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the collective is lowered.
Since the tail rotor is geared to the main rotor, low main
rotor r.p.m. may prevent the tail rotor from producing
enough thrust to maintain directional control. If pedal
control is lost and the altitude is low enough that a
landing can be accomplished before the turning rate
increases dangerously, slowly decrease collective pitch,
maintain a level attitude with cyclic control, and land.
SYSTEM MALFUNCTIONS
The reliability and dependability record of modern
helicopters is very impressive. By following the
manufacturer’s recommendations regarding periodic
maintenance and inspections, you can eliminate most
systems and equipment failures. Most malfunctions or
failures can be traced to some error on the part of the
pilot; therefore, most emergencies can be averted before
they happen. An actual emergency is a rare occurrence.
ANTITORQUE SYSTEM FAILURE
Antitorque failures usually fall into two categories.
One focuses on failure of the power drive portion of the
tail rotor system resulting in a complete loss of antitorque.
The other category covers mechanical control
failures where the pilot is unable to change or control
tail rotor thrust even though the tail rotor may still be
providing antitorque thrust.
Tail rotor drive system failures include driveshaft failures,
tail rotor gearbox failures, or a complete loss of
the tail rotor itself. In any of these cases, the loss of
antitorque normally results in an immediate yawing of
the helicopter’s nose. The helicopter yaws to the right
in a counter-clockwise rotor system and to the left in a
clockwise system. This discussion assumes a
helicopter with a counter-clockwise rotor system. The
severity of the yaw is proportionate to the amount of
power being used and the airspeed. An antitorque
failure with a high power setting at a low airspeed
results in a severe yawing to the right. At low power
settings and high airspeeds, the yaw is less severe. High
airspeeds tend to streamline the helicopter and keep it
from spinning.
If a tail rotor failure occurs, power has to be reduced in
order to reduce main rotor torque. The techniques
differ depending on whether the helicopter is in flight
or in a hover, but will ultimately require an autorotation.
If a complete tail rotor failure occurs while hovering,
enter a hovering autorotation by rolling off the
throttle. If the failure occurs in forward flight,
enter a normal autorotation by lowering the collective
and rolling off the throttle. If the helicopter has
enough forward airspeed (close to cruising speed) when
the failure occurs, and depending on the helicopter
design, the vertical stabilizer may provide enough directional
control to allow you to maneuver the helicopter to
a more desirable landing sight. Some of the yaw may be
compensated for by applying slight cyclic control opposite
the direction of yaw. This helps in directional
control, but also increases drag. Care must be taken not
to lose too much forward airspeed because the streamlining
effect diminishes as airspeed is reduced. Also,
more altitude is required to accelerate to the
correct airspeed if an autorotation is entered into at a
low airspeed.
A mechanical control failure limits or prevents control
of tail rotor thrust and is usually caused by a
stuck or broken control rod or cable. While the tail
rotor is still producing antitorque thrust, it cannot be
controlled by the pilot. The amount of antitorque
depends on the position where the controls jam or
fail. Once again, the techniques differ depending on
the amount of tail rotor thrust, but an autorotation is
generally not required.
LANDING—STUCK LEFT PEDAL
Be sure to follow the procedures and techniques
outlined in the FAA-approved rotorcraft flight manual
for the helicopter you are flying. A stuck left
pedal, such as might be experienced during takeoff or
climb conditions, results in the helicopter’s nose
yawing to the left when power is reduced. Rolling off
the throttle and entering an autorotation only makes
matters worse. The landing profile for a stuck left
pedal is best described as a normal approach to a
momentary hover at three to four feet above the
surface. Following an analysis, make the landing. If
the helicopter is not turning, simply lower the
helicopter to the surface. If the helicopter is turning
to the right, roll the throttle toward flight idle the
amount necessary to stop the turn as you land. If the
helicopter is beginning to turn left, you should be
able to make the landing prior to the turn rate
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