Resistance testing on stator windings – kelvin method

Stator Winding Resistance Test: Kelvin 4-Wire Method

Resistance testing on stator windings is a critical electrical measurement used to precisely determine the conductor resistance within the winding. This test is essential for ensuring the correct operation of electric motors and generators across all industrial applications, from automotive manufacturing to energy production.

Why Stator Winding Resistance Testing Matters

This measurement detects anomalies before they become costly failures, covering the following critical areas:

How the Kelvin 4-Wire Measurement Works

To achieve accurate, repeatable results — especially with low-resistance copper windings — the Kelvin method (4-wire) is the industry-standard technique. Unlike conventional 2-wire measurements, the Kelvin approach eliminates the influence of test lead and contact resistance by separating two independent circuits:

Resistance is then calculated via Ohm’s Law: R = V / I, where V is the voltage drop across the winding and I is the injected current.

This dual-circuit approach is particularly important when dealing with resistance values in the milliohm range, where even the resistance of a standard test cable could introduce significant measurement errors. The Kelvin method effectively removes this variable, ensuring that only the winding resistance is measured. You can read more about the theoretical basis of this technique on the four-terminal sensing Wikipedia page.

Compared to traditional 2-wire ohmmeter measurements, the Kelvin method can be up to 10 times more accurate on low-resistance windings — making it the preferred choice in quality-critical environments such as automotive, aerospace, and industrial motor manufacturing.

Key Advantages of Kelvin 4-Wire Measurement

What Equipment Is Used for Stator Winding Resistance Testing

Performing a reliable stator winding resistance test requires dedicated instrumentation designed for milliohm-level measurements. The most common solutions include:

Temperature is a critical factor in resistance testing: copper resistance increases with temperature at a rate of approximately 0.393% per °C. Professional test systems always log the winding temperature at the time of measurement and apply the appropriate correction factor. The correction methodology follows the guidelines defined in IEC international standards for electrical machine testing.

TST-S-5000: Technical Specifications

The TST-S-5000 by SM SYSTEM is an automatic test system for motor stators, alternators, and coils. Its resistance measurement module covers the full range required for industrial stator testing:

RangeResolutionTest CurrentAccuracy
5 mΩ0.1 μΩ1 A±(0.03% rdg + 0.3% range)
50 mΩ1 μΩ1 A±(0.03% rdg + 0.03% range)
500 mΩ10 μΩ100 mA±(0.03% rdg + 0.03% range)
5 Ω100 μΩ100 mA±(0.03% rdg + 0.03% range)
50 Ω1 mΩ10 mA±(0.03% rdg + 0.03% range)
500 Ω10 mΩ1 mA±(0.03% rdg + 0.02% range)
5 kΩ100 mΩ100 μA±(0.03% rdg + 0.02% range)
50 kΩ1 Ω10 μA±(0.03% rdg + 0.02% range)
500 kΩ10 Ω10 μA±(0.03% rdg + 0.02% range)
5 MΩ (GOM-804)1000 Ω1 μA±(0.3% rdg + 0.02% range)
5 MΩ (GOM-805)1000 Ω1 μA±(0.3% rdg + 0.02% range)

Temperature range: 0°C – 50°C  |  Accuracy (0°C–40°C): 0.3% ± 0.5°C  |  Resolution: 0.1°C

Industrial Applications of Stator Winding Resistance Testing

The Kelvin resistance test is performed at multiple stages of the electrical machine lifecycle:

In the context of electric vehicle (EV) motor production, stator winding resistance testing has become increasingly important. The stringent performance and safety requirements of EV drivetrains demand extremely tight resistance tolerances between phases, making the Kelvin method an indispensable part of the manufacturing process.

Interpreting the Test Results

Once the resistance values for each winding phase are obtained, the results are evaluated against two main criteria:

Any significant deviation from expected values should trigger a deeper investigation, including visual inspection of the winding connections, contact points, and solder joints.

tst s 5000 software screenshot
TST-S-5000 software: resistance test results with PASS indicators and winding temperature readout (23.8°C)

Frequently Asked Questions

The main difference between 2-wire and 4-wire resistance measurement is the measurement accuracy, especially for very low resistance values such as motor windings, stators, transformers, and inductors. In a 2-wire measurement, the resistance of the test leads is included in the result, introducing errors in the milliohm range. The 4-wire Kelvin method eliminates this by using separate circuits for current injection and voltage sensing, ensuring only the winding resistance is measured.

Temperature compensation allows the measured resistance value to be corrected according to the winding temperature, improving the accuracy of the test. Since copper resistance increases approximately 0.393% per °C, measurements taken at different temperatures cannot be directly compared without this correction. Professional test systems log the winding temperature and normalize the result to a reference temperature (typically 20°C or 25°C).

Winding resistance testing is important to verify the electrical integrity of the winding and detect issues such as bad connections, unbalanced phases, damaged wires, or manufacturing defects. When performed as part of end-of-line quality control, it ensures that only conforming units reach the market — reducing warranty claims and field failures.

Conclusion: A Fundamental Test for Electrical Machine Reliability

The Kelvin stator winding resistance test is a straightforward yet highly significant procedure for assessing the quality and long-term reliability of electrical windings. When integrated into a structured testing or maintenance workflow, it effectively reduces failure risk and extends the operational life of electric motors and generators. Whether applied in high-volume production environments or during field maintenance, the 4-wire Kelvin method remains the most accurate and reliable approach available today.