Download presentation
Presentation is loading. Please wait.
1
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Aerodynamics Chapter 1 Forces Acting on an Airplane
2
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-1. Drag counteracted by thrust.
3
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-2. The airplane is supported by the ground, and in the air by lift.
4
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-3. The four main forces are in equilibrium during unaccelerated flight.
5
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-4. Weight acts downward through the center of gravity (CG).
6
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-5. Airfoil shape.
7
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-6. Left aileron.
8
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-7. Vertical stabilizer and rudder.
9
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-8. Wing flaps.
10
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-9. Laminar flow.
11
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-10. Turbulent flow.
12
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-11. Total reaction.
13
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-12. Pressure around an airfoil.
14
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-13. Dynamic pressure increases with airspeed.
15
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-14. Dynamic pressure is greater in dense air.
16
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-15. Airflow can lift a flat plate (but not efficiently).
17
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-16. Examples of various airfoil shapes.
18
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-17. A cambered airfoil with internal structure.
19
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-18. More camber, more lift, less drag.
20
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-19. Mean camber line.
21
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-20. Camber.
22
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-21. Chord line.
23
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-22. The production of lift and drag.
24
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-23. The aerodynamic force acts through a point on the wing called the center of pressure.
25
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-24. Relative airflow (measured relative to the “free-stream” airflow).
26
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-25. Same angle of attack, but different pitch attitudes.
27
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-26. Same pitch attitude, but different angles of attack.
28
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-27. The angle-of-incidence is fixed during design and construction.
29
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-28. Coefficient of lift versus angle of attack; each angle of attack produces a particular C L value.
30
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-29. A cambered and a symmetrical airfoil.
31
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-30. Lift curve for a symmetrical airfoil.
32
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-31. The size of the aerodynamic force and the CP position change at various angles of attack.
33
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-32. The elevator keeps the attitude constant.
34
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-33. Contamination on the wings can seriously affect the lifting characteristics.
35
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-34. Low drag requires only low thrust to counteract it.
36
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-35. Skin friction and form drag.
37
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-36. A stalled wing increases form drag substantially.
38
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-37. Streamlining, especially behind the shape, greatly reduces form drag.
39
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-38. Streamlining reduces form drag.
40
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-39. Ice accretion on the airframe will increase drag.
41
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-40. Parasite drag increases with airspeed.
42
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-41. Induced drag increases as angle of attack increases.
43
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-42. The production of lift creates wingtip vortices and induced drag.
44
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-43. Induced drag is greatest at low speeds and high angles of attack.
45
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-44. High aspect ratio.
46
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-45. Total drag versus airspeed.
47
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-46. Aspect ratio.
48
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-47. Minimum drag speed.
49
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-48. Coefficient of drag versus angle of attack.
50
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-49. Design features that minimize induced drag.
51
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-50. C L versus angle of attack.
52
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-51. C D versus angle of attack.
53
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-52. Lift/drag ratio versus angle of attack.
54
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-53. Same lift at a different cost in total drag.
55
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-54. Lift/drag ratio versus angle of attack.
56
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-55. Typical flap installation—a Cessna wing-flap system.
57
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-56. Same airspeed: increased camber and/or wing flaps give higher lift.
58
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-57. Flaps lower the stall speed (and nose attitude).
59
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-58. Effect of flaps on lift/drag ratio.
60
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-59. Lowering the flaps can cause the airplane to balloon unless you simultaneously adjust the pitch attitude.
61
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-60. Extending the flaps may cause the nose to pitch.
62
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-61. A Fowler flap.
63
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-62. Slats and slots delay the stall.
64
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-63. Propeller terminology.
65
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-64. The speed of the blade section depends on the radius and RPM.
66
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-65. Each propeller blade-section follows its own path.
67
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-66. The propeller blade angle is made progressively larger from tip to hub to provide efficient angles of attack along its full length.
68
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-67. Forces on a propeller blade.
69
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-68. Fixed-pitch propeller—the angle of attack varies with forward speed and RPM.
70
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-69. A constant-speed propeller maintains an efficient angle of attack over a wide speed/RPM range.
71
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-70. Constant-speed propeller controls.
72
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-71. An offset fin helps counteract propeller-slipstream effect.
73
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-72. The down-going propeller blade produces more thrust when the airplane is in a nose-high attitude, causing P-factor.
74
© 2009 Aviation Supplies & Academics, Inc. All Rights Reserved. The Pilot’s Manual – Ground School Figure 1-73. Questions 68 to 70.
Similar presentations
