It is likely not possible to derive a closed-form (analytic or symbolic) solution for those. Create an anonymous function to use with one of the numerical oODE solvers instead, and integrate with one of them.
syms M_w c_pco c_pev c_phx c_pr c_ps c_pw D D_s k_a L_w m_c_co m_c_hx m_ch M_co M_ev m_h M_hx M_s p_r q_max Q_s r_s T_c_co_in T_c_hx_in T_ch_in T_h_in h_r
syms t q_de(t) T_de(t) q_ad(t) T_ad(t) M_w_co(t) T_co(t) T_ev(t) M_w_ev(t) T_ch_out(t) T_h_out(t) T_c_hx_out(t) T_c_co_out(t) q_0_ad(t) q_0_de(t) Y
sympref('AbbreviateOutput',false);
M_s = 0.69
M_w = 0.789
c_ps = 0.84
c_pr = 2.5*10^(-3)
c_pw = 0.42
M_hx = 4.6282
c_phx = 0.5
m_h = 0.333
T_h_in = 353
m_c_hx = 0.267
T_c_hx_in = 303
M_co = 6.0547
c_pco = 0.50
L_w = 2.42
m_c_co = 0.267
T_c_co_in = 303
M_ev = 6.0547
c_pev = 0.50
m_ch = 0.1
T_ch_in = 300
D_s = 0.63*10^(-10)
k_a = 1.0
q_max = 1.24
D = 2.844*10^(-6)
p_r = 0.56
r_s = 2*10^(-3)
Q_s = 1.2715
h_r = 38.6/46.07*1000
eqn1(t) = (M_s*c_ps+M_s*c_pr*q_de+M_hx*c_phx)*diff(T_de, t) == m_h*c_pw*(T_h_in-T_h_out)+Q_s*diff(q_de, t)
eqn2(t) = (M_s*c_ps+M_s*c_pr*q_ad+M_hx*c_phx)*diff(T_ad, t) == m_h*c_pw*(T_c_hx_in-T_c_hx_out)+Q_s*diff(q_ad, t)
eqn3(t) = (M_w_co*c_pw+M_co*c_pco)*diff(T_co, t) == -h_r*diff(q_de, t)+c_pr*(T_de-T_co)*diff(q_de, t)+m_c_co*c_pw*(T_c_co_in-T_c_co_out)
eqn4(t) = (M_w_ev*c_pw+M_ev*c_pev)*diff(T_ev, t) == -h_r*diff(q_ad, t)+m_ch*c_pw*(T_ch_in-T_ch_out)
eqn5_de(t) = T_h_out == T_de+(T_h_in-T_de)*exp(-0.88)
eqn5_ad(t) = T_c_hx_out == T_ad+(T_c_hx_in-T_ad)*exp(-0.88)
eqn5_co(t) = T_c_co_out == T_co+(T_c_co_in-T_co)*exp(-0.88)
eqn5_ev(t) = T_ch_out == T_ev+(T_ch_in-T_ev)*exp(-0.88)
eqn6_1(t) = diff(M_w_co, t)+diff(q_de, t) == 0
eqn6_2(t) = diff(M_w_ev, t)+diff(q_ad, t) == 0
eqn7_ad(t) = q_0_ad == q_max*exp(-D*(T_ad*log(p_r))^2)
eqn8_ad(t) = diff(q_ad, t) == 15*D_s\r_s^2*(q_0_ad-q_ad)
eqn7_de(t) = q_0_de == q_max*exp(-D*(T_de*log(p_r))^2)
eqn8_de(t) = diff(q_de, t) == 15*D_s\r_s^2*(q_0_de-q_de)
eqn1 = subs(eqn1, lhs(eqn5_de), rhs(eqn5_de))
eqn2 = subs(eqn2, lhs(eqn5_ad), rhs(eqn5_ad))
eqn3 = subs(eqn3, lhs(eqn5_co), rhs(eqn5_co))
eqn4 = subs(eqn4, lhs(eqn5_ev), rhs(eqn5_ev))
eqn8_ad = subs(eqn8_ad, lhs(eqn7_ad), rhs(eqn7_ad))
eqn8_de = subs(eqn8_de, lhs(eqn7_de), rhs(eqn7_de))
eqns = [eqn1(t); eqn2(t); eqn3(t); eqn4(t); eqn6_1(t); eqn6_2(t); eqn8_ad(t); eqn8_de(t)]
% cond_T_ad = T_ad(0) == T_c_hx_in
% cond_T_de = T_de(0) == T_h_in
% cond_T_co = T_co(0) == T_c_co_in
% cond_T_ev = T_ev(0) == T_ch_in
% cond_T_c_co_out = T_c_co_out(0) == T_c_co_in
% cond_T_c_hx_out = T_c_hx_out(0) == T_c_hx_in
% cond_T_ch_out = T_ch_out(0) == T_ch_in
% cond_T_h_out = T_h_out(0) == T_h_in
% cond_q_ad = q_ad(0) == 0
% cond_q_de = q_de(0) == 0
% cond_M_w_co = M_w_co(0) == 0
% cond_M_w_ev = M_w_ev(0) == M_w
% conds = [cond_T_ad; cond_T_de; cond_T_co; cond_T_ev; cond_q_ad; cond_q_de; cond_M_w_co; cond_M_w_ev]
% S = dsolve(eqns, conds)
[VF,Sbs] = odeToVectorField(eqns)
eqnsfcn = matlabFunction(VF, 'Vars',{'t','Y','q_de','T_de','T_ad','q_ad','T_co','T_ev','M_w_co','M_w_ev'})
Then use ode45 (or other suitable solver, perhaps ode15s if the system turns out to be stiff. (If ode45 takes longer than a minute or two to integrate these, ithe system is likely stiff. Just change the solver to ode15s or one of the other stiff solvers, and it should integrate quickly.)
The ode45 call should be something like this —
initcons = [ ... ]; % Initial Conditions Vector
start_time = 0;
end_time = ...;
tspan = [start_time end_time];
[t,y] = ode45(@(t,y)eqnsfcn(t,Y,q_de,T_de,T_ad,q_ad,T_co,T_ev,M_w_co,M_w_ev), tspan, initconds);
figure
plot(t, y)
grid
.
