Abstract
Degraded or defect machine components and consumables negatively impact manufacturing quality and productivity. Diagnosing and predicting the wear or degradation status of critical machine components or parts are therefore of general interest. To tackle this challenge, data-driven approaches based on supervised machine learning principles have demonstrated promising results. However, supervised learning models capable of degradation identification require large quantities of data. In practice, run-to-failure data in large amounts is usually not available and expensive to obtain. To overcome this issue, this study proposes an unsupervised learning approach for degradation prognostics of machine tool components and consumables. It uses time series of multi-sensor signal data, which are transformed into a feature representation. The features consist of various characterizations of the time series, allowing to make different signal measurements comparable, and cluster them according to their feature values. The herewith obtained density-based clustering model is used to diagnose and predict the degradation states of components and parts in unknown conditions. The novelty in the proposed approach lies within the identification of continuous component and part degradation states based on unsupervised learning principles. The proposal is verified and demonstrated on an exemplary data set containing a small sample of run-to-failure multi-sensor signals of milling inserts and their corresponding wear state. By the application of the proposed procedure on the exemplary data set, we demonstrate that an unsupervised clustering approach is capable of separating wear data such that meaningful and accurate estimations of the part condition are possible. The advantages are its ability to cope with scarce data sets, its limited engineering and hyperparameter tuning effort, and its straightforward implementation to a multitude of degradation and wear diagnostics scenarios.
Highlights
Machine tools in manufacturing value chains are critical in view of amortization and smooth supply chain operation.Degraded consumables and components affect both aspects, as they increase the risk for non-conformities and unplanned downtimes [1, 2]
There are different feed rates, depths of cut (DOC), and materials used, which allows to test the abilities of the proposed approach
The wear is given as a quantitative indication of the VB value, which represents the width of the damaged surface in reference to its original state (Fig. 6b)
Summary
Machine tools in manufacturing value chains are critical in view of amortization and smooth supply chain operation.Degraded consumables and components affect both aspects, as they increase the risk for non-conformities and unplanned downtimes [1, 2]. Machine tools in manufacturing value chains are critical in view of amortization and smooth supply chain operation. The maintenance approaches can be divided into three main types: corrective, preventive, and predictive [3]. Preventive maintenance can be costly and inhibit the risk of chance failures, which remain unnoticed without monitoring. Wear status and conditions of machine components need to be continuously detected and assessed, to allow for predictive maintenance. The diagnostic and prediction of wear on critical components and parts are primary research objects, according to Kusiak [4]. They are generally referred to as prognostics and health management (PHM).
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