1. Simple Machines

2. Biblical Reference
The wheels were made like chariot wheels; the axles, rims, spokes and hubs were all of cast metal.
1 Kings 7:33

3. What is a Simple Machine?
A simple machine has few or no moving parts.
Simple machines make work easier.
Simple Machines:
Transfer a force from one place to another.
Change the direction of a force.
Increase the distance or speed of a force.

4. What is a Simple Machine?
Six types of simple machines do work using only one movement.
Lever
Wheel and Axle
Inclined Plane
Wedge
Screw
Pulley

5. Levers
A lever is a rigid bar that rotates around a fixed point, called the fulcrum.
The bar can be either straight or curved.
Force is applied at one end of a lever, and the force is transferred to a load at the other end.

6. Three Classes of Levers
The class of a lever is determined by the location of the applied force and the load in relation to the fulcrum.

7. First Class Levers
In a first-class lever, the fulcrum is between the input force and the output force.
The direction of the input force is opposite the direction of the output force

8. First Class Levers
A finger tab on a beverage can is a first-class lever.

9. Second Class Levers
A second-class lever has the output force between the input force and the fulcrum.
The output force and the input force act in the same direction.
A second-class lever makes the output force greater than the input force.

10. Second Class Levers
A wheel barrow is an example of a second-class lever.

11. Third Class Levers
A third-class lever has the input between the output force and the fulcrum.
The output force is less than the input force. Both the input force and the output force act in the same direction.

12. Third Class Levers
A rake is an example of a third-class lever.

13. Levers on the Human Body
The neck, foot, and arm are examples of first-, second-, and third-class levers in the human body..

14. Mechanical Advantage of Levers
The ideal mechanical advantage of a lever equals the length of the input arm divided by the length of the output arm.

15. 1st Class Lever MA

16. 2nd Class Lever MA

17. 3rd Class Lever MA

18. Wheel & Axle The wheel and axle are a simple machine.
The axle is a rod that goes through the wheel which allows the wheel to turn.
Gears are a form of wheels and axles

19. Wheel & Axle
For a wheel & axle, the length of the input arm is the radius of the wheel; the length of the output arm is the radius of the axle.
A screwdriver is a wheel & axle. The handle is the wheel and the shaft is the axle.

20. Wheel & Axle MA
Even though no machine is 100% efficient, you can calculate the ideal mechanical advantage of a wheel and axle.

21. Inclined Planes
An inclined plane is a flat surface that is higher on one end
Inclined planes make the work of moving things easier
Can be used to change effort and distance involved in doing work.

22. Inclined Planes Moving a sofa is easier using a ramp.
Using a ramp only requires a 100-N force to move the 500-N sofa.
Because of friction, no ramp operates at its ideal mechanical advantage.

23. Inclined Plane MA
The ideal mechanical advantage of an inclined plane equals its length divided by its height.

24. Inclined Planes
The longer or less-sloped an inclined plane is, the less force is needed to move an object along its surface.
A wagon train often went back and forth up a steep hill to reduce the slope to help a team pull a heavy load
This same technique is used in modern freeways, which travel winding paths up steep mountains

25. Wedge A sloped surface that moves is called a wedge.
A wedge is really a type of inclined plane with one or two sloping sides.
The MA of a Wedge is the length of either slope divided by the thickness of the big end.

26. Screw A screw is an inclined plane wrapped around a cylinder.
The inclined plane allows the screw to move itself when rotated.
When you turn a screw, the screw threads change the input force to an output force and the output force pulls the screw into the material.

27. Screw MA
The MA for a screw is the number of threads per linear inch.

28. Pulleys Pulley are wheels and axles with a groove around the outside.
A pulley needs a rope, chain or belt around the groove to make it do work.
A pulley can be used to change the direction of a force or gain mechanical advantage.

29. Fixed Pulley
A fixed pulley only changes the direction of the force.

30. Movable Pulley
Movable pulleys are attached to the object being lifted and decrease the force needed to lift the object.

31. Pulley System
A pulley system is a combination of fixed and movable pulleys that work together.

32. Pulley MA
The ideal mechanical advantage of a pulley or a pulley system is equal to the number of sections of rope supporting the object.

33. Compound Machines
Simple Machines can be put together in different ways to make complex machinery.
Compound Machines can be as small as a watch or large as a tank.

34. Gears A gear is a wheel and axle with teeth around the wheel.
Two or more gears working together form a compound machine.
When the teeth of two gears interlock, turning one gear causes the other to turn.
Gears of different sizes turn at different speeds.

35. Compound Machine Efficiency
The efficiency of a compound machine is calculated by multiplying the efficiencies of each simple machine together.
Each simple machine decreases the overall efficiency of the compound machine.
Example: Wheel & Axle (93%), Screw (88%), Lever (91%) & Wedge (96%)

36. Everyday Compound Machines

37. Everyday Compound Machines

38. Pop Quiz
What are levers, wheels and axles, inclined planes, wedges, screws, and pulleys examples of?
A. Complex Machines
B. Compound Machines
C. Ideal Machines
D. Simple Machines

39. Pop Quiz
Which uses less force to raise an object compared to lifting the object straight up?
A. Fulcrum
B. Inclined plane
C. Screw
D. Wheel

40. Pop Quiz
Which is a simple machine consisting of a grooved wheel with a rope or cable wrapped around it?
A. Gear
B. Pulley
C. Screw
D. Wedge