Process Creation.ppt

Lecture 2 – Objectives
 Understand how to go about assembling design data and
creating a preliminary data base.
 Be able to implement the steps in creating flowsheets
involving reactions, separations, and T-P change
operations. In so doing, many alternatives are identified
that can be assembled into a synthesis tree that contains
the most promising alternatives.
 Know how to select the principal pieces of equipment and
to create a detailed process flowsheet, with a material and
energy balance and a list of major equipment items.

Lecture 2 – Outline
• Preliminary Database Creation
– to assemble data to support the design
• Experiments
– often necessary to supply missing database items or
verify crucial data
• Preliminary Process Synthesis
– top-down approach
– to generate a “synthesis tree” of design alternatives
– illustrated by the synthesis of a process for the
manufacture of VCM
• Development of Base-case Design
– focusing on the most promising alternative(s) from the
synthesis tree

Preliminary Database Creation
• Thermophysical property data
– physical properties
– phase equilibria (VLE data)
– property prediction methods
• Environmental and safety data
– toxicity data
– flammability data
• Chemical Prices
– e.g. as published in the Chemical Marketing Reporter
• Experiments
– to check on crucial items above

Preliminary Process Synthesis
• Synthesis of Chemical Processes
– Selection of processing mode: continuous or batch
– Fixing the chemical state of raw materials, products,
and by-products, noting the differences between them
– Process (unit) operations - flowsheet building blocks
– Synthesis steps
 Eliminate differences in molecular types
 Distribute chemicals by matching sources and sinks
 Eliminate differences in composition
 Eliminate differences in temperature, pressure and phase
 Integrate tasks (combine tasks into unit operations)

Preliminary Process Synthesis
• Continuous or Batch Processing
Continuous
Batch
Fed-batch
Batch-product
removal

The Chemical State
• Decide on raw material and product specifications
– Mass (flow rate)
– Composition (mole or mass fraction of each chemical
species having a unique molecular type)
– Phase (solid, liquid, or gas)
– Form (e.g., particle-size distribution and particle shape)
– Temperature
– Pressure

Process Operations
• Chemical reaction
– Positioning in the flowsheet involves many considerations
(conversion, rates, etc.), related to T and P at which the reaction
are carried out.
• Separation of chemicals
– needed to resolve difference between the desired composition of a
product stream and that of its source. Selection of the appropriate
method depends on the differences of the physical properties of
the chemical species involved.
• Phase separation
• Change of temperature
• Change of pressure
• Change of phase
• Mixing and splitting of streams and branches

Synthesis Steps
Synthesis Step
 Eliminate differences in
molecular types
 Distribute chemicals by
matching sources and sinks
 Eliminate differences in
composition
 Eliminate differences in
temp, pressure and phase
 Integrate tasks (combine
tasks into unit operations)
Process Operation
Chemical reaction
Mixing and splitting
Separation
Temperature, pressure
and phase change

Example: Vinyl Chloride
 Eliminate differences in molecular types
– Chemicals participating in VC manufacture
Chemical
Molecular
weight
Chemical
formula
Chemical
structure
Acetylene 26.04 C2H2 H- C C- H
Chlorine 70.91 Cl2
Cl-Cl
1,2-Dichloroethane 98.96 C2H4Cl2
Cl Cl
| |
H-C-C-H
| |
H H
Ethylene 28.05 C2H4
H H
C= C
H H
Hydrogen chloride 36.46 HCl H-Cl
Vinyl chloride 62.50 C2H3Cl
H Cl
C= C
H H

 Eliminate differences in molecular types (Cont’d)
– Selection of pathway to VCM (1)
 Direct chlorination of ethylene
Advantages:
– Attractive solution to the specific problem denoted as Alternative 2 in
analysis of primitive problem.
– Occurs spontaneously at a few hundred oC.
Disadvantages:
– Does not give a high yield of VC without simultaneously producing large
amounts of by-products like dichloroethylene
– Half of the expensive chlorine is consumed to produce HCl by-product,
which may not be sold easily.
HCl
Cl
H
C
Cl
H
C 3
2
2
4
2 

 (4.1)

 Hydrochlorination of acetylene
Advantages:
– This exothermic reaction is a potential solution for the specific problem
denoted as Alternative 3. It provides a good conversion (98%) of C2H2
to VC in the presence of HgCl2 catalyst impregnated in activated carbon at
atmospheric pressure.
– These are fairly moderate reaction conditions, and hence, this reaction
deserves further study.
Disadvantages:
– Flammability limits of C2H2 (2.5 100%)
Cl
H
C
HCl
H
C 3
2
2
2 
 (4.2)

 Thermal cracking of C2H4Cl2 from chlorination of C2H4
Advantages:
– Conversion of ethylene to 1,2-dichloroethane in exothermic reaction (4.3)
is 98% at 90C and 1 atm with a Friedel-Crafts catalyst such as FeCl3.
This intermediate is converted to vinyl chloride by thermal cracking
according to the endothermic reaction (4.4), which occurs spontaneously
at 500C with conversions as high as 65% (Alternative 2).
Disadvantages:
– Half of the expensive chlorine is consumed to produce HCl by-product,
which may not be sold easily.
2
4
2
2
4
2 Cl
H
C
Cl
H
C 

HCl
Cl
H
C
Cl
H
C 3
2
2
4
2 

HCl
Cl
H
C
Cl
H
C 3
2
2
4
2 


(4.3)
(4.4)
(4.1)

 Thermal cracking of C2H4Cl2 from oxychlorination of C2H4
Advantages:
– Highly exothermic reaction (4.5) achieves a 95% conversion to C2H4Cl2 in
the presence of CuCl2 catalyst, followed by pyrolysis step (4.4) as
Reaction Path 3.
– Excellent candidate when cost of HCl is low
– Solution for specific problem denoted as Alternative 3.
Disadvantages:
– Economics dependent on cost of HCl
(4.5)
(4.4)
(4.6)
O
H
Cl
H
C
O
HCl
2
H
C 2
2
4
2
2
2
1
4
2 



HCl
Cl
H
C
Cl
H
C 3
2
2
4
2 

O
H
Cl
H
C
O
HCl
H
C 2
3
2
2
2
1
4
2 




 Balanced Process for Chlorination of Ethylene
Advantages:
– Combination of Reaction Paths 3 and 4 - addresses Alternative 2.
– All Cl2 converted to VC
– No by-products!
(4.5)
(4.3)
(4.7)
O
H
Cl
H
C
O
HCl
2
H
C 2
2
4
2
2
2
1
4
2 



HCl
2
Cl
H
C
2
Cl
H
C
2 3
2
2
4
2 
 (4.4)
2
4
2
2
4
2 Cl
H
C
Cl
H
C 

O
H
Cl
H
C
2
O
Cl
H
C
2 2
3
2
2
2
1
2
4
2 




– Evaluation of alternative pathways
• Due to low selectivity Reaction Path  is eliminated
• Remaining four paths compared first in terms of Gross Profit
Chemical Cost (cents/lb)
Ethylene 18
Acetylene 50
Chlorine 11
Vinyl chloride 22
Hydrogen chloride 18
Water 0
Oxygen (air) 0
Chemical Bulk Prices

– Computing Gross Profit
Reaction path  C2H4 + Cl2 = C2H3Cl + HCl
lb-mole 1 1 1 1
Molecular weight 28.05 70.91 62.50 36.46
lb 28.05 70.91 62.50 36.46
lb/lb of vinyl chloride 0.449 1.134 1 0.583
cents/lb 18 11 22 18
Gross profit = 22(1) + 18(0.583) - 18(0.449) - 11(1.134) = 11.94 cents/lb VC
Reaction
Path
Overall Reaction
Gross Profit
(cents/lb of VC)
 C2H2 + HCl = C2H3Cl -9.33
 C2H4 +Cl2 = C2H3Cl + HCl 11.94
 C2H4 + HCl + O2 = C2H3Cl + H2O 3.42
 2C2H4 + Cl2 + O2 = 2C2H3Cl + H2O 7.68

• Preliminary Flowsheet for Reaction Path 
– 800 MM lb/year @ 330 days/yr  100,000 lb/hr VC
– From this principal sink, the HCl sink and reagent
sources can be computed (each flow is 1,600 lbmol/h)
– Next step involves distributing the chemicals by
matching sources and sinks.
Cl2
113,400 lb/hr
C2H4
44,900 lb/hr
Direct
Chlorination
Pyrolysis
C2H4Cl2
HCl
58,300 lb/hr
C2H3Cl
100,000 lb/hr
HCl
C2H3Cl
C2H4Cl2
C2H4Cl2  C2H3Cl + HCl
C2H4 + Cl2 C2H4Cl2

 Distribute the chemicals
– A conversion of 100% of the C2H4 is assumed in the
chlorination reaction

 Distribute the chemicals (Cont’d)
– Only 60% of the C2H4Cl2 is converted to C2H3Cl with a byproduct of
HCl, according to Eqn. (4.4).
– To satisfy the overall material balance, 158,300 lb/h of C2H4Cl2
must produce 100,000 lb/h of C2H3Cl and 58,300 lb/h of HCl.
– But a 60% conversion only produces 60,000 lb/h of VC.
– The additional C2H4Cl2 needed is computed by mass balance to
equal:
[(1 - 0.6)/0.6] x 158,300 or 105,500 lb/h.
– Its source is a recycle stream from the separation of C2H3Cl from
unreacted C2H4Cl2, from a mixing operation, inserted to combine
the two sources, to give a total 263,800 lb/h.

– The effluent stream from the pyrolysis operation is the
source for the C2H3Cl product, the HCl by-product, and
the C2H4Cl2 recycle.

– Reactor pressure levels
• Chlorination reaction: 1.5 atm is recommended, to eliminate the
possibility of an air leak into the reactor containing ethylene.
• Pyrolysis reaction: 26 atm is recommended by the B.F.
Goodrich patent (1963) without any justification. Since the
reaction is irreversible, the elevated pressure does not
adversely affect the conversion. Most likely, the patent
recommends this pressure to reduce the size of the pyrolysis
furnace, although the tube walls must be considerably thicker
and many precautions are necessary for operation at elevated
pressures.
• The pressure level is also an important consideration in
selecting the separation operations, as will be discussed in the
next synthesis step.

 Eliminate differences in composition
– The product of the chlorination reaction is nearly pure C2H4Cl2, and
requires no purification.
– In contrast, the pyrolysis reactor conversion is only 60%, and one
or more separation operations are required to match the required
purities in the C2H3Cl and HCl sinks.
– One possible arrangement is given in the next slide. The data
below explains the design decisions made.
Boiling point (oC) Critical constants
Chemical 1 atm 4.8 atm 12 atm 26 atm Tc,C Pc, atm
HCl -84.8 -51.7 -26.2 0 51.4 82.1
C2H3Cl -13.8 33.1 70.5 110 159 56
C2H4Cl2 83.7 146 193 242 250 50

 Eliminate differences in composition (Cont’d)
Boiling point (oC) Critical constants
Chemical 1 atm 4.8 atm 12 atm 26 atm Tc,C Pc, atm
HCl -84.8 -51.7 -26.2 0 51.4 82.1
C2H3Cl -13.8 33.1 70.5 110 159 56
C2H4Cl2 83.7 146 193 242 250 50
Other, possibly better configurations, will be discussed in Lecture 4 (Chapter 8).

 Eliminate differences in T, P & phase

 Integrate tasks (tasks  unit operations)

• Assembly of synthesis tree




Reaction
path
Distribution
of chemicals
Separations T, P and
phase
changes
Task
integration

Algorithmic methods are very effective for the synthesis,
analysis and optimization of alternative flowsheets. These will
be covered later

• Development of Base Case Design

Summary – Process Creation
• Preliminary Database Creation
– to assemble data to support the design
• Experiments
– often necessary to supply missing data or verify crucial data
• Preliminary Process Synthesis
– top-down approach
– to generate a “synthesis tree” of design alternatives
– illustrated by synthesis of for VCM process
• Development of Base-case Design
– focusing on most promising alternative(s) from the synthesis tree

Process Creation.ppt

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Process Creation.ppt