Aviation 1052 Propeller Controls Tutorial PDF

Summary

This document provides high-level information regarding propeller theory and controls from a course in aviation. The document contains an extensive explanation of the concepts involved in propeller propulsion. It provides an informative structure focusing primarily on propeller technology.

Full Transcript

AVIA-1052

1
Previously On AVIA-1052
 Well there is no “previously”, this is our first class together.

 Now this is first class

2
Today On AVIA-1052
 We are going to talk about…
 You guessed it, Propellers
 Some general prop stuff
 Aircraft Propeller Theory
 Basic Propeller Controls

3
Where are we?
 Powerplant (Vol. 2) 7-2 to 7-6 
 Start at
 General
 Stop at
 Propeller Location

 FAA-H-8083-30A, Aviation Maintenance Technician Handbook-General
 FAA-H-8083-31A, Aviation Maintenance Technician Handbook-Airframe Volume 1
 FAA-H-8083-31A, Aviation Maintenance Technician Handbook-Airframe Volume 2
 FAA-H-8083-32A, Aviation Maintenance Technician Handbook-Powerplant Volume 1
 FAA-H-8083-32A, Aviation Maintenance Technician Handbook-Powerplant Volume 2 4
AVIA-1052

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 Powerplant 7-2

Propellers
 the unit that must absorb the power
output of the engine
 Propeller development
 the propeller has passed through
many stages of development
 propeller development has
encouraged many changes as
propulsion systems have evolved
 the first propellers were fabric-
covered sticks
 Designed to force air in a rearward
direction

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 Powerplant 7-2

Propellers
 propellers started as simple two-bladed wood
propellers
 have advanced to the complex propulsion
systems of turboprop aircraft that involve
more than just the propeller
 more complex propellers
 a variable-pitch, constant-speed feathering
and reversing propeller system
 allows the engine rpm to be varied only
slightly during different flight conditions
 increases flying efficiency

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 Powerplant 7-2

Propellers
 constant-speed systems
 a basic constant-speed system consists of:
 a flyweight-equipped governor unit that
controls the pitch angle of the blades so
that the engine speed remains constant

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 Powerplant 7-2

Propellers
 a flyweight-equipped governor unit
 that controls the pitch angle of the blades so
that the engine speed remains constant
 can be regulated by controls in the cockpit so
that any desired blade angle setting, and
engine operating speed can be obtained at
 takeoff
 low-pitch
 high-rpm setting
 flight
 higher pitch
 lower rpm setting

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 Powerplant 7-2

Propellers
 This figure shows normal propeller movement with the positions of
 low pitch
 high pitch
 Feather-used if the engine quits to reduce drag
 zero pitch into negative pitch-reverse pitch

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 Powerplant 7-2

Common Propeller Types
 Propellers

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 Powerplant 7-2

Propellers
 most propellers are two-bladed
 great increases in power output have
resulted in the development of
 four-bladed propellers
 six-bladed propellers of large
diameters

 all propeller-driven aircraft are limited by
the revolutions per minute (rpm) at which
propellers can be turned

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 Powerplant 7-2

Propellers
 forces acting on the propeller as it turns
 centrifugal force
 tends to pull the blades out of the hub at high rpm
 blade weight is very important to the design of a propeller

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 Powerplant 7-2

Propellers
 excessive blade tip speed
 rotating the propeller too fast may result in
 poor blade efficiency
 fluttering
 vibration

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 Powerplant 7-2

Propellers
 since the propeller speed is limited, the aircraft speed of a propeller driven aircraft is also
limited approximately 400 miles per hour (mph) (644 kilometers per hour)
 as aircraft speeds increased, turbofan engines were used for higher speed aircraft

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 Powerplant 7-2

Propellers
 propeller-driven aircraft have several
advantages
 takeoff and landing can be
 shorter
 less expensive to maintain
 new blade materials and manufacturing
techniques have increased the efficiency of
propellers
 widely used for applications in
 turboprops
 reciprocating engine installations
 many smaller aircraft will continue to use
propellers well into the future

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 Powerplant 7-2

Propellers
 propeller systems
 many different types of propeller
systems have been developed for
 specific aircraft installation
 speed
 type of operation

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 Powerplant 7-2

Propellers
 diagrams
 basic nomenclature of the parts of a simple
fixed-pitch, two-bladed wood propeller

 aerodynamic cross-section of a blade (next slide)
 includes terminology to describe certain areas
shown

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 Powerplant 7-2

Propellers
 aerodynamic cross-section of a blade

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AVIA-1052

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 Powerplant 7-2

Basic Propeller Principles
 the aircraft propeller consists of:
 two or more blades
 each blade is essentially a rotating
wing
 produce forces that create thrust to
pull or push the airplane through the
air
 the power needed to rotate the
propeller blades is furnished by the
engine
 a central hub to which the blades are
attached

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 Powerplant 7-3

Basic Propeller Principles
 mounted on a shaft
 low-horsepower engines
 which may be an extension of the
crankshaft
 high-horsepower engines
 mounted on a propeller shaft that is
geared to the engine crankshaft
 the engine rotates the airfoils of
the blades through the air at high
speeds
 the propeller transforms the rotary
power of the engine into thrust

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 Powerplant 7-3

Propeller Aerodynamic Process
 an airplane moving through the air creates a drag force
 opposing its forward motion
 there must be a force applied to it that is equal to the drag
but acting forward
 if an airplane is to fly on a level path this force is called
thrust
 the work done by thrust is equal to the thrust times the
distance it moves the airplane
 work = thrust × distance
 the power expended by thrust is equal to the thrust times
the velocity at which it moves the airplane
 power = thrust × velocity

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 Powerplant 7-3

Propeller Aerodynamic Process
 the power expended by the thrust is termed
thrust horsepower if the power is measured in
horsepower units
 the engine supplies brake horsepower
through a rotating shaft
 the propeller converts it into thrust
horsepower
 some power is wasted in this conversion
 the propeller must be designed to keep
this waste as small as possible for
maximum efficiency
 (image to the right is for a boat prop)

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 Powerplant 7-3

Propeller Aerodynamic Process
 propeller efficiency is the ratio of thrust horsepower to brake horsepower
since the efficiency of any machine is the ratio of the useful power output to
the power input
the usual symbol for propeller efficiency is the Greek letter η (eta)

 propeller efficiency varies from 50-87% depending on how much the propeller slips

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 Powerplant 7-3

Propeller Aerodynamic Process
 pitch is not the same as blade angle
 because pitch is largely determined by blade angle
 the two terms are often used interchangeably
 an increase or decrease in one is usually
associated with an increase or decrease in the
other
 blade angle
 the angle between the face or chord/
chord line of a blade section and the
plane in which the propeller rotates
 usually measured in degrees

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 Powerplant 7-3

Propeller Aerodynamic Process
 geometric pitch
 is the distance a propeller should advance in one revolution with no slippage
 usually expressed in pitch inches
 calculated by using the following formula:
 GP = 2 × π R × tangent of blade angle at 75% station
 R = Radius at the 75% blade station
 π = 3.14
 based on no slippage

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 Powerplant 7-3

Propeller Aerodynamic Process
 effective pitch
 is the distance it advances
 recognizes propeller slippage in the air
 propeller slip is the difference between the geometric pitch of the propeller and its effective
pitch
 geometric pitch – effective pitch = slip

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 Powerplant 7-3

Propeller Aerodynamic Process
 the chord line of the propeller blade is determined in about the same manner as the chord
line of an airfoil
 a propeller blade can be considered as being composed of an infinite number of thin
blade elements
 each of which is a miniature airfoil section whose chord is the width of the propeller blade
at that section
 the chord line is often drawn along the face of the propeller blade because most
propellers have a flat blade face

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 Powerplant 7-3

Propeller Aerodynamic Process
 the typical propeller blade can be described as a twisted airfoil of irregular planform
 a blade can be divided into segments that are located by station numbers in inches from
the center of the blade hub
 for purposes of analysis

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 Powerplant 7-4

Propeller Aerodynamic Process
 the cross-sections of each
6-inch blade segment are
shown as airfoils on the
right side

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 Powerplant 7-4

Propeller Aerodynamic Process
 also identified are:
 blade shank
 thick, rounded portion of the propeller blade
 near the hub
 designed to give strength to the blade

 blade butt
 also called the blade base or root
 the end of the blade that fits in the propeller hub

 blade tip
 part of the propeller blade farthest from the hub
 generally defined as the last 6 inches of the blade

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 Powerplant 7-4

Propeller Aerodynamic Process
 this section or blade element is an airfoil comparable to a cross-section of an aircraft wing
 blade back
 cambered or curved side of the blade
 like the upper surface of an aircraft wing

 blade face
 flat side of the propeller blade

 chord line
 an imaginary line drawn through the blade from the leading edge to the trailing edge

 leading edge
 thick edge of the blade that meets the air as the propeller rotates

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 Powerplant 7-4

Propeller Aerodynamic Process
 the principal forces acting on a rotating
propeller
 centrifugal force
 a physical force
 tends to throw the rotating propeller
blades away from the hub
 the most dominant force on the propeller

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 Powerplant 7-4

Propeller Aerodynamic Process
 torque bending
 tends to bend the propeller blades in the
direction opposite that of rotation
 in the form of air resistance

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 Powerplant 7-4

Propeller Aerodynamic Process
 thrust bending
 loads that tends to bend propeller blades
forward as the aircraft is pulled through
the air
 at least two of these forces acting on the
propeller's blades are used to move the
blades
 on a controllable pitch propeller
 centrifugal twisting
 aerodynamic twisting

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 Powerplant 7-4

Propeller Aerodynamic Process
 aerodynamic twisting
 tends to turn the blades to a high blade angle
 used to move the blades into high pitch

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 Powerplant 7-4

Propeller Aerodynamic Process
 a rotating propeller is acted upon by:
 centrifugal twisting
 greater than the aerodynamic
twisting force
 tends to force the blades toward a
low blade angle
 sometimes used to move the
blades to the low pitch position

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 Powerplant 7-4

Propeller Aerodynamic Process
 a propeller must be capable of withstanding severe
stresses
 greater near the hub
 caused by centrifugal force and thrust
 increase in proportion to the rpm
 the blade face is also subjected to tension from:
 the centrifugal force
 the bending
 nicks or scratches on the blade may cause very
serious consequences
 these could lead to:
 cracks
 failure of the blade

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 Powerplant 7-4

Propeller Aerodynamic Process
 a propeller must also be rigid enough to
prevent fluttering
 a type of vibration
 the ends of the blade twist back and forth
at high frequency around an axis
perpendicular to the engine crankshaft
 the constant vibration tends to weaken
the blade and eventually causes failure
 accompanied by a distinctive noise
 often mistaken for exhaust noise

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 Powerplant 7-4

Aerodynamic Factors
 consider first its motion
 to understand the action of a propeller
 which is both rotational and forward
 a section of a propeller blade moves downward and forward

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 Powerplant 7-4

Aerodynamic Factors
 the result is the same as if the blade were
stationary and the air coming at it from a
direction opposite its path
 as far as the forces are concerned, the
angle at which this air (relative wind)
strikes the propeller blade is called angle of
attack(AOA)
 the air deflection produced by this angle
causes the dynamic pressure at the engine
side of the propeller blade to be greater
than atmospheric pressure, therefore
creating thrust

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 Powerplant 7-4

Aerodynamic Factors
 the shape of the blade also creates thrust
 because it is shaped like a wing, as the air flows past the
propeller, the pressure on one side is lower than the
pressure on the other side
 this difference in pressure produces a reaction force in
the direction of the lesser pressure
 Example: the area above a wing has less pressure, the
force (lift) is upward
 the area of decreased pressure is in front of a propeller
which is mounted in a vertical instead of a horizontal
position
 the force (thrust) is in a forward direction
 thrust is the result of the propeller shape and the
AOA of the blade aerodynamically
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 Powerplant 7-4

Aerodynamic Factors
 another way to consider thrust is in terms of the mass of air handled
 thrust = the mass of air handled x the slipstream velocity - the velocity of the airplane
 in these terms, the power expended in producing thrust depends on the mass of air
moved per second

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 Powerplant 7-4

Aerodynamic Factors
 the amount of air displaced (moved) depends on the blade angle
 for any single revolution of the propeller which determines the quantity or amount of
mass of air the propeller moves, the blade angle is an excellent means of adjusting the
load on the propeller to control the engine rpm
 if the blade angle is increased, more load is placed on the engine tending to slow it down
unless more power is applied

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 Powerplant 7-4

Aerodynamic Factors
 thrust constitutes approximately 80% of the torque
 total horsepower absorbed by the propeller balances the horsepower delivered by the
engine for any speed of rotation
 the other 20% is lost in friction and slippage

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 Powerplant 7-4

Aerodynamic Factors
 as an airfoil is moved through the air, it
produces two forces:
 lift and drag
 increasing propeller blade angle:
 increases the AOA
 produces more lift and drag
 increases the horsepower required to turn
the propeller at a given rpm
 slows the propeller down (since the engine
is still producing the same horsepower)

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 Powerplant 7-4

Aerodynamic Factors
 decreasing propeller blade angle:
 speeds the propeller up
 the engine rpm can be controlled by increasing or decreasing the blade angle
 lift versus drag curves drawn for:
 propellers
 wings

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 Powerplant 7-4

Aerodynamic Factors
 indicate that the most efficient AOA is a
small one varying from 2° to 4° positive
 the actual blade angle necessary to
maintain this small AOA varies with the
forward speed of the airplane
 due to a change in the relative wind
direction which varies with aircraft
speed

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 Powerplant 7-4

Aerodynamic Factors
 the blade angle
 an excellent method of adjusting the AOA of
the propeller
 the blade angle must be adjusted to provide
the most efficient AOA at all engine and
airplane speeds on constant-speed propellers
 fixed-pitch and ground-adjustable propellers
are designed: for best efficiency at:
 One rotation speed
 One forward speed

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 Powerplant 7-4

Aerodynamic Factors
 to fit a given airplane and engine
combination, a propeller may be
used that provides the maximum
propeller efficiency for:
takeoff
climb
cruising
high speeds
 any change in these conditions
results in lowering the efficiency
of both the propeller and the
engine

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 Powerplant 7-4

Aerodynamic Factors
 A constant-speed propeller keeps the blade angle adjusted for maximum efficiency for most
conditions encountered in flight
 during takeoff, when maximum power and thrust are required:
 the constant-speed propeller is at a low propeller blade angle or pitch
 the low blade angle keeps the AOA small and efficient with respect to the relative wind
 it allows the propeller to handle a smaller mass of air per revolution

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 Powerplant 7-4

Aerodynamic Factors
 this light load allows the engine to turn at high rpm and to convert the maximum amount of
fuel into heat energy
 the high rpm also creates maximum thrust
 the engine rpm is high
 the slipstream velocity (air coming off the propeller) is high
 the thrust is maximum with the low airplane speed

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 Powerplant 7-6

Aerodynamic Factors
 after liftoff, as the speed of the airplane
increases
 the constant-speed propeller changes
to a higher angle (or pitch)
 the higher blade angle keeps the AOA
small and efficient with respect to the
relative wind
 the higher blade angle increases the
mass of air handled per revolution
 this decreases the engine rpm,
reducing fuel consumption and engine
wear, and keeps thrust at a maximum

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 Powerplant 7-6

Aerodynamic Factors
 for climb after takeoff
 the power output of the engine is reduced to climb power by decreasing the manifold
pressure and increasing the blade angle to lower the rpm
 the torque (horsepower absorbed by the propeller) is reduced to match the reduced
power of the engine
 the AOA is kept small by the increase in blade angle
 the greater mass of air handled per second is more than offset by the lower slipstream
velocity and the increase in airspeed

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 Powerplant 7-6

Aerodynamic Factors
 at cruising altitude, when the airplane is in level flight and less power is required than is
used in takeoff or climb
 engine power is reduced by lowering the manifold pressure and increasing the blade
angle to decrease the rpm
 this reduces torque to match the reduced engine power
 it is more than offset by a decrease in slipstream velocity and an increase in airspeed
 the AOA is still small because the blade angle has been increased with an increase in
airspeed

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 Powerplant 7-6

Aerodynamic Factors
 pitch distribution is the twist in the blade from the shank to the blade tip, due to the
variation in speeds that each section of the blade is traveling
 the tip of the blade is traveling much faster than the inner portion of the blade

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AVIA-1052

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Propeller Controls and Instruments
 https://youtu.be/0bP2MH3LqvI
 The Propeller Explained (24.04)

 https://www.youtube.com/watch?v=GNsnXjxopJM
 ConstantSpeedPropPart1 (14:23)
Landed valve=pilot valve=spool valve

 https://youtu.be/-KyxxrEJBH0
 HOW PROPELLERS ARE MADE: Hartzell Propeller (8:42)

 https://youtu.be/HHXlhJlPqKg
 She is a Builder! Wood Worker! Prop Maker! Machinist! (36:40)
 https://www.youtube.com/c/CulverProps

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 Powerplant 7-6

Propeller Controls and Instruments
 fixed pitch propellers:
 have no controls
 require no adjustments in flight
 constant-speed propellers:
 have a propeller control in the center
pedestal between the throttle and the
mixture control (typically a blue knob)

 the two positions for the control
are:
 increase rpm
 (full forward)
 decrease rpm
 (pulled aft)
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 Powerplant 7-6

Propeller Controls

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 Powerplant 7-6

Propeller Controls and Instruments
 Controls are directly connected to the propeller governor and adjusts the tension on the
governor speeder spring by moving the control
 can be used to feather the propeller in some aircraft by moving the control to the full
decrease rpm position
 controls rotations per minute (rpm)

 the two main instruments used are:
 the engine tachometer
 the manifold pressure gauge
 adjusted by the throttle

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 Powerplant 7-6

Speed Sensing
 tachometer generator
 measures the rotational rate of a shaft
using an internally generated electrical
signal
 reference signal or voltage is generated by
rotating the generator's internal
mechanism
 generated alternating current (AC) is then
read by tachometer circuitry and
displayed

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