Digital signal processing of acoustic emission signals using power spectral density and counts statistic applied to single-point dressing operation

Dressing is an important operation for the grinding process. Its goal is to recondition the wheel tool to re-establish its cutting characteristics, owing to the wear produced after successive passes. Monitoring systems that use acoustic emission (AE) have been studied to correlate the signals with s...

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Bibliographic Details
Published in:IET science, measurement & technology measurement & technology, 2017-08, Vol.11 (5), p.631-636
Main Authors: Nascimento Lopes, Wenderson, Isaac Ferreira, Fabio, Aparecido Alexandre, Felipe, Santos Ribeiro, Danilo Marcus, Conceição Junior, Pedro de Oliveira, de Aguiar, Paulo Roberto, Bianchi, Eduardo Carlos
Format: Article
Language:English
Subjects:
acoustic emission
acoustic emission signal processing
AE monitoring system
AE signal processing
aluminium oxide grinding wheel
automatic control system
correlation methods
cutting
cutting tools
digital signal processing
filtering theory
grinding
grinding machines
grinding process
power spectral density
process automation
production engineering computing
production testing
Research Article
signal processing
single‐point dresser
single‐point dressing operation
spectral analysis
statistical analysis
tool cutting condition
wear
wheel tool reconditioning
wheels
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Summary:Dressing is an important operation for the grinding process. Its goal is to recondition the wheel tool to re-establish its cutting characteristics, owing to the wear produced after successive passes. Monitoring systems that use acoustic emission (AE) have been studied to correlate the signals with several tool conditions. This study brings a new approach of processing AE signals with the purpose of identifying the correct moment to stop the dressing, which is essential in an automatic control system. From the AE signals collected in dressing tests with aluminium oxide grinding wheel and single-point dresser, spectral analysis was made through power spectral density, selecting frequencies bands that best characterise the process. The statistical parameter ‘counts’ was applied to the raw signal unfiltered and filtered in the selected bands in order to identify the tool condition and, in turn, towards a monitoring system implementation. Results showed an expressive relation between tool cutting conditions and processed signals in the selected bands. There was a great disparity of the filtered signals in the selected bands and signals unfiltered, reflecting that the filtered ones were more efficient in terms of process automation.
ISSN:1751-8822
1751-8830
1751-8830
DOI:10.1049/iet-smt.2016.0317