Efficient Hairpin Winding Fault Detection Using Impedance Measurements

Zhang, Yu; Huangfu, Yixin; Ziada, Youssef; Habibi, Saeid

doi:10.1109/access.2023.3309247

IEEE Access

2023

DOI: 10.1109/access.2023.3309247

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Efficient Hairpin Winding Fault Detection Using Impedance Measurements

Yu Zhang,

Yixin Huangfu,

Youssef Ziada

et al.

Abstract: This study investigates various hairpin winding faults in electric motors using impedance measurements. Both high-frequency and low-frequency impedances are measured to characterize winding fault conditions. This study proposes various techniques to extract distinctive feature patterns that are associated with fault conditions. These include open circuit faults that show significant discrimination within the low-frequency range, and welding mismatch faults that are distinguished by a proposed similarity indica… Show more

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2024

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Cited by 3 publications

References 35 publications

(35 reference statements)

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A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

Zhu,

Zhang,

Yin

2024

Int J Adv Manuf Technol

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A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

Zhu,

Zhang,

Yin

2024

Int J Adv Manuf Technol

View full text Add to dashboard Cite

A Hybrid Fault Detection Method for Hairpin Windings Integrating Physics Model and Machine Learning

Zhang,

Huangfu,

Ziada

et al. 2024

IEEE Access

Self Cite

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This study proposes a hybrid fault detection methodology for detecting epoxy faults in hairpinbased stator windings of electric motors. The hybrid methodology integrates a model-based approach for feature extraction and a data-driven approach for fault classification. A new lumped-parameter equivalent circuit model specifically for hairpin windings is developed. It can accurately simulate the high-frequency impedance behaviors of hairpin windings and physically interpret the distinction of the measurement curves under different epoxy configurations. Using system identification, the parameters of this new model are identified to extract the features of phase windings, reflecting different fault conditions by varying the parameters in distinct ranges. Fault classification is implemented using a data-driven method to distinguish the underlying patterns, which is difficult to achieve by conventional threshold limit checking due to the inevitably introduced noise and uncertainties. Principal Component Analysis (PCA) is applied to refine the features, followed by a Support Vector Machine (SVM) performing fault classification. The proposed hybrid methodology successfully detects epoxy-related fault conditions, providing a new strategy for fault detection.

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Laser contacting of hairpin windings in electrical vehicle motors using ring-mode laser beams based on angularly-uniform Lissajous trajectories

Zhu,

Ji,

Zhang

et al. 2024

Opt. Express

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The contacting process of hairpin windings is deemed the most important and challenging process in manufacturing electric vehicle motors. This paper proposes a ring-mode laser contacting method for copper hairpin windings based on Lissajous-shaped cyclic scanning with a uniform angular speed. Two key variables, trajectory cycle n and angular multiplier k, which represent the laser energy input and distribution respectively, were investigated via single-factor experiments. Morphology, microstructure, mechanical and electrical properties were analyzed consequentially to show the influence on the contact quality. The results show that, as n increases, contact appearance is criticized for being under-contacted, well-contacted, or over-contacted. Molten pool behaviors affected by n variations determine morphology formation. Larger k facilitates molten pool evolution and improves laser contacting efficiency. Fusion zone (FZ) has directional columnar grains, while heat-affected zone (HAZ) has overgrown equiaxed grains coarser than those of base metal (BM). The microstructure of FZ becomes coarser if n increases, or finer if k increases. The highest tensile force of 712.5 N was reached when k = 4, n = 6. Ductile dimple fractures in FZ indicate the contacts’ excellent strength and toughness. FZ and HAZ show lower microhardness than BM due to thermal softening. FZ is slightly harder than HAZ due to its densely-interlaced microstructure. Poor contacts cause reduction in their electrical conductivity and increase in their resistance.

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Efficient Hairpin Winding Fault Detection Using Impedance Measurements

Cited by 3 publications

References 35 publications

A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

A Hybrid Fault Detection Method for Hairpin Windings Integrating Physics Model and Machine Learning

Laser contacting of hairpin windings in electrical vehicle motors using ring-mode laser beams based on angularly-uniform Lissajous trajectories

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