Preparation of Sm−Fe−N Bulk Magnets with High Maximum Energy Products

Q3 Engineering

Journal of the Magnetics Society of Japan Pub Date : 2020-05-01 DOI:10.3379/msjmag.2005r003

R. Matsunami, M. Matsuura, N. Tezuka, S. Sugimoto

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引用次数: 6

Abstract

In an effort to increase the maximum energy product ((BH)max) and coercivity (HcJ) of Zn-bonded Sm−Fe−N magnets, we developed a process for preparing Sm−Fe−N and Zn powders with low oxygen contents and subjected them to spark plasma sintering. The oxygen content, remanence, and coercivity of the Sm−Fe−N powder were 0.22 wt%, 151 A·m2·kg−1, and 0.72 MA·m−1, respectively. The oxygen content and secondary average particle size of the Zn powder were 0.083 wt% and 0.93 μm, respectively. The magnetic properties of the Zn-free Sm−Fe−N magnets included an HcJ of 0.86 MA·m−1 and a (BH)max of 188 kJ·m−3, while the Zn-bonded (10 wt%) Sm−Fe−N magnets exhibited excellent magnetic properties with a (BH)max of 200 kJ·m−3 and an HcJ of 1.28 MA·m−1. Compared with previous studies, this is the high (BH)max observed for a Sm−Fe−N bulk magnet simultaneously displaying a high HcJ. The (BH)max of the Zn-bonded magnets was greater than that of the Zn-free magnets owing to the higher relative density of the former. Therefore, Zn is an effective binder for increasing not only the coercivity but also the density of Sm−Fe−N magnets. Consequently, the procedure reported herein permits the successful preparation of high-performance Sm−Fe−N bulk magnets.

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高最大能积Sm - Fe - N块状磁体的制备

为了提高Zn键合Sm - Fe - N磁体的最大能量积(BH)max)和矫顽力(HcJ)，我们开发了一种制备低氧含量Sm - Fe - N和Zn粉末的工艺，并对其进行火花等离子烧结。Sm - Fe - N粉末的氧含量、剩余物和矫顽力分别为0.22 wt%、151 A·m2·kg - 1和0.72 MA·m - 1。锌粉的氧含量为0.083 wt%，二次平均粒度为0.93 μm。无锌Sm - Fe - N磁体的HcJ值为0.86 MA·m−1,HcJ值为188 kJ·m−3，而含锌(10 wt%) Sm - Fe - N磁体的HcJ值为1.28 MA·m−1,HcJ值为200 kJ·m−3。与以前的研究相比，这是Sm - Fe - N体磁铁同时显示高HcJ的高(BH)max。由于锌结合磁体的相对密度较高，其(BH)max大于无锌磁体。因此，Zn是一种有效的粘结剂，不仅可以提高Sm - Fe - N磁体的矫顽力，还可以提高磁体的密度。因此，本文报道的方法允许成功制备高性能Sm−Fe−N块体磁体。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the Magnetics Society of Japan Engineering-Electrical and Electronic Engineering

CiteScore

2.00

自引率

0.00%

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