Abstract
Tool fault diagnosis in numerical control (NC) machines plays a significant role in ensuring manufacturing quality. However, current methods of tool fault diagnosis lack accuracy. Therefore, in the present paper, a fault diagnosis method was proposed based on stationary subspace analysis (SSA) and least squares support vector machine (LS-SVM) using only a single sensor. First, SSA was used to extract stationary and non-stationary sources from multi-dimensional signals without the need for independency and without prior information of the source signals, after the dimensionality of the vibration signal observed by a single sensor was expanded by phase space reconstruction technique. Subsequently, 10 dimensionless parameters in the time-frequency domain for non-stationary sources were calculated to generate samples to train the LS-SVM. Finally, the measured vibration signals from tools of an unknown state and their non-stationary sources were separated by SSA to serve as test samples for the trained SVM. The experimental validation demonstrated that the proposed method has better diagnosis accuracy than three previous methods based on LS-SVM alone, Principal component analysis and LS-SVM or on SSA and Linear discriminant analysis.
Highlights
Rapid technological development has brought automated and intelligent production processes to manufacturing
The present study proposes a damage diagnosis approach to Numerical control (NC) machine tools based on subspace analysis (SSA) and least squares support vector machine (LS-support vector machine (SVM))
The original data are transformed from one-dimensional data into high-dimensional signals using phase space reconstruction (PSR)
Summary
Rapid technological development has brought automated and intelligent production processes to manufacturing. Numerical control (NC) machines are flexible, high-performance automated machines that can solve complex and sophisticated processing problems. NC machines play an important role in industries that rely on high precision, high productivity and strong adaptability. In practice, owing to tool damage or failure, NC machine processing performance degrades, even leading to scraping of the workpiece. Tool faults account for about 20% of machine failures. Monitoring and identifying NC machine tool faults in a timely and accurate manner has attracted considerable interest. It is a challenge to develop and adopt effective signal processing techniques that can discover the crucial damage information from responsive signals [1]
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