New technology for moving airplanes on the ground]

New technology for moving airplanes on the ground]

New technology for moving airplanes on the ground

Keywords: Aircraft, Electric motors

The Boeing Company and Chorus Motors have demonstrated an exploratory technology that could lead to a more efficient way of moving aeroplanes when they are on the ground at airports.

Successful tests last June of an onboard electric motor attached to the nose wheel of a Boeing 767 have shown that it may be a viable way of powering aeroplanes to move in and around gates, largely eliminating the use of airport tow tugs and jet engines now serving this purpose, as well as reducing emissions.

“We are striving to help our aerospace customers operate more efficiently, cleanly and quietly at airports,” said Jim Renton, a director of Technology Integration in Boeing Phantom Works, the company's advanced research and development unit. “Our testing has shown that onboard electric motors can be very useful in achieving that goal if packaging, weight and flight-related technical issues identified during these tests can be resolved.”

“We believe onboard electric motors have a great many advantages,” added Bob Carman, Chorus Motors' WheelTug program manager. “They could reduce the need for ground tugs and their associated costs, allow faster flight turnarounds and increased fuel efficiency per trip, and reduce aeroplane noise and emissions at airports, to name just a few advantages.”

Phantom Works researchers, together with those from Chorus Motors, a developer of innovative electric motor technologies, have worked together this year to design, build and operate a prototype onboard electric drive system that may enable pilots of large aeroplanes to be in complete control of their aeroplanes from gate to gate.

In June, the Phantom Works/Chorus Motors team, in co-operation with Air Canada, installed an electric motor drive on an Air Canada 767 and conducted a series of successful tests. Air Canada pilots performed ground manoeuvres on slopes and terrains typical of those at airports around the world, including driving in reverse from a gate and taxiing forward to a runway.

Tests also were performed at ramp temperatures exceeding 120 degrees Fahrenheit and at loads of up to 94 percent of the maximum takeoff weight for the aeroplane.

“Powered nose wheels have very positive benefits and I am quite impressed with the potential of the electric motor technology,” said Capt. Hugh Campbell, director of Pilot Qualifications at Air Canada, who participated in the testing with Air Canada's chief 767 pilot, Capt. Richard Burke.

Next steps involve working to successfully resolve the technical issues that surfaced during the tests in order to define a path for commercial system installation.

Details available from: Boeing Phantom Works, Tel: +1 206 766 2923. Chorus Motors Aerospace, Tel: +1 805 908 1762.