Considering the new applications of high power electronics for (hybrid) electric vehicles, a lot of new requirements arise for soft magnetic materials. The combination of high permeability under DC excitation (DC Bias characteristics), low core loss, good thermal stability, and low cost allows the reduction of size, weight, and price of magnetic components used in. Among the today's most relevant soft magnetic materials to high power inductors, metal alloy powder cores are good candidates. In this paper, improved experimental results of Fe-Si-Al alloy powder cores by metallurgical process are shown and discussed: Dramatic decrease of hysteresis loss of Fe-Si-Al alloy powder cores (150 mW/cc @50KHz, 0.1T) was achieved by getting lower coercive force (Hc) through the high temperature grain growth process of raw material powders. Lowest core loss and increased DC Bias characteristics are simultaneously achieved by controlling the shape of individual particles and adjusting the metallurgical alloy composition of Fe-Si-Al powders. It was found that precise metallurgical process controlling could provide the high potential of possible innovations of the inductive components.
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机译:考虑到高功率电子设备在(混合动力)电动汽车中的新应用,对软磁材料提出了许多新要求。直流激励下的高导磁率(直流偏置特性),低铁损,良好的热稳定性和低成本的结合,可以减少所用磁性元件的尺寸,重量和价格。在当今最相关的软磁性材料中,大功率电感器,金属合金压粉磁芯是不错的选择。本文展示并讨论了通过冶金工艺改进的Fe-Si-Al合金压粉磁芯的实验结果:大大降低了Fe-Si-Al合金压粉磁芯(150 mW / cc @ 50KHz,0.1T)的磁滞损耗。通过在原料粉末的高温晶粒生长过程中获得较低的矫顽力(Hc)来实现。通过控制单个颗粒的形状并调整Fe-Si-Al粉末的冶金合金成分,可以同时实现最低的铁损和增加的DC偏置特性。已经发现,精确的冶金过程控制可以为电感部件的创新提供很高的潜力。
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