What is the method’s primary goal?
Does it compute that goal rigorously? goal is least cost but usually
least cost will not be most
optimal process

Is that goal critical in practice? Is it most important in
deciding the best? What is more important in practice?
should consider
cost AND revenue

Given the work involved and its limitations, what is the best
approach to get the best sequence?

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