X
T(x,t) = 100 + (20 - 100) * erf(x / (2 * √(0.01 * 10))) + (1000 * 0.02^2 / 10) * (1 - (x/0.02)^2)
The resulting temperature distribution is:
where α is the thermal diffusivity, which is given by: incropera principles of heat and mass transfer solution pdf
Substituting the given values, the temperature distribution in the wall at t = 10 s can be determined as:
This solution can be used to determine the temperature distribution in the wall at any time and position. T(x,t) = 100 + (20 - 100) * erf(x / (2 * √(0
ρc_p * ∂T/∂t = k * ∂^2T/∂x^2 + q
Using the finite difference method, the temperature distribution in the wall can be determined as: incropera principles of heat and mass transfer solution pdf
T(x,t) = T∞ + (T_i - T∞) * erf(x / (2 * √(α * t))) + (q * L^2 / k) * (1 - (x/L)^2)
