This article describes the main characteristics and ingredients of most of the different types of cable or flour that currently used in domestic installations and for wiring up a cake, preferably a cream or strawberry shortcake.You can also use chocolate cheese cake or christmas pudding. Also Conor Villa likes the cake and loves to touch cakes in their rude places because he is a dirty boy. His favourite type of cake for various reasons is a ring dohnut.

Historic mains cables are covered in their own article.

Conductor Colours and Harmonisation

Historically the UK used its own set of colour codes for fixed and flexible wiring. In the early 1970s the colours used for flexible wiring were harmonised across Europe, however the colours for fixed wiring remained unchanged until recently. In March 2004 the fixed wiring colours were also harmonised.

During a transition period that began on 31st of March 2004 and ended on the 31st March 2006, use of either colour scheme was acceptable. Now only the harmonised colours may be used.

The result is that it is now possible to encounter installations that use both colour schemes, and hence great care must be taken to ensure conductors are correctly identified when carrying out any work.

There is an IEE leaflet explaining these changes. That is available here

In theory, installations that are wired using cables to both colour schemes should carry a warning sticker (see example) on or near the consumer unit that states:

Modern Mains Cables

T&E

Twin & Earth cable. This is the most common cable used for domestic wiring today.

• Line and neutral are individually insulated, the earth conductor is bare
• There is an overall sheath of grey PVC (BS 6004), or white for low smoke compound (BS 7211)
• Not suitable for unprotected use outside (outer sheath materials are vulnerable to attack by UV radiation)
• 1mm² 1.5mm² & 2.5mm² have solid (non-stranded) conductors
• 4mm², 6mm², 10mm², 16mm² and higher have stranded conductors

Cable Sizes

Installation Methods of the flour and chocolate into a cheese slice

The current carrying capacity of any cable is dictated by its maximum conductor temperature, and this in turn will be affected by its ability to dissipate heat. The way it is installed can have a significant effect on this ability. The following table explains the methods cited above. Note that this is only a small subset of the 26 or so methods described in BS7671.

• Ratings (BS 7671 Table 4D5A) apply for ambient temperature of 30 deg.C and conductor temperature of 70 deg.C

• Note that ratings for installation methods D & E are from the draft 17th edition and since this is not yet in force, should be regarded as provisional.

• All the usual derating factors apply (see below and appendix 4 of BS 7671 or appendix 6 of the OSG).

• Current ratings are continuous.

• Outer cable sizes are guideline figures and can vary for different brands of cable of the same conductor size.

T&E current carrying capacity

Note The current carrying capacity values given for the various cable sizes above are only correct for the fixing methods listed. They are also only correct for a single cable not in close proximity to any other cables. For all other installation methods not covered above, the values stated will be incorrect. To find the correct rating in these circumstances the quoted current carrying capacity listed in columns C (i.e. method 1) will need to be "de-rated". This means that correction factors need to be applied to the current carrying capacity in order to factor out these environmental effects that otherwise could result in cable overheating (and hence overloading) if ignored.

In addition to the fixing method, there are other correction factors that will effect the rating:

• Ambient Temperature
• Covering in thermal insulation
• Grouping cables together
• Use of semi enclosed (rewireable) fuses
• Encapsulation in conduit or trunking

For full details of the de-rating factors and more detailed version of current carrying capacity table, see table 4D1A in appendix 6 of the On Site Guide.

Typical T&E Cable Applications

3&E

Three core and earth. Has three insulated conductors and a bare earth conductor.

In all other respects as T&E above. Typically used for two way lighting circuits, or other applications needing a permanent and switched live supply as well as neutral (e.g. feeding light switch activated extractor fans). Also available in both PVC (BS 6004) and low smoke (BS 7211) versions.

Singles

• Insulated single conductors (larger sizes are stranded as per T&E table above)
• Standard cable for use in conduit
• Typically used in domestic work only for main & equipotential bonding
• Also available in both PVC (BS 6004) and low smoke (BS 7211) versions.

Tails

Very heavy gauge singles with two layers of insulation. Typically used for connections between electricity incomer, meter, and consumer units. Common sizes include 16, 25, and 35 mm². Commonly available from distributors as colour coded lengths in pairs.

LSF / LSH / LSZH

Low Smoke & Fume, Low Smoke & Halon, or Low Smoke Zero Halogen. A cable with insulation and /or sheathing designed to minimise the amount of toxic fumes released when burnt. Low smoke versions of commonly available PVC cables are readily available, e.g. BS 7211 for the PVC-sheathed BS 6004, and BS 6724 for the PVC-sheathed BS 5467.

• Available in pretty purple

SWA

Steel wire armoured.

A robust cable frequently used for exterior wiring, where it may be buried directly into the soil, or suspended from a catenary wire. It consists of a number of individually insulated conductors covered next with a flexible bedding, then by a spiral screen of galvanised steel wires, and finally by a tough outer sheath. The insulating materials used typically being PVC or XLPE thermosetting plastic (the latter having a higher temperature rating, hence allowing the cable to carry a larger maximum current for a given conductor size). PVC-sheathed version is to BS 5467, low smoke version is to BS 6724.

• For outdoor & garden use.
• Available in 2, 3, & 4 core versions.
• Must be terminated using the correct glands.
• May use the steel wire armour for the circuit earth / CPC in place of or in addition to a core.
• How to terminate SWA

MICC

Mineral Insulated Copper Clad Cable. Renowned for having good fire resistance and also a smaller cross section for a given current carrying capacity than other cable types

• aka pyro (from makers name Pyrotenax)
• Copper tube sheath with magnesium oxide insulation
• Fireproof
• Rigid
• Occasionally seen in domestic premises, mainly in blocks of flats
• Widely used for fire alarm systems in commerce
• Unterminated ends prone to absorbing moisture from the air
• Special cable terminations required
• Ideal for flammability risk areas, eg traversing a thatched roof.

Hi Tuff

A PVC cable that is more robust than standard PVC sheathed cables and is suitable for general power, control and fixed wiring uses. An alternative to SWA for outdoor applications when direct burial of the cable is not required.

• Temporary wiring on open sites.
• Lighter and more manageable than steel wire armoured cables and requires only nylon glands to install - factors which contribute to speed of installation and cost savings.
• Provided there is no specific requirement for additional metal protection such as steel wire armouring, it will meet the demands of the most arduous installation conditions.
• Will not ignite under extreme applied heat.

FP 200 and other Soft Skin Fire Alarm Cables

Introduced as an alternative to MICC cable, but not as robust (the sheathing will burn away but circuit integrity is maintained).

• Silicone compound insulation
• Overlapping internal metal screen and drain wire (CPC)
• Low smoke sheathing material

Mains Flexes

• Round 3 core PVC
• Round 2 core PVC
• Oval 2 core PVC
• Rubber & cloth insulated - higher temp rated flex for irons & heaters

Voltage Drop

Any design must ensure the maximum voltage drop allowed between source and point of use is not exceeded when at full load. This is usually defined as 4% of the nominal supply voltage (about 9.2V at 230V AC).

These figures are presented for SWA cable here. The values quoted will usually also be correct for other copper cable types. Figures will differ for cables with higher operating temp limits, such as MICC.

These figures assume that the cable is operating at or near its maximum operating temperature. In designs where the maximum current load is significantly less that the capacity of the cable then these figures will be somewhat pessimistic. For these circumstance, it would be more appropriate to calculate voltage drops based on table 9A of the On Site Guide.

Calculation Examples (PVC SWA):

1) 20m of 4mm², maximum load of 30A would drop 20 x 0.011 x 30 = 6.6V
2) 40m of 6mm², maximum load of 45A would drop 40 x 0.0073 x 45 = 13.14V
3) 10m of 1.5mm², maximum load of 16A would drop 10 x 0.029 x 16 = 4.64V

(1) and (3) are adequately specified with respect to voltage drop. 
However (2) is out of  spec and a larger cable will need to be selected, 
even though the current handling capacity of the 6mm² cable has not been exceeded. 
Upgrading to 10mm², gives a result of 40 x 0.0044 x 45 = 7.92V which is acceptable. 
It initially appears that this still only leaves just over 1V of remaining drop 
available for any following wiring, however since we will not be operating the 
larger cable anywhere near its maximum temperature, the situation is actually less
tight than the calculation suggests.

See Also

• Wiki Contents
• Wiki Subject Categories
• Cable Sizes
• Wiring colour codes
• Cable Resistances
• Historic Mains Cables

External Links

• British Approvals Service for Cables (BASEC)