Effect of Pressure and Heating Temperature on the Structure and Mechanical Properties of Explosion-Welded Aluminum-Niobium Multilayer Composite

IF 0.6 4区材料科学 Q4 METALLURGY & METALLURGICAL ENGINEERING

Metal Science and Heat Treatment Pub Date : 2024-02-20 DOI:10.1007/s11041-024-00971-0

Yu. N. Malyutina, D. V. Lazurenko, E. A. Lozhkina

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Abstract

Multilayer composites formed by explosion welding from alternated plates of niobium and aluminum are studied. The samples are subjected to annealing at 700, 800 and 900°C under a load and without load. The structure, the ultimate tensile strength, the impact toughness and the Vickers microhardness of the composites are determined. It is shown that mixed zones represented by nonequilibrium phases, intermetallic particles of NbAl₃ and Nb₂ Al, and undissolved niobium volumes are formed near “local melting/rapid solidification” interfaces. Increase of the annealing temperature from 700 to 900°C causes growth of the intermetallic inclusions, appearance of cracks in the reaction layer, and considerable worsening of the mechanical properties. The highest ultimate strength (700 MPa) and impact toughness (86 J/cm² ) are obtained in the samples annealed under pressure at 900 and 800°C, respectively. Annealing at 700°C at a pressure of 30 MPa is shown to be an optimum treatment producing a favorable effect on the strength characteristics and providing a defect-free structure.

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压力和加热温度对爆焊铝铌多层复合材料结构和机械性能的影响

研究了由铌和铝交替板材通过爆炸焊接形成的多层复合材料。样品分别在 700、800 和 900°C 的温度下进行有载荷和无载荷退火。测定了复合材料的结构、极限拉伸强度、冲击韧性和维氏硬度。结果表明，在 "局部熔化/快速凝固 "界面附近形成了以非平衡相、NbAl3 和 Nb2 Al 金属间化合物颗粒以及未溶解铌体积为代表的混合区。将退火温度从 700°C 提高到 900°C，会导致金属间夹杂物的增长、反应层裂纹的出现以及机械性能的显著恶化。极限强度（700 兆帕）和冲击韧性（86 焦耳/平方厘米）最高的分别是在 900 和 800°C 下加压退火的样品。在 30 兆帕的压力下于 700°C 退火是一种最佳处理方法，可对强度特性产生有利影响，并提供无缺陷结构。

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来源期刊

Metal Science and Heat Treatment 工程技术-冶金工程

CiteScore

1.20

自引率

16.70%

发文量

102

审稿时长

4-8 weeks

期刊介绍： Metal Science and Heat Treatment presents new fundamental and practical research in physical metallurgy, heat treatment equipment, and surface engineering. Topics covered include: New structural, high temperature, tool and precision steels; Cold-resistant, corrosion-resistant and radiation-resistant steels; Steels with rapid decline of induced properties; Alloys with shape memory effect; Bulk-amorphyzable metal alloys; Microcrystalline alloys; Nano materials and foam materials for medical use.