Denny John, Bryer C. Sousa, Tanaji Paul, Sohail M. A. K Mohammed, Danielle L. Cote, Arvind Agarwal
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引用次数: 0
摘要
由于缺乏对粉末微观结构与其变形行为之间相关性的了解,使用非晶/纳米晶铝高熵合金(Al HEA)粉末开发高强度冷喷沉积物的工作受到了阻碍。本研究在 298、345、362 和 450 °C 下对气原子化铝高熵合金粉(Al90.05-Y4.4-Ni4.3-Co0.9-Sc0.35 at.%)进行了蜕变,以优化冷喷涂的强度和变形。蜕变引起的原子重排形成了等轴的铝晶粒以及 Al3Ni 和 Al3Sc 沉淀。非晶质含量、晶粒生长、硬析出物和位错密度的降低使 298 °C 时的硬度提高了 16% 至 515 HV,450 °C 时的硬度降低了 55% 至 190 HV。铝 HEA 粉末的抗压强度在 298 °C 时增加了 5%,达到 1559 兆帕,而在 450 °C 时则降低了 49%,达到 760 兆帕。为了提高 Al HEA 粉末的有限喷涂性,抗压强度被用来模拟优化的冷喷涂工艺图。温度为 300 至 800 ℃、压力为 40 巴的氦气可产生沉积效率大于 70% 的冷喷沉积物。本研究获得的科学见解为开发新型轻质高强度铝合金沉积物提供了一个途径,从而标志着冷喷涂技术的进步。
Devitrification-Induced Tailoring of Microstructure and Strength in Aluminum High-Entropy Alloy Powder for Cold Spray Deposition
The development of high-strength cold spray deposits using amorphous/nanocrystalline aluminum high-entropy alloy (Al HEA) powder is hindered by the lack of understanding of correlations between powder microstructure and its deformation behavior. In this study, gas-atomized Al HEA powder (Al90.05-Y4.4-Ni4.3-Co0.9-Sc0.35 at.%) is devitrified at 298, 345, 362, and 450 °C to optimize strength and deformation for cold spraying. Devitrification-induced atomic rearrangement developed equiaxed Al grains and Al3Ni and Al3Sc precipitates. The amorphous content, growth of grains, hard precipitates, and reduced dislocation density increased the hardness by 16% to 515 HV at 298 °C and decreased the hardness by 55% to 190 HV at 450 °C. The compressive strength of Al HEA powder increased by 5% to 1559 MPa at 298 °C and decreased by 49% to 760 MPa at 450 °C. To enhance the limited sprayability of Al HEA powder, compressive strength is used to model optimized cold spray process maps. Helium gas with temperatures from 300 to 800 °C and a pressure of 40 bar can produce cold spray deposits with deposition efficiency greater than 70%. The scientific insights acquired from the present study provide a gateway toward developing novel lightweight and high-strength aluminum alloy deposits, thus marking an advancement in cold spray technology.
期刊介绍:
From the scientific to the practical, stay on top of advances in this fast-growing coating technology with ASM International''s Journal of Thermal Spray Technology. Critically reviewed scientific papers and engineering articles combine the best of new research with the latest applications and problem solving.
A service of the ASM Thermal Spray Society (TSS), the Journal of Thermal Spray Technology covers all fundamental and practical aspects of thermal spray science, including processes, feedstock manufacture, and testing and characterization.
The journal contains worldwide coverage of the latest research, products, equipment and process developments, and includes technical note case studies from real-time applications and in-depth topical reviews.
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