On the Development of a Heat Treatment for Inconel Alloy X-750 Produced Using Laser Powder Bed Fusion

G. M. Volpato, A. S. P. Pereira, M. C. Fredel, U. Tetzlaff
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Abstract

The substantial development that the additive manufacturing technique of powder bed fusion using a laser beam (PBF-LB) underwent in the past decades, though expressive, has been restricted to particular materials and applications. When coming to Ni-based superalloys, the technology has been mostly developed regarding a few polycrystalline Ni–Cr–Fe and Ni–Cr alloys, particularly Inconel 718 and 625. However, when produced using PBF-LB, these materials should undergo tailored heat treatment sequences to adjust its microstructure to industrial standards, which must be developed according to the behavior of each particular alloy. In view of such restrictiveness, this study assessed 77 experimental heat treatments for PBF-LB Inconel X-750, an alloy with comparatively limited research volume when considering additive manufacturing, aiming at providing guidelines for its post-processing after PBF-LB manufacturing. These heat treatments were based on the standard ASM 5668 sequence for maximization of creep resistance, and, contradicting the known precipitation behavior of the conventional material, often resulted in coarse precipitation of detrimental bulk η-Ni3Ti intermetallic phases. This indicates insufficient chemical homogenization after heat treatment, evidencing a different microstructural response of the material when processed using PBF-LB and the importance of optimizing the post-processing of such materials.

Abstract Image

利用激光粉末床熔融技术生产的铬镍铁合金 X-750 的热处理开发
使用激光束的粉末床熔融(PBF-LB)增材制造技术在过去几十年中取得了长足的发展,尽管这种技术具有很强的表现力,但却仅限于特定的材料和应用领域。就镍基超合金而言,该技术主要针对一些多晶镍铬铁合金和镍铬合金,尤其是铬镍铁合金 718 和 625。然而,在使用 PBF-LB 生产时,这些材料必须经过定制的热处理顺序,以调整其微观结构,使其符合工业标准,而这些标准必须根据每种特定合金的特性来制定。鉴于这种局限性,本研究评估了 PBF-LB Inconel X-750 的 77 种实验性热处理,旨在为 PBF-LB 制造后的后处理提供指导。这些热处理基于标准的 ASM 5668 序列,旨在最大限度地提高抗蠕变性,但与传统材料的已知析出行为相矛盾的是,这些热处理往往会导致有害的大量 η-Ni3Ti 金属间相的粗大析出。这表明热处理后的化学均匀性不足,证明使用 PBF-LB 加工时材料的微观结构反应不同,以及优化此类材料后处理的重要性。
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