Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth
In traditional electrical steel production oxide inclusions are conventionally perceived as deleterious elements for the functional and structural properties. The present work describes the fabrication of a high silicon content electrical steel alloy (Fe-6.5wt%Si) using directed energy deposition (D...
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sg-ntu-dr.10356-1844312025-05-03T16:49:22Z Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth Shen, Xiaojun Liogas, Konstantinos A. Soh, Verner Qun Liang Lek, Yung Zhen Meng, Fanbo Shen, Yiming Huber, John E. Reed, Roger C. Wang, Pei Korsunsky, Alexander M. Lee, Christopher Ho Tin School of Mechanical and Aerospace Engineering School of Electrical and Electronic Engineering Engineering Directed energy deposition Abnormal Goss grain In traditional electrical steel production oxide inclusions are conventionally perceived as deleterious elements for the functional and structural properties. The present work describes the fabrication of a high silicon content electrical steel alloy (Fe-6.5wt%Si) using directed energy deposition (DED), coupled with oxide inclusions to mitigate core energy losses. Abnormal Grain Growth (ABG) was observed after thermal post-processing at 1000 °C for 24 h (1000–24), together with the creation of oxide inclusions mainly around the grain boundaries. Magnetic properties were assessed through dynamic and quasi-static measurements for both as-printed (AP) and 1000–24 samples. The quasi-static analysis revealed hysteresis losses of 206.9 J/m3 for the AP and 19.02 J/m3 for the 1000–24, with maximum flux densities of 1.295 T and 1.031 T, at the magnetic field of 3000 A/m. Dynamic magnetic analysis demonstrated an improvement of 39.2% in the total core losses of the 1000–24 sample (2088.8 J/m3), compared to the AP sample (3436.9 J/m3). The microstructure of the 1000–24 sample revealed the formation of Goss texture via ABG, ultimately decreasing the static hysteresis loss. Furthermore, an improved electrical resistivity compare to conventional electrical steel alloys was demonstrated at 119 μΩcm for the 1000-24 sample, and 105 μΩcm for the AP sample. This work introduces a promising avenue to minimize core energy losses by incorporating oxide inclusions and ABG Goss texture in additively manufactured soft magneitc components after thermal post-processing. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) Published version The work was supported by the Panasonic Industrial Devices Singapore Pte. Ltd, Singapore, under its Joint Lab Programme 04IDS001408C140, National Research Foundation (NRF) Singapore under its NRF Fellowship Grant NRF-NRFF12- 2020-0003. The work is also supported by the Agency for Science, Technology and Research (A*STAR) of Singapore via the Individual Research Grant (Grant reference No. A20E7c0109). 2025-04-29T06:00:32Z 2025-04-29T06:00:32Z 2025 Journal Article Shen, X., Liogas, K. A., Soh, V. Q. L., Lek, Y. Z., Meng, F., Shen, Y., Huber, J. E., Reed, R. C., Wang, P., Korsunsky, A. M. & Lee, C. H. T. (2025). Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth. Materials and Design, 252, 113730-. https://dx.doi.org/10.1016/j.matdes.2025.113730 0264-1275 https://hdl.handle.net/10356/184431 10.1016/j.matdes.2025.113730 2-s2.0-85219083030 252 113730 en 04IDS001408C140 NRF-NRFF12-2020-0003 A20E7c0109 Materials and Design © 2025 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/bync-nd/4.0/). application/pdf |
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Engineering Directed energy deposition Abnormal Goss grain |
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Engineering Directed energy deposition Abnormal Goss grain Shen, Xiaojun Liogas, Konstantinos A. Soh, Verner Qun Liang Lek, Yung Zhen Meng, Fanbo Shen, Yiming Huber, John E. Reed, Roger C. Wang, Pei Korsunsky, Alexander M. Lee, Christopher Ho Tin Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| description |
In traditional electrical steel production oxide inclusions are conventionally perceived as deleterious elements for the functional and structural properties. The present work describes the fabrication of a high silicon content electrical steel alloy (Fe-6.5wt%Si) using directed energy deposition (DED), coupled with oxide inclusions to mitigate core energy losses. Abnormal Grain Growth (ABG) was observed after thermal post-processing at 1000 °C for 24 h (1000–24), together with the creation of oxide inclusions mainly around the grain boundaries. Magnetic properties were assessed through dynamic and quasi-static measurements for both as-printed (AP) and 1000–24 samples. The quasi-static analysis revealed hysteresis losses of 206.9 J/m3 for the AP and 19.02 J/m3 for the 1000–24, with maximum flux densities of 1.295 T and 1.031 T, at the magnetic field of 3000 A/m. Dynamic magnetic analysis demonstrated an improvement of 39.2% in the total core losses of the 1000–24 sample (2088.8 J/m3), compared to the AP sample (3436.9 J/m3). The microstructure of the 1000–24 sample revealed the formation of Goss texture via ABG, ultimately decreasing the static hysteresis loss. Furthermore, an improved electrical resistivity compare to conventional electrical steel alloys was demonstrated at 119 μΩcm for the 1000-24 sample, and 105 μΩcm for the AP sample. This work introduces a promising avenue to minimize core energy losses by incorporating oxide inclusions and ABG Goss texture in additively manufactured soft magneitc components after thermal post-processing. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Shen, Xiaojun Liogas, Konstantinos A. Soh, Verner Qun Liang Lek, Yung Zhen Meng, Fanbo Shen, Yiming Huber, John E. Reed, Roger C. Wang, Pei Korsunsky, Alexander M. Lee, Christopher Ho Tin |
| format |
Article |
| author |
Shen, Xiaojun Liogas, Konstantinos A. Soh, Verner Qun Liang Lek, Yung Zhen Meng, Fanbo Shen, Yiming Huber, John E. Reed, Roger C. Wang, Pei Korsunsky, Alexander M. Lee, Christopher Ho Tin |
| author_sort |
Shen, Xiaojun |
| title |
Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| title_short |
Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| title_full |
Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| title_fullStr |
Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| title_full_unstemmed |
Mitigating core energy losses in Fe-Si alloys fabricated by direct energy deposition through oxide inclusions and abnormal Goss grain growth |
| title_sort |
mitigating core energy losses in fe-si alloys fabricated by direct energy deposition through oxide inclusions and abnormal goss grain growth |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/184431 |
| _version_ |
1833072176279846912 |