Chemical Reaction Engineering Asynchronous Video Series
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Chemical Reaction Engineering Asynchronous Video Series Chapter 4, Part 1: Applying the Algorithm to a CSTR H. Scott Fogler, Ph.D.
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Chemical Reaction Engineering Asynchronous Video Series. Chapter 4, Part 1: Applying the Algorithm to a CSTR H. Scott Fogler, Ph.D. Summary. At the start of the chapter we saw we needed -r A =f(X). This result is achieved in two steps. Rate Laws -r A =k f(C i ) - PowerPoint PPT Presentation
Transcript of Chemical Reaction Engineering Asynchronous Video Series
Chemical Reaction Engineering
Asynchronous Video Series
Chapter 4, Part 1:
Applying the Algorithm to a CSTR
H. Scott Fogler, Ph.D.
Summary
At the start of the chapter we saw we needed -rA=f(X). This result is achieved in two steps.
1. Rate Laws
– -rA=k f(Ci)
– 1st order A--> B or 1st order
– 2nd order A+B --> C
– Rate laws are found by experiment
2. Stoichiometry
– Liquid:
– Gas:
-rA=kCA
€
−rA = k C A −C B
KC
⎡
⎣ ⎢ ⎢
⎤
⎦ ⎥ ⎥
-rA=kACACB
€
C A = CA 0 1− X( )
€
C A =CA 0 1− X( )
1+ εX( )PP0
T0
T
€
C A = CT 0
FT
FT 0
PP0
T0
T
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
The Evaluate step can be carried out:
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
The Evaluate step can be carried out:1. Graphically (Chapter 2 plots)
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
The Evaluate step can be carried out:1. Graphically (Chapter 2 plots)
2. Numerically (Quadrature formulas: Chapter 2 and Appendices)
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
The Evaluate step can be carried out:1. Graphically (Chapter 2 plots)
2. Numerically (Quadrature formulas: Chapter 2 and Appendices)
3. Analytically (Integral tables in Appendix)
Algorithm for Isothermal Reactor Design
1. Mole Balance and Design Equation
2. Rate Law
3. Stoichiometry
4. Combine
5. Evaluate
The Evaluate step can be carried out:1. Graphically (Chapter 2 plots)
2. Numerically (Quadrature formulas: Chapter 2 and Appendices)
3. Analytically (Integral tables in Appendix)
4. Software packages (Appendix - Polymath)
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Stoichiometry: gas phase, isothermal (T=T0), no pressure drop (P=P0)
French Menu Analogy
French Menu Analogy
Remember the French Menu reaction:
For a gas phase system:
Deriving CA and CB:
French Menu Analogy
Remember the French Menu reaction:
For a gas phase system:
If the conditions are isothermal (T = T0) and isobaric (P =P0):
Deriving CA and CB:
French Menu Analogy
Remember the French Menu reaction:
For a gas phase system:
If the conditions are isothermal (T = T0) and isobaric (P =P0):
We must divide by the stoichiometric coefficient of our basis of calculation yielding:
Deriving CA and CB:
French Menu Analogy
Remember the French Menu reaction:
For a gas phase system:
If the conditions are isothermal (T = T0) and isobaric (P =P0):
We must divide by the stoichiometric coefficient of our basis of calculation yielding:
And if the feed is equal molar, then:
Deriving CA and CB:
French Menu Analogy
This leaves us with CA as a function of conversion alone:
Deriving CA and CB:
French Menu Analogy
This leaves us with CA as a function of conversion alone:
Similarly for CB:
€
FB0 = FA0
Therefore, Θ B =1
Deriving CA and CB:
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Stoichiometry: gas phase, isothermal (T=T0), no pressure drop (P=P0)
[Why do you think CB is constant, when B is consumed?]
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Stoichiometry: gas phase, isothermal (T=T0), no pressure drop (P=P0)
[Why do you think CB is constant, when B is consumed?]
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Stoichiometry: gas phase, isothermal (T=T0), no pressure drop (P=P0)
[Why do you think CB is constant, when B is consumed?]
Combine:
French Menu Analogy
Example: The elementary gas phase reaction takes place in a CSTR at constant temperature (500 K) and constant pressure (16.4 atm). The feed is equal molar in A and B.
Mole Balance:
Rate Law:
Stoichiometry: gas phase, isothermal (T=T0), no pressure drop (P=P0)
[Why do you think CB is constant, when B is consumed?]
Combine:
Evaluate:
French Menu Analogy
