An Over-Coupled Fused Coupler Based Acoustic Emission Sensor for Detecting Partial Discharges

Abstract Topics of this article concern the study of the fundamental nature of the sonoluminescence phenomenon occurring in liquids. At the Institute of Electrical Power Engineering at Opole University of Technology the interest in that phenomenon known as secondary phenomenon of cavitation caused by ultrasound became the genesis of a research project concerning acoustic cavitation in mineral insulation oils in which a number of additional experiments performed in the laboratory aimed to determine the influence of a number of acoustic parameters on the process of the studied phenomenona. The main purpose of scientific research subject undertaken was to determine the relationship between the generation of partial discharges in high-voltage power transformer insulation systems, the issue of gas bubbles in transformer oils and the generated acoustic emission signals. It should be noted that currently in the standard approach, the phenomenon of generation of acoustic waves accompanying the occurrence of partial discharges is generally treated as a secondary phenomenon, but it can also be a source of many other related phenomena. Based on our review of the literature data on those referred subjects taken, it must be noted, that this problem has not been clearly resolved, and the description of the relationship between these phenomena is still an open question. This study doesn’t prove all in line with the objective of the study, but can be an inspiration for new research project in the future in this topic. Solution of this problem could be a step forward in the diagnostics of insulation systems for electrical power devices based on non-invasive acoustic emission method.

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Experimental investigation on time-domain features in the diagnosis of rolling element bearings by acoustic emission

Journal of Vibration and Control ◽

10.1177/10775463211016130 ◽

2021 ◽

pp. 107754632110161

Author(s):

Aref Aasi ◽

Ramtin Tabatabaei ◽

Erfan Aasi ◽

Seyed Mohammad Jafari

Keyword(s):

Acoustic Emission ◽

Condition Monitoring ◽

Time Domain ◽

Central Moment ◽

Rolling Element Bearings ◽

Test Rig ◽

Acoustic Emission Sensor ◽

Outer Race ◽

Common Time ◽

Rolling Element

Inspired by previous achievements, different time-domain features for diagnosis of rolling element bearings are investigated in this study. An experimental test rig is prepared for condition monitoring of angular contact bearing by using an acoustic emission sensor for this purpose. The acoustic emission signals are acquired from defective bearing, and the sensor takes signals from defects on the inner or outer race of the bearing. By studying the literature works, different domains of features are classified, and the most common time-domain features are selected for condition monitoring. The considered features are calculated for obtained signals with different loadings, speeds, and sizes of defects on the inner and outer race of the bearing. Our results indicate that the clearance, sixth central moment, impulse, kurtosis, and crest factors are appropriate features for diagnosis purposes. Moreover, our results show that the clearance factor for small defects and sixth central moment for large defects are promising for defect diagnosis on rolling element bearings.

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Development of a low‐power wireless acoustic emission sensor node for aerospace applications

Structural Control and Health Monitoring ◽

10.1002/stc.2701 ◽

2021 ◽

Author(s):

Stephen Grigg ◽

Rhys Pullin ◽

Matthew Pearson ◽

David Jenman ◽

Robert Cooper ◽

...

Keyword(s):

Acoustic Emission ◽

Low Power ◽

Sensor Node ◽

Acoustic Emission Sensor ◽

Aerospace Applications

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High-temperature (> 1000 °C) acoustic emission sensor

10.1117/12.2009301 ◽

2013 ◽

Cited By ~ 2

Author(s):

Joseph A. Johnson ◽

Kyungrim Kim ◽

Shujun Zhang ◽

Di Wu ◽

Xiaoning Jiang

Keyword(s):

Acoustic Emission ◽

High Temperature ◽

Acoustic Emission Sensor

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Study of the Metal Crack Propagation by Acoustic Emission Testing

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.105-107.2179 ◽

2011 ◽

Vol 105-107 ◽

pp. 2179-2182

Author(s):

Wei Min Zhang ◽

Shu Xuan Liu ◽

Yong Qiu ◽

Cheng Feng Chen

Keyword(s):

Acoustic Emission ◽

Crack Propagation ◽

Acquisition System ◽

Signal Acquisition ◽

Sensor Signal ◽

Acoustic Emission Sensor ◽

Axial Tension ◽

Emission Testing ◽

Acoustic Emission Testing ◽

Signal Operating

Crack propagation is the main reason which leads to the invalidity of the metal components. A set of detecting equipment based on the acoustic emission method was designed, and it was mainly composed of acoustic emission sensor, signal operating circuits and signal acquisition system. Specimens of 16MnR material were manufactured and the static axial tension test of them was carried on. Acoustic emission signals from the specimen were detected by acoustic emission equipment by using piezoelectric ceramic sensor. Signal datum were acquired and operated by the acquisition system, as well as the acquisition program written for it. The final results has demonstrated that acoustic emission equipment designed for the test performed well in acquiring the signals induced by the metal crack propagation.

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Simultaneous Monitoring of Rolling-Element and Journal Bearings Using Analysis of Structure-Born Ultrasound Acoustic Emissions

Volume 13: Sound, Vibration and Design ◽

10.1115/imece2010-39814 ◽

2010 ◽

Cited By ~ 1

Author(s):

A. Albers ◽

M. Dickerhof

Keyword(s):

Acoustic Emission ◽

Acoustic Emissions ◽

Piezoelectric Sensor ◽

Journal Bearings ◽

Rolling Element Bearings ◽

Acoustic Emission Sensor ◽

Outer Race ◽

Rolling Element ◽

Characteristic Values ◽

Acoustic Emission Technology

The application of Acoustic Emission technology for monitoring rolling element or hydrodynamic plain bearings has been addressed by several authors in former times. Most of these investigations took place under idealized conditions, to allow the concentration on one single source of emission, typically recorded by means of a piezoelectric sensor. This can be achieved by either eliminating other sources in advance or taking measures to shield them out (e. g. by placing the acoustic emission sensor very close to the source of interest), so that in consequence only one source of structure-born sound is present in the signal. With a practical orientation this is often not possible. In point of fact, a multitude of potential sources of emission can be worth considering, unfortunately superimposing one another. The investigations reported in this paper are therefore focused on the simultaneous monitoring of both bearing types mentioned above. Only one piezoelectric acoustic emission sensor is utilized, which is placed rather far away from the monitored bearings. By derivation of characteristic values from the sensor signal, different simulated defects can be detected reliably: seeded defects in the inner and outer race of rolling element bearings as well as the occurrence of mixed friction in the sliding surface bearing due to interrupted lubricant inflow.

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