Analysis of Cylindrically and Spherically Embossed Flux Barriers in Non-oriented Electrical Steel

Forming the Future Pub Date : 2020-07-30 DOI:10.31224/osf.io/jr3tx

Ines Gilch, S. Vogt, T. Neuwirth, B. Schauerte, K. Hameyer, M. Schulz, A. Gustschin, W. Volk, H. A. Weiss

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引用次数: 2

Abstract

In reluctance and permanent magnet synchronous machines, flux barriers are crucial for magnetic flux guidance. Designed as cutouts, flux barriers reduce the mechanical strength of the rotor construction. To operate these electric drives at higher rotational speed, an alternative flux barrier design is required. Since residual stress influences the magnetic properties of soft magnetic materials, this paper deals with embossing induced residual stress as flux barriers in non-oriented electrical steel with 2.4 wt% silicon and a sheet thickness of 0.35 mm. The investigated flux barriers were fabricated with a cylindrical or spherical punch at two different penetration depths and were compared to a flux barrier fabricated as cutout. A residual stress analysis using Finite Element Analysis helps understanding the mechanism of embossed flux barriers. Additionally, the influence of induced residual stress on the magnetic material behavior is measured using standardized single sheet tests and neutron grating interferometry measurements. This investigation aimed at a better understanding of the flux barrier design by local induction of residual stress.

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无取向电工钢圆柱和球形压纹磁阻分析

在磁阻和永磁同步电机中，磁通屏障是磁通引导的关键。作为断路器，磁通屏障降低了转子结构的机械强度。为了在更高的转速下操作这些电驱动器，需要一种替代的磁通屏障设计。由于残余应力影响软磁材料的磁性能，本文研究了在含硅量为2.4 wt%、板材厚度为0.35 mm的无取向电工钢中压花诱导残余应力作为磁阻的问题。所研究的磁通屏障是用圆柱或球形冲孔在两种不同的穿透深度下制造的，并与作为切口制造的磁通屏障进行了比较。利用有限元方法进行残余应力分析有助于理解压纹磁阻的机理。此外，采用标准化单片测试和中子光栅干涉测量法测量了诱导残余应力对磁性材料性能的影响。本研究旨在通过局部感应残余应力来更好地理解磁通屏障设计。

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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Forming the Future

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