Technology guide

Contactless torque measurement — principles, methods and industrial applications

Torque is the truth signal in the drivetrain. Contactless telemetry measures it directly on the rotating shaft — without slip rings, batteries, or mechanical signal pickup.

Discuss a measurement task View torque service

Strain gauge measurement directly on the rotating shaft

Inductive power transfer instead of batteries or slip rings

Digital signal acquisition on the shaft

Applications in automotive, test benches and industry

Principle

What is contactless torque measurement?

Contactless torque measurement captures torque on a rotating shaft without mechanical contact between the rotating measurement part and the stationary evaluation unit.

The proven sensor principle is still the strain gauge. Under torsion, the shaft deforms minimally, the strain gauge changes electrical resistance, and torque is calculated from that signal. The progress is in power transfer, digitization and data transmission.

In telemetric torque measurement, a stator antenna supplies the rotor electronics inductively. At the same time, the rotor unit sends digitized measurement data back to the control unit. No brushes, no slip contacts, no battery.

Strain gauge application on a measurement shaft for torque measurement — Strain gauge application and telemetry layout belong together: the sensor signal is created directly on the rotating measurement point.

Rotor unit

Mounted directly on the shaft, it powers the strain gauges, captures sensor signals and digitizes them at the rotating measurement point.

Stator unit

Creates the inductive field for power transfer and receives the digitally transmitted measurement data without contact.

Control unit

Controls power transfer, processes data and provides values as analog or CAN bus signals for test bench and vehicle use.

Slip ring vs. telemetry

Measurement methods compared

Industrial measurement tasks are not decided by lab values alone, but by performance at speed, with oil, temperature, relative motion and maintenance pressure.

AXON stator unit as the contactless interface to rotor telemetry — Contactless telemetry separates the rotating measurement point from stationary evaluation without mechanical signal pickup.

Recommended for rotating shafts

Telemetry with strain gauges

Principle: Strain gauges on the shaft plus inductive power and data transfer
Strength: Precise, maintenance-free and robust at high speeds
Limit: Application and layout must match the specific shaft
Fit: Automotive, test benches, endurance testing, machinery

Slip ring

Principle: Strain gauge signal through mechanical contacts
Strength: Known method for clean lab conditions
Limit: Wear, signal noise and maintenance in real environments
Fit: Moderate speeds, short tests, simple lab setups

Magnetoelastic

Principle: Change of magnetic properties under mechanical stress
Strength: Contactless and no applied strain gauges
Limit: Only for suitable shaft materials and usually less flexible
Fit: Production-adjacent applications and condition monitoring

Optical

Principle: Torsion via light signals or phase shift
Strength: Theoretically precise in very clean environments
Limit: Sensitive to contamination, oil mist and vibration
Fit: Research and clean special setups

Benefits of contactless telemetry

Maintenance-free

No brushes, slip contacts or mechanical abrasion — important for endurance runs and long-term tests.

High rotational speed

Inductive telemetry avoids the mechanical limits of classical slip rings in dynamic drivetrains.

Robust in real environments

Oil, humidity, temperature, contamination and vibration are considered in application and protection.

No batteries

The rotor unit is inductively powered. Battery replacement and battery-related measurement failures are avoided.

Anti-EMC for e-drives

Measurements near inverters and high-voltage environments need interference-resistant data transfer.

On-shaft digitization

Tiny analog signals are digitized directly on the shaft before contactless transmission.

Air-gap tolerance

Larger transfer distances help when rotor and stator move relative to each other.

Operating data visibility

Temperature, supply status and signal quality help assess the measurement chain during tests.

Applications

Typical applications

Contactless torque measurement is strongest where the measurement point rotates, is hard to access, or must remain stable over long test durations.

Automotive test vehicle for drivetrain torque measurement

Vehicle testing

Automotive & e-mobility

Torque measurement on side shafts, cardan shafts, transmission inputs and outputs, and e-drives — including transient states, recuperation and EMC-loaded environments.

Torque measurement Service for rotating shafts AXON J1DB 1-channel strain gauge telemetry

Test bench

Test benches

Engine, transmission, component, brake and dynamometer test benches need reproducible torque data across many measurement cycles.

Measurement shaft application From component to measurement shaft AXON J2DT Strain gauge + temperature

Mechanical engineering production with heavy industrial components and drive technology

Machinery

Machinery & industrial drives

Torque traces support load spectra, condition monitoring and early detection of wear or misalignment.

Strain gauge application Sensorics directly on the component

Wind turbines as an application for robust torque and load measurement

Wind power

Wind, aerospace and high-end validation

High loads, relative movement and strict documentation requirements call for robust measurement chains with traceable operating parameters.

Contact AXON Clarify your measurement task

From measurement task to ready-to-use solution

AXON treats torque measurement as a complete measurement chain: sensor, telemetry, mechanical integration and calibration.

Measurement shafts and rotating components for industrial torque measurement — Measurement shaft, rotor unit, stator position and interface need to fit together mechanically and electrically.

1. Define the task

Clarify shaft, speed range, torque range, temperature, media exposure, installation space and interfaces.

2. Design strain gauges and telemetry

Select strain gauges, rotor unit, antennas, control unit and protection for the application.

3. Integrate mechanically

Position rotor and stator sides so power transfer, data transmission and installation space work together.

4. Calibrate and commission

Check, calibrate, document and hand over the measurement chain for test bench, vehicle or machine.

System selection

Which AXON system fits the task?

The right system depends on whether the task needs torque only, multiple strain gauge channels, additional temperature or a measurement flange.

AXON J1DB

Universal 1-channel strain gauge telemetry transmitter for torque measurement.

Details

AXON J2D / J2DT

Two-channel strain gauge telemetry, optionally combined with temperature.

Details

AXON JXTH

Multi-channel telemetry for temperature measurement on rotating components.

Details

AXON AT10

Plug-and-play measurement flange for existing torque flange environments.

Details

FAQ: contactless torque measurement

Why is contactless torque measurement more robust than a slip ring?

Because power and data are transmitted without mechanical contacts. There are no brushes, no contact wear and fewer signal issues from transition resistance.

Is torque measured directly?

The shaft torsion is measured via strain gauges. Torque is then determined through calibration and the measurement chain.

What data does AXON need for a layout?

Useful inputs include shaft or component data, expected torque range, speed, installation space, temperature, media exposure and the required interface to the test bench or vehicle.

Plan torque measurement for your rotating application

Describe shaft, installation space, speed, temperature and interface. AXON will assess which telemetry and strain gauge application makes sense.

Discuss a measurement task