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Rotorcraft Flying Menu >Aerodynamics
of Flight >Forward
Flight > Dissymmetry of Lift
When the helicopter moves through the air,
the relative airflow through the main rotor disc is different
on the advancing side than on the retreating side. The relative
wind encountered by the advancing blade is increased by the
forward speed of the helicopter, while the rela-tive wind speed
acting on the retreating blade is reduced by the helicopter’s
forward airspeed. Therefore, as a result of the relative wind
speed, the advancing blade side of the rotor disc produces more
lift than the retreating blade side. This situation is defined
as dissymmetry of lift. [Figure 3-14]
Figure 3-14. The blade tip speed of
this helicopter is approxi-mately 300 knots. If the helicopter
is moving forward at 100 knots, the relative wind speed on the
advancing side is 400 knots. On the retreating side, it is only
200 knots. This differ-ence in speed causes a dissymmetry of
lift.
If this condition was allowed to exist, a helicopter
with a counterclockwise main rotor blade rotation would roll
to the left because of the difference in lift. In reality, the
main rotor blades flap and feather automatically to equalize
lift across the rotor disc. Articulated rotor sys-tems, usually
with three or more blades, incorporate a horizontal hinge (flapping
hinge) to allow the individ-ual rotor blades to move, or flap
up and down as they rotate. A semirigid rotor system (two blades)
utilizes a teetering hinge, which allows the blades to flap
as a unit. When one blade flaps up, the other flaps down.As
shown in figure 3-15, as the rotor blade reaches the advancing
side of the rotor disc (A), it reaches its max-imum upflap velocity.
When the blade flaps upward, the angle between the chord line
and the resultant rela-tive wind decreases. This decreases the
angle of attack, which reduces the amount of lift produced by
the blade. At position (C) the rotor blade is now at its maximum
downflapping velocity. Due to downflapping, the angle between
the chord line and the resultant relative wind increases. This
increases the angle of attack and thus the amount of lift produced
by the blade.
Figure 3-15. The combined upward flapping
(reduced lift) of the advancing blade and downward flapping
(increased lift) of the retreating blade equalizes lift across
the main rotor disc counteracting dissymmetry of lift.
The combination of blade flapping and slow
relative wind acting on the retreating blade normally limits
the maxi-mum forward speed of a helicopter. At a high forward
speed, the retreating blade stalls because of a high angle of
attack and slow relative wind speed. This situation is called
retreating blade stall and is evidenced by a nose pitch up,
vibration, and a rolling tendency—usually to the left
in helicopters with counterclockwise blade rotation.
You can avoid retreating blade stall by not
exceeding the never-exceed speed. This speed is designated VNE
and is usually indicated on a placard and marked on the airspeed
indicator by a red line.
During aerodynamic flapping of the rotor blades
as they compensate for dissymmetry of lift, the advancing blade
achieves maximum upflapping displacement over the nose and maximum
downflapping displacement over the tail. This causes the tip-path
plane to tilt to the rear and is referred to as blowback. Figure
3-16 shows how the rotor disc was originally oriented with the
front down follow-ing the initial cyclic input, but as airspeed
is gained and flapping eliminates dissymmetry of lift, the front
of the disc comes up, and the back of the disc goes down. This
reorientation of the rotor disc changes the direction in which
total rotor thrust acts so that the helicopter’s for-ward
speed slows, but can be corrected with cyclic input.
Figure 3-16. To compensate for blowback,
you must move the cyclic forward. Blowback is more pronounced
with higher airspeeds.
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