PDEPE solver failure (spatial discretization) ; partial differential/derivative temperature modelling

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Josh am 20 Apr. 2024

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https://de.mathworks.com/matlabcentral/answers/2109406-pdepe-solver-failure-spatial-discretization-partial-differential-derivative-temperature-modellin

Bearbeitet: Torsten am 20 Apr. 2024

Attempting to model temperature profile of an adsorption column based on concentration profile since this determines the heat of adsorption.

This is the function:

function[c,f,s] = pdefunEB(x,t,u,dudx)
global qmax_phenol K_L_phenol kf De u_s Rep Dp epsilon rho_liq cp_AC cp_feed H_ads h alpha
C = u(1) ;
q = u(2) ;
Tf = u(3) ;
dCdx = dudx(1) ;
dqdx = dudx(2) ;
dTdx = dudx(3) ;
Ts = 298.15 ; % adsorbent temp Kelvin
qstar = ((qmax_phenol)*(K_L_phenol)*C)/(1+(K_L_phenol)*C) ;
dqdt = kf*(qstar-q) ;
c = ones(3,1) ;
f = [De*dCdx;
        0;
        0];
s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;
        dqdt;
        -u_s*dTdx+(((h*alpha*(Tf-Ts)-(H_ads/cp_AC))+(H_ads/cp_feed))*(dqdt*((1-epsilon)/epsilon)))] ;
end
%% initial condition
function u0 = icfunEB(x)
u0 = [0;
        0;
        298.15] ;
end 
%% boundary condition
function [p1,q1,pr,qr] = bcfunEB(x1,u1,xr,ur,t)
global C_phenol
C0 = C_phenol ;
p1 = [u1(1)-C0;0;-298.15] ;
q1 = [0;1;0] ;
pr = [0;0;0] ;
qr = [1;1;1] ;
end

this is where the error appears (Error using pdepe Spatial discretization has failed. Discretization supports only parabolic and elliptic equations, with flux term involving spatial derivative)

mEB = 0 ;
sol1 = pdepe(mEB,@pdefunEB,@icfunEB,@bcfunEB,x,t) ; 
CEB = sol1(:,:,1) ; 
qEB = sol1(:,:,2) ;
TEB = sol1(:,:,3) ;
figure(2)
T0 = 298.15 ;
Cp1 = C1(:,end)./C01 ;
plot(t,TEB,'b-','LineWidth',2)
grid on
title('Column Temperature')
xlabel('time in minutes')
ylabel('temp in kelvin')

Heres a picture of my mathematical working before input into matlab:

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Answer 1

Torsten am 20 Apr. 2024

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https://de.mathworks.com/matlabcentral/answers/2109406-pdepe-solver-failure-spatial-discretization-partial-differential-derivative-temperature-modellin#answer_1444916

Bearbeitet: Torsten am 20 Apr. 2024

In MATLAB Online öffnen

Please include the constants defined as globals so that we can test your code.

One obvious error is the boundary condition for T in the left boundary point. Use

p1 = [u1(1)-C0;0;u1(3)-298.15] ;

instead of

p1 = [u1(1)-C0;0;-298.15] ;

Another problem can be that f = 0 for equations (2) and (3). "pdepe" - as the name indicates - is designed for parabolic-elliptic partial differential equations (thus for equations with second-order spatial derivatives present). Your second equation is a simple ODE, your third equation is hyperbolic in nature.

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Josh am 20 Apr. 2024

Bearbeitet: Torsten am 20 Apr. 2024

In MATLAB Online öffnen

global qmax_5HMF qmax_furfural qmax_acetic qmax_phenol

global K_L_5HMF K_L_furfural K_L_acetic K_L_phenol

global C_5HMF C_furfural C_acetic C_phenol

global kf De u_s Rep Dp epsilon rho_liq cp_AC cp_feed H_ads h alpha

Dp = 2.5e-3 ; %% 4e-4 < Dp < 2.5e-3

epsilon = 0.427 ; %0.427

cp_AC = 0.751 ; %(Kutub Uddin source)

cp_feed = 4.177 ; %(see excel calcs)

H_ads = 33.15 ; %(Mingling Ren source)

F = 1.44120296 ; % inlet flow rate ; see excel

u_s = 0.06 ; %% 0.06 < u_s < 0.24

A = F/u_s ;

L = 100*u_s ;

V = L*A ;

Dc = 2*(sqrt(A/pi)) ;

rho_AC = 1480 ; %% [kg/m3]

m_AC = epsilon*V*rho_AC ; %% 1480 kg/m3 AC

h = 0.017 ; %(Wang 2003)

specificA = 1000e3 ; %% 913e3 - 1413e3

alpha = specificA*m_AC ;

L/u_s %% L/u > 100

ans = 100

A*u_s %% A*u > F

ans = 1.4412

%% mass fractions

x_water = 0.894250861 ;

x_glucose = 0.025266561 ;

x_xylose = 0.037260453 ;

x_5HMF = 0.000371 ;

x_furfural = 0.00302 ;

x_acetic = 0.00634 ;

x_phenolic = 0.0335 ;

%% viscosities

mu_water = 0.00089002 ;

mu_glucose = 0.00124 ;

mu_xylose = 0.0000010 ;

mu_5HMF = 0.00092 ;

mu_furfural = 0.001494 ;

mu_acetic = 0.001037 ;

mu_phenolic = 0.0017844 ;

%% particle reynolds

rho_liq = 1027.839426 ;

mu_liq = ((mu_water^x_water)+(mu_glucose^x_glucose)+(mu_xylose^x_xylose)+(mu_5HMF^x_5HMF)+(mu_furfural^x_furfural)+(mu_acetic^x_acetic)+(mu_phenolic^x_phenolic)) ;

Rep = (Dp*(u_s/60)*rho_liq)/(mu_liq)

Rep = 4.9528e-04

%% pressure drop

deltaP = ((150/Rep)*(1-epsilon)+1.75)*(((1-epsilon)/(epsilon^3))*(L/Dp)*rho_liq*(u_s^2)) ;

deltaP %% deltaP < 20

deltaP = 1.1343e+10

kf = (0.0011*Rep)+0.0009 ; % film MTC [1/min]

De = ((1e-11)*Rep)+(1e-10) ; % diffusive term (Pergamon Source) [m2/min]

%% langmuir coefficients [m3/kg]

K_L_5HMF = 0.047 ; %(rajoriya source)

K_L_furfural = 0.047 ; %(rajoriya source)

K_L_acetic = 0.071889 ; %(Mutasim source)

K_L_phenol = 0.0154 ; %(xie source)

%% adsoprtion capacities [kg/kg]

qmax_5HMF = 86.21 ; %(rajoriya source)

qmax_furfural = 86.21 ; %(rajoriya source)

qmax_acetic = 108.5 ; %(wu source)

qmax_phenol = 214.13 ; %(xie source)

%% concentrations [kg/m3]

C_5HMF = 0.38122 ;

C_furfural = 3.10996 ;

C_acetic = 6.52088 ;

C_phenol = 34.413 ;

%%

x = linspace(0,L,201) ;

t = 0:10000:1000000 ;

%% solve

m1 = 0 ;

sol1 = pdepe(m1,@pdefun1,@icfun1,@bcfun1,x,t) ;

C1 = sol1(:,:,1) ;

q1 = sol1(:,:,2) ;

m2 = 0 ;

sol2 = pdepe(m2,@pdefun2,@icfun2,@bcfun2,x,t) ;

C2 = sol2(:,:,1) ;

q2 = sol2(:,:,2) ;

m3 = 0 ;

sol3 = pdepe(m3,@pdefun3,@icfun3,@bcfun3,x,t) ;

C3 = sol3(:,:,1) ;

q3 = sol3(:,:,2) ;

m4 = 0 ;

sol4 = pdepe(m4,@pdefun4,@icfun4,@bcfun4,x,t) ;

C4 = sol4(:,:,1) ;

q4 = sol4(:,:,2) ;

%% plotting breakthrough curve

figure(1)

C01 = C_5HMF ;

Cp1 = C1(:,end)./C01 ;

plot(t,Cp1,'m-','LineWidth',1)

grid on

title('Breakthrough curve')

xlabel('time in minutes')

ylabel('C/C0')

hold on

C02 = C_furfural ;

Cp2 = C2(:,end)./C02 ;

plot(t,Cp2,'g--','LineWidth',1)

hold on

C03 = C_acetic ;

Cp3 = C3(:,end)./C03 ;

plot(t,Cp3,'b:','LineWidth',1)

hold on

C04 = C_phenol ;

Cp4 = C4(:,end)./C04 ;

plot(t,Cp4,'r-.','LineWidth',1)

%% ENERGY BAL

mEB = 0 ;

t=linspace(0,1.4,10);

sol1 = pdepe(mEB,@pdefunEB,@icfunEB,@bcfunEB,x,t) ;

CEB = sol1(:,:,1) ;

qEB = sol1(:,:,2) ;

TEB = sol1(:,:,3) ;

figure(2)

T0 = 298.15 ;

Cp1 = C1(:,end)./C01 ;

plot(t,TEB,'b-','LineWidth',2)

grid on

title('Column Temperature')

xlabel('time in minutes')

ylabel('temp in kelvin')

function[c,f,s] = pdefun1(x,t,u,dudx)

global qmax_5HMF K_L_5HMF kf De u_s Rep Dp epsilon rho_liq

C = u(1) ;

q = u(2) ;

dCdx = dudx(1) ;

dqdx = dudx(2) ;

qstar = ((qmax_5HMF)*(K_L_5HMF)*C)/(1+(K_L_5HMF)*C) ;

dqdt = kf*(qstar-q) ;

c=[1;1] ;

f = [De*dCdx;0] ;

s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;dqdt] ;

end

%% initial condition

function u0 = icfun1(x)

u0 = [0;0] ;

end

%% boundary condition

function [p1,q1,pr,qr] = bcfun1(x1,u1,xr,ur,t)

global C_5HMF

C0 = C_5HMF ;

p1 = [u1(1)-C0;0] ;

q1 = [0;1] ;

pr = [0;0] ;

qr = [1;1] ;

end

function[c,f,s] = pdefun2(x,t,u,dudx)

global qmax_furfural K_L_furfural kf De u_s Rep Dp epsilon rho_liq

C = u(1) ;

q = u(2) ;

dCdx = dudx(1) ;

dqdx = dudx(2) ;

qstar = ((qmax_furfural)*(K_L_furfural)*C)/(1+(K_L_furfural)*C) ;

dqdt = kf*(qstar-q) ;

c=[1;1] ;

f = [De*dCdx;0] ;

s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;dqdt] ;

end

%% initial condition

function u0 = icfun2(x)

u0 = [0;0] ;

end

%% boundary condition

function [p1,q1,pr,qr] = bcfun2(x1,u1,xr,ur,t)

global C_furfural

C0 = C_furfural ;

p1 = [u1(1)-C0;0] ;

q1 = [0;1] ;

pr = [0;0] ;

qr = [1;1] ;

end

function[c,f,s] = pdefun3(x,t,u,dudx)

global qmax_acetic K_L_acetic kf De u_s Rep Dp epsilon rho_liq

C = u(1) ;

q = u(2) ;

dCdx = dudx(1) ;

dqdx = dudx(2) ;

qstar = ((qmax_acetic)*(K_L_acetic)*C)/(1+(K_L_acetic)*C) ;

dqdt = kf*(qstar-q) ;

c=[1;1] ;

f = [De*dCdx;0] ;

s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;dqdt] ;

end

%% initial condition

function u0 = icfun3(x)

u0 = [0;0] ;

end

%% boundary condition

function [p1,q1,pr,qr] = bcfun3(x1,u1,xr,ur,t)

global C_acetic

C0 = C_acetic ;

p1 = [u1(1)-C0;0] ;

q1 = [0;1] ;

pr = [0;0] ;

qr = [1;1] ;

end

function[c,f,s] = pdefun4(x,t,u,dudx)

global qmax_phenol K_L_phenol kf De u_s Rep Dp epsilon rho_liq

C = u(1) ;

q = u(2) ;

dCdx = dudx(1) ;

dqdx = dudx(2) ;

qstar = ((qmax_phenol)*(K_L_phenol)*C)/(1+(K_L_phenol)*C) ;

dqdt = kf*(qstar-q) ;

c=[1;1] ;

f = [De*dCdx;0] ;

s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;dqdt] ;

end

%% initial condition

function u0 = icfun4(x)

u0 = [0;0] ;

end

%% boundary condition

function [p1,q1,pr,qr] = bcfun4(x1,u1,xr,ur,t)

global C_phenol

C0 = C_phenol ;

p1 = [u1(1)-C0;0] ;

q1 = [0;1] ;

pr = [0;0] ;

qr = [1;1] ;

end

function[c,f,s] = pdefunEB(x,t,u,dudx)

global qmax_phenol K_L_phenol kf De u_s Rep Dp epsilon rho_liq cp_AC cp_feed H_ads h alpha

C = u(1) ;

q = u(2) ;

Tf = u(3) ;

dCdx = dudx(1) ;

dqdx = dudx(2) ;

dTdx = dudx(3) ;

Ts = 298.15 ; % adsorbent temp Kelvin

qstar = ((qmax_phenol)*(K_L_phenol)*C)/(1+(K_L_phenol)*C) ;

dqdt = kf*(qstar-q) ;

c = ones(3,1) ;

f = [De*dCdx;

0;

0];

s = [-u_s*dCdx-(1-epsilon)/epsilon*rho_liq*dqdt;

dqdt;

-u_s*dTdx+(((h*alpha*(Tf-Ts)-(H_ads/cp_AC))+(H_ads/cp_feed))*(dqdt*((1-epsilon)/epsilon)))] ;

end

%% initial condition

function u0 = icfunEB(x)

u0 = [0;

0;

298.15] ;

end

%% boundary condition

function [p1,q1,pr,qr] = bcfunEB(x1,u1,xr,ur,t)

global C_phenol

C0 = C_phenol ;

p1 = [u1(1)-C0;0;u1(3)-298.15] ;

q1 = [0;1;0] ;

pr = [0;0;0] ;

qr = [1;1;1] ;

end

Josh am 20 Apr. 2024

Bearbeitet: Josh am 20 Apr. 2024

Yes, so the error message has changed since i implemented your boundary condition change... How would you go about fixing it ?

Torsten am 20 Apr. 2024

Bearbeitet: Torsten am 20 Apr. 2024

As you can see above, the temperature explodes at the right endpoint (see above). Check the possible reasons (especially your sourceterm -u_s*dTdx+(((h*alpha*(Tf-Ts)-(H_ads/cp_AC))+(H_ads/cp_feed))*(dqdt*((1-epsilon)/epsilon))) )

h*alpha = 1.5e9 !!!

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PDEPE solver failure (spatial discretization) ; partial differential/derivative temperature modelling

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PDEPE solver failure (spatial discretization) ; partial differential/derivative temperature modelling

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