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Research Articles

Microstructure characteristics and surface oxidation behaviour of SLM WC/IN718 composite

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Pages 308-317 | Received 18 Aug 2021, Accepted 28 Nov 2021, Published online: 10 Dec 2021

References

  • Thirugnan KG, Natarajan S. Degradation mechanism for high temperature erosion in surface modified IN718 superalloy. Surf Eng. 2015;31(1):24–28.
  • Bansal A, Zafar S, Sharma AK. Influence of heat treatment on microstructure of Inconel 718 microwave clads. Surf Eng. 2017;33(3):167–174.
  • Huang W, Yang J, Yang H, et al. Heat treatment of Inconel 718 produced by selective laser melting: microstructure and mechanical properties. Mater Sci Eng A. 2019;750:98–107.
  • Li Z, Paramasivam T, Niu W, et al. Surface engineering of IN-718 by low-temperature carburisation: properties and thermal stability. Surf Eng. 2019;35(3):281–293.
  • Wang YC, Lei LM, Shi L, et al. Scanning strategy dependent tensile properties of selective laser melted GH4169. Mater Sci Eng A. 2020;788:139616.
  • Sitek R, Molak R, Zdunek J, et al. Influence of an aluminizing process on the microstructure and tensile strength of the nickel superalloy IN 718 produced by the selective laser melting. Vacuum. 2021;186:110041.
  • Xia M, Gu D, Ma C, et al. Microstructure evolution, mechanical response and underlying thermodynamic mechanism of multi-phase strengthening WC/Inconel 718 composites using selective laser melting. J Alloy Compd. 2018;747:684–695.
  • Wu P, Zhou CZ, Tang XN. Microstructural characterization and wear behavior of laser cladded nickel-based and tungsten carbide composite coatings. Surf Coat Technol. 2003;166(1):84–88.
  • Ortiz A, García A, Cadenas M, et al. WC particles distribution model in the cross-section of laser cladded NiCrBSi + WC coatings, for different wt% WC. Surf Coat Technol. 2017;324:298–306.
  • Xu J, Lin X, Guo P, et al. The effect of preheating on microstructure and mechanical properties of laser solid forming IN-738LC alloy. Mater Sci Eng A. 2017;691:71–80.
  • Yang J, Li F, Pan A, et al. Microstructure and grain growth direction of SRR99 single-crystal superalloy by selective laser melting. J Alloy Compd. 2019;808:151740.
  • Xia M, Gu D, Ma C, et al. Fragmentation and refinement behavior and underlying thermodynamic mechanism of WC reinforcement during selective laser melting of Ni-based composites. J Alloy Compd. 2019;777:693–702.
  • Jia Q, Gu D. Selective laser melting additive manufactured Inconel 718 superalloy parts: high-temperature oxidation property and its mechanisms. Optics Laser Technol. 2014;62:161–171.
  • Jia Q, Gu D. Selective laser melting additive manufacturing of Inconel 718 superalloy parts: densification, microstructure and properties. J Alloy Compd. 2014;585:713–721.
  • Rong T, Gu D. Formation of novel graded interface and its function on mechanical properties of WC1−x reinforced Inconel 718 composites processed by selective laser melting. J Alloy Compd. 2016;680:333–342.
  • Lu Y, Wu S, Gan Y, et al. Study on the microstructure, mechanical property and residual stress of SLM inconel-718 alloy manufactured by differing island scanning strategy. Optics Laser Technol. 2015;75:197–206.
  • Schneider J, Lund B, Fullen M. Effect of heat treatment variations on the mechanical properties of Inconel 718 selective laser melted specimens. Add Manufact. 2018;21:248–254.
  • Li J, Zhao Z, Bai P, et al. Microstructural evolution and mechanical properties of IN718 alloy fabricated by selective laser melting following different heat treatments. J Alloy Compd. 2019;772:861–870.
  • Jiang R, Mostafaei A, Pauza J, et al. Varied heat treatments and properties of laser powder bed printed Inconel 718. Mater Sci Eng A. 2019;755:170–180.
  • McLouth TD, Witkin DB, Lohser JR, et al. Temperature and strain-rate dependence of the elevated temperature ductility of Inconel 718 prepared by selective laser melting. Mater Sci Eng A. 2021;824:141814.
  • Feng K, Liu P, Li H, et al. Microstructure and phase transformation on the surface of Inconel 718 alloys fabricated by SLM under 1050°C solid solution + double ageing. Vacuum. 2017;145:112–115.
  • Aboulkhair NT, Tuck C, Ashcroft I, et al. On the precipitation hardening of selective laser melted AlSi10Mg. Metall Mater Trans A. 2015;46(8):3337–3341.
  • Ravichander BB, Amerinatanzi A, Shayesteh Moghaddam N, et al. Toward mitigating microcracks using nanopowders in laser powder bed fusion. SPIE. 2021;11589:1–4.
  • Gu D, Wang H, Zhang G. Selective laser melting additive manufacturing of Ti-based nanocomposites: the role of nanopowder. Metall Mater Trans A. 2014;45(1):464–476.
  • Kurian S, Mirzaeifar R. Selective laser melting of aluminum nano-powder particles, a molecular dynamics study. Addit Manuf. 2020;35:101272.
  • Yu X, Lin X, Tan H, et al. Microstructure and fatigue crack growth behavior of Inconel 718 superalloy manufactured by laser directed energy deposition. Int J Fatigue. 2021;143:143–146.
  • Sui S, Tan H, Chen J, et al. The influence of Laves phases on the room temperature tensile properties of Inconel 718 fabricated by powder feeding laser additive manufacturing. Acta Mater. 2019;164:413–427.
  • Saunders N, Guo UKZ, Li X, et al. Using JMatPro to model materials properties and behavior. JOM. 2003;55(12):60–65.
  • Ni M, Liu S, Chen C, et al. Effect of heat treatment on the microstructural evolution of a precipitation-hardened superalloy produced by selective laser melting. Mater Sci Eng A. 2019;748:275–285.
  • Liu P, Hu J, Sun S, et al. Microstructural evolution and phase transformation of Inconel 718 alloys fabricated by selective laser melting under different heat treatment. J Manufact Process. 2019;39:226–232.
  • Keller T, Lindwall G, Ghosh S, et al. Application of finite element, phase-field, and CALPHAD-based methods to additive manufacturing of Ni-based superalloys. Acta Mater. 2017;139:244–253.
  • Liu P, Wu C. Effect of substitutional solid solution plus double ageing treatment on the microstructure of the X-Y surface of Inconel 718 alloy fabricated with selective laser melting (SLM). Lasers in Eng. 2019;30(1-3):47–58.
  • Devaux A, Nazé L, Molins R, et al. Gamma double prime precipitation kinetic in alloy 718. Mater Sci Eng A. 2008;486(1-2):117–122.
  • Lifshitz VVS IM. The kinetics of precipitation from supersaturated solid solutions. J Phys Chem Solids. 1961;19(1-2):35–50.
  • Wan HY, Zhou ZJ, Li CP, et al. Effect of scanning strategy on grain structure and crystallographic texture of Inconel 718 processed by selective laser melting. J Mater Sci Technol. 2018;34(10):1799–1804.
  • Popovich VA, Borisov EV, Popovich AA, et al. Functionally graded Inconel 718 processed by additive manufacturing: crystallographic texture, anisotropy of microstructure and mechanical properties. Mater Des. 2017;114:441–449.
  • Sadowski M, Ladani L, Brindley W, et al. Optimizing quality of additively manufactured Inconel 718 using powder bed laser melting process. Add Manufact. 2016;11:60–70.
  • Karimi P, Raza T, Andersson J, et al. Influence of laser exposure time and point distance on 75-μm-thick layer of selective laser melted alloy 718. The Inter J Adv Manufact Technol. 2018;94(5-8):2199–2207.
  • Konijnenberg PJ, Zaefferer S, Raabe D. Assessment of geometrically necessary dislocation levels derived by 3D EBSD. Acta Mater. 2015;99:402–414.
  • Moussa C, Bernacki M, Besnard R, et al. About quantitative EBSD analysis of deformation and recovery substructures in pure Tantalum. IOP conference series. Mater Sci Eng A. 2015;89(1):12038.
  • Wu X, Jiang P, Chen L, et al. Extraordinary strain hardening by gradient structure. PNAS. 2014;111(20):7197–7201.
  • Hruby P, Singh SS, Williams JJ, et al. Fatigue crack growth in SiC particle reinforced Al alloy matrix composites at high and low R-ratios by in situ X-ray synchrotron tomography. Int J Fatigue. 2014;68:136–143.
  • Zhang H, Li C, Guo Q, et al. Improving creep resistance of nickel-based superalloy Inconel 718 by tailoring gamma double prime variants. Scripta Mater. 2019;164:66–70.
  • Sundararaman M. Some aspects of the precipitation of metastable intermetallic phases in INCONEL 718. Metall Mater Trans A. 1992;23(7):2015–2028.
  • Theska F, Stanojevic A, Oberwinkler B, et al. Microstructure-property relationships in directly aged alloy 718 turbine disks. Mater Sci Eng A. 2020;776:138967.
  • Wang X, Chou K. Electron backscatter diffraction analysis of Inconel 718 parts fabricated by selective laser melting additive manufacturing. JOM. 2017;69(2):402–408.
  • Keshavarzkermani A, Sadowski M, Ladani L. Direct metal laser melting of Inconel 718: process impact on grain formation and orientation. J Alloy Compd. 2018;736:297–305.
  • Wang H, Souza N D, Zhao S, et al. Effects of elemental vaporization and condensation during heat treatment of single crystal superalloys. Scripta Mater. 2014;78–79:45–48.
  • Zhuo L, Huang M, Wang F, et al. The effect of elemental vaporization and redistribution during sub-solvus recrystallization of a single crystal superalloy. Mater Lett. 2015;143:305–308.
  • Kim KS, Winograd N. X-ray photoelectron spectroscopic studies of nickel-oxygen surfaces using oxygen and argon ion-bombardment. Surf Sci. 1974;43(2):625–643.
  • Nan Z, Jiao Q, Tan Z, et al. Investigation of thermodynamic properties of Co2O3 powder. Thermochim Acta. 2003;404(1–2):245–249.
  • Wang J, Li B, Li R, et al. Unprecedented oxidation resistance at 900 °C of Mo-Si-B composite with addition of ZrB2. Ceram Int. 2020;46(10):14632–14639.
  • Klein L, Bartenwerffer B, Killian MS, et al. The effect of grain boundaries on high temperature oxidation of new (′-strengthened Co-Al-W-B superalloys. Corros Sci. 2014;79:29–23.

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