Isothermal reactor design - 2013

Class date(s):

04 February to 14 February



Download video: Link (plays in Google Chrome) [291 M]



Download video: Link (plays in Google Chrome) [304 M]



Download video: Link (plays in Google Chrome) [393 M]



Download video: Link (plays in Google Chrome) [M]



Download video: Link (plays in Google Chrome) [243 M]



Download video: Link (plays in Google Chrome) [353 M]

F2011: Chapter 5 and 6
F2006: Chapter 4

04 February 2013 (05A)

General problem solving strategy for reactor engineering
Audio and video recording of the class

06 February 2013 (05B)

The Ergun equation derivation
Audio and video recording of the class

07 February 2013 (05C)

Notes used during the class
The spreadsheet with the Ergun equation example. Use it to try
- different lengths of reactor
- different catalyst particle sizes
- different pipe diameters
- gas properties (e.g. density)

to see the effect on pressure drop in the packed bed.

Audio and video recording of the class

11 February 2013 (06A)

Audio and video recording of the class
Codes to solve the example in class are available on the page software for integrating ODEs.

14 February 2013 (06C): midterm review

Audio and video recording of the class

25 February 2013 (07A)

Audio and video recording of the class

The example covered in class is based on example 4-8 in F2006 and example 6-2 in F2011. <rst> <rst-options: 'toc' = False/> <rst-options: 'reset-figures' = False/> The 3 ODE's are:

.. math::

\dfrac{dF_A}{dV} &= r_A\\ \dfrac{dF_B}{dV} &= r_B - R_B \\ \dfrac{dF_C}{dV} &= r_C

where :math:`-r_A = r_B = r_C` and :math:`-r_A = k\left(C_A - \dfrac{C_B C_C}{K_C} \right)`, and :math:`R_B = k_\text{diff}C_B`.

:math:`k = 0.01\,\text{s}^{-1}`
:math:`k_\text{diff} = 0.005\,\text{s}^{-1}`
:math:`K_C = 50\,\text{mol.m}^{-3}`

We derived earlier in the course that

.. math:: C_A = C_\text{TO}\left(\dfrac{F_A}{F_T}\right)\left(\dfrac{P}{P_0}\right)\left(\dfrac{T_0}{T}\right)

Assuming isothermal and isobaric conditions in the membrane:

.. math:: C_A = C_\text{T0}\left(\dfrac{F_A}{F_T}\right)

where :math:`F_T = F_A + F_B + F_C` and :math:`C_\text{T0} = \dfrac{P_0}{RT_0}`. Similar equations can be written for :math:`C_B` and :math:`C_C`.

Using all of the above derivations, we can set up our numerical integration as shown below. </rst>

MATLAB	Python
In a file called `membrane.m`: sdfsdf In a separate file (any name), for example: `ode_driver.m`, which will "drive" the ODE solver: asdas File:Plots-MATLAB.png	asdasd File:Plots-Python.png

and in Polymath:

d(FA)/d(V) = rA
d(FB)/d(V) = rB - kDiff * CB
d(FC)/d(V) = rC

FA(0) = 0.25  # mol/s
FB(0) = 0.0   # mol/s
FC(0) = 0.0   # mol/s

# Independent variable	
V(0) = 0
V(f) = 0.4  #m^3

# Constants
kDiff = 0.005  # s^{-1}
k = 0.01       # s^{-1}
KC = 50        # mol.m^{-3}
P0 = 830600    # Pa
T0 = 500       # K
R  = 8.314     # J/(mol.K)

# Algebraic equations
FT = FA + FB + FC
CT0 = P0 / (R * T0)
CA = CT0 * FA / FT
CB = CT0 * FB / FT
CC = CT0 * FC / FT
rA = -k * (CA - CB * CC / KC)
rB = -rA
rC = -rA