期刊
JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T
卷 23, 期 -, 页码 5698-5709出版社
ELSEVIER
DOI: 10.1016/j.jmrt.2023.02.184
关键词
Cold spray additive manufacturing; Pure tantalum; High-temperature compression; Deformation behavior; Surface oxidation
Solid-state cold spray additive manufacturing (CSAM) was used to fabricate pure tantalum (Ta) and its high-temperature mechanical and deformation behavior were investigated. The CSAM-fabricated Ta consisted of irregularly shaped, elongated powder particles perpendicular to the spraying direction. Microstructural evolution occurred along the boundaries between powder particles in response to harsher plastic deformation. Compression test results showed that the room temperature yield strength of CSAM Ta was approximately 901 MPa, significantly higher than conventional Ta processes. Furthermore, CSAM Ta exhibited excellent mechanical properties at high temperatures up to approximately 950 degrees C, attributed to the interaction between high-temperature oxidation behavior and microstructural evolution, i.e. dynamic recrystallization. The relationship between microstructure, room-to-high-temperature mechanical properties, and deformation behaviors are discussed.
Solid-state cold spray additive manufacturing (CSAM) was used to fabricate pure tantalum (Ta) and the high-temperature mechanical and deformation behavior of this material was investigated. The pure Ta fabricated using CSAM consists of irregularly shaped powder particles elongated in the direction perpendicular to the spraying direction. In addition, microstructural evolution occurs in the process of accommodating harsher plastic deformation along the boundaries between powder particles. Compression test results confirmed that the room temperature yield strength was approximately 901 MPa, which is four to six times higher than that of pure Ta produced using conventional processes such as vacuum arc melting etc. Moreover, CSAM Ta has excellent mechanical properties even at high temperatures, and these properties were confirmed to be retained up to approximately 950 degrees C. Surface and microstructural observations after deformation revealed that the sample crumbled in a compression test at 800 degrees C. However, the sample retained its shape at temperatures above 800 degrees C. This phenomenon was a result of the interaction between high-temperature oxidation behavior and microstructural evolution, i.e. dynamic recrystallization. Based on these findings, the relationship among the microstructure, room-to high-temperature mechanical properties, and deformation behaviors are also discussed. (c) 2023 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
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