Microstructure and high temperature tensile properties of powder metallurgy Mo−Re alloys
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摘要: 采用粉末冶金结合高温压力加工制备了Mo−14Re和Mo−42Re合金棒材,观察与测试了Mo−Re合金的微观组织、相组成、室温及高温拉伸性能,并结合断口形貌分析了合金断裂机制。结果表明,经高温压力加工后,Mo−Re合金晶粒由等轴状转变为拉长的纤维状,相对密度达99.6%以上。Re固溶于Mo中,使Mo−Re合金晶格常数从Mo−14Re的3.1384 Å减小到Mo−42Re的3.1304 Å,导致晶格畸变程度增大。当Re质量分数从14%增加到42%,Mo−Re合金的室温及高温强度得到大幅提升。随测试温度升高,合金强度下降,Mo−14Re断后伸长率有所下降,而Mo−42Re断后伸长率呈上升趋势。Mo−14Re室温断口呈木纹状撕裂型断裂,1100~1300 ℃断口呈韧窝状,在1500 ℃时塑性变形主要由晶界滑移产生。Mo−42Re室温断口为穿晶断裂,1100~1500 ℃断口为完全的韧窝状,塑性变形由韧窝产生的非均匀变形提供。Abstract: Mo−14Re and Mo−42Re alloy bars were prepared by powder metallurgy and hot press working. The microstructure, phase composition, and tensile properties at room and high temperature were observed and tested, and the fracture mechanism of Mo−Re alloys was analyzed, combined with the fracture morphology. The results show that, after the hot press working, the Mo−Re alloy grains change from equiaxed to elongated fibrous, and the relative density of alloy bars is more than 99.6%. The solid solution of Re in Mo reduces the lattice constant of Mo−Re alloy from 3.1384 Å of Mo−14Re to 3.1304 Å of Mo−42Re, leading to the increase of lattice distortion. The room and high temperature strength of Mo−Re alloys are greatly improved with the increase of Re mass fraction from 14% to 42%. With the increase of test temperature, the strength of Mo−Re alloys decreases, the elongation of Mo−14Re alloys decreases slightly, while that of Mo−42Re increases. The room temperature fracture of Mo−14Re alloys exhibits a wood-grain tearing fracture, the fracture at 1100~1300 ℃ is dimple, and the plastic deformation is mainly caused by grain boundary slip at 1500 ℃. The room temperature fracture of Mo−42Re alloys shows a transgranular fracture, the fracture at 1100~1500 ℃ is completely dimpled, and the plastic deformation at high temperature is provided by the non-uniform deformation produced by dimple.
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Key words:
- Mo−Re alloys /
- microstructure /
- tensile property /
- fracture morphology
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图 1 原料粉末形貌:(a)Mo粉;(b)Re粉
Figure 1. Morphology of the raw powders: (a) Mo powders; (b) Re powders
图 2 Mo−Re合金烧结态微观组织:(a)Mo−14Re;(b)Mo−42Re
Figure 2. Microstructure of the sintered Mo−Re alloys: (a) Mo−14Re; (b) Mo−42Re
图 3 Mo−Re合金锻造态微观组织:(a)Mo−14Re;(b)Mo−42Re
Figure 3. Microstructure of the forging Mo−Re alloys: (a) Mo−14Re; (b) Mo−42Re
图 5 Mo−Re合金室温拉伸应力-应变曲线
Figure 5. Tensile stress-strain curves of the Mo−Re alloys at room temperature
图 6 不同温度下Mo−Re合金拉伸性能:(a)抗拉强度及屈服强度;(b)断后伸长率及断面收缩率
Figure 6. Tensile properties of the Mo−Re alloys at the different temperatures: (a) tensile strength and yield strength; (b) elongation and area shrinkage after fracture
图 7 Mo−Re合金拉伸断口形貌:(a)、(b)Mo−14Re合金,室温;(c)Mo−14Re合金,1100 ℃;(d)Mo−14Re合金,1300 ℃;(e)Mo−14Re合金,1500 ℃;(f)、(g)Mo−42Re合金,室温;(h)Mo−42Re合金,1100 ℃;(i)Mo−42Re合金,1300 ℃;(j)Mo−42Re合金,1500 ℃
Figure 7. Tensile fracture morphology of the Mo−Re alloys: (a), (b) Mo−14Re alloys at room temperature; (c) Mo−14Re alloys at 1100 ℃; (d) Mo−14Re alloys at 1300 ℃; (e) Mo−14Re alloys at 1500 ℃; (f), (g) Mo−42Re alloys at room temperature; (h) Mo−42Re alloys at 1100 ℃; (i) Mo−42Re alloys at 1300 ℃; (j) Mo−42Re alloys at 1500 ℃
表 1 Mo−Re合金棒材成分及密度
Table 1. Composition and density of the Mo−Re alloy bar
编号 质量分数 / ×10−6 密度 /
(g·cm−3)理论密度 /
(g·cm−3)相对密度 / % H N O Fe Ca K Al Si Mo−14Re 10 30 20 2.10 0.69 <0.005 0.62 0.22 10.99 11.01 99.8 Mo−42Re 10 30 20 0.39 2.10 1.500 4.20 3.10 13.00 13.05 99.6 
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表 2 Mo−Re合金晶面间距及晶格常数
Table 2. Interplanar spacing and lattice constant of the Mo−Re alloys
材料 (110) 晶面 (200) 晶面 (211) 晶面 (220) 晶面 晶格常数,
a / Å衍射角,
θ / (°)晶面间距 / Å 衍射角,
θ / (°)晶面间距 / Å 衍射角,
θ / (°)晶面间距 / Å 衍射角,
θ / (°)晶面间距 / Å Mo* 20.258 2.2247 29.304 1.5738 36.841 1.2847 43.798 1.1129 3.1472 Mo−14Re 20.313 2.2192 29.379 1.5701 36.912 1.2826 43.903 1.1109 3.1384 Mo−42Re 20.364 2.2135 29.471 1.5657 37.065 1.2781 44.087 1.1071 3.1304 注:Mo*标准衍射参数来自于2004版粉末衍射卡片(PDF)数据库,卡片号42-1120。
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