Abstract
The new generation of high-frequency and high-efficiency motors has high demands on the soft magnetic properties, mechanical properties and corrosion resistance of its core materials. Bulk amorphous and nanocrystalline alloys not only meet its performance requirements but also conform to the current technical concept of integrated forming. At present, spark plasma sintering (SPS) is expected to break through the cooling-capacity limitation of traditional casting technology with high possibility to fabricate bulk metallic glasses (BMGs). In this study, Fe84Si7B5C2Cr2 soft magnetic amorphous powders with high sphericity were prepared by a new atomization technology, and its characteristic temperature was measured by DSC to determine the SPS temperature. The SEM, XRD, VSM and universal testing machine were used to analyze the compacts at different sintering temperatures. The results show that the powders cannot be consolidated by cold pressing (50 and 500 MPa) or SPS temperature below 753 K (glass transition temperature Tg = 767 K), and the tap density is only 4.46 g·cm−3. When SPS temperature reached above 773 K, however, the compact could be prepared smoothly, and the density, saturation magnetization, coercivity and compressive strength of the compacts increased with the elevated sintering temperature. In addition, due to superheating, crystallization occurred even when the sintering temperature was lower than 829 K (with the first crystallization onset temperature being Tx1 = 829 K). The compact was almost completely crystallized at 813 K, resulting in a sharp increase in the coercivity of the compact from 55.55 A·m−1 at 793 K to 443.17 A·m−1. It is noted that the nanocrystals kept growing in size as the temperature increased to 833 K, which increased the coercivity remarkably but showed an enhanced saturation magnetization.
Highlights
Based on the world-class strategic goal of “energy saving, emission reduction and environmental protection”, the new integrated inductor with miniaturization, low magnetic loss and excellent stability is emerging in the electronics and electrical fields and is expected to promote the development of a new generation of high-frequency and highefficiency motors [1,2]
Fe-based soft magnetic amorphous/nanocrystalline alloys with high saturation magnetization, low coercivity, low magnetic loss and low cost are expected to solve the problem of poor performance stability of traditional soft magnetic materials under high-frequency conditions and provide reserve for ideal materials for integrated inductance forming [3]
Fe-based amorphous alloys with poor glass-forming ability (GFA) are usually produced by atomization with sufficient cooling rate in industry, and bulk metallic glasses (BMGs) with a certain size can be fabricated by consolidation technology [8]
Summary
Based on the world-class strategic goal of “energy saving, emission reduction and environmental protection”, the new integrated inductor with miniaturization, low magnetic loss and excellent stability is emerging in the electronics and electrical fields and is expected to promote the development of a new generation of high-frequency and highefficiency motors [1,2]. Fe-based amorphous alloys with poor GFA are usually produced by atomization with sufficient cooling rate in industry, and BMGs with a certain size can be fabricated by consolidation technology [8]. The traditional powder-consolidation process usually requires high-temperature conditions to produce dense bulk amorphous alloys, which cannot achieve the combination of high fraction of amorphous phase and high density. The amorphous powders with high sphericity produced by the new atomization process were used as raw material, and Fe-Si-B-C-Cr BMGs with poor forming ability were prepared by SPS and cold pressing. The effects of different sintering temperatures on density, magnetic properties and mechanical properties of compacts are studied to provide practical guidance for the consolidation and performance improvement of the bulk Fe-Si-B-C-Cr system
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