Abstract
For transformers and inductors to meet the world’s growing demand for electrical power, more efficient soft magnetic materials with high saturation magnetic polarization and high electrical resistivity are needed. This work aimed at the development of a soft magnetic composite synthesized via spark plasma sintering with both high saturation magnetic polarization and high electrical resistivity for efficient soft magnetic cores. CoFe powder particles coated with an insulating layer of Al2O3 were used as feedstock material to improve the electrical resistivity while retaining high saturation magnetic polarization. By maintaining a continuous non-magnetic Al2O3 phase throughout the material, both a high saturation magnetic polarization, above 1.5 T, and high electrical resistivity, above 100 μΩ·m, were achieved. Through microstructural characterization of samples consolidated at various temperatures, the role of microstructural evolution on the magnetic and electronic properties of the composite was elucidated. Upon consolidation at relatively high temperature, the CoFe was to found plastically deform and flow into the Al2O3 phase at the particle boundaries and this phenomenon was attributed to low resistivity in the composite. In contrast, at lower consolidation temperatures, perforation of the Al2O3 phase was not observed and a high electrical resistivity was achieved, while maintaining a high magnetic polarization, ideal for more efficient soft magnetic materials for transformers and inductors.
Highlights
More efficient power conversion devices, transformers are needed for power grids to meet the global demands for increased energy consumption
A CoFe–Al2O3 composite was produced by consolidating Al2O3-coated CoFe powder particles via spark plasma sintering (SPS), targeting a SMC with high Js and high electrical resistivity
After SPS consolidation of the coated powders at 1000 °C, decreases to the magnetic properties, proportional to the volume fraction of the Al2O3 phase and minimal changes to the electronic properties were observed compared to the CoFe alloy
Summary
More efficient power conversion devices, transformers are needed for power grids to meet the global demands for increased energy consumption. Transformers and other power conversion devices such as motors and inductors rely on magnetic cores which must be made of soft magnetic materials [1–3]. Soft magnetic materials are not necessarily mechanically soft, but are magnetically soft, meaning the induced magnetic polarity in the material can be switched by an applied field and the material has relatively low magnetic coercivity (Hc \ 1000 A/ m) [3]. Some of the applied magnetic field is required to overcome the material’s coercivity before a polarity can be induced in the material, causing magnetic power losses. Eddy current losses are another major source of power losses. Eddy current losses can be approximated using Eq (1) from [4], d2 B2 f 2
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