Question 9.10: The pool boiling of Example 9.1 takes place with a tube-wall...

For pool film boiling on a horizontal tube, the Bromley equation is applicable. The following data are obtained from Example 9.1:

\rho_{L}=567  kg / m ^{3}\quad \quad\mu_{V}=7.11  \times  10^{-6}  kg / m \cdot s

\rho_{V}=18.09  kg / m ^{3}\quad \quad D_{o}=1 \text { in. }=0.0254  m

\lambda=272,000  J / kg \quad \quad T_{\text {Sat }}=437.5  K

The temperature difference is:

\Delta T_{e}=T_{w}-T_{s a t}=537.5-437.5=100 K

The heat-transfer coefficient for film boiling is obtained by substituting into Equation (9.101).

\frac{h_{fb} D_{o}}{k_{V}}=0.62\left[\frac{g \rho_{V}\left(\rho_{L}  –  \rho_{V}\right) D_{o}^{3}\left(\lambda  +  0.76 C_{P, V} \Delta T_{e}\right)}{k_{V} \mu_{V} \Delta T_{e}}\right]^{0.25}

\frac{h_{f b} D_{o}}{k_{V}}=341.57

h_{f b}=341.57  \times  k_{V} / D_{o}=341.57  \times  0.011 / 0.0254

h_{f b}=148  W / m ^{2} \cdot K

The radiative heat-transfer coefficient is estimated using Equation (9.103). Assuming an emissivity of 0.8 for the tube wall, we have

h_{ r }=\frac{\epsilon \sigma_{S B}\left(T_{w}^{4}  –  T_{s a t}^{4}\right)}{T_{w}  –  T_{s a t}}=\frac{0.8  \times  5.67  \times  10^{-8}\left[(537.5)^{4}-(437.5)^{4}\right]}{537.5  –  437.5}

h_{ r }=21  W / m ^{2} \cdot K

Since h_{ r } < h_{f b}, Equation (9.104) is used to obtain the effective heat-transfer coefficient:

h_{ t }=h_{f b}+0.75  h_{ r }=148+0.75  \times  21 \cong 164  W / m ^{2} \cdot K

This value is one to two orders of magnitude lower than the heat-transfer coefficient for nucleate boiling calculated in Example 9.1.