期刊
MATERIALS CHARACTERIZATION
卷 175, 期 -, 页码 -出版社
ELSEVIER SCIENCE INC
DOI: 10.1016/j.matchar.2021.111103
关键词
High strength titanium alloys; Impact toughness; Microstructure design
类别
资金
- National Key Research and Development Program of China [2016YFB0301201]
- National International Science and Technology Cooperation Project of China [2015DF151430]
Samples with different microstructures (BM, TM, LM) of a high strength Ti-5321 alloy were tested for impact performance, with results showing that LM had the highest impact toughness and crack initiation energy. SEM and EBSD analysis revealed the influence of microstructure on crack initiation and propagation during impact process, indicating that LM exhibited better impact properties due to its specific microstructure characteristics.
To achieve preferable impact performance of a newly designed high strength Ti-5321 alloy, samples with three kinds of microstructures, i.e., bimodal microstructure (BM), tri-modal microstructure (TM) and lamellar microstructure (LM) were prepared for instrument Charpy tests at room temperature. Results of impact tests indicated that LM presented the higher impact toughness of 37.5 J/cm2 than that of BM (11.25 J/cm2) and TM (25 J/cm2). Moreover, both crack initiation energy and crack propagation energy of LM were obviously raised. Further analysis containing fracture surfaces and the cross-sectional microstructures of the impact samples by the usage of SEM and EBSD provided insights into the influence of microstructure on crack initiation and propagation during impact process. The largely plastic deformation of primary ? near the V-notch tip impeded crack initiation and enhanced the crack initiation energy. The interweaved ? colonies with high angle boundaries deflected the crack propagation direction and thus increased the crack propagation energy. Besides, TEM analysis showed that the typical deformation characteristic under impact test with high strain rate. Except for dislocation lines, the pile-up of highly dense dislocations, twinning, dislocation cells, sub-grains, shear bands and fragmentation of ? phase can be found. These approaches presented in this study could provide certain insights into fabricating typical microstructure in the high strength titanium alloys to ameliorate impact properties.
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