DocumentCode
1131019
Title
Anisotropic Fracture Behavior of Sintered Rare-Earth Permanent Magnets
Author
Li, Wei ; Li, Anhua ; Wang, Huijie
Author_Institution
Div. of Functional Mater., Central Iron & Steel Res. Inst., Beijing, China
Volume
41
Issue
8
fYear
2005
Firstpage
2339
Lastpage
2342
Abstract
Sintered rare-earth permanent magnets (for example, Sm 
Co 
, SmCo 
, and Nd Fe 
B magnets) are quite brittle and easily crack in the course of fabrication, machining, and application. Here, we report on an investigation of fracture behavior and mechanical characteristics of sintered rare-earth permanent magnets and discuss the origin of rare-earth magnet brittleness. We studied three groups of bending specimens with different orientations, cut from the same block of magnet. The bending strength was measured. The fracture surfaces were carefully observed by scanning electron microscopy and showed that the fracture behavior and bending strength of sintered rare-earth permanent magnets obviously exhibit anisotropy. Sintered Sm–Co magnets tend to cleavage fracture in the close-packed ( 
) plane or in the ( 
) plane. The fracture mechanism of sintered Nd Fe B magnet appears to be mainly intergranular fracture. Our analysis indicates that the anisotropy of fracture behavior and mechanical strength of sintered rare-earth magnets is caused by the strong crystal-structure anisotropy and grain texture created by magnetic field alignment during the fabrication process.
Co , SmCo , and Nd Fe B magnets) are quite brittle and easily crack in the course of fabrication, machining, and application. Here, we report on an investigation of fracture behavior and mechanical characteristics of sintered rare-earth permanent magnets and discuss the origin of rare-earth magnet brittleness. We studied three groups of bending specimens with different orientations, cut from the same block of magnet. The bending strength was measured. The fracture surfaces were carefully observed by scanning electron microscopy and showed that the fracture behavior and bending strength of sintered rare-earth permanent magnets obviously exhibit anisotropy. Sintered Sm–Co magnets tend to cleavage fracture in the close-packed ( ) plane or in the ( ) plane. The fracture mechanism of sintered Nd Fe B magnet appears to be mainly intergranular fracture. Our analysis indicates that the anisotropy of fracture behavior and mechanical strength of sintered rare-earth magnets is caused by the strong crystal-structure anisotropy and grain texture created by magnetic field alignment during the fabrication process.Keywords
bending strength; brittleness; crystal structure; fracture toughness; magnetic anisotropy; magnetomechanical effects; neodymium compounds; permanent magnets; scanning electron microscopy; sintering; Nd2Fe14B; Nd2Fe14B magnet; Sm-Co; Sm-Co magnets; anisotropic fracture; bending strength; crystal-structure anisotropy; fracture behavior; fracture mechanism; grain texture; intergranular fracture; magnetic field alignment; mechanical characteristics; mechanical strength; rare-earth magnet brittleness; rare-earth permanent magnets; scanning electron microscopy; Anisotropic magnetoresistance; Fabrication; Iron; Machining; Magnetic analysis; Magnetic force microscopy; Neodymium; Permanent magnets; Scanning electron microscopy; Surface cracks; Anisotropy; fracture behavior; mechanical strength; rare-earth permanent magnets;
fLanguage
English
Journal_Title
Magnetics, IEEE Transactions on
Publisher
ieee
ISSN
0018-9464
Type
jour
DOI
10.1109/TMAG.2005.852948
Filename
1492536
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