Transformer Secondary Fault Level Calculation

How to calculate three-phase transformer secondary fault current and fault level using transformer kVA, secondary voltage and percentage impedance.

Updated May 27, 2026

The transformer secondary fault level is the fault current or fault apparent power available at the secondary terminals of a transformer. It is an important input for switchgear ratings, protective-device selection, protection coordination and downstream cable fault-withstand checks.

This simplified calculation uses transformer percentage impedance and assumes an infinite fault level on the transformer primary side. In other words, the upstream network impedance is taken as zero. Where the primary fault level is known and finite, the upstream source impedance should also be included.

Transformer secondary fault level diagram — Transformer secondary fault level depends on transformer rating, secondary voltage and percentage impedance.

Required input data

Transformer rated capacity, kVA.
Primary line-to-line voltage, V₁, if a finite primary fault level is being considered.
Secondary line-to-line voltage, V₂.
Transformer percentage impedance, Z%.

For the simplified infinite-primary-source calculation, the primary voltage is not used directly because the upstream network impedance is assumed to be zero.

Secondary fault current

The three-phase secondary short-circuit current can be estimated from:

I_{sc} = \frac{Transformer kVA \times 1000}{V_{2} \times \sqrt{3} \times (\frac{Z %}{100})}

Here I_sc is the transformer secondary fault current in amperes, V₂ is the secondary line-to-line voltage in volts, and Z% is the transformer percentage impedance.

Secondary fault level in MVA

The secondary fault level in MVA is then:

Fault Level (MVA) = \frac{I_{sc} \times V_{2} \times \sqrt{3}}{1,000,000}

Example calculation

For a three-phase transformer with the following data:

Transformer rating	1000 kVA
Primary line-to-line voltage, V₁	11000 V
Secondary line-to-line voltage, V₂	400 V
Transformer percentage impedance, Z%	6%

The secondary fault current is:

I_{sc} = \frac{1000 \times 1000}{400 \times \sqrt{3} \times (6 / 100)} \approx 24056 A \approx 24.1 kA

The corresponding secondary fault level is:

Fault Level = \frac{24056 \times 400 \times \sqrt{3}}{1,000,000} \approx 16.6 MVA

For this example, the secondary three-phase fault level is therefore approximately 24.1 kA, or 16.6 MVA.

Use in cable fault calculations

The transformer secondary fault level can be used as a source fault level for downstream cable calculations. It may be converted to source impedance for IEC 60909-style calculations or used to check equipment short-circuit rating and cable thermal withstand.

Transformer Secondary Fault Level Calculation

Required input data

Secondary fault current

Secondary fault level in MVA

Example calculation

Use in cable fault calculations

Related Articles

Cable Reactance: Inductive and Capacitive Reactance

Sheath Induced Voltage and Circulating Current in Single-Core Cables

Dielectric Loss in Cables: Tan Delta and Capacitance