Abstract
Gearboxes are widely used in industrial processes as mechanical power transmission systems. Then, gearbox failures can affect other parts of the system and produce economic loss. The early detection of the possible failure modes and their severity assessment in such devices is an important field of research. Data-driven approaches usually require an exhaustive development of pipelines including models’ parameter optimization and feature selection. This paper takes advantage of the recent Auto Machine Learning (AutoML) tools to propose proper feature and model selection for three failure modes under different severity levels: broken tooth, pitting and crack. The performance of 64 statistical condition indicators (SCI) extracted from vibration signals under the three failure modes were analyzed by two AutoML systems, namely the H2O Driverless AI platform and TPOT, both of which include feature engineering and feature selection mechanisms. In both cases, the systems converged to different types of decision tree methods, with ensembles of XGBoost models preferred by H2O while TPOT generated different types of stacked models. The models produced by both systems achieved very high, and practically equivalent, performances on all problems. Both AutoML systems converged to pipelines that focus on very similar subsets of features across all problems, indicating that several problems in this domain can be solved by a rather small set of 10 common features, with accuracy up to 90%. This latter result is important in the research of useful feature selection for gearbox fault diagnosis.
Highlights
Gearboxes are crucial devices in industrial processes, as they play an important role in power transmission
The section is divided into two main subsections, each one devoted to one of the Auto Machine Learning (AutoML) systems considered in this work
This paper presents the application of two AutoML systems, H2O Driverless AI (DAI) and TPOT, for obtaining fault severity ML pipelines for spur gears under three different failures modes at different severity levels
Summary
Gearboxes are crucial devices in industrial processes, as they play an important role in power transmission. Previous studies have visually shown that the vibration signal behavior is non-monotonic to the fault severity increment in helical gearboxes [9,10]; that is, the signal amplitude does not increase with the fault. ML is everywhere with successful applications in diverse domains such as automatic programming [41] and the prediction of complex chemical processes [42], and the list of examples grows every day This success, has created the need to simplify and accelerate the development of problem-specific ML deployments. The latter, on the other hand, employs a search process to discover large model architectures [49,50,51]
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