Replicating the 1903 Wright Flyer

1. Replicating the 1903 Wright Flyer

2. Introduction • Sir George Cayley • Conventional configuration • Otto Lilienthal • Airfoil data, first pilot • Alphonse Penaud • Rubber powered models • Octave Chanute • Pratt truss

3. Wright Brothers • Control centric approach • Wing warping for roll control • First wind tunnel tests • Adverse yaw • Canard for pitch control

4. The Wright approach • Wing warping tested on 1899 kite • 1901 glider was a disappointment • Wind tunnel testing leads to 1902 glider • First powered flight, 1903

5. Problems in replication • Instability • Pitch, CG behind NP • Spiral mode, Anhedral • Control • Smaller tail volumes • Constructional • Practical limits due to scaling down

6. Strategy

7. Strategy • Exploring a/c • Literature study • Proposed solutions • Making gliders • Material selection • Practical limits on fabrication • Implementation of control mechanisms

8. Propulsion • Market survey for • Contra-rotating pushers • Belts, pulleys and shafts • Engine • Test the setup

9. Glider Specifications • 1:12 scaled down model • Wing Span 1.02 m • Length 0.54m • Canard area 6.3% of wing area, 0.0210 m2 • Rudder area 0.01 m2 • Weight 0.15 Kg • Ballast weight 0.040 Kg • Wing loading 0.11 kg/m2

10. Glider

11. Glider Experience • Material selection • Central carbon fibre box supporting • Wing • Canard and rudder • Engine • Landing gear

12. Central Box

13. Glider Experience • Material selection • Balsa wood used for • Wing ribs • Canard and rudder • Vertical struts

14. Glider Experience • Monokote for wing covering • Slotted ribs for front spar • Joints • Strut-spar pin joints replicated • Pins lashed to spars and struts • Rigging with twine thread

15. View of joints

16. Glider Experience • Controls • Steel wire for wing warping • Flexible joints in rear spar for wing warping • Complete canard moved for pitch control (unlike original variable camber)

17. Weight estimation • Controls part • 4 servos + Receiver+ Battery pack + Miscellaneous • 160gm + 30gm + 120gm + 50gm =360 gm • Propulsion part • Engine + Mount + Shafts, Belts, Pulleys + Fuel + Misc 335gm + 150gm+ 300gm+ 250gm+ 65gm =1100 gm • Landing gear = 150gm • Structure part • Carbon fiber composite + Balsa + Misc • 450gm + 300gm + 250gm =1000gm • Total Maximum weight = 3 kg • Wing loading with this weight = 0.338 kg/m2

18. Thrust and Power Estimation • Max thrust required at min Cl/Cd = 12 N • Power required at this Cl/Cd is 120 W • Engine of 250 W at 16000 rpm • Two 10X6 props at 8000 rpm give 15 N thrust • Thrust in lbs = 2.83x10-12 x RPM2 x D4 x Cp x (P/29.92) x (528/(460+T))

19. Propulsion • Electric motor • Less weight • No starting problems • Ease of maintenance • Large battery weight (Can be used as ballast) • Lesser heating problems

20. Propulsion • Wankel IC engine • High power • Less fuel weight • Cooling problems ?

21. Propulsion • Belt pulley system • Propeller shaft mounting replicated • Contra-rotating propellers ?

22. Side view transmission system 9.3 cm 4 cm 11 cm 6 cm 25 cm

23. Front View 23.5 cm 12 cm 5 cm 39.4 cm

24. Unsolved problems • Roll-yaw coupling ? • Asymmetric yawing moment ? • Pitch SAS using rate gyro? • Tail and canard volumes ? • Anhedral ? • Landing ? • Twisted belt drive ?

25. Cost Estimate

26. Acknowledgements • Prof. K. Sudhakar, IIT Bombay • Dr. H. Arya, IIT Bombay