House Wiring for Beginners
House Wiring for Beginners gives an overview of a typical basic domestic mains wiring system, then discusses or links to the common options and extras.
Further information on options is available in the Rewiring Tips article.
- 1 Safety
- 2 Regulations
- 3 Word Meanings
- 4 Overview
- 5 Consumer Unit (CU)
- 6 Earthing
- 7 Residual Current Devices (RCD)
- 8 Sockets
- 9 Lighting
- 10 Bathroom Electrics
- 11 Kitchens
- 12 Misc Information
- 13 See Also
- This article cannot practically cover everything.
- The writing of this article may be incomplete when you read it.
- Laws and regulations change over time.
- Interpretation of regulations and law may change over time
- The article may assume knowledge that some readers might not possess
- Unexpected situations may change the specific requirements for some circuits.
Anyone installing wiring should also understand some basic safety issues not discussed here. This article is an introductory overview rather than a complete A to Z on rewiring, and assumes some basic electrical knowledge.
Some regulatory requirements are mentioned in this article. These apply to new wiring, and in many cases are not requirements for existing wiring.
The Electrical Glossary may be useful.
Typical house wiring diagram illustrates each type of circuit:
In a typical new town house wiring system, we have:
- Live & Neutral tails from the electricity meter to the CU
- A split load CU
- Ring circuits from 32A MCBs in the CU supplying mains sockets. 2 such rings is typical for a 2 up 2 down, larger houses have more.
- Radial lighting circuits from 6A CU MCBs. 2 or more circuits typical.
- Earth connection from incomer to CU.
- 10mm² Main equipotential bond to other incoming metal services (gas, water, oil)
Systems often have some of the following as well:
- Dedicated circuit MCB & cable supplying cooker
- Dedicated high current circuit MCB & cable supplying shower
- 2 way lighting switching for stairs, large rooms & walk through rooms
- Outdoor lighting supplied by a 6A MCB, often via a PIR motion detector switch.
- 16A MCB and cable supplying hot water immersion heater.
- MCB supplying storage heaters. Sometimes these are run from the main CU, but often from a timeswitch controlled dedicated CU (with either a separate "off peak" electricity meter, or a dual tariff meter).
The radial lighting circuit has 3 common wiring options, which may be mixed at will:
- "Loop-in" (as per diagram above). The circuit is fed to each lamp fitting in turn, and a separate cable connects from the fitting to the switch. (this is the most common method)
- Switch loop through (the circuit connects to each switch in turn, and a separate cable goes from the switch to each lamp)
- Junction box loop in, where the termination and feed connection are done at junction boxes, and cables run to switches and lamps from there.
- 20A radial socket circuits
- 10A lighting circuits are occasionally used
Consumer Unit (CU)
The Consumer Unit, previously called a fusebox, contains these things:
- A main isolating switch. This switches off everything.
- In most cases at least one RCD
- A fuse or MCB for each circuit. This cuts the power to the circuit in the event of high fault current.
- An earth connection block which connects earth to the earth wires of the various circuits
- 1 or 2 neutral connection blocks which supply the neutral connection to the Neutral wires of the various circuits
Split Load CU
Split load CUs have become popular in recent years, and ubiquitous since 2008 with the introduction of the 17th edition of the wiring regs. They usually offer significant advantages over the traditional unsplit CU type. See 17th Edition Consumer Units for more details.
The split load CU has the following advantages:
- Some wiring work can be carried out with just a section of a CU turned off, perhaps retaining access to light and power while working.
- Almost all faults can only take out the power to part of the system
- The split load arrangement means both RCDed and non RCDed loads can be supplied from the one CU.
Earthing is a fundamental safety system used in electrical installations. It works in co-ordination with circuit breakers MCBs, Fuses, and RCDs to ensure that an electrical supply can be disconnected quickly in the event of a fault. This greatly reduces shock risk.
Residual Current Devices (RCD)
The 17th Edition of the wiring regulations impose more frequent requirements to install RCD (or RCBO) protection than the previous 16th Edition. In general, ANY cable which is buried less than 50mm below a wall's surface AND is NOT mechanically protected, or wired in one of a number of specialised cable types that incorporate an earthed screen must have 30mA trip RCD protection. Such circuit protection may be derived from either an RCD protecting several circuits, or individual RCD/RCBOs on each circuit.
New installations will have two or more RCDs. Older ones may only have one or none. (currently half the properties in the UK have none according to research)
RCDs reduce the risks of injury from electric shock (they don't eliminate it completely), however they can also introduce reliability and issues of their own if not used in an appropriate way. Historically RCDs were usually only used on some circuits rather than all.
With a supplier provided earth connection, the most common historical arrangement was a split CU with a RCD on one side, and no RCD on the other. Generally the RCD side is used to supply sockets and shower, with most other items on the non-RCD side.
With a local earth rod, the situation is different in that all circuits must be RCD protected, since a local earth rod is not usually a sufficiently good earth on its own to clear all earth faults. So RCDs are used on all circuits even in older installations. A common option is to have the supply fed through a 100mA time delayed RCD, the output of which goes to a split CU with RCD on one side. This is not an ideal arrangement, as a large earth leakage fault on the non-RCD side will cause complete power failure, and sometimes inability to reset the power.
An RCBO is a combined RCD and MCB in one module, and is fitted in place of an MCB. RCBOs allow individual circuits to be protected by their own RCD without any risk that a fault in an unrelated circuit could cause it to trip. However protecting all circuits like this is more expensive.
Neutral Connections & RCDs
The same principle is true for RCBOs, each RCBOed circuit needs to have its neutral connected to the RCBO neutral and not elsewhere.
RCD or non-RCD side
- Lighting circuits
- Immersion heater circuits
- Circuits where disconnection is undesirable (i.e. freezers, fire alarms, boilers, etc)
All socket circuits, should have RCD protection since Plug-in are the source of almost all electrocutions.
Modern installations will typically provide additional RCDs so that vulnerable circuits (i.e. lighting) are unlikely to be affected by a nuisance trip, and so that circuit types prone to high earth leakage (e.g. things with heater elements and water in close proximity) are separately protected from others.
Sockets may be wired on ring circuits or radial circuits. Mostly rings are used, as they use less copper for most circuit layouts, they have safety advantages over radial circuits (sometimes debated), can provide more power, and cover more floor area per circuit.
Sockets are on 32A ring circuits in most house installations. These use a ring of cable (ie a loop), so that at the CU 2 cables are connected to the MCB instead of 1. An unlimited number of sockets may be connected on each ring.
One ring circuit per floor is a fairly common arrangement, but by no means the only option. Larger houses generally have more rings. Its also common to have a ring dedicated just for sockets in the kitchen since that is where you will find many of the highest power consuming appliances in a modern house.
Spurs are permitted, but sockets should be included in the ring rather than spurred wherever practical. Spurring is best only used for later additions to circuits.
Rules apply to the loading and number of sockets allowed on the end of a spur.
Spurring sockets prevents the easy later addition of more sockets in some positions, as a spur may not be spurred off a spur. Spurs also prevent the addition of more sockets at existing spurred positions, whereas a practically unlimited number of sockets can be added where a socket is in the ring. Bear in mind the number of sockets wanted has risen greatly over the years, and can only be expected to rise further.
Radial socket circuits are used less often. These use a single cable from CU to socket, then a single cable to the next socket along the line etc. Radials use more copper on most circuits, though less cable on physically long narrow shaped circuits. Connection faults have greater consequences than with ring circuits. (Confusion over the relative safety of ring & radial circuits is widespread.)
Number of Sockets
Minimum and desirable numbers of sockets recommended per room are given. Recommended numbers are inevitably a matter of opinion, and are only recommended as a starting point for consideration.
- Minimum: none
- Recommended: 1 double socket for a short corridor, 2 or possibly more in a long one. Put one where a hall table might go.
- Minimum: 1 double socket at each of 2 locations
- Recommended: 2x double sockets at each of 4 locations (in or near corners) + 1-3 double sockets where PC or AV equipment is to be used. If the room has 2 or more doors, 2 way lighting switches controllable at each door. 4-6x 2A or 5A sockets on lighting circuit.
- Utility room:
- Minimum: 1 double socket
- Recommended: 2 or 3 double sockets, all on ring circuit
- Home Office:
- Minimum: a double socket at 2 locations
- Recommended: 2x double sockets at each of 4 locations (generally near corners), plus anything from 2 to 6 double sockets where computer or other business appliances will go.
- Small shed:
- Minimum: no electricity supply
- Recommended: if far from the house, a double socket can be useful. If you'll spend time in it, a light too.
- Large shed:
Radial circuits are used for lighting. There is one lighting circuit on each lighting MCB. Lighting circuits are usually on a 6A MCB or 5A fuse, though 10A can be used (with some extra restrictions (now removed in the 17th edition of the wiring regs)) for large circuits. However if the area served is large, more 5A or 6A circuits would in most cases be preferable.
Fuse or MCB
Filament lamp failures can trip MCBs, so fuses have an advantage over MCBs for lighting circuits, as they rarely nuisance trip on bulb failure. (Less sensitive type C and D MCBs can often be used to help reduce this problem.)
The power feed cable may go to either the switch or the bulbholder. If it goes to the bulbholder, this is called loop-in wiring, and the ceiling rose (a junction box with a downward facing cable outlet) then uses four sets of connections instead of 3, the extra one being a switched live.
With loop-in wiring, the cable from the ceiling rose to the switch has 3 conductors, namely earth, unswitched live and switched live. Regs conformance requires that brown sleeving be fitted over the neutral coloured conductor at each end of the switch cable since it is being used as a live.
A typical view inside a ceiling rose:
Which is a little easier to understand in schematic form:
All cable colours are as expected except for the switched live. Light switches are usually wired with standard T&E, which means the switched live wire will be black (existing installs) or blue (new installs) - this should be marked with live coloured tape or sleeving (though alas this is often missing).
Single & Earth
A less commonly met system of wiring lighting circuits.
This run starts from the MCB and loops between the lightswitches to provide a permanent live and earth to the lightswitches. Another length of 6241Y is then used from the lightswitch to the light fitting to provide a switched live and earth at the light fitting.
The neutral cable is a double sheathed cable (6181Y with a blue inner sheath) that runs from the CU neutral busbar and from light fitting to light fitting (there will only be one neutral at the end of the circuit).
It makes it easier to put light fittings up as there are less cables to mess with at the fitting.
Other Wiring Options
In addition to the common Loop In scheme shown above, other systems are also often used. These are Switch loop through which makes all the connections at a switch. There is also junction box wiring which is basically the same as the ceiling rose system except there is no local connection to a lamp - so its better suited to remote lamps like wall lights. All combinations of these can exist on the same circuit if necessary :
Two Way Switching
Two way switching means having two or more switches in different locations to control one lamp. They are wired so that operation of either switch will control the light(s).
Light circuit earthing
In some older properties (typically wired in or before the mid 1960s), its not uncommon to find lighting circuits without an earth wire. Care should be taken if you have such a circuit to ensure that only appropriate light fittings and switches are used. Most metal light fittings and switches will require earthing, but those marked with the double insulated symbol do not need an earth connection. Most plastic switches and light fittings are also safe for use on circuits with no earth.
Note the earth wire in the T&E must be run to all switches, junction boxes & light fittings, including those that are currently plastic. It is not permitted to borrow an earth from another circuit. Ideally the non-earthed circuit ought to be re-wired, or at least have a RCD installed to protect it.
For more information about unearthed lighting circuits see Lighting Circuits Without an Earth
Outdoor lighting is usually run on its own radial circuit off its own MCB in the CU. Usually this is a 6A MCB, but lighting is less likely to cause problems if run on a 5A fuse. Exterior cabling must be appropriate for use outside (many cable types degrade under prolonged exposure to sunlight for example).
Bathrooms (or rooms with showers) are "special locations" in the language of the wiring regulations. This is because they are places where people are particularly vulnerable to serious injury from electric shock (due to being wet and barefoot). In modern designs all bathroom electrics are supplied by RCD protected circuits.
Bathrooms are divided into 3 zones, with different rules for each zone.
- Electrical fittings in the bathroom in zone 0 must conform to IPX7 or better, and must be of an extra low voltage type.
- Electrical fittings in the bathroom in zones 1 & 2 must conform to IPX4 or better.
- Electrical fittings in the bathroom outside of the zones do not need to confirm to any specific IP rating, but must be appropriate for the circumstance in which they are used.
There are also limitations to the type of electrical equipment permitted in each zone. See the Bathroom electrics article for more details.
All metal items that enter a bathroom from outside of the room (e.g. copper pipes, electric circuit cables) are connected together using 4mm² green/yellow insulated wire. Connection is also made to each of the protective earth wires in each circuit that feeds an appliance in the bathroom (e.g. lamps, heaters, towel rails etc). This is called equipotential bonding and is designed to minimise exposure to dangerous voltages that may be present during electrical fault conditions. The wire is connected to metal pipes using BS 951 earth clamps. The wire is connected to radiators using connectors. It is permitted to place equipotential bonding connections immediately outside the bathroom if necessary. Note equipotential bonding can be omitted if all the circuits that enter the bathroom are protected by RCD(s) with trip thresholds of 30mA or less.
Until the introduction of the 17th edition of the wiring regulation, sockets were not permitted in a bathroom at all, unless they were either a transformer isolated shaver socket, or sockets to power extra low voltage devices, both of which are permitted in Zone 2 or outside. For more information on bathroom electrics, see Bathroom electrics.
All in one electric cookers (oven, hob & grill in one unit) are fed by a high current cable from the CU, typically on a 32A MCB. Single cavity ovens with no hob are more often put on a 13A plug. Most hobs require their own high current feed, but some are available that incorporate load limiting switching, and are designed to be run on a 13A plug. Combi cookers (microwave & fan oven, with or without grill) are always on a 13A plug.
Contrary to popular belief kitchens do not need equipotential bonding.
Number of Rings
Most kitchens are supplied by one ring circuit. However this may be insufficient for large or all-electric kitchens.
Cable Colour changes
Although the UK has used the European standard of Blue / Brown colouring for flexes for a long time, the same colour standard has also now been adopted for fixed wiring as well. Hence you need to be aware of the changes:
- Red = Live
- Black = Neutral
- Bare or green/yellow = Earth
- Brown = Live
- Blue = Neutral
- Bare or green/yellow = Earth
For more info on house wiring see
- Rewiring Tips
- Electrical Glossary
- Bathroom electrics
- Taking electricity outside
- and Category:Electrical
For more information on lighting see
For more information on outdoor lighting, see
- Rewiring Tips#Outdoor Security Lighting
- Dimmed PIR Lights
- Taking electricity outside
For more information on RCDs & RCBOs, see