Your calculations of rad_w and rad_g produce vectors of size 8x1 that lead to tdot being larger than 3x1. Should these two (i.e. rad_w and rad_g) be the sum of the values in the vectors?
Error using odearguments (line 95) SOL returns a vector of length 18, but the length of initial conditions vector is 3. The vector returned by SOL and the initial conditions vector must have the same number of elements.
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I am trying to solve 3 ODEs by using ode45. i dont know if im doing this right or not, I appreciate any small help.
this is my code.
my main problem is how to include the transient effect of solar radiation. I tried to solve it with constant solar radiation and it worked fine.
t1=8; %start time
t2=15; %end time
tspan=[0,(t2-t1)*3600];
IC=[38,40,37]; %initial temperatures
[time,temp]=ode45(@sol,tspan,IC);
function tdot =sol(t,T)
t1=8;
t2=15;
vol=4;
mair=vol*1.225;
cp=1005;
Qh=0;%220;
Tac=15;
mac=0.09;
Uinwall=4;
Uoutwall=4.5;
Uinmass=12;
Amass=3;
Tamb=45;
cpwall=600;
cpmass=1450;
mwall=900;
mmass=50;
emiss=0.9;
Tsky=22.6;
abswall=0.19;
absmass=1;
trans=0.8;
A=[2.479,0 %roof
0.864,0.864 %windsheild
0.787,0.787 %rear window
1.533+0.224+0.266,0.224+0.266 %right side
1.533+0.224+0.266,0.224+0.266]; %left side
Aw=A(:,1); %area of walls
Ag=A(:,2); % area of glass
Awall=sum(Aw,'all');
AHwall=Aw(1,:);
lat=33.3152; %latitude
long=44.3661; % longitude
gmt=3;
mint=0;
tiltang_w=[0 % tilt angle of the walls
60
45
90
90];
zs_w=[0 % zenith angle of the walls
0
180
90
270];
tiltang_g=[60 % tilt angle of the glass
45
90
90];
zs_g=[0 % zenith angle of the glass
180
90
270];
costhetaz=[]; % cosine of the zenith angle
costheta_w=[]; %incident angle of solar radiation on the walls
costheta_g=[]; %incident angle of solar radiation on the glass
for hour=t1:1:t2
lot=hour+mint/60;%local time of the city
dn=190; % day of the year
a=1160+75*sind((dn-275)*360/365); %constants of the equation
b=0.174+0.035*sind((dn-100)*360/365); %constants of the equation
c=0.095+0.04*sind((dn-100*360/365)); %constants of the equation
delta=23.45*sind((dn+284)*360/365); % Declination angle
bn=(dn-1)*360/365;
eot=2.2918*(0.0075+0.1686*cosd(bn)-...
3.2077*sind(bn)-1.4615*cosd(2*bn)-...
4.089*sind(2*bn)); % equation of time
lst=15*gmt; % local standard time
st=(lot+(eot/60)+(long-lst)/15); % solar time
omega=15*(12-st); % hour angle
costhetaz_i=cosd(delta).*cosd(lat).*cosd(omega)+...
sind(delta).*sind(lat); % cosine of the zenith angle
costheta_wi=sind(delta).*sind(lat).*cosd(tiltang_w)-...
sind(delta).*cosd(lat).*sind(tiltang_w).*cosd(zs_w)+...
cosd(delta).*cosd(lat).*cosd(tiltang_w).*cosd(omega)+...
cosd(delta).*sind(lat).*sind(tiltang_w).*cosd(zs_w).*cosd(omega)+...
cosd(delta).*sind(tiltang_w).*sind(zs_w).*sind(omega); %incident angle of solar radiation on the walls
costheta_gi=sind(delta).*sind(lat).*cosd(tiltang_g)-...
sind(delta).*cosd(lat).*sind(tiltang_g).*cosd(zs_g)+...
cosd(delta).*cosd(lat).*cosd(tiltang_g).*cosd(omega)+...
cosd(delta).*sind(lat).*sind(tiltang_g).*cosd(zs_g).*cosd(omega)+...
cosd(delta).*sind(tiltang_g).*sind(zs_g).*sind(omega);%incident angle of solar radiation on the glass
costhetaz=[costhetaz;costhetaz_i];
costheta_w=[costheta_w;costheta_wi];
costheta_g=[costheta_g;costheta_gi];
end
hour=t1:1:t2;
costhetaz;
costheta_w;
costheta_g;
minLength = min(length(costhetaz), length(costheta_w)); % i wrote this line becasue i didnt get the same number of values for costheatz,costheta_w and costheta_g
costhetaz = costhetaz(1:minLength);
costheta_w = costheta_w(1:minLength);
costheta_g = costheta_g(1:minLength);
[idir]=a.*exp(-b./costhetaz); % direct solar radiation
costheta_w(costheta_w<0)=0; % this line to neglect the negative values of costheta_w and costheta_g
costheta_g(costheta_g<0)=0;
rad_w=idir.*costheta_w; % solar radiation on the walls
rad_g=idir.*costheta_g; % solar radiation on the glass
totalrad_w=0;
totalrad_g=0;
for i=1:1:5
totalrad_w=totalrad_w+rad_w.*Aw(i,1);
end
for i=1:1:5
totalrad_g=totalrad_g+rad_g.*Ag(i,1);
end
Q_ac=0;%(mac*cp*(Tac-T(1)));
Qin_w=(Uinwall*Awall*(T(1)-T(2)));
Qin_m=(Uinmass*Amass*(T(1)-T(3)));
Qout_w=(Uoutwall*Awall*(Tamb-T(2)));
Qin_rad=(5.67*10^-8*Amass*((T(3)+273)^4-(T(2)+273)^4));
Qout_rad=-(5.67*10^-8*emiss*AHwall*((T(2)+273)^4-(Tsky+273)^4));
Qabssolar=abswall*totalrad_w;
Qtranssolar=trans*absmass*totalrad_g;
tdot=[(Qh+Q_ac-Qin_w-Qin_m)/(mair*cp)
(Qin_w+Qout_w+Qin_rad+Qabssolar-Qout_rad)/(mwall*cpwall)
(Qin_m+Qtranssolar-Qin_rad)/(mmass*cpmass)];
end
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Réponses (1)
Alan Stevens
le 20 Déc 2020
9 commentaires
Alan Stevens
le 20 Déc 2020
As I noted before, where you currently have
for hour=t1:1:t2
replace this with
if t>=t1 & t<=t2
then work out lot etc for this specific time using the value of t.
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