Multiple Steady States in a Continuously Stirred Tank Reactor

​
heat transfer coefficient (cal/[
2
dm
K s])
0
reverse reaction pre-exponential factor (1/s)
0
feed temperature (K)
265
residence time (s)
400
This Demonstration plots the concentration of product
B
as a function of temperature for the mass and energy balances done on a continuous stirred-tank reactor (CSTR) with heat transfer. The reversible, elementary, exothermic reaction
A↔B
takes place in the CSTR. Use sliders to change the feed temperature, residence time, heat transfer coefficient, and reverse-reaction pre-exponential factor. The intersections of the green curve and straight blue line correspond to the steady-state solutions for the CSTR. Either one or three solutions are possible; for three solutions, the middle solution is unstable.

Details

The mass balance is nonlinear:
C
B
=τ
k
f
-
E
f
RT
e
C
A,0
1+τ
k
f
-
E
f
RT
e
+τ
k
r
-
E
r
RT
e
,
where
C
B
is the concentration of product
B
(
mol/
3
dm
),
C
A,0
is the reactant feed concentration (mol),
k
f
and
k
r
are the pre-exponential factors for the forward and reverse reactions (1/s),
E
f
and
E
r
are the activation energies for the forward and reverse reactions (cal/mol),
τ
is residence time (s),
R
is the ideal gas constant (cal/[mol K]), and
T
is temperature of the CSTR (K).
The energy balance is linear and has two terms that correspond to (1) the energy needed to change the feed temperature to the reactor temperature, and (2) the energy removed or added by heat transfer to a cooling/heating fluid, which is at a constant temperature of 310 K.
C
B
=
-vρCp(T-
T
0
)-UA(T-
T
c
)
vΔH
,
where
v
is the volumetric flow rate (
3
dm
/s
),
ρ
is the density of the bulk fluid (
kg
3
dm
),
Cp
is the mass heat capacity of the feed (cal/[kg K]),
T
0
and
T
c
are the temperatures of the feed and coolant (K),
U
is the heat transfer coefficient (
cal/[
2
dm
Ks]
),
A
is the heat transfer area (
2
dm
), and
ΔH
is the heat of reaction (cal/mol).
As the feed temperature increases from a low value, the reactor temperature increases until the reactor reaches a temperature above which three steady-state solutions are possible. The upper and lower solutions are stable, and the middle solution is unstable. The operating conditions of the reactor depend on how the reactor is started up. As the feed temperature increases further, a temperature is reached above which only one solution is possible, and this has a high conversion.
Varying the heat transfer coefficient changes both the slope and intercept of the energy balance line, and this can change the number of steady-state solutions. Increasing the pre-exponential factor for the reverse reaction changes the mass balance curve, and the maximum conversion decreases as the equilibrium conversion become less than one.
The screencast video at[1] shows how to use this Demonstration.

References

[1] Multiple Steady States in a Continuously Stirred Tank Reactor. www.colorado.edu/learncheme/kinetics/MultipleSteadyStatesCSTRnoHeat.html.

External Links

Multiple Steady States in a Continuous Stirred-Tank Reactor with Heat Exchange

Permanent Citation

Rachael L. Baumann, John L. Falconer
​
​"Multiple Steady States in a Continuously Stirred Tank Reactor"​
​http://demonstrations.wolfram.com/MultipleSteadyStatesInAContinuouslyStirredTankReactor/​
​Wolfram Demonstrations Project​
​Published: June 7, 2013