Terms

Question 1

Airfoil

Answer 1

• Shape of a wing or blade of propeller, rotor or turbine as seein in cross-section
• Airfoil-shaped body moved through a fluid(air) produces an aerodynamic force(lift)
• any surface producing more lift than drag when passing thru air

Question 2

Torque

Answer 2

• Momentum of force is the tendency of a force to rotate an object about an axis, fulcrum, or pivot
• Helicopter fuselage tends to rorate in direction opposite rotor blades(Newton’s third law)
• Torque results from rotor being driven by engine power output. Any changes in engine power output brings on corresponding change in torque effect

Question 3

Yaw

Answer 3

• Movement around the yaw axis of a rigid body that changes the direction it is pointing, to the left or right of its direction of motion
• Commonly measured in degrees per second or radians per second.

Question 4

Transmission

Answer 4

• Assembly of parts including the speed-changing gears and the propeller shaft by which the power is transmitted from an engine to a live axle
• Set of complex mechanical gearboxes to convert the high rotation speed of gas turbines into the low speed required to drive main and tail rotors.

Question 5

Aft

Answer 5

• Rear of helicopter

Question 6

Turbine

Answer 6

• Rotary mechanical device that extracts energy from a fluid flow and converts it into useful work.
• A turbine is a turbomachine with at least one moving part called a rotor assembly, which is a shaft or drum with blades attached
• Moving fluid acts on the blades so that they move and impart rotational energy to the rotor
• . Early turbine examples are windmills andwaterwheels.

Question 7

Rotocraft

Answer 7

• Machine deriving lift from rotor blades rotating around a mast
• also know as a rotary-wing aircraft

Question 8

Mast

Answer 8

hollow cynlindrical metal shaft extending up from/driven from transmisson

Question 9

Hub

Answer 9

attachment point for rotor blades at top of mast

Question 10

Main Rotor

Answer 10

• mounted horizontally to a vertical mast to provide vertical lift. Rotates counter-clockwise(US) Clockwise(EU)

Question 11

Tail Rotor

Answer 11

• Newton’s 3rd law: every action has an equal and opposite reaction: creation of torque
• With a single main rotor helicopter, the creation of torque as the engine turns the rotor creates a torque effect that causes the body of the helicopter to turn in the opposite direction of the rotor.
• Tail rotor system creates anti torque to combat this by pushing or puling against the tail

Question 12

Tandem Rotor

Answer 12

• Aka Dual Rotor
• two large twin counter-rotating horizontal rotor system/assemblies for heavy weight machines

Question 13

Coaxial Rotor

Answer 13

• pair of counter-rotating rotors mounted on same mast one above each other.

Question 14

Drive shaft

Answer 14

• powered by main transmission and a gearbox mounted at end of tail boom

Question 15

Gearbox

Answer 15

• provides angled drive for the tail rotor

Question 16

Pitch change links

Answer 16

• adjusted to set the angle of incidence

Question 17

Cyclic

Answer 17

• varies the pitch of the rotor blades throughout each revolution of the main rotor system to create unequal lift(thrust)
• Tilts the rotor disc in a particular direction resulting in helicopter moving in that direction(i.e. cyclic pushed forward pushes rotor disc forward and creates forward thrust)
• can be joystick or teetering bar control system.

Question 18

**Collective **

Answer 18

• Changes pitch angle of all main rotor blades collectively. All blades change equally, increasing/decreasing total lift or thrust
• Result is increase or decrease in altitude or airspeed.
• Variable friction control to prevent inadvertent movement
• Aka collective pitch control

Question 19

Anti-Torque Pedals

Answer 19

• Control direction in which nose is pointed.
• Pedal input changes pitch of tail rotor blades
• Increases/reduces thrust produced by tail rotor and causes nose to yaw in direction of applied pedal.

Question 20

Throttle

Answer 20

• controls power produced by engine connected to rotor via transmission
• Purpose: maintain enough engine power to keep rotor rpm within allowable range to keep rotor producing enough lift for flight
• Twist grip mounted on collective

Question 21

Collective

Answer 21

• Operated w/ left hand
• Changes pitch angle of main rotor blades simultaneously(collectively)
• Increase in collective=increase in pitch angle of all main rotor blades

Question 22

Throttle

Answer 22

• Regulates engine rpms.
• Governor system usually maintains desired rpm instead of manual throttle inputs

Question 23

Governor

Answer 23

• Device that senses rotor and engine rpm and makes necessary adjustments to keep a constant/safe rotor rpm

Question 24

Correlator

Answer 24

• Mechanical connection between collective and engine throttle.
• When collective is raised, power is auto increased.
• Maintains rpm close to desired value but still requires throttle adjustment for fine tuning

Question 25

Cyclic

Answer 25

• Controls forward/rearward, left and right flight
• Total lift force is always perpendicular to the tip-path plane of main rotor
• Cyclic purpose is to tilt tip-path plane in direction of desired horizontal direction
• Rotor disc tilts in same direction as cyclic input

Question 26

Anti Torque Pedals

Answer 26

• control the pitch and therefore the thrust of the tail rotor blades or other antitorque system
• Pedals control pitch angle increase/decrease of tail rotor putting heli in longitudinal trim

Question 27

Thrust

Answer 27

• Forward force produced by rotor.
• Opposes/overcomes drag force
• Generally acts parallel to longitudinal axis
• generated by rotation of main rotor system
• Types: forward, reward, sideward or vertical
• Combined Lift and thrust determine direction of movement for helicopter
• Tail rotor also produces variable thrust and is used to control the Yaw

Question 28

Drag

Answer 28

• Force resisting movement through air.
• Produced when lift is developed
• Overcome by engine powering transmission to turn the rotor
• Always acts parallel to relative wind
  
  • Direction of movement fluid relative to airfoil/aircraft. Opposite direction of movement of airfoil/aircraft.

Question 29

Weight

Answer 29

• rotor system must generate enough lift to overcome

Question 30

Aerodynamic Loads

Answer 30

• banking while maintaining constant altitude causes load factor(G load) to increase
• Aerodynamic forces effect every movement in helicopter=never push limits of your machine

Question 31

Load Factor(G Load)

Answer 31

actual load on the rotor blades at any time divided by normal load(aka gross weight of helicopter)

To overcome increase in G load, more lift must be produced. If extra engine power isn’t available, helicopter either descends or must decelerate to maintain same altitude. Over 30 degree bank G load soars

Turbulent Air also causes large G load:

Question 32

Netwon’s 1st Law

Answer 32

• : Every object in uniform motion remains in that state of motion unless external force(lift) is applied

Question 33

Lift

Answer 33

• Generated when an object changes the direction of flow of a fluid
• When the object and fluid move relative to each other and the object deflects the fluid flow in a direction perpendicular to that flow, the force required to do this work creates and equal and opposite force(lift)
• The flow meeting the leading edge of the airfoil is forced to split over/under the object
  
  • Fluid flow is accelerated above airfoil: Creates area of low pressure to form behind leading edge of the upper surface of airfoil
  • Fluid flow is slowed/stagnated below airfoil: Creates area of low pressure
    • Both fluid flows leave trailing edge of airfoil with a downward
• Bottom Line: as blade spins, it forces air over it’s curved surface then throws it down behind it toward the ground, producing lift(majority of lift). momentum(lift)

Question 34

Angle of Attack

Answer 34

• Angle at which airfoil(rotor blade) meets oncoming airflow(fluid) and vice versa.
• Positive AOA: Symmetrical airfoil must have to generate positive lift
• Zero AOA=no lift
• Negative AOA=Negative Lift

Question 35

Bernouli’s Principle

Answer 35

• As the speed(velocity) of a moving fluid increases, the pressure within the fluid decreases
  
  • Fluid speeds up in direct proportion to reduction in area(venturi effect
• Ventruri Effect: reduction in fluid pressure that results when a fluid flows through a constricted section of pipe
• Conservation of Energy: energy cannot be created/destroyed and amount of energy entering system must also exit

Question 36

Profile Drag

Answer 36

• Frictional Resistance of blades passing through the air.
• Moderate increase with airspeed increase

Question 37

Form Drag

Answer 37

• resultant of turbulent wake causes by separation of airflow from surface of the structure

Question 38

Skin Drag

Answer 38

• surface roughness

Question 39

Induced Drag

Answer 39

• Component of lift that is acting in reward direction. airflow circulation around rotor blade as it creates lift
• Vortex produced by H pres. Area beneath blade joining L pres. Area above at trailing edge And rotor tips
• Vortices deflect airstream downward creating increase in downwash
• Decreases as airspeed increases and increases as airspeed decreases
• Main case of drag at low airspeeds

Question 40

Downwash

Answer 40

• Change in direction of air deflected by aerodynamic action of airfoil while producing lift.

Question 41

Parasite Drag

Answer 41

• Always present when helicopter moves through air
• Cabin, rotor mast, tail, landing gear(i.e non-lifting components)
• Rapid Increases with increasing airspeed
• Main cause of drag at high airspeeds

Question 42

Total Drag

Answer 42

• Sum of Profile, Induced and Parasitic Drag
• Airspeed increase=Parasite drag increase, induced drag decrease, profile drag remains mostly constant with some increase at higher speeds.

Question 43

Blade Span

Answer 43

• the length of the rotor blade from center of rotation to tip of the blade

Question 44

Chord line

Answer 44

• a straight line intersecting leading and trailing edges of the airfoi

Question 45

Chord

Answer 45

• the length of the chord line from leading edge to trailing edge; it is the characteristic longitudinal dimension of the airfoil section

Question 46

Mean camber line

Answer 46

• a line drawn halfway between the upper and lower surfaces of the airfoil

Question 47

Camber

Answer 47

• : curvature of the airfoil

Question 48

Leading Edge

Answer 48

• front edge of airfoil

Question 49

Trailing Edge

Answer 49

• rearmost edge of airfoil

Question 50

Induced Flow

Answer 50

• downward flow of air through rotor disc
• Aka downwash
• Each blade has a decreased AOA due to downwash b/c rotor blade action(pitch change) changes still air to column of descending air.
• Most pronounced during Hover w/ no –wind conditions

Question 51

Relative wind

Answer 51

• Direction of movement fluid relative to airfoil/aircraft.
• Opposite direction of movement of airfoil/aircraft(may not be exact opposite)
• Moves in a parallel but opposite direction to movement of airfoil
• Rotational for rotary wing.

Question 52

Rotational Relative Wind

Answer 52

• rotation of rotor blades as they turn about the mast produces rotational relative wind
• Aka Tip-Path Plane
• Flows opposite physical flightpath of airfoil.
• Highest at blade tips decreasing to zero at axis of rotation(center of mast)

Question 53

Resultant relative wind

Answer 53

• : relative wind modified by induced flow
• Opposite effective flightpath of airfoil rather than physical flightpath(rotational relative wind)
• Serves as ref. plane for dev. Of lift, drag and TAF(total aerodynamic force vectors on airfoil)

Question 54

Angle of attack(AOA)

Answer 54

• angle measured between resultant relative wind and chord line
• Hard to measure b/c it’s a ‘aerodynamic angle’
• Can change with no change in blade pitch angle(AOI)
• Increase in AOA=air flowing over airfoil is diverted over greater distance, results in increase air velocity(more lift)
  
  • Further increase becomes more difficult for air to flow smoothly over top of airfoil(approaches a turbulent pattern)= large increase in Drag/Loss of Lift
• Pilot has little direct control over AOA. Adjust AOA thru normal control manipulation of pitch angle of blades.
  
  • Pitch angle(AOI) increases, AOA increases
• Indirectly changed by Colletive/Cyclic inputs on AOI
• Majority of changes come from change in airspeed and rate of climb/descent

Question 55

Angle of Incidence(AOI)

Answer 55

• angle between chord line of main/tail rotor blade and rotor hub
• AKA Blade pitch angle
• Collective input + cyclic feathering change AOI
• Change in AOI changes AOA which therefore changes lift produced by airfoil
• Zero induced flow means AOA=AOI
• When induced flow, upflow, or airspeed changes relative wind, AOA different AOI
• Easy to measure b/c it’s a ‘mechanical angle’

Question 56

Center of Pressure

Answer 56

• : point along chord line through which all aerodynamic forces are considered to act.
• Pressure variances caused by AOA changes cause center to move along chord line.

Question 57

FlightPath Velocity

Answer 57

speed + direction of airfoil passing thru air.
Rotational velocity +/- a component of directional airspeed

Question 58

Hub

Answer 58

• center point on mast and attaching point for root of blade

Question 59

Root

Answer 59

• inner end of blade that attaches to hub

Question 60

Tip

Answer 60

• farthest outboard section of blade

Question 61

Twist

Answer 61

• change in blade incidence from root to outer blade

Question 62

In Ground Effect(IGE)

Answer 62

• increased efficiency or rotor system by interference of airflow when near ground
• Air pressure is increased acting to decrease downward velocity of air
• Permits relative wind to be more horizontal, lift vector to be more vertical and reduced induced drag
• Smooth hard surfaces=most efficiency produces
• Overall reduces power required to hover IGE

Question 63

Out of Ground effect(OGE)

Answer 63

• efficiency is lost above IGE altitude
• Induced flow velocity is increased=decrease in AOA and decrease in lift
• Downward flow can become so localized that helicopter and locally disturbed air will sink at high rate
• High blade pitch angle required to maintain same AOA in IGE hover but this also creates more drag and therefore requires more power to hover.

Question 64

Symmetrical Airfoil

Answer 64

• : identical upper/lower surfaces
• Produces no lift at zero AOA

Question 65

Non Symmetrical Airfoil

Answer 65

• different upper/lower surfaces
• AKA Cambered
• Greater curvature above chord line than below
• Produces lift at zero AoA
• Advantage: more lift at given AOA then symmetrical, improved lift-to-drag ratio, better stall characteristics
• Disadvantage: Center of Pressure can travel up to 20% of chord line=creates undesirable torque on airfoil structure, and greater production costs

Question 66

Blade Twist

Answer 66

• Because of lift differential due to differing rotational relative wind values along the blade, the blade should be designed with a twist to alleviate internal blade stress and distribute the lifting force more evenly along the blade
• . Blade twist provides higher pitch angles at the root where velocity is low and lower pitch angles nearer the tip where velocity is higher. This increases the induced air velocity and blade loading near the inboard section of the blade.

Question 67

Rotor Blade Angles

Answer 67

• two angles that enable a rotor system to produce lift

Question 68

Critical Angle of Attack

Answer 68

• increases in AOA under CAA will increase lift. Increases in AOA past CAA will produce a stall/rapid decrease in lift.

Question 69

Powered Flight

Answer 69

• Total Lift and thrust forces of a rotor are perpendicular to the tip-path plane(rotational relative wind) or plane of rotation of the rotor

Question 70

Hovering Flight

Answer 70

• Constant control inputs + corrections required
• Cyclic used to eliminate drift in horizontal plane
• Throttle(if not governor controlled) used to control RPM’s
• Collective used to maintain altitude
• Pedals used to control nose direction(heading)
• Lift must equal weight and thrust must equal any wind + tail rotor thrust to maintain position.
• Power must also be sufficient to turn rotors and overcome various drags(mostly induced drag)/frictions involved

Question 71

Translating Tendency(Drift)

Answer 71

• during hovering, single main rotor heli tends to move laterally/sideward in direction of tail rotor thrust

Question 72

Pendular Action

Answer 72

• naturally occurring but can be exaggerated by over controlling. Therefore, Control movements should be smooth and not exaggerated.
• Occurs b/c heli body has mass and is suspended from a single point(rotor mast head)
• Horizontal Stabilizer: levels airframe in forward flight

Question 73

Horizontal Stabilizer

Answer 73

• levels airframe in forward fight

Question 74

Tail Strike

Answer 74

• in reward flight the horizontal stabilizer can press tail downward

Question 75

Centrifugal force

Answer 75

• rotation of rotor system creates cent. Force(inertia) which tends to pull blades straight outward from main rotor hub
• Give blades their rigidity and strength to support Heli

Question 76

Coning

Answer 76

• : during takeoff two major forces are acting at same time
• Centrifugal force acting outward
• Lift acting upward.
• Result is blades assume a slight conical path instead of remaining in plane perpendicular to mast.
• Too low rotor RPM=center. Force becomes smaller and coning angle becomes much larger(i.e. should rpm decrease too much, some point rotor blades could fold up with no change of recovery)

Question 77

Coriolis Effect

Answer 77

• rotating body continue to rotate with same rotational velocity until some external force is applied to change speed of rotation
• Aka law of conservation of angular momentum
• Changes in angular velocity occur as mass of rotating body is move closer(angular acceleration) or farther away(angular deceleration) from axis of rotation. Example: Figure skater on ice
• When rotor blade flaps/cone upward, center of mass of that blade moves closer to axis of rotation and blade acceleration takes place in order to conserve angular momentum

Question 78

Gyroscopic precession

Answer 78

• 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).

Question 79

Vertical Flight

Answer 79

• Increasing the angle of incidence of the rotor blades (pitch) while keeping their rotation speed constant generates additional lift and the helicopter ascends.
• Decreasing the pitch causes the helicopter to descend.

Question 80

Forward Flight

Answer 80

4 forces(lift, drag, thrust, weight) must be in balance
Once the tip-path plane is tilted forward, the total lift-thrust force is also tilted forward. This resultant lift-thrust force can be resolved into two components—lift acting vertically upward and thrust acting horizontally in the direction of flight.
In order to maintain unaccelerated flight, the pilot must understand that with any changes in power or in cyclic movement, the helicopter begins either to climb or to descend
Once straight-and-level flight is obtained, the pilot should make note of the power (torque setting) required and not make major adjustments to the flight controls.

Question 81

Straight and Level Flighta

Answer 81

• : flight w/ constant heading and altitude

Question 82

Forward Flight Airflow

Answer 82

Differs from airflow in hovered flight
Fluid flows opposite aircraft’s flightpath
Fluid velocity=Heli forward speed
The highest velocity of airflow occurs over the right side (3 o’clock position) of the helicopter (advancing blade in a rotor system that turns counterclockwise)
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).

Question 83

Advancing blade

Answer 83

• rotor blade moving in same direction as aircraft
• In forward flight, advancing blade has higher airspeed than retreating blade, creating unequal lift across rotor disc(produces more lift)
• 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.

Question 84

Retreating Blade

Answer 84

• rotor blade moving in opposite direction as aircraft
• 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.

Question 85

Dissymmetry of Lift

Answer 85

• Unequal(differential) lift between advancing and retreating halves of rotor dick causes by different wind flow velocity across each half
• Blades flap and feather automatically as a unit(when on flaps up the other flaps down) to equalize lift across rotor disc via teetering hinge

Question 86

Translational Lift

Answer 86

• Improved rotor(main and tail) efficiency from directional flight
• Efficiency greatly improved with each knot of incoming wind due to vortices left behind as incoming wind enters rotor system producing air flow that becomes more horizontal

Question 87

Effective Translational Lift(ETL)

Answer 87

• During transition from hover to forward @ 16-24 knots
• Rotor system completely outruns the recirculation of old vortices and begins to work in relatively undisturbed air
• The flow of air through the rotor system is more horizontal; therefore, induced flow and induced drag are reduced.
• The AOA is effectively increased, which makes the rotor system operate more efficiently.
• This increased efficiency continues with increased airspeed until the best climb airspeed is reached, and total drag is at its lowest point.
• Once the helicopter is transitioning through ETL, the pilot needs to apply forward and left lateral cyclic input to maintain a constant rotor-disk attitude.

Question 88

Translational Thrust

Answer 88

• Occurs when tail rotor becomes more efficient due to ETL (16-24 knots)
• As the tail rotor works in progressively less turbulent air, this improved efficiency produces more antitorque thrust, causing the nose of the aircraft to yaw left
  
  • Countered with right pedal(decreasing AOA in tail rotor blade)
• as the helicopter achieves ETL, you must reduce tail rotor thrust by pedal input at about the same time that you need to make cyclic adjustments for lateral tracking, acceleration, and climb.

Question 89

Induced Flow

Answer 89

• As the rotor blades rotate, they generate what is called rotational relative wind. This airflow is characterized as flowing parallel and opposite the rotor’s plane of rotation and striking perpendicular to the rotor blade’s leading edge. This rotational relative wind is used to generate lift
• . As rotor blades produce lift, air is accelerated over the foil and projected downward. Anytime a helicopter is producing lift, it moves large masses of air vertically and down through the rotor system
• This downwash or induced flow can significantly change the efficiency of the rotor system. Rotational relative wind combines with induced flow to form the resultant relative wind. As induced flow increases, resultant relative wind becomes less horizontal. Since AOA is determined by measuring the difference between the chord line and the resultant relative wind, as the resultant relative wind becomes less horizontal, AOA decreases.

Question 90

Transverse Flow Effect

Answer 90

• Difference in lift between fore and aft portions of rotor disc caused when induced flow drops to near zero at forward disc area/increases at aft disc area as heli accelerates in forward flight.
• Recognized by increased vibrations of Heli at airspeeds just below ETL on takeoff/landing.
• Cyclic input to left usually counters this.

Question 91

Sideward Flight

Answer 91

• Rotational Relative Wind(aka tip path plane) tilted in direction that flight is desired
• Horizontal(thrust) component now acts sideward with drag acting to opposite side
• Vertical(lift) still acts upward and weight downward
• Very unstable due to Parasitic drag of fuselage + lack of horizontal stabilizer

Question 92

Reward Flight

Answer 92

• Rotational Relative Wind(aka tip path plane) tilted in reward
• Drag acts forward/Thrust reward
• Lift straight up and weight straight down
• Due to position of horizontal stabilizer, tail of heli tends to pitch downward

Question 93

Turning Flight

Answer 93

• In forward flight, the rotor disk is tilted forward, which also tilts the total lift-thrust force of the rotor disk forward. When the helicopter is banked, the rotor disk is tilted sideward resulting in lift being separated into two components. Lift acting upward and opposing weight is called the vertical component of lift. Lift acting horizontally and opposing inertia (centrifugal force) is the horizontal component of lift (centripetal force). [Figure 2-44]
• As the angle of bank increases, the total lift force is tilted more toward the horizontal, thus causing the rate of turn to increase because more lift is acting horizontally. Since the resultant lifting force acts more horizontally, the effect of lift acting vertically is decreased. To compensate for this decreased vertical lift, the AOA of the rotor blades must be increased in order to maintain altitude. The steeper the angle of bank is, the greater the AOA of the rotor blades required to maintain altitude.
• Thus, with an increase in bank and a greater AOA, the resultant lifting force increases and the rate of turn is higher. Simply put, collective pitch must be increased in order to maintain altitude and airspeed while turning. Collective pitch controls the angle of incidence and along with other factors, determines the overall AOA in the rotor system.

Question 94

Autorotation

Answer 94

• Main rotor system being turned by air moving through rotor instead of engine power
• In normal, powered flight, air is drawn into the main rotor system from above and exhausted downward, but during autorotation, air moves up into the rotor system from below as the helicopter descends

Question 95

Freewheeling unit

Answer 95

• separate clutch mechanical component that permits autorotations
• If the engine fails, the freewheeling unit automatically disengages the engine from the main rotor allowing the main rotor to rotate freely