Title :
Anisotropic HDDR epoxy bonded magnets from NdFeBZr
Author :
McGuiness, P.J. ; Short, C.L. ; Harris, I.R.
Author_Institution :
Sch. of Metall. & Mater., Birmingham Univ., UK
fDate :
9/1/1992 12:00:00 AM
Abstract :
The hydrogenation disproportionation desorption recombination (HDDR) process has been established as an effective processing route for the production of isotropic NdFeB coercive powder. By the addition of very small amounts of zirconium to the initial composition, it has also been found that anisotropic powder can be produced during the HDDR process. Two compositions were selected for this work: Nd16Fe 75.9B8Zr0.1 and Nd16Fe75.7B8Zr0.3. These alloys were processed at temperatures between 770°C and 840°C, and a maximum coercivity of 800 kA/m was achieved for the alloy containing 0.1 at.% Zr at a processing temperature of 795°C, but the alloy containing 0.3 at.% Zr failed to exhibit any coercivity greater than 120 kA/m, across a wide range of processing temperatures. This can be attributed to a much larger final grain size for this material under the processing conditions used. Magnetic anisotropy is produced by the submicron grains of Nd2Fe14B recombining from the disproportionated structure with a preferred orientation distribution
Keywords :
boron alloys; coercive force; ferromagnetic properties of substances; grain size; heat treatment; iron alloys; magnetic anisotropy; neodymium alloys; permanent magnets; powder metallurgy; zirconium alloys; 770 to 840 degC; Nd16Fe75.7B8Zr0.3; Nd16Fe75.9B8Zr0.1; anisotropic powder; coercivity; epoxy bonded magnets; grain size; hydrogenation disproportionation desorption recombination; magnetic anisotropy; processing temperature; Anisotropic magnetoresistance; Bonding; Coercive force; Iron; Magnets; Neodymium; Powders; Production; Temperature distribution; Zirconium;
Journal_Title :
Magnetics, IEEE Transactions on
