MULTIMILLING-INSERT WEAR ASSESSMENT USING NON-LINEAR VIRTUAL SENSOR, TIME-FREQUENCY DISTRIBUTION AND NEURAL NETWORKS

Autor:	Tzong-Chyi Tzeng, C. James Li
Rok vydání:	2000
Předmět:	Engineering Insert (composites) Signal processing Torsional vibration Artificial neural network business.industry Mechanical Engineering Acoustics Aerospace Engineering Control engineering Signature (logic) Computer Science Applications Vibration Nonlinear system Control and Systems Engineering Signal Processing Tool wear business Civil and Structural Engineering
Zdroj:	Mechanical Systems and Signal Processing. 14:945-957
ISSN:	0888-3270
DOI:	10.1006/mssp.1999.1282
Popis:	The objective of this study is to establish a signal processing methodology that can infer the state of milling insert wear from translational vibration measured on the spindle housing of a milling machine. First, the tool wear signature in a translational vibration is accentuated by mapping the translational vibration into a torsional vibration using a previously identified non-linear relationship between the two, i.e. a virtual sensor. Second, a time-frequency distribution, i.e. a Choi–Williams distribution, is calculated from the torsional vibration. Third, scattering matrices and orthogonalisation are employed to identify the time–frequency components that are best correlated to the state of wear. Fourth, a neural network is trained to estimate the extent of wear from these critical time frequency components. The combination of the virtual sensor, time–frequency analysis and neural network is then validated with data obtained from real cutting tests.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::cac4a6850c5b0c40fb6e95c6c1104f3e https://doi.org/10.1006/mssp.1999.1282 Zobrazit plný text záznamu Full Text from ScienceDirect