Abstract
The new generation of ICT solutions applied to the monitoring, adaptation, simulation and optimisation of factories are key enabling technologies for a new level of manufacturing capability and adaptability in the context of Industry 4.0. Given the advances in sensor technologies, factories, as well as machine tools can now be sensorised, and the vast amount of data generated can be exploited by intelligent information processing techniques such as machine learning. This paper presents an online tool wear classification system built in terms of a monitoring infrastructure, dedicated to perform dry milling on steel while capturing force signals, and a computing architecture, assembled for the assessment of the flank wear based on deep learning. In particular, this approach demonstrates that a big data analytics method for classification applied to large volumes of continuously-acquired force signals generated at high speed during milling responds sufficiently well when used as an indicator of the different stages of tool wear. This research presents the design, development and deployment of the system components and an overall evaluation that involves machining experiments, data collection, training and validation, which, as a whole, has shown an accuracy of 78%.
Highlights
Industry 4.0 aims at leveraging manufacturing systems to the level where the right combination of advanced information and communication technologies (ICT) and manufacturing enables the implementation of flexible, smart and reconfigurable manufacturing processes [1,2]
This paper presented an indirect online condition monitoring system that exploits a vast amount of high frequency generated sensory data with deep learning
An online tool wear classification system built in terms of a monitoring infrastructure, dedicated to performing dry milling on steel while capturing force signals in real time, and a computing architecture, assembled for the real-time assessment of the flank wear based on deep learning
Summary
Industry 4.0 aims at leveraging manufacturing systems to the level where the right combination of advanced information and communication technologies (ICT) and manufacturing enables the implementation of flexible, smart and reconfigurable manufacturing processes [1,2]. Depending on the cutting conditions and purpose of the workpiece, finding the right moment for replacing a tool is challenging as this usually happens either too late or too soon In the former, tools can present signs of wear earlier than expected, requiring prompt replacement before affecting the quality of the manufactured workpiece. This paper presents the design, development, deployment and validation of an online tool wear classification system that fits within the area of control monitoring systems and predicted condition-based maintenance. It enlarges a methodology for the online assessment of flank wear based on force signals’ classification using deep learning.
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