Study of thermal deformation for selective laser melting in additive manufacturing
Selective Laser Melting (SLM) is a popular method of carrying out metal additive manufacturing. It involves building layers upon layers of melted feedstock using a high intensity laser to fuse a powder bed consisting of metal powder. Through this process, complex parts can be built with varying geom...
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Nanyang Technological University
2023
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sg-ntu-dr.10356-1669632023-05-20T16:51:28Z Study of thermal deformation for selective laser melting in additive manufacturing Ho, Brandon Jia Jun Du Hejun School of Mechanical and Aerospace Engineering Tran Van Thai MHDU@ntu.edu.sg Engineering::Mechanical engineering::Prototyping Selective Laser Melting (SLM) is a popular method of carrying out metal additive manufacturing. It involves building layers upon layers of melted feedstock using a high intensity laser to fuse a powder bed consisting of metal powder. Through this process, complex parts can be built with varying geometric designs. However, SLM is not without its limitations. Printing process parameters greatly affect the resulting physical properties and geometries of the part. Commonly, in-situ thermal gradients will result in the accumulation of residual stresses during the SLM process. The combined effect of residual stress and thermal contraction during the solidification of melted feedstock results in a final part deformation. This project aims to investigate the effects of varying two process parameters – scanning strategy and support structure design – on the final part deformation. An L16 Taguchi array was used to vary top tooth support length and scanning pattern. For each factor, 4 levels were tested in a total of 16 runs. The final part surface was scanned using a non-contact profiler, the Keyence Laser Microscope. Thereafter, the maximum deformation was calculated. Finally, a smaller is better signal-to-noise ratio was used to identify the most impactful print settings and the results were explained using a thermal model of the printing process via COMSOL Multiphysics. From the SLM print, the top tooth length of 1mm and a 45 scanning strategy yielded a part with the least deformation. Aside from deformation, it was also observed that surface texture varied from print to print, as a side effect of changing print parameters. As such, a preliminary analysis was also done to investigate this phenomenon. Bachelor of Engineering (Mechanical Engineering) 2023-05-17T03:00:19Z 2023-05-17T03:00:19Z 2023 Final Year Project (FYP) Ho, B. J. J. (2023). Study of thermal deformation for selective laser melting in additive manufacturing. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/166963 https://hdl.handle.net/10356/166963 en application/pdf Nanyang Technological University |
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Engineering::Mechanical engineering::Prototyping Ho, Brandon Jia Jun Study of thermal deformation for selective laser melting in additive manufacturing |
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Selective Laser Melting (SLM) is a popular method of carrying out metal additive manufacturing. It involves building layers upon layers of melted feedstock using a high intensity laser to fuse a powder bed consisting of metal powder. Through this process, complex parts can be built with varying geometric designs. However, SLM is not without its limitations. Printing process parameters greatly affect the resulting physical properties and geometries of the part. Commonly, in-situ thermal gradients will result in the accumulation of residual stresses during the SLM process. The combined effect of residual stress and thermal contraction during the solidification of melted feedstock results in a final part deformation. This project aims to investigate the effects of varying two process parameters – scanning strategy and support structure design – on the final part deformation. An L16 Taguchi array was used to vary top tooth support length and scanning pattern. For each factor, 4 levels were tested in a total of 16 runs. The final part surface was scanned using a non-contact profiler, the Keyence Laser Microscope. Thereafter, the maximum deformation was calculated. Finally, a smaller is better signal-to-noise ratio was used to identify the most impactful print settings and the results were explained using a thermal model of the printing process via COMSOL Multiphysics. From the SLM print, the top tooth length of 1mm and a 45 scanning strategy yielded a part with the least deformation. Aside from deformation, it was also observed that surface texture varied from print to print, as a side effect of changing print parameters. As such, a preliminary analysis was also done to investigate this phenomenon. |
| author2 |
Du Hejun |
| author_facet |
Du Hejun Ho, Brandon Jia Jun |
| format |
Final Year Project |
| author |
Ho, Brandon Jia Jun |
| author_sort |
Ho, Brandon Jia Jun |
| title |
Study of thermal deformation for selective laser melting in additive manufacturing |
| title_short |
Study of thermal deformation for selective laser melting in additive manufacturing |
| title_full |
Study of thermal deformation for selective laser melting in additive manufacturing |
| title_fullStr |
Study of thermal deformation for selective laser melting in additive manufacturing |
| title_full_unstemmed |
Study of thermal deformation for selective laser melting in additive manufacturing |
| title_sort |
study of thermal deformation for selective laser melting in additive manufacturing |
| publisher |
Nanyang Technological University |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/166963 |
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1772826573379993600 |