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Work Work done is a measure of the energy transferred. E.g. when lifting a pencil I do work against the earth’s gravity force, energy has been transferred:

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Presentation on theme: "Work Work done is a measure of the energy transferred. E.g. when lifting a pencil I do work against the earth’s gravity force, energy has been transferred:"— Presentation transcript:

1 Work Work done is a measure of the energy transferred. E.g. when lifting a pencil I do work against the earth’s gravity force, energy has been transferred: chemical energy in my body has been turned into kinetic energy which is turned into potential energy as the pencil gains height.

2 Work Work done = Force x distance W = F x d Joules, J Newtons, N metres, m Example Calculate the work done by the brakes of a car if a 4.5kN average force are applied over a distance of 20 m.

3 Work done W = F x d F = 45 kN = 4.5x10 4 N, d = 20 m W = 4.5 x 10 4 x 20 W = 9.0 x10 5 J The car originally had 9.0 x10 5 J of kinetic energy. To bring the car to rest the brakes must do the exact same amount of work, 9.0 x 10 5 J.

4 Power This is the rate of doing work ( transferring energy ) i.e. work done per second Units are Watts, W 1 W = 1 J s -1 i.e. a 2000 W heater transfers 2000 J of electrical energy into heat energy every second

5 Power Calculate the work done by a 75kW motor running for 5 mins. P = 75 kW = 75 000 W t = 5 mins = 5 x 60 = 300 s

6 Potential Energy Energy stored in an object as it is lifted of the ground. Potential Energy mass gravitational field strength ( joules, J ) (kilograms,kg ) ( Newtons per kilogram, N kg -1 ) Change in height ( metres, m )

7 Potential energy This is really a special case of ‘doing work’ Work done = average force x distance moved If we lift something vertically at uniform speed then the forces acting on it are balanced F up = F gravity = m x g For a vertical distance we normally write h instead of d Therefore W = f x d W = m x g x h

8 Kinetic Energy Moving objects have kinetic energy, E k, Kinetic energy mass speed squared ( joules, J )( kilograms, kg ) ( metres per second squared

9 Kinetic energy Calculate the speed a 1000 kg van is moving at if it has 50 000 J of E k. E k = 50 000 J, m = 1000 kg v = ?

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