Respuesta :
Explanation:
Expression to calculate thermal resistance for iron ([tex]R_{I}[/tex]) is as follows.
[tex]R_{I} = \frac{L_{I}}{k_{I} \times A_{I}}[/tex]
where, [tex]L_{I}[/tex] = length of the iron bar
[tex]k_{I}[/tex] = thermal conductivity of iron
[tex]A_{I}[/tex] = Area of cross-section for the iron bar
Thermal resistance for copper ([tex]R_{c}[/tex]) = \frac{L_{c}}{k_{c} \times A_{c}}[/tex]
where, [tex]L_{c}[/tex] = length of copper bar
[tex]k_{c}[/tex] = thermal conductivity of copper
[tex]A_{c}[/tex] = Area of cross-section for the copper bar
Now, expression for the transfer of heat per unit cell is as follows.
Q = [tex]\frac{(100^{o} - 0^{o}}{\frac{L_{I}}{k_{I}.A_{I}} + \frac{L_{c}}{k_{c}.A_{c}}}[/tex]
Putting the given values into the above formula as follows.
Q = [tex]\frac{(100^{o} - 0^{o})}{\frac{L_{I}}{k_{I}.A_{I}} + \frac{L_{c}}{k_{c}.A_{c}}}[/tex]
= [tex]\frac{(100^{o} - 0^{o})}{21 \times 10^{-2} m[\frac{1}{73 \times 10^{-4}m^{2}} + \frac{1}{386 \times 10^{-4}m^{2}}}[/tex]
= 2.92 Joule
It is known that heat transfer per unit time is equal to the power conducted through the rod. Hence,
P = [tex]\frac{Q}{T}[/tex]
Here, T is 1 second so, power conducted is equal to heat transferred.
So, P = 2.92 watt
Thus, we can conclude that 2.92 watt power will be conducted through the rod when it reaches steady state.
