VOLTAGEDROPCALCULATOR
Three-Phase Quality Tool

Voltage UnbalanceCalculator

Calculate three-phase voltage unbalance from field readings and flag motor, feeder, and service-quality concerns.

Enter the three measured phase voltages to calculate percent voltage unbalance using the standard maximum-deviation-from-average method. Use line-to-line readings for motor and service checks whenever possible. Line-to-neutral readings are useful for troubleshooting, but final three-phase motor evaluation should normally be based on line-to-line voltage.

Voltage Readings

Use loaded field measurements when available

Formula
Percent unbalance equals the maximum voltage deviation from the three-reading average divided by the average voltage, multiplied by 100.

Unbalance Results

Maximum deviation from average voltage

Good
Voltage unbalance
0.83%

Within the common 1% target used for sensitive three-phase motor planning.

Maximum deviation
4.00 V

Continue with normal voltage-drop and wire-size checks.

Average voltage
480.00 V
Voltage spread
8.00 V
Motor derate guide
100%
Estimated current effect

Motor current unbalance can often be several times voltage unbalance. A planning range for these readings is about 5.00% to 8.33% current unbalance.

Design note

Unbalance is not solved by oversizing conductors alone. Check supply voltage, transformer taps, loose terminations, unequal single-phase loading, and long feeder voltage drop.

How To Use This Calculator

Take all three readings at the same operating condition, preferably with the normal load running. For motor feeders and service checks, line-to-line measurements are usually the most useful. If the result is above 1%, investigate balance before treating voltage drop as the only design issue.

1. Measure under load

Record A-B, B-C, and C-A voltage with the equipment operating, not from disconnected conductors.

2. Compare the average

The calculator finds the average and the largest deviation, then reports the unbalance percentage.

3. Continue sizing

Once voltage quality is acceptable, use the voltage-drop and wire-size tools for conductor selection.

Related Tools

Continue from voltage-quality troubleshooting into voltage drop, wire sizing, tables, and code review.

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AC Voltage Drop Calculator

Check feeder and branch-circuit voltage drop after you confirm the phase readings are balanced.

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DC Voltage Drop Calculator

Use for battery, controls, solar, and other two-wire DC voltage-loss checks.

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Wire Size Calculator

Move from acceptable voltage quality into conductor sizing for the connected load.

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Wire Tables

Compare conductor resistance and ampacity data before choosing a final wire size.

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NEC Standards

Review voltage-drop recommendations and code context for electrical design decisions.