Slowed rotor has high-speed implications
CarterCopter
prototype breaks mu-1 barrier for second time
With a wingspan and rotor diameter of 45
feet, the Carter Aviation SR/C takes off like a helicopter and cruises like an
airplane.
It takes off and lands like a helicopter, cruises
like an airplane, and autorotates like an autogyro. Carter Aviation
Technologies' Slowed Rotor/Compound (SR/C) prototype broke the μ-1 barrier-a
ratio of the forward speed of an aircraft to the speed of its rotor tip that
generally limits the speed of rotorcraft-Nov. 7, the second time the company has
achieved the feat.
The aircraft, which Carter Aviation President and CEO
Jay Carter said can be flown with a fixed-wing pilot certificate, reached a true
airspeed of 200 mph at 10,790 feet msl on the milestone flight. It flew for 49
seconds at μ-1 and above and seven minutes, 32 seconds above μ-0.96, the company
said.
Spinning rotor blades present an aerodynamic challenge to aircraft
designers aiming for high-speed flight: As the aircraft moves forward, the
advancing blade travels through the air much faster than the retreating blade,
creating a potentially dangerous imbalance of lift. If the advancing rotor tip
has a speed of 200 mph and the aircraft is moving forward at 200 mph-a μ of
1-that tip is hurtling forward at 400 mph while the retreating tip has an
airspeed of zero. An aircraft will typically roll.
High-speed helicopters
such the Sikorsky X2 and the Eurocopter X3 tackle the problem with what Carter
called "brute force": For as fast as the aircraft travels, the rotor blades
travel faster. (AOPA Pilot Senior Editor Alton K. Marsh discusses Sikorsky's
approach to the challenge, which includes counter-rotating blades, in the
October 2011 article "Swamp Pirates.") Carter Aviation Technologies takes the
opposite approach: Slow the rotor so much that it becomes a nonissue in cruise
flight.
"The rotor's just along for the ride," Carter said.
In
high-speed cruise, Carter said the SR/C travels as fast and efficiently as
general aviation fixed-wing airplanes. The slow-moving rotor basically
disappears from a drag standpoint-"it's like one thirtieth of the drag"-and the
pusher-prop aircraft relies on lift from the long, thin wings. Because the
aircraft takes off and lands using the rotors, the wings can be optimized for
cruise flight, he said. With a more powerful engine, he said that the technology
could reach 500 mph.
"I know I'm biased, but this aircraft can change
aviation," Carter said. "... I see this as general aviation, commercial
aviation-we can build these aircraft up to a 767 size that can carry 250
passengers."
The research and development firm, which licenses technology
to other aerospace companies, first broke the μ-1 barrier with a
first-generation design in June 2005. The aircraft was damaged in an emergency
landing later that day, and the company decided not to repair it. The
second-generation prototype is more than twice as efficient as the original,
making it almost four times as efficient as the best helicopter, Carter
said.
He touted the aircraft's ability to take off and land vertically,
autorotate at any altitude, and cruise at high speeds.
"We can combine
the best of the fixed wing and the best of a helicopter and the best of a gyro
all in one aircraft," he said.
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