A Data-Driven Approach to Air Leakage Detection in Pneumatic Systems Show others and affiliations
2021 (English) In: 2021 Global Reliability and Prognostics and Health Management (PHM-Nanjing): October 15-17, 2021 in Nanjing, China / [ed] Wei Guo; Steven Li, IEEE, 2021Conference paper, Published paper (Refereed)
Abstract [en]
During the transition phase of traditional manufacturing companies towards smart factories, they are likely to experience challenges like lack of prehistoric data recordings or events on which the machine learning models need to be trained. This paper introduces a novel approach of artificially induced anomalies for data labelling. Moreover, for newly installed systems or a setup, which has not seen any kind of malfunction yet, the combination of artificially induced anomalies by experiments and machine learning model help to proactively prepare for any kind of future hindrance of the production systems. Two experiments were performed for detection of air leakage. The first one was designed to identify 'sensitive feature' and understand the behaviour of the sensor readings with respect to different state of the machine. The second one was performed to capture more data points pertaining to leaking state of machine on a normal production day since the first one was conducted on a maintenance break). RUSBoosted bagged trees model was built as a supervised machine-learning model, which was yielded 98.73% accuracy, 99.40% precision, recall of 99.21%, and F1 score of 99.30% on test data for detecting pneumatic leakage. As a conclusion, previously unknown hidden patterns and insights regarding temperature feature along with a standardized and systematic methodology are the important deliverables of this study.
Place, publisher, year, edition, pages IEEE, 2021.
Keywords [en]
Artificial anomalies, Data labelling, Data-driven decision-making, Machine learning, Pneumatic leakage, Predictive maintenance, Pneumatics, Supervised learning, Trees (mathematics), Air leakage, Artificial anomaly, Data driven decision, Data-driven approach, Decisions makings, Machine learning models, Decision making
National Category
Computer Sciences Other Computer and Information Science Robotics and automation
Research subject Skövde Artificial Intelligence Lab (SAIL)
Identifiers URN: urn:nbn:se:his:diva-20891 DOI: 10.1109/PHM-Nanjing52125.2021.9612973 Scopus ID: 2-s2.0-85123450051 ISBN: 978-1-6654-0131-9 (electronic) ISBN: 978-1-6654-0130-2 (electronic) ISBN: 978-1-6654-2979-5 (print) OAI: oai:DiVA.org:his-20891 DiVA, id: diva2:1634628
Conference 12th IEEE Global Reliability and Prognostics and Health Management, PHM-Nanjing 2021, Nanjing 15 October 2021 through 17 October 2021, Code 174772
Funder Vinnova, 201900789
Note © 2021 IEEE.
This paper has been produced from the Master thesis study of the first and second authors at Chalmers University of Technology. The authors would like to thank the Production 2030 Strategic Innovation Program funded by VINNOVA for their funding of the research project PACA-Predictive Maintenance using Advanced Cluster Analysis (Grant No. 201900789), which this study has been conducted. Thanks also to Thomas Sundqvist, Jonas Vallström, and Robert Andersson Jarl for their guidance and support with the real-time data from a real-world manufacturing system. This study has been conducted within Production Area of Advance at the Chalmers University of Technology.
2022-02-032022-02-032025-02-05 Bibliographically approved