<< Chapter < Page Chapter >> Page >
Thermal conductivities of common substances At temperatures near 0ºC.
Substance Thermal conductivity k (J/s⋅m⋅ºC)
Silver 420
Copper 390
Gold 318
Aluminum 220
Steel iron 80
Steel (stainless) 14
Ice 2.2
Glass (average) 0.84
Concrete brick 0.84
Water 0.6
Fatty tissue (without blood) 0.2
Asbestos 0.16
Plasterboard 0.16
Wood 0.08–0.16
Snow (dry) 0.10
Cork 0.042
Glass wool 0.042
Wool 0.04
Down feathers 0.025
Air 0.023
Styrofoam 0.010

A combination of material and thickness is often manipulated to develop good insulators—the smaller the conductivity k size 12{k} {} and the larger the thickness d size 12{d} {} , the better. The ratio of d / k size 12{d/k} {} will thus be large for a good insulator. The ratio d / k size 12{d/k} {} is called the R size 12{R} {} factor    . The rate of conductive heat transfer is inversely proportional to R size 12{R} {} . The larger the value of R size 12{R} {} , the better the insulation. R size 12{R} {} factors are most commonly quoted for household insulation, refrigerators, and the like—unfortunately, it is still in non-metric units of ft 2 ·°F·h/Btu, although the unit usually goes unstated (1 British thermal unit [Btu] is the amount of energy needed to change the temperature of 1.0 lb of water by 1.0 °F). A couple of representative values are an R size 12{R} {} factor of 11 for 3.5-in-thick fiberglass batts (pieces) of insulation and an R size 12{R} {} factor of 19 for 6.5-in-thick fiberglass batts. Walls are usually insulated with 3.5-in batts, while ceilings are usually insulated with 6.5-in batts. In cold climates, thicker batts may be used in ceilings and walls.

The figure shows two thick rectangular pieces of fiberglass batt lying one upon the other.
The fiberglass batt is used for insulation of walls and ceilings to prevent heat transfer between the inside of the building and the outside environment.

Note that in [link] , the best thermal conductors—silver, copper, gold, and aluminum—are also the best electrical conductors, again related to the density of free electrons in them. Cooking utensils are typically made from good conductors.

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 14.0 cm in diameter. The boiling water is evaporating at the rate of 1.00 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 .

T 2 T 1 = Q t d kA . size 12{T rSub { size 8{2} } - T rSub { size 8{1} } = { {Q} over {t} } left ( { {d} over { ital "kA"} } right )} {}

Solution

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

    The thickness of the pan, d = 0 .800 cm = 8.0 × 10 3  m, the area of the pan, A = π ( 0 .14 / 2 ) 2  m 2 = 1 . 54 × 10 2  m 2 , and the thermal conductivity, k = 220 J/s m⋅° C.

  2. Calculate the necessary heat of vaporization of 1 g of water:
    Q = mL v = 1 . 00 × 10 3  kg 2256 × 10 3  J/kg = 2256  J. size 12{Q= ital "mL" rSub { size 8{v} } = left (1 "." 0 times "10" rSup { size 8{ - 3} } `"kg" right ) left ("2256" times "10" rSup { size 8{6} } `"J/kg" right )="2256"`J} {}
  3. Calculate the rate of heat transfer given that 1 g of water melts in one second:
    Q / t = 2256  J/s or 2.26 kW. size 12{Q/t="2256"`"J/s"} {}
  4. Insert the knowns into the equation and solve for the temperature difference:
    T 2 T 1 = Q t d kA = 2256  J/s 8 . 00  ×  10 3 m 220  J/s m ⋅º C 1 . 54 × 10 2  m 2 = 5 . 33º C.

Discussion

The value for the heat transfer Q / t  = 2 . 26 kW  or  2256  J/s size 12{Q/t"=2" "." "26"`"kW"`"or"`"2256"`"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 100ºC size 12{"100°C"} {} 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.

Practice Key Terms 3

Get Jobilize Job Search Mobile App in your pocket Now!

Get it on Google Play Download on the App Store Now




Source:  OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14
Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'College physics for ap® courses' conversation and receive update notifications?

Ask