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Aerodynamics Basics: Make It Fly PowerPoint by James Davis

Understand aerodynamics principles using the weight, lift, thrust, and drag concepts. Calculate the weight of an A-10 Thunderbolt and learn how to determine lift in level flight. Explore aerodynamics with examples like the SR-71 Blackbird, two sheets of paper airflow experiments, and forces on a ping pong ball. Discover how drag, wind, and Bernoulli's Principle impact flight dynamics.

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Aerodynamics Basics: Make It Fly PowerPoint by James Davis

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  1. Make it Fly PPT By: James Davis

  2. Weight (W)

  3. Lift (L) Weight (W)

  4. Lift (L) Thrust (T) Weight (W)

  5. Lift (L) Drag (D) Thrust (T) Weight (W)

  6. Lift (L) Drag (D) Thrust (T) Weight (W)

  7. A-10 Thunder Bolt Weight Mass(m) = 13800 kg

  8. A-10 Thunder Bolt Weight Mass(m) = 13800 kg W = ?

  9. A-10 Thunder Bolt Weight W = m ∙ g Mass(m) = 13800 kg

  10. A-10 Thunder Bolt Weight W = m ∙ g = (13,800 kg) ∙ (9.81 m/s2)

  11. A-10 Thunder Bolt Weight W = m ∙ g = 135,378 kg ∙ m/s2

  12. A-10 Thunder Bolt Weight W = 135,378 N

  13. A-10 Thunder Bolt Level Flight L = ? W = 135,378 N

  14. A-10 Thunder Bolt Level Flight L = W W = 135,378 N

  15. A-10 Thunder Bolt Level Flight L = W = 135,378 N W = 135,378 N

  16. A-10 Thunder Bolt Level Flight (L = W) L = 135,378 N W = 135,378 N

  17. SR-71 Blackbird Steady Flight D = ? T = 290, 000 N

  18. SR-71 Blackbird Steady Flight D = T T = 290, 000 N

  19. SR-71 Blackbird Steady Flight (T = D) D = 290,000 N T = 290, 000 N

  20. Basic Aerodynamics

  21. Two Sheets of Paper ( No Airflow)

  22. Two Sheets of Paper ( No Airflow) P = Patm P = Patm P = Patm

  23. Two Sheets of Paper ( No Airflow) P = Patm P = Patm P = Patm

  24. Two Sheets of Paper (with airflow)

  25. Two Sheets of Paper (with airflow) P = Patm P < Patm P = Patm

  26. Two Sheets of Paper (with airflow) P = Patm P < Patm P = Patm

  27. Two Sheets of Paper Airflow Between Sheets No Airflow P < Patm P = Patm P = Patm P = Patm P = Patm P = Patm

  28. (No) Airflow w/ Straw Balanced Air Pressure

  29. (No) Airflow w/ Straw Balanced Air Pressure

  30. (No) Airflow w/ Straw

  31. Airflow w/ Straw Blow Blow

  32. Airflow w/ Straw Blow Blow

  33. Airflow w/ Straw Blow Blow

  34. Airflow w/ Straw Blow Blow

  35. Forces on our ping pong ball

  36. Forces on our ping pong ball Weight

  37. Forces on our ping pong ball Weight Wind Hair Dryer

  38. Forces on our ping pong ball Weight Wind Hair Dryer

  39. Forces on our ping pong ball Drag Weight Wind Hair Dryer

  40. Forces on our ping pong ball Drag Weight

  41. Forces on our ping pong ball Wind Weight Hair Dryer

  42. Forces on our ping pong ball Wind Weight Hair Dryer

  43. Forces on our ping pong ball Wind Weight Hair Dryer

  44. Forces on our ping pong ball Drag Wind Weight Hair Dryer

  45. Forces on our ping pong ball Drag Wind Weight Hair Dryer

  46. Forces on our ping pong ball Lift Drag Wind Weight Hair Dryer

  47. Forces on our ping pong ball Drag Lift Drag Weight Wind Wind Weight Hair Dryer Hair Dryer

  48. Bernoulli's Principle P < Patm Patm Wind Hair Dryer

  49. Forces on our ping pong ball Lift Drag Weight Hair Dryer

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