Helicopter Dynamics of Flight PDF

Summary

This document details the dynamics of helicopter flight, including concepts like airflow, blade actions, and helicopter tendencies. It discusses topics like the interplay between wind speed and blade movements within a helicopter's forward flight. Specific actions, described diagrammatically include, the advancing and retreating blades, translating tendencies, and pendular action.

Full Transcript

BASIC
HELICOPTER
& PROPELLER
DESIGN
Helicopter dynamics of Flight

Prepared By Engr. Shiara Denise M. Valencia
Technical and
Operational Terms

Engr SDVM 2
 Airflow in Forward Flight
Airflow across the rotor disk in forward flight varies from airflow at a
hover.

In forward flight, air flows opposite the aircraft’s flightpath.
The velocity of this air flow equals the helicopter’s forward
speed.

Because the rotor blades turn in a circular pattern, the velocity of
airflow across a blade depends on the position of the blade in the
plane of rotation at a given instant, its rotational velocity, and airspeed
of the helicopter.
Engr SDVM 3
 Airflow in Forward Flight
The highest velocity of airflow
occurs over the right side (3 o’clock
position) of the helicopter (advancing
blade) in a rotor disk that turns
(counterclockwise) and decreases to
rotational velocity over the nose.

It continues to decrease until the
lowest velocity of airflow occurs
over the left side (9 o’clock position)
of the helicopter (retreating blade).

Engr SDVM 4
 Advancing Blade
As the relative wind speed of the
advancing blade increases, the blade
gains lift and begins to flap up.
It reaches its maximum upflap velocity
at the 3 o’clock position, where the
wind velocity is the greatest.
This upflap creates a downward flow
of air and has the same effect as
increasing the induced flow velocity by
imposing a downward vertical velocity
vector to the relative wind which
decreases the AOA.

Engr SDVM 5
 Retreating Blade
As relative wind speed of the
retreating blade decreases, the blade
loses lift and begins to flap down.
It reaches its maximum downflap
velocity at the 9 o’clock position,
where wind velocity is the least.
This downflap creates an upward
flow of air and has the same effect as
decreasing the induced flow velocity
by imposing an upward velocity
vertical vector to the relative wind
which increases the AOA.

Engr SDVM 6
Engr SDVM 7
 Dissymmetry of Lift
is the differential (unequal) lift between advancing and retreating
halves of the rotor disk caused by the different wind flow velocity
across each half.

This difference in lift would cause the helicopter to be uncontrollable
in any situation other than hovering in a calm wind.

Engr SDVM 8
 Dissymmetry of Lift
The relative wind encountered by the
advancing blade is increased by the
forward speed of the helicopter, while
the relative wind speed acting on the
retreating blade is reduced by the The blade tip speed of this helicopter is
helicopter’s forward airspeed. approximately 400 knots. If the helicopter is
moving forward at 100 knots, the relative
windspeed on the advancing side is 500 knots.
On the retreating side, it is only 300 knots.
This difference in speed causes a dissymmetry
of lift.

Engr SDVM 9
 Translating Tendency
(Drift)
During hovering flight, a single
main rotor helicopter tends
to move in the direction of tail
rotor thrust. This lateral
(or sideward) movement is
called translating tendency.

Engr SDVM 10
 Translating Tendency

Engr SDVM Source: https://www.youtube.com/watch?v=17_FzAuoeWw&list=PL2tY7KqPLKuRoxnHXr827FUD3yFSF_o-2&index=6&ab_channel=FlightFirst 11
 Pendular Action
refers to the swinging
motion of the fuselage side
to side or back and forth.

This refers to the swinging
motion of a helicopter's
fuselage due to changes in lift
or thrust

Engr SDVM 12
 Pendular Action

Engr SDVM Source: https://www.youtube.com/watch?v=0KlNcjEzbUU&ab_channel=FlightFirst 13
 Coning
The rotation of the rotor disk
creates centrifugal force
(inertia), which tends to pull the
blades straight outward
from the main rotor hub:

The faster the rotation, the
greater the centrifugal force, the
slower the rotation, the smaller
the centrifugal force.

Engr SDVM 14
 Coning

Engr SDVM Source: https://www.youtube.com/watch?v=pT-zAuZpGXM&list=PL2tY7KqPLKuRoxnHXr827FUD3yFSF_o-2&index=8&ab_channel=FlightFirst 15
 Coriolis Effect
The Coriolis Effect is also referred to as the law of
conservation of angular momentum.

It states that the value of angular momentum of a rotating body does
not change unless an external force is applied.

In other words, a rotating body continues to rotate with the same
rotational velocity until some external force is applied to change the
speed of rotation.

Angular momentum is the moment of inertia (mass
times distance from the center of rotation squared) multiplied
by the speed of rotation.
Engr SDVM 16
 Coriolis Effect

Engr SDVM Source: https://www.youtube.com/watch?v=0KlNcjEzbUU&ab_channel=FlightFirst 17
 Gyroscopic Precession
The spinning main rotor of a
helicopter acts like a gyroscope.
As such, it has the properties of
gyroscopic action, one of
which is precession.
Gyroscopic precession is the
resultant action or deflection of a
spinning object when a force is
applied to this object. This action
occurs approximately 90° in the
direction of rotation from the point
where the force is applied (or 90°
later in the rotation cycle).

Engr SDVM 18
 Coriolis Effect

Engr SDVM Source: https://www.youtube.com/watch?v=0KlNcjEzbUU&ab_channel=FlightFirst 19
 Gyroscopic Precession
The spinning main rotor of a helicopter acts like a
gyroscope.
As such, it has the properties of gyroscopic action, one of
which is precession.

Gyroscopic precession is the resultant
action or deflection of a spinning object when a force is
applied to this object. This action occurs approximately 90°
in the direction of rotation from the point where the force
is applied (or 90° later in the rotation cycle).
Engr SDVM 20
 Autorotation
is the state of flight where the main rotor disk of a helicopter
is being turned by the action of air moving up through the
rotor rather than engine power driving the rotor.

Engr SDVM 21
 Autorotation
Autorotation is permitted mechanically by a freewheeling unit,
which is a special clutch mechanism that allows the main rotor
to continue turning even if the engine is not running.

If the engine fails, the freewheeling unit automatically
disengages the engine from the main rotor allowing the main
rotor to rotate freely.

It is the means by which a helicopter can be landed safely in
the event of an engine failure; consequently, all helicopters
must demonstrate this capability in order to be certified.
Engr SDVM 22
 Autorotation
The spinning main rotor of a helicopter acts like a
gyroscope.
As such, it has the properties of gyroscopic action, one of
which is precession.

Gyroscopic precession is the resultant
action or deflection of a spinning object when a force is
During an autorotation, the upward flow of relative wind
applied to thispermits
object.
the mainThis action
rotor blades to rotateoccurs approximately
at their normal speed. 90°
in the direction of rotation from the point where the force
In effect, the blades are “gliding” in their rotational plane.

is applied (or 90° later in the rotation cycle).
Engr SDVM 23
 VIDEO REFERENCES

HELICOPTER AERODYNAMICS
https://www.youtube.com/playlist?list=PL2tY7KqPLKuRoxnHXr827FUD3yFSF_o-2

Engr SDVM 24