In-flight Refueling For Commercial Airlines?
There's real pressure on the aviation industry to
introduce faster, cheaper and greener aircraft, while maintaining the high
safety standards demanded of airlines worldwide.
Airlines carry more than
three billion passengers each year, which presents an enormous challenge not
only for aircraft manufacturers but for the civil aviation infrastructure that
makes this extraordinary annual mass-migration possible. Many international
airports are close to or already at capacity. The International Air Transport
Association (IATA) has estimated that, without intervention, many global
airports - including major hubs such as London Heathrow, Amsterdam Schiphol,
Beijing and Dubai - will have run out of runway or terminal capacity by
2020.
The obvious approach to tackling this problem is to extend and
enlarge airport runways and terminals - such as the long-proposed third runway
at London Heathrow. However there may be other less conventional alternatives,
such as introducing in-flight refueling for civil aircraft on key long-haul
routes.
Our project, Research on a Cruiser-Enabled Air Transport
Environment (Recreate), began in 2011 to evaluate whether this was something
that could prove a viable, and far cheaper, solution.
Aircraft
weight-watchers
The world's first in-flight refuelling in 1923.
AF.mil
If in-flight refuelling seems implausible, it's worth remembering that
it was first trialed in the 1920s, and the military has continued to develop the
technology ever since. The appeal is partly to reduce the aircraft's weight on
take-off, allowing it to carry additional payload, and partly to extend its
flight range.
Notably, during the Falklands War in 1982 RAF Vulcan
bombers used in-flight refueling to stage what was at the time the longest
bombing mission ever, flying 8,000 miles non-stop from Ascension Island in the
South Atlantic to the Falklands and back.
Reducing take-off weight could
offer many benefits for civilian aircraft too. Without the need to carry so much
fuel the aircraft can be smaller, which means less noise on take-off and landing
and shorter runways. This opens up the network of smaller regional airports as
new potential sites for long-haul routes, relieving pressure on the major hubs
that are straining at the seams.
There are environmental benefits too, as
a smaller, lighter aircraft requires less fuel to reach its destination. Our
initial estimates from air traffic simulations demonstrate that it's possible to
reduce fuel burn by up to 11% over today's technology by simply replacing
existing global long-haul flight routes with specifically designed 250-seater
aircraft with a range of 6,000nm after one refueling - roughly the distance from
London to Hong Kong.
This saving could potentially grow to 23% with
further efficiencies, all while carrying the same number of passengers the same
distance as is possible with the current aircraft fleet, and despite the
additional fuel burn of the tanker aircraft.
However, this is not the
whole picture - in-flight refueling will require the aerial equivalent of petrol
stations in order to deliver keep passenger aircraft in the sky. With so much
traffic it simply wouldn't be possible to refuel any aircraft any time, anywhere
it was needed. The location of these refueling zones, coupled with the flight
distance between the origin and destination airports can greatly affect the
potential benefits achievable, possibly pulling flights away from their shortest
route, and even making refueling on some routes impossible - if for example the
deviation to the nearest refueling zone meant burning as much fuel as would have
been saved.
Safety and automation
As with all new concepts -
particularly those that involve bringing one aircraft packed with people and
another full of fuel into close proximity during flight - it's quite right to
ask whether this is safe. To try and answer this question, the Dutch National
Aerospace Laboratory and German Aerospace Centre used their flight simulators to
test the automated in-flight refuelling flight control system developed as part
of the Recreate project.
One simulator replicated the maneuver from the
point of view of the tanker equipped with an in-flight refuelling boom, the
other simulated the aircraft being refuelled mid-flight. Critical test
situations such as engine failure, high air turbulence and gusts of wind were
simulated with real flight crews to assess the potential danger to the
operation. The results were encouraging, demonstrating that the maneuver doesn't
place an excessive workload on the pilots, and that the concept is viable from a
human as well as a technical perspective.
So far we've demonstrated the
potential aerial refueling holds for civilian aviation, but putting it into
practice would still pose challenges. Refueling hubs would need to be
established worldwide, shared between airlines. There would need to be
fundamental changes to airline pilot training, alongside a wider public
acceptance of this departure from traditional flight operations.
However,
it does demonstrate that, in addition to all the high-tech work going into
designing new aircraft, new materials, new engines and new fuels, the technology
we already have offers solutions to the long-term problems of ferrying billions
of passengers by air around the world.The Conversation
Juliana Early,
Lecturer in Mechanical and Aerospace Engineering at Queen's University Belfast.
This article was originally published on The Conversation. Read the original
article. Top image: IIAF
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