Defect prevention in selective laser melting components: compositional and process effects
Defect prevention in selective laser melting components: compositional and process effects
A model to predict the conditions for printability is presented. The model focuses on crack prevention, as well as on avoiding the formation of defects such as keyholes, balls and lack of fusion. Crack prevention is ensured by controlling the solidification temperature range and path, as well as via quantifying its ability to resist thermal stresses upon solidification. Defect formation prevention is ensured by controlling the melt pool geometry and by taking into consideration the melting properties. The model's core relies on thermodynamics and physical analysis to ensure optimal printability, and in turn offers key information for alloy design and selective laser melting process control. The model is shown to describe accurately defect formation of 316L austenitic stainless steels reported in the literature.
Additive manufacturing, Austenitic stainless steel, Porosity, Solidification cracking
Sabzi, Hossein Eskandari
767d5a23-489d-455f-80d0-bad990b42783
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
18 November 2019
Sabzi, Hossein Eskandari
767d5a23-489d-455f-80d0-bad990b42783
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Sabzi, Hossein Eskandari and Rivera-Díaz-del-Castillo, Pedro E.J.
(2019)
Defect prevention in selective laser melting components: compositional and process effects.
Materials, 12 (22), [3791].
(doi:10.3390/ma12223791).
Abstract
A model to predict the conditions for printability is presented. The model focuses on crack prevention, as well as on avoiding the formation of defects such as keyholes, balls and lack of fusion. Crack prevention is ensured by controlling the solidification temperature range and path, as well as via quantifying its ability to resist thermal stresses upon solidification. Defect formation prevention is ensured by controlling the melt pool geometry and by taking into consideration the melting properties. The model's core relies on thermodynamics and physical analysis to ensure optimal printability, and in turn offers key information for alloy design and selective laser melting process control. The model is shown to describe accurately defect formation of 316L austenitic stainless steels reported in the literature.
Text
materials-12-03791-v2
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Accepted/In Press date: 13 November 2019
Published date: 18 November 2019
Keywords:
Additive manufacturing, Austenitic stainless steel, Porosity, Solidification cracking
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Local EPrints ID: 492257
URI: http://eprints.soton.ac.uk/id/eprint/492257
PURE UUID: 762c083b-94e6-42d2-940b-914b630c962d
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Date deposited: 23 Jul 2024 16:34
Last modified: 24 Jul 2024 02:07
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Contributors
Author:
Hossein Eskandari Sabzi
Author:
Pedro E.J. Rivera-Díaz-del-Castillo
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