Aerodynamics 1

Question 1

Define Scalar

Answer 1

A quantity expressing only magnitude (e.g. Time, amount of money, volume of a body)

Question 2

Define Vector

Answer 2

A quantity the expresses both magnitude and direction. A vector quantity is represented by an arrow that displays direction and has a length proportional to magnitude.

Question 3

Define Mass

Answer 3

(m) The quantity of molecular material that comprises an object

Question 4

Define Volume

Answer 4

The size of the mass, or the amount of space occupied by an object

Question 5

Define Density

Answer 5

(ρ) Mass per unit volume

Question 6

Define Force

Answer 6

Mass times Acceleration; A vector quantity equal to the push or pull exerted on a body. By Newton’s second law, a force is a function of an acceleration and the mass of the body.

Question 7

Define Weight

Answer 7

The force at which a mass is attracted toward the center of the earth by gravity

Question 8

Define Moment

Answer 8

A tendency to cause rotation around a point or axis, as a control surface around its hinge or an airplane around its center of gravity; the measure of this tendency, equal to the product of the force and perpendicular distance between the point of rotation and the direction of the force., expressed as a vector. Also called torque.

Question 9

Define Work

Answer 9

(W) Work is done when a force acts on a body and it moves. Work is a scalar quantity measured in ft.-lbs. W=F x s

Question 10

Define Power

Answer 10

(P) The rate of doing work, or work per unit time. Measured in ft.-lbs./sec or horsepower.

Question 11

Define Energy

Answer 11

The ability or capacity to do work. Expressed in ft.-lbs.

Question 12

Define Potential Energy

Answer 12

(PE) The ability of a body to do work because of its position or physical state.

Question 13

Define Kinetic Energy

Answer 13

(KE) The ability of a body to do work because of its motion.

Question 14

Explain Newton’s Law of Equilibrium

Answer 14

Newton’s First Law. “A body at rest tends to remain at rest and a body in motion tends to remain in motion in a straight line at a constant velocity unless acted upon by some unbalanced force.”

Question 15

State the requirements for an airplane to be in equilibrium flight

Answer 15

Equilibrium flight exists when the sum of all forces and the sum of all moments around the center of gravity are equal to zero. This may occur during straight and level, climbing, or descending flight so long as there is no change in flight path.

Question 16

State the requirements for an airplane to be in trimmed flight

Answer 16

Trimmed flight exists when the sum of all moments around the center of gravity is equal to zero. The sum of all forces around the center of gravity may not be equal to zero. This may occur in a constant rate turn.

Question 17

Explain Newton’s Law of Acceleration

Answer 17

Newton’s Second Law. “An unbalanced force (F) acting on a body produces an acceleration (a) in the direction of the force that is directly proportional to the force and inversely proportional to the mass (m) of the body.” equation: a=F/m. (e.g. when the airplanes thrust is greater than its drag, the excess thrust will accelerate the airplane until drag increases to equal thrust)

Question 18

Explain Newton’s Law of Interaction

Answer 18

Newton’s Third Law. “For every action there is an equal and opposite reaction; the forces of two bodies on each other are always equal and are directed in opposite directions.” (e.g. The rearward force from a propeller’s propwash causes an aircraft to move forward with an equal amount of force)

Question 19

Define Static Pressure

Answer 19

(Ps) The weight of a column of air over a given area; the pressure each air particle exerts on another due to the weight of all the particles above; the potential energy per unit volume.

Question 20

Define Air Density

Answer 20

(ρ) The total mass of air particles per unit volume

Question 21

Define Temperature

Answer 21

A measure of the average kinetic energy of air particles, expressed in degrees (°C), Fahrenheit (°F), or Kelvin (K).

Question 22

Define Lapse Rate

Answer 22

The rate that temperature decreases as you increase in altitude. (usually 2 °C per 1000 ft until about 36,000 ft) From about 36,000 ft through 66,000 feet the air remains at a constant -56.5 °C. This is called the isothermal layer.

Question 23

Define Humidity

Answer 23

The amount of water vapor in the air

Question 24

Describe the relationship between humidity and air density

Answer 24

As humidity increases, density decreases. This is because water molecules have less mass but displace the same number of air molecules.

Question 25

Define Viscosity

Answer 25

(µ) A measure of a fluid’s resistance to flow and shearing.

Question 26

Describe the relationship between temperature and viscosity

Answer 26

Air viscosity increases when temperature increases.

Question 27

Define local speed of sound

Answer 27

The rate at which sound waves travel through a particular air mass.

Question 28

Describe the relationship between temperature and local speed of sound

Answer 28

As air temperature increases, the speed of sound increases.

Question 29

State the values for standard atmosphere

Answer 29

• Static Pressure (Ps0) = 29.92 in. Hg. (1013.25 mbar)
• Temperature (T0) = 59 °F (15 °C)
• Average Lapse Rate = 3.57 °F / 1000 ft. (2°C / 1000 ft)

Question 30

Describe the General Gas Law, given static pressure, air density, temperature, and altitude

Answer 30

The standard gas law sets the relationship between the three properties of air: pressure (P), density (ρ), and temperature (T). R is the constant for any given gas. P=ρRT (e.g. if density remains constant and temperature increases, then pressure will increase)

Question 31

Explain Bernoulli’s Equation, given dynamic pressure, static pressure, and total pressure

Answer 31

Bernoulli’s equation explains the variation of pressure exerted by a moving mass of fluid. His equation shows that the total energy of a fluid can be separated into potential energy (static pressure) and kinetic energy (dynamic pressure). Total pressure (H or Pt) = static pressure (Ps) + dynamic pressure (q). (Dynamic pressure = 1/2 density (ρ) x velocity (V) squared.)

Question 32

Define Steady Airflow

Answer 32

Airflow in which at every point in the moving air mass, the pressure, density, temperature and velocity are constant.

Question 33

Define Streamline

Answer 33

The path traced by a particle of air while in steady flow

Question 34

Define Streamtube

Answer 34

An impenetrable tube formed by many streamlines. Streamtubes are closed systems.

Question 35

Explain the continuity equation given density, cross-sectional area, and velocity

Answer 35

The amount of mass passing any point in the streamtube may be found by multiplying area by velocity to give volume/unit time and then multiplying by density to give mass/unit time. This is called Mass flow rate (Ṁ) and is expressed as Ṁ=ρAV. In subsonic airflow we can ignore changes in density due to compressibility. The mount of mass flowing through any given section of the streamtube must be equal, therefore if area decreases, velocity increase. A1V1=A2V2.

Question 36

Define Indicated Altitude

Answer 36

The indication on a pressure altimeter when the Kollsman window is set to the current local altimeter setting.

Question 37

Define Above Ground Level (AGL) altitude

Answer 37

The height of a point measured from the earth’s surface directly below it.

Question 38

Define Mean Sea Level (MSL) altitude

Answer 38

The height of a point measured from mean sea level. (Also known as True Altitude)

Question 39

Define Pressure Altitude

Answer 39

The height above the standard datum plane. The standard datum plane is the actual elevation at which the barometric pressure is 29.92 in.Hg. (In a standard atmosphere, Pressure altitude equals true altitude)

Question 40

Define Density Altitude

Answer 40

The altitude in the standard atmosphere where the air density is equal to the local air density. It is found by correcting pressure altitude for temperature and humidity deviations from the standard atmosphere.

Question 41

Describe the pitot-static system given the system components and Bernoulli’s equation

Answer 41

Using Bernoulli’s equation, dynamic pressure (q), relating to airspeed, can be calculated by measuring the total and static pressure acting on the aircraft. The pitot-static system consists of a pitot tube that sense total pressure (H or Pt), and a static port that senses static pressure (Ps). H=Ps+1/2ρV^2, By rearranging this equation, we may find velocity.

Question 42

Define Indicated Airspeed

Answer 42

Indicated airspeed is the actual instrument indication of the dynamic pressure the airplane is exposed to during flight. This may be significantly different then actual flight speed due to altitude, and installation or instrument error.f

Question 43

Define Calibrated Airspeed

Answer 43

Indicated airspeed corrected for instrument error.

Question 44

Define Equivalent Airspeed

Answer 44

The true airspeed at sea level on a standard day that produces the same dynamic pressure as the actual flight condition. It is found by correcting calibrated air speed for compressibility error.

Question 45

Define True Airspeed

Answer 45

The actual velocity at which an airplane moves through an air mass. It is found by correcting equivalent airspeed for the difference between the local air density and the density of the air at sea level on a standard day.

Question 46

Define Ground Speed

Answer 46

The airplane’s actual speed over the ground. If we correct true airspeed for wind, we get ground speed.

Question 47

Describe the factors affecting the different types of airspeed

Answer 47

• Indicated airspeed (IAS) is affected by altitude, compressibility effects, instrument error, and installation error.
• Calibrated airspeed (CAS) Is affected by altitude and compressibility effects.
• Equivalent Airspeed (EAS) is affected by altitude.
• True Airspeed (TAS) is the actual speed of the aircraft moving through an air mass.
• Ground speed (GS) is affected by wind.

Question 48

Define an aircraft

Answer 48

Any device used or intended to be used for flight in the air.

Question 49

Define an airplane

Answer 49

An engine driven, heavier-than-air, fixed wing aircraft that is supported by the dynamic reaction of airflow over its wings.

Question 50

Describe the five components of an airplane

Answer 50

• Fuselage: basic structure of the airplane to which all other components are attached
• Wing: an airfoil attached to the fuselage designed to produce lift
• Empennage: the assembly of the stabilizing and control surfaces on the tail of the airplane
• Landing Gear: permits ground taxi operations and absorbs the shock encountered during takeoff and landing
• Engine: provides thrust necessary for powered flight

Question 51

State the advantages of the semi-monocoque fuselage construction

Answer 51

The semi-monocoque fuselage is lightweight and is easier to repair than a monocoque fuselage. The T-6B uses a semi-monocoque fuselage

Question 52

Define full cantilever wing construction

Answer 52

All bracing is internal to the wing. T-6B wings are full cantilever.

Question 53

Describe the airplane three-axis reference system

Answer 53

• longitudinal axis: passes from nose to tail;
  
  • movement about this axis is called roll.
  • control surface: Ailerons
• lateral axis: passes from wingtip to wingtip;
  
  • movement about this axis is called pitch.
  • control surface: Elevator
• vertical axis: passes vertically through the center of gravity;
  
  • movement about this axis is called yaw.
  • control surface: Rudder

Question 54

Define chord line

Answer 54

An infinitely long straight line that passes through the leading and trailing edges.

Question 55

Define chord

Answer 55

The precise measurement between the leading and trailing edges along the chord line.

Question 56

Define root chord

Answer 56

The chord measured at the wing centerline.

Question 57

Define tip chord

Answer 57

The chord measured at the wingtip.

Question 58

Define average chord

Answer 58

The average of every chord from the wing root to the wing tip.

Question 59

Define mean camber line

Answer 59

The locus of points halfway between the upper and lower surfaces, measured perpendicular to the mean chamber line itself.

Question 60

Define symmetric airfoil

Answer 60

An airfoil in which the mean camber line is coincident with the chord line. Also called a zero camber airfoil.

Question 61

Define positive chamber

Answer 61

An airfoil in which the mean camber line is above the chord line

Question 62

Define negative camber

Answer 62

An airfoil in which the mean camber line is below the chord line.

Question 63

Define spanwise flow

Answer 63

Airflow that travels the span of the wing, parallel to the leading edge, normally root to tip. This airflow is not accelerated over the wing and therefore produces no pressure differential or lift.

Question 64

Define chordwise flow

Answer 64

Airflow perpendicular to the leading edge of an airfoil; airflow along the chord of an airfoil. Since chordwise flow is accelerated over a wing, it produces lift.

Question 65

Define pitch attitude

Answer 65

(θ) The angle between the longitudinal axis of the airplane and the horizon.

Question 66

Define flight path

Answer 66

(FP) The path described by an airplanes center of gravity as it moves through an air mass.

Question 67

Define relative wind

Answer 67

(RW) The airflow experienced by the aircraft as it flies through the air. It is always equal and opposite to the flightpath. The relative wind may arise from the motion of the body, from the motion of the air, or from both.

Question 68

Define angle of attack

Answer 68

(AOA, α) The angle formed between the relative wind and the chord line of the airfoil.

Question 69

Define angle of incidence

Answer 69

The angle between the airplane’s longitudinal axis and the chord line of its wing. The root chord is commonly chosen to measure the angle of incidence.

Question 70

Define Dihedral angle

Answer 70

The angle between the spanwise inclination of a wing and the lateral axis. It is the upward slope of the wing when viewed from head on. A negative dihedral is called anhedral.

Question 71

Define Wingspan

Answer 71

(b) The length of a wing, measured from wingtip to wingtip. Also called span. The wingspan of the T-6B is 33’5”

Question 72

Define Wing area

Answer 72

(S) The surface area of a wing from wingtip to wingtip. The area within the outline of a projection of a wing on the plane of its chord, including that area lying within the fuselage or nacelles. With a swept wing, the area within the fuselage is contained within lines having the same sweep angles as the leading and trailing edges, fairings or fillets being ignored.

Question 73

Define wing loading

Answer 73

(WL) A ratio of airplane weight to the wing surface area.

Question 74

Define taper ratio

Answer 74

(λ) The ratio of tip chord to root chord. The ratio affects the lift distribution and the structural weight of the wing. The T-6B tapered wings.

Question 75

Define Sweep angle

Answer 75

(Λ) The angle measured between the line of 25% chord and a line drawn perpendicular to the root chord. Also called sweepback. The T-6B wing is swept.

Question 76

Define aspect ratio

Answer 76

(AR) The ratio of the wingspan to the average chord.

Question 77

Define the center of gravity

Answer 77

(CG) The point at which the weight of an object is considered to be concentrated and about which all forces and moments are measured.

Question 78

Define the aerodynamic center

Answer 78

(AC) The point along the chord line of an airfoil where all changes in aerodynamic force effectively take place. It is normally located at the point of 25% chord.

Question 79

Describe the motions that occur around the airplane center of gravity

Answer 79

The movement of the airplane can be described by the movement of its center of gravity. Relative movement around all three axes occurs around the CG.

Question 80

Explain the aerodynamic relationship of the four primary forces of equilibrium flight

Answer 80

• Weight is the force of the earths gravity acting on the aircraft and is always pointed toward the center of the earth.
• Thrust is produced by the jet engine or propeller.
• Lift primarily acts against weight.
• Drag primarily acts against thrust and retards aircraft motion

Question 81

State the pressure distribution around an airfoil , given changes in angle of attack and camber

Answer 81

At zero AOA, a positively cambered airfoil will have lower pressure on the upper surface, thus generating lift. As AOA increases, lift will increase. A symmetric airfoil will have equal pressure distribution on upper and lower surface, thus generating no lift at zero AOA. Positive AOA will generate lift.

Question 82

Define the lift component of aerodynamic force

Answer 82

The component of the aerodynamic force acting perpendicular to the relative wind

Question 83

Describe how factors in the lift equation affect lift production, given density, velocity, surface area, and coefficient of lift.

Answer 83

• An increase in density will increase lift.
• An increase in velocity will increase lift.
• An increase in surface area will increase lift.
• A larger coefficient of lift will increase lift.
  
  • Compressibility, aspect ratio, viscosity, angle of attack, and camber are all accounted for in the coefficient of lift.

Question 84

List the factors affecting the coefficient of lift that the pilot can directly control.

Answer 84

The shape of the airfoil and the angle of attack

Question 85

Define the drag component of aerodynamic force.

Answer 85

The component of the aerodynamic force acting parallel to, and in the same direction as the relative wind.

Question 86

Define parasite drag and its components: form, friction, and interference drag

Answer 86

• (Ps) Parasite drag is all drag not associated with the production of lift.
  
  • Form drag is drag resulting from airflow over a surface with some frontal area, often referred to as pressure drag, profile drag, or plate drag.
  • Friction drag is drag arising from friction forces at the surface of an aircraft due to viscosity of the air.
  • Interference drag is drag caused by the mixing of streamlines around aircraft components due to their proximity.

Question 87

Describe the measures that can be take to reduce each of the components of parasite drag.

Answer 87

• To reduce form drag, the fuselage and other surfaces exposed to the airstream are streamlined (shaped like a teardrop).
• Friction drag can be reduced by smoothing the surfaces of the airplane through painting, cleaning, waxing, polishing, or using flush rivets.
• Proper fairing and filleting will reduce interference drag.

Question 88

State the effects of up wash and down wash on an infinite wing

Answer 88

Up was increases lift and down wash decreases lift proportionally. Therefore there is no net change in lift.

Question 89

State the effects of up wash and down wash on a finite wing.

Answer 89

Some of the high pressure air in the leading edge stagnation point flows spanwise to the wingtips and up to the upper surface of the wing. It combines with the other down wash when it flows over the trailing edge, therefore reducing effective lift and increasing induced drag.

Question 90

Define induced drag

Answer 90

That portion of total drag resulting from the production of lift.

Question 91

State the cause of induced drag on a finite wing

Answer 91

Since there is twice as much down wash as up wash near the wingtips of a finite wing, the average relative wind is slanted downward, thus the total lift vector will be inclined aft. The horizontal component of total lift is induced drag.

Question 92

Describe factors affecting induced drag, given the induced drag equation, and changes in lift, weight, density velocity, and wingspan

Answer 92

Increasing lift or weight will increase induced drag. Increasing density (ρ), velocity (V), or wingspan (b) will reduce induced drag.

Question 93

State when a plane will enter ground effect.

Answer 93

Within one wingspan of the ground. (About 33 ft for the T-6B)

Question 94

State the effects of ground effect on lift, effective lift, and induced drag

Answer 94

The decrease in downwash allows the total lift vector to rotate forward, increasing effective lift and decreasing induced drag.

Question 95

Describe effects of angle of attack changes on coefficient of lift and coefficient of drag.

Answer 95

As AOA increases, lift increases up to a maximum value (Clmax). The coefficient of drag is low and nearly constant at low AOA, but increases rapidly at higher angles of attack.

Question 96

Explain the lift to drag ratio, using the lift and drag equations.

Answer 96

A high L/D ratio indicates a more efficient airfoil. It is calculated by dividing lift by drag.

Question 97

Explain the importance of L/D MAX.

Answer 97

• L/D_MAX AOA produces the minimum total drag;
• the airfoil produces an equal amount of parasite drag and induced drag;
• it produces the greatest ratio of lift to drag;
• and it is the most efficient angle of attack.

Question 98

Define total drag.

Answer 98

Parasite drag and Induced drag added together.

Question 99

Describe the effects of changes in velocity on total drag

Answer 99

Total drag will be lowest where induced drag and parasite drag are equal. It will increase rapidly at lower airspeed and increase gradually at higher airspeeds.

Question 100

Define thrust components: thrust required and thrust available.

Answer 100

• Thrust Required (Tr) is the thrust required to overcome drag to maintain level equilibrium flight.
• Thrust available (Ta) is the thrust an engine produces under a specific velocity, density, and throttle setting.

Question 101

Define power components: power required and power available

Answer 101

• Power required (Pr) is the power required to produce enough thrust to overcome drag in equilibrium flight.
• Power available (Pa) is the power an engine is producing.

Question 102

Describe the effects of throttle setting on thrust available.

Answer 102

• Full throttle will result in greatest thrust available.
• As throttle is retarded, thrust available decreases.

Question 103

Describe the effects of velocity on thrust available.

Answer 103

• For turbo-prop aircraft, thrust available decreases with an increase in velocity.
• For turbojets, thrust available remains the same regardless of velocity.

Question 104

Describe the effects of density on thrust available.

Answer 104

As air density decreases thrust available decreases.

Question 105

Describe the effects of throttle setting on power available.

Answer 105

• Full throttle will result in greatest power available.
• As throttle is retarded, power available decreases.

Question 106

Describe the effects of velocity on power available.

Answer 106

• For turbo-prop aircraft, As velocity increases, power available will initially increase, but will then decrease due to a decrease in thrust available.
• For turbojets, power available will increase linearly

Question 107

Describe the effects of density on power available.

Answer 107

As air density decreases power available decreases.

Question 108

Define thrust horsepower and components: shaft horsepower and propeller efficiency

Answer 108

• Thrust horsepower (THP) is the actual amount of horsepower that an engine-propeller system transforms into thrust, equal to shaft horsepower multiplied by propeller efficiency.
• Shaft horsepower (SHP) is the horsepower delivered at the rotating driveshaft of an engine.
• Propeller efficiency (PE) is a measure of the effectiveness of a propeller in converting shaft horsepower into thrust horsepower.

Question 109

State the maximum rated shaft horsepower in the T-6B

Answer 109

1100 SHP

Question 110

Explain how propeller efficiency affects thrust horsepower

Answer 110

Under ideal conditions thrust horsepower would equal shaft horsepower, but propeller efficiency is never 100%, and the lower its efficiency, the less thrust horsepower is produced.

Question 111

Describe power required in terms of thrust required

Answer 111

Power required is the amount of power required to produce thrust required.

Question 112

State the location of L/D _MAX on the thrust required curve.

Answer 112

L/D Max is at the bottom of the thrust required curve.

Question 113

State the location of L/D_MAX on the power required curve.

Answer 113

L/D_MAX is to the right of the bottom of the power required curve (where a line drawn from the origin is tangent to the Pr curve)

Question 114

Describe how thrust required and power required vary with velocity

Answer 114

Thrust required is lowest at L/D max, increases rapidly at lower velocities, and increases gradually at higher velocities. Power required follows a similar pattern, but curves back up at a lower velocity than L/D max.

Question 115

Define excess thrust and excess power

Answer 115

• Excess thrust occurs when thrust available is greater than thrust required. Te=Ta-Tr.
• Excess power is similar to excess thrust, and occurs when power available is greater than power required. Pe=Pa-Pr

Question 116

Describe the effects of excess thrust and excess power

Answer 116

Excess thrust and excess power will produce a climb, acceleration, or both.

Question 117

Describe the effects of changes in weight on thrust and power components: thrust required, power required, excess thrust, and excess power

Answer 117

• An increase in weight will require an increase in thrust required and a corresponding increase in power required.
• Weight changes have no effect on thrust available and power available,
• thus thrust excess and power excess will decrease.

Question 118

Describe the effects of changes in altitude on thrust and power components: thrust required, power required, thrust available, power available, excess thrust, and excess power

Answer 118

• As altitude increase, the thrust required curve shifts to the right, but not up.
• Since power required is a function of thrust required and velocity, the Pr curve will shift up and to the right.
• Both thrust available and power available will decrease as altitude increases.
• Thrust excess and Power excess will also decrease with an increase in altitude.

Question 119

Describe the effects of changes in configuration on thrust and power components: thrust required, power required, excess thrust, and excess power

Answer 119

• Lowering the landing gear will increase drag, thus causing thrust required and power required to increase.
• Lowering the flaps increases the coefficient of lift, but also greatly increase parasite drag, thus the thrust required and power required curves shift up and to the left.
• Configuration changes have no effect on Thrust available and Power available, therefore if landing gear or flaps are lowered, excess thrust and excess power will decrease.

Question 120

Describe the aerodynamic effects of raising or lowering the flaps

Answer 120

Lowering the flaps increases the coefficient of lift, allowing the aircraft to fly at lower velocity, but also significantly increases drag.

Question 121

Describe the aerodynamic effects of raising and lowering the landing gear

Answer 121

Lowering the landing gear has no effect on lift, but does dramatically increase parasite drag.

Question 122

Explain the aerodynamic effects of the elevator.

Answer 122

If stick is pushed forward, the elevator moves down, increases the camber of the tail, producing lift, raising the tail, and pitching the nose down.

Question 123

Explain the aerodynamic effects of the ailerons.

Answer 123

If the stick is pushed left, the left aileron raises creating negative camber on the left wing, producing lift in the downward direction. At the same time, the right aileron lowers increasing the camber on the right wing, producing more lift. This difference in lift causes the airplane to roll left.

Question 124

Explain the aerodynamic effects of the rudder.

Answer 124

Stepping on the left rudder pedal will cause the rudder to deflect left, creating lift on the right side of the tail and yawing the airplanes nose to the left.

Question 125

Describe how the trim tab system holds an airplane in trimmed flight

Answer 125

A trim tab at the trailing edge of a control surface creates a force that moves the control surface opposite the direction the tab is oriented. For example a trim tab on the elevator that is deflected down, will create a force that will cause the elevator to deflect up. The total force from the elevator will cause the airplane to pitch nose up. The pilot trims to relieve pressure on the controls so that they stay in the desired position without being held there by the pilot.

Question 126

Define aerodynamic balancing

Answer 126

The feature of a control surface that reduces the magnitude of the aerodynamic moment around the hinge line.

Question 127

Define Mass Balancing

Answer 127

The feature of a control surface that reduces the magnitude of the inertial and gravitational moments around the hinge line.

Question 128

State the methods for aerodynamic and mass balancing employed on the T-6B

Answer 128

• Aerodynamic balancing is accomplished on the T-6B through the use of shielded horns on the elevator and rudder.
• For mass balancing, weights are placed inside the control surface overhang, ahead of the hinge line.

Question 129

What are the three basic types of control systems?

Answer 129

Conventional, power boosted, and full-power

Question 130

State the characteristics of conventional controls

Answer 130

The forces applied to the stick and rudder pedals are directly transferred to the control surfaces via push-pull tubes, pulleys, cables, and levers. This system gives the pilot direct feedback on control pressures.

Question 131

State the characteristics of power-boosted controls.

Answer 131

Power-boosted controls use hydraulic, pneumatic, or electric boosters to assist the pilot in moving the controls. If the boost system fails, the pilot can still control the airplane, but control forces will be greatly increased.

Question 132

State the characteristics of full-power controls

Answer 132

With full-power or fly-by-wire controls, the pilot has no direct connection with the control surfaces. The surfaces are controlled by hydraulic valves or electrical switches, which are directed by computer commands. This system requires artificial feel since there is no feedback from the control surfaces.

Question 133

State how trim tabs can be used to generate artificial feel on a control surface

Answer 133

• Servo tabs move in the opposite direction of the surface, making it easier for the pilot to deflect the control surface.
• Anti-servo tabs move in the same direction, requiring more force to deflect the control surface.

Question 134

Describe the purpose of bobweights and downsprings

Answer 134

The bobweight increases the force required to pull the stick aft during maneuvering flight, while the downsprings increase the force required to pull the stick aft at low airspeeds.