期刊
INTERNATIONAL JOURNAL OF FATIGUE
卷 124, 期 -, 页码 389-399出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.ijfatigue.2019.03.022
关键词
Cyclic deformation behavior; Anisotropy; Additive manufacturing; Microstructural defects; AISI 316L; Short-time procedures
资金
- Bundeswehr Research Institute for Materials, Fuels and Lubricants (WIWeB)
To exploit the high potential of additive manufacturing (AM) technology for production of safety relevant structural components, it is indispensable to get a sound knowledge about the fatigue behavior of additively manufactured materials. However, fatigue investigations are time and material consuming, leading to high costs for fatigue validation of AM materials. To reduce this effort, in this research work the short-time procedures PhyBaL(CHT) (CHT: cyclic hardness test), based on cyclic indentation testing, and PhyBaL(LIT) (physically based lifetime calculation; LIT: load increase test), based on load increase tests (LITs) are used to comprehensively characterize the fatigue behavior of selectively laser melted specimens made of austenitic stainless steel AISI 316L in three different building directions. The different building directions lead to layer planes perpendicular (SLM-V), in 45 degrees direction (SLM-45) and parallel (SLM-H) to the loading direction. In addition to the short-time procedures, several constant amplitude tests (CATs) were performed to validate the results. The results of CATs showed only slight differences in the fatigue behavior of SLM specimens, which correlates well with the results of LITs. Furthermore, the results of CATs demonstrate a high influence of the microstructural defects i.e. pores on the fatigue behavior and different defect tolerances depending on the building direction. The vertical building direction lead to the highest defect tolerance, which is proved by the results of PhyBaL(CHT). The S-N-f curves, calculated by the PhyBaL(LIT) approach, are in good accordance to the CATs and hence, can describe the characteristics of the fatigue properties of the different orientations with good accuracy. Consequently, the influence of different building directions on the fatigue behavior of the SLM specimens could be determined efficiently with the presented short-time procedures.
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