Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment
For processing the difficult-to-cut materials, TiAlSiN coatings have been widely applied to machining tools. Pulse magnetic field treatment, as a novel, fast, and environmentally friendly post-treatment method, can directly modify the finished TiAlSiN-coated tools without causing physical damage. Th...
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| Format: | Article |
| Language: | English |
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EDP Sciences
2025-01-01
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| Series: | Manufacturing Review |
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| Online Access: | https://mfr.edp-open.org/articles/mfreview/full_html/2025/01/mfreview240058/mfreview240058.html |
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| _version_ | 1849731978505486336 |
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| author | Zhang Lin Yan Qiaosong He Asha Chen Zhe Wu Mingxia Yang Yi Liu Jian |
| author_facet | Zhang Lin Yan Qiaosong He Asha Chen Zhe Wu Mingxia Yang Yi Liu Jian |
| author_sort | Zhang Lin |
| collection | DOAJ |
| description | For processing the difficult-to-cut materials, TiAlSiN coatings have been widely applied to machining tools. Pulse magnetic field treatment, as a novel, fast, and environmentally friendly post-treatment method, can directly modify the finished TiAlSiN-coated tools without causing physical damage. This study investigates the wear resistance of pulse magnetic field-treated TiAlSiN-coated carbide samples under both dry and lubricated friction conditions. Results show that pulse magnetic field-treated TiAlSiN-coated samples exhibit improved wear resistance and friction reduction in both friction environments. In dry friction conditions, the coating's coefficient of friction decreased by 13.73%, resulting in a more stable friction process. In lubricated conditions, the coefficient of friction decreased by 23.46%. Due to the effects of the pulse magnetic field, the hardness of the coating and substrate increased by 6.58% and 3.7%, respectively. The bonding phase Co in the carbide substrate exhibited phase transformation and increased defect density, such as dislocations. These changes enhanced the bonding strength at the coating/substrate interface, thereby improving its mechanical performance and tribological behavior. |
| format | Article |
| id | doaj-art-3e3e313bf1d14db286047edc74fe71e7 |
| institution | DOAJ |
| issn | 2265-4224 |
| language | English |
| publishDate | 2025-01-01 |
| publisher | EDP Sciences |
| record_format | Article |
| series | Manufacturing Review |
| spelling | doaj-art-3e3e313bf1d14db286047edc74fe71e72025-08-20T03:08:21ZengEDP SciencesManufacturing Review2265-42242025-01-0112510.1051/mfreview/2024026mfreview240058Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatmentZhang Lin0Yan Qiaosong1He Asha2Chen Zhe3Wu Mingxia4Yang Yi5Liu Jian6School of Mechanical Engineering, Sichuan UniversitySchool of Mechanical Engineering, Sichuan UniversityDepartment of Industrial Engineering, Sichuan University-Pittsburgh Institute ChengduSchool of Mechanical Engineering, Sichuan UniversitySchool of Mechanical Engineering, Sichuan UniversitySchool of Mechanical Engineering, Sichuan UniversitySchool of Mechanical Engineering, Sichuan UniversityFor processing the difficult-to-cut materials, TiAlSiN coatings have been widely applied to machining tools. Pulse magnetic field treatment, as a novel, fast, and environmentally friendly post-treatment method, can directly modify the finished TiAlSiN-coated tools without causing physical damage. This study investigates the wear resistance of pulse magnetic field-treated TiAlSiN-coated carbide samples under both dry and lubricated friction conditions. Results show that pulse magnetic field-treated TiAlSiN-coated samples exhibit improved wear resistance and friction reduction in both friction environments. In dry friction conditions, the coating's coefficient of friction decreased by 13.73%, resulting in a more stable friction process. In lubricated conditions, the coefficient of friction decreased by 23.46%. Due to the effects of the pulse magnetic field, the hardness of the coating and substrate increased by 6.58% and 3.7%, respectively. The bonding phase Co in the carbide substrate exhibited phase transformation and increased defect density, such as dislocations. These changes enhanced the bonding strength at the coating/substrate interface, thereby improving its mechanical performance and tribological behavior.https://mfr.edp-open.org/articles/mfreview/full_html/2025/01/mfreview240058/mfreview240058.htmltialsin coatingspulse magnetic fieldtreatmentfriction performance |
| spellingShingle | Zhang Lin Yan Qiaosong He Asha Chen Zhe Wu Mingxia Yang Yi Liu Jian Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment Manufacturing Review tialsin coatings pulse magnetic field treatment friction performance |
| title | Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment |
| title_full | Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment |
| title_fullStr | Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment |
| title_full_unstemmed | Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment |
| title_short | Improving the friction performance of TiAlSiN-coated hard alloy through pulsed magnetic field treatment |
| title_sort | improving the friction performance of tialsin coated hard alloy through pulsed magnetic field treatment |
| topic | tialsin coatings pulse magnetic field treatment friction performance |
| url | https://mfr.edp-open.org/articles/mfreview/full_html/2025/01/mfreview240058/mfreview240058.html |
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