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Grain refinement in laser powder bed fusion: the influence of dynamic recrystallization and recovery

Grain refinement in laser powder bed fusion: the influence of dynamic recrystallization and recovery
Grain refinement in laser powder bed fusion: the influence of dynamic recrystallization and recovery

During laser powder bed fusion (LPBF) the powder bed undergoes several thermal cycles incorporating complex thermo-mechanical processing. Different restoration mechanisms such as dynamic recovery, dynamic recrystallization and grain growth can be activated at different thermal cycles, leading to a very fine average grain size. This is modelled via classical and thermostatistical approaches for an austenitic stainless steel. Four subsequent thermal cycles in each layer induce various microstructural transitions for each individual grain. The high cooling rate solidification in the first two thermal cycles leads to the formation of a highly deformed cellular microstructure. Discontinuous and continuous dynamic recrystallization are activated in the third thermal cycle to induce grain refinement. The fourth thermal cycle undergoes dynamic recovery and grain growth. The as-built alloys exhibit an excellent combination of high yield and ultimate tensile strength. The high strength is attributed to the activation of the various dynamic recrystallization mechanisms, as well as to the development of the cellular structures resulting from a high cooling rate upon solidification. A methodology to design alloys with tailored microstructures is presented.

316L stainless steel, Additive manufacturing, Laser powder bed fusion, Microstructure, Recrystallization
0264-1275
Sabzi, Hossein Eskandari
767d5a23-489d-455f-80d0-bad990b42783
Aboulkhair, Nesma T.
ab71d67b-b3eb-47bb-b5c5-9fa0174dceef
Liang, Xingzhong
a3a45c11-e85d-43e7-82a7-15192ec48bd2
Li, Xiao Hui
61cbda8d-ab83-4fff-80a6-3e1e92d1d93a
Simonelli, Marco
61debb45-6dad-429f-b5a1-c5619295624f
Fu, Hanwei
5bfa8370-2f21-436c-8c78-ce414d925d94
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Sabzi, Hossein Eskandari
767d5a23-489d-455f-80d0-bad990b42783
Aboulkhair, Nesma T.
ab71d67b-b3eb-47bb-b5c5-9fa0174dceef
Liang, Xingzhong
a3a45c11-e85d-43e7-82a7-15192ec48bd2
Li, Xiao Hui
61cbda8d-ab83-4fff-80a6-3e1e92d1d93a
Simonelli, Marco
61debb45-6dad-429f-b5a1-c5619295624f
Fu, Hanwei
5bfa8370-2f21-436c-8c78-ce414d925d94
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2

Sabzi, Hossein Eskandari, Aboulkhair, Nesma T., Liang, Xingzhong, Li, Xiao Hui, Simonelli, Marco, Fu, Hanwei and Rivera-Díaz-del-Castillo, Pedro E.J. (2020) Grain refinement in laser powder bed fusion: the influence of dynamic recrystallization and recovery. Materials and Design, 196, [109181]. (doi:10.1016/j.matdes.2020.109181).

Record type: Article

Abstract

During laser powder bed fusion (LPBF) the powder bed undergoes several thermal cycles incorporating complex thermo-mechanical processing. Different restoration mechanisms such as dynamic recovery, dynamic recrystallization and grain growth can be activated at different thermal cycles, leading to a very fine average grain size. This is modelled via classical and thermostatistical approaches for an austenitic stainless steel. Four subsequent thermal cycles in each layer induce various microstructural transitions for each individual grain. The high cooling rate solidification in the first two thermal cycles leads to the formation of a highly deformed cellular microstructure. Discontinuous and continuous dynamic recrystallization are activated in the third thermal cycle to induce grain refinement. The fourth thermal cycle undergoes dynamic recovery and grain growth. The as-built alloys exhibit an excellent combination of high yield and ultimate tensile strength. The high strength is attributed to the activation of the various dynamic recrystallization mechanisms, as well as to the development of the cellular structures resulting from a high cooling rate upon solidification. A methodology to design alloys with tailored microstructures is presented.

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More information

Accepted/In Press date: 21 September 2020
e-pub ahead of print date: 23 September 2020
Published date: 30 September 2020
Keywords: 316L stainless steel, Additive manufacturing, Laser powder bed fusion, Microstructure, Recrystallization

Identifiers

Local EPrints ID: 492255
URI: http://eprints.soton.ac.uk/id/eprint/492255
DOI: doi:10.1016/j.matdes.2020.109181
ISSN: 0264-1275
PURE UUID: 08e68eba-19b2-4d19-a515-e9e49982ea03
ORCID for Pedro E.J. Rivera-Díaz-del-Castillo: ORCID iD orcid.org/0000-0002-0419-8347

Catalogue record

Date deposited: 23 Jul 2024 16:34
Last modified: 24 Jul 2024 02:07

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Contributors

Author: Hossein Eskandari Sabzi
Author: Nesma T. Aboulkhair
Author: Xingzhong Liang
Author: Xiao Hui Li
Author: Marco Simonelli
Author: Hanwei Fu
Author: Pedro E.J. Rivera-Díaz-del-Castillo ORCID iD

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