dTdz=30.12; Ri=0.05; Ro=0.075; Rm=0.0621; hcoeff=100; To=300; Ti=0; Zo=0; Zi=1.3*Ri*hcoeff*(Ti-To); uRi=0; uRo=0; tawi=4.3465; tawo=3.792; npoints=1000;
h=(Ro-Ri)/npoints;
r=(Ri+h:h:Ro)';
uR= zeros(npoints,1);
T= zeros(npoints,1);
Z = zeros(npoints,1);
for i=1:1:(npoints-1)
T(1)=Ti;
Z(1)=Zi;
uR(1)= uRi;
if r(i)<Rm
k1=h*dUdrI(r(i),tawi,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ri);
w1=h*dTdr(r(i),Z(i),Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f1=h*dZdr(r(i),rho(T),Cp(T),uR,dTdz);
k2=h*dUdrI((r(i)+h/2),tawi,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ri);
w2=h*dTdr((r(i)+h/2),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f2=h*dZdr((r(i)+h/2),rho(T),Cp(T),uR,dTdz);
k3=h*dUdrI((r(i)+h/2),tawi,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ri);
w3=h*dTdr((r(i)+h/2),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f3=h*dZdr((r(i)+h/2),rho(T),Cp(T),uR,dTdz);
k4=h*dUdrI((r(i)+h),tawi,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ri);
w4=h*dTdr((r(i)+h),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f4=h*dZdr((r(i)+h),rho(T),Cp(T),uR,dTdz);
uR(i+1) = uR(i) + (k1+2*k2+2*k3+k4)/6;
T(i+1) = T(i) + (w1+2*w2+2*w3+w4)/6;
Z(i+1) = Z(i) + (f1+2*f2+2*f3+f4)/6;
end
end
for i=(npoints-1):1:1
T(1)=To;
Z(1)=Zo;
uR(1)=uRo;
if r(i)>=Rm
k1=h*dUdrO(r(i),tawo,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ro);
w1=h*dTdr(r(i),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f1=h*dZdr(r(i),rho(T),Cp(T),uR,dTdz);
k2=h*dUdrO((r(i)-h/2),tawo,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ro);
w2=h*dTdr((r(i)-h/2),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f2=h*dZdr((r(i)-h/2),rho(T),Cp(T),uR,dTdz);
k3=h*dUdrO((r(i)-h/2),tawo,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ro);
w3=h*dTdr((r(i)-h/2),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f3=h*dZdr((r(i)-h/2),rho(T),Cp(T),uR,dTdz);
k4=h*dUdrO((r(i)-h),tawo,mu(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo),Rm,Ro);
w4=h*dTdr((r(i)-h),Z,Cp(T),k(T),rho(T),epsilon_m_(r,T,Rm,Ri,Ro,tawi,tawo));
f4=h*dZdr((r(i)-h),rho(T),Cp(T),uR,dTdz);
uR(i+1)=uR(i)+(k1+2*k2+2*k3+k4)/6;
T(i+1)=T(i)+(w1+2*w2+2*w3+w4)/6;
Z(i+1)=Z(i)+(f1+2*f2+2*f3+f4)/6;
end
end
figure, plot (r,uR)
xlabel('Radius')
ylabel('Velocity')
title('Velocity vs Radius')
figure, plot (r,T)
xlabel('Radius')
ylabel('Temperature')
title('Temperature vs Radius')
figure, plot (r,Z)
xlabel('Radius')
ylabel('Heat transfer per unit length')
title('Heat transfer per unit length vs Radius')
function [dZdr_] = dZdr (r,rho,Cp,uR,dTdz)
dZdr_ = -r*rho(T)*Cp(T)*uR*dTdz;
end
function [dTdr_] = dTdr (Z,r,k,rho,Cp,epsilon_m_)
dTdr_ = Z/(r*(k(T)+rho(T)*Cp(T)*epsilon_m_));
end
function [dUdrI_] = dUdrI (tawi,mu,rho,epsilon_m_,Rm,r,Ri)
dUdrI_= tawi./(mu+rho*epsilon_m_)*((Rm^2-r^2)/(Rm^2-Ri^2))*(Ri/r);
end
function [dUdrO_] = dUdrO (tawo,mu,rho,epsilon_m_,r,Rm,Ro)
dUdrO_= tawo./(mu+rho*epsilon_m_)*((r^2-Rm^2)/(Ro^2-Rm^2))*(Ro/r);
end
function [epsilon_m] = epsilon_m_ (r,T,Rm,Ri,Ro,tawi,tawo)
if r<Rm
radratio=(r-Ri)/(Rm-Ri);
rEpsI=6.516e-4+3.9225e-1*radratio+(-6.0949e-1)*(radratio).^2+(2.3391e-1)*(radratio).^3+(1.410e-1)*(radratio).^4+(-9.6098e-2)*(radratio).^5;
epsilon_m=rEpsI*sqrt(tawi./rho(T))*(Rm-Ri);
else
radratio=(Ro-r)/(Ro-Rm);
rEpsO=6.516e-4+3.9225e-1*radratio+(-6.0949e-1)*(radratio).^2+(2.3391e-1)*(radratio).^3+(1.410e-1)*(radratio).^4+(-9.6098e-2)*(radratio).^5;
epsilon_m=rEpsO*sqrt(tawo./rho(T))*(Ro-Rm);
end
end
function [Cp_]=Cp(T)
Cp_=1010.4755 + 0.1151*(T) + 4.00e-5*(T).^2;
end
function [k_]=k(T)
k_=0.0243+(6.548e-5)*(T) - (1.65e-8)*(T).^2;
end
function [mu_]=mu(T)
mu_=1.747e-5 + 4.404e-8*(T) - 1.645e-11*((T).^2);
end
function [Pr_]=Pr(T)
Pr_=0.7057*10^(2.06e-5*(T));
end
function [rho_]=rho (T)
rho_ =1e5/(287*(T));
end
function [vis_]=vis(T)
vis_=1.380e-5 + (8.955e-8)*(T) - (1.018e-10)*(T)^2;
end
