Example 14.5 Calculating Heat Transfer Through Conduction: Conduction Rate Through an Ice Box

A polystyrene foam ice box has a total area of $0\text{.950}{\text{ m}}^2$ and walls with an average thickness of 2.50 cm. The box contains ice, water, and canned beverages at $\text{ºC}$. The inside of the box is kept cold by melting ice. How much ice melts in one day if the ice box is kept in the trunk of a car at $\text{35}\text{ºC}$?

Strategy

This question involves both heat for a phase change (melting of ice) and the transfer of heat by conduction. To find the amount of ice melted, we must find the net heat transferred. This value can be obtained by calculating the rate of heat transfer by conduction and multiplying by time.

Solution

1. Identify the knowns.
   14.28 $$A=0\text{.}\text{950}{\text{ m}}^2\mathrm{; }d=2\text{.}\text{50}\text{ cm}=0\text{.0250 m;}{T}_1=\mathrm{0\; º}\text{C;}{T}_2=\text{35}\mathrm{º}\text{C,}t=\text{1 day}=\text{24 hours}=\text{86,400 s.}$$
2. Identify the unknowns. We need to solve for the mass of the ice, $m\text{.}$ We will also need to solve for the net heat transferred to melt the ice, $Q\text{.}$
3. Determine which equations to use. The rate of heat transfer by conduction is given by
   14.29 $$\frac{Q}{t}=\frac{\text{kA}(T_2-T_1)}{d}\text{.}$$
4. The heat is used to melt the ice, $Q={\text{mL}}_{\text{f}}.$
5. Insert the known values.
   14.30 $$\frac{Q}{t}=\frac{\left(\text{0.010 J/s}\cdot \text{m}\cdot º\text{C}\right)\left(\text{0.950}{\text{ m}}^2\right)\left(\text{35.}\mathrm{0\; º}\text{C}-\mathrm{0\; º}\text{C}\right)}{\text{0.0250 m}}=\text{13.3 J/s}$$
6. Multiply the rate of heat transfer by the time ($1\text{ day = 86,400}\text{ s}$).
   14.31 $$Q=\left(Q/t\right)t=\left(\text{13}\text{.}3\text{ J/s}\right)\left(\text{86},\text{400}\text{ s}\right)=1\text{.}\text{15}\times {\text{10}}^6\text{ J}$$
7. Set this equal to the heat transferred to melt the ice: $Q={\text{mL}}_{\text{f}}\text{.}$ Solve for the mass $m$.
   14.32 $$m=\frac{Q}{L_{\text{f}}}=\frac{1\text{.}\text{15}\times {\text{10}}^6\text{ J}}{\text{334 }\times {\text{10}}^3\text{ J/kg}}=3\text{.}\text{44}\text{kg}$$

Discussion

The result of 3.44 kg, or about 7.6 lb., seems about right, based on experience. You might expect to use about a 4 kg (7–10 lb.) bag of ice per day. A little extra ice is required if you add any warm food or beverages.

Inspecting the conductivities in Table 14.3 shows that polystyrene foam is a very poor conductor and thus a good insulator. Other good insulators include fiberglass, wool, and goose-down feathers. Like polystyrene foam, these all incorporate many small pockets of air, taking advantage of air’s poor thermal conductivity.

Example 14.6 Calculating the Temperature Difference Maintained by a Heat Transfer: Conduction Through an Aluminum Pan

Water is boiling in an aluminum pan placed on an electrical element on a stovetop. The sauce pan has a bottom that is 0.800 cm thick and 14 cm in diameter. The boiling water is evaporating at the rate of 1 g/s. What is the temperature difference across—through—the bottom of the pan?

Strategy

Conduction through the aluminum is the primary method of heat transfer here, and so we use the equation for the rate of heat transfer and solve for the temperature difference.

Solution

1. Identify the knowns and convert them to the SI units.

   The thickness of the pan, $d=0\text{.800 cm}=8.0\times {\text{10}}^{-3}\text{ m,}$ the area of the pan $A=\pi (0\text{.14}/2{)}^2{\text{ m}}^2=1\text{.}\text{54}\times {\text{10}}^{-2}{\text{ m}}^2$, and the thermal conductivity, $k=\text{220 J/s}\cdot \mathrm{m\cdot °}\mathrm{C.}$

2. Calculate the necessary heat of vaporization of 1 g of water.
   14.34 $$Q={\text{mL}}_{\text{v}}=\left(1\text{.}00\times {\text{10}}^{-3}\text{ kg}\right)\left(\text{2,256}\times {\text{10}}^3\text{ J/kg}\right)=\text{2,256}\mathrm{ J}$$
3. Calculate the rate of heat transfer given that 1 g of water melts in one second.
   14.35 $$Q/t=\text{2,256}\text{ J/s or 2.26 kW}$$
4. Insert the knowns into the equation and solve for the temperature difference.
   14.36 $$T_2-T_1=\frac{Q}{t}\left(\frac{d}{\text{kA}}\right)=\left(\text{2,256}\text{ J/s}\right)\frac{8\text{.}\text{00} \times {\text{10}}^{-3}\text{m}}{\left(\text{220}\text{ J/s}\cdot \text{m}\cdot º\text{C}\right)\left(1\text{.}\text{54}\times {\text{10}}^{-2}{\text{ m}}^2\right)}=5\text{.}\mathrm{33\; º}C$$

Discussion

The value for the heat transfer $Q/t\text{ = 2}\text{.}\text{26}\text{kW}\text{ or }\text{2,256}\text{ J/s}$ is typical for an electric stove. This value gives a remarkably small temperature difference between the stove and the pan. Consider that the stove burner is red hot while the inside of the pan is nearly $\text{100 ºC}$ because of its contact with boiling water. This contact effectively cools the bottom of the pan in spite of its proximity to the very hot stove burner. Aluminum is such a good conductor that it only takes this small temperature difference to produce a heat transfer of 2.26 kW into the pan.

Conduction is caused by the random motion of atoms and molecules. As such, it is an ineffective mechanism for heat transport over macroscopic distances and short time distances. Take, for example, the temperature on Earth, which would be unbearably cold during the night and extremely hot during the day if heat transport in the atmosphere was to be only through conduction. In another example, car engines would overheat unless there was a more efficient way to remove excess heat from the pistons.

Applying the Science Practices: Estimating Thermal Conductivity

Footnotes

• 7 At temperatures near 0 ºC.