1. W O R K & S I M P L E M A C H I N E S The right tool for the right job.

2. W O R K Work is defined as a force applied over a distance. W = F d Work in Joules (Nm) = Force in Newtons (N) distance in meters (m) NOTE: If the object does not move in the direction of the force, NO WORK IS ACCOMPLISHED.

3. How much work is accomplished by moving a 600N crate 7 m? 1. 85.7 J 2. 0.012 J 3. 4200 J 4. 593 J 5. 607 J 6. 657979.9 J

4. How much work is accomplished by a 4500N piledriver falling 25 m? 1. 180 J 2. 112500 J 3. 0.005 J 4. 4475 J 5. 4525 J 6. 3.2 x 10 14 J

5. How far do you have to push a 300 N crate to accomplish 6000 J of work? 1. 1800000 m 2. 0.05 m 3. 20 m 4. 5700 m 5. 6300 m

6. Which of these unit combinations represents one Joule of work? 1. kg●m 2. kg●m/s 2 3. N●m/s 2 4. kg●m 2 5. N●m 6. kg 2 ●m/s 2

7. How much work is accomplished by an 80kg person walking 10 m upstairs? 1. 800 J 2. 8 J 3. 0.125 J 4. 7840 J 5. 70 J 6. 90 J

8. M A C H I N E S Machines are devices that help us accomplish work. They can do this by: –Redirecting a force –Multiplying a force –Both redirecting & multiplying a force

9. W O R K on M A C H I N E S The force you put into a machine is the Input or Effort Force (F e or F i ). The distance the machine moves because of the Effort Force is the Effort Distance (d e ). The Effort Force multiplied by the Effort Distance gives you the Work Input (W IN ) for the machine. F e ● d e = W IN

10. W O R K on M A C H I N E S The force the machine applies to another object is the Output or Resistance Force (F r or F o ). The distance the machine moves the other object because of the Resistance Force is the Resistance Distance (d r ). The Resistance Force multiplied by the Resistance Distance gives you the Work Output (W OUT ) for the machine. F r ● d r = W OUT

11. T R A D E – O F F In normal operations, –the person using the machine moves the machine with little force (F e ) through a large distance (d e ). –The machine moves an object with a large force (F r ) over a small distance (d r ). In essence, you are moving the machine an extra distance so the machine will apply extra force.

12. Which force do you supply to a machine? 1. Effort Force 2. Effort Distance 3. Input Force 4. Resistance Force 5. Resistance Distance 6. Output Force

13. How far does the machine move another object? 1. Effort Force 2. Effort Distance 3. Input Force 4. Resistance Force 5. Resistance Distance 6. Output Force

14. Which components comprise the Work Output? 1. Effort Force 2. Effort Distance 3. Resistance Force 4. Resistance Distance

15. Which of these do you increase on a machine? 1. Effort Force 2. Effort Distance 3. Resistance Force 4. Resistance Distance

16. Which of these does the machine increase? 1. Effort Force 2. Effort Distance 3. Resistance Force 4. Resistance Distance

17. Mechanical Advantage Mechanical Advantage describes the number of times a machine multiplies the force you apply to it. MA = F o / F i

18. What is the mechanical advantage of a machine that applies 35 N for the 25 N of force put into it? 1. 875 2. 0.7 3. 1.4 4. -10 5. 10

19. What is the MA of a machine that applies 100 N for the 15 N of force put into it? 1. 0.15 2. 6.7 3. 1500 4. -85 5. 85

20. What is the Force Output of a machine with a MA of 12 when you put 9 N of force into it? 1. 21 N 2. -3 N 3. 1.3 N 4. 0.75 N 5. 108 N

21. Simple Machines A Simple Machine accomplishes the work in one motion. A Compound Machine is made up of two or more simple machines. Most machines are compound machines.

22. The Lever A Lever is comprised of a bar that moves around a fixed point. The fixed point, or pivot point, is called the fulcrum. –The distance from where the effort force is applied to the fulcrum is the Effort Arm of the lever. –The distance from the fulcrum to where the resistance force is applied is the Resistance Arm.

23. MA LEVER The MA of a lever is calculated as: MA Lever = Effort Arm Resistance Arm (both in units of length, so there are no MA units) The longer the effort arm, the more the MA

24. 1 st Class Lever See-Saw (Teeter- Totter) Prying up a lid by pushing down on a bar Pairs: Scissors, Pliers, Hedgeclippers

25. 2 nd Class Lever Door Wheelbarrow Pairs: Shears, Nutcracker

26. 3 rd Class Lever WARNING: MA < 1 Increases distance, not force Anything you swing –Bat, sword, stick, golf club Brooms, rakes, mops

27. What is the MA of a lever with an Effort Arm of 6 m and a Resistance Arm of.3 m? 1. 2 2..2 3. 1.8 4. 0.05 5. 20 6. 200

28. Which type of lever does not increase the force output of the machine? 1. 1 st class 2. 2 nd class 3. 3 rd class 4. 4 th class

29. If a lever has a MA of 9, and a force of 6 N is applied, how much force will the lever apply? 1. 0.67 N 2. 1.5 N 3. 54 N

30. Wheel-and-Axle A simple machine made of two circles of different diameters that rotate together. The outer circle (wheel) is turned with less force over a larger distance so that the inner circle (axle) turns with more force over a shorter distance.

31. MA Wheel-and-Axle MA = r Wheel r Axle Explains how to steer larger vehicles with less force Ex. Steering wheels, door knobs, faucet handles

32. What is the MA of a Wheel with a 50 cm radius connected to an Axle with a 2.5 cm radius? 1. 125 2. 20 3. 0.05

33. Pulley The Pulley is a simple machine comprised of a wheel with a rope or chain running around it. The MA of a pulley system is equal to the number of supporting ropes.

35. 2 Types of Pulleys There are two kinds of pulleys, fixed and moveable. Fixed pulleys do not move, and only redirect force. Moveable pulleys are attached to the object being moved and multiply force.

36. The Block-and-Tackle A Block and Tackle system is a multiple- pulley system where large amounts of distance are converted into force.

37. What is the MA of this pulley system? 1. 1 2. 2 3. 3 4. 4 5. 5 6. 6 7. 7 8. 8 9. 9 10. 10

38. What is the Force Output of this pulley system? 1. 10 N 2. 100 N 3. 50 N 4. 500 N 5. 5000N

39. Inclined Plane The Inclined Plane is a sloping surface used to lift objects. It is easier to apply a small force over the slope of the ramp than to lift the object straight up the height of the ramp.

40. What is the MA of a ramp that is 12 m long but only 4 m tall? 1. 48 2. 0.33 3. 3 4. 8

41. The Wedge The Wedge is comprised of a moving inclined plane or two or more inclined planes put back-to-back.

42. The Screw A Screw is an inclined plane wrapped around a cylinder. MA is increased by increasing the pitch (slope) of the threads or the number of threads per unit length.

43. More on the screw A screw works when a material is pushed up the inclined plane formed by the threads As more material is in contact with the threads, the overall amount of friction increases Screws pull objects together (apart) and can hold more force than a nail of equal size

44. 2 Types of Simple Machines? In essence, the pulley and the wheel- and-axle are types of levers The wedge and screw are types of inclined planes

45. What is the function of an inclined plane? 1. Slide objects 2. Raise objects up 3. Transport objects over a long distance

46. What is the MA of an inclined plane with a height of 3 m and a length of 6 m? 1. 3 2. 20 3. 0.5 4. 9 5. 2

47. Which type of pulley multiplies force? 1. Fixed 2. Taffy 3. Moveable 4. Shank

48. What is the MA of a handle with a diameter of 9 cm if the post has a diameter of 3 cm? 1. 27 2. 12 3. 6 4. 3 5. 0.333

49. Which of these is an example of a lever? 1. Inclined Plane 2. Pulley 3. Wedge 4. Screw 5. Knife edge 6. Bolt

50. Which of these is an example of an inclined plane? 1. Wheel-and-Axle 2. Pulley 3. 2 nd Class lever 4. Wedge 5. Bicycle

51. Efficiency Describes how well machine converts the energy put into it Always shown as a percentage 100% efficient means that all of the energy put into the machine is applied to the object being worked on

52. 2 nd Law of Thermodynamics States that whenever energy is converted from one form to another, some energy is always lost as heat due to friction  no machine can be 100% efficient (an “Ideal Machine”)

53. Efficiency Formula W OUTPUT =F r x d r W INPUT =F e x d e If you wind up with an answer at more than 100%, you have your fraction upside-down If you wind up with an answer at more than 100%, you have your fraction upside-down X 100%

54. Converting percentages A whole number becomes a decimal out of 100 48% = 0.486% = 0.06 A decimal becomes a whole number, adding the percentage sign 0.21 = 21%0.75 = 75%

55. What is the efficiency of a machine that produces 89 J of work for the 100 J of work put into it? 1. 8900 J 2 2. 1.12 3. 0.89 4. 112% 5. 89%

56. What is the efficiency of a machine that produces 6100 J of work for the 9000 J of work put into it? 1. 1.48 2. 68% 3. 148% 4. 0.677 5. 54900000 J 2

57. What is the Work Output of a 62% efficient machine when 1000 J of work is put into it? 1. 0.62 J 2. 16.13 J 3. 620 J 4. 1612.9 J 5. 62000 J

58. How much work must be put into a 21% efficient machine to generate 34 J of useable work? 1. 7.14 J 2. 161.9 J 3. 714 J 4. 1.619 J

59. P O W E R Power is the rate at which work is accomplished P = W t W Pt

60. Power – Power – Power Power is measured in Joules per second, called Watts (W) For the same amount of work, less time requires more power

61. How much power applies 600 J of work in 9s? 1. 66.7 W 2. 5400 W 3. 0.015 W

62. Applying 21000 W of power produces how much work in 7 s? 1. 3000 J 2. 0.0003 J 3. 147000 J