Airfield rubber removal

Airfield rubber removal, also known as runway rubber removal, is the use of high pressure water, abrasives, chemicals and/or other mechanical means to remove the rubber that builds up on airport landing strips. The Federal Aviation Administration (FAA) specifies friction levels for safe operation of planes and measures friction coefficients for the evaluation of appropriate friction levels. Individual airports incorporate rubber removal into their maintenance schedules based on the number of take offs and landings that each airport experiences.

ource of airfield rubber build-up

When a plane lands, the tires are not spinning. The time it takes for the tires to get up to speed is referred to as "spin up time" (Speidel, 2002). During this time the tires are effectively dragging on the runway as well as being put under pressure by the weight of the airplane. The friction built up causes the rubber to polymerize and harden to the runway surface.

Effects of rubber buildup

The build up of rubber affects the level of friction of the runway, most noticeable as a reduction in braking and ground handling performance. This can lead to incidents such as runway overrun or a lateral slide off the runway.

The contributing factors for viscous hydroplaning are a damp or wet pavement,medium to high speed, poor pavement texture, and worn tire tread. If a runwayhas good microtexture and grooving and the aircraft tires have a good treaddesign, viscous hydroplaning could be alleviated.(NTSB, p.92)

Methods

High pressure water and ultra high pressure water

Sometimes referred to as hydrocleaning, high pressure and ultra high pressure work on the same principle of applying a spinning jet or set of jets to the surface in order to break the hardened rubber free from the runway surface. The main difference between the two is the pressure and flow. High pressure removal uses 2,000-1500 psi at up to 30 gallons of water per minute (gpm) while ultra high pressure removal uses up to 40,000 psi with a water usage between 8 and 16 gpm (Speidel, 2002, p.4). High pressure and ultra high pressure water operations rely on the impact of water alone and no chemicals are used.

Chemical removal

Cleaning the runway using chemicals involves the application of proprietary cleaners that are brushed into the surface of the runway and then washed off using low pressure water. There is a time between applying the chemicals and washing the runway when the chemicals are allowed to react with and break down the rubber. During this time the runway is unusable for landing operations and therefore could not be used safely in an emergency situation. The chemicals used can be expensive and require special handling. Still some runway maintenance crews like the ability to do their rubber removal in-house using existing or lower cost machinery.

High velocity impact removal

This method employs the principle of throwing abrasive particles at a very high velocity at the runway pavement surface, thus blasting the contaminants from the surface (Speidel, 2002). Also known as sandblasting, this method can introduce foreign object debris to the runway if not contained and cleaned up properly.

Mechanical removal

This type of removal involves the milling of the first 1/8 to 3/16 of an inch of the runway surface.

References

* [http://www.faa.gov/airports_airtraffic/airports/resources/advisory_circulars/media/150-5320-12C/150_5320_12c.PDF US. Department of Transportation.(1997). Measurement, Construction, and Maintenance of Skid-Resistand Airport Surfaces. Federal Aviation Administration Advisory Circular.]
* [http://www.airporttech.tc.faa.gov/naptf/att07/2002%20TRACK%20S.pdf/S5.pdf Speidel, Donna J., (2002, February). Airfield Rubber Removal Paper presented at the 2002 Federal Aviation Administration Technology Transfer Conference.]
* [http://ntsb.gov/Publictn/2001/AAR0102.pdf National Transportation Safety Board. 2001. Runway Overrun During Landing, American Airlines Flight 1420, McDonnell Douglas MD-82, N215AA, Little Rock, Arkansas, June 1, 1999. Aircraft Accident Report NTSB-AAR-01-02. Washington, DC.]