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Jahangiri, M., Bayani, H., Ardestani, M. (2022). Effect of laser line interruption on the structure and magnetic properties of GO-silicon-steel-sheets in the laser scribing process. , 33(2), 147-160. doi: 10.22067/jmme.2022.74057.1036
Mohammadreza Jahangiri; Hessam Bayani; Mohammad Ardestani. "Effect of laser line interruption on the structure and magnetic properties of GO-silicon-steel-sheets in the laser scribing process". , 33, 2, 2022, 147-160. doi: 10.22067/jmme.2022.74057.1036
Jahangiri, M., Bayani, H., Ardestani, M. (2022). 'Effect of laser line interruption on the structure and magnetic properties of GO-silicon-steel-sheets in the laser scribing process', , 33(2), pp. 147-160. doi: 10.22067/jmme.2022.74057.1036
Jahangiri, M., Bayani, H., Ardestani, M. Effect of laser line interruption on the structure and magnetic properties of GO-silicon-steel-sheets in the laser scribing process. , 2022; 33(2): 147-160. doi: 10.22067/jmme.2022.74057.1036

Effect of laser line interruption on the structure and magnetic properties of GO-silicon-steel-sheets in the laser scribing process

مهندسی متالورژی و مواد
Article 10, Volume 33, Issue 2 - Serial Number 26, September 2022, Pages 147-160    PDF (612.69 K)
Document Type: Original Articles
DOI: 10.22067/jmme.2022.74057.1036
Authors
Mohammadreza Jahangiri* 1; Hessam Bayani2; Mohammad Ardestani3
1Metallurgy Research Group, Niroo Research Institute, Tehran, Iran
2Department of Materials Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran.
3Department of Materials Engineering, Science and Research Branch, Islamic
Abstract
In this work, the effect of laser line interruption was studied on the structure and magnetic properties of grain-oriented silicon steel sheets during the laser-scribing process in the presence/absence of an external magnetic field. By applying different patterns of interruption, the effect of discontinuity length, one-sided or two-sided application of laser and overlapping or non-overlapping of laser lines (for sheets scribed on both sides) was investigated on the domain structure and core losses of silicon steel sheets. Based on the results of these experiments, the optimal conditions of discontinuous laser scribing were obtained. The results show that although at small interruption lengths such as 2 mm, the effect of laser scribing is negligible on reducing the core losses, but by increasing the interruption length to about 6 mm, the magnetic losses are greatly improved. By re-increasing the length of interruption to about 10 mm, the core losses increase again and this indicates that a break length of 6 mm creates optimal core losses in the sheets. Use of a longitudinal external magnetic field during the discontinuous laser irradiation with an optimum interruption pattern results in a reduction of about 16% in core losses in grain-oriented silicon steel sheets.
Keywords
Grain-oriented silicon steel; Laser scribing; Laser discontinuity; Domain structure; Core loss
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