Calculation of Transformer Impedance

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Transformer Impedance & Short Circuit Calculator

Transformer Rated Capacity (kVA)

Secondary Rated Voltage (V)

Nameplate Impedance (Z%)

Phase Type Three-Phase (3Ø) Single-Phase (1Ø)

Base Impedance (Z_base): –

Actual Impedance (Z_ohms): –

Full Load Current (I_fl): –

Short Circuit Current (I_sc): –

Understanding Transformer Impedance Calculation

Transformer impedance, typically expressed as a percentage (Z%), represents the ratio of voltage drop across the transformer windings at full load compared to the rated voltage. This parameter is critical for electrical engineers to determine short-circuit current ratings, protective device coordination, and voltage regulation.

How the Calculation Works

To convert the nameplate percentage impedance to actual Ohms (Ω), we use the following steps:

Calculate Rated Current: For a 3-phase system, I = kVA / (√3 × kV).
Calculate Base Impedance: Z_base = V_phase / I_phase or kV² / MVA.
Calculate Actual Ohms: Z_ohms = (Z% / 100) × Z_base.

Why Is Transformer Impedance Important?

The impedance value determines how much current will flow during a fault. A lower impedance results in higher short-circuit currents, which may require more expensive circuit breakers with higher interrupting capacities. A higher impedance reduces short-circuit current but causes a larger voltage drop when the transformer is under heavy load.

Example Calculation

Consider a 1000 kVA, 3-phase transformer with a 480V secondary and 5.75% impedance:

Rated Current: 1000 / (1.732 * 0.480) = 1,202.8 Amps.
Short Circuit Current: 1,202.8 / (5.75 / 100) = 20,918 Amps.
Ohmic Impedance: (0.0575 * 0.480²) / 1.0 MVA = 0.0132 Ω.

Transformer Impedance & Short Circuit Calculator

Understanding Transformer Impedance Calculation

How the Calculation Works

Why Is Transformer Impedance Important?

Example Calculation

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