Principles Of Flight

Question

Are cambered aerofoils much more "sensitive" to contamination than laminar profiles?

Answer 1

No, but only for small angles of attack.

Answer 2

Yes, but only at high angles of attack.

Answer 3

Increase the bending rigidity of the wing and apply mass balance to the aileron.

Answer 4

Apply aerodynamic balance - move the wing CoG closest to the axis of torsion.

Answer 5

Apply balance tab and increase the torsional rigidity of the wing.

Answer 6

Apply anti-balance tab and aileron mass balance.

Answer 7

Increase the torsional rigidity of the wing and move the wing CoG closest to the axis of torsion.

Answer 8

Apply aerodynamic balance - move the wing CoG closest to the axis of torsion.

Answer 9

Apply balance tab and increase the torsional rigidity of the wing.

Answer 10

Apply anti-balance tab and aileron mass balance.

Answer 11

Increase the torsional rigidity of the wing.

Answer 12

Apply aerodynamic ballance.

Answer 13

Apply balance tab.

Answer 14

Apply anti-balance tab.

Answer 15

Use the T-tail configuration and carefully design wing-fuselage joint.

Answer 16

Use the T-tail configuration and trim tab.

Answer 17

Use trim tab and carefully design wing-fuselage joint.

Answer 18

Increase the bending and torsional rigidity of the tailplane.

Answer 19

Airflow velocity is zero and the pressure equals stagnation pressure.

Answer 20

Airflow velocity is zero.

Answer 21

The pressure is greater than the stagnation pressure.

Answer 22

Airflow velocity is zero and the pressure is at its minimum value.

Answer 23

Aileron flutter.

Answer 24

Bending- torsional flutter.

Answer 25

Airleron reversal.

Answer 26

Wing torsional divergence.

Answer 27

Shaking of control surfaces.

Answer 28

Bending- torsional vibrations.

Answer 29

Aileron flatter.

Answer 30

Tailplane flatter.

Answer 31

Angular speed "Omega" doubles - centripetal accelaration "ar" increases four times.

Answer 32

Angular speed "Omega" doubles - centripetal accelaration "ar" doubles.

Answer 33

Angular speed "Omega" increases four times - centripetal accelaration "ar" increases four times.

Answer 34

Angular speed "Omega" increases four times - centripetal accelaration "ar" doubles.

Answer 35

Angular speed "Omega" decreases by half - the object's full period path doubles - centripetal accelaration "ar" decreases by half.

Answer 36

Angular speed "Omega" decreases by half - the object's full period path decreases by half - centripetal accelaration "ar" decreases by half.

Answer 37

Angular speed "Omega" decreases by half - the object's full period path doubles - centripetal accelaration "ar" doubles.

Answer 38

Angular speed "Omega" decreases by half - the object's full period path double - centripetal accelaration "ar" stays constant.

Answer 39

Towards the track center.

Answer 40

Towards the outside of the track.

Answer 41

Since the speed "V" is constant, no acceleration acts on the body.

Answer 42

Tangent to the circle.

Answer 43

Minimal on the upper surface and maximal on the bottom surface.

Answer 44

Maximal on the upper surface and mnimal at the bottom surface.

Answer 45

Minimal on the upper surface ana minimal on the bottom surface.

Answer 46

Maximal on the upper surface and maximal on the bottom surface.

Answer 47

Relation between static pressure, density, temperature and gas constant p=rho*g*R*T [Pa].

Answer 48

Relation between the air pressure and its temperature

Answer 49

Equation of a balance between the air pressure and its humidity.

Answer 50

Equation of the balance between the air pressure and earth acceleration

Answer 51

Ability of the object to "respond" to control impulses induced by the pilot.

Answer 52

Assurance that acrobatic exercises are permitted.

Answer 53

Assurance that the object's performance is as designed.

Answer 54

Assurance that the object is statically and dynamically stable.

Answer 55

The difference between the dynamic and static pressure.

Answer 56

The highest measured pressure.

Answer 57

The lowest measured pressure.

Answer 58

The sum of a dynamic and static pressure.

Answer 59

Undisturbed flow from the leading edge to the separation point.

Answer 60

Undisturbed flow along the entire chord, with air streams adhering to the profile.

Answer 61

Disturbed (turbulent) flow along the entire profile chord.

Answer 62

Disturbed (turbulent) flow along the entire profile chord, with maintained stream adherence to the profile.

Answer 63

The highest theoretical altitude that the aircraft is able to climb.

Answer 64

An altitude calculated in the design project of an aircraft.

Answer 65

The altitude at which the aircraft still maintains the climbing ability of 0,5m/s.

Answer 66

The altitude of the atmospere surrounding the Earth.

Answer 67

A tendency (in a form of force or a moment) to return to the former equilibrium after a disturbance.

Answer 68

Balance condition.

Answer 69

No reaction to balance disturbance.

Answer 70

Object static fluctuations around the lateral axis.

Answer 71

An imaginable point on the chord of an aerofoil at with the resultant force (of all aerodynamic forces) act.

Answer 72

A drag force application point.

Answer 73

A point at which the pressure value is average.

Answer 74

A center of the profile chord line.

Answer 75

A layer of air flowing around an arbitrary aircraft element in which the stream velocity changes from zero to free stream velocity.

Answer 76

A turbulent air region in the area of fuslage and other aircraft elements joints.

Answer 77

A part of an airstream flowing a part of aircraft with A-type flow.

Answer 78

A part of an airstream which changes from laminar to A-type flow.

Answer 79

The ratio of wingspan to average chord length.

Answer 80

The ratio of wing or blade length to the chord length at the base of it.

Answer 81

The ratio of wingspan (rotor diameter) to the aircraft (helicopter) length.

Answer 82

The ratio of mean aerodynamic chord to the wing or blade length.

Answer 83

The physical elevation (altitude) of an airport apron above mean sea level according to ISA.

Answer 84

The facade of an airport building.

Answer 85

The surface of the runway.

Answer 86

The slope of the main runway surface.

Answer 87

An air mass contained in a volume of 1m3.

Answer 88

The opposite of the atmospheric viscosity.

Answer 89

The number of molecules of oxygen and nitrogen in a 1cm3 volume.

Answer 90

The weight of 1 m3 air.

Answer 91

A set of values considered as standard of static pressure (p), temperatures (t/T) and the air density (rho) at different heights.

Answer 92

A set of intormation about atmospheric parameters held at the UN headquarters in New York.

Answer 93

A set of intormation about atmospheric parameters held at the ICAO headquarters in Montreal.

Answer 94

A collection of air chemical composition at different heights.

Answer 95

A reading of a pressure altimeter which is set to an airport pressure QFE.

Answer 96

A reading of a pressure altimeter which is set to sea level pressure QNH.

Answer 97

A reading of a radio altimeter.

Answer 98

The airport elevation.

Answer 99

A reading of a pressure altimeter when it is set to the current sea level pressure QNH.

Answer 100

The airport elevation.

Answer 101

A reading of a pressure altimeter when it is set to the current airport pressure QFE.

Answer 102

A reading of a radio altimeter.

Answer 103

Theoretical height, where the air density is equal to the standard density according to ISA.

Answer 104

The height according to international standard atmosphere (ISA).

Answer 105

The airport elevation height corrected for the current air density.

Answer 106

The pressure altitude corrected for humidity.

Answer 107

A reading of a pressure altimeter when it is set to the standard value at sea level (QNH) this is 1013.25 hPa or 760 mm Hg.

Answer 108

A reading of a standard radio altimeter.

Answer 109

The airport elevation.

Answer 110

Density altitude, corrected for ambient temperature.

Answer 111

Yes, expressed as the Universal Gas Law p=rho*g*R*T [Pa], where g is the gravity constant g = 9.81 m/s2 and gas constant R = 29.2746 m/K.

Answer 112

Yes, expressed in Mallets Law p=R*g*rho*dT [Pa], where g is the gravity constant g = 9.81 m/s2 and air gas constant R = 29.2746 m/K.

Answer 113

Yes, expressed as a Crakow's form f [A, g, p, rho, T].

Answer 114

There is no connection.

Answer 115

Static stability is not important for the dynamic stability.

Answer 116

Fixed-wing aircraft - yes, Rotorcraft - no.

Answer 117

Yes, controlability decreases.

Answer 118

Yes, controlability increses.

Answer 119

No, changes of stability do not affect controlability.

Answer 120

Yes, at large angles of attack the controlability increases and at small decreases.

Answer 121

The static stability takes into account only tendency to return to the equilibrium state, the dynamic stability takes into account objects's movement type.

Answer 122

There is no difference, the phenomenon is the same, just different names.

Answer 123

They differ in the importance - dynamic stability is more important.

Answer 124

The static stability concerns only balance on the ground, the dynamic stability - in-flight balance.

Answer 125

A tendency (in a form of force or a moment) to continue moving in the direction of displacement following a disturbance.

Answer 126

Lack of any object reaction following a disturbance.

Answer 127

Static fluctuations around the object lateral axis.

Answer 128

Trim balance condition.

Answer 129

Lack of any object reacton following a disturbance.

Answer 130

A tendency (in a form of force or a moment) to return to equilibrium state following a disturbance.

Answer 131

Static fluctuations around the object lateral axis.

Answer 132

Trim balance condition.

Answer 133

Double convex symmetrical.

Answer 134

Plano-convex.

Answer 135

Concave-convex.

Answer 136

Double convex asymmetrical.

Answer 137

A fourfold increase of the distance.

Answer 138

A double increase of the distance.

Answer 139

A double reduction of the distance.

Answer 140

A fourfold reduction of the distance.

Answer 141

A double increase in the distance.

Answer 142

A fourfold increase in the distance.

Answer 143

A double reduction in the distance.

Answer 144

A fourfold reduction in the distance.

Answer 145

The chord does not change along the wingspan.

Answer 146

The chord decreases along the wingspan.

Answer 147

The chord increases along the wingspan.

Answer 148

The chord at first increases and then decreases along the wingspan.

Answer 149

The same for all planforms.

Answer 150

Highest for an elliptical planform and the smallest for a rectangular.

Answer 151

Highest for the rectangular planform and the smallest for an elliptical.

Answer 152

Highest for an elliptical planform and the smallest for the tapered.

Answer 153

A polar curve depicting the value of lift coefficient vs. drag coefficient.

Answer 154

A polar autorotation curve.

Answer 155

A chart of the power required.

Answer 156

A graph called "Titus Huber curve" in Poland.

Answer 157

Fowler flap and the leading edge flaps.

Answer 158

Winglets and trailing edge flaps.

Answer 159

Slots and the split flaps.

Answer 160

Trainling edge flaps and the split flaps.

Answer 161

Trailing edge flaps.

Answer 162

Split flaps.

Answer 163

Fowler flap.

Answer 164

Leading edge flaps.

Answer 165

All answers are correct.

Answer 166

Increase in the lateral static stability

Answer 167

Reduction of the lateral static stability.

Answer 168

Reduction of the lateral static stability at positive angles of attack and the increase at negative.

Answer 169

Increase in the lateral static stability at positive angles of attack, and reduction at negative.

Answer 170

Depends on the angle of attack.

Answer 171

Is a constant characteristic for the profile and corresponds to the (CL/CD)max.

Answer 172

Always increases when increasing angle of attack.

Answer 173

Always increases when decreasing angle of attack.

Answer 174

A fourfold decrease of static pressure.

Answer 175

A fourfold increase of static pressure.

Answer 176

A twofold increase of static pressure.

Answer 177

A double decrease of static pressure.

Answer 178

The occurrence of self-existing vibrations.

Answer 179

The formation of the lift force.

Answer 180

The formation of drag force.

Answer 181

Elevator/rudder/aileron reversal.

Answer 182

The velocity "V" increases at reduced cross-sectional area .

Answer 183

The velocity "V" changes as the static pressure changes.

Answer 184

The velocity "V" does not change at all.

Answer 185

The velocity "V" decreases at reduced cross-sectional area and increases at increased cross-sectional area.

Answer 186

The greatest distance between the upper and the lower airfoil surfaces, perpendicular to its chord.

Answer 187

The average distance between the upper and lower airfoil surfaces.

Answer 188

The distance between the upper and the lower airfoil surfaces at 50% chord line (MAC).

Answer 189

The greatest distance between the upper airfoil surface and the chord line.

Answer 190

Opór tarcia większy, a warstwa przyścienna grubsza. The greater the drag and the thicker the boundary layer.

Answer 191

Opór tarcia mniejszy, a warstwa przyścienna cieńsza. The smaller the drag and the thinner the boundary layer.

Answer 192

Opór tarcia większy, a warstwa przyścienna cieńsza. The greater the drag and the thinner the boundary layer.

Answer 193

Opór tarcia mniejszy, a warstwa przyścienna grubsza. The smaller the drag and the thicker the boundary layer.

Answer 194

Additional drag caused by slots between those surfaces and wings.

Answer 195

Induced drag.

Answer 196

Wave drag.

Answer 197

Skin friction drag.

Answer 198

Balance tab.

Answer 199

Anti-balance tab.

Answer 200

Increase 4 times.

Answer 201

Increase 8 times.

Answer 202

Reduce 4 times.

Answer 203

Anti-balance tab.

Answer 204

Balance tab.

Answer 205

Separation Point.

Answer 206

Stagnation Point.

Answer 207

Pressure Point.

Answer 208

Turbulent point.

Answer 209

Biegunowa. The Drag Polar.

Answer 210

Krzywa doskonałości. Airfoil fineness curve.

Answer 211

Biegunowa prędkości. Polar speed curve.

Answer 212

Wykres sprawności. Chart performance.

Answer 213

Never Exceed Speed.

Answer 214

Cruising speed.

Answer 215

Economic speed.

Answer 216

Optimal speed.

Answer 217

Kilogram (kg), meter (m) and second (sec).

Answer 218

Kilogram (kg), kilometer (km) and second (sec).

Answer 219

Kilogram (kg), nautical mile (nm) and hour (h).

Answer 220

Ton (t), meter (m) and minutes (min).

Answer 221

Newton (N), Pascal (Pa), Kelvin (K).

Answer 222

Dyna (D), Bar (b), the degree Celsius (° C).

Answer 223

Pond (Po), atmosphere (at), degree Fahrenheit (° F).

Answer 224

Kilogram-force (kG), atmosphere (at), Kelvin (K).

Answer 225

100000 N/m.

Answer 226

1000000 N/m.

Answer 227

10000 N/m.

Answer 228

Increases 4 times.

Answer 229

Increases 2 times.

Answer 230

Increases 8 times.

Answer 231

Does not change.

Answer 232

Increases.

Answer 233

Slightly decreases.

Answer 234

Does not change.

Answer 235

Decreases inversly proportional to the relative density sigma.

Answer 236

Greater angular change of direction in a flat spin.

Answer 237

Greater angular change of direction in a steep spin.

Answer 238

Higher rate of descent in a flat spin.

Answer 239

During the spin the pilot does not see any difference.

Answer 240

760 mm Hg.

Answer 241

800 mm Hg.

Answer 242

750 mm Hg.

Answer 243

860 mm Hg.

Answer 244

Relative pressure.

Answer 245

Standard pressure.

Answer 246

Modulal pressure.

Answer 247

The Hypocrite's Number.

Answer 248

The relative air density.

Answer 249

Laplace's constant.

Answer 250

The M/S ratio.

Answer 251

The Piccard's ratio.

Answer 252

The dimensionless relative temperature.

Answer 253

The absolute temperature.

Answer 254

The Don Pedro's constant.

Answer 255

The d'Amore coefficient.

Answer 256

After = 101325 N / m = 1013.25 hPa

Answer 257

After = 100000 N / m = 1000.00 hPa.

Answer 258

After = 111325 N / m = 1113.25 hPa.

Answer 259

After = 100025 N / m = 1000.25 hPa.

Answer 260

To = 288 K.

Answer 261

To = 258 K.

Answer 262

To = 277 K.

Answer 263

To = 301 K.

Answer 264

rho o = 1.2255 kg/m2.

Answer 265

rho o = 1.0000 kg/m2.

Answer 266

rho o = 1.0255 kg/m2.

Answer 267

rho o = 1.2000 kg/m2.

Answer 268

t = 15 deg. C

Answer 269

t = 10 deg. C

Answer 270

t = 20 deg. C

Answer 271

16.5 deg. C

Answer 272

T = t + 273.

Answer 273

T = t + 233.

Answer 274

T = t + 283.

Answer 275

T = t + 373.

Answer 276

Higher drag and higher lift coefficient.

Answer 277

Higher drag and lower lift coefficient.

Answer 278

Higher drag and the same lift coefficient.

Answer 279

The same drag and higher lift coefficient.

Answer 280

Static pressure, temperature and density.

Answer 281

Humidity and dynamic pressure.

Answer 282

Temperature, density and kinematic viscosity.

Answer 283

The content proportions of nitrogen and oxygen.

Answer 284

Deka-(da), hecto-(h), kilo-(k).

Answer 285

Kilo-(k), mega-(m), deca-(da).

Answer 286

The decision-(dc), hecto-(h), mega-(M).

Answer 287

Mega-(M), giga-(G), pico-(p).

Answer 288

It is enough to know the bank angle.

Answer 289

We need to know the speed and bank angle.

Answer 290

We need to know the turn radius and bank angle.

Answer 291

We need to know the speed, turn radius and bank angle.

Answer 292

They change the aerodynamic coefficients in order to change the aircraft's performance (eg. approach speed).

Answer 293

They increase the maximum lift.

Answer 294

They increase the aicraft's airspeed.

Answer 295

They improve the aircraft's performance and therefore the economy of an aircraft.

Answer 296

The Radio altimeter (radar).

Answer 297

The pressure altimeter.

Answer 298

The optical rangefinder.

Answer 299

The time that elapses from the disturbance from equilibrium until it decreases in half (50%).

Answer 300

The half-period time of fugoidal flucutations caused by the disturbance.

Answer 301

Absolute stability.

Answer 302

Absolute instability.

Answer 303

Neutral stability.

Answer 304

Dynamic stability.

Answer 305

Absolute stability.

Answer 306

Absolute instability.

Answer 307

Absolute instability

Answer 308

Neutral stability.

Answer 309

Dynamic stability.

Answer 310

Absolute stability.

Answer 311

Less than the overall drag of the assembled airframe.

Answer 312

Greater than the overall drag of the assembled airframe.

Answer 313

Equal to the overall drag of the assembled airframe.

Answer 314

To answer correctly one needs additional data from a wind tunnel.

Answer 315

Increases 4 times.

Answer 316

Increases 2 times.

Answer 317

Decreases 4 times.

Answer 318

Decreases 2 times.

Answer 319

Increases 4 times.

Answer 320

Increases 2 times.

Answer 321

Decreases 4 times.

Answer 322

Decreases 2 times.

Answer 323

Aerodynamic forces on the wing increase.

Answer 324

Aerodynamic forces on the wing decrease.

Answer 325

Aerodynamic forces on the wing will not change because they do not depend on temperature.

Answer 326

Wing glide ratio increases.

Answer 327

Longitudinal static stability increases.

Answer 328

Longitudinal static stability decreases.

Answer 329

Longitudinal controllability increases.

Answer 330

Longitudinal controllability does not change.

Answer 331

Fałsz, współczynnik oporu kształtu zależy również od ustawienia ciała. False, the form drag coefficient also depends on the body placement relative to the airflow.

Answer 332

Zawsze prawda. Always true.

Answer 333

Fałsz, współczynnik oporu kształtu nie zależy od kształtu ciała. False, the form drag coefficient does not depend on the body placement relative to the airflow.

Answer 334

Prawda tylko dla profili lotniczych. True only for airfoils.

Answer 335

Less than the angle of attack for (Cl/Cd)max.

Answer 336

Less than the angle of attack for optimal Cd.

Answer 337

Equal the angle of attack for Cl = 0.

Answer 338

Greater than the angle of attack for Cl = 0.

Answer 339

Geometrical profile chord and the direction of undisturbed airflow.

Answer 340

Aerodynamic profile chord and velocity vector.

Answer 341

Geometrical profile chord and direction of descent vector.

Answer 342

The mean camber line and velocity vector.

Answer 343

Profile angle of attack.

Answer 344

Profile convergence angle.

Answer 345

Dihedral angle.

Answer 346

Sweepback angle.

Answer 347

When ambient air conditions are the same as specified in the International Standard Atmosphere table.

Answer 348

In the tropical conditions.

Answer 349

When the radio altimeter indicates 0.

Answer 350

In the arctic conditions.

Answer 351

Increase Czmax.

Answer 352

Reduce the drag force at low speeds.

Answer 353

Improve the controllability in the full range of angles of attack.

Answer 354

Improve the stability in the full range of angles of attack.

Answer 355

Reduce control forces.

Answer 356

Balance the control surface in neutral position.

Answer 357

It act as mass balance of control surface.

Answer 358

Increase control forces.

Answer 359

True, but only if the rudder mass balance has not been applied.

Answer 360

True, but only if rudder trim tab has not been applied.

Answer 361

More dangerous than the steep.

Answer 362

Slightly less dangerous than the steep.

Answer 363

Same dangerous as the steep spin.

Answer 364

A lot less dangerous than the steep.

Answer 365

Vibration excitating forces are equal damping forces.

Answer 366

Vibration excitating forces are larger than the damping forces.

Answer 367

Vibration excitating forces are smaller than the damping forces.

Answer 368

Forces damping self- excited vibrations disappear.

Answer 369

Oś OZ? OZ-axis?

Answer 370

Oś OX? OX-axis?

Answer 371

Oś OY? Axis OY?

Answer 372

Takiej nazwy nie używa się. Such names are not used.

Answer 373

Such names are not used.

Answer 374

Such names are not used.

Answer 375

Increasing Cz max by reducing induced air flow, such as winglets.

Answer 376

Acting against flow separation on upper wing side on small angle of attack.

Answer 377

Changing effective aerodynamic angle of attack.

Answer 378

Increasing wing surface.

Answer 379

The product of weight and body height - unit joule [J].

Answer 380

The product of mass and body height-unit joule [J].

Answer 381

The product of weight and body height-unit Watt [W].

Answer 382

The product of mass and body height-unit Watt [W].

Answer 383

The planform of the wing.

Answer 384

The outline of the profile.

Answer 385

The Mean Camber line.

Answer 386

The Mean Chord line.

Answer 387

Leading edge.

Answer 388

Trailing edge.

Answer 389

The chord line.

Answer 390

The Mean Camber line.

Answer 391

Trailing edge.

Answer 392

Leading edge.

Answer 393

The chord line.

Answer 394

The Mean Camber line.

Answer 395

The Mean Camber line.

Answer 396

The Chord line.

Answer 397

Maximum Camber.

Answer 398

Maximum Thickness.

Answer 399

The percentage increase of "Cz" is greater than the percentage increase of "Cx".

Answer 400

The percentage increase of "Cx" is greater than the percentage increase of "Cz".

Answer 401

The percentage increase of "Cx" is the same as the percentage increase of "Cz".

Answer 402

L/D ratio of the airframe will not change.

Answer 403

Neutralize adverse yaw.

Answer 404

Increase banking momentum.

Answer 405

Reduce skin friction drag.

Answer 406

Reduce form drag during aileron deflection.

Answer 407

OZ axis and OY axis.

Answer 408

The greatest speed with which you can make a flight in calm air.

Answer 409

Velocity, to which no restrictions in the use of the aircraft is provided according to its intended purpose.

Answer 410

The maximum speed at which you can still use the full controls deflection without exceeding the maximum airframe loads.

Answer 411

The maximum flight speed in turbulent air.

Answer 412

Is a constant value characteristic for the profile and corresponds to the maximum Cz/Cx ratio.

Answer 413

Varies depending on the angle of attack.

Answer 414

Always increases with increasing angle of attack.

Answer 415

Always increases with decreasing angle of attack.

Answer 416

Increase Czmax.

Answer 417

Reduce drag force at low speeds.

Answer 418

Improve the controllability in the full range of angles of attack.

Answer 419

Improve the stability of the full range of angles of attack.

Answer 420

Is true only for symmetric profiles.

Answer 421

Always true.

Answer 422

Is always false.

Answer 423

True but only for asymmetrical profiles.

Answer 424

Almost does not depend on the angle of attack, but it is proportional to the square of airspeed.

Answer 425

Is proportional to the square of the angle of attack and flight speed.

Answer 426

Almost does not depend on the angle of attack and flight speed.

Answer 427

Is constant and does not depend on the angle of attack and flight speed.

Answer 428

Drag of aileron deflected downwards is greater than the drag of aileron deflected upwards.

Answer 429

Drag of aileron deflected downwards is lower than the drag of aileron deflected upwards.

Answer 430

Aileron deflection is accompanied by a hinge momentum, which causes the the adverse yaw.

Answer 431

Aileron deflection is accompanied by increase of induced drag.

Answer 432

The greater angle when closer to the wing tip.

Answer 433

The greater angle when closer to the center of the wing.

Answer 434

At constant angle at any wing point, but it depends on the angle of attack.

Answer 435

At constant angle at any wing point, but it depends on the speed of flight.

Answer 436

The greater angle when the angle of attack is greater.

Answer 437

The smaller angle when the angle of attack is greater.

Answer 438

At constant angle at any wing point, but it depends on the angle of attack.

Answer 439

At constant angle at any wing point, but it depends on the speed of flight.

Answer 440

Deflected towards the wing root on the upper surface - Deflected towards the wing tip on the lower surface. E1633+SUM(SUM(D494:D1632))

Answer 441

Deflected towards the wing root on the lower surface - deflected towards the wing tip on the upper surface.

Answer 442

Deflected towards the wing root on the lower and upper surface.

Answer 443

Deflected towards the wing tip on the lower and upper surface.

Answer 444

Maximum Thickness.

Answer 445

Height of profile.

Answer 446

Thickness Chord Ratio.

Answer 447

Profile height ratio.

Answer 448

Adverse yaw.

Answer 449

Roll momentum.

Answer 450

Dutch roll.

Answer 451

Aileron hinge moment.

Answer 452

Dynamicznej bocznej. Directional dynamic.

Answer 453

Statycznej kierunkowej. Directional static.

Answer 454

Dynamicznej poprzecznej. Lateral dynamic.

Answer 455

Dynamicznej kierunkowej. Lateral static.

Answer 456

Dynamicznej bocznej. Lateral dynamic.

Answer 457

Statycznej podłużnej. Directional static.

Answer 458

Dynamicznej poprzecznej. Directional dynamic.

Answer 459

Dynamicznej kierunkowej. Lateral static.

Answer 460

Increase of the "Cx "and the "Cz".

Answer 461

Decrease of the "Cx "and the "Cz".

Answer 462

Increase of the "Cx" and decrease of the "Cz".

Answer 463

Increase of the "Cz" and decrease of the "Cx".

Answer 464

Increase of the minimum speed.

Answer 465

Increase of the lift force.

Answer 466

Decrease of the rate of descent.

Answer 467

Decrease of the drag.

Answer 468

Współczynnika oporu, powierzchni odniesienia, gęstości powietrza kwadratu prędkości lotu. Wing aspect ratio decreases .

Answer 469

Współczynnika siły nośnej, oporu kształtu i powierzchni nośnej.Wing span increases.

Answer 470

Współczynnika oporu i ciśnienia całkowitego.Profile chord decreases.

Answer 471

Mocy silnika i prędkości lotu. Engine power and airspeed.

Answer 472

Maleje wydłużenie płata. Wing aspect ratio decreases.

Answer 473

Wzrasta rozpiętość skrzydła. Wing span increases.

Answer 474

Maleje cięciwa profilu. Profile chord decreases.

Answer 475

Maleje grubość profilu. Profile thickness decreases.

Answer 476

The fact that airflow is greatly disturbed where various components join togeather.

Answer 477

Interference between slot drag from various airframe parts.

Answer 478

Formation of vortices at wing tips.

Answer 479

Wave interference in subsonic flows.

Answer 480

False, form drag also depends on the body position in airflow.

Answer 481

Always true.

Answer 482

False, form drag does not depend on the shape of the body

Answer 483

Is true only for the airfoil.

Answer 484

Turbulent.

Answer 485

Lilienthal.

Answer 486

Is always higher.

Answer 487

The same for a perfectly clean surface, in other cases higher.

Answer 488

Always the same.

Answer 489

Induced drag.

Answer 490

Interference drag.

Answer 491

Wave resistance.

Answer 492

Rotational drag.

Answer 493

True, but only if the airframe is statically unstable.

Answer 494

True, but only if the airframe is dynamically unstable.

Answer 495

Wings will twist (critical damage).

Answer 496

Buffeting.

Answer 497

Ailerons reversal.

Answer 498

Wing twisting momentum, which causes an increase in wing angle of attack.

Answer 499

Wing twisting momentum, which reduces the wing angle of attack.

Answer 500

An additional lift force, which causes only bending of the wings, without twist.

Answer 501

An additional lift force, which causes only a roll, with no effect on the twisting and bending the wing.

Answer 502

Produces less lift than the wing with smaller angle of attack.

Answer 503

Produces more lift than the wing with smaller angle of attack.

Answer 504

Produces the lift as the wing with smaller angle of attack.

Answer 505

Does not produce lift, but only drag.

Answer 506

Przesuwa się do przodu. Moves forward.

Answer 507

Przesuwa się do tyłu. Moves aft.

Answer 508

Jest stałe i nie zależy od prędkości lotu. Is constant and does not depend on flight speed.

Answer 509

Jest stałe, ale zależy od prędkości lotu. Is constant, but depends on the flight speed.

Answer 510

Przesuwa się do tyłu. Moves aft.

Answer 511

Jest stałe. Is constant.

Answer 512

Przesuwa się do przodu. Moves forward.

Answer 513

Jest stałe, ale zależy od prędkości lotu. Is constant, but depends on the flight speed.

Answer 514

Zmniejszenia Vmin. Reduce Vmin.

Answer 515

Zmniejszenia siły oporu na małych prędkościach. Reduce drag at low speed.

Answer 516

Poprawienia sterowności w pełnym zakresie kątów natarcia. Improve the controllability in the full range of angles of attack.

Answer 517

Poprawienia stateczności w pełnym zakresie kątów natarcia. Improve the stability of the full range of angles of attack.

Answer 518

Powierzchnia ograniczona obrysem skrzydła. Wing planform.

Answer 519

Powierzchnia dolnej płaszczyzny skrzydła. The lower surface of the wing.

Answer 520

Iloczyn rozpiętości skrzydła i szerokości profilu S=b c. Product of wing span and chord.

Answer 521

Iloczyn średniej cięciwy geometrycznej i wydłużenia skrzydła S=l Cśr. Product of the Mean Geometric Chord and wing aspect ratio.

Answer 522

Too small bank angle or too high angular velocity.

Answer 523

Too high bank angle or too small angular velocity.

Answer 524

Too high bank angle or too high angular velocity.

Answer 525

Too small bank angle or too small angular velocity.

Answer 526

Too high bank angle or too small angular velocity

Answer 527

Too high bank angle or too high angular velocity.

Answer 528

Too small bank angle or too small angular velocity.

Answer 529

Too small bank angle or too high angular velocity.

Answer 530

The maximum speed at which you can still use the full controls deflection without exceeding the maximum airframe load.

Answer 531

The maximum flight speed in turbulent air.

Answer 532

The maximum flight speed in calm air.

Answer 533

The speed to which all kinds of manoeuvres are permitted.

Answer 534

The maximum flight speed in turbulent air.

Answer 535

The maximum flight speed in calm air.

Answer 536

The speed to which all kinds of manoeuvres are permitted.

Answer 537

The maximum speed at which you can still use the full controls deflection without exceeding the maximum airframe load.

Answer 538

The maximum thickness of the profile is in the range 50% -70% of the chord.

Answer 539

The maximum thickness of the profile is in the range of 20% -40% of the chord.

Answer 540

For medium and high-speed flow there is no transition from laminar to turbulent airflow.

Answer 541

The transition point from laminar flow around turbulence occurs in the posterior part of the profile.

Answer 542

Cięciwa geometryczna profilu. The Chord line.

Answer 543

Cięciwa aerodynamiczna profilu. The Aerodynamic Chord line.

Answer 544

Średnia cięciwa aerodynamiczna. The mean aerodynamic chord.

Answer 545

Średnia grubość profilu. Average Thickness.

Answer 546

There is a rapid change in wing angle of attack.

Answer 547

There is a slow change in wing angle of attack.

Answer 548

Aircraft remains dynamically stable.

Answer 549

Aircraft remains statically stable.

Answer 550

A slow change of angle of attack of the wing.

Answer 551

A rapid change of angle of attack of the wing.

Answer 552

Aircraft remains statically stable.

Answer 553

An increase in static stability.

Answer 554

Are greater when lift is greater.

Answer 555

Are greater when flight speed is higher.

Answer 556

Are greater when lift is samller.

Answer 557

Are greater when the attack angle of the wing is smaller.

Answer 558

Decreases possibility of a flat spin entry.

Answer 559

Increases possibility of a flat spin entry.

Answer 560

Facilitates spin entry.

Answer 561

Makes recovery from a spin more difficult.

Answer 562

Facilitates spin entry.

Answer 563

Makes spin entry more difficult.

Answer 564

Decreases possibility of a flat spin entry.

Answer 565

Facilitates spin recovery.

Answer 566

Increases the difference of lift produced on both wings during the slip.

Answer 567

Lateral controlability is increasing.

Answer 568

Lateral static stability decreases.

Answer 569

Minimum speed decreases.

Answer 570

Increases.

Answer 571

Decreases.

Answer 572

Does not change.

Answer 573

Gforce does not depend on bank angle, but on the airspeed.

Answer 574

Rezonansu pomiędzy drganiami zaburzonych strug zaskrzydłowych z drganiami własnymi powierzchni sterowych. A high-frequency instability, caused by airflow separation or shock wave oscillations from one object striking another. It is caused by a sudden impulse of load increasing.

Answer 575

Drgań giętno-skrętnych usterzenia. Torsional vibrations of control surfaces.

Answer 576

Flatteru usterzenia. Flutter of control surfaces.

Answer 577

Zjawiska zwanego dywergencją skrętną usterzenia. Phenomenon known as torsional divergence of control surfaces.

Answer 578

Positive if we move yoke forward.

Answer 579

Negative if we move yoke forward.

Answer 580

Is always positive.

Answer 581

Is always negative.

Answer 582

Trailing edge.

Answer 583

Leading edge.

Answer 584

Back edge.

Answer 585

Front edge.

Answer 586

Leading edge.

Answer 587

Trailing edge.

Answer 588

Front edge.

Answer 589

Centre of Pressure.

Answer 590

Aerodynamic center.

Answer 591

Profile center.

Answer 592

Geometric center.

Answer 593

Aerodynamic center.

Answer 594

Centre of Pressure.

Answer 595

Profile center.

Answer 596

Geometric centre.

Answer 597

Adverse yaw.

Answer 598

A favorable deflection.

Answer 599

Adverse roll.

Answer 600

A favorable yaw.

Answer 601

Neutralize adverse yaw.

Answer 602

Increase roll moment.

Answer 603

Reduce aileron hinge moment.

Answer 604

Reduce forces necessary for aileron deflection.

Answer 605

Three axes OX, OY, OZ.

Answer 606

Two axes OX and OY.

Answer 607

One axis OX.

Answer 608

Four axes OW, OX, OY, OZ.

Answer 609

Greater than the drag force on the opposite wing.

Answer 610

Smaller than the drag force on the opposite wing.

Answer 611

The same as the drag force on the opposite wing.

Answer 612

Slightly less than the drag force on the opposite wing.

Answer 613

Siła oporu kształtu.Form drag.

Answer 614

Siła oporu tarcia. Skin friction drag.

Answer 615

Siła oporu indukowanego. Induced drag.

Answer 616

Siła oporu interferencyjnego. Interference drag.

Answer 617

They decrease with the decreasing density

Answer 618

They increase inverse proportionally to the decreasing density.

Answer 619

They remain the same, regardless of air density.

Answer 620

They change proportionally to the square of the density.

Answer 621

Increase Czmax.

Answer 622

Reduce the drag force at low speeds.

Answer 623

Improve the controllability in the full range of angles of attack.

Answer 624

Improve the stability of the full range of angles of attack.

Answer 625

Directional.

Answer 626

Longitudinal.

Answer 627

Longitudinal.

Answer 628

Horizontal.

Answer 629

Directional.

Answer 630

Odchylania i przechylania. Rolling and yawing.

Answer 631

Tylko pochylania. Only pitching.

Answer 632

Tylko przechylania. Only rolling.

Answer 633

Tylko odchylania. Only tilting.

Answer 634

Pochylania. Pitching.

Answer 635

Przechylania.Rolling.

Answer 636

Odchylania. Yawing.

Answer 637

Odchylania i przechylania. Yawing and rolling.

Answer 638

Statecznością holendrowania. Directional and lateral stability.

Answer 639

Statecznością kierunkową. Directional stability.

Answer 640

Statecznością poprzeczną. Lateral stability.

Answer 641

Statecznością dynamiczną podłużną. Longitudinal dynamic stability.

Answer 642

Odchylania. Yawing.

Answer 643

Odchylania i przechylania. Yawing and rolling.

Answer 644

Pochylania. Pitching.

Answer 645

Przechylania. Rolling.

Answer 646

Pochylania. Pitching.

Answer 647

Przechylania. Rolling.

Answer 648

Odchylania. Yawing.

Answer 649

Odchylania i przechylania. Yawing and rolling.

Answer 650

Przechylania. Rolling.

Answer 651

Odchylania. Yawing.

Answer 652

Odchylania i przechylania. Yawing and rolling.

Answer 653

Pochylania. Pitching.

Answer 654

The average speed.

Answer 655

The average acceleration.

Answer 656

Instantaneous velocity.

Answer 657

Instantaneous acceleration.

Answer 658

The Mean Geometric Chord.

Answer 659

Aspect ratio.

Answer 660

Convergence.

Answer 661

The Angle of Sweepback.

Answer 662

The average acceleration.

Answer 663

Distance traveled by the body at time t.

Answer 664

Change in kinetic energy of the body.

Answer 665

Instantaneous acceleration.

Answer 666

Największa odległość między linią szkieletową i cięciwą profilu. The maximum distance between the mean camber line and the chord line.

Answer 667

Najmniejsza odległość między linią szkieletową i cięciwą profilu. The minimum distance between the mean camber line and the chord line.

Answer 668

Największa odległość między górnym i dolnym obrysem profilu. The maximum distance between the upper and lower surface of airfoil.

Answer 669

Największa odległość między górnym obrysem profilu i cięciwą aerodynamiczną. The maximum distance between the upper surface of aerofoil and the mean aerodynamic chord.

Answer 670

Linia łącząca środki okręgów wpisanych w obrys profilu lotniczego. The line drawn equidistant between the upper and lower surfaces of an aerofoil.

Answer 671

Linia prosta łącząca nosek profilu z ostrzem (spływem) profilu lotniczego. A straight line connecting leading and trailing edge.

Answer 672

Linia łącząca noski profili płata lotniczego. A line connecting front points of aerofoil.

Answer 673

Linia łącząca ostrza profili płata lotniczego. A line connecting back points of aerofoil.

Answer 674

Directly proportional to the increase of angular velocity during the measurement -inversely proportional to the time of measurement.

Answer 675

Directly proportional to the increase of angular velocity during the measurement -directly proportional to the time of measurement.

Answer 676

Inversely proportional to the increase of angular velocity during the measurement -inversely proportional to the time of measurement.

Answer 677

Inversely proportional to the increase of angular velocity during the measurement -directly proportional to the time of measurement.

Answer 678

With respect to which the aerodynamic moment does not depend on the angle of attack (in a large range of changes of the angle of attack).

Answer 679

Where the line of the resultant aerodynamic force intersects with the chord line.

Answer 680

Equidistant from the leading and the trailing edge.

Answer 681

Which in a large range of changes of the angle of attack coincides with the geometrical centre of aerofoil.

Answer 682

In a large range of changes of the angle of attack does not change its position.

Answer 683

Moves forward.

Answer 684

Moves aft.

Answer 685

Does not change its position in the full range of changes the angle of attack.

Answer 686

W którym linia działania wypadkowej siły aerodynamicznej przecina cięciwę profilu. Positioned on chord aerodinamic force the intersection of the Total Reaction (Tr) of the chord line.

Answer 687

Względem którego moment aerodynamiczny nie zależy od kąta natarcia (w dużym przedziale zmian kąta natarcia). Reletive to the aerodynamic torque does not depend on the angle of attack (in a large range of changes in the angle of attack).

Answer 688

Równoodległy od noska i ostrza (spływu) profilu. At the same distance from the leading edge and the trailing edge of profile.

Answer 689

Który w dużym przedziale zmian kąta natarcia pokrywa się z geometrycznym środkiem profilu. Which has a large range of changes of the angle of attack and coincides with the geometrical profile.

Answer 690

Dynamic stability.

Answer 691

Static stability.

Answer 692

Increased static stability.

Answer 693

Neutral static stability.

Answer 694

Buffeting.

Answer 695

Pre-stall buffet.

Answer 696

Ailerons flutter.

Answer 697

Tail flutter.

Answer 698

Zmniejszenie stateczności statycznej podłużnej. Reduction in the longitudinal static stability.

Answer 699

Zwiększenie stateczności statycznej podłużnej. Increase of the longitudinal static stability.

Answer 700

Zmniejszenie stateczności statycznej podłużnej na dodatnich kątach natarcia, a zwiększenie na ujemnych. Reduction of the static longitudinal stability at positive angles of attack, and the increase in the negative.

Answer 701

Zwiększenie stateczności statycznej podłużnej na dodatnich kątach natarcia, a zmniejszenie na ujemnych. Increase of the longitudinal static stability at positive angles of attack, and reduction on the negative.

Answer 702

ośi OZ›. Z- yaw axis.

Answer 703

ośi OX›. X- roll axis.

Answer 704

ośi OY›. Y- lateral axis.

Answer 705

ośi OX› i ośi OY›. X- roll axis and the y lateral axis.

Answer 706

ośi OY›. Y- lateral axis.

Answer 707

ośi OZ›. Z- yaw axis.

Answer 708

ośi OX›. X- roll axis.

Answer 709

ośi OZ› i ośi OX›. Z- yaw axis and the x roll axis.

Answer 710

Różnicowe wychylenie lotek. Lift augmentation system differential aileron deflection.

Answer 711

Dodatkowe wychylenia klapo-lotek. Extra-aileron deflection flap- aileron.

Answer 712

Wychylenie lotek o dokładnie ten sam kąt. Aileron deflection by exactly the same angle.

Answer 713

Jak najmniejsze wychylenia lotek. The lowest aileron deflection.

Answer 714

- stałej ; - obojętnej; - chwiejnej - fixed -neutral- unstable

Answer 715

- stałej ; - chwiejnej; - ruchomej - fixed -unstable- mobile

Answer 716

- stałej ; - obojętnej; - ruchomej - fixed- neutral- mobile

Answer 717

- nieobojętnej; - obojętnej; - chwiejnej -indifferent- indifferent- unstable

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Principles Of Flight

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