Effect of plastic strain and forming temperature on magnetic properties of low-carbon steel

Claw poles are a key component of automobile generators. The output power performance of the generator is very dependent on the magnetic properties of its claw poles. Plastic deformation is known to significantly change the magnetic behavior of ferromagnetic materials in claw poles. In this paper, c...

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Bibliographic Details
Published in:International journal of minerals, metallurgy and materials metallurgy and materials, 2020-02, Vol.27 (2), p.210-219
Main Authors: Zeng, Fan, Bai, Xue-jiao, Hu, Cheng-liang, Tang, Min-jun, Zhao, Zhen
Format: Article
Language:English
Subjects:
Carbon content
Ceramics
Characterization and Evaluation of Materials
Chemistry and Materials Science
Coercivity
Cold working
Composites
Corrosion and Coatings
Error analysis
Ferromagnetic materials
Fluctuations
Flux density
Glass
Hot forming
Hysteresis loops
Low carbon steel
Low carbon steels
Machining
Magnetic fields
Magnetic flux
Magnetic properties
Materials Science
Metallic Materials
Natural Materials
Plastic deformation
Plastics
Poles
Remanence
Room temperature
Surface roughness
Surfaces and Interfaces
Thin Films
Tribology
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Summary:Claw poles are a key component of automobile generators. The output power performance of the generator is very dependent on the magnetic properties of its claw poles. Plastic deformation is known to significantly change the magnetic behavior of ferromagnetic materials in claw poles. In this paper, changes in the magnetic properties of low-carbon steel, used for claw pole components due to their plastic deformation, were investigated for different strains and temperatures. Ring-shaped material samples were prepared by machining and their magnetic properties were measured. The surface roughness was first evaluated and a machining process with an arithmetic average of roughness Ra 1.6 µm was selected as enabling the lowest measurement error. Hysteresis loops at different applied magnetic fields of the material were obtained for different plastic strains and forming temperatures. The magnetic parameters of magnetic flux density, coercivity, and remanence were obtained and compared with magnetic flux density as the primary focus. Results showed that machining, cold forming, and hot forming all led to lower magnetic flux density, larger coercivity, and smaller remanence. Magnetic flux density showed a sharp decrease at the start of plastic deformation, but as the strain increased, the decreasing trend gradually reached a constant value. The decrease was much larger for cold forming than for hot forming. For example, at 500 A/m, the degradation of magnetic flux density with a reduction percentage of 5% at room temperature was about 50%, while that of hot forming at 1200°C was about 10%. Results of this research may provide a reference for the future process design of hot-forged claw poles.
ISSN:1674-4799
1869-103X
DOI:10.1007/s12613-019-1905-7