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Chapter 16, Problem 16.1P

(a)

Interpretation Introduction

Interpretation:

The fraction of a fluid that spends 9minutes or more than 9minutes in a reactor is to be stated.  The fraction of a fluid that spends 2minutes or less than 2minutes in a reactor is to be stated.

Concept introduction:

The full form of PFR is Plug-Flow Reactor which consists of a cylindrical pipe and it is used for the gas-phase reactions. It is also known as tubular reactor.

The time of residence of fluid inside the reactor, determines the rate of conversion of the reactant or fluid, depending upon the concentration and mixing of the fluid inside the reactor.

(a)

Expert Solution
Check Mark

Answer to Problem 16.1P

The fraction of a fluid that spends 9minutes or more than 9minutes in a reactor is 0.0968. The fraction of a fluid that spends 2minutes or less than 2minutes in a reactor is 0.0677.

Explanation of Solution

The given E(t) versus time graph is shown as follows.

Elements of Chemical Reaction Engineering (5th Edition) (Prentice Hall International Series in the Physical and Chemical Engineering Sciences), Chapter 16, Problem 16.1P , additional homework tip  1

Figure 1

The expression to calculate the fluid present in the reactor is as follows.

    ϕ=t1t2E(t)dt                                                                                     (1)

Where,

  • 0E(t)dt corresponds to the area covered within E(t) curve.
  • t1 and t2 are the time intervals.

The area that is covered between 9minutes to 15minutes is shown as follows.

Elements of Chemical Reaction Engineering (5th Edition) (Prentice Hall International Series in the Physical and Chemical Engineering Sciences), Chapter 16, Problem 16.1P , additional homework tip  2

Figure 2

Substitute the limits t1 as 9min and t2 as 15min in equation (1).

    ϕ=915E(t)dt=913.5E(t)dt+13.5150dt=913.5E(t)dt

The Simpson’s 3/8 rule is used to calculate the area under the curve as follows.

    X0X3E(t)dt=3h8[f(X0)+3f(X1)+3f(X2)+f(X3)]                      (2)

Where,

  • h is equal to X3X03
  • X0 is the lower limit.
  • X3 is the upper limit.

For the limits, X0=9 and X3=13.5, the value of h is calculated as follows.

    h=13.593=1.5

According to the graph, the values of f(X0) is 0.044, f(X1) is 0.03, f(X2) is 0.012 and f(X3) is 0.002.

Substitute the values of h as 1.5, f(X0) as 0.044, f(X1) as 0.03, f(X2) as 0.012 and f(X3) as 0.002 in equation (2).

    913.5E(t)dt=3×1.58[0.044+3×0.03+3×0.012+0.002]=0.5625[0.172]=0.0968

Thus, the fraction of a fluid that spends between 9minutes to 15minutes in a reactor is 0.0968.

The area that is covered between less than 2minutes is shown as follows.

Elements of Chemical Reaction Engineering (5th Edition) (Prentice Hall International Series in the Physical and Chemical Engineering Sciences), Chapter 16, Problem 16.1P , additional homework tip  3

Figure 3

Substitute the limits t1 as 0min and t2 as 2min in equation (1).

    ϕ=02E(t)dt

The Simpson’s 1/3 rule is used to calculate the area under the curve as follows.

    X0X2E(t)dt=h3[f(X0)+3f(X1)+f(X2)]                                        (3)

Where,

  • h is equal to X2X02
  • X0 is the lower limit.
  • X2 is the upper limit.

For the limits, X0=0 and X2=2, the value of h is calculated as follows.

    h=202=1

According to the graph, the values of f(X0) is 0, f(X1) is 0.04 and f(X2) is 0.083.

Substitute the values of h as 1, f(X0) as 0, f(X1) as 0.04, and f(X2) as 0.083 in equation (3).

    02E(t)dt=13[0+3×0.04+0.083]=13[0.203]=0.0677

Thus, the fraction of a fluid that spends less than 2minutes in a reactor is 0.0677.

(b)

Interpretation Introduction

Interpretation:

The change in the value of E(t) if τp is reduced by 50% and τs increased by 50% is to be stated.  The fraction of a fluid that spends 2minutes or less than 2minutes in a reactor is to be stated.

Concept introduction:

The full form of PFR is Plug-Flow Reactor which consists of a cylindrical pipe and it is used for the gas-phase reactions. It is also known as tubular reactor.

The full form of CSTR is Continuous-Stirred Tank Reactor. This reactor has its application in the industrial processes and used for liquid-phase reactions.

The processing time for one reactor volume of fluid, depending on a set of inlet conditions of reactant is represented by the space time, τ. It is the ratio of volume of the reactor to the flow rate entering the reactor.

(b)

Expert Solution
Check Mark

Answer to Problem 16.1P

The change in the value of E(t) if τp is reduced by 50% and τs increased by 50% is e((t0.5)1.5)1.5. The fraction of a fluid that spends 2minutes or less than 2minutes in a reactor is 0.0677.

Explanation of Solution

The second-order liquid-phase reaction is given.

For the second order reaction which takes place in a real CSTR and in a real PFR possesses the value of τp=τs=1.

The given condition is space time of PFR, τp, is decreased by 50% and the space time of CSTR, τs, is increased by 50%.

The exit function E(t) for the combined reactors, PFR and CSTR, is given below.

    E(t)=0t<τp=e((tτp)τs)τstτp                                                                (4)

If τp=1 for the given combination of PFR and CSTR and it is reduced to 50% then the value of τp becomes 0.5.

If τs=1 for the given combination of PFR and CSTR and it is increased to 50% then the value of τs becomes 1+0.5=1.5.

Substitute the value of τs as 1.5 and τp as 0.5 in equation (4).

    E(t)=e((t0.5)1.5)1.5

Thus, the value of E(t) becomes e((t0.5)1.5)1.5 for the given conditions.

As calculated above, the fraction of a fluid that spends less than 2minutes in a reactor is 0.0677.

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Chapter 16 Solutions

Elements of Chemical Reaction Engineering (5th Edition) (Prentice Hall International Series in the Physical and Chemical Engineering Sciences)

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