Unravelling the dominant influence of microsegregation on creep rupture behaviour of additively manufactured inconel 718

This investigation focuses on unravelling the dominant influence of microsegregation and microstructure altered due to heat treatment cycle variation on creep rupture behaviour of additively manufactured Inconel 718 (AM-IN718). Two microstructural variants differing in the fraction of recrystallized...

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Veröffentlicht in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2025-01, Vol.919, p.147480, Article 147480
Hauptverfasser: Sabari, Singaravelu Rajan, Koundinya, N.T.B.N., Godha, Akshat, Makineni, Surendra Kumar, Narayana Murty, S.V.S., Nagesha, B.K., Janaki Ram, G.D., Kottada, Ravi Sankar
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Sprache:eng
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Zusammenfassung:This investigation focuses on unravelling the dominant influence of microsegregation and microstructure altered due to heat treatment cycle variation on creep rupture behaviour of additively manufactured Inconel 718 (AM-IN718). Two microstructural variants differing in the fraction of recrystallized grains while δ-phase being absent, were produced. A typical heat treatment (HT) cycle includes the stress-relieving of the as-built specimens at 980 °C, followed by solution treatment at 1080 °C (STA1080, a partially recrystallized microstructural variant) or 1150 °C (STA1150, a fully recrystallized microstructural variant), and double ageing (soaking at 720 °C for 8h and subsequent furnace cooling, followed by 8h at 620 °C and air cooling). Detailed microstructural characterization of two microstructural variants through correlative microscopy revealed a prevalent existence of Nb-rich precipitate-free zones (PFZ) in STA1080 than in STA1150. Creep characterization of the two microstructural variants in the temperature range of 625–675 °C and at 500–750 MPa demonstrated superior creep resistance in STA1150. The correlation of kinetic analysis and comprehensive post-deformation microstructural characterization suggests grain boundary cavitation as the main damage/softening mechanism and the reason for the difference in creep rupture behaviour between the two microstructural variants. The long-term exposure heat treatment methodology demonstrates that PFZs are the major influencing factor responsible for microsegregation-dependent creep rupture behaviour. Interestingly, the presence of the δ phase within PFZs appeared to retard cavity coalescence and failure during creep, despite its usual detrimental role in creep resistance. •Common heat treatment cycle(STA1080) renders poor creep resistance of AM-IN718.•Poor creep resistance of STA1080 attributed to microsegregation and ensuing PFZs.•STA1150 resulted in complete (chemical and microstructural) homogenization.•PFZs accelerated cavity nucleation and coalescence causing creep failure in STA1080.•STA1150 specimens exhibit superior creep resistance and rupture life than STA1080.
ISSN:0921-5093
DOI:10.1016/j.msea.2024.147480