Development of High-strength, High-temperature Nb-Si-Ti Alloys through Mechanical Alloying

Journal of Korean Powder Metallurgy Institute Pub Date : 2024-02-28 DOI:10.4150/kpmi.2024.31.1.30

Jung-Joon Kim, Sang-Min Yoon, Deok-Hyun Han, Jongmin Byun, Young-Kyun Kim

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Abstract

The aerospace and power generation industries have an increasing demand for high-temperature, high-strength materials. However, conventional materials typically lack sufficient fracture toughness and oxidation resistance at high temperatures. This study aims to enhance the high-temperature properties of Nb-Si-Ti alloys through ball milling. To analyze the effects of milling time, the progression of alloying is evaluated on the basis of XRD patterns and the microstructure of alloy powders. Spark plasma sintering (SPS) is employed to produce compacts, with thermodynamic modeling assisting in predicting phase fractions and sintering temperature ranges. The changes in the microstructure and variation in the mechanical properties due to the adjustment of the sintering temperature provide insights into the influence of Nb solid solution, Nb5Si3, and crystallite size within the compacts. By investigating the changes in the mechanical properties through strengthening mechanisms, such as precipitation strengthening, solid solution strengthening, and crystallite refinement, this study aims to verify the applicability of Nb-Si-Ti alloys in advanced material systems.

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通过机械合金化开发高强度高温铌硅钛合金

航空航天和发电行业对高温、高强度材料的需求与日俱增。然而，传统材料通常缺乏足够的高温断裂韧性和抗氧化性。本研究旨在通过球磨提高 Nb-Si-Ti 合金的高温性能。为了分析研磨时间的影响，根据 XRD 图谱和合金粉末的微观结构评估了合金化的进展。采用火花等离子烧结（SPS）技术生产紧凑型材料，热力学模型有助于预测相分数和烧结温度范围。调整烧结温度会引起微观结构的变化和机械性能的变化，这有助于深入了解铌固溶体、Nb5Si3 和致密材料中晶粒尺寸的影响。通过研究沉淀强化、固溶强化和晶粒细化等强化机制对力学性能的影响，本研究旨在验证 Nb-Si-Ti 合金在先进材料体系中的适用性。

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Journal of Korean Powder Metallurgy Institute

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