Tech Block 1

Question 1

1. Definition of V1? Must be less/greater than?

Answer 1

o V1 must be greater than or equal to Vmcg o V1 must be less than or equal to Vr o V1 must be less than or equal to Vmbe o V1 = The speed on which from a balanced field takeoff it is possible to either reject the takeoff and stop within the available stopping distance or to continue after engine failure and clear a screen height of 35 feet at the end of the surface available. In effect V1 is a “go speed”.

Question 2

2. Definition of V2 (must be greater/equal to?)

Answer 2

o V2 must be greater than or equal to 1.2 Vs o V2 must be greater than or equal to 1.1 Vmca o V2 is the take-off safety speed or initial target climb speed. It is the speed to be attained at or before 35’ following an engine failure to ensure climb gradients are achieved and hence obstacles are cleared by the required margins.

Question 3

4. Definition of Vmca

Answer 3

o The minimum airspeed at which, when sudden and complete failure of the critical engine occurs at that speed, it is possible to recover the airplane with that engine still inoperative and maintain it in straight flight at that speed, either with zero yaw or with an angle of bank not in excess of 5 degrees. o Must be greater than or equal to 1.2 Vs (with undercarriage retracted and flaps in take off position).

Question 4

5. Definition of Vmcg

Answer 4

o Is the minimum speed on the ground during the take off run, at which it is possible to recover control of the aircraft with the use of the primary aerodynamic controls and the take off can be continued safely, when the critcal engine suddenly becomes inoperative, with the remaining engines at take off thrust.

Question 5

6. Definition of Va

Answer 5

o Design Manoeuvring Speed, the maximum speed at which application of full available rudder, aileron or elevator will not overstress the aircraft.

Question 6

7. Performance Group A

Answer 6

o Capable of continuing a flight in IMC after failure of a critical engine at speed V1 and proceeding to a suitable aerodrome and landing. o All multi-engine turbo-jet and all multi-engine turbo-prop with more than 9 seats or with MTOW > 5,700kg

Question 7

8. Definition of runway

Answer 7

o Defined rectangular area for take off and landing run of aircraft.

Question 8

9. Definition of stopway

Answer 8

o Clear area immediately beyond the runway and at least as wide, capable of supporting aircraft for braking.

Question 9

10. Definition of clearway

Answer 9

o Clear area immediately beyond the runway over which aircraft may fly at a height of 35 ft. Can include stopway.

Question 10

12. What is ASDA?

Answer 10

o Accelerate Stop Distance Available is the combined distance of runway and stop-way.

Question 11

13. What is TODA?

Answer 11

o Take off distance available, is the runway and clearway. Clearway includes stopway.

Question 12

14. What is A Balanced Field?

Answer 12

Is when TODR = ASDR i.e. when the clearway is the same as the stopway.

Question 13

15. How is ASDA calculated (time to react)?

Answer 13

o Distance to accelerate to V1 - 1 second recognition - 2 second transition phase - distance to bring aircraft to stop. Engine failure occurs prior to V1, as your decision should have been made by V1.

Question 14

17. What is take off run required TORR?

Answer 14

o Is the distance required to accelerate to V1, engine fail, continue to midway between Vlof and 35ft point. o Or 115% of distance to reach to point midway between lift off and 35ft point (all engines), whichever is greater.

Question 15

18. What is the take off distance required (TODR)?

Answer 15

o The distance required to accelerate to V1, engine fail, continue climb to 35 ft. (15ft wet) o Or 115% of the distance to reach 35ft point (all engines), whichever is greater.

Question 16

19. Vlof is limited by?

Answer 16

o Speed at actual lift off is limited by: o Max tyre speed / Vmbe

Question 17

20. State the climb requirements for each segment

Answer 17

o 1st segment, 35ft to gear retracted (+ve ROC) o 2nd segment, end of 1st segment to 400ft or higher flap retract height, at V2 (2.4% climb gradient required) o 3rd segment, end of second segment, level acceleration to final climb speed (1.2% climb gradient capability required) o 4th segment, end of 3rd segment to 1500ft, at or greater than 1.25 Vs (1.2% min climb gradient required).

Question 18

21. The net take off flight path is deemed to end when..

Answer 18

o the aircraft passes 1500ft

Question 19

22. What is the use of the extended second segment climb?

Answer 19

o Rather than retract flap in the 3rd segment, the flaps are kept down, and on reaching the 5 min take off thrust time, the power is set to MCT. After which the flaps are then retracted, this allows for improved climb gradient but is only to be used for obstacles within the 2nd and 3rd segement. The aircraft must be clean by the 400ft point if obstacle clearance is required in the final segment.

Question 20

23. Reduced thrust take offs are dependant on…(4)

Answer 20

o Field length o Take off flight path (obstacles) o Engine inop climb gradients o Aircraft take off weight

Question 21

24. What are the disadvantages of a reduced thrust take off?

Answer 21

o Longer climb time o Higher fuel burn

Question 22

25. What conditions should reduced thrust take off not be used?

Answer 22

o Standing water (ice/slush/snow) o Mixed engine configuration o Any non-standard take off

Question 23

26. What is the reduced screen height for a wet take off?

Answer 23

o 15ft

Question 24

27. State the critical engine on a jet during take off?

Answer 24

o Nil in head wind o The most upwind engine in crosswind due to increased yaw if engine fails (weather cocking). o In the cruise the outboard engines of a 4 engine aircraft are critical.

Question 25

28. What effect does a balanced field have on take off performance?

Answer 25

o A balanced field means that it is critical that an abort is carried out immediately on engine failure recognition. o Also that the take off on one engine could be marginal if continued as a balance field is a take off right on performance limits for the given aircraft weight - not favourable.

Question 26

29. Definition of second segment of take off path?

Answer 26

o From gear retraction to level acceleration altitude, which is normally a minimum of 400 ft above take off surface. In this segment the gear is retracted, the flaps are in take off position and the aircraft is set in take off power. The speed is equal to V2 (initial climb out speed) and the required minimum gross gradient of climb, in a two engined aircraft, is 2.4%. The net flight path gradient is the gross flight path gradient reduced by 0.8%, i.e 1.6%. o Conditions are o Landing gear is retracted o Flaps are still in take off position o Speed is V2 o The minimum gross climb gradient in a twin engined aircraft is 2.4% o The minimum net climb gradient in a twin engined aircraft is 1.6% and o take off power is still set.

Question 27

30. Definition if ISA

Answer 27

o 1013.25 hPa (29.92”hg) o 15 degrees Celcius o Lapse rate is 1.98 degrees celcius per 1000’ up to 36,090’ then -56.5 degrees celcius o Density is 1.225 kg/m3

Question 28

31. Temperature at 39,000ft?

Answer 28

o -56.5 degrees celcius

Question 29

32. Aircraft maintains a constant IAS in climb, what happens to TAS & LSS & Mach?

Answer 29

o TAS will increase o LSS will decrease o Mach will increase

Question 30

33. How does temperature affect the speed of sound? (formula?)

Answer 30

o The speed of sound is directly proportional to the square root of the absolute temperature (the speed of sound will increase with an increase in temperature) o LSS =38.94 X square root Kelvin o At sea level ISA LSS=661kts o At 35,000’ ISA LSS=575kts

Question 31

34. Airspeed in a climb at a constant TAS/IAS/Mach No. What do each other do?

Answer 31

o Constant IAS = Both TAS & Mach No INCREASE o Constant Mach No = Both IAS & TAS DECREASE o Constant TAS = Mach No INCREASE, IAS DECREASE

Question 32

35. Cruise Mach No is more limiting when?

Answer 32

In warm temperatures The higher the aircraft flies *When Mach number is reduced (high altitudes) and when TAS is reduced (warm temperatures)* Mach No = TAS LSS

Question 33

36. What happens to the speed of sound with altitude / temperature?

Answer 33

o LSS reduces with altitude and with cooling temperatures

Question 34

37. Formula for True Altitude?

Answer 34

TA = Actual temp (K) x Indicated altitude . ISA temperature (K) True altitude is your actual altitude above mean sea level, no errors.

Question 35

39. Explain airspeed errors?

Answer 35

o IAS - Position error - CAS - Compressibility error - EAS - Density error - TAS

Question 36

40. What errors does a Mach meter NOT suffer from?

Answer 36

o Density error and compressibility error

Question 37

41. The two capsules in a Mach meter are what?

Answer 37

o Airspeed o Altitude calibration

Question 38

42. Mfs is…

Answer 38

o Free stream Mach Number - airflow unaffected by the aircraft

Question 39

43. Ml is…

Answer 39

o Local Mach number - is the speed of air relative to the local speed of sound measured at a point on the aircraft.

Question 40

44. Mcrit is…

Answer 40

o MCRIT is the critical Mach number. This is the speed at which the airflow over certain parts of the airframe (most likely the point of maximum camber of the aerofoil) reaches M1.0. MCRIT is increased through slimness and through the use of sweepback.

Question 41

45. How does weight affect Mcrit?

Answer 41

An increase in weight will reduce Mcrit

Question 42

46. Drag divergence Mach number is…

Answer 42

o The increase in drag associated with compressibility effect (110-115% of Mcrit)

Question 43

47. What happens to the centre of pressure (CP) leading up to super sonic flight? (relative to MCrit)

Answer 43

o The CP is well forward (below Mcrit) o The CP moves rearward (in excess of Mcrit) o The CP moves forward Mcrit - Mfs > M1 o The CP gradually moves further rearward as speed increases further

Question 44

48. Wave drag is…

Answer 44

o The separation of the airflow behind the shock wave

Question 45

49. A shock stall is the result of…

Answer 45

o The boundary layer behind the shock wave becoming turbulent and separating, spilling rearwards and striking the tailplane, creating buffet and rearwards CP movement. Rear movement of the CP causes nose pitch down.

Question 46

50. Wing design for high speed flight takes into consideration..

Answer 46

o Minimal camber to delay shock waves o Manoeuvrability o Low thichness chord ratio

Question 47

38. Formula for Mach No?

Answer 47

o M = TAS / LSS