Difference between revisions of "Work Done"
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:<math> W = 0J</math> | :<math> W = 0J</math> | ||
No work has been done because the movement is not in the direction of the force. The weight acts downwards but the movement was horizontal. | No work has been done because the movement is not in the direction of the force. The weight acts downwards but the movement was horizontal. | ||
+ | |||
+ | ===Work Done by Deformation=== | ||
+ | : When an [[object]] is [[deformation|deformed]], such as a spring being stretched, '''work''' is done to [[Energy Transfer|transfer energy]] into its [[Elastic Potential Energy Store]]. | ||
+ | |||
+ | ====Work Done on a Spring==== | ||
+ | {| class="wikitable" | ||
+ | |- | ||
+ | |[[File:HookesLawSpring.png|center|400px]] | ||
+ | |- | ||
+ | | style="height:20px; width:200px; text-align:left;" |'''Work''' is done to stretch this spring. | ||
+ | |} | ||
+ | |||
+ | : The Force needed to stretch a spring is proportional to the extension of the spring ([[Hooke's Law]]). Force = Spring Constant x Extension | ||
+ | : The '''Work Done''' on an object is proportional to the force and the distance traveled. Work Done = Force x Distance | ||
+ | : The distance moved is the same as the extension 'x'. | ||
+ | These two equations can be combined: | ||
+ | <math>F = kx</math> | ||
+ | <math>W = Fx</math> | ||
+ | <math>W = (kx) \times x</math> | ||
+ | <math>W = kx^2</math> |
Revision as of 10:17, 14 October 2018
Contents
Key Stage 3
Meaning
Work Done is the amount of energy transferred by the action of a force.
About Work Done
- Work Done is measured in Joules.
- Work Done can only be calculated for objects moving in the direction of the force.
Equation
Work Done = Force X Distance moved in the direction of the force \[ W = F \times d\] \[ W = Fd\]
- Work done is written with a capital W. Force is written with a capital F. Distance is written with a lower case d.
Example Calculations
- 1. A person lifts a 40N box by a height of 1.2m. Calculate the work done by the person against gravity.
- Force = 40N
- Distance moved in the direction of the force = 1.2m
\[ W = Fd\] \[ W = 40 \times 1.2\] \[ W = 48J\]
- 2. The brakes on a car apply a force of 10,000N. The car travels a distance of 15m braking. Calculate the work done by the brakes.
- Force = 10,000N
- Distance moved in the direction of the force = 15m
\[ W = Fd\] \[ W = 10,000 \times 15\] \[ W = 15,000J\]
- 3. A person carries a 20N box along a horizontal path of 20m.
- Force = 40N
- Distance moved in the direction of the force = 0m
\[ W = Fd\] \[ W = 20 \times 0\] \[ W = 0J\] No work has been done because the movement is not in the direction of the force. The weight acts downwards but the movement was horizontal.
Work Done by Deformation
- When an object is deformed, such as a spring being stretched, work is done to transfer energy into its Elastic Potential Energy Store.
Work Done on a Spring
Work is done to stretch this spring. |
- The Force needed to stretch a spring is proportional to the extension of the spring (Hooke's Law). Force = Spring Constant x Extension
- The Work Done on an object is proportional to the force and the distance traveled. Work Done = Force x Distance
- The distance moved is the same as the extension 'x'.
These two equations can be combined\[F = kx\] \(W = Fx\) \(W = (kx) \times x\) \(W = kx^2\)