期刊
JOURNAL OF MATERIALS SCIENCE & TECHNOLOGY
卷 111, 期 -, 页码 268-278出版社
JOURNAL MATER SCI TECHNOL
DOI: 10.1016/j.jmst.2021.10.006
关键词
Additive manufacturing; 316L stainless steel; Fatigue behavior; Cellular structure; Nanotwins
资金
- Swedish Governmental Agency for Innovation Systems (Vinnova) [2016-05175]
- Science Foundation Ireland (SFI) [16/RC/3872]
- Center for Additive Manufacturing-metal (CAM2)
- Ji Hua Laboratory [X210141TL210]
This study investigates the influence of microstructure characteristics on low cycle fatigue properties and strengthening effects in additively manufactured stainless steel. It reveals that the presence of cell structures significantly increases the fatigue life by inhibiting dislocation propagation and promoting the formation of nanotwins. Additionally, compositional micro-segregation serves as another important strengthening mechanism. The findings highlight the potential of additive manufacturing in designing high-performance energy absorbent alloys through tailored microstructure.
We have investigated the low cycle fatigue (LCF) properties and the extent of strengthening in a dense additively manufactured stainless steel containing different volume fractions of cell structures but having all other microstructure characteristics the same. The samples were produced by laser powder bed fusion (L-PBF), and the concentration of cell structures was varied systematically by varying the annealing treatments. Load-controlled fatigue experiments performed on samples with a high fraction of cell structures reveal an up to 23 times increase in fatigue life compared to an essentially cell-free sample of the same grain configuration. Multiscale electron microscopy characterizations reveal that the cell structures serve as the soft barriers to the dislocation propagation and the partials are the main carrier for cyclic loading. The cell structures, stabilized by the segregated atoms and misorientation between the adjacent cells, are retained during the entire plastic deformation, hence, can continuously interact with dislocations, promote the formation of nanotwins, and provide massive 3D network obstacles to the dislocation motion. The compositional micro-segregation caused by the cellular solidification features serves as another non negligible strengthening mechanism to dislocation motion. Specifically, the cell structures with a high density of dislocation debris also appear to act as dislocation nucleation sites, very much like coherent twin boundaries. This work indicates the potential of additive manufacturing to design energy absorbent alloys with high performance by tailoring the microstructure through the printing process. (c) 2021 Published by Elsevier Ltd on behalf of Chinese Society for Metals. This is an open access article under the CC BY license ( http://creativecommons.org/licenses/by/4.0/ )
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