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Effect of process parameters on microstructure and properties of Inconel-718 superalloy fabricated by wire-arc direct energy deposition technique

Jingjing Shi, Ning Qian, Shengyuan Sun, Yusuf Kaynak, Raj Das, Yucan Fu, Honghua Su

2025Journal of Materials Research and Technology9 citationsDOIOpen Access PDF

Abstract

As critical aero-engine components, closed impellers demand precision manufacturing to ensure reliability under extreme conditions. Traditional casting and powder-bed additive manufacturing face challenges in defect control and cost-effectiveness. Wire-arc directed energy deposition offers high material utilization and deposition rates for near-net-shape fabrication, yet its inherent high heat input induces microstructural defects such as Laves phase segregation in Inconel-718 superalloy. This study investigates CMT + P-based wire-arc DED processing of Inconel-718, focusing on energy density effects spanning 360–540 J/mm on thin-wall geometry, microstructure, and mechanical properties. Energy-dispersive X-ray spectroscopy and XRD analysis reveal that increased energy density expands primary dendrite arm spacing from 4.68 to 18.97 μm and Laves phase area fraction from 3.12 to 8.10 %, correlating with reduced as-deposited tensile strength of 725 ± 45 MPa. Post-deposition solution-aging heat treatment enhances ultimate tensile strength to 1354 ± 54 MPa. The mechanical properties of Inconel-718 deposited via CMT + P were compared with those produced by the conventional CMT process. Mechanical property benchmarking against Inconel-718 casting and forging standards provides actionable insights for industrial process optimization.

Topics & Concepts

Materials scienceInconelSuperalloyMicrostructureMetallurgyDeposition (geology)Arc (geometry)Process (computing)AlloyMechanical engineeringPaleontologyBiologyEngineeringSedimentOperating systemComputer scienceAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys StudiesWelding Techniques and Residual Stresses