Difference between revisions of "Energy Efficiency"

Latest revision as of 13:48, 19 November 2019

Key Stage 4

Meaning

Energy efficiency is a ratio of Useful Energy transferred to total energy put into a system.

About Efficiency

Energy efficiency is a measure of how effectively energy is transferred from one energy store into an intended energy store.

Efficiency may be written as a percentage or as a decimal.

Efficiency as a percentage can never be greater than 100% and as a decimal can never be greater than 1 because you can never get more energy out than you put in due to Conservation of Energy.

Equation

Efficiency = (Useful Energy Out)/(Total Energy In)

\(Efficiency = \frac{E_{Useful}}{E_{Total}}\)

Where:

E_Useful = The Useful Energy transferred to a device's intended purpose.

E_Total = The Total Energy transferred to a system.

References

AQA

Energy efficiency, pages 16-19, 21, GCSE Physics; Third Edition, Oxford University Press, AQA

Edexcel

Energy efficiency, pages 318-319, GCSE Combined Science, Pearson Edexcel

Energy efficiency, pages 36-37, GCSE Physics, Pearson Edexcel

@@ Line 5: / Line 5: @@
 ===About Efficiency===
 : '''Energy efficiency''' is a [[measure]] of how effectively [[energy]] is [[Energy Transfer|transferred]] from one [[Energy Store|energy store]] into an intended [[Energy Store|energy store]].
-: '''Efficiency''' may be written as a [[percentage]] or as a [[decimal]].
+: '''Efficiency''' may be written as a [[percentage]] or as a decimal.
-: '''Efficiency''' as a [[percentage]] can never be greater than 100% and as a [[decimal]] can never be greater than 1 because you can never get more [[energy]] out than you put in due to [[Conservation of Energy]].
+: '''Efficiency''' as a [[percentage]] can never be greater than 100% and as a decimal can never be greater than 1 because you can never get more [[energy]] out than you put in due to [[Conservation of Energy]].
 ===Equation===
-<math>Efficiency = \frac{Useful_{ } Energy_{ } Out}{Total_{ } Energy_{ } In}</math>
+'' '''Efficiency''' = ([[Useful Energy]] Out)/([[Total Energy]] In)''
+<math>Efficiency = \frac{E_{Useful}}{E_{Total}}</math>
+Where:
+E<sub>Useful</sub> = The [[Useful Energy]] [[Energy Transfer|transferred]] to a device's intended purpose.
+E<sub>Total</sub> = The [[Total Energy]] [[Energy Transfer|transferred]] to a [[system]].
+===References===
+====AQA====
+:[https://www.amazon.co.uk/gp/product/019835939X/ref=as_li_tl?ie=UTF8&camp=1634&creative=6738&creativeASIN=019835939X&linkCode=as2&tag=nrjc-21&linkId=57e96876985fc39b1a3d8a3e3dc238b6 ''Energy efficiency, pages 16-19, 21, GCSE Physics; Third Edition, Oxford University Press, AQA '']
+====Edexcel====
+:[https://www.amazon.co.uk/gp/product/1292120193/ref=as_li_tl?ie=UTF8&camp=1634&creative=6738&creativeASIN=1292120193&linkCode=as2&tag=nrjc-21&linkId=572df39392fb4200db8391d98ae6314e ''Energy efficiency, pages 318-319, GCSE Combined Science, Pearson Edexcel '']
+:[https://www.amazon.co.uk/gp/product/1292120223/ref=as_li_tl?ie=UTF8&camp=1634&creative=6738&creativeASIN=1292120223&linkCode=as2&tag=nrjc-21&linkId=068ecf40278c32406a7f1c6e66751417 ''Energy efficiency, pages 36-37, GCSE Physics, Pearson Edexcel '']