AMPHIBIOUS VEHICLE

1. AMPHIBIOUS VEHICLE

2. The Team The Project Overview The Design & Prototype The Testing The Conclusion The Acknowledgements

3. Michael Gondhi Steve Brink Steve DeMaagd Jasper Gondhi Tyler Vandongen • THE TEAM

4. THE GOAL Colossians 3:17 “And whatever you do, whether in word or deed, do it all in the name of the Lord Jesus, giving thanks to God the Father through him.”

5. PRIMARY GOAL Design and develop a working prototype of human powered amphibious vehicle (AV) by applying the principles of an engineering design process from concept to production. THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

6. SECONDARY GOALS Speed on Land of 15 mph Speed on Water of 2 mph Successful Braking on Land Successful Transitions between Land and Water THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

7. Design Goals • Water: • Buoyancy • Stability • Getting on/off • Turning radius Land: • Speed • Braking • Turning radius • Stability THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

8. Design Norms Trust Transparency Stewardship THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

9. Scope Human-poweredrecreation vehicle market Customer: Lake house owners Flood region service Customer: Disaster relief agencies and NGO’s THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

10. THE DESIGN & PROTOTYPE THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

13. FRAME DRIVE TRAIN PROPULSION STEERING FLOTATION THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

14. FRAME THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

15. FRAME – Finite Element Analysis Maximum Deflection: 0.08 in. Direction of Force • MODEL W/ FEA THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

16. DRIVE TRAIN FRONT AXLE PADDLE WHEEL AXLE THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

17. DRIVE TRAIN – FRONT AXLE Minimize Axle Length: 66 in. - 62 in. 0.75 in. 0.475 in. THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

18. DRIVE TRAIN – PADDLE WHEEL AXLE Paddle Wheel Axle Aluminum Tubing Wheels Flotation Initial safety factor used for flotation = 2 Result: Vehicle floats too muchand paddle wheels don’t hit water as they are placed with respect to the flotation Change: Paddle wheel assembly lowered to match necessary height. Aluminum Tubing Wheels Flotation Paddle Wheel Axle THANK YOU PROJECT OVERVIEW DESIGN & PROTOTYPE TESTING CONCLUSION

19. FLOTATION PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

20. FLOTATION PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

21. FLOTATION PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

22. THE MANUFACTURING PROCESS PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

23. Frame Specifications • Material: Aluminum 6061 • High strength to weight ratio • Shape: Circular Tubing • Ease of welding • Diameter: 3 inch • Size donated from Steelcase • Thickness: 1/8 inch • Ease of welding • Strength PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

24. Frame • Created Jig • Fish-mouthed Tubing • Aluminum MIG welded • Smoothed Welds PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

25. Drive Train Specifications • Material: 4130 Cold Rolled Steel • According to Calculations • Diameter: 7/8 inch • Available from Machine Shop • Length: 62 inches • According to Frame Width PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

26. Drive Train • Drilled Ends: .322 Diameter • Tapped Ends: 3/8-26 Tap • Manufactured Bearing Adapters • Manufactured Gear Hub Adapters • Purchased Bearings w/ Set Screws • Weld Gear Hub onto Axle PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

27. Flotation Specifications • Material: Closed Cell Polystyrene • High Buoyancy • Low Cost • Availability • Coating: Epoxy, Resin (Hardener), Fiberglass Cloth • High Strength • Ease of Manufacture • Dimensions: 7 in. x 18 in. x 96 in. • According to Buoyancy Calculations PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

28. Flotation CNC Hotwired Foam Square Jig for Router Routed Square Hole Connected Bolts into Wood Fiber-glassed PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

29. Steering Specifications • Material: • Land: Stainless Steel Cable • Durable • Water Resistant • Ease of Manufacture • Water: Polyurethane Sheet • Availability • Ease of Assembly • Effectiveness PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

30. Steering • Cut Aluminum Block to Raw 3 in. Cube • Programmed Bridgeport Mill • Milled “U-Shape contour” • Milled “Grooves” additional grip • Milled and Tapped Holes PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

31. Propulsion Specifications • Material: • 4130 Steel Axle and Sleeves • For High Strength and Welding Purposes • Plastic Paddles and Housings • Availability, Effectiveness, and Water Resistant • Dimensions: • Axle: ¾ in. diameter • To Fit Paddle Wheels • Paddle: 19 in. diameter • Common Paddle Size PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

32. Propulsion • Machined four sleeves • Welded Gear Hub to Inner Sleeve • Screwed in Paddle Wheels • Spaced Housings • Attached Paddle Wheel Assembly to Frame PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

33. Braking and Seating Specifications • Seating: • 3 Aluminum “L- slider brackets” on each side • Adjustable seat for all riders • 1 inch square tubing • Available in Engineering Shop • Braking: • Used “center-pull” bicycle brakes • Simplicity • Proven Design PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

34. Braking and Seating • Seating: • Weld slider brackets • Drill holes on both sides • Weld seat sectionals • Slide material • Braking: • Extend brake cable • Attach brakes to handles PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

35. TESTING • LAND • WATER • TRANSITION PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

36. Testing on Land • Speed • Braking • Turning • Reverse* PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

37. Speed Data PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

38. Speed Test Method PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

39. Braking Data PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

40. Braking Test Method PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

41. Turning Test Method PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

42. Testing on Water • Buoyancy • Stability • Speed • Transition PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

43. Buoyancy Test Method w/ Rider w/out Rider PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

44. Buoyancy Data PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

45. Stability Test Method PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

46. Stability Data PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

47. Speed Test Method PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

48. Speed Data PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

49. Transition: Land to Water PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION

50. Transition: Water to Land PROJECT OVERVIEW DESIGN & PROTOTYPE THANK YOU TESTING CONCLUSION