Magnetic losses and mechanical properties of Fe-4 to 7.8 wt% Si rapidly quenched alloys

Magnetic losses and mechanical properties of Fe-4 to 7.8 wt% Si rapidly quenched alloys

Magnetic and mechanical properties have been investigated in Fe-4 to 7.8 wt% Si rapidly quenched and annealed ribbons. The roles played by composition and microstructure on the magnetic energy losses and the tensile stress-strain behavior have been put in evidence, by carrying out the related experi...

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Veröffentlicht in:IEEE Transactions on Magnetics 1997-09, Vol.33 (5), p.3802-3804
Hauptverfasser: Fiorillo, F., Ferrara, E., Ferrando, L., Appino, C., Lebourg, C., Degauque, J., Baricco, M.
Format: Artikel
Sprache:eng
Schlagworte:
Annealing
Coercive force
Energy loss
ENERGY LOSSES
EXPERIMENTAL DATA
Frequency
Grain size
IRON BASE ALLOYS
Magnetic losses
MAGNETIC PROPERTIES
Magnetoelasticity
Magnetostriction
MATERIALS SCIENCE
Mechanical factors
MECHANICAL PROPERTIES
MICROSTRUCTURE
SILICON ALLOYS
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Beschreibung
Zusammenfassung:Magnetic and mechanical properties have been investigated in Fe-4 to 7.8 wt% Si rapidly quenched and annealed ribbons. The roles played by composition and microstructure on the magnetic energy losses and the tensile stress-strain behavior have been put in evidence, by carrying out the related experiments as a function of grain size. The energy losses attain a minimum value at the 6.7% Si composition at all frequencies in the investigated range d.c.-10 kHz. The vanishing of a demonstrably important magnetostriction-related coercivity contribution, which can be singled out in these stress-free samples, is recognized as the leading cause of loss minimization. The composition and grain size dependent stress-strain curves are found to obey a Hall-Petch law for the yield stress. While the elastic limit increases with the Si content, a decrease of the strain at fracture is correspondingly observed.
ISSN:0018-9464
1941-0069
DOI:10.1109/20.619576