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Reactors. Mixing Model. Conservative and Instantaneous Signal. A signal is a tracer that injected into the influent to a reactor. Conservative means it does not react. Instantaneous means the tracer is introduced into the influent instantaneously. Ideal reactors. Mixed Batch.
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Mixing Model Conservative and Instantaneous Signal A signal is a tracer that injected into the influent to a reactor Conservative means it does not react Instantaneous means the tracer is introduced into the influent instantaneously
Ideal reactors Mixed Batch Fully mixed, no inflow, no out flow Plug Flow Continuous flow, but no mixing Completely Mixed Flow Reactor Continuous flow with perfect mixing
Mixed Batch Reactor Conservative Instantaneous Signal Added Signal added at time zero, mixed instantaneously This figure is called a C-distribution A plot of C vs t or C/C0 vs t
t = V/Q Plug Flow Reactor No longitudinal mixing, all elements of water enter and exit in same order. The time spent in the reactor, the residence time, is equal for all elements: V = volume Q = flow rate Another way to think of the residence time is the time to fill the reactor. This is actually true for any type of reactor.
Plug Flow Reactor C-distribution Curve
Plug Flow Reactor F-distribution Curve F is the fraction of that has left the reactor at any time t: F = (A0 –AR)/A0 A0 = the mass of tracer added to the reactor AR = the mass of tracer remaining in the reactor
Rate of Signal Accumulated Rate of Signal in Rate of Signal out Rate of Signal Generated = - + Rate of Signal Accumulated Rate of Signal out - = 0 Completely Mixed Flow Reactor Abbreviated CMF. Often called Completely Stirred Tank Reactor (CSTR) or Complete Mix reactor Signal introduced instantaneously so the rate in = 0 Also, no generation (conservative tracer) C0 = A0/V Where: A0 = mass of signal in the reactor at t = 0 V = volume of the reactor C0 = concentration in reactor at t = 0
Rate of Signal Accumulated Rate of Signal out - = Rate of Signal Accumulated = - C Q = -(A/V) Q After the tracer has been introduced (instantaneously) the concentration changes with time because water without tracer keeps entering the reactor and: C = A/V Where: A = mass of tracer in the reactor at any time t V = volume of the reactor C = concentration at time t Now: So: dA/dt = -(A/V) Q
A t dA/A = - Q/V dt A0 0 t = V/Q So: A/A0 = e-t / t Or: C/C0 = e-t / t dA/dt = -(A/V) Q lnA - lnA0 = - (Q/V) t A/A0 = e-(Q/V)t
C/C0 = e-t / t When t = t,: C/C0 = e-1 = 0.368
Completely Mixed Flow Reactor F-distribution Curve
CSTR’s in Series N reactors in series Each reactor has a volume of V0 Total volume of the system, V = n x V0 The rest of the discussion is section 5.1.4 in your text is incorrect. The following derivation is the right way to do it!
Mass balance on the first reactor: (V/n) dC1/dt = Q C0 – Q C1 Or: dC1/dt = (nQ/V) (C0 – C1) Separate variables and integrate: C1 = C0 e-n(Q/V)t = C0 e-n t / to where to = V/Q (residence time of the whole system)
Mass balance on the second reactor: (V/n)dC2/dt = Q C1 - Q C2 Or: dC2/dt + (nQ/V)C2 = (nQ/V) C1 Since: C1 = C0 e-n t / to dC2/dt + (nQ/V)C2 = (nQ/V) C0 e-n t / to The solution to this equation is: C2 = C0n (t / t0) e-n t / to
By extension: Ci = (C0/(i – 1)!) [n(t/t0)]i-1 e-n(t/to) Use this equation to predict concentration coming from any reactor in the series at any time t Or: Ci/C0 = (1/(i – 1)!) [n(t/t0)]i-1 e-n(t/to) Use this equation to plot a C-distribution curve Note: These equations are slightly different from the equations in the book. The equations in the book are incorrect. (Equations 5.2 and 5.3)
F-distribution curves for a series of CSTR’s may also be Developed. The equation is in your text on page 135. It is correct. The F-distribution for n= infinity is identical to the f-distribution for a plug flow reactor
In the real world there is no such thing as a perfect plug flow reactor or CSTR Causes: Imperfect mixing Short circuiting Dead Space Arbitrary Flow Reactors