Acoustic Analysis: Definition, Methods and Industrial Applications

Definition: Acoustic analysis is the process of capturing, measuring, and interpreting sound and acoustic emission signals from industrial equipment to assess its condition and detect developing faults. Sound and vibration are byproducts of mechanical activity: rotating components, fluid flow, friction, and structural stress all produce characteristic acoustic signatures. When those signatures change, the change indicates a change in the underlying physical condition. Acoustic analysis translates those signals into actionable maintenance intelligence.

How Acoustic Analysis Works

Acoustic analysis follows a consistent signal chain regardless of the specific technique used. A transducer captures acoustic energy from the asset: this may be a microphone for audible airborne sound, an ultrasonic sensor for high-frequency airborne signals, or an acoustic emission sensor mounted directly on the equipment for structure-borne stress waves.

The transducer converts acoustic energy into an electrical signal. That signal is then amplified, filtered to remove irrelevant frequencies, and digitized for software processing. Analysis software examines the frequency spectrum and identifies patterns that correspond to known fault conditions.

Different fault types produce characteristic frequencies and spectral signatures. A bearing with insufficient lubrication generates a distinct ultrasonic output. A compressed air leak produces broadband noise in the ultrasonic range. Crack propagation in a pressure vessel generates short, high-energy stress wave bursts. The analysis task is to match the observed spectral pattern to the known signature for each fault type.

Airborne Acoustic Analysis vs. Acoustic Emission Analysis

Acoustic analysis divides into two main branches depending on the medium through which the signal travels and the frequency range of interest.

Airborne Acoustic Analysis

Airborne acoustic analysis captures sound waves traveling through air. The audible range covers 20 Hz to 20 kHz. The ultrasonic range extends above 20 kHz, with most industrial instruments operating between 20 kHz and 100 kHz.

Ultrasonic detectors are the primary tool. A technician directs the instrument at a target and listens through headphones while reading a decibel level on the display. A characteristic hissing sound in the ultrasonic range indicates compressed air or steam leaks, early-stage bearing faults, and electrical discharge (arcing, corona, and tracking) before those conditions are visible or audible at normal distances.

Acoustic Emission Analysis

Acoustic emission (AE) analysis captures high-frequency stress waves that travel through solid material when the material deforms, cracks, or undergoes friction. AE signals typically range from 100 kHz to several MHz. AE sensors are mounted directly on the asset surface, similar in form to accelerometers but optimized for much higher frequencies.

AE analysis is particularly suited to slow-speed rotating equipment, where vibration analysis loses sensitivity. It is also the primary technique for structural integrity monitoring of pressure vessels, storage tanks, and pipelines, where crack initiation and growth must be detected before they become safety hazards.

Factor Airborne Acoustic Analysis Acoustic Emission Analysis
Signal medium Air Solid material
Frequency range 20 Hz to 100 kHz (audible and ultrasonic) 100 kHz to several MHz
Sensor type Microphone or ultrasonic detector AE sensor (piezoelectric contact sensor)
Mounting Non-contact; handheld or fixed at a distance Direct contact; mounted on the asset surface
Best applications Leak detection, electrical discharge, bearing faults at early stages Slow-speed bearings, pressure vessels, structural crack detection
Typical fault types detected Compressed air leaks, steam leaks, corona discharge, arcing, early bearing wear Bearing spalling, crack initiation and growth, friction events, pipeline defects

Common Applications in Industrial Maintenance

  • Bearing fault detection: Acoustic emission and ultrasonic analysis detect early-stage bearing wear before it appears in vibration spectra. This is particularly valuable for slow-speed bearings (below 100 RPM) where vibration analysis loses sensitivity due to the low energy levels involved.
  • Lubrication monitoring: Insufficient lubrication produces a measurable increase in ultrasonic output from a bearing. Acoustic analysis can confirm when relubrication is needed and verify that the intervention was effective by showing a return to baseline levels.
  • Leak detection: Compressed air, steam, gas, and vacuum leaks produce broadband ultrasonic noise. Acoustic analysis can locate leaks in pipelines, valves, and fittings that are inaudible at normal working distances, supporting energy efficiency and safety programs in manufacturing and oil and gas facilities.
  • Electrical fault detection: Arcing, corona discharge, and tracking in electrical equipment produce distinctive ultrasonic signatures detectable through cabinet panels with an airborne acoustic detector, allowing faults to be identified without opening energized equipment.
  • Structural monitoring: AE sensors mounted on pressure vessels, storage tanks, and structural members detect crack initiation and growth in real time, supporting inspection programs and fitness-for-service assessments.

Acoustic Analysis vs. Vibration Analysis

Acoustic analysis and vibration analysis are complementary techniques, not competing ones. Each covers fault types and operating conditions where the other has limitations.

Vibration analysis is the dominant technique for rotating machinery faults: imbalance, misalignment, and bearing damage on equipment running at moderate to high speeds. It is well established, widely deployed, and supported by decades of diagnostic practice.

Acoustic analysis adds value in the cases where vibration is less effective: slow-speed equipment where vibration energy is too low to detect reliably, early-stage lubrication faults before they generate detectable vibration changes, leak detection in pressurized systems, and electrical discharge in switchgear and transformers. In a complete predictive maintenance program, both techniques are used together to cover the full range of fault types an asset may develop.

Factor Acoustic Analysis Vibration Analysis
Primary signal type Sound and stress waves (ultrasonic and AE frequencies) Mechanical vibration (acceleration, velocity, displacement)
Sensor contact required Not required for airborne; required for AE Yes (accelerometer mounted on the asset)
Best speed range All speeds; especially effective below 100 RPM Moderate to high speeds; less sensitive below 100 RPM
Early-stage bearing detection Strong; detects pre-vibration fault stages Good at moderate/high speed; limited at low speed
Leak detection Yes (compressed air, steam, gas, vacuum) No
Electrical fault detection Yes (arcing, corona, tracking) No
Integration with IIoT platforms Yes, via fixed AE or ultrasonic sensors Yes, via continuously monitored accelerometers

Acoustic Analysis Equipment

Ultrasonic Detector

A handheld instrument for airborne and structure-borne ultrasonic detection. Used during inspection rounds, the technician scans the target area and listens through headphones while reading a decibel level on the display. Applications include compressed air and steam leak location, early-stage bearing fault detection, and electrical discharge identification. Results are immediate and require no signal processing beyond the instrument's internal heterodyne conversion.

Acoustic Emission Sensor

A contact sensor for structure-borne AE analysis, similar in physical form to an accelerometer but designed for the 100 kHz to several MHz frequency range. AE sensors are mounted directly on the asset and used for slow-speed bearing and gearbox monitoring, pressure vessel and pipeline integrity assessment, and structural crack detection and propagation monitoring.

Acoustic Camera

An array of microphones arranged in a fixed geometry that produces a visual overlay showing the loudest sound source in a scene. Used for leak detection surveys across large areas, noise source identification in industrial environments, and quality control applications in manufacturing where sound signatures are linked to assembly quality. The spatial visualization helps maintenance teams prioritize which sources to address first when multiple leaks or noise sources are present.

Continuous acoustic and vibration monitoring on every critical asset

Tractian's condition monitoring platform tracks acoustic, vibration, and temperature signals from rotating equipment in real time, detecting fault patterns before they become failures. No manual inspection rounds required.

See Tractian condition monitoring

Frequently Asked Questions

What is acoustic analysis used for in maintenance?

Acoustic analysis is used to detect fault conditions in industrial equipment by measuring sound and acoustic emission signals. Common applications include early-stage bearing fault detection, lubrication monitoring, compressed air and steam leak detection, electrical discharge detection in switchgear, and structural crack monitoring. It is especially valuable for slow-speed equipment and assets where vibration analysis has limited sensitivity.

What is the difference between acoustic analysis and vibration analysis?

Both techniques detect mechanical faults in industrial equipment but work at different frequency ranges and suit different applications. Vibration analysis uses accelerometers to measure low-to-mid frequency vibration (1 Hz to 20 kHz) and excels at detecting imbalance, misalignment, and bearing damage on moderate and high-speed rotating machinery. Acoustic analysis operates at ultrasonic frequencies (above 20 kHz for airborne, up to several MHz for acoustic emission) and is better suited to slow-speed equipment, early lubrication faults, leak detection, and electrical fault detection. The two techniques are complementary in a complete predictive maintenance program.

What is acoustic emission analysis?

Acoustic emission (AE) analysis captures high-frequency stress waves (typically 100 kHz to several MHz) that propagate through solid material when the material deforms, cracks, or undergoes friction. AE sensors are mounted directly on the asset and detect events that would be invisible to vibration sensors. Primary applications include slow-speed bearing monitoring, pressure vessel and pipeline integrity, and structural crack detection.

How does acoustic analysis support predictive maintenance?

Acoustic analysis provides fault signatures at earlier stages than many other techniques. A bearing in the initial stages of degradation may show no change in temperature or vibration but will produce a measurable increase in ultrasonic output. By detecting this change early, maintenance teams can plan an intervention before the fault progresses to a failure, avoiding unplanned downtime. Acoustic data feeds into condition monitoring platforms alongside vibration, temperature, and current signals to build a complete asset health picture.

The Bottom Line

Acoustic analysis is a practical and sensitive tool for detecting fault conditions that are difficult to identify with visual inspection or conventional vibration monitoring alone. For slow-speed equipment, electrical assets, and pressurized systems, it fills gaps that other techniques leave open.

In a complete predictive maintenance program, acoustic analysis sits alongside vibration, temperature, and current monitoring as one of the data streams that feeds the overall asset health picture. Each technique covers fault types the others may miss, and together they give maintenance teams the earliest possible warning before failures occur.

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