ρ * c_p * (∂T/∂t) = k * (∂^2T/∂x^2) + Q
Using the general heat conduction equation and the boundary conditions, the temperature distribution can be obtained as:
T(x) = (Q/k) * (x^2/2) - (Q/k) * L * x + T_s
ρ * c_p * (∂T/∂t) = k * (∂^2T/∂x^2) + Q
Using the general heat conduction equation and the boundary conditions, the temperature distribution can be obtained as:
T(x) = (Q/k) * (x^2/2) - (Q/k) * L * x + T_s
ρ * c_p * (∂T/∂t) = k * (∂^2T/∂x^2) + Q
Using the general heat conduction equation and the boundary conditions, the temperature distribution can be obtained as:
T(x) = (Q/k) * (x^2/2) - (Q/k) * L * x + T_s