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Worked Example: Earth Fault Loop Impedance Verification for a TN-S System per BS 7671 Chapter 41

Step-by-step earth fault loop impedance verification for a 32 A Type B MCB circuit in a TN-S system. Covers conductor resistance at 20°C, temperature correction to 70°C, Zs calculation, and comparison against BS 7671 Table 41.3 maximum values.

BS 7671:2018+A312 min readUpdated March 6, 2026
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Project Description

This worked example verifies that a final circuit in a TN-S earthing system achieves automatic disconnection of supply within the time required by BS 7671:2018+A3, Regulation 411.3.2.2. The verification centres on calculating the total earth fault loop impedance Zs at the furthest point of the circuit and comparing it against the maximum permitted value from Table 41.3.

Earth fault loop impedance is a critical safety parameter. If Zs is too high, the fault current will be insufficient to trip the protective device within the required time (0.4 s for final circuits up to 63 A), leaving the exposed-conductive-part energised at a dangerous voltage.

Given Data

ParameterValue
Supply voltage230 V single-phase, 50 Hz
Earthing systemTN-S (separate neutral and earth conductors from DNO)
Protective device32 A Type B MCB (BS EN 60898)
Line conductor6 mm² copper, XLPE insulated (70°C maximum operating temperature)
Protective conductor (PE)6 mm² copper, same cable as line conductor
Cable route length25 m (from distribution board to final point)
Cable typeTwin + earth, XLPE 70°C rated copper
External earth fault loop impedance (Ze)0.35 Ω (measured at origin of installation)
Conductor operating temperature70°C (design maximum under fault conditions)
Ambient temperature30°C

The task is to determine whether Zs at the remote end of the circuit is low enough to ensure the 32 A Type B MCB disconnects within 0.4 seconds under an earth fault condition.

Step 1: Determine Conductor Resistance at 20°C

First, we calculate the resistance of the line conductor (R1) and the protective conductor (R2) at the standard reference temperature of 20°C. From BS 7671 Table I1 (Onsite Guide), the resistance per metre of 6 mm² copper conductor at 20°C is:

Resistivity of copper at 20°C:  ρ20 = 1.724 × 10&sup-8; Ω·m

For 6 mm² conductor:
  r1 = ρ / A = (1.724 × 10&supmin;&sup8;) / (6 × 10&supmin;&sup6;)
  r1 = 2.873 × 10&supmin;³ Ω/m
  r1 = 3.08 mΩ/m  (tabulated value from BS 7671 Table I1)

Since the line and PE conductors are both 6 mm² copper:

r1 = 3.08 mΩ/m  (line conductor)
r2 = 3.08 mΩ/m  (protective conductor)

(r1 + r2) at 20°C = 3.08 + 3.08 = 6.16 mΩ/m

For 25 m route length:

(R1 + R2)20°C = 6.16 × 25 / 1000
(R1 + R2)20°C = 0.154 Ω
Note: The tabulated value of 3.08 mΩ/m from Table I1 includes a small allowance for stranding. The pure calculated value from resistivity would be 2.87 mΩ/m, but the tabulated value accounts for the practical construction of stranded conductors.

Step 2: Apply Temperature Correction Factor

Conductor resistance increases with temperature. During a fault, the conductor heats rapidly. We must calculate the resistance at the maximum operating temperature to determine the worst-case loop impedance. The correction factor from 20°C to the operating temperature is given by BS 7671 Regulation 411.4.4 and Appendix 14:

Temperature correction factor:
  Ct = [1 + α20 × (top − 20)]

Where:
  α20 = 0.00393 /°C  (temperature coefficient for copper at 20°C)
  top = 70°C  (maximum conductor operating temperature for XLPE 70°C cable)

  Ct = 1 + 0.00393 × (70 − 20)
  Ct = 1 + 0.00393 × 50
  Ct = 1 + 0.1965
  Ct = 1.20

This factor of 1.20 means the conductor resistance at 70°C is 20% higher than at 20°C. This is a significant increase and must not be neglected.

Practical note: Some references use a simplified factor of 1.20 for 70°C PVC/XLPE cables. The precise calculation above confirms this commonly used value. For 90°C XLPE cables, the factor would be 1.28.

Step 3: Calculate (R1+R2) at Operating Temperature

Apply the temperature correction factor to the 20°C resistance:

(R1 + R2)70°C = (R1 + R2)20°C × Ct

(R1 + R2)70°C = 0.154 × 1.20

(R1 + R2)70°C = 0.185 Ω

This represents the combined resistance of the line and protective conductors over the 25 m route at the worst-case operating temperature.

Step 4: Calculate Total Earth Fault Loop Impedance (Zs)

The total earth fault loop impedance is the sum of the external earth fault loop impedance (Ze) provided by the electricity distributor and the internal circuit impedance (R1 + R2):

Zs = Ze + (R1 + R2)70°C  — (Eq. 1, BS 7671 Reg 411.4.5)

Zs = 0.35 + 0.185

Zs = 0.535 Ω
Note: This simplified formula treats the loop as purely resistive. In practice, Ze has a reactive component, and Zs = √[(Re + R1 + R2)² + Xe²]. However, for most LV installations the resistive component dominates and the simplified method is conservative (gives a slightly higher Zs than the true impedance).

Step 5: Compare Against BS 7671 Table 41.3

From BS 7671 Table 41.3 — Maximum earth fault loop impedance (Zs) for Type B MCBs to BS EN 60898, the maximum permitted Zs for a 32 A Type B MCB to achieve disconnection within 0.4 seconds is:

MCB Rating (A)Type B Zs max (Ω)Type C Zs max (Ω)Type D Zs max (Ω)
67.673.831.92
104.602.301.15
162.871.440.72
202.301.150.57
251.840.920.46
321.440.720.36
401.150.570.29
500.920.460.23

For a 32 A Type B MCB:

Zs (max) = 1.44 Ω  (from Table 41.3)

Our calculated Zs = 0.535 Ω

0.535 Ω < 1.44 Ω  → COMPLIANT

The calculated Zs of 0.535 Ω is well within the maximum permitted value of 1.44 Ω. The circuit will achieve automatic disconnection within 0.4 seconds as required by Regulation 411.3.2.2.

Step 6: Verify Prospective Fault Current

As a supplementary check, calculate the prospective earth fault current to confirm it is sufficient to trip the MCB within the required time:

If = U0 / Zs  — (Eq. 2)

If = 230 / 0.535

If = 430 A

For a 32 A Type B MCB, the magnetic trip threshold is 5 × In = 5 × 32 = 160 A. Our fault current of 430 A is 2.7 times the magnetic trip threshold, confirming instantaneous tripping (typically within 10–20 ms, well within the 0.4 s requirement).

Fault current ratio:  If / In = 430 / 32 = 13.4

Type B magnetic trip range: 3× to 5× In
  Lower threshold: 3 × 32 = 96 A
  Upper threshold: 5 × 32 = 160 A

430 A > 160 A  → guaranteed instantaneous magnetic trip
Note: The 80% rule — some practitioners apply a 0.8 multiplier to the Table 41.3 maximum values to provide a safety margin for measurement uncertainty and supply voltage variations. Applying this: 1.44 × 0.8 = 1.15 Ω. Our Zs of 0.535 Ω still passes comfortably.

Result Summary

ParameterRequirementCalculated ValueStatus
(R1+R2) at 20°C0.154 Ω
Temperature correction factor1.20 (to 70°C)
(R1+R2) at 70°C0.185 Ω
Ze0.35 Ω (measured)
Zs total≤ 1.44 Ω (Table 41.3)0.535 Ω✓ PASS
Prospective fault current≥ 160 A (5 × In)430 A✓ PASS
Disconnection time≤ 0.4 s< 0.02 s (instantaneous)✓ PASS

The circuit is compliant with BS 7671 Chapter 41 for automatic disconnection of supply in a TN-S system. The earth fault loop impedance of 0.535 Ω provides a substantial margin below the maximum of 1.44 Ω, ensuring reliable protective device operation even with supply impedance variations.

Key References

  • BS 7671:2018+A3, Regulation 411.3.2.2 — Automatic disconnection for TN systems (0.4 s for final circuits ≤ 63 A)
  • BS 7671:2018+A3, Table 41.3 — Maximum Zs values for MCBs to BS EN 60898
  • BS 7671:2018+A3, Regulation 411.4.5 — Earth fault loop impedance formula
  • BS 7671:2018+A3, Appendix 14 — Temperature correction for conductor resistance
  • IET On-Site Guide, Table I1 — Conductor resistance per metre at 20°C
  • BS EN 60898-1 — MCB characteristics (Type B: 3–5 × In)

Try It Yourself

Use the ECalPro Cable Sizing Calculator to verify earth fault loop impedance for your own circuits. Select BS 7671 as the standard, enter your Ze value and cable details, and the calculator will automatically check Zs against Table 41.3 — including temperature correction, the 80% rule, and full intermediate step reporting.

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Frequently Asked Questions

Earth fault loop impedance (Zs) is the total impedance of the path that fault current follows during an earth fault: from the transformer secondary, through the line conductor, through the fault, back via the protective conductor and earth path to the transformer star point. A low Zs ensures sufficient fault current flows to trip the protective device quickly.
Copper resistance increases by approximately 0.4% per degree Celsius. At 70°C operating temperature, resistance is about 20% higher than at 20°C. Since we need the worst-case (highest) Zs to verify the circuit will still disconnect in time, we must use the elevated temperature resistance. Using the 20°C value would underestimate Zs and give a falsely optimistic result.
The 80% rule (also called the 0.8 multiplier) is a practical safety margin applied during testing. It accounts for supply voltage variations, measurement uncertainty, and the fact that Ze can increase during peak demand. When testing on site, the measured Zs should not exceed 80% of the Table 41.3 maximum to ensure compliance under all operating conditions.

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