Can I ask you, how did you derive the differential equations that you are using in your model?
Fixed Bed Adsorption Model
26 vues (au cours des 30 derniers jours)
Afficher commentaires plus anciens
I have to model a fixed bed adsorption to obtain the breakthrough curve of the adsorption. I tried to code the model but i think the initial and boundary condition in the code are not correct. Beside that, I got this error when i ran this code.
Warning: Failure at t=2.006182e+02. Unable to meet integration tolerances without reducing the step size below the
smallest value allowed (4.547474e-13) at time t.
> In ode15s (line 655)
In fyp (line 19)
I am not really good with MATLAB, so I would really appreciate any of your help. Thank you very much. I have also attached the model's equations in the file.
Cfeed = 0.0224; % Inlet concentration
tf = 2000; % End time
nz = 200; % Number of gateways
np = nz + 1; % Number of gateposts
% Initial Concentrations
Cb = zeros(np,1); Cb(1) = Cfeed;
Cp = zeros(np,1);
% Prepare data to pass to ode solver
c0 = [Cb; Cp];
dt = tf/100;
tspan = 0:dt:tf;
% Call ode solver
[t, c] = ode15s(@rates, tspan, c0);
% Plot results
plot(t, c(:,np)/Cfeed),grid
xlabel('time'), ylabel('Cb/Cfeed')
title('Figure 1: Exit Cb/Cfeed vs time')
figure
plot(t, c(:,2*np)),grid
xlabel('time'), ylabel('Cp')
title('Figure 2: Exit Cp vs time')
figure
plot(t, c(:,np)-c(:,2*np)), grid
xlabel('time'), ylabel('Cb - Cp')
title('Figure 3: Exit Cb-Cp vs time')
k = 598;
q = k*c(:,2*np); % Freundlcih equation
figure
plot(t,q), grid
xlabel('time'), ylabel('q')
title('Figure 4: Exit q vs time')
% Function to calculate rate of change of concentrations with time
function dcdt = rates(~, c)
a=0.00000000261;
b=0.2102;
d=1705.4719;
e=-38.8576;
L=0.08;
nz = 200; % Number of gateways
np = nz + 1; % Number of gateposts
dz = L/nz;
Cb = c(1:np);
Cp = c(np+1:end);
dCbdt = zeros(np,1);
dCpdt = zeros(np,1);
for i = 2:np-1
dCbdt(i) = (a/dz^2)*(Cb(i+1)-2*Cb(i)+Cb(i-1)) - b/(2*dz)*(Cb(i+1)-Cb(i-1)) - d*(Cb(i)-Cp(i));
dCpdt(i) = e*(Cb(i)-Cp(i)); % Needed to change the sign from -ve to +ve here.
end % i loop
% For simplicity, set exit rates to those of the immediately previous nodes
dCbdt(np) = dCbdt(np-1);
dCpdt(np) = dCpdt(np-1);
% Combine rates for the function to return to the calling routine
dcdt = [dCbdt; dCpdt];
end % of rates function
Réponses (1)
Torsten
le 16 Avr 2022
Modifié(e) : Torsten
le 16 Avr 2022
Cfeed = 0.0224; % Inlet concentration
tf = 3000; % End time
nz = 400; % Number of gateways
np = nz + 1; % Number of gateposts
% Initial Concentrations
Cb = zeros(np,1); Cb(1) = Cfeed;
Cp = zeros(np,1);
% Prepare data to pass to ode solver
c0 = [Cb; Cp];
dt = tf/200;
tspan = 0:dt:tf;
% Call ode solver
[t, c] = ode15s(@rates, tspan, c0);
% Plot results
figure(1)
plot(t, c(:,np)/Cfeed),grid
xlabel('time'), ylabel('Cb/Cfeed')
title('Figure 1: Exit Cb/Cfeed vs time')
figure(2)
plot(t, c(:,2*np)),grid
xlabel('time'), ylabel('Cp')
title('Figure 2: Exit Cp vs time')
figure(3)
plot(t, c(:,np)-c(:,2*np)), grid
xlabel('time'), ylabel('Cb - Cp')
title('Figure 3: Exit Cb-Cp vs time')
k = 598;
q = k*c(:,2*np); % Freundlcih equation
figure(4)
plot(t,q), grid
xlabel('time'), ylabel('q')
title('Figure 4: Exit q vs time')
L=0.08;
dz = L/nz;
z=0:dz:L;
figure(5)
plot(z,[c(1,1:np);c(2,1:np);c(3,1:np);c(4,1:np);c(5,1:np)])
figure(6)
plot(z,[c(1,np+1:2*np);c(2,np+1:2*np);c(3,np+1:2*np);c(4,np+1:2*np);c(5,np+1:2*np)])
% Function to calculate rate of change of concentrations with time
function dcdt = rates(t, c)
a=0.00000000261;
b=0.2102;
d=1705.4719;
e=8.8576;
L=0.08;
nz = 400; % Number of gateways
np = nz + 1; % Number of gateposts
dz = L/nz;
Cb = c(1:np);
Cp = c(np+1:end);
dCbdt = zeros(np,1);
dCpdt = zeros(np,1);
for i = 2:np-1
%dCbdt(i) = (a/dz^2)*(Cb(i+1)-2*Cb(i)+Cb(i-1)) - b/(2*dz)*(Cb(i+1)-Cb(i-1)) - d*(Cb(i)-Cp(i));
dCbdt(i) = (a/dz^2)*(Cb(i+1)-2*Cb(i)+Cb(i-1)) - b/dz*(Cb(i)-Cb(i-1)) - d*(Cb(i)-Cp(i));
dCpdt(i) = e*(Cb(i)-Cp(i)); % Needed to change the sign from -ve to +ve here.
end % i loop
% For simplicity, set exit rates to those of the immediately previous nodes
%dCbdt(np) = dCbdt(np-1);
%dCpdt(np) = dCpdt(np-1);
dCbdt(np) = -2*a*(Cb(np)-Cb(np-1))/dz^2 - d*(Cb(np)-Cp(np));
dCpdt(np) = e*(Cb(np)-Cp(np));
% Combine rates for the function to return to the calling routine
dcdt = [dCbdt; dCpdt];
t
end % of rates function
Concerning your equations: Since you don't solve equations for Cp within the particle, but only define an overall mass transfer coefficient at r=R, you don't need the conditions at r=0 and r=R.
13 commentaires
Torsten
le 15 Mai 2022
Modifié(e) : Torsten
le 15 Mai 2022
time = [0 40 50 65 75 90 110];
cnorm = [0 0 0.01 0.2 0.6 0.95 1.0];
p0 = 2.0;
info = 0;
sol = lsqnonlin(@(p)fit(p,time,cnorm,info),p0);
info = 1;
res = fit(sol,time,cnorm,info)
function res = fit(p,time,cnorm,info)
format long
p
Cfeed = 0.0227; % Inlet concentration
tf = 250; % End time
nz = 100; % Number of gateways
np = nz + 1; % Number of gateposts
% Initial Concentrations
Cb = zeros(np,1); Cb(1) = Cfeed;
Cp = zeros(np,1);
% Prepare data to pass to ode solver
c0 = [Cb; Cp];
if info==0
tspan = time;
elseif info==1
tf = 250; % End time
dt = tf/200;
tspan = 0:dt:tf;
end
% Call ode solver
[t, c] = ode15s(@(t,c)rates(t,c,p), tspan, c0);
if info==0
res = cnorm.' - c(:,np)/Cfeed
elseif info==1
res = cnorm - interp1(t,c(:,np),time)/Cfeed
end
if info == 1
% Plot results
figure(1)
plot(t, c(:,np)/Cfeed),grid
hold on
plot(time,cnorm,'*')
xlabel('time'), ylabel('Cb/Cfeed')
title('Figure 1: Exit Cb/Cfeed vs time')
L=0.065;
dz = L/nz;
z=0:dz:L;
figure(2)
plot(z,[c(40,1:np);c(80,1:np);c(120,1:np);c(160,1:np);c(200,1:np)])
figure(3)
plot(z,[c(40,np+1:2*np);c(80,np+1:2*np);c(120,np+1:2*np);c(160,np+1:2*np);c(200,np+1:2*np)])
end
end
% Function to calculate rate of change of concentrations with time
function dcdt = rates(t, c, e)
persistent iter
if isempty(iter)
iter = 0;
end
iter = iter + 1;
a=0.00000001278;
b=0.16056;
d=244.9429;
%e=1.3964;
L=0.065;
nz = 100; % Number of gateways
np = nz + 1; % Number of gateposts
dz = L/nz;
Cb = c(1:np);
Cp = c(np+1:end);
dCbdt = zeros(np,1);
dCpdt = zeros(np,1);
for i = 2:np-1
%dCbdt(i) = (a/dz^2)*(Cb(i+1)-2*Cb(i)+Cb(i-1)) - b/(2*dz)*(Cb(i+1)-Cb(i-1)) - d*(Cb(i)-Cp(i));
dCbdt(i) = (a/dz^2)*(Cb(i+1)-2*Cb(i)+Cb(i-1)) - b/(2*dz)*(Cb(i+1)-Cb(i-1)) - d*(Cb(i)-Cp(i));
dCpdt(i) = e*(Cb(i)-Cp(i)); % Needed to change the sign from -ve to +ve here.
end % i loop
% For simplicity, set exit rates to those of the immediately previous nodes
%dCbdt(np) = dCbdt(np-1);
%dCpdt(np) = dCpdt(np-1);
dCbdt(np) = -b/dz*(Cb(np)-Cb(np-1)) - 2*a/dz^2*(Cb(np)-Cb(np-1)) - d*(Cb(np)-Cp(np));
dCpdt(np) = e*(Cb(np)-Cp(np));
% Combine rates for the function to return to the calling routine
dcdt = [dCbdt; dCpdt];
if mod(iter,100)==0
disp(t)
iter = 0;
end
end % of rates function
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