Energy & Power in Appliances (Oxford AQA IGCSE Physics)

Revision Note

Power & Energy in Appliances

The power of an appliance is defined as:

The rate at which energy is transferred by an appliance

Power can be calculated using:

$P = \frac{E}{t}$

Where:
- P = power measured in watts (W)
  - The watt is equivalent to joules per second (J / s)
- E = energy transferred measured in joules (J)
- t = time measured in seconds (s)
This equation can also be written as

$P = \frac{W}{t}$

Where:
- W = work done measured in joules (J), which is equivalent to energy transferred

Exam Tip

The equation will be given in both forms on your equation sheet for your exam.

Time is an important consideration when it comes to power
Two cars transfer the same amount of energy, or do the same amount of work to accelerate over a distance
If one car has more power, it will transfer that energy, or do that work, in a shorter amount of time

Two cars with different amounts of power

Two cars, the one with greater power reaches a greater kinetic energy quicker, IGCSE & GCSE Physics revision notes — **Two cars accelerate to the same final speed, but the one with the most power will reach that speed sooner**

Two electric motors:
- lift the same weight
- by the same height
- but one motor lifts it faster than the other
The motor that lifts the weight faster has more power

Two motors with different amounts of power

The more powerful motor does more work against gravity in a given time, downloadable AS & A Level Physics revision notes — **The motor with the most power lifts the weight faster for a given height**

Power ratings are given to appliances to show the amount of energy transferred per unit time
Common power ratings are shown in the table below:

Power Rating Table

Appliance	Power Rating
Torch	1 W
Light bulb	10 - 100 W
Electric cooker	10 000 W or 10 kW (1 kW = 1000 W)
Railway engine	1 000 000 W or 1 MW (megawatt)
Saturn V space rocket	100 MW
Large power station	10 000 MW
Global demand for power	10 000 000 MW
Star (similar in size to the Sun)	100 000 000 000 000 000 000 MW

Power, Current & Potential Difference

The power of a device depends on:
- The potential difference across the device
- The current flowing through the device
The power transferred to an electrical component (or appliance) is given by the equation:

$P = I \times V$

Where:
- P = power measured in watts (W)
- V = potential difference measured in volts (V)
- I = current measured in amps (A)

Worked Example

A 12 V battery supplies a lamp. The lamp is supplied with 2880 J every minute.

The lamp manufacturer can make fuses rated to 3 A, 5 A or 15 A.

Suggest which fuse they have fitted in the lamp.

Answer:

Step 1: List the known quantities

Energy transferred, E = 2880 J
Time, t = 1 minute = 60 s
Potential difference supplied, V = 12 V

Step 2: Find the power equation from the equation sheet

$P = \frac{E}{t}$

Step 3: Substitute energy and time into this equation

$P = \frac{2880}{60} = 48 W$

Step 4: Rearrange the electrical power equation from the equation sheet for the current

$P = I \times V$

Divide both sides by V

$\frac{P}{V} = \frac{I \times V}{V}$

$I = \frac{P}{V}$

Step 5: Substitute power and potential difference

$I = \frac{48}{12} = 4.0 A$

Step 6: Suggest a suitable fuse

A fuse should be rated to just over the normal operating current
3A is below the normal operating current of 4 A
15 A is too high above the normal operating current of 4 A
The most suitable fuse is the 5 A fuse

Energy, Potential Difference & Charge

The potential difference across a component is defined as:

The energy transferred per unit charge

In equation form, the energy transferred can be written as:

$E = Q \times V$

Where:
- E = energy transferred measured in joules (J)
- V = potential difference measured in volts (V)
- Q = charge measured in coulombs (C)
This can be combined with the power definition to produce the electrical power equation:
Recall that power is defined as:

$P = \frac{E}{t}$

Substitute the equation above into this definition

$P = \frac{Q \times V}{t}$

This is equivalent to

$P = \frac{Q}{t} \times V$

Finally, recall the definition of the current

$I = \frac{Q}{t}$

Substituting this into the previous equation gives the electrical power equation

$P = I \times V$

Exam Tip

In your equation sheet, the energy transferred equation is given as

$V = \frac{E}{Q}$

Make sure you are confident in rearranging this to the form given in this spec point.

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