Pushback (aviation)

(Redirected from Aircraft tug)

In aviation, pushback is an airport procedure during which an aircraft is pushed backwards away from its parking position, usually at an airport gate by external power.[1][2] Pushbacks are carried out by special, low-profile vehicles called pushback tractors or tugs.

A KLM Boeing 777 being pushed back from a gate at Narita International Airport in Japan.

Although many aircraft are capable of moving themselves backwards on the ground using reverse thrust (a procedure referred to as a powerback),[1] the resulting jet blast or prop wash would cause increased noise, damage to the terminal building or equipment, and can cause injury to airport staff due to flying debris. This debris would also be sucked into the engine, as it is in normal use, and cause excessive wear - a major cause of wear on aircraft engines is during ground use.[3] A pushback is therefore the preferred method when ground-handling aircraft.

Definition

edit

IATA defines aircraft pushback as "rearward moving of an aircraft from a parking position to a taxi position by use of specialized ground support equipment."[1]

Procedure

edit
Airbus A380 pushback

Pushbacks at busy aerodromes are usually subject to ground control clearance to facilitate ground movement on taxiways.[4][5] Once clearance is obtained, the pilot will communicate with the tractor driver (or a ground handler walking alongside the aircraft in some cases) to start the pushback. To communicate, a headset may be connected near the nose gear.

Since the pilots cannot see what is behind the aircraft, steering is done by the pushback tractor driver and not by the pilots. Depending on the aircraft type and airline procedure, a bypass pin may be temporarily installed into the nose gear to disconnect it from the aircraft's normal steering mechanism.

Once the pushback is completed, the towbar is disconnected, and any bypass pin removed. The ground handler will show the bypass pin to the pilots to make it clear that it has been removed.[4] The pushback is then complete, and the aircraft can taxi forward under its own power.

Equipment

edit

Moving light aircraft

edit
 
Light aircraft can usually be moved by human power alone. Here, this Aerotechnik EV-97A Eurostar is being pulled into position for refueling

Very small airplanes may be moved by human power alone. The airplane may be pushed or pulled by landing gear or wing struts since they're known to be strong enough to drag the airplane through the air. To allow for turns, a person may either pick up or push down on the tail to raise either the nose wheel or tail wheel off the ground, then rotate the airplane by hand. A less cumbersome method involves attaching a short tow bar to either the nose wheel or tail wheel, which provides a solid handhold and leverage to steer with, as well as eliminates the danger of handling the propeller. These tow bars are usually a lightweight aluminum alloy construction which allows them to be carried on board the airplane. Other small tow bars have a powered wheel to help move the airplane, with power sources as diverse as lawnmower engines or battery-operated electric drills. However, powered tow bars are usually too large and heavy to be practically carried on small airplanes.

Tractors and towbars

edit
 
Pushback tug with a towbar on the apron
 
A conventional tractor hooked up to a United Airlines Boeing 777-200ER at Denver International Airport

Large aircraft cannot be moved by hand and must have a tractor or tug. Pushback tractors use a low profile design to fit under the aircraft nose. For sufficient traction the tractor must be heavy, and most models can have extra ballast added. A typical tractor for large aircraft weighs up to 54 tonnes (59.5 short tons; 53.1 long tons; 119,000 pounds) and has a drawbar pull of 334 kN (75,000 lbf). Often the driver's cabin can be raised for increased visibility when reversing and lowered to fit under aircraft. There are two types of pushback tractors: conventional and towbarless (TBL).

Conventional tugs use a tow bar to connect the tug to the nose landing gear of the aircraft. The tow bar is fixed laterally at the nose landing gear, but may move slightly vertically for height adjustment. At the end that attaches to the tug, the tow bar may pivot freely laterally and vertically. In this manner the tow bar acts as a large lever to rotate the nose landing gear. Each aircraft type has a unique tow fitting so the towbar also acts as an adapter between the standard-sized tow pin on the tug and the type-specific fitting on the aircraft's landing gear. The tow bar must be long enough to place the tug far away enough to avoid hitting the aircraft and to provide sufficient leverage to facilitate turns. On heavy tow bars for large aircraft the towbar rides on its own wheels when not connected to an aircraft. The wheels are attached to a hydraulic jacking mechanism which can lift the towbar to the correct height to mate to both the airplane and the tug, and once this is accomplished the same mechanism is used in reverse to raise the tow bar wheels from the ground during the pushback process. The tow bar can be connected at the front or the rear of the tractor, depending on whether the aircraft will be pushed or pulled. The towbar has a shear pin which prevents the aircraft from being mishandled by the tug; when overstressed the shear pin will snap, disconnecting the bar from the nose gear to prevent damage to the aircraft and tug.

 
A towbarless tug at Frankfurt Airport transporting a Lufthansa Airbus A340-300
 
Towbars are used to connect the tractor to the aircraft.

Towbarless (TBL) tractors do not use a towbar; they scoop up the nose landing gear and lift it off the ground. This avoids the time penalty of connecting/disconnecting a towbar, and entirely removes the cost/complexity of maintaining towbars on the ramp. The tug itself does not need to be particularly massive - the aircraft's nosewheel weight provides the necessary downward force. Lastly, a TBL tug is much shorter (compared to a tug+towbar system) and has only a single pivot point instead of one at either end of the towbar, so it has much simpler and precise control of the aircraft. This is very useful in general aviation settings with a wider variety of aircraft in more confined spaces than their airline counterparts.

Manufacturers of electric TBL tugs offer models capable of moving any aircraft from the smallest single-engine type to narrow-body airliners, military cargo and airline-sized business jets. Just as specialized towbars are required for a wide range of aircraft, many TBL tugs use adapters which enable the movement of many unique aircraft. The majority of aircraft do not require adapters and can be moved without any special adjustments to the tug. This is in contrast to conventional tugs which often use so-called "universal" towbars which must be adjustable to suit many aircraft types. Electric TBL tugs are gaining popularity among general aviation operators and FBOs as an alternative to gas or diesel-powered conventional tugs. Being electric rather than internal combustion-powered, electric tugs are low-emission which is a major advantage for environmentally-conscious operators; this also enables the tug to be safely operated inside a closed hangar.

Robotic tractor/tug

edit

The Lahav Division of Israel Aerospace Industries has developed a semi-robotic towbarless tractor it calls TaxiBot that can tow an aircraft from the terminal gate to the take-off point (taxi-out phase) and return it to the gate after landing (taxi-in phase). The TaxiBot eliminates the use of airplane engines during taxi-in and until immediately prior to take-off during taxi-out potentially saving airlines billions of dollars in fuel that is used. The TaxiBot is controlled by the pilot from the cockpit using the regular pilot controls.[6]

British Airways has been using a similar sort of tug too. [7]

Other equipment applications

edit

While the vehicle is referred to as a pushback tug, it is also used to tow aircraft in areas where taxiing the aircraft is not practical or is unsafe, such as moving aircraft in and out of maintenance hangars, or moving aircraft that are not under their own power.

Some airlines, notably Virgin Atlantic, advocated towing aircraft to the holding point of the runway to save fuel and reduce environmental impact.[8] However, the practice was discontinued after landing gear maintenance costs increased due to the stress put on the landing gear during the towing process.[9]

Some fuel must still be burned to operate the auxiliary power unit to provide electrical and pneumatic power to run lighting, environmental and communications systems, unless the tug itself provides these sources of power, which some do. This method also places a larger workload on ground crews and equipment, especially if the aircraft and tow tractor ends up having to wait in a long line of aircraft.

In media

edit

In an advertising campaign, also documented on the television show Fifth Gear, a Volkswagen Touareg was used to pull a Boeing 747. As cited before, the "tractor" needs to be heavy to aid traction. The Touareg carried 4.3 tons worth of cement bags, and the tires were inflated to twice the normal pressure to handle the extra weight. Tractor tires have high sidewall ratios for that reason.[10] This is the world record for the heaviest load towed by a production car.

edit

See also

edit

References

edit
  1. ^ a b c "IATA Reference Manual (IRM) for Audit Programs 11th edition". IATA.org. Montreal—Geneva: International Air Transport Association. 2021. Retrieved 2 May 2021.
  2. ^ Kumar, Bharat; DeRemer, Dale; Marshall, Douglas M. (2004). An Illustrated Dictionary of Aviation. New York: McGraw-Hill. p. 514. ISBN 978-0-07-139606-6.
  3. ^ Ravikovich, A (2020). "Criterion for evaluation of erosion of aviation engine parts from polymer composite materials". IOP Conf. Series: Materials Science and Engineering. 868 (1): 1. Bibcode:2020MS&E..868a2026R. doi:10.1088/1757-899X/868/1/012026 – via Research Gate. This effect is inherent in the take-off and landing stages when sand and dust are lifted from the runway by an air stream, which greatly affects the durability of PCM parts.
  4. ^ a b Smith, David (2015). Air Traffic Control Handbook (10th ed.). Manchester: Crécy. p. 127. ISBN 978-08597-91830.
  5. ^ "Doc 4444 Procedures for Air Navigation Services — Air Traffic Management (PANS-ATM)" (PDF). OPS Group. 2016. p. 12.3.4.4. Retrieved 2 May 2021.
  6. ^ "New IAI "taxibot" to save airlines billions". Globes. Globes. 3 February 2011. Retrieved 9 July 2012.
  7. ^ "Remotely controlled aircraft tugs: The future of ground handling".
  8. ^ "BBC NEWS - Business - Virgin Atlantic move to save fuel". BBC.co.uk. 3 December 2006. Retrieved 17 March 2017.
  9. ^ Ellie Zolfagharifard, "Reducing runway emissions", The Engineer, December 7, 2009.
  10. ^ Fifth Gear (21 August 2014). "VW Touareg Towing a 747 Jumbo Jet - Fifth Gear". Archived from the original on 2021-12-21. Retrieved 17 March 2017 – via YouTube.

Sources

edit