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Work, Power, and Machines

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Presentation on theme: "Work, Power, and Machines"— Presentation transcript:

1 Work, Power, and Machines
Section 8.1

2 Objectives Define work and power
Calculate the work done on an object and the rate at which work is done Use the concept of mechanical advantage and calculate it

3 Is this considered work?

4 Work Definition: A quantity that measures the effects of a force acting over a distance Equation: W = Force * distance W = F * d Measured in units of Joules (J) No force = no work Example: A ball rolling on a flat surface at constant velocity No distance = no work Example: A weightlifter holding a huge weight overhead, but not moving it. Force and distance must also act parallel to each other, so is the ant actually doing any work?

5 Example A crane uses an average force of 5200 N to lift a girder 25 meters. How much work does the crane do on the girder? W = F * d W = (5200 N) * (25 m) W = 130,000 J

6 The definition of power?

7 Power Definition: A quantity that measures the rate at which work is done Equation: Power = work / time P = W / t Measured in units of Watts (W) In general: Doing the same amount of work but in less time requires more power. (running vs. walking upstairs to the 10th floor)

8 Example: A crane uses an average force of 5200 N to lift a girder 25 meters in a time of 150 seconds. Calculate the power output of the crane. W = F * d W = (5200 N) * (25 m) W = 130,000 J P = W / t P = (130,000 J) / (150 s) P = 870 W

9 Mechanical Advantage Definition: A quantity that measures how much a machine multiplies force or distance Equation: Mechanical advantage = output force / input force Mechanical advantage = input distance / output distance

10 A mathematical example:
W = F * d 2 J = 2 N * 1 m 2 J = 1 N * 2 m 2 J = 0.5 N * 4 m 2 J = 0.25 N * 8 m 2 J = N * 16 m 2 J = N * 32 m

11 Moral of the story: If you’re not superman, you can use mechanical advantage to lift a car by applying small forces repeatedly over larger distances to do the same amount of work

12 Example: Determine the mechanical advantage of an automobile jack that lifts a 9900 N car with an input force of 150 N. Mechanical advantage = output force / input force Mechanical advantage = 9900 N / 150 N Mechanical advantage = 66

13 Bonus: Rube-Goldberg Rube Goldberg device Watch for these things:
Count how many times gravity pulls an object downward. Count how many times a given object is moving. See if there are other ways in which energy is being stored and/or released.

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