Answer:
The temperature of the strip as it exits the furnace is 819.15 °C
Explanation:
The characteristic length of the strip is given by;
[tex]L_c = \frac{V}{A} = \frac{LA}{2A} = \frac{5*10^{-3}}{2} = 0.0025 \ m[/tex]
The Biot number is given as;
[tex]B_i = \frac{h L_c}{k}\\\\B_i = \frac{80*0.0025}{21} \\\\B_i = 0.00952[/tex]
[tex]B_i[/tex] < 0.1, thus apply lumped system approximation to determine the constant time for the process;
[tex]\tau = \frac{\rho C_p V}{hA_s} = \frac{\rho C_p L_c}{h}\\\\\tau = \frac{8000* 570* 0.0025}{80}\\\\\tau = 142.5 s[/tex]
The time for the heating process is given as;
[tex]t = \frac{d}{V} \\\\t = \frac{3 \ m}{0.01 \ m/s} = 300 s[/tex]
Apply the lumped system approximation relation to determine the temperature of the strip as it exits the furnace;
[tex]T(t) = T_{ \infty} + (T_i -T_{\infty})e^{-t/ \tau}\\\\T(t) = 930 + (20 -930)e^{-300/ 142.5}\\\\T(t) = 930 + (-110.85)\\\\T_{(t)} = 819.15 \ ^0 C[/tex]
Therefore, the temperature of the strip as it exits the furnace is 819.15 °C
