The effect of laser scanning speed on microstructural evolution during direct laser deposition 12CrNi2 alloy steel

• Published in: Optics and laser technology Vol. 125; p. 106041
• Main Authors: Zhou, Yue, Chen, Suiyuan, Chen, Xueting, Liang, Jing, Liu, Changsheng, Wang, Mei
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.05.2020; Elsevier BV
• Subjects: 12CrNi2 alloy steel; Alloy steels; Anisotropy; Bainite; Cooling rate; Design parameters; Direct laser deposition; Evolution; Ferrite; Grain size; Heat flux; Heat treating; Impact strength; Laser applications; Laser deposition; Laser scanning speed; Lasers; Martensite; Martensitic transformations; Microhardness; Microstructural evolution; Microstructure; Multilayers; Optimization; Process parameters; Product development; Properties; Scanning; Toughness; Wear resistance; 12CrNi2 alloy steel; Microstructural evolution; Properties; Direct laser deposition; Laser scanning speed
• ISSN: 0030-3992; 1879-2545
• DOI: 10.1016/j.optlastec.2019.106041

•The microstructural evolution of DLD 12CrNi2 with laser scanning speed was studied.•The relationship between laser scanning speed and microstructure were fitted.•Bainite ferrite with a width of 500–600 nm was observed due to high energy input.•The impact toughness could reach 80 J/cm2 due to a large amount of ferrite phase. This paper focused on the effect of different laser scanning speed (4 mm/s, 5 mm/s, 6 mm/s and 7 mm/s) on the microstructural evolution of direct laser deposition (DLD) 12CrNi2 alloy steel, and analyzed the relationship between microstructure and performance of DLD-processed samples. The results showed that the microstructure in the middle of as-deposited samples consisted of a large amount of bainite, a small amount of martensite (M) and ferrite (F). With the increase of laser scanning speed, the fraction of ferrite decreased from 55.6% to 14.7%, while that of martensite increased from nearly 0% to 4.9%. Besides, as increasing the laser scanning speed, granular bainite (GB) transformed into lath bainite (LB) due to the increase of cooling rate, and the fraction of LB reached the maximum of 29.9% when the scanning speed was 7 mm/s. In addition, the functions about the relationship between laser scanning speed and phase fractions were fitted in order to provide a theoretical basis for the design of DLD process parameters. EBSD maps of as-deposited samples exhibited anisotropy due to the complex heat flux direction during the multi-layer laser deposition process. With the increase of laser scanning speed, the grain size showed a downward trend from 5.89 µm2 to 3.44 µm2. The sample fabricated at 7 mm/s contained more LB and M, leading to the highest mean microhardness of 355 ± 6 HV0.2. The sample fabricated at 6 mm/s exhibited the best wear resistance due to its optimum combination of hardness and toughness. Because of a large amount of ferrite with optimal toughness, the sample fabricated at 4 mm/s had the best impact toughness of aku = 80 J/cm2.