Application of CO2 laser cutting in producing biocompatible stainless steel 316L medical implants
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Full Text |
Pdf
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Author |
Armansyah Ginting and Gunawan
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e-ISSN |
1819-6608 |
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On Pages
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2019-2027
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Volume No. |
20
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Issue No. |
23
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Issue Date |
February 10, 2026
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DOI |
https://doi.org/10.59018/1225224
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Keywords |
mesh medical implant, geometry, dimension, heat-affected zone (HAZ), thermal burr, surface roughness.
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Abstract
The application of CO2 laser cutting technology in the fabrication of medical implants holds significant promise for enhancing precision, efficiency, and quality in biomedical manufacturing processes. This paper describes a study that investigates the use of CO2 laser cutting to create mesh medical implants utilizing biocompatible material, specifically stainless steel 316L. Through a brief review of laser cutting principles and previous studies, the paper provides insights into the process parameters to achieve optimal outcomes. The study investigates the influence of laser power, cutting speed, and gas pressure on the quality and characteristics of the manufactured implants. The primary focus is on the attributes of the shape, dimensions, heat-affected zone (HAZ), thermal burr, and surface roughness. Experimental results reveal the capability of CO2 laser cutting to accurately reproduce intricate mesh medical implant designs with minimal material waste and high precision. Moreover, the study highlights the importance of CNC control systems in ensuring consistent and reproducible manufacturing processes. Overall, the findings underscore the potential of CO2 laser cutting technology to revolutionize the production of mesh medical implants, offering improved quality, functionality, and patient outcomes in biomedical applications.
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