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RC Hovercraft
- 2. Project members: Rana Bilal Mujahid Aziz Naseer Ahmed Project Advisor Sir Hassan Ahmed
- 3. Contents: (sequence) • Introduction of hovercraft • History • Working principle • Basic parts of hovercraft • Design & analysis • Configuration selection • Advantages and disadvantages • Application of hovercraft • Future of hovercraft • conclusion
- 4. Hovercraft • As modes of transportation have evolved over the years, finding more efficient and economic ways of movement have been the chief goals of developers. It is from this evolution that the hovercraft arose.
- 5. Introduction: A hovercraft or air cushion vehicle(acv) is a craft designed to travel over any smooth surface supported by a cushion of high pressure air ejected downwards against the surface below , and contained within a “skirt”.
- 6. Introduction: A Hovercraft is a vehicle that Flies like a plane Float like a boat Drive like a car
- 7. History 1716 Emmanuel Swedenborg (Swedish Designer & Philosopher) • He first conceptualized the idea of supporting a vehicle on a cushion of air but his projectwas short lived and his craft never built.
- 8. History Mid 1870s Sir John Thornycroft (British Engineer) • He developed the air cushion effect idea further by building and testing a number of models but no applications were found since the technology to implement the concept did not exist at the time.
- 9. History 1952 Sir Christopher Cockerell (British Engineering) • He invented the hovercraft and got his idea patented in 1955. • With diligent work he was able to bring his idea to reality with the first commercial hovercraft in 1959. • From there on the idea took with numerous developments with the vehicle.
- 11. BASIC PARTS OF A HOVERCRAFT Hull Vertical Column Payload Skirt Lift fan Propeller Rudder Battery/Engine Steering/RC *** insert a good quality labeled diagram here
- 13. DESIGN OBJECTIVES Parameter Objective Payload Capacity 0.5 -1 kg Power Battery powered Control medium RC controlled Terrain capability Land and water Running time 10 – 15 min Cost Economic
- 14. DESIGN CONSIDERATIONS Design Constraints: o Budget : 25k-30k o Manufacturing facilities o Materials availability Personal skill level Project duration
- 15. DESIGN METHODOLOGY Select configuration Estimate material, components req. Estimate sizing details Weight Estimation Calculate hover, lift parameters Calculate thrust parameters Select components Analysis & modification
- 17. CONFIGURATION SELECTION 2. Air Cushion
- 20. DESIGN CALCULATIONS 1. Weight Estimation Components Mass Quantity Net Mass Total mass,weight Hull 300g 1 300g 1.952kg Or 19.52 N Vertical Column 52g 1 52g Skirt 200g 1 200g Rudder 100g 1 100g Bldc Motor 300g 2 600g Servo motor 200g 1 200g ESC 100g 1 100g Battery 400g 1 400
- 21. DESIGN CALCULATIONS 2. Lift Force and Air Cushion Pressure Required lift force = Air cushion pressure * lift area FL = Pc * AL Pc = FL / AL FL = Lift force = Estimated weight = 1.95 kg * g = 19.5 N AL = Total area covered by hull – Area of lift motor duct = 0.610 m x - 0.450 m - ∏ x (0.1 mm)2 =0.243 m2 Pc = Air cushion pressure = 19.5 N / 0.243 m2 = 88.76 Pa Pc = 88.76 Pa
- 22. DESIGN CALCULATIONS 3. Drag Force Estimation Fd = ½* ρ v2 Cd A Cd = Drag coefficient = 1.05 (for cubic front) ρ = Density of air = 1.225 kg/m3 A= Frontal Area = 0.095 m2 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 0 1 2 3 4 5 DragForce(N) Velocity (m/s) Velocity-Drag Graph
- 23. DESIGN CALCULATIONS 4. Thrust Requirement Net force = Thrust – Drag a = required acceleration m= mass of hovercraft Ft = ma + Fd 0 2 4 6 8 10 12 14 0 1 2 3 4 5ThrustForce(N) Acceleration (m/s2) Thrust Force v=0.5 m/s v=5 m/s
- 24. DESIGN CALCULATIONS 4. Running Time Total capacity = 10000 mAh Total current drain (65A ESC) =130A Running time = Capacity/ Amperage = 11 min approximately
- 25. STRUCTURAL DETAILS 1. Assembly Model
- 26. STRUCTURAL DETAILS 2. Front View
- 27. STRUCTURAL DETAILS 3. Top View
- 28. STRUCTURAL DETAILS 4. Side View
- 30. STRUCTURAL DETAILS 6. Vertical Column
- 33. STRUCTURAL DETAILS 9. Fan Duct
- 34. ELECTRONIC COMPONENTS RC Controller Servo MotorBLDC Motors ESC Lipo Battery Connecting Wires
- 35. Comparison of Pros & Cons Advantages Disadvantages ****Did not understand what to add in it
- 36. Commercial hovercraft. Leisure hovercraft. Military hovercraft. Rescue hovercraft. Survey hovercraft. APPLICATIONS
- 37. Advantages of hovercraft Travel over any surface. Shortcutting routes. Travel rivers up as fast as down, irrespective of the current. Hovercraft are very fuel efficient (CO² friendly). No collision with debris, logs etc.
- 38. Disadvantages of hovercraft They move a lot air and can be relatively loud. Noise pollution. Steep grade can be issue. Potential of skirt damage. Difficult to control on the land.
- 39. Current status Literature review has done. Design has completed. All the detailed drawings are designed. Demands are initiated. Prototype model has manufactured.
- 40. Learning outcomes Manufacturing skills. Management skills. Designing skills. Utilization of subjects studied through out the diploma. Teamwork. Overall experience was good.
- 41. Future of hovercraft The future of hovercraft seems uncertain, but there is a good chance there will be huge hover ports all over the world, like the one in the picture. Thinner hovercraft might be built so civilians can drive safely on roads. It also seems likely that the larger hover vehicles will become larger than ever! Hovercraft are likely to be capable of high flight.
- 42. Conclusion Hovercrafts are generally simple mechanisms in theory. Yet the process from theory to manifestation is not as easy as it may seem. A plethora of problems exist and must be faced in order to attain a well functioning hovercraft. The plans and designs must be flawless. One thing is certain; when building a hovercraft, be well aware of the demands of construction. Be prepared and willing to embrace failure for it is the only way to success.