$Re_{D}=\frac{\rho V D}{\mu}=\frac{999.1 \times 3.5 \times 2}{1.138 \times 10^{-3}}=6.14 \times 10^{6}$
$T_{c}=T_{s}+\frac{P}{4\pi kL}$
Heat conduction in a solid, liquid, or gas occurs due to the vibration of molecules and the transfer of energy from one molecule to another. In solids, heat conduction occurs due to the vibration of molecules and the movement of free electrons. In liquids and gases, heat conduction occurs due to the vibration of molecules and the movement of molecules themselves.
(c) Conduction:
The Nusselt number can be calculated by:
$\dot{Q} {conv}=h A(T {skin}-T_{\infty})$
$\dot{Q}_{rad}=1 \times 5.67 \times 10^{-8} \times 1.5 \times (305^{4}-293^{4})=41.9W$ $Re_{D}=\frac{\rho V D}{\mu}=\frac{999
Assuming $h=10W/m^{2}K$,
The heat transfer from the wire can also be calculated by:
$Nu_{D}=hD/k$
$\dot{Q}_{cond}=0.0006 \times 1005 \times (20-32)=-1.806W$
$\dot{Q}_{conv}=150-41.9-0=108.1W$
$Nu_{D}=0.26 \times (6.14 \times 10^{6})^{0.6} \times (7.56)^{0.35}=2152.5$ (c) Conduction: The Nusselt number can be calculated