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Vol 275
Pages:
42-55
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Article
Geotechnical Engineering and Engineering Geology

Centrifugal pump and electrical motor fault detection with motor current signature analysis and automated machine learning

Authors:
Roman R. Khalikov1
Mikhail Yu. Chernetskiy2
Ilia E. Revin3
Vadim A. Potemkin4
About authors
  • 1 — Specialist ROTEC Digital Solutions JSC ▪ Orcid
  • 2 — Ph.D. Head of Department ROTEC Digital Solutions JSC ▪ Orcid
  • 3 — Ph.D. Researcher ITMO University ▪ Orcid
  • 4 — Ph.D. Researcher ITMO University ▪ Orcid
Date submitted:
2025-04-09
Date accepted:
2025-08-25
Online publication date:
2025-10-13
Date published:
2025-10-31

Abstract

Centrifugal pumps, as key components of hydraulic systems, play a fundamental role in ensuring the reliable operation of numerous industrial processes in sectors such as energy, chemical production, and oil refining, where uninterrupted equipment performance is of critical importance. Failures of centrifugal pumps can result in substantial financial losses due to costly repairs and unplanned production downtime. This paper presents an innovative approach to diagnosing and detecting faults in centrifugal pumps. The method is based on the application of Motor Current Signature Analysis (MCSA) in combination with automated machine learning (AutoML) technologies. Such an approach enables efficient and highly accurate identification of early signs of equipment malfunction. The experimental study was conducted using an open dataset collected under conditions close to real-world operation. The proposed method achieved a fault detection accuracy of 89 %, which significantly exceeds the performance of the traditional gradient boosting method. This confirms the advantage of a comprehensive model developed through AutoML. Further improvement in diagnostic accuracy was made possible by applying an enhanced Park’s vector transformation to the raw current and voltage data. This approach makes it possible to detect even subtle anomalies in pump operation, thereby strengthening the capability for early fault prediction. The study not only highlights the potential of MCSA as a non-invasive and scalable tool for equipment condition monitoring but also demonstrates the promise of AutoML for technical diagnostics of industrial pumps.

Область исследования:
Geotechnical Engineering and Engineering Geology
Keywords:
machine learning electric motor gradient boosting composite model AutoML fault detection time series
Go to volume 275

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