Thermal expansion is exploited in the bimetallic strip (
[link] ). This device can be used as a thermometer if the curving strip is attached to a pointer on a scale. It can also be used to automatically close or open a switch at a certain temperature, as in older or analog thermostats.
Calculating linear thermal expansion
The main span of San Francisco’s Golden Gate Bridge is 1275 m long at its coldest. The bridge is exposed to temperatures ranging from
to
. What is its change in length between these temperatures? Assume that the bridge is made entirely of steel.
Strategy
Use the equation for linear thermal expansion
to calculate the change in length,
. Use the coefficient of linear expansion
for steel from
[link] , and note that the change in temperature
is
Solution
Substitute all of the known values into the equation to solve for
:
Significance
Although not large compared with the length of the bridge, this change in length is observable. It is generally spread over many expansion joints so that the expansion at each joint is small.
Unconstrained objects expand in all dimensions, as illustrated in
[link] . That is, their areas and volumes, as well as their lengths, increase with temperature. Because the proportions stay the same, holes and container volumes also get larger with temperature. If you cut a hole in a metal plate, the remaining material will expand exactly as it would if the piece you removed were still in place. The piece would get bigger, so the hole must get bigger too.
Thermal expansion in two dimensions
For small temperature changes, the change in area
is given by
where
is the change in area
is the change in temperature, and
is the coefficient of linear expansion, which varies slightly with temperature.