chapter 14: work, power, & machines pg. 410 - 443

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Chapter 14: Work, Power, & Machines Pg. 410 - 443

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Page 1: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Chapter 14: Work, Power, & MachinesPg. 410 - 443

Page 2: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Unit 1: Work and PowerPg. 412 - 416

Page 3: Chapter 14: Work, Power, & Machines Pg. 410 - 443

What is work? Work is the product of force and

distance.

For a force to do work on an object, some of the force must act in the same direction as the object moves. If there is no movement, no work is done.

Was any work done to lift this barbell over the weightlifter’shead?

Is any work being done to keep this barbell in the air?

Page 4: Chapter 14: Work, Power, & Machines Pg. 410 - 443

What is work? Any part of a force that does not act in

the direction of motion does no work on an object.

Page 5: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Calculating WorkWork = Force [N] x Distance [m]

As the distance increases, what happens to the amount of work being done? What if it decreases?

What if the force is increased? Decreased?

Page 6: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Calculating WorkWork = Force [N] x Distance [m]

The joule [J] is the SI unit of work.

When a force of 1 Newton moves an object 1 meter, 1 joule of work is done.

[J]

Page 7: Chapter 14: Work, Power, & Machines Pg. 410 - 443

What is power? Power is the rate of doing work.

Doing work at a faster rate requires more power. To increase power, you can increase the amount of work done in a given time, or you can do a given amount of work in less time.

Page 8: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Calculating Power You can calculate power by dividing the

amount of work done by the time needed to do the work:

What happens to power as time is increased? Decreased?

Page 9: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Calculating Power The SI unit of power is the watt [w].

A watt is equal to 1 Joule per second.

Page 10: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Horsepower One horsepower [hp] is equal to about

746 watts.

Page 11: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Unit 2: Work and MachinePg. 417 - 420

Page 12: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Machines do Work Machines change a force to make work

easier to do. They change the size of a force needed, the direction of a force, or the distance over which a force acts.

Does the jack used to lift the car increase or decrease the force applied to it?

Why?

Page 13: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Work Input and Output Because of friction, the work done by a

machine is always less than the work done on the machine.

Page 14: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Work Input and Output The force you exert on a machine is called

the input force.

The distance the input force acts through is known as the input distance.

The work done by the input force acting through the input distance is called the work input.

Page 15: Chapter 14: Work, Power, & Machines Pg. 410 - 443
Page 16: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Work Input and Output The force that is exerted by a machine

is called the output force.

The distance the output force is exerted through is the output distance.

The work output of a machine is the output force multiplied by the output distance.

Page 17: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Unit 3: Mechanical Advantage and EfficiencyPg. 421 - 426

Page 18: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Mechanical Advantage The mechanical advantage of a

machine is the number of times that the machine increases an input force.

The actual mechanical advantage [AMA] is the ratio of the output force to the input force. In an ideal [IMA] situation, there would be no loss of force to friction. AMA is always less than IMA.

Page 19: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Unit 4: Simple MachinesPg. 427 - 435

Page 20: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Simple Machines The six types of simple machines are:

The lever The wheel and axel The inclined plane The wedge The screw And the pulley

Page 21: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Levers A lever is a rigid bar that is free to

move around a fixed point.

The fixed point is called a fulcrum.

The input arm is the distance between the input force and fulcrum. The output arm is the distance from the fulcrum to the output force.

Page 22: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Levers

Page 23: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Wheel and Axle A wheel and axle is a simple machine

that consists of two disks or cylinder, each one with a different radius.

Page 24: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Inclined Planes An inclined plane is a slanted surface

along which a force moves an object to a different elevation.

Page 25: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Wedges and Screws A wedge is a V-shaped object whose

sides are two inclined planes sloped toward each other.

Page 26: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Wedges and Screws A screw is an inclined plane wrapped

around a cylinder.

Page 27: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Pulleys A pulley is a simple machine that

consists of a rope that fits into a groove in a wheel.

Page 28: Chapter 14: Work, Power, & Machines Pg. 410 - 443

Compound Machines A compound machine is a

combination of two or more simple machines which operate together.