3.-Rotor-Configuration-Flight-Controls_1599253909.pdf

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BASIC
HELICOPTER
& PROPELLER
DESIGN
Rotor system, rotor configuration and flight controls

Prepared By Engr. Shiara Denise M. Valencia
Rotor
System
The helicopter rotor system is the rotating part of a
helicopter that generates lift.

A rotor system may be mounted:
- horizontally, as main rotors are, providing lift vertically;
- vertically, such as a tail rotor, to provide lift horizontally
as thrust to counteract torque effect.
 For TILT ROTORS, the rotor is m ounted on a nacelle
that rotates at the edge of the wing to transition the rotor
from a horizontal mounted position, providing lift
horizontally as thrust, to a vertical mounted position
providing lift exactly as a helicopter.
 The swash plate assembly consists of two parts — the
upper and lower swash plates.

The upper swash plate connects to the mast, or rotor shaft,
through special linkages. As the engine turns the rotor shaft,
it also turns the upper swash plate and the rotor blade
system.

The lower swash plate is fixed and doesn't rotate. Ball
bearings lie between the upper and lower swash plates,
allowing the upper plate to spin freely on top of the lower
plate.
Control rods from the upper swash plate have a connection
point on the blades, making it possible to transfer
movements of the upper swash plate to the blades.

Control rods attached to the
lower swash plate connect to
the cyclic- and collective-pitch
levers.
Blade grips connect
the blades to a hub.
ROTOR BLADE MOVEMENTS
Main rotor systems are classified according to how the main rotor
blades are attached and move relative to the main rotor hub.

FEATHER

FLAP

LEAD - LAG
ROTOR BLADE MOVEMENTS
LEAD – LAG
FEATHER FLAP
DRAG
ROTOR BLADE MOVEMENTS
Blade Flap

The ability of the rotor blade to move in a vertical direction. Blades
may flap independently or in unison.

Blade lead or lag

The fore and aft movement of the blade in the plane of rotation. It is
sometimes called hunting or dragging.

Feathering

The action that changes the pitch angle of the rotor blades by rotating
them around their feathering (spanwise) axis.
CLASSIFICATION OF ROTOR
SYSTEM
Main rotor systems are classified according to how the main rotor
blades are attached and move relative to the main rotor hub.

rigid

semirigid

fully articulated
CLASSIFICATION OF ROTOR SYSTEM
Semi rigid

A semirigid rotor system is usually composed of two
blades that are rigidly attached to the main rotor
hub. The main rotor hub is free to tilt with respect
to the main rotor shaft on what is known as a
teetering or flapping hinge. This allows the blades
to flap together as a unit. As one blade flaps up,
the other flaps down.
CLASSIFICATION OF ROTOR SYSTEM
Semi rigid

The teetering hinge
allows the main rotor to
tilt.

The feathering hinge
enables the main rotor
angle’s to change.
CLASSIFICATION OF ROTOR SYSTEM
rigid

the blades are rigidly attached to the rotor hub.
They cannot flap or lead-lag, but they can be
feathered. rigid rotor systems may become more
common because the system is fundamentally easier
to design and offers the best properties of both
semirigid and fully articulated systems.
CLASSIFICATION OF ROTOR SYSTEM
rigid

The rigid rotor system is very responsive and is
usually not susceptible to mast bumping like the
semirigid systems because the rotor hubs are
mounted solid to the main rotor mast. This allows
the rotor and fuselage to move together as one
entity and eliminates much of the oscillation
usually present in the other rotor systems.
CLASSIFICATION OF ROTOR SYSTEM
CLASSIFICATION OF ROTOR SYSTEM
rigid
CLASSIFICATION OF ROTOR SYSTEM
rigid
CLASSIFICATION OF ROTOR SYSTEM
Fully articulated

Fully articulated rotor systems allow each blade
to lead-lag (move back and forth in plane), flap
(move up and down about an inboard mounted hinge)
independent of the other blades, and feather rotate
about the pitch axis to change lift).
CLASSIFICATION OF ROTOR SYSTEM
Fully articulated
CLASSIFICATION OF ROTOR SYSTEM
Fully articulated
CLASSIFICATION OF ROTOR SYSTEM
Fully articulated
Flight
Controls
FLIGHT CONTROLS
FLIGHT CONTROLS
COLLECTIVE

The collective, operated
by the pilot with the left
hand, is pulled up or
pushed down to increase
or decrease the angle of
attack on all of the rotor
blades simultaneously. This
increases or decreases
lift and moves the
aircraft up or down.
FLIGHT CONTROLS
COLLECTIVE

Collective
changes the pitch
angle of all the
main rotor blades
collectively.
FLIGHT CONTROLS
THROTTLE

The engine
throttle control
is located on the
hand grip at the
end of the
collective.
FLIGHT CONTROLS
THROTTLE

The throttle controls the
power produced by the
engine, which is connected to
the rotor by a transmission.

The purpose of the throttle
is to maintain enough engine
power to keep the rotor rpm
within allowable limits to
produce enough lift for
flight.
FLIGHT CONTROLS
CYCLIC

The cyclic is the
control “stick” located
between the pilot’s
legs. It can be moved
in any direction to tilt
the plane of rotation
of the rotor blades.
This causes the
helicopter to move in
the direction that the
cyclic is moved.
FLIGHT CONTROLS
CYCLIC
The control is called the
cyclic because it can vary
the pitch of the rotor
blades throughout each
revolution of the main
rotor system (i.e., through
each cycle of rotation) to
develop unequal lift
(thrust).
FLIGHT CONTROLS
FOOT PEDALS

The foot pedals
control the pitch
of the tail rotor
blades thereby
balancing main
rotor torque
FLIGHT CONTROLS
HELICOPTER
FLIGHT CONTROLS
FLIGHT CONTROLS