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—Case
Studies—
Airport Runway Insulation—Newton
Field, located in Jackman, Maine, is Maine’s first public
airport to insulate under its runway. Half-a- million board
feet of XPS extruded polystyrene insulation was used to carry
out the project.
Jackman is cold. Frost penetrates eight to ten feet into the
ground. Despite frigid winter weather, real pavement problems
do not begin until spring, when thaws trigger frost heaving
and paving deterioration. Other than the obvious safety hazards
that this presented, it also meant additional maintenance
expenses.
Traditionally, freeze/thaw problems have been solved by a
deep layer of gravel under the pavement. It would take 118
inches of gravel to prevent the subgrade from freezing and
the Federal Aviation Administration requires native soils
to be replaced with granular soils to two-thirds of the frost
depth. For Jackman, the FAA estimated depth of frozen soil
was 72 inches, requiring 48 inches of pavement and base section.
At Newton Field, however, it was decided to use an alternate
technique: extruded polystyrene insulation placed under the
roadbed. This application can not only prevent those problems
associated with frost heave, but can also save money in the
initial construction because less aggregate is needed for
the base. In this case, the use of insulation saved 36 inches
of gravel subgrade—more than 19,000 cubic yards of gravel
and the excavation to fill it.
The specification for Newton field called for a high compressive
strength insulation board, leveled on a minimum 1-inch layer
of supporting granular material, covered with 12½ inches
of gravel and two inches of bituminous pavement. The thickness
of the board depends on severity of the frost. About ½
inch of board thickness is recommended for each 500 freezing
index days. Two-inch board was specified for Jackman with
its freezing index of 2200.
According to a spokesman for the Maine airport, it was necessary
that the insulation withstand a loading of 40lbs. per square
inch, had a high insulating factor and a low water absorbency.
The water absorbency, in particular, was very important. If
the insulation absorbed too much water, it would freeze and
be useless as an insulator. They tested XPS as specified in
ASTM C 578 2001, Type VI, and it met all the requirements,
including a competitive price.
The Newton Field project used XPS as specified in ASTM C 578
2001, Type VI boards 8-feet long, 24-inches wide and 2-inches
thick. XPS, made by UC Industries, Inc., is a 40 psi high
density, closed cell foam panel with continuous skin surfaces
for water resistance and a long term R-value of 5 per inch
of thickness. XPS is lightweight and easy to handle, weighing
about 400 lbs per 1,000 square feet in the 2-inch thickness.
It meets AASHTO Spec-M230, Federal Spec HH-I-524C, Type IV,
ASTM C 578-87a VI and other cold weather specs.
Because Newton Field is the first U.S. airport where extensive
use has been made of insulation under the runway, the project
is being monitored by the U.S. Army’s Cold Regions Research
& Engineering Laboratory, which hopes to use the data
to validate and refine airport designs and procedures for
frost-prone areas.
XPS in Highway Applications—Highway
frost heave is a major factor responsible for the distress
of pavement in Colorado and other states. The phenomenon presents
a problem both from the standpoint of safety and costly, repeated
repairs. Three things must be present for frost heaves to
occur: freezing and thawing temperature ranges, free flowing
water and permeable soils. When the frost penetrates deep,
ice lenses form in the roadway foundation. As a result, the
pavement surface is thrust upward into the hump we call “frost
heave.” The key to frost heave is soil temperature —
by insulating the roadway, frost is prevented from cycling
in the ground.
In the summer of ’88 two roadway upgrading projects
were done by the Colorado Department of Highways, in mountainous
terrain, on the approach to the Eisenhower Tunnel. In both
cases Type VI XPS as specified in ASTM C 578 2001 was used
to help control chronic frost heave. One project used about
300 linear feet of XPS, the other, a 10 mile stretch of I-70,
had eight areas where frost heave problems had been experienced.
XPS was used in sections ranging from 85 to 500 ft. —
a total of about 1900 linear feet of insulated roadway.
Traditionally, depending on analysis of soil, excavation is
to a depth of 10 inches — 6 inches of base course and
4 inches of asphalt. The department added another 8 inches
to accommodate insulation, excavating to about 18 inches total.
Then 2 in. of base for a leveling course is placed. Next the
2 in. XPS panels are positioned. Workers stagger the joints
of the panels in a brick pattern. This helps interlock them
— a standard insulation practice originally developed
on flat roof applications. Fine sand is shoveled over each
joint and scattered over the boards holding the panels in
place. Then an 8 in. base (crushed gravel) is followed by
plant mix, leveling coat, and seal coat.
The work is all standard except for a minimum of extra care
required when applying gravel on top of the XPS panels. It’s
a simple technique, and the crews of both contractors picked
it up easily.
Wendell Upright, Project Engineer, says, “The key is
to go deeper with roadbed excavation in order to include insulation.
If there’s a drainage problem, it gets solved by adding
filter material and perforated pipe, so that water can get
out again. Workers place insulation over the pipe to keep
cold air from penetrating upward to the road.”
Engineers decided that use of a few hundred feet of extra
XPS would be a good investment to avoid future problems. So
wherever plans called for installation of perforated pipe
to drain water, they insulated the pipe with the same 2-in
XPS as specified in ASTM C 578 2001, Type VI extruded polystyrene
being used under the roadbed.
The Colorado Department of Highways now insulates all pipes
when building new roads or when installing or replacing pipes
in existing roads.
As Wes Goff, Resident Engineer puts it, “We would no
longer contemplate a sizable project without applying insulation
where frost heave problems would be anticipated. The experimental
projects gave us confidence to go ahead. Extruded polystyrene
insulation is no longer experimental — it’s the
approved, standard technique.”
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