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基于机械合金化粉末的伪核壳坡莫合金(超坡莫合金)@ZnFeO粉末及放电等离子烧结体

Pseudo-Core-Shell Permalloy (Supermalloy)@ZnFeO Powders and Spark Plasma Sintered Compacts Based on Mechanically Alloyed Powders.

作者信息

Marinca Traian Florin, Cotojman Loredana, Popa Florin, Neamțu Bogdan Viorel, Prică Călin-Virgiliu, Chicinaș Ionel

机构信息

Materials Science and Engineering Department, Technical University of Cluj-Napoca, 400641 Cluj-Napoca, Romania.

出版信息

Materials (Basel). 2024 Aug 21;17(16):4139. doi: 10.3390/ma17164139.

DOI:10.3390/ma17164139
PMID:39203317
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11356188/
Abstract

Soft magnetic composite cores were produced by spark plasma sintering (SPS) from NiFe@ZnFeO and NiFeMo@ZnFeO pseudo-core-shell powders. In the Fe-Ni alloys@ZnFeO pseudo-core-shell composite powders, the core is a large nanocrystalline Permalloy or Supermalloy particle obtained by mechanical alloying, and the shell is a pseudo continuous layer of Zn ferrite particles. The pseudo-core-shell powders have been compacted by SPS at temperatures between 500-700 °C, with a holding time of 0 min. Several techniques were used for the characterisation of the powders and sintered compacts: X-ray diffraction, scanning electron microscopy, energy dispersive X-ray spectroscopy, magnetic hysteresis measurements (DC and AC), and electrical resistivity. The electrical resistivity is stabilised at values of about 7 × 10 Ω·m for sintering temperatures between 600-700 °C and this value is three orders of magnitude higher than the electrical resistivity of sintered Fe compacts. The best relative initial permeability was obtained for the Supermalloy/ZnFeO composite compacts sintered at 600 °C, which decreases linearly for the entire frequency range studied, from around 95 to 50. At a frequency of 2000 Hz, the power losses are smaller than 1.5 W/kg. At a frequency of 10 kHz, the power losses are larger, but they remain at a reduced level. In the case of Supermalloy/ZnFeO composite compact SPS-ed at 700 °C, the specific power losses are even lower than 5 W/kg. The power losses' decomposition proved that intra-particle losses are the main type of losses.

摘要

软磁复合磁芯是由NiFe@ZnFeO和NiFeMo@ZnFeO准核壳粉末通过放电等离子体烧结(SPS)制备而成。在Fe-Ni合金@ZnFeO准核壳复合粉末中,核是通过机械合金化获得的大纳米晶坡莫合金或超坡莫合金颗粒,壳是一层准连续的铁酸锌颗粒层。准核壳粉末在500-700°C的温度下通过SPS压实,保温时间为0分钟。使用了几种技术来表征粉末和烧结体:X射线衍射、扫描电子显微镜、能量色散X射线光谱、磁滞测量(直流和交流)以及电阻率。对于600-700°C的烧结温度,电阻率稳定在约7×10Ω·m的值,该值比烧结铁体的电阻率高三个数量级。在600°C烧结的超坡莫合金/ZnFeO复合烧结体获得了最佳的相对初始磁导率,在整个研究频率范围内从约95线性下降到50。在2000Hz的频率下,功率损耗小于1.5W/kg。在10kHz的频率下,功率损耗较大,但仍处于降低水平。在700°C下进行SPS烧结的超坡莫合金/ZnFeO复合烧结体的情况下,比功率损耗甚至低于5W/kg。功率损耗的分解证明颗粒内损耗是主要的损耗类型。

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本文引用的文献

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