EASA Rules of Thumb for Three-Phase Motors — Full Professional Guide
This guide provides detailed explanations, practical examples, and worked calculations for three-phase induction motors, based on a 55 kW example motor. It is intended for engineers, technicians, and maintenance teams to ensure safe, reliable, and efficient motor operation according to EASA recommendations and industry best practices.
Example Motor Specification
- Rated Power: Prated = 55 kW = 55,000 W
- Line Voltage: VLL = 415 V (3-phase)
- Frequency: f = 50 Hz → 4 poles → Nsync = 1500 rpm
- Efficiency: η = 0.93
- Power Factor: PF = 0.90
1. Voltage Variation — Concept & Calculation
Explanation: Voltage variation measures how much the supply voltage deviates from the motor's rated voltage. Small deviations are normal, but large variations can cause overheating, reduced torque, or even insulation breakdown over time. For reliable operation, maintain voltage within ±10% of rated voltage; ±5% is ideal.
%Variation = (Vmeas - Vrated) ÷ Vrated × 100
Example: Vmeas = 385 V, Vrated = 415 V → %Variation ≈ -7.23%
2. Voltage Unbalance — Effects & Calculation
Explanation: Voltage unbalance occurs when the three-phase supply voltages differ in magnitude. This creates negative-sequence currents in the motor, which can lead to overheating, reduced torque, and premature bearing or insulation failure. Keep unbalance below 1% if possible; up to 2% is acceptable in practice.
Vavg = (Va + Vb + Vc) ÷ 3
Vunb% = max(|Va - Vavg|, |Vb - Vavg|, |Vc - Vavg|) ÷ Vavg × 100
Example: Va=418 V, Vb=410 V, Vc=420 V → Vavg=416 V, Vunb% ≈ 1.44%
3. Current Variation — Monitoring Load
Explanation: Current variation shows changes in motor load. Sudden increases may indicate mechanical blockage, short circuits, or overload. Small variations under normal load are expected; a change above ±15% should trigger inspection.
- ±10% variation is considered normal under varying load.
- Sudden >15% indicates potential mechanical or electrical fault.
4. Current Unbalance — Formula & Sample
Explanation: Unequal current in phases increases heating in one phase, which can damage insulation and reduce efficiency. It often results from unequal supply voltage, faulty connections, or asymmetrical loads.
Iavg = (Ia + Ib + Ic) ÷ 3
Iunb% = max(|Ia - Iavg|, |Ib - Iavg|, |Ic - Iavg|) ÷ Iavg × 100
Example: Ia=95 A, Ib=87 A, Ic=94 A → Iavg=92 A, Iunb% ≈ 5.43%
5. Full-Load Current (FLC)
Explanation: FLC is the steady-state current the motor draws at rated voltage and full load. It is used to set overload protection and evaluate energy consumption.
IFL = Prated ÷ (√3 × VLL × η × PF)
Example: 55 kW, 415 V, η=0.93, PF=0.90 → IFL ≈ 91.42 A
6. Locked-Rotor Current (LRC)
Explanation: LRC is the current drawn when the rotor is stationary at start. Protection devices must allow this short-duration high current without tripping. Typical values are 5–8 times FLC.
ILRC ≈ 5 ~ 8 × IFL
Example using 6×: ILRC ≈ 548.5 A
7. Instantaneous Starting Spike
Explanation: At motor start, a short-duration spike occurs due to magnetizing current. It lasts only a few milliseconds but may reach 10–14× FLC. Protection devices and breakers must tolerate this brief surge.
Ispike ≈ 10 ~ 14 × IFL
Example: Ispike ≈ 914 A (very short duration)
8. Locked-Rotor / Stall Energy (I²t)
Explanation: I²t measures thermal energy absorbed by the motor during start or stall. It is useful to compare with full-load energy to ensure thermal protection settings are adequate.
Estart = ILRC² × tstart
EFL1h = IFL² × 3600
Ratio = Estart ÷ EFL1h
Example: ILRC=548.5 A, t=10 s → Ratio ≈ 0.10 → start energy ≈ 10% of 1-hour full-load energy
9. Number of Allowable Starts
Explanation: Each motor start causes heating. Frequent starts shorten insulation life. Use conservative limits or manufacturer duty class.
- Cold motor: 2–3 starts/hr
- Hot motor: 1–2 starts/hr
- Check manufacturer data for exact duty cycle
10. Slip — Definition & Formula
Explanation: Slip indicates how much the rotor lags behind synchronous speed. It is a measure of rotor speed relative to magnetic field speed, usually a few percent for induction motors under normal load.
s (rpm) = Nsync - Nrated
s (%) = (Nsync - Nrated) ÷ Nsync × 100
Example: Nsync=1500 rpm, Nrated=1460 rpm → s ≈ 40 rpm, s% ≈ 2.67%
Quick Reference — Rounded Values (55 kW Motor)
| Parameter | Value |
|---|---|
| FLC | ≈ 91 A |
| LRC (6×) | ≈ 548 A |
| Instantaneous spike | ≈ 914 A (short) |
| Voltage variation | ±10% allowed (±5% ideal) |
| Voltage unbalance | ≤1% target |
| Current unbalance | <5% ideal; ≤10% max |
Protection Guidelines
- Set thermal overload relays to FLC × service factor to protect windings.
- Instantaneous protection must tolerate start currents without unnecessary tripping.
- Use reduced-voltage starters or VFDs for frequent starts or high-inertia loads to reduce mechanical and electrical stress.
On-Site Checklist
- Read motor nameplate: P, V, FLC, rated RPM.
- Measure Va, Vb, Vc and Ia, Ib, Ic; record ambient and bearing temperatures.
- Calculate voltage variation, voltage unbalance, current unbalance; compare to recommended limits.
- Measure start current and acceleration time if safe to verify against expected values.
- Check protection settings and cooling times between consecutive starts.
BR 21806 
VN 6081 
US 5236 
AR 3192 
MX 2370 
IN 1603 
IQ 1512 
GB 1496 
