具有交叉层状结构的生物启发互穿 Ti2AlNb/TiAl 基复合材料的微观结构演变和力学性能

IF 12.7 1区 材料科学 Q1 ENGINEERING, MULTIDISCIPLINARY Composites Part B: Engineering Pub Date : 2024-09-21 DOI:10.1016/j.compositesb.2024.111851
Hang Zou , Rui Hu , Mi Zhou , Zitong Gao , Xinxin Liu , Xian Luo
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引用次数: 0

摘要

具有低密度、高抗蠕变性和高温性能的 TiAl 合金被认为是替代 700 ∼ 800 °C镍基超级合金的候选材料。然而,TiAl 合金的内在脆性一直是制约其发展的最大瓶颈。本文通过选择性激光熔化(SLM)和真空热压烧结(HPS)相结合的方法,在 1150 °C/1 h/45 MPa 的条件下制备了具有交叉层状结构的生物启发穿透 Ti2AlNb/TiAl 复合材料,提高了复合材料的强度和韧性。同时,研究了不同体积能量密度(VED)条件下打印的 Ti2AlNb 增强骨架的冶金缺陷和微观结构,并系统研究了复合材料界面区微观结构的演变。此外,我们还研究了复合材料的力学性能,包括纳米压痕测试、室温拉伸和弯曲测试。结果表明,VED 为 88.89 J/mm3,得到了几乎完全致密的增强骨架(∼99.8 %)。由于元素的扩散,界面区可分为四个不同的反应层,即 LⅠ、LⅡ、LⅢ 和 LⅣ。LⅠ 主要由 O 厚/薄板状相和 O 短棒状相组成。LⅡ 主要由 B2/β 相、针状 α2 相和纳米级 ω-Ti3NbAl2 相组成。LⅢ 主要由 B2/β 相组成。LⅣ 由 α2 相组成。复合材料中各相的变形能力:B2/β相> O相>γ相>α2相>ω相。与 TiAl 合金相比,生物启发互穿 Ti2AlNb/TiAl 基复合材料的拉伸强度和断裂韧性分别提高了 24.0% 和 89.0%,这主要归功于基体与增强体之间的强界面结合以及 Ti2AlNb 增强体的高强度和高韧性协同效应。
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Microstructure evolution and mechanical properties of bioinspired interpenetrating Ti2AlNb/TiAl matrix composite with a crossed-lamellar structure
TiAl alloys with low density, high creep resistance and high temperature performance are considered as candidate materials to replace nickel-based superalloys in the range of 700∼800 °C. However, the intrinsic brittleness of TiAl alloys has always been the biggest bottleneck restricting their development. In this paper, a bioinspired interpenetrating Ti2AlNb/TiAl composite with crossed-lamellar structure was prepared by combining selective laser melting (SLM) and vacuum hot press sintering (HPS) under the condition of 1150 °C/1 h/45 MPa, to improve the strength and toughness of the composite. Meanwhile, the metallurgical defects and microstructure of Ti2AlNb reinforcement skeleton printed under different volume energy densities (VEDs) were investigated, as well as the evolution of the microstructure at the interface region of the composite was systematically studied. What's more, we studied the mechanical properties of the composite including nanoindentation test, room temperature tensile and bending tests. The results show that the VED is 88.89 J/mm3, an almost completely dense reinforcement skeleton (∼99.8 %) is obtained. The interface region can be divided into four different reaction layers, namely L, L, L and L, due to the diffusion of elements. L is mainly composed of Othick/thin lath-like phase and O short rod-like phase. L is mainly composed of B2/β phase, acicular α2 phase and nanoscale ω-Ti3NbAl2 phase. The L mainly consists of B2/β phase. The L is composed of α2 phase. The deformability of each phase in the composite: B2/β phase > O phase >γ phase >α2 phase >ω phase. The tensile strength and fracture toughness of bioinspired interpenetrating Ti2AlNb/TiAl matrix composite are increased by 24.0 % and 89.0 %, respectively, compared with TiAl alloy, which is mainly contributed to the strong interfacial bonding between matrix and reinforcement as well as the synergistic effect of Ti2AlNb reinforcement with high strength and toughness.
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来源期刊
Composites Part B: Engineering
Composites Part B: Engineering 工程技术-材料科学:复合
CiteScore
24.40
自引率
11.50%
发文量
784
审稿时长
21 days
期刊介绍: Composites Part B: Engineering is a journal that publishes impactful research of high quality on composite materials. This research is supported by fundamental mechanics and materials science and engineering approaches. The targeted research can cover a wide range of length scales, ranging from nano to micro and meso, and even to the full product and structure level. The journal specifically focuses on engineering applications that involve high performance composites. These applications can range from low volume and high cost to high volume and low cost composite development. The main goal of the journal is to provide a platform for the prompt publication of original and high quality research. The emphasis is on design, development, modeling, validation, and manufacturing of engineering details and concepts. The journal welcomes both basic research papers and proposals for review articles. Authors are encouraged to address challenges across various application areas. These areas include, but are not limited to, aerospace, automotive, and other surface transportation. The journal also covers energy-related applications, with a focus on renewable energy. Other application areas include infrastructure, off-shore and maritime projects, health care technology, and recreational products.
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