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Chemical Reaction Engineering Asynchronous Video Series Chapter 2: Conversion and Reactors in Series H. Scott Fogler, Ph.D.

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Presentation on theme: "Chemical Reaction Engineering Asynchronous Video Series Chapter 2: Conversion and Reactors in Series H. Scott Fogler, Ph.D."— Presentation transcript:

1 Chemical Reaction Engineering Asynchronous Video Series Chapter 2: Conversion and Reactors in Series H. Scott Fogler, Ph.D.

2 Reactor Mole Balance Summary

3 Conversion

4

5

6 Batch Reactor Conversion For example, let’s examine a batch reactor with the following design equation:

7 Batch Reactor Conversion For example, let’s examine a batch reactor with the following design equation: Consider the reaction:

8 Batch Reactor Conversion For example, let’s examine a batch reactor with the following design equation: Consider the reaction:

9 Batch Reactor Conversion For example, let’s examine a batch reactor with the following design equation: Consider the reaction: Differential Form: Integral Form:

10 CSTR Conversion Algebraic Form: There is no differential or integral form for a CSTR.

11 PFR Conversion PFR

12 PFR Conversion PFR

13 PFR Conversion PFR Differential Form: Integral Form:

14 Design Equations

15

16

17 V

18 V

19 Example

20 0 0.01

21 Example 0 0 0.01

22 Example 0 X 0.20.4 0.60.8 10 20 30 40 50 0 0.01

23 Reactor Sizing Given -r A as a function of conversion, -r A =f(X), one can size any type of reactor.

24 Reactor Sizing Given -r A as a function of conversion, -r A =f(X), one can size any type of reactor. We do this by constructing a Levenspiel plot.

25 Reactor Sizing Given -r A as a function of conversion, -r A =f(X), one can size any type of reactor. We do this by constructing a Levenspiel plot. Here we plot either as a function of X. 0.20.4 0.60.8 10 20 30 40 50

26 Reactor Sizing Given -r A as a function of conversion, -r A =f(X), one can size any type of reactor. We do this by constructing a Levenspiel plot. Here we plot either as a function of X. For vs. X, the volume of a CSTR is: Equivalent to area of rectangle on a Levenspiel Plot X EXIT 0.20.4 0.60.8 10 20 30 40 50

27 Reactor Sizing Given -r A as a function of conversion, -r A =f(X), one can size any type of reactor. We do this by constructing a Levenspiel plot. Here we plot either as a function of X. For vs. X, the volume of a CSTR is: For vs. X, the volume of a PFR is: Equivalent to area of rectangle on a Levenspiel Plot X EXIT = area under the curve =area 0.20.4 0.60.8 10 20 30 40 50

28 Numerical Evaluation of Integrals The integral to calculate the PFR volume can be evaluated using Simpson’s One-Third Rule:

29 Numerical Evaluation of Integrals The integral to calculate the PFR volume can be evaluated using Simpson’s One-Third Rule (see Appendix A.4 on p. 924):

30 Reactors In Series

31

32

33 Reactors in Series Also consider a number of CSTRs in series:

34 Reactors in Series Finally consider a number of CSTRs in series: We see that we approach the PFR reactor volume for a large number of CSTRs in series: X

35 Summary

36

37

38

39

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