Process Design Learning Outcomes PDF

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This document provides learning outcomes for a process design course, covering topics like chemical process industry (CPI), its scope, role in Singapore, life cycles of chemical plants, types of process design, and more.

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Process Design – Learning Outcomes
Define chemical process industry (CPI) and its scope.
Describe the role of CPI in Singapore.
Describe the life cycles of chemical plants and products.
Explain the types of process design and their continual need.
List the steps and considerations in a design project.
Explain the general structure of a chemical process.
Describe the overall strategy for process development.
List the main sections of a typical chemical plant.
Contrast continuous versus batch processes.
State a recommended hierarchy for process development
decisions.
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 History of Chemical Industry
Chemistry is at the root of chemical industry.
Alchemy (original chemistry) had roots in ancient Egypt,
Mesopotamia, and Greece.
Alchemists sought to transform metals into gold.
Jabir ibn Hayyan (Geber) during the Islamic Golden Age is
often considered the father of Chemistry.
He introduced experiments, apparatus, and techniques.
English “Gibberish” comes from his name!
Dyeing, leather tanning, and brewing were known since ages.
Modern chemical industry began in UK after industrial
revolution.
Na2CO3 process by Nicolas Leblanc is commonly considered to be
the birth of modern chemical industry.

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 Key Historic Events in Chemical Industry
1746: Lead chamber process for H2SO4 by John Roebuck.
1789: Leblanc process for Na2CO3 by Nicolas Leblanc.
1850: The first oil refinery by Samuel Kier in PA, USA.
1905: Haber-Bosch process for ammonia (most important process
of all times) by Fritz Haber & Carl Bosch.
1920: Large-scale industrial process for isopropanol from oil by
Standard Oil Company – First process from oil.
1923: High-pressure process for methanol by BASF.
1923: Fischer-Tropsch process for synthetic liquid fuels from coal
gasification.
1934: First tire from synthetic rubber, neoprene.
1939: Large-scale LDPE at ICI and PVC in Germany & USA.
1955: Large-scale process for PET (PE Terephthalate)
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 What is CPI (Chemical Process Industry)?
Huge and most diverse industry in the manufacturing sector.
Wide variety of inorganics, organics, fuels, feedstocks, gases,
pharmaceuticals, agrochemicals, ceramics, polymers, &
consumer products.
Consumption/production of many of these products is a measure of
nation’s industrialization or economic advance.
Key contributor to the economy of many advanced nations.

Trade is mostly B2B vs B2C (Business-2-Consumer).
Most chemicals are used to produce other chemicals.
Many chemicals are used in making consumer products.
Only some chemicals find direct consumer use.
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 Categories of CPI Chemicals/Products

Composition-based Performance-based
(Commodities) (Specialties)
Standard, universal grades Company-specific qualities
Fungible (Undifferentiated) Non-fungible (Differentiated)
High-volume, Low-margin Low-volume, High-margin
Mostly B2B B2B & B2C

Pharmaceuticals

Fuels
Agrochemicals

Feedstocks Consumer Products
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 Hierarchy of CPI Chemicals/Products
Final Products Plastics, Pharmaceuticals, Fibers, Solvents,
Detergents, Perfumes, fertilizers, insecticides
(~30,000)

Intermediates
Bulk Chemicals

Acetic acid, Formaldehyde, Urea, Ethene oxide,
(~300) Acrylonitrile, Acetaldehyde, Terephthalic acid

Base Chemicals Ethene, Propene, Butadiene, BTX, SynGas,
(~20) ammonia, methanol, sulfur, chlorine, salt
Fuels
(~10)
Raw Materials
Air, ??, ??, ??, ??
(~10) 10 basic raw materials: air, water, coal,
crude oil, natural gas, ores and
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biomass
 Major Industries within CPI
Bulk Inorganics Oil & Gas Pharmaceuticals Petrochemicals
H2 APIs PAN
Acids Acids
(H2SO4, HCl, Kerosene Nylon
C2H6 Vaccines Alcohols
HNO3, HF, …) Petrol PE/PET
Diesel NGL Peptides Aldehydes
Alkalies PP/PPO
HFO Amino Ketones
(NaOH, NH4OH, C2H4
KOH, Lime, …) LPG Acids PS
Phenols
NG C3H8 PEG
Salts Vitamins EG
LSD PTFE
(Na2CO3, K2CO3, C3H6 EO
NH4SO4, NaNO3, DF
NH4NO3, CaSO4, PU
…) ATF Naphtha Minerals BTX
MGO PEster
Naphthenes
Feedstocks
Industrial MDO PVC
Gases Organics
(N2, O2, He, Ar, Fuels PVA
Cl2, Kr, Xe, …) API = Active Pharmaceutical Ingredient, MDO = Marine Distillate Oil, ATF = Aviation Turbine Polymers
Copyright © IA Karimi Fuel or Jet Fuel, LSD = Low-Sulfur Diesel, MGO = Marine Gas Oil, DF = Distillate Fuel 7
 Other CPI-Related Industries
Lubricants
Food & Paints & & Additives Agrochem
Beverages Coatings Inhibitors
Vegetable oils Fertilizers
Paints Enhancers Pesticides
Dairy, Sugar Pigments (fuels, flows, Insecticides
Beer, Drinks Varnishes paints, polymers)
Colors, Flavors Films
Fragrances Coatings
Preservants Adhesives Paper &
Nutraceuticals
Sealants Pulp
Ink
Catalysts Paper
Personal Enzymes Notes
Care Resins
Soaps & Shampoos
Cosmetics Electronic
Detergents Textiles
Soaps Lotions Solvents
Inks
Detergents Make-ups Photographic Dyes
Cleaners Polishes
Treatment Coatings
Surfactants Perfumes
(water)

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 CPI in Singapore
Manufacturing sector is a key economy driver for Singapore.
It accounts for nearly 20% of Singapore’s GDP.
Total manufacturing output was 447 Billion S$ in 2022.
Electronics 196 Billion S$ (44%), Chemicals & Refinery 120
Billion S$ (27%), and Pharmaceutical & Biological 19 Billion S$
(4.3%). 130

Source: www.statista.com 120
Manufacturing Output (Billion S$)

110

Jurong Island hosts 100

90

>100 chemical 80

companies. 70

60

50

40
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022
Year

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 Competition in CPI Causes Life Cycles
Product substitution (Multiple products for the same market)
Polyethylene vs. polypropylene, NaOH vs. Na2CO3, LPG vs NG/TG
Gasoline vs ethanol vs electricity vs hydrogen vs ammonia
Precursors or reaction pathways
Acrylonitrile via acetylene vs. propylene
Cyclohexane via naphtha vs. benzene
Phenol and methanol via three different processes
Processing technologies (T, P, catalyst)
Ammonia via high-P, med-P, or low-P processes
Raw materials (Coal vs LNG vs petroleum vs biomass)
Companies (Dow vs. DuPont, GSK vs Pfizer vs MSD, etc.)
Industries: Natural vs. synthetic fibers
Net result: Product/plant lifecycles & need for continual design

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 S-Curve for Product/Market Life Cycle

Start Mature Death
Phase Phase Phase
Growth
Phase

Cost/margin decrease over time.
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 Plant Life Cycle
Conception: R&D, market needs, etc.
Engineering: Diagrams and plans for construction workers
Construction: From diagrams to complete facility.
Commissioning: Full checkup, validation, calibration, startup
(zero to full production), testing, training, and handover.
Operation: Profitable production over 10 to 20 years.
Regular maintenance, repairs, replacements, etc.
Periodic shutdowns, cleanups, and overhauls
Retrofit or debottlenecking
Closure & Scrap/Disposal, or Reuse

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 Types of Design Projects
Revamp or Retrofit: Modify or upgrade an existing plant.
Increase production capacity (debottlenecking)
Handle different feeds
Make different products
Exploit new technology
Decrease emissions
Improve performance, efficiency, safety, reliability, or consistency.
50% of all projects
Capacity Expansion: Build/duplicate plants to increase total
production.
45% of all projects
Only 5% of all industrial projects build new plants based on
new laboratory R&D.
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 Greenfield vs Brownfield Projects
Greenfield (Grass-roots) projects construct new plants on
barren land plots.

Plain, totally undeveloped site with no existing infrastructure or
development.

Brownfield projects construct new plants on sites that
produced something else before.

Repurpose an abandoned site for a different use.

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 Key Steps in a Process Design Project
Idea, Need, Design Basis, Specs, Gather Literature,
Objective External Constraints Data & Information

If chemical is not available on the Process Development
simulation databank, use a
chemical with similar properties Simulation Models
to allow simulation to run (Performance & profitability)

Design R&D
Best Process/Design (Physical properties,
Alternatives Pilot studies, …)
Optimize
Detailed Design Designs
& Equipment Specs

Procurement
Commissioning Operation
& Construction
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 Design Basis – Project Statement
Raw materials, products/byproducts, & specifications
Grades, purities, impurities, storage conditions (P, T), …
Plant capacity: xxx – xxx ktpa (kilo tonne per annum)
Onstream time: 8000 h/y to 8256 h/y (downtime, overhauls)
Potential location/s, if not fixed already.
Company, local, and national design codes and standards
Codes recommend various design procedures and safety margins.
Safety factors (margins) allow for uncertainties in material properties,
procedures, fabrication, and operation.
Standards stipulate common equipment sizes, dimensions,...
NIST, ANSI, API, ASTM, ASME, NFPA, TEMA, ISA, ISO, …
System of units: Imperial, SI, CGS, MKS, …
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 External Constraints – Beyond Designer
Physical laws
Mass & energy conservations, thermodynamics, kinetics, heat
transfer coefficients,...
Government regulations
NEA controls
Effluent discharges & emission limits regulations for
waste discharge in
Tax code, corporate taxes or incentives Singapore

Depreciation rules
Safety: Exposure limits, safe distances, …
Codes and standards: Previous slide
Resources
Time, construction equipment, manpower, land, sourcing, …

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 Company Policies or Guidelines
Raw materials, products, specs, plant site, contractors,
vendors, design factors (margins), …
Design factors overdesign to embed operational flexibility.
Typical: Max (design) flow = 1.1 x desired flow, 10% for pumps,
20% for exchangers, …
Danger of gross overdesign, if repeated by people. Cost increases
and efficiency decreases drastically.
Mr S Singh (Amec-Foster-Wheeler) opined that this is not done anymore, as
computer simulations are quite accurate and reliable.
Project economics
Budget, RORI, Payback period, discount rate, inflation, interest,
equity, …

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 Literature, Data, & Information
The mother of all sources, ChatGPT, Online databases (e.g.
Science Direct), patent databases,...
Company reports, people, and plants
Licensors (ABB Lummus, UOP, etc.)
Books, handbooks, encyclopedias, …
Codes and standards
Research/Trade journals and publications
AIChE J, Ind Eng Chem Res, Chem Eng Sci, Comp Chem Eng, Chem Eng
J, …
ChE Progress, Hydrocarbon Processing, Chem Eng, Chem Marketing
Reporter, …
SRI (Stanford Res Inst) International for detailed design reports
HTRI (Heat Transfer Res Inst, US) & HTFS (Heat Transfer &
Fluid Flow Service, UK) for heat exchangers
FRI (Fractionation Research Institute) for distillation
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 Reports & Documents
Market or technoeconomic analysis
Preliminary design or feasibility study
Basic engineering design or FEED (Front End Eng Design)
BFD, PFD, P&ID, and isometric drawings
Firm process design
Plant-wide controllability analysis
HAZOP study: Hazard identification & risk assessment
Environmental impact analysis
Life cycle and sustainability analysis
General correspondence

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 Market or Technoeconomic Analysis
Market potential (demand) of target product/s? Price
projections?
Projected local and global profiles over10-20 years.

would only use the
Main competitors? technology if it has a TRL of
at least 7/8

Technologies? Technology readiness levels (TRL)? TRL levels range
Technology licensors? Any political embargos? from 1 to 10

Raw materials? suppliers?
Any significant safety, environmental, societal, or geopolitical
risks?
Carbon footprints and harmful emissions? Sustainability?
Estimated rates of returns?
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 Block Flow Diagram (BFD)
Broad and multiple definitions exist.
Simple diagram with blocks showing major sections or
operations in a process.
Benzene + Hydrogen Cyclohexane Cyclohexane Water
Dehydrogenation

Hydrogen
Benzene Benzene Cyclohexene Cyclohexene Cyclohexanol
Hydrogenation Recovery Recovery Hydration Recovery
Benzene

Benzene Cyclohexanol

Production of cyclohexanol from benzene via hydration of cyclohexene

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 BFD for Process Simulation
BFD with blocks that represent various modules in a
commercial process simulation model (e.g. Aspen Hysys).
Compress N2 + H2 + CH4 Purge
340 psia 320 psia
Heat

H2 Heat React Cool Condense Flash
V-Mix Expand
340 psia 335 psia 335-320 psia 320 psia 320 psia 320 psia
120 F 340 psia 15 psia
570 F 570-430 F DPT DPT-120 F 120 F

Vaporize L-Mix Pump Split Purge
340 psia 340 psia 340 psia 320 psia
Light Ends

C6 H 6 C6H12+C6H6 Cool Expand
Pump 15 psia
Distil
15 psia
100 F 340 psia 100 F 100 F 20 psia 20 psia

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 Process Flow Diagram (PFD)
Key reference for most design tasks with two main parts
Directional network diagram & Steam table
Diagram shows complete process and flow structures.
Sequenced process units with standard icons, names, labels, legend, and
nominal operating conditions (P, T, …)
ISO 10628 is the international standard, but companies have own symbols.
MS Visio is often used by FYDP students.
Directional streams/flows (pipelines) of materials and utilities with
systematic labels
Control valve locations and equipment for storage and transport
Stream table shows key data for all streams.
Mass flows of each stream and its components
P, T, and phase at reasonable precisions
Critical trace species and amounts versus zero or blank.
indicate important contaminants

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 PFD for Benzene Manufacture

Production of Benzene via Hydrodealkylation of Toluene
stream flow Stream 1 2 3 4 5 6 7 8 9 10 using standard symbols
information Pressure (kPa) and icons to indicate the
table Temperature (K) type of equipment with
Enthalpy (MJ/s) each individual
Phase Fraction (wt) equipment tag name
Total Flow (kg/s)
Benzene (kg/s)
Toluene (kg/s)
Hydrogen (kg/s)
Source: https://www.informit.com/articles/article.aspx?p=1915161&seqNum=2
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 Piping & Instrumentation Diagram (P&ID)
A = Alarm
C = Controller
E = Element
F = Flow
H = High
I = Indicator
L = Level
L = Low
P = Pressure
T = Temperature
T = Transmitter
V = Valve
X = Composition
Y = Y-type valve

P, T, F, and L
dominate

Source: https://www.linkedin.com/pulse/how-develop-piping-instrumentation-diagram-pid-sadeghi-azizkhani of Javad Sadeghi
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 Isometric Piping Diagram - Example

Source: https://whatispiping.com/basic-piping-isometric-drawings/?expand_article=1 by Nur Hidayah Haron
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 3D Model of Chemical Plant - Example

Source: https://www.cgtrader.com/3d-models/industrial/other/chemical-plant-3
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 Preliminary Design or Feasibility Study
Quick-estimate design with ±30% cost accuracy to assess
project potential tells us whether design is profitable or not

BFD, PFD, and stream table with all major sections, units,
and operating conditions

Critical dimensions of all major units for estimating costs
from correlations
laws, regulations, licenses, equipment, operational cost, salaries

Cash flow analysis (revenue vs cost) to estimate profitability
This is partially the scope of your FYDP.

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 FEED (Front End Eng Design)
Also called basic engineering design

Detailed optimized design with ±10% cost accuracy

Basis for a Go/No-Go budgeting decision by the corporate
board

Minimal drafting work (engineering drawings)

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 Firm Process Design
Final, ready-to-purchase/fabricate designs

Firm vendor quotes with 2-5% cost accuracy

Detailed equipment specifications & drawings

PFD and P&ID

Complete Isometric Piping Diagrams (3D drawings)

3D visualization (e.g. PDS)
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 HAZOP Study
Identify all process (material, equipment, & operational)
hazards.
Material safety data sheets or MSDS
Explosion limits, flammability limits, toxicity, etc.
Can tank overflow? Can pressure exceed design level? What is
valve fails? What if a seal (e.g. gasket corrodes or degrades/dissolves
due to chemical reaction) leaks?
Quantitative risk assessment
What is the frequency of occurrence?
What is the extent of damage?
How mechanisms are in place to reduce damage?
Alarms, relief devices, pressure switches, etc.
Prof Sin will go into more details.
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 SHE, Controllability, & Others
Environmental impact analysis
Disposal of waste streams (toxic or nontoxic)
Toxic releases and dispersion models
Facilities for reducing emissions
Water treatment plants
Life cycle and sustainability analysis
Cradle-to-grave impact on carbon emissions and renewable penetration
Energy efficiency, energy penalty, material intensity, footprints (land,
carbon, water, energy, materials, …)
Plant-wide controllability analysis
Control system design (control schemes, controllers, variables)
General correspondence
Internal and external (client, vendors, regulators, …)
Licenses, permits, agreements, and approvals
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 Example Design Project in Singapore
Investment = $700 million to $1 billion
Duration = 18-30 months
Feasibility to go/no-go: 6-12 months, 4-5% of investment
Authority submissions: 3-5 months
URA (Urban Redevelopment Authority) & JTC (Jurong Town
Corporation) for planning approvals
BCA (Building & Construction Authority) for building plans
FSB (Fire & Safety Board) for safety issues
NEA (National Environmental Agency) for pollution control & drainage
MoM (Ministry of Manpower) for permits & inspection
MPA (Maritime & Port Authority) for waterfront issues
EPCC steps (% of project value)
Engineering: 10-12% (250K man-hours, 120 people, S$100 million)
Procurement: 50-60%, Construction: 30-35%, Commissioning: 10-15%
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 Process Development – Learning Outcomes
Explain the general structure of a chemical process.
List the main sections of a typical chemical plant.
Describe the overall strategy for process development.

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 Industrial Strategy of Process Development
Most business leaders avoid risking huge money
Design Objective on unproven process technologies,
unless returns are high, and no good alternatives exist.

No Is there a Does a process
Is it for an No No Develop a
commercial exist for a similar
existing plant? new process
process? objective?
Yes Yes
Revamp Explore & assess Very few processes
existing process Yes get developed from
current plant scratch in practice.
alternatives
50% of all projects are
revamp projects
Rule of Thumb
Yes Modify Plagiarize* much,
Need for
existing reinvent nothing.
improvement?
process
Source: Towler & Sinnot (2013)

Use existing Developing a PFD from scratch is good
process for learning the basics of process development.
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 Typical Chemical Process Structure
Recycle of Valuable Byproduct
Unreacted Reactants Storage
This section gets repeated in a multi-step process.
Raw
Feed Product Product Product
Material Reaction
Preparation Separation Purification Storage
Storage

Wastes

Wastes
Effluents & Waste
Emissions Treatment
Adapted from Towler & Sinnot (2013)

Shared Utility System (Compressed air, N2, power, steam, cooling water, …)
e.g. Boiler, Heater, Combined Heat & Power (CHP) System, …

Benzene (C6H6) + 3H2  Cyclohexane (C6H12) has 1 step.
Benzene + 2H2  Cyclohexene (C6H10) + H2O  Cyclohexanol (C6H11OH) has 2 steps.
Several additional recycles may exist for mass separating agents (e.g. solvents).

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 Feed / Product Storage
Several huge, insulated / jacketed, often refrigerated / heated,
tank won’t be solely atmospheric pressure
near-atmospheric cylindrical tanks. (slightly above) but not too high to save costs
(tank has to be made of material and of a
Why atmospheric? Heated? Refrigerated? thickness to maintain the pressure) and for
safety reasons

Normally for liquid or solid materials. Why not gaseous?
for the same amount of
Buffer between plant and outside world. Why? liquid and gas, volume
for gas will be huge

Normally hold a few days of supply/demand. For what?convenience of
Often inerted or blanketed with nitrogen. Why? storage and
trasnportation

Preserve quality and integrity of perishable (e.g. food) or sensitive
(e.g. drugs) materials due to degradation, discoloration (Vitamin C),
contamination, or humidification.
 Oxidation? Corrosion? Combustion / Explosion? Evaporation?
inerting storage with nitrogen
reduces the effects of these
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products
 Feed Preparation
Natural raw materials and synthetic feeds are always impure:
They contain species (impurities) other than reactants.
What about air? noble gases, dust, SO2, NOx, nitrogen, water vapour
What about crude oil? sulfur, heavy metals, salt
What about natural gas? sulfur, mercury,

Three types of impurities: Inert, reactive, and harmful
Catalyst, equipment, health, or environment, …

Most impurities are undesirable. They can make a process
impractical (e.g. waste heat recovery from power plants).

Why not always use high-purity feeds?
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 Inert Impurities
Species that remain intact through a process. Ar present
in air
Example 1: C3H8 in C3H6 feed for polypropylene
Example 2: Ar in N2 feed for NH3 (How did Ar get there?)
Example 3: N2, CO2 in natural gas
How can an inert affect a process?
Reaction rate? reduce reaction rate because concentration of reactants is
lower as inert impurity takes up space

Reactor size? larger reactor size to compensate
for the reduced reactor size
purge required
Recycle of unreacted reactants? What becomes necessary? because recycling
will keep the inerts
Product quality? What becomes necessary?
Always remove inerts from feeds? How to decide?
What about the examples above? unless harmful,
no point spending
money to remove
the inert
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 e.g. sulfur as
it reacts to

Reactive Impurities
form SOx,
which is
harmful

Many impurities react with reactants or other impurities to form
side products.
Side products may or may not be desirable.
Some may be pollutants or harmful emissions.
Example 1: Air cannot be used for ammonia.
Example 2: Reactive impurity in petrol, diesel, and fuels?
Example 3: Reactive impurity combustion air? Diesel?
How do they impact process?
Product quality?
Product yield?
Product cost?
Process after reactor?
Some impurities may decompose or polymerize.
Always remove reactive impurities? How to decide?
Example 2? Example 3?

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 always
remove sulfur
as sulfur
poisons
catalysts
Harmful Impurities
Catalyst/Adsorbent: S, moisture, … can poison or deactivate.
Health: Hg in NG is highly toxic and carcinogen.
Environment: NH3 in emissions
Process efficiency: Moisture in MSW for incineration plant
Operations: Water, CO2, C3+ in NG liquefaction.
Equipment: Moisture in flue gas can corrode
Always remove above impurities?
have to remove the ones above as they
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 Product Recovery (Separate & Purify)
Reactor effluents are almost always mixtures versus single
pure products. Why?
Most reactions are slow or equilibrium controlled. Few reach
100% conversions.
Ammonia and methanol syntheses have only 20-30% conversions.
Side reactions (hence side products) are generally inevitable.
Many organics in Fischer-Tropsch synthesis (coal gasification)
Excess reactants are common and strategic.
Fully consume a reactant: Excess H2 in benzene hydrogenation
remove a carcinogen and simplifies downstream separation.
Suppress side reactions:
Facilitate temperature control in highly exothermic reactions.
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 Why Separate & Purify Effluent?
Reactor effluent has inerts, unreacted reactants, and side
products (useful or not)
Example 1: Ammonia reactor effluent has N2, H2, NH3 with Ar and
CH4 as inerts.
Example 2: Benzene hydrogenation gives cyclohexane (useful side
product), cyclohexene, benzene, and hydrogen.
Example 3: SMR (Steam Methane Reforming) process for H2 gives
CH4, CO, H2, and CO2 (useless)
Why must we separate and purify?
Products must meet market specs (99.9% hydrogen for FCEV).
Valuable excess reactants cannot be wasted.
Byproducts can be valuable and improve process economics.
Harmful and polluting species must be removed before discharge or
venting.
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 Plant Utility System
Chemical plants use two types of utilities: Energy & Mass
Energy utilities supply energy of various forms to process.
Steam, power (electricity), cooling water, chilled water, air for cooling, …
Which three common energy forms in a plant? heat (internal energy), electricity,
mechanical
Mass utilities are all auxiliary materials that are not process
materials (feeds, products, internal streams). material added to make
the process easier and
Compressed air, fire water, inert/buffer/drying gases, …simpler
Solvents, catalysts, additives, inhibitors, and flow enhancers are known as
auxiliary materials, but could be called mass utilities.
Most large plants have an auxiliary section for utilities.
Some/small plants may also use external suppliers (e.g. SUT).
Two reasons to have a separate utility system? economies of scale (to reduce cost), space
efficiency, reliability of supply

Energy utilities impact carbon footprint or intensity.
Mass utilities impact mass/resource/sustainability footprint.
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that carbon footprint is minimised
 Why do we Need Utilities?
Most chemical plants operate at non-ambient and non-normal
process conditions.
Point-to-point, unit-to-unit condition (stream variable)
changes are inevitable & pervasive.
Velocity, elevation, P, T, phase, size/shape, composition, species,...
ALL changes need energy in various forms. electrical energy

P-change: What energy form does it need? What heat utility?
energy
T-change: What energy form does it need? What utility?
electrical energy
Size/shape: What energy form? What utility? heat and

Which forms of energy does enthalpy include? mechanical

What is the current source of our energy? How about future? solar, wind, hydrogen
fossil fuels

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 Batch vs Continuous Plants
Most ChEs view chemical plants as continuous. in pharma, typically
reactors are batch
Traditional training emphasizes them heavily. reactors

Most well-known chemical plants are continuous.
Batch plants are more common than expected. Examples?
reasons Feature/Aspect Batch Continuous
for
choosing Mode of Operation Intermittent, shared 24/7 continuous, dedicated
batch:
Role of Time Planning & scheduling is critical. Limited
- long Scale and nature of production Low-volume, high-margin High-volume, low-margin
residence
time Number & Nature of Products Multiple, multi-step syntheses Single, 1-step synthesis
required
Nature of operation Largely manual, labor intensive Highly automated
- Flexibility High Low & limited
synthesis
process is Cleaning/maintenance Much easier Expensive, yearly
very
complex Product identity Tagged batches Loss of identity
Process utilization Low High
Residence times Long Short
Copyright © IA Karimi typical residence time for 47
continuous reactors is in
milliseconds
 process synthesis means determining
the structure of a process

Continuous Process Synthesis
Generate and evaluate several plausible process alternatives to
achieve the desired objective in the best possible manner.
Processes that differ in technology, structures, units, sequence, …
How to define best? (Prof Suraj will discuss this & process
optimization)
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Final deliverable: PFD for the best process design
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 Process Synthesis is Iterative & Complex
Highly creative and multi-disciplinary
No universal or systematic procedure exists.
Computer-aided commercial tools for process modeling,
simulation, optimization, integration, and visualization have
made a huge impact.
Today’s designs use them fully and cleverly.
Few designs without them!
University research on systematic & automated methods or
algorithms for optimally synthesizing processes from scratch
or revamping them.
Industry relies heavily on best practices, experience, rules of
thumb, heuristics, etc.
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 Onion Diagram for Process Synthesis
Smith (2005) recommends a core of
Robin Smith (2005)
hierarchy of major decisions for the
chemical
continuous process. process

Premise: Reactors, their
Reactors
conversions, yields, and selectivity
largely dictate separations and Separations &
recycles. Recycles

Separations, recycles, and energy Energy Integration

integration determine structure.
Utility System
They offer most complexity and
network alternatives. Water & Effluent
Treatment

Our first focus will be separations.
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