ENERGY

CH

AP

TE

R 4

WORK

Work is done on an object when a force moves an object through a distance

Work = force x distance

Work is measured in Joules (Newton-meter)

Examples: Pushing a swing Lifting a box Carrying a box – no work is done! If 90° angle,

between force and motion

PROBLEMS

You push a refrigerator with a horizontal force of 100 N. If you move the refrigerator a distance of 5 m with pushing, how much work do you do?

Work = force x distance

W = fd

W = (100 N)(5 m)

= 500 J

PROBLEMS

A couch is pushed with a horizontal force of 80 N and moves a distance of 5 m across the floor. How much work is done on the couch?

Work = force x distance

W = fd

W = (80 N)(5 m) = 400 J

PROBLEMS

How much work do you do when you lift a 100 N child 0.5 m?

Work = force x distance

W = fd

W = (100 N)(0.5 m)

= 50 J

PROBLEMS

The brakes on a car do 240,000 J of work in stopping the car. If the car travels a distance of 40 m while the brakes are being applied, how large is the average force that the brakes exert on the car?

W = fd

F = W/d

F = (240,000 J)/(40 m)

= 6000 J

ENERGY

Is defined as the ability to do work or cause a change

Work is the transfer of energy Measured in Joules System: anything around which you can imagine

a boundary

TYPES OF ENERGY

Kinetic energy

Energy of motion

Depends upon mass and velocity

Kinetic energy (in J) = ½ mass (in kg) x [velocity (in m/s)]2

KE = ½ mass x velocity2 = mass x velocity2

2KE ↑ as mass ↑KE ↑ as velocity ↑

POTENTIAL

Stored energy

It has the potential to do work

Elastic PE – Energy that is stored by compressing or stretching an object

Chemical PE – Energy due to chemical bonds

Gravitational PE – depends on heightMass (kg) x gravity (N/kg) x height (m)

GPE = mgh where g = 9.8 N/kg

PROBLEMS

A jogger moving forward with a mass of 60.0 kg is moving forward at a speed of 3.0 m/s. What is the jogger’s kinetic energy from this forward motion?

KE = ½ (mass x velocity2 )

KE = ½ (60.0 kg) (3.0 m/s)2

KE = ½ (60.0 kg)(9.0 m2/s2)

= 270 J

PROBLEMS

A baseball with a mass of 0.15 kg is moving at a speed of 40 m/s. What is the baseball’s kinetic energy from this motion?

KE = ½ (mass x velocity2 )

KE = ½ (0.15 kg) (40.0 m/s)2

KE = ½ (0.15 kg)(1600 m2/s2)

= 120 J

PROBLEMS

A 4.00 kg ceiling fan placed 0.25 m above floor. What is the gravitational potential energy of the Earth-ceiling fan system relative to the floor?

GPE = mass x gravity x height

GPE = mgh

GPE = (4.00 kg)(9.8 N/kg)(0.25 m)

= 9.8 N•m = 9.8 J

PROBLEMS

An 8.0 kg history textbook placed on 1.25 m high desk. How large is the gravitational potential energy of the textbook-Earth system relative to the floor?

GPE = mass x gravity x height

GPE = mgh

GPE = (8.0 kg)(9.8 N/kg)(1..25 m)

= 98 N•m = 98 J

CONSERVATION OF ENERGY

Energy cannot be created or destroyed.

Energy can only be converted from one form to another or transferred from one place to another.

Mechanical energy is the sum of the kinetic and potential energy of the objects in a system Example: running water, swing Swing