# Difference between revisions of "Calculating A Cable Size"

For typical domestic lighting and general purpose socket circuits one can usually use one of "standard" circuits presented in the On Site Guide, safe in the knowledge that so long as you follow the guidelines, the combinations of protective device and cable specified will meet all of the (sometimes complex and confusing) requirements applicable. This article is for all those cases where the "off the shelf" circuits are not appropriate, and you are faced with the need to design your own circuit, and prove its adequacy.

Choosing the right sized cable is not always as easy as it looks.

Selecting the correct cable for the application is imperative to ensure a satisfactory life of conductors and insulation subjected to the thermal effects of carrying current for prolonged periods of time in normal service.

Choosing the minimum size cross sectional area of the conductors is essential to meet the requirements for

• Protection against electric shock
• Protection against thermal effects
• Overcurrent protection
• Voltage drop
• Limiting temperatures for terminals of equipment to which the conductors are connected

# How to size a cable

## Differences between fault current protection and overload current protection

All circuits are designed to protect the cables against fault current (e.g. a short circuit from line to earth or line to neutral). However full overload current protection is not always required (or possible) on some circuits.

Overload protection is required when a cable may conceivably be required to carry a circuit current in excess of its design current for a period of time, either brought about by the circuit's user, or by a predictable failure mode of equipment supplied by the circuit. e.g. a user connecting too many high power appliances to a socket circuit.

Overload current protection is not required when we know the fixed current of the appliance, and we install a dedicated cable that is capable of carrying this current. A good example of this would be an electric shower or an immersion heater supply cable where there is no end user action, or typical equipment failure mode that could result in an overload. We will show in the worked examples later on, that it is even possible in some circumstances to safely install an MCB that has a higher rating than the cable's maximum current rating.

Section 433.3.1 of BS7671 also describes other circumstances where overload current protection can be omitted. Note also there are also some classes of equipment where overload current protection may be omitted on safety grounds (typically fire detection and extinguisher systems, life support equipment, some rotating or lifting equipment etc. See section 433.3.3 of BS7671 for full details).

Overload current protection is required for any circuit where a user could potentially raise the current demand from the circuit to above that anticipated in its design. This would be the case with the vast majority of general purpose socket circuits for example.

## Sizing conductors for your circuit

### How to calculate ${\displaystyle I_{z}}$

${\displaystyle I_{z}}$ and some other terms we will require shortly are defined as:

• ${\displaystyle I_{z}}$ - The rated current carrying capacity of the chosen cable, for continuous service, under the particular installation conditions.
• ${\displaystyle I_{t}}$ - The nominal current carrying capacity of the cable. For T&E cable ${\displaystyle I_{t}}$ is taken from this table.
• ${\displaystyle I_{b}}$ - The design current of the circuit. This is the starting point for all the calculations. If available, then ${\displaystyle I_{b}}$ should be taken from the rated full load current of the appliance. If this is not given, then ${\displaystyle I_{b}}$ may be calculated by dividing the VA rating of the appliance by 230 (the nominal voltage). For cases where the VA rating is not provided, then use the quoted power in Watts divided by 230. Note that diversity can be applied to reduce the full load current where permitted (e.g. with a cooker circuit in a domestic environment)
• ${\displaystyle I_{n}}$ - The rated current of the protective device.
• ${\displaystyle I_{2}}$ - For completeness we will include ${\displaystyle I_{2}}$ - the actual operating current of the protective device. However for domestic work there are only two classes of protective device of interest: Cartridge Fuses, MCBs, and RCBOs where ${\displaystyle I_{2}}$ is ${\displaystyle 1.45\times I_{n}}$, and rewireable fuses where ${\displaystyle I_{2}}$ is ${\displaystyle 2.0\times I_{n}}$, so we can simplify things a little summaries of the requirements given in case 1 and case 2 below:

Having calculated the easy bits: the design current (${\displaystyle I_{b}}$) and then protective device rating (${\displaystyle I_{n}}$) we now need to calculate ${\displaystyle I_{z}}$.

${\displaystyle I_{z}}$ may be found either by reference to the tables in BS7671 (the wiring regs) or the IEE On Site Guide (a subset of which are reproduced here for common domestic cables sizes), or, by calculation based on the various factors that affect the installation.

#### Case 1: overload protection required

When overload protection is required, we must ensure that:

${\displaystyle I_{n}\geq I_{b}}$ (Overload Protective Device rating is equal to or bigger than load)

and also, for cartridge fuse, MCB or RCBO protective devices that:

${\displaystyle I_{z}\geq I_{n}}$ (cable rating (as-installed) is equal to bigger than the Overload Protective Device rating)

or for rewireable fuse then:

${\displaystyle I_{z}\geq I_{n}}$ / 0.725 (cable must be up-rated to allow for coarser protection from this type of fuse);

#### Case 2: overload protection not required, due to characteristics of load

Where overload protection is not required then ${\displaystyle I_{z}}$ should ideally be greater than or equal to the MCBs nominal rating, (i.e. ${\displaystyle I_{z}\geq I_{n}}$). However if this can't easily be achieved, then it is also acceptable to opt for ${\displaystyle I_{z}}$ > ${\displaystyle I_{b}}$ even if ${\displaystyle I_{z}}$ is actually less than the nominal rating of the MCB (i.e. ${\displaystyle I_{b}\leq I_{z}\leq I_{n}}$). Warning: If the latter design option is used, then it should be remembered that the cable size will have been verified as adequate only for the selected appliance, and it may not be adequate for a more powerful appliance even if the MCB could in theory support it.

${\displaystyle I_{n}}$ summary: when overload protection is not required, then we must ensure that:

${\displaystyle I_{n}\geq I_{b}}$ (as for case 1)
${\displaystyle I_{z}\geq I_{b}}$ (cable rating (as-installed) equal to bigger than load)

but if ${\displaystyle I_{z} an adiabatic calculation must be performed to verify fault (i.e. short circuit) protection of the cable is still provided (see section below).

Method 1 - by reference to the tables

With direct reference to the table. If the cable is installed ungrouped,
in an ambient temperature of 30C, and  is protected by a B type MCB, then ${\displaystyle I_{z}}$ = ${\displaystyle I_{t}}$ and the cable
size is chosen by looking down your reference method column to find ${\displaystyle I_{z}}$. (note ratings for a
number of more exotic installation methods can be found in BS7671)


Method 2 - calculation

${\displaystyle I_{z}}$ is calculated by using the formula

${\displaystyle I_{z}=I_{t}\times C_{a}\times C_{g}\times C_{i}\times C_{c}}$

Where ${\displaystyle I_{t}}$ is column C of the table.

${\displaystyle C_{a}}$ is a correction factor due to the ambient temperature (values from table 4B1)

${\displaystyle C_{g}}$ is a correction value for cables grouped with other circuits (values from table 4C1)

${\displaystyle C_{i}}$ is a correction value for cables in insulation (Table 52.2)

${\displaystyle C_{c}}$ is a correction factor of 0.725 for BS3036 fuses and 0.9 for cables "in a duct in the ground"
or "buried direct". If a buried cable is protected by a BS 3036 fuse then ${\displaystyle C_{c}=0.725\times 0.9=0.653}$

Worked Example

Say we have a radial circuit feeding a pair of 3kW immersion heaters. The cable will be
grouped with two other circuits and will pass through an aperture in a fully insulated stud
wall, containing 100mm of slab insulation. The ambient temperature of the insulated wall
is 40°C. The circuit protection will be a B32 MCB, and the cable is initially specced
as 4.0mm² T&E.

So we know that ${\displaystyle I_{b}={\frac {2\times 3000}{230}}=26A}$

Initial inspection of column C of the table shows a rating for
4.0mm² cable at 37A.

However from the tables below we can see that the ambient temperature of 40°C yields
a derating of 0.87 and our total of three circuits grouped together gives a factor of
0.7. Finally the 100mm of insulation introduces a further factor of 0.78. Since the
protective device is a MCB there is no factor to apply due to the use of a BS 3036
re-wireable fuse.

${\displaystyle I_{z}=37\times 0.87\times 0.7\times 0.78\times 1=17.57A}$

Since overload protection is not required for this circuit, we need to achieve only
${\displaystyle I_{z}}$ > ${\displaystyle I_{b}}$ as a minimum requirement, however in this case it is clear that we have not
achieved this. Even drilling extra access holes for the cable to remove the grouping
related factor, will still not meet the target. Hence we will have to increase the
cable size to 6.0mm² and drill some extra holes:

Reworking with the new ${\displaystyle I_{t}}$ of 47A, and removing the grouping factor we get:

${\displaystyle I_{z}=47\times 0.87\times 1\times 0.78\times 1=31.89A}$

This does meet the minimum requirement of ${\displaystyle I_{z}>I_{b}}$ and hence is acceptable. It is
however very slightly outside the ideal of ${\displaystyle I_{b}\leq I_{n}\leq I_{z}}$.

(a more practical solution may actually be to wire each heater using its own
2.5mm² T&E cable. Since the reduced load on each of 3kW (13A), will come in
with a ${\displaystyle I_{z}}$ of just over 18A if one also removes the grouping factor). One could
even go further by wiring a ring circuit instead of two radials.


### Effects of ambient temperature

Table 4B1

Ambient temperature Derating factor ${\displaystyle C_{a}}$
25 1.03
30 1.00
35 0.94
40 0.87
45 0.79
50 0.71
55 0.61
60 0.50

### Effects of cable being embedded in insulation

Table 52.2

Length in insulation (mm) Dereating factor ${\displaystyle C_{i}}$
50 0.88
100 0.78
200 0.63
400 0.51
>500 0.50

### Effects of cable grouping

Table 4C1

Arrangement (cables touching) Number of circuits Applicable reference method
1 2 3 4 5 6 7 8 9 12 16 20
Bunched in air, on a surface, embedded or enclosed 1.0 0.80 0.70 0.65 0.60 0.57 0.54 0.52 0.50 0.45 0.41 0.38 A to F
Single layer on a wall 1.0 0.85 0.79 0.75 0.73 0.72 0.72 0.71 0.70 0.70 0.70 0.70 C
• The ${\displaystyle C_{g}}$ value applies to the number of circuits not the number of cables
• If a cable is to be expected to carry less than 30% of it's grouped rating it may be ignored for the purpose of obtaining the rating factor for the rest of the group

### Checking Voltage Drop

For lighting circuits the maximum volts drop is 3% (6.9V) and for all other circuits the maximum voltage drop is 5% (11.5V).

We now need to test that the chosen cable will be big enough to supply the circuit without dropping the maximum allowed voltage drop. The table below shows the voltage drop in mili Volts (mV) per amp, per meter. So to find the total drop simply multiply this value by the design current ${\displaystyle I_{b}}$, and the length of the cable L:

${\displaystyle TotalVoltageDrop=VoltageDrop\times I_{b}\times L}$

This will give the voltage drop in mV. Divide by 1000 to convert to Volts

Conductor CSA (mm²) PVC (max 70° C)

Voltage drop mV/A/m

1.0 44
1.5 29
2.5 18
4.0 11
6 7.3
10 4.4
16 2.8
Worked Example

Say we have an electric shower with a design current ${\displaystyle I_{b}}$ of 41A, and a cable run of 19m, installed
using Method C. Initial checks would suggest that 6mm² T&E will be adequate. From the table above
we know that 6mm² will drop 7.3 mV/A/m. So:

${\displaystyle TotalDrop={\frac {7.3\times 41\times 19}{1000}}=5.67V}$ which is acceptable


### Checking the Maximum Earth Loop Impedance (ELI)

Table 41.3

Please note, these figures are appropriate for installations completed prior to the 3rd amendment of the 17th edition of the wiring regs - for new installation work, see below

Type B circuit breakers to BS EN 60898
Rating (amps) 6 10 16 20 25 32 40 45 50 ${\displaystyle I_{n}}$
${\displaystyle Z_{s}}$ (ohms) 7.67 4.60 2.87 2.30 1.84 1.44 1.15 1.02 0.92 46/${\displaystyle I_{n}}$
• The circuit loop impedances given in the table should not be exceeded when the conductors are at their operating temperature. If the conductors are at a different temperature when tested, the reading should be adjusted accordingly.

#### 17th Edition Amendment 3, Cmin factor

As a result of recent research published by CENELEC: "Technical Report PD CLC/TR 50480:2011 Determination of cross sectional area of conductors and selection of protective devices", the third amendment of BS7671:2008 (the 17th edition of the wiring regs) includes a change that lowers the maximum permitted earth loop impedance.

Background

Normally mains supplies in the UK should meet the specification of 230V +10%/-6% (i.e. between 253V and 216V).

For properties which have a supply voltage closer to the lower end of that range, the time required to clear faults on circuits might increase beyond those desired. Hence the above table has been superseded by one with all values reduced by 5% :

Circuit breakers to BS EN 60898
Rating (amps) 6 10 16 20 25 32 40 45 50 ${\displaystyle I_{n}}$
${\displaystyle Z_{s}}$ (ohms) Type B MCB 7.29 4.37 2.73 2.19 1.75 1.37 1.09 0.97 0.87 44/${\displaystyle I_{n}}$
${\displaystyle Z_{s}}$ (ohms) Type C MCB 3.64 2.19 1.37 1.09 0.87 0.68 0.55 0.49 0.44 22/${\displaystyle I_{n}}$
${\displaystyle Z_{s}}$ (ohms) Type D MCB 1.82 1.09 0.68 0.55 0.44 0.34 0.27 0.24 0.22 11/${\displaystyle I_{n}}$

Note that you can calculate the minimum loop impedance for any circuit with the following formula:

${\displaystyle Zs={\frac {U_{0}\times C_{min}}{I_{a}}}}$

Where:

${\displaystyle U_{0}}$ is the nominal AC RMS line voltage (normally 230V)
${\displaystyle C_{min}}$ is the minimum voltage factor which takes into account the voltage variations depending on time, place, and changing transformer taps and other considerations. This is currently specified as 0.95
${\displaystyle I_{a}}$ is the current which causes operation of the protective device within the specified time. So for example with a B type circuit breaker, it's 0.1 sec (or "instant") trip current would normally be equal to 5 x its nominal rating, e.g. 160A for a B32 device. (note for a C type device it is 10x, and a D type 20x)
Example:

For a C20 MCB the new maximum ELI is :

${\displaystyle Zs={\frac {230\times 0.95}{200}}}$         (where 200A is the (${\displaystyle 10\times I_{n}}$) typical 0.1 sec operating current for that device)

${\displaystyle Zs=1.09\Omega }$


Having now chosen a cable that is suitable to carry our design current and meet the required voltage drop requirements we now need to check that the cable will allow the MCB , fuse or RCBO to trip the circuit quickly enough in the event of a fault.

A fault may be caused by either a line to neutral fault or a line to earth fault. A Prospective Fault Current (PFC) is a line to earth fault limited by the Earth Loop Impedance (ELI) and a Prospective Short Circuit (PSC) current is a line to neutral fault limited by the Line Impedance.

Non time delayed RCD protected circuits automatically protect the circuit against line earth faults however it is advisable when possible to design the circuit so that the MCB or overcurrent characteristics of an RCBO still clears the fault in the case of a faulty RCD.

For TN supplies disconnection times are 0.4 seconds for circuits up to 32A and 5 seconds for other circuits. Fortunately for a B type MCB or RCBO the trip current for both 0.4 and 5 seconds disconnection are the same. Table 41.3 above gives the maximum impedance to meet the disconnection times.

To check the disconnection times, we need to know the ELI or LI at the far end of the supply cable. To calculate this we in turn need to know the Earth Loop Impedance or Line Impedance at the consumer unit, this can be found by measurement if you have the appropriate test gear. Alternatively use the default figures of 0.8 for a TN-S earthing system and 0.35 for a TN-C-S system (for TT systems see notes below). Add to this the cable resistance. You can find this by multiplying the length of the cable by the appropriate value from the table below.

Resistance values for cables operating at 70°C
Wire CSA/CPC (mm²) L + N
(m${\displaystyle \Omega }$/m)
L + CPC
(m${\displaystyle \Omega }$/m)
1.0 / 1 43.44 43.44
1.5 / 1 29.04 36.24
2.5 / 1.5 17.78 23.42
4.0 / 1.5 11.06 20.05
6.0 / 2.5 7.39 12.59
10.0 / 4 4.39 7.73
16.0 / 6 2.76 5.08

Table Notes

• The values in this table are for copper cables at 70°C and have been increased by a correction factor of 1.2 from the values of those in Table 9A of the OSG to allow for the increased resistance due to operating temperature
• The Wire Cross Section Area (CSA) column also indicates the typical CSA of the CPC wire used in a modern cable.

If the calculated impedance is less than in table 41.3 then the disconnection times are met.

Worked Example

Say we have an electric water heater with a design current ${\displaystyle I_{b}}$ of 41A, and a cable run of 19m,
installed using Method C. Initial checks would suggest that 6mm² T&E will be adequate. We
have already confirmed the voltage drop is acceptable so now we need to check the
disconnection times.

From the above table ${\displaystyle ELI={\frac {19\times 12.59}{1000}}=0.24\Omega }$
and ${\displaystyle LI={\frac {19\times 7.39}{1000}}=0.14\Omega }$

For a TN-S supply with a Ze of 0.8 ohms then the calculated maximum resistances are
ELI is 0.8 + 0.24 = 1.04 ohms
LI is 0.8 + 0.14 = 0.94 ohms

As the ELI of 1.04 ohms is greater than the maximum 0.97 ohms allowed by a 45A MCB then this cable
installation is not suitable for use on a TN-S supply without RCD protection (Unless you can confirm by measurement that the actual external earth impedance (Ze) is lower than the standardised 0.8 ohms figure). Alternatively specifying a
larger CSA cable (or shortening the route of the existing one) may reduce the ELI sufficiently to bring


#### TT Supplies

TT Earthing systems will rarely provide a low enough ELI to meet disconnection times (or for that matter allow a sufficiently large PFC to flow to achieve disconnection at all!) Hence they must rely on RCD protection on all circuits to achieve earth fault disconnection. Note also that the disconnection time limits are tighter for TT systems, at 0.2 secs for circuits up to 32A, and 1 second for other circuits. (typical RCDs will disconnect in approx 40ms for "normal" types, and 900ms for Time delayed (Type S) devices).

The final design exercise is to check that in the event of a fault (i.e. very high current short circuits between line and earth or line to neutral etc), the cable has sufficient conductor cross sectional area to survive long enough to allow the circuit breaker or fuse to clear the fault without the cable being damaged by overheating. As a starting point one needs to assume that the cable is already running at its maximum design temperature (e.g. 70°C for PVC T&E). The high short circuit current will result in rapid heating of the cable, and given that this will happen very quickly there will be little time for any of this energy to be dissipated to the cables surroundings. This is known as adiabatic heating. This is compounded further by the fact that the wire resistance will rise with temperature, and hence the heating effect will also increase in direct proportion.

The wiring regs handle this situation with what is known as the adiabatic equation.

The equation for this is usually arranged to calculate the minimum required conductor cross sectional area "s":

${\displaystyle s={\frac {\sqrt {I^{2}\times t}}{k}}}$

Where:

• I is the prospective fault current, and
• t is the time to open the circuit breaker (typically 0.1 secs)
• k is a constant that takes into account the characteristics of the materials it is made from as well as highest possible short term rise in conductor temperature that it will tolerate without damage.

See table below for a list of common values (or see BS7671 table 43.1 for other cables not covered here):

k values for copper conductor cables of CSA < 300mm²

Copper conductors with
${\displaystyle I_{n}}$sulation material
Assumed initial
temperature (°C)
Final
temperature (°C)
k
70°C Thermoplastic (general purpose PVC) 70 160 115
90°C Thermoplastic (PVC) 90 160 100
60°C Thermosetting (eg Rubber) 60 200 141
90°C Thermosetting (eg XLPE) 90 250 143

Worked Example

If we take the previous example of a circuit with 19m of 10mm² T&E on a TN-S supply
with a ELI of 0.8 ohms we can calculate the ELI at the far end as

${\displaystyle 0.8+{\frac {19\times 7.73}{1000}}=0.95\Omega }$.

So we can now calculate the prospective fault
current as

${\displaystyle {\frac {230}{0.95}}=243A}$, which will open a 45A MCB in 0.1 secs.

So using these figures:

${\displaystyle s={\frac {\sqrt {243^{2}\times 0.1}}{115}}=0.67mm^{2}}$

Since the CPC in 10mm² T&E is 4mm² this will be more than adequate.