Partekatu
Gorde erreferentzia
Izenburua
Hybrid Fault Detection and Diagnosis Approach of Power Connections for Induction MotorsEgilea
Argitalpen data
2025Beste erakundeak
https://ror.org/00wvqgd19Bertsioa
PostprintaDokumentu-mota
Kongresu-ekarpenaHizkuntza
IngelesaEskubideak
© 2025 IEEESarbidea
Sarbide irekiaArgitaratzailearen bertsioa
https://doi.org/10.1109/WEMDCD61816.2025.11014155Non argitaratua
IEEE Workshop on Electrical Machines Design, Control and Diagnosis (WEMDCD) Valletta (Malta), 09-10 April 2025Argitaratzailea
IEEEGako-hitzak
Data-driven methods
fault diagnosis
Hardware
Physics-based model (PBM) ... [+]
fault diagnosis
Hardware
Physics-based model (PBM) ... [+]
Data-driven methods
fault diagnosis
Hardware
Physics-based model (PBM)
ODS 7 Energía asequible y no contaminante
ODS 9 Industria, innovación e infraestructura
ODS 11 Ciudades y comunidades sostenibles [-]
fault diagnosis
Hardware
Physics-based model (PBM)
ODS 7 Energía asequible y no contaminante
ODS 9 Industria, innovación e infraestructura
ODS 11 Ciudades y comunidades sostenibles [-]
Laburpena
The increasing demand for reliable electric mobility
solutions highlights the need for advanced fault detection and
diagnosis (FDD) strategies to ensure system reliability and safety.
This paper pr ... [+]
The increasing demand for reliable electric mobility
solutions highlights the need for advanced fault detection and
diagnosis (FDD) strategies to ensure system reliability and safety.
This paper presents a hybrid approach that integrates physicsbased
models with data-driven techniques for FDD in induction
motors (IMs). A Hardware-in-the-Loop (HiL) platform is used
to generate synthetic data that replicates real-life operating
conditions. In this study, a progressive classification strategy
based on a One-Class Support Vector Machine (OCSVM) is
trained exclusively on healthy operation data and tested with
HiL-generated faulty responses to evaluate its anomaly detection
capabilities. Focusing on railway traction systems, the
research simulates common IM faults, including opposite-phase
wiring, high-resistive connections, and open-phase failures. By
extending the Cross Industry Standard Process for Data Mining
(CRISP-DM) methodology with physics-based model validation
and synthetic data generation, the proposed hybrid strategy
enhances scalability, effectively addressing challenges such as
limited faulty data and inadequate real-time monitoring. This
approach demonstrates significant potential for improving fault
detection in electric traction applications. [-]
