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IEC 60364-5-52: Correction Factors (B.52.14-B.52.21)

IEC 60364-5-52 correction factors explained — ambient temperature (B.52.14), grouping (B.52.17), soil thermal resistivity (B.52.16). Reference tables and application guide.

IEC 6036411 min readUpdated March 19, 2026
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Correction Factors in IEC 60364-5-52

IEC 60364-5-52 Annex B provides a comprehensive set of correction factors (also known as derating factors or rating factors) that adjust the base current-carrying capacity values from Table B.52.2/B.52.3 to account for actual installation conditions.

The correction factor tables in Annex B are numbered B.52.14 through B.52.21, each covering a specific installation variable. The overall derated current rating is calculated as:

Iz = Itab × k1 × k2 × k3 × ...

where Itab is the tabulated base current rating and k1, k2, k3 are the applicable correction factors. Multiple factors are multiplied together, so the combined effect can be substantial.

The correction factor tables are:

TableFactorApplies When
B.52.14Ambient air temperatureAir temperature ≠ 30°C
B.52.15Ground temperatureSoil temperature ≠ 20°C (buried cables)
B.52.16Soil thermal resistivitySoil resistivity ≠ 2.5 K·m/W
B.52.17Grouping — bunched cablesMultiple circuits in same enclosure
B.52.18Grouping — single layer on wall/floorCables touching on surface
B.52.19Grouping — single layer on trayCables on perforated or solid tray
B.52.20Grouping — buried cablesMultiple buried circuits
B.52.21Thermal insulationCable in contact with building insulation

Temperature Correction — Tables B.52.14 and B.52.15

Table B.52.14 provides correction factors for ambient air temperatures different from the 30°C reference. The factors depend on the cable’s maximum conductor operating temperature:

Ambient Temp (°C)PVC (70°C max)XLPE (90°C max)
101.221.15
151.171.12
201.121.08
251.061.04
301.001.00
350.940.96
400.870.91
450.790.87
500.710.82
550.610.76
600.500.71
650.65
700.58
750.50
800.41

Table B.52.15 provides the equivalent factors for ground temperature (reference 20°C), used for cables installed by Methods D1 and D2. The mathematical relationship is:

Correction factor = √((Tmax − Tambient) / (Tmax − Treference))

where Tmax is the maximum conductor temperature (70°C for PVC, 90°C for XLPE), Tambient is the actual ambient temperature, and Treference is the standard reference (30°C air, 20°C ground).

Grouping Correction — Tables B.52.17 to B.52.20

Grouping (proximity) factors account for the mutual heating effect when multiple loaded cables or circuits share the same installation route. IEC 60364-5-52 provides four grouping tables for different installation arrangements:

Table B.52.17 — Cables bunched in conduit or enclosed in trunking:

Number of CircuitsCorrection Factor
11.00
20.80
30.70
40.65
50.60
60.57
70.54
80.52
90.50
120.45
160.41
200.38

Table B.52.20 — Buried cables (multicore or trefoil single-core):

Number of CircuitsCables TouchingOne Cable Diameter Apart
20.750.80
30.650.70
40.600.60
50.550.55
60.500.55

For buried cables, spacing between circuits provides a measurable improvement. Maintaining at least one cable diameter spacing between parallel buried circuits can increase the grouping factor by 5–10%, potentially avoiding a cable size increase.

Soil Thermal Resistivity — Table B.52.16

Table B.52.16 provides correction factors for soil thermal resistivity values different from the 2.5 K·m/W reference. This factor only applies to buried cables (Methods D1 and D2).

Soil Resistivity (K·m/W)Correction FactorTypical Soil Type
0.51.28Very wet soil, clay saturated
0.71.20Wet clay, damp conditions
1.01.18Moist clay or sand
1.51.10Damp sand / loam
2.01.05Slightly damp ground
2.51.00Reference (dry sand/loam)
3.00.96Dry sand

Key insight: In moist soil conditions (resistivity 1.0 K·m/W or below), the correction factor increases the cable rating by up to 28%. This is because wet soil conducts heat away from the cable more effectively than the dry reference condition. Conversely, in very dry sandy soil (resistivity 3.0+), the cable must be derated.

Soil thermal resistivity varies seasonally and with weather conditions. Designers should use the worst-case (driest, highest resistivity) value expected during the cable’s service life. Local geotechnical data or on-site thermal probe measurements provide the most reliable values.

Thermal Insulation — Table B.52.21

Table B.52.21 addresses the situation where cables are enclosed in or in contact with building thermal insulation material. This is increasingly common in modern energy-efficient buildings.

The correction factor depends on the length of cable enclosed in insulation and the degree of enclosure:

  • Cable touching insulation on one side: Factor of approximately 0.75 — the exposed side still provides some heat dissipation.
  • Cable fully enclosed in insulation for a short length (< 0.5 m): Factor of approximately 0.89.
  • Cable fully enclosed for more than 0.5 m: Factor of approximately 0.55–0.50, depending on insulation thickness.

These factors are among the most severe in the entire correction factor system. A cable fully enclosed in thermal insulation for more than 0.5 m effectively loses half its current-carrying capacity. Wherever possible, cables should be routed to avoid prolonged contact with thermal insulation.

IEC 60364 vs BS 7671 vs AS/NZS 3008 Correction Factors

The three major cable sizing standards use similar but not identical correction factor systems:

FactorIEC 60364BS 7671AS/NZS 3008
Reference ambient temp30°C (air)30°C (air)40°C (air)
Reference ground temp20°C20°C25°C
Reference soil resistivity2.5 K·m/W2.5 K·m/W1.2 K·m/W
Temperature tablesB.52.14, B.52.154B1, 4B2Table 22, Table 23
Grouping tablesB.52.17–B.52.204C1–4C5Table 25
Soil resistivityB.52.164B3Table 27

IEC 60364 and BS 7671 values are essentially identical (BS 7671 is derived from IEC 60364). AS/NZS 3008 uses higher reference temperatures appropriate for Australian/NZ climate conditions and lower soil resistivity reflecting typical Australian soil types.

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Frequently Asked Questions

The grouping factor (Table B.52.17) typically has the largest impact in above-ground installations. With 6 circuits bunched in conduit, the cable capacity drops to 57% of the tabulated value. For buried cables, soil thermal resistivity can have an equally large impact — very dry soil (3.0+ K·m/W) combined with multiple grouped circuits can require cables two or three sizes larger than a single circuit in good soil.
Yes, for practical purposes. BS 7671 is the UK national implementation of IEC 60364, and the correction factor tables (B.52.14-B.52.21 in IEC vs 4B1-4C5 in BS 7671) contain the same values. The only differences arise for cable types specific to one standard — such as UK flat twin-and-earth cable in BS 7671, which has no IEC equivalent.
Soil thermal resistivity can be measured on-site using a thermal probe test (to IEC 60287-3-1) or estimated from geotechnical survey data. Typical values: wet clay 0.7-1.0 K·m/W, damp sand 1.5-2.0 K·m/W, dry sand 2.5-3.0 K·m/W. If no site data is available, the conservative approach is to use the 2.5 K·m/W reference value. For critical installations, site-specific testing is recommended.

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