Fixed-bed adsorption
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Hello everybody, I am trying to obtain breakthrough curves from my matlab code, but probably there are some errors that I am not able to find. In particular, I have few doubts on time course. I have attached the matlab code and I hope that someone wants to help me. Thanks a lot.
epsilon = 0.62; % Voidage fraction
Kc = 4.5542e-5; % Mass Transfer Coefficient
Kl = 2.37; % Langmuir parameter
qs = 0.27; % Saturation capacity
cFeed = 10; % Feed concentration
L = 0.01; % Column length
R = 4.52e-10;
rho = 400;
t0 = 0; % Initial Time
tf = 900; % Final time
dt = 10; % Time step
z = [0:0.01:L]; % Mesh generation
t = [t0:dt:tf];% Time vector
n = numel(z); % Size of mesh grid
%Initial Conditions / Vector Creation
c0 = zeros(n,1);% t = 0, c = 0
c0(1)=cFeed;
q0 = zeros(n,1); % t = 0, q = 0 for all z,
q0(1) = zeros;
y0 = [c0 ; q0]; % Appends conditions together
%ODE15S Solver
[T, Y] = ode15s(@(t,y) Myfun(t,y,z,n),[t0 tf],y0);
plot(Y(:,n)/cFeed,'b')
xlabel('time')
ylabel('exit conc.')
function DyDt=Myfun(t,y,z,n)
% Defining Constants
D = 6.25e-4; % Axial Dispersion coefficient
v = 1*10^-3; % Superficial velocity
epsilon = 0.62; % Voidage fraction
Kc = 4.5542e-5; % Mass Transfer Coefficient
Kl = 2.37; % Langmuir parameter
qs = 0.27;% Saturation capacity
R = 4.52e-10;
rho = 400;
%Tc = zeros(n,1);
%q = zeros(n,1);
DcDt = zeros(n,1);
DqDt = zeros(n,1);
DyDt = zeros(2*n,1);
zhalf = zeros(n-1,1);
DcDz = zeros(n,1);
D2cDz2 = zeros(n,1);
c = y(1:n);
q = y(n+1:2*n);
% Interior mesh points
zhalf(1:n-1)=(z(1:n-1)+z(2:n))/2;
for i=2:n-1
DcDz(i) = ((z(i)-z(i-1))/(z(i+1)-z(i))*(c(i+1)-c(i))+(z(i+1)-z(i))/(z(i)-z(i-1))*(c(i)-c(i-1)))/(z(i+1)-z(i-1));
D2cDz2(i) = (zhalf(i)*(c(i+1)-c(i))/(z(i+1)-z(i))-zhalf(i-1)*(c(i)-c(i-1))/(z(i)-z(i-1)))/(zhalf(i)-zhalf(i-1));
end
% Calculate DcDz and D2cDz2 at z=L for boundary condition dc/dz = 0
DcDz(n) = 0;
D2cDz2(n) = -1.0/(z(n)-zhalf(n-1))*(c(n)-c(n-1))/(z(n)-z(n-1));
% Set time derivatives at z=0
% DcDt = 0 since c=cFeed remains constant over time and is already set as initial condition
% Standard setting for q
DqDt(1) = 3/R*Kc*( ((qs*c(1))/(Kl + c(1))) - q(1) );
DcDt(1) = 0.0;
% Set time derivatives in remaining points
for i=2:n
%Equation: dq/dt = k(q*-q) where q* = qs * (b*c)/(1+b*c)
DqDt(i) = 3/R*Kc*( ((qs*c(i))/(Kl + c(i))) - q(i) );
%Equation: dc/dt = D * d2c/dz2 - v*dc/dz - ((1-e)/(e))*dq/dt
DcDt(i) = D/epsilon*D2cDz2(i) - v/epsilon*DcDz(i) - ((1-epsilon)/(epsilon))*rho*DqDt(i);
end
% Concatenate vector of time derivatives
DyDt = [DcDt;DqDt];
end
1 Comment
shubham chauhan
on 17 Nov 2020
Can u tell me ur model equations and plzz tell units of parameters u have taken
Accepted Answer
Alan Stevens
on 5 Sep 2020
Do you just need a finer mesh? See:
epsilon = 0.62; % Voidage fraction
Kc = 4.5542e-5; % Mass Transfer Coefficient
Kl = 2.37; % Langmuir parameter
qs = 0.27; % Saturation capacity
cFeed = 10; % Feed concentration
L = 0.01; % Column length
R = 4.52e-10;
rho = 400;
t0 = 0; % Initial Time
tf = 90; % Final time %%%%%%%%%%% Shorter time
dt = 1; % Time step %%%%%%%%%%% Smaller timestep
z = 0:0.001:L; % Mesh generation %%%%%%%%%%% Finer mesh
t = t0:dt:tf;% Time vector
n = numel(z); % Size of mesh grid
%Initial Conditions / Vector Creation
c0 = zeros(n,1);% t = 0, c = 0
c0(1)=cFeed;
q0 = zeros(n,1); % t = 0, q = 0 for all z,
q0(1) = zeros;
y0 = [c0 ; q0]; % Appends conditions together
%ODE15S Solver
[T, Y] = ode15s(@(t,y) Myfun(t,y,z,n),[t0 tf],y0);
plot(T, Y(:,n)/cFeed,'b')
xlabel('time')
ylabel('exit conc.')
function DyDt=Myfun(~,y,z,n)
% Defining Constants
D = 6.25e-4; % Axial Dispersion coefficient
v = 1*10^-3; % Superficial velocity
epsilon = 0.62; % Voidage fraction
Kc = 4.5542e-5; % Mass Transfer Coefficient
Kl = 2.37; % Langmuir parameter
qs = 0.27;% Saturation capacity
R = 4.52e-10;
rho = 400;
%Tc = zeros(n,1);
%q = zeros(n,1);
DcDt = zeros(n,1);
DqDt = zeros(n,1);
%DyDt = zeros(2*n,1);
zhalf = zeros(n-1,1);
DcDz = zeros(n,1);
D2cDz2 = zeros(n,1);
c = y(1:n);
q = y(n+1:2*n);
% Interior mesh points
zhalf(1:n-1)=(z(1:n-1)+z(2:n))/2;
for i=2:n-1
DcDz(i) = ((z(i)-z(i-1))/(z(i+1)-z(i))*(c(i+1)-c(i))+(z(i+1)-z(i))/(z(i)-z(i-1))*(c(i)-c(i-1)))/(z(i+1)-z(i-1));
D2cDz2(i) = (zhalf(i)*(c(i+1)-c(i))/(z(i+1)-z(i))-zhalf(i-1)*(c(i)-c(i-1))/(z(i)-z(i-1)))/(zhalf(i)-zhalf(i-1));
end
% Calculate DcDz and D2cDz2 at z=L for boundary condition dc/dz = 0
DcDz(n) = 0;
D2cDz2(n) = -1.0/(z(n)-zhalf(n-1))*(c(n)-c(n-1))/(z(n)-z(n-1));
% Set time derivatives at z=0
% DcDt = 0 since c=cFeed remains constant over time and is already set as initial condition
% Standard setting for q
DqDt(1) = 3/R*Kc*( ((qs*c(1))/(Kl + c(1))) - q(1) );
DcDt(1) = 0.0;
% Set time derivatives in remaining points
for i=2:n
%Equation: dq/dt = k(q*-q) where q* = qs * (b*c)/(1+b*c)
DqDt(i) = 3/R*Kc*( ((qs*c(i))/(Kl + c(i))) - q(i) );
%Equation: dc/dt = D * d2c/dz2 - v*dc/dz - ((1-e)/(e))*dq/dt
DcDt(i) = D/epsilon*D2cDz2(i) - v/epsilon*DcDz(i) - ((1-epsilon)/(epsilon))*rho*DqDt(i);
end
% Concatenate vector of time derivatives
DyDt = [DcDt;DqDt];
end
24 Comments
Francesco Caputo
on 5 Sep 2020
Francesco Caputo
on 5 Sep 2020
Alan Stevens
on 5 Sep 2020
Why not try changing them and see!
Francesco Caputo
on 5 Sep 2020
Alan Stevens
on 5 Sep 2020
Ok, I'll have a look, though I'm not familiar with the physics here!
Alan Stevens
on 5 Sep 2020
Edited: Alan Stevens
on 5 Sep 2020
It does change! Your problem must be that you are changing the values at the top of the program, but these aren't used! You have redefined them within Myfun. These are the ones you need to change.
Francesco Caputo
on 5 Sep 2020
Francesco Caputo
on 9 Sep 2020
Alan Stevens
on 9 Sep 2020
Edited: Alan Stevens
on 9 Sep 2020
Because you wrote "visualize" I assume you want to plot area under the curve as a function of time. If so, use cumtrapz (the cumulative area). Use the following in your code:
figure
subplot(2,1,1)
plot(T, Y(:,n)/cFeed,'b')
grid
xlabel('time')
ylabel('exit conc.')
title(['Kl = ', num2str(Kl), ' qs = ', num2str(qs)])
% Cumulative area
A = cumtrapz(T,Y(:,n)/cFeed);
subplot(2,1,2)
plot(T,A),grid
xlabel('time'), ylabel('Area')
This results in something like the following:
Francesco Caputo
on 9 Sep 2020
Francesco Caputo
on 10 Sep 2020
Alan Stevens
on 10 Sep 2020
I can't really tell. Possibly include
DcDz(1) = v*(c(1)-cFeed)/D;
though this doesn't seem to make any noticeable difference.
Francesco Caputo
on 10 Sep 2020
shubham chauhan
on 17 Nov 2020
Mr Alan steavns the code u solve for fixed bed absorption I need modelling equations and the parameters values
shubham chauhan
on 17 Nov 2020
Mr Alan Stevens also tell which mathematical technique you used to solve the code for partial differential equation
Alan Stevens
on 17 Nov 2020
@ shubham chauhan All the coding, values etc are given in the replies above.
shubham chauhan
on 19 Nov 2020
I Need breakthrough curve at the exit of the bed help me developing code for this
Alan Stevens
on 19 Nov 2020
@shubham chauhan The coding listed by Francesco on 10 Sep 2020 above, together with my reply just below it produces the breakthrough curve (whatever that might be!).
shubham chauhan
on 20 Nov 2020
@alan stevens i have different modelling equations to obtain breakthrough curve. If u are interested in making code for that i will share my modelling equations. I have two PDEs to solve
Aïli Bourbah
on 22 Nov 2020
@shubham chauhan Hi. I am a student working for a company about tetrachloro-ethene adsorption and desorption into activated carbon as a school project. Could I have your email to ask you some things about making a code for simulation ?
Aniruddha Jain
on 30 Nov 2020
Can you send the research paper from where you solved the above equations?
Anshul Suri
on 14 Jul 2021
Hi can someone please refer me to theoretical background over this problem?
Federico Urbinati
on 18 Oct 2022
hi does anyone have the matlab code to solve adsorption when you have multiple components and not just one?
I hope someone can answer, I can not go forward. thank you
Federico Urbinati
on 24 Oct 2022
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