Solving an integral within a partial derivative

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kjell revenberg am 21 Dez. 2023

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Kommentiert: Torsten am 9 Jan. 2024

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Hi everyone,

I am having trouble solving the following heat equation in Matlab

As you can see there will be an integral within the partial derivative.

When solving my equations work, but do not work over time. Thus i have a feeling I do something wrong with solving the integral. This is how I currently describe the problem. I did not fully iplement the higher order terms, as it does not work yet.

P = dimensionless term cf/kf

Z = 1/kf(w/W)

tmax = 1000 s

Any help would be greatly appreciated

m = 0;
sol = pdepe(m,@heatpde,@heatic,@heatbc,x,t);
function [c,f,s] = heatpde(x,t,u,dudx)
global B tmax Z P
c =P;
f = dudx;
y = @(u) (u.*(1-B/3*u+7*B^2/45*u.^2));
A = sqrt(2*B *integral(y,0,tmax))
s = -Z*u/A;
end
function u0 = heatic(x)
u0 = 0;
end
function [pl,ql,pr,qr] = heatbc(xl,ul,xr,ur,t)
pl = ul-1;
ql = 0;
pr = ur;
qr = 0;

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Answer 1

Torsten am 21 Dez. 2023

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Bearbeitet: Torsten am 21 Dez. 2023

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You have to solve a second ordinary differential equation for y:

dy/dt = 2*Ste * theta_f*(1-Ste/3 * theta_f + 7/45*Ste^2*theta_f^2)
y(t=0,x) = 0

Then y_LS = sqrt(y) in your equation for theta_f.

This can give problems because "pdepe" is designed to solve partial differential equations, not ordinary differential equations.

But since you prescribe theta_f at both ends of the spatial interval, you can compute y at these endpoints, too, and prescribe its value in "heatbc":

at x = 0: y = 2*Ste*integral(1-Ste/3+7/45*Ste^2) dt = 2*Ste*(1-Ste/3+7/45*Ste^2)*t

at x = L: y = 2*Ste*integral(0 dt) = 0

Is y_LS' differentiation with respect to t or with respect to x ? Same question for theta_f'.

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kjell revenberg am 3 Jan. 2024

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Hi Torsten,

Sorry for the late response, it was due to my holiday.

I cleaned up the code, so it is more readable. This seems to be working, however the results are not there yet as the integration tolerances are not met. This is due to the fact that at point t =0 theta_f and Y_ls are both zero creating singularity.

This can be solved by adding the value for theta_f for t=0:t*

Where t* is significantly smaller then tmax.

I am just not sure how I can add this. Would you use a forloop?

Thanks in advance!

clc;close all;clear all;
%% Temperature input
TB = 64;                                % Fin base temperature;
TM = 44;                                % Temperature PCM
%% Fin input
k_f = 237;                              % Thermal conductivity fin
Cp_f = 2300;                            % Heat capacity 
rho_f = 2710;                           % Density
%% PCM properties
rho_p = 780;                            % Density
Cp_p = 2300;                            % Heat capacity
k_p = 0.15;                             % Conductivity
H = 244000;                             % Latent Heat
a_p = k_p/(rho_p*Cp_p);                 % Thermal diffusivity
%% Meshing input
w = 0.005;                              % 1/2 the fin thickness
W = 0.05;                               % 1/2 the pcm height
tmax = 1000;                            % Maximum timestep
L = 0.2;                                % Maximum length
x = 0:L/10:L;
t = 0:tmax/10:tmax;
%% Dimensionless numbers
STE = Cp_p*(TB-TM)/H;                  % Stefan number
Cp_d = (rho_f*Cp_f)/(rho_p*Cp_p);      % Dimensionless heat capacity
k_d = k_f/k_p;                         % Dimensionless conductivity
w_d = w/W;                             % Aspect ratio
t_d = a_p.*t/W^2;                      % Dimensionless time
x_d = x/W;                             % Dimensionless distance
tdmin = tmax/10000;
 %% Storing values in one place
C.STE =STE;
C.k_d = k_d;
C.w = w;
C.W = W;
C.Cp_d = Cp_d;
%% Solving the function
m = 0;
heat = @(x,t,u,dudx) heatpde(x,t,u,dudx,C);
bc = @(xl,ul,xr,ur,t) heatbc(xl,ul,xr,ur,t,C);
sol = pdepe(m,heat,@heatic,bc,x,t);
function [c,f,s] = heatpde(x_d,t_d,u,dudx,C)
k_d = C.k_d;
STE = C.STE;
w = C.w;
W = C.W;
Cp_d = C.Cp_d;
theta_f = u(1);
y_LS = sqrt(u(2));
dtheta_fdx = dudx(1);
d_y_LS_dx = 1/(2*u(2))*dudx(2);
c = [Cp_d/k_d;1];
f =[dudx(1);0];
s = [-1/(k_d*w/W)*(theta_f/y_LS+STE*theta_f*(theta_f+2*dtheta_fdx/d_y_LS_dx*y_LS)/(6*y_LS)-...
       STE^2*theta_f^2*(40*(dtheta_fdx/d_y_LS_dx)^2*theta_f^2+85*theta_f*dtheta_fdx/d_y_LS_dx*y_LS+19*theta_f^2)/(360*y_LS));...
       2*STE * theta_f*(1-STE/3 * theta_f + 7/45*STE^2*theta_f^2)];
end
function u0 = heatic(x_d)
 u0 = [0;0];
end
function [pl,ql,pr,qr] = heatbc(xl,ul,xr,ur,t_d,C)
 STE = C.STE;
 pl = [ul(1)-1;ul(2)-2*STE*(1-STE/3+7/45*STE^2)*t_d];
 ql = [0;0];
 pr = [0;0];
 qr = [1;1];
end

kjell revenberg am 5 Jan. 2024

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Hi Torsten,

I calculated the function seperately as it added a lot of time to the simulation.

I used a t* of 10^-4

For theta_f it goes from 1 to 0.025 and at the third point it already zero.

Y_ls should be zero as it is neglected at this stage.

However I still get an error due to not meeting the integration tolerances. These values are similar to the paper so it should be possible, however I can't get it to work. I now changed u0(1) to a small avlue to see if i could find a point where it works, but it doesn''t

clc;close all;clear all;
%% Temperature input
TB = 64;                                % Fin base temperature;
TM = 44;                                % Temperature PCM
%% Fin input
k_f = 237;                              % Thermal conductivity fin
Cp_f = 2300;                            % Heat capacity 
rho_f = 2710;                           % Density
%% PCM properties
rho_p = 780;                            % Density
Cp_p = 2300;                            % Heat capacity
k_p = 0.15;                             % Conductivity
H = 244000;                             % Latent Heat
a_p = k_p/(rho_p*Cp_p);                 % Thermal diffusivity
%% Meshing input
w = 0.005;                              % 1/2 the fin thickness
W = 0.05;                               % 1/2 the pcm height
tmax = 5;                            % Maximum timestep
tmin = 0.1;
L = 0.2;                                % Maximum length
x = 0:L/10:L;
t = tmin:tmin/10^5:tmax;
ts = 0:tmin/10:tmin;
%% Dimensionless numbers
STE = Cp_p*(TB-TM)/H;                  % Stefan number
Cp_d = (rho_f*Cp_f)/(rho_p*Cp_p);      % Dimensionless heat capacity
k_d = k_f/k_p;                         % Dimensionless conductivity
w_d = w/W;                             % Aspect ratio
t_d = a_p.*t/W^2;                      % Dimensionless time
x_d = x/W;                             % Dimensionless distance
x_d = transpose(x_d);
ts_d =a_p.*ts/W^2;
ts_d2 =a_p.*tmin/W^2;
 %% Storing values in one place
C.STE =STE;
C.k_d = k_d;
C.w = w;
C.W = W;
C.Cp_d = Cp_d;
%% Solving the function
m = 0;
heat = @(x,t,u,dudx) heatpde(x_d,t_d,u,dudx,C);
bc = @(xl,ul,xr,ur,t_d) heatbc(xl,ul,xr,ur,t_d,C);
sol = pdepe(m,heat,@heatic,bc,x_d,t_d);
function [c,f,s] = heatpde(x_d,t_d,u,dudx,C)
k_d = C.k_d;
STE = C.STE;
w = C.w;
W = C.W;
Cp_d = C.Cp_d;
theta_f = u(1);
y_LS = sqrt(u(2));
dtheta_fdx = dudx(1);
d_y_LS_dx = 1/(2*u(2))*dudx(2);
c = [Cp_d/k_d;1];
f =[dudx(1);0];
s = [-1/(k_d*w/W)*(theta_f/y_LS+STE*theta_f*(theta_f+2*dtheta_fdx/d_y_LS_dx*y_LS)/(6*y_LS)-...
       STE^2*theta_f^2*(40*(dtheta_fdx/d_y_LS_dx)^2*y_LS^2+85*theta_f*dtheta_fdx/d_y_LS_dx*y_LS+19*theta_f^2)/(360*y_LS));...
       2*STE * theta_f*(1-STE/3 * theta_f + 7/45*STE^2*theta_f^2)];
end
function u0 = heatic(x_d)
u0 = [0.1;0];
end
function [pl,ql,pr,qr] = heatbc(xl,ul,xr,ur,t_d,C)
 STE = C.STE;
 pl = [ul(1)-1;ul(2)-2*STE*(1-STE/3+7/45*STE^2)*t_d];
 ql = [0;0];
 pr = [0;0];
 qr = [1;1];
end

kjell revenberg am 8 Jan. 2024

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Hi Torsten, I am still struggling. I found some mistakes and think that the boundary conditions for y are not correct, but should be the same as theta_f. However it is still not working. I would really appreciate it if you could look at it again:

%% Temperature input
TB = 64;                                % Fin base temperature;
TM = 44;                                % Temperature PCM
%% Fin input
k_f = 237;                              % Thermal conductivity fin
Cp_f = 2300;                            % Heat capacity 
rho_f = 2710;                           % Density
%% PCM properties
rho_p = 780;                            % Density
Cp_p = 2300;                            % Heat capacity
k_p = 0.15;                             % Conductivity
H = 244000;                             % Latent Heat
a_p = k_p/(rho_p*Cp_p);                 % Thermal diffusivity
%% Meshing input
w = 0.005;                              % 1/2 the fin thickness
W = 0.05;                               % 1/2 the pcm height
tmax = 1000;                            % Maximum timestep
tmin = 0.1;
L = 0.2;                                % Maximum length
x = 0:L/400:L;
t = tmin:tmin:tmax;
ts = 0:tmin/10:tmin;
%% Dimensionless numbers
STE = Cp_p*(TB-TM)/H;                  % Stefan number
Cp_d = (rho_f*Cp_f)/(rho_p*Cp_p);      % Dimensionless heat capacity
k_d = k_f/k_p;                         % Dimensionless conductivity
w_d = w/W;                             % Aspect ratio
t_d = a_p.*t/W^2;                      % Dimensionless time
x_d = x/W;                             % Dimensionless distance
x_d = transpose(x_d);
ts_d =a_p.*ts/W^2;
ts_d2 =a_p.*tmin/W^2;
 %% Storing values in one place
C.STE =STE;
C.k_d = k_d;
C.w = w;
C.W = W;
C.Cp_d = Cp_d;
%% Solving the function
m = 0;
heat = @(x_d,t_d,u,dudx) heatpde(x_d,t_d,u,dudx,C);
bc = @(xl,ul,xr,ur,t_d) heatbc(xl,ul,xr,ur,t_d,C);
options = odeset('RelTol', 1, 'AbsTol', 1);
sol = pdepe(m,heat,@heatic,bc,x_d,t_d,options);
function [c,f,s] = heatpde(x_d,t_d,u,dudx,C)
k_d = C.k_d;
STE = C.STE;
w = C.w;
W = C.W;
Cp_d = C.Cp_d;
theta_f = u(1);
y_LS = sqrt(u(2));
dtheta_fdx = dudx(1);
d_y_LS_dx = 1/(2*u(2))*dudx(2);
c = [Cp_d/k_d;1];
f =[dudx(1);0];
s = [-1/(k_d*w/W)*(theta_f/y_LS+STE*theta_f*(theta_f+2*dtheta_fdx/d_y_LS_dx*y_LS)/(6*y_LS)- ...
    STE^2*theta_f*(40*(dtheta_fdx/d_y_LS_dx)^2*y_LS^2+85*theta_f*dtheta_fdx/d_y_LS_dx*y_LS+19*theta_f^2)/(360*y_LS));...
       2*STE * theta_f*(1-STE/3 * theta_f + 7/45*STE^2*theta_f^2)];
end
function u0 = heatic(x_d)
u0 = [0.01;0.00001];
end
function [pl,ql,pr,qr] = heatbc(xl,ul,xr,ur,t_d,C)
 STE = C.STE;
 pl = [ul(1)-1;ul(2)-1];
 ql = [0;0];
 pr = [0;0];
 qr = [1;1];
end

kjell revenberg am 9 Jan. 2024

HI Torsten,

I think I found a solution to part of the problem.

dtheta_fdx and dy_ls_dx are both 0 at some points. Thus creating singularity to the equation.

I solved this by adding a small epsilon to the problem, some of the results seem accurate while the PCM temperature is not right.

I wondered how you came to the formula for

dy_ls_dx as I think there lies the error.

Thanks in advance

Torsten am 9 Jan. 2024

In MATLAB Online öffnen

I wondered how you came to the formula for

dy_ls_dx as I think there lies the error.

Thanks in advance

Yes, it's sqrt(u(2)) instead of u(2) in the denominator:

y_ls = sqrt(u(2)) -> d(y_ls)/dx = 1/(2*sqrt(u(2))) * dudx(2)

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Solving an integral within a partial derivative

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Solving an integral within a partial derivative

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