Initial Irreversible Losses and Enhanced High‐Temperature Performance of Rare‐Earth Permanent Magnets

There is an increasing demand for permanent magnets with high‐temperature stability. Normally, the magnets are heat treated above the operating temperature range to saturate the irreversible losses, thereby producing magnets that are stable, but with significantly degraded performance. In addition,...

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Bibliographic Details
Published in:Advanced functional materials 2019-06, Vol.29 (24), p.n/a
Main Authors: Xia, Wei, He, Yangkun, Huang, Houbing, Wang, Hui, Shi, Xiaoming, Zhang, Tianli, Liu, Jinghua, Stamenov, Plamen, Chen, Longqing, Coey, John Michael David, Jiang, Chengbao
Format: Article
Language:English
Subjects:
Circuit design
Demagnetization
demagnetizing field
energy product
Heat treatment
Hysteresis loops
irreversible loss
Magnetic circuits
magnetic domains
Magnetism
Magnetization curves
Materials science
Operating temperature
Performance degradation
permanent magnet
Permanent magnets
Remanence
Skin
Thrusters
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Summary:There is an increasing demand for permanent magnets with high‐temperature stability. Normally, the magnets are heat treated above the operating temperature range to saturate the irreversible losses, thereby producing magnets that are stable, but with significantly degraded performance. In addition, uncertainty about the losses in differently shaped magnets causes difficulties for efficient magnetic circuit design. The variation of the initial irreversible losses with magnet shape, hysteresis loop, and operating temperature is presented here. Losses are not associated with thermal demagnetization of the whole magnet, but the damage is concentrated in an outer surface “skin” at the pole surfaces, where the demagnetizing field is nonuniform. The initial irreversible remanence loss at room temperature ΔMr′/Mr can be predicted as the product of the slope of the high‐temperature magnetization curve k(T) and the effective demagnetizing factor N. Heat treatment with the vulnerable surfaces in contact with soft iron slabs moves the skin out of the permanent magnet and reduces the irreversible remanence loss by 30% or more, potentially improving the performance of permanent‐magnet motors, generators, bearings, and thrusters. The results deepen the understanding of the magnetism of irreversible losses and will guide the applications of permanent magnets at higher temperatures. A magnetized Sm‐Co magnet heated at 500 °C creates an inhomogeneous demagnetizing field that forms a demagnetized skin at the surface (top). The effect can be eliminated if the magnet is placed in contact with an iron sheet (bottom), and the irreversible losses can be drastically decreased.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201900690