Gearing

1. Gearing

2. Very Simple Chain Theory 16 32 Let us start with a very simple example

3. Building a Robot Chain Theory 16 32

4. Building a Robot Chain Theory 16 32

5. Building a Robot Chain Theory 16 32

6. Building a Robot Chain Theory 16 32

7. Building a Robot Chain Theory 16 32

8. Building a Robot Chain Theory 16 32

9. Building a Robot Chain Theory 16 32

10. Building a Robot Chain Theory 16 32

11. Building a Robot Chain Theory 16 32

12. Building a Robot Chain Theory 16 32

13. Building a Robot Chain Theory 16 32

14. Building a Robot Chain Theory 16 32

15. Building a Robot Chain Theory 16 32

16. Building a Robot Chain Theory 16 32

17. Building a Robot Chain Theory 16 32

18. Building a Robot Chain Theory 16 32

19. Building a Robot Chain Theory 16 32

20. The Effect on Speed • When gears are combined, there is also an effect on the output speed. • To measure speed we are interested in the circumference of the gear, C= 2  r. • If the circumference of Gear1 is twice that of Gear2, then Gear2 must turn twice for each full rotation of Gear1. • => Gear2 must turn twice as fast to keep up with Gear1.

21. Gearing Law for Speed • If the output gear is larger than the input gear, the speed decreases. • If the output gear is smaller than the input gear, the speed increases. • => Gearing up decreases speed • => Gearing down increases speed

22. Gearing Laws

23. Gearing Law for Speed • These are all important when you are building a robot

24. Gearing in robots • Gears are used to alter the output torque of a motor. • The force generated at the edge of a gear is equal to the ratio the torque and the radius of the gear (T = F r), in the line tangential to its circumference. • This is the underlying law behind gearing mechanisms. force F = T / r r T = F r

25. Building a Robot Chain Theory Torque output = Torque input radius output / radius input

26. Gear Radii and Force/Torque • By combining gears with different radii, we can manipulate the amount of force/torque the mechanism generates. • The relationship between the radii and the resulting torque is well defined • The torque generated at the output gear is proportional to the torque on the input gear and the ratio of the two gear's radii.

27. Example of Gearing torque t1 • Suppose Gear1 with radius r1 turns with torque t1, generating a force of t1/r1 perpendicular to its circumference. • If we mesh it with Gear2, with r2, which generates t2/r2, then t1/r1 = t2/r2 • To get the torque generated by Gear2, we get: t2 = t1 r2/r1 • If r2 > r1, we get a bigger torque, • if r1 > r2, we get a smaller torque. r1 force of t1/r1 r2 Forces are equal

28. Gearing Law for Torque • If the output gear is larger than the input gear, the torque increases. • If the output gear is smaller than the input gear, the torque decreases. • => Gearing up increases torque • => Gearing down decreases torque

29. Exchanging Speed for Torque • When a small gear drives a large one, torque is increased and speed is decreased. Analogously, when a large gear drives a small one, torque is decreased and speed is increased. • Gears are used in DC motors (which are fast and have low torque) to trade off extra speed for additional torque. • How?

30. Gear Teeth • The speed/torque tradeoff is achieved through the numbers of gear teeth • Gear teeth must mesh well. • Any looseness produces backlash, the ability for a mechanism to move back & forth within the teeth, without turning the whole gear. • Reducing backlash requires tight meshing between the gear teeth, which, in turn, increases friction.

31. Mobile Robot on wheels, Speed considerations

32. Robot Speed Mobile base design, general assumptions.

33. Robot Speed

34. Building a Robot

35. Robot Speed What size wheel should I use if I want my robot’s maximum speed to be 3 feet per second?

36. Robot Speed What size wheel should I use if I want my robot’s maximum speed to be 3 feet per second?

37. Building a Robot Robot Speed What size wheel should I use if I want my robot’s maximum speed to be 3 feet per second? (6 inches)

38. Building a Robot Robot Speed If the 6” wheels are the largest in the kit, how would I make my robot’s maximum speed 1.5 feet per second (without damaging the motor or making custom wheels)?

39. Building a Robot Robot Speed If the 6” wheels are the largest in the kit, how would I make my robot’s maximum speed 1.5 feet per second (without damaging the motor or making custom wheels)?

40. Building a Robot Robot Speed If the 6” wheels are the largest in the kit, how would I make my robot’s maximum speed 1.5 feet per second (without damaging the motor or making custom wheels)?

41. Building a Robot Robot Speed If the 6” wheels are the largest in the kit, how would I make my robot’s maximum speed 1.5 feet per second (without damaging the motor or making custom wheels)? Put a sprocket on the motor that is half the size of the sprocket on the wheel.

42. Gear Reduction Example • To achieve “three-to-one” gear reduction (3:1), we combine a small gear on the input with one that has 3 times as many teeth on the output • E.g., a small gear can have 8 teeth, and the large one 24 teeth • => We have slowed down the large gear by 3 and have tripled its torque.

43. Gears in Series • Gears can be organized in series, in order to multiply their effect. • E.g., four 3:1 gears in series result in 12:1 reduction. This requires a clever arrangement of gears (see book). • Gears in series can save space • Multiplying gear reduction is the underlying mechanism that makes DC motors useful and ubiquitous.

44. Principles of using Gears in robots • Transfer rotation from one axle to another • Even number of gears reverses the direction of rotation • The radii determine gear spacing, transferred speed, and power • Inverse relationship between power and speed • There are lots of gear spacing issues beyond the scope of this talk • Special half-stud beams or diagonal spacing sometimes help • An eight tooth gear has a diameter equal to one stud • 8, 24, and 40 tooth gears work well together because their radii are all multiples of 0.5

45. Gears (continued) • Worm gears • Are effectively one tooth gears • Significant efficiency lost to friction • Since they can’t be back driven, they are great for arms that should hold their position • Some good gear info at • http://www.owlnet.rice.edu/%7Eelec201/Book/legos.html

46. Gears: Basics DC motors usually run at too high a speed or too low a torque for controlling a small robot. Thus, a DC must be geared down. Drive Gear Pinion Wheel Motor

47. Calculating Gear Ratios

48. Calculating Gears Ratios for a Gear Train Wheel Motor Increase torque Gear Train: ratio 1:6 Decrease speed

49. Gears: Types and Descriptions Spur Gears Helical Gears Bevel Gears Worm Gears Straight Gears

50. Practical Lego Designs