Choosing a plug fuse
It is likely that most of your mains powered appliances will sport a BS1363 13A Mains plug on the end of their flex. This plug is highly regarded for its safety (the ability to reliably carry high currents for long periods without overheating, the standard inclusion of shutters to make them "child safe" etc), but it also has another uncommon feature, the inclusion of an internal Fuse.
This article will explain how to choose which rating fuse to use in a UK mains plug.
In electrical wiring systems, fuses and circuit breakers are used to protect both the users and the systems themselves when something goes wrong. They are a deliberate "weak link" that will cut the power, and so greatly reduce the risk of fire and serious electrical shock.
The inclusion of this fuse allows UK socket circuits to be protected by a much higher current circuit breaker. So the circuit as a whole can provide power to many sockets and appliances since the circuit breaker for the whole circuit no longer needs to have a low enough trip threshold to the protect the flex of every appliance on the circuit as well as the circuit cables themselves.
What fuse should I use?
The plugs accept standard BS1362 fuses, which are commonly available in 3A, 5A, and 13A ratings. (other capacities are also available, but not as easy to find in normal shops).
With most modern electrical appliances (there are exceptions - see below), the fuse in the plug has one purpose and one purpose only - to protect the flex between the plug and the appliance from the effects of the massive "fault current" that could flow in the flex should it be badly damaged or even cut.
The term "fault current" has a very specific meaning when talking about electrical circuits. It is what you get when current follows an abnormal path through or around the load - usually directly from live to neutral, or from live to earth.
In normal operation the appliance itself limits the current flowing, but under fault current conditions there is nothing to limit the current flow other than the tiny resistance of the copper cables themselves. This can result in huge currents that will typically be 100s of amps, or in some cases 1000s of amps.
Unsurprisingly, if you stick 1000 amp through a flex that only has a maximum continuous current rating of 3A or 13A, it is going to get very very hot very quickly. Its insulation will melt and char, it may burst into flames, and in some cases could even "explode" (a very dangerous event known as an "arc flash").
The key to stopping this from happening, is to interrupt the current flow very quickly, This needs to happen in a fraction of a second (i.e. a 10th of a second or less).
It may seem counter intuitive, but since fault currents are so large, even a 13A fuse will protect a 3A flex from the effects of a fault current in the vast majority of cases.
So you might wonder, if a 13A fuse can do the job, why would you need any of the other values? There are some specific cases we will cover shortly where a 13A fuse can't be used, but while no longer strictly necessary, many still consider it good practice to pick a fuse that is more closely matched to the expected load of the appliance. If nothing else you might get fewer sparks when you accidentally cut the mains lead, and a lower risk of a melted flex if you manage to damage it in such a was as it only has a partial short circuit on it.
In most cases the decision will be :
Is the appliance power consumption less than 720 watt?,
- If yes, fit a 3A fuse,
- otherwise fit a 13A fuse.
(The 720W number being 3A x 240V since the power of an appliance is typically the product of its voltage and current draw).
A slightly more nuanced approach would be to divide the power rating by 240V and pick the next fuse size larger than that.
So for a 1kW appliance, the sum would be 1000 / 240 = 4.16A. So fit a 5A fuse or higher.
|Table Lamp||Most lamps are limited to 60W loads or lower. With modern replacement LED lamps the actualy load may be significantly lower.|
|Alarm clock||Or any mains powered clock|
|Flat screen TV or monitor||Modern LCD and OLED screens|
|Radio||and other small electronic devices|
However there are some appliances that while they have normal operating currents less than 3A, they may experience high "inrush" currents at startup. These may result in a 3A fuse blowing when on the face of it, it looks like it would be ok.
|Old style CRT Television||Colour TVs have a powerful "degauss" feature that will briefly draw a high current|
|Appliances with larger transformers||Like some high power HiFi amplifiers. Microwave ovens.|
|Some computer systems||Those with high power CPUs and Graphics cards (often "gaming" PCs)|
|Laser Printer||During normal operation most laser printers draw relatively little power, however they do have a heater in their fuser unit that may draw a high current for a short time when powering up or coming out of standby.|
|Appliances with induction motors.||Induction motors swallow a big gulp of current while getting up to speed. You will often find these in devices with "quiet" motors like ans, fridges, freezers etc.|
Modern UK appliances are designed to meet harmonised standards that will allow them to be sold anywhere in the European Union and frequently worldwide. (Even though the UK is no longer part of the EU, all equipment made here will still meet the same standards to allow export to other countries). Since most countries don't have fused plugs, the equipment design can't take advantage of the presence of the plug fuse in the UK for any purpose other than for protection of the flex - since sold in most countries, it won't be there!
With a modern appliance design, if it it known that it needs some kind of overload protection (say because there a way it can be used or abused, or there is a known mechanism that could cause it to draw more current than it should), then it must include this internally. While the plug fuse might also be able to protect the appliance in this circumstance, the design must not rely on it.
Old appliances are one special case. If you go back far enough in time (30 - 40 years or more) you will find some appliances which were designed specifically for the UK market and not intended for export. Here the designers could and did rely on the plug fuse to also protect the internals of the device as well as the flex. The plug for these must be fitted with the fuse specified by the instructions, or if these are not available, by calculating the size as described above.
Many modern appliances, and most detachable mains leads will come with "moulded on" plugs. Usually the plug itself (and often a label fixed to the flex) will state what fuse is required. You must never fit a fuse with a higher capacity than specified.
Extension leads, and in particular extension leads with multiple sockets on the far end, may often specify the maximum capacity of the plug fuse. This may be a less common rating like 10A.
This is an example of an "appliance" (if that is not stretching the definition a bit!), where the plug fuse is also being relied on to provide some overload protection, and not just protection from fault currents. If the lead has several sockets on the end, it would be possible to connect a load of significantly more than 13A. Better quality leads will have a fuse in the socket end to stop this overload being "felt" by the lead, but many don't
Many longer extension leads are also of a "marginal" design - using slightly undersized cable to keep weight and cost down (with the anticipation that the loads on the end will likely be shorter term loads (power tools etc), and hopefully the user has read the instructions about not using the lead while still coiled!).
Many multi-way power strips are built to a price and quality which makes them unsuitable for higher loads anyway, and it is often advisable to fit a 10A fuse to these, even if they come pre-fitted with a 13A fuse.
Modified Appliances (extended cables)
If an appliance has had its mains lead changed for a longer one, it may need more closely matched fuse protection. Often when manufactures fit mains leads with a thin cross section (say 0.5mm², rated for ~3A continuous load), they will also only fit a relatively short length. This is to ensure that the overall cable resistance remains low enough to blow a 13A fuse or open a 16A circuit breaker should a fault occur at the far end of the lead.
If you extend the lead and use the same gauge of flex, this may no longer be true, and you may also need to fit a lower capacity fuse to ensure it is adequately protected.
(there is a way of calculating when this becomes necessary by using the adiabatic check formula described here).