5_POF EXAM PREP

Question

270 Winglets? (Fig. 8)

Answer 1

O Do not significantly affect lateral and directional stability.

Answer 2

O Improve lateral and directional stability.

Answer 3

O Improve spin recovery.

Answer 4

O Improve roll rates.

Answer 5

O Increase.

Answer 6

O Decrease in every phase of flight.

Answer 7

O Increases or decreases pending on weight.

Answer 8

O None of them.

Answer 9

O Longitudinal stability would be unaffected.

Answer 10

O CL would decrease;

Answer 11

O Angle of attack would increase.

Answer 12

O Angle of incidence will be iprooved..

Answer 13

O Decreases lateral stability,

Answer 14

O Increases directional stability,

Answer 15

O Decreases longitudinal stability.

Answer 16

O Makes difficult to steer on the ground.

Answer 17

O 79 kts 97 kts

Answer 18

O 85 kts 104 kts

Answer 19

O 56 kts 64 kts

Answer 20

O 62 kts 70 kts

Answer 21

O the tip incidence less than the root incidence.

Answer 22

O the tip incidence greater than the root incidence.

Answer 23

O the tip camber less than the root camber.

Answer 24

O the tip chord less than the root chord.

Answer 25

O variations in aeroplane΄s loading.

Answer 26

O variations in flight altitude.

Answer 27

O Changes in pitch attitude.

Answer 28

O Changes with atmospheric pressure.

Answer 29

O at speed 5% to 10% above the stalling speed.

Answer 30

O at the stalling speed.

Answer 31

O at a speed more than 15%, above the stalling speed.

Answer 32

O at speed bellow the stalling speed.

Answer 33

O The aeroplane to stall, at an angle of attack that is lower than normal.

Answer 34

O Drag factor, is of great importance, that sufficient speed can not be achieved during the take off.

Answer 35

O Is of no importance.

Answer 36

O The aeroplane to stall, at an angle of attack quite higher than normal.

Answer 37

O The coefficient of lift to its max value of CLmax at critical angle of attack.

Answer 38

O The aerofoil induced drag in relation to angle of attack.

Answer 39

O The aerofoil lift/drag ratio.

Answer 40

O The aerofoil product in relation to bank angle.

Answer 41

O angle of attack regardless of altitude, with relation to the horizon.

Answer 42

O angle of attack and altitude, with relation to the horizon.

Answer 43

O airspeed regardless of the altitude, with relation to the horizon.

Answer 44

O indicated airspeed regardless of altitude, bank angle and load factor.

Answer 45

O the induced and parasite drag are equal.

Answer 46

O the induced drag is greater than parasite drag.

Answer 47

O the parasite drag is greater than the induced drag.

Answer 48

O the parasite drag is greater than the induced drag

Answer 49

O (i) parasite (ii) induced (iii) total

Answer 50

O (ii) parasite (i) induced (iii) total

Answer 51

O (i) total (ii) induced (iii) parasite

Answer 52

O (i) total (ii) parasite (iii) induced

Answer 53

O Point B is the stall speed and point A is the min drag speed

Answer 54

O Point B is the stall speed and point D is Vg

Answer 55

O Point B is the min drag speed and point D is the stall speed

Answer 56

O Point A is the VA and point C is the min power speed.

Answer 57

O ISA +2°C.

Answer 58

O ISA -1°C.

Answer 59

O ISA -3°C.

Answer 60

O ISA +4°C.

Answer 61

O standardised atmospheric values of temperature, pressure and density for all altitudes

Answer 62

O values of actual conditions of temperature, pressure and density that exist at all levels of the atmosphere.

Answer 63

O sea level conditions of atmospheric temperature, pressure and density.

Answer 64

O ambient conditions of atmospheric temperature, pressure and density for all altitudes.

Answer 65

O temperature, pressure, density and humidity.

Answer 66

O temperature, pressure and humidity.

Answer 67

O pressure, humidity and oxygen content.

Answer 68

O pressure, humidity, temperature and specific gravity.

Answer 69

O decreases with increase in height above the Earth.

Answer 70

O will decrease with height only if an inversion layer is present.

Answer 71

O increases with increase in height above the Earth.

Answer 72

O increases with decrease,in random maner in height above the Earth.

Answer 73

O pressure, and inversely proportional to temperature.

Answer 74

O temperature, and inversely proportional to pressure

Answer 75

O humidity and temperature.

Answer 76

O pressure and temperature

Answer 77

O remains constant, but the lower atmospheric pressure at altitude makes it more difficult for the body to absorb oxygen

Answer 78

O falls, but since the quantity is adequate, the fall has little effect on the pilot at any altitude.

Answer 79

O decreases due to the decreased air pressure.

Answer 80

O increases slightly up to the tropbpause above which it remains constant.

Answer 81

O cause the air density to decrease.

Answer 82

O not affect the air density if the temperature remains constant.

Answer 83

O cause the air density to increase.

Answer 84

O cause air density to fluctuate whilst pressure is changing due to adiabatic heating and cooling.

Answer 85

O nitrogen, oxygen and water vapour.

Answer 86

O hydrogen, carbon dioxide, helium and oxygen.

Answer 87

O oxygen, carbon dioxide, carbon monoxide and water vapour.

Answer 88

O carbon monoxide, hydroxide nytrogen and air.

Answer 89

O a lower density.

Answer 90

O a greater density.

Answer 91

O a similar density.

Answer 92

O an imbeure density.

Answer 93

O the pressure falls.

Answer 94

O of the fall in water vapour content.

Answer 95

O the temperature falls.

Answer 96

O of adiabatic cooling.

Answer 97

O increase.

Answer 98

O decrease.

Answer 99

O remain constant because the volume is constant.

Answer 100

O vary only with changes in the lapse rate.

Answer 101

O the amount of water vapour present in the air compared to the maximum amount of water vapour the air could hold at the same temperature. This is expressed as a percentage.

Answer 102

O the percentage of water in a measured volume of air irrespective of temperature.

Answer 103

O the relative amount of water vapour in the air at any time and any temperature but specific volume.

Answer 104

O the water vapour density at any temperature compared with its density at saturation temperature.

Answer 105

O decrease.

Answer 106

O increase.

Answer 107

O remain constant because the volume is constant.

Answer 108

O remain constant because pressure will have no effect on density at a constant volume and temperature.

Answer 109

O a nose pitch down and aircraft sink.

Answer 110

O a nose pitch up and aircraft sink.

Answer 111

O yaw tendency and flutter.

Answer 112

O sink and spin.

Answer 113

O the same at low airspeed but higher at high airspeed.

Answer 114

O the same at low airspeed but lower at high airspeed.

Answer 115

O the weight equals lift and the drag equals the thrust.

Answer 116

O the lift equals the drag and the thrust equals the weight.

Answer 117

O the weight equals the drag and the horizontal component of lift equals the thrust.

Answer 118

O the weight equals the lift couple and the drag equals the thrust couple.

Answer 119

O at or just prior to the stall.

Answer 120

O between 4° and 6° angle of attack in straight and level flight.

Answer 121

O at the minimum drag speed(Vmd) in the clear configuration.

Answer 122

O at the minimum power required (Vmp).

Answer 123

O cause the inboard section of the wing to stall first.

Answer 124

O equalize the angle of incidence all over the wing.

Answer 125

O cause the outboard section of the wing to stall first.

Answer 126

O prevent progressive wing stall and loss of control.

Answer 127

O (i) greatest (ii) heavy (iii) slow

Answer 128

O (i)greatest (ii)light (iii)high

Answer 129

O (i)least (ii)heavy (iii)slow

Answer 130

O (i)least (ii)light (iii)moderate

Answer 131

O must be inspected by a qualified engineer before the next flight.

Answer 132

O must be inspected by the pilot in command and if no defect is found, he will not be required to make an appropriate entry in the aircraft technical log the mechanics hold.

Answer 133

O must be inspected by at least two pilots licenced on the type, one of whom must be the pilot in command.

Answer 134

O must be subjected to a duplicate inspected by two engineers before the next flight.

Answer 135

O cause an increase in the stalling speed.

Answer 136

O effect the stalling angle.

Answer 137

O cause a decrease in the stalling speed.

Answer 138

O cause an increase in the flapless stalling speed but increase in the clean stalling angle.

Answer 139

O an increase of both lift and drag.

Answer 140

O a decrease in lift but an increase in drag.

Answer 141

O no change in lift generated by the wing, but an increase in airframe drag.

Answer 142

O an increase only in lift.

Answer 143

O static pressure + dynamic pressure.

Answer 144

O pitot pressure + dynamic pressure.

Answer 145

O pitot pressure + partial pressure.

Answer 146

O pitot + pressure gradient.

Answer 147

O angle of attack

Answer 148

O angle of incidence

Answer 149

O angle of lift

Answer 150

O dihedral angle

Answer 151

O they delay the break up of the smooth airflow over the wing.

Answer 152

O they dump positive pressure airflow from under the wing.

Answer 153

O they increase the effective wing area at the leading edge

Answer 154

O they decrease the ineffective wing area at the leading edge.

Answer 155

O greatly reduced applied elevator force during the flare.

Answer 156

O an increased stalling angle.

Answer 157

O an increased sense and feeling and applied elevator force during rotation.

Answer 158

O an increased sense and feeling and applied rudder force during rotation.

Answer 159

O induced drag decreases and parasite drag increases.

Answer 160

O parasite drag decreases and induced drag increases.

Answer 161

O induced drag increases and total drag decreases.

Answer 162

O induced drag decreases and parasite drag decreases.

Answer 163

O is reduced as airspeed increases.

Answer 164

O is not a factor of airspeed.

Answer 165

O is increased as airspeed increases.

Answer 166

O is reduced as angle of bank increases.

Answer 167

O be adjusted on the ground after a flight test to achieve laterally level flight.

Answer 168

O not be adjusted once set by the manufacturer.

Answer 169

O be adjusted on the ground after a test flight to achieve longitudinally level flight.

Answer 170

O only be adjusted after maintenance inspection.

Answer 171

O ensure that the pilot's physical control load increases with increase of control surface deflection.

Answer 172

O ensure the centre of pressure is maintained forward of the hinge line.

Answer 173

O trim the tolerance of trim tab.

Answer 174

O ensure that the pilot's physical control load decreases with increase of control surface deflection.

Answer 175

O trim tab position remaining constant relative to the control surface.

Answer 176

O trim tab moving to a new position and will have to be re-set.

Answer 177

O trim tab position remaining constant relative to the airflow.

Answer 178

O trim tab moving in the opposite direction to the main flying control surface.

Answer 179

O the square root of the load factor.

Answer 180

O the square of the wing area.

Answer 181

O the square root of the weight.

Answer 182

O the square root of aspect ratio.

Answer 183

O the angle subtended by the aerofoil chord line and the relative airflow.

Answer 184

O the angle subtended by the aerofoil chord line and the longitudinal axis.

Answer 185

O the angle subtended by the aerofoil mean chord line and the horizon.

Answer 186

O the angle subtended by the aerofoil mean chord line and the ground surface.

Answer 187

O a greater velocity.

Answer 188

O low angular velocity.

Answer 189

O a reduced velocity.

Answer 190

O a relative conformal velocity.

Answer 191

O the same.

Answer 192

O unpredictable.

Answer 193

O The fin.

Answer 194

O The rudder.

Answer 195

O The rudder trim tab.

Answer 196

O The trim tab and anti-tab.

Answer 197

O side slipping.

Answer 198

O left and the rudder to the right.

Answer 199

O right and the rudder to the left.

Answer 200

O right and rudder to the right.

Answer 201

O left and rudder to the left.

Answer 202

O prevents flutter of that control in the higher speed range.

Answer 203

O eases the hand movements during the power-on stall

Answer 204

O makes the control easier for the pilot to move.

Answer 205

O makes the control more difficult for the pilot to move.

Answer 206

O mass balance forward of the control surface hinge.

Answer 207

O a special assembly to the elevator.

Answer 208

O balance tabs to the leading edge.

Answer 209

O balance tabs to the trailing edge.

Answer 210

O has an area of the control surface forward of the hinge line.

Answer 211

O has been modified with a trim tab..

Answer 212

O uses a balance weight forward of the hinge line.

Answer 213

O uses a balance weight aft of the hinge line.

Answer 214

O adverse aileron drag.

Answer 215

O the higher degree of spiral diving.

Answer 216

O lateral positive stability.

Answer 217

O lateral instability

Answer 218

O rudder > roll ailerons > yaw and spiral dive

Answer 219

O rudder > turn ailerons > roll and spiral dive

Answer 220

O rudder > adverse yaw ailerons > skid

Answer 221

O rudder > yaw ailerons > turn and spin

Answer 222

O re-establishes its original flight path without any pilot input.

Answer 223

O remains in the new flight path.

Answer 224

O becomes further displaced from its original flight path.

Answer 225

O oscillates about its original flight path without leaving its flight path.

Answer 226

O remains in the new attitude.

Answer 227

O oscillates about its original attitude before eventually settling in its original attitude.

Answer 228

O immediately re-establishes its original attitude.

Answer 229

O departs further from its original attitude and diverts.

Answer 230

O the tailplane producing a downward force.

Answer 231

O the tailplane producing an upward force.

Answer 232

O neither an upward nor downward tailplane force as the aircraft will be in equilibrium.

Answer 233

O either an upward or downward tailplane force as the aircraft will not be in equilibrium.

Answer 234

O independently by the pilot, to remove excessive control loads.

Answer 235

O automatically to assist the pilot in moving the controls.

Answer 236

O automatically to provide feel to the controls.

Answer 237

O artificial feel to the controls.

Answer 238

O be reduced because the centre of lift is closer to the wing root.

Answer 239

O be increased because of increased lift.

Answer 240

O not be affected.

Answer 241

O be decreased because of increased lift.

Answer 242

O A projection of the outer edge of the control surface forward of the hinge line.

Answer 243

O A rod projecting upward from the main control surface to which the control cables are attached.

Answer 244

O A rod projecting forward from the control surface with a weight attached to the end.

Answer 245

O None of them.

Answer 246

O mechanical stops.

Answer 247

O aerodynamic forces.

Answer 248

O is not limited.

Answer 249

O servomotors.

	Created by tsampikos pompou almost 8 years ago

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