Ti-46Al-8Nb难熔金属间合金凝固初相组织研究

A. Kartavykh
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引用次数: 4

摘要

本文通过实验分析和澄清了有关难熔Ti-46Al-8Nb (at.%)合金显微组织形成与Ti-Al-Nb相图内高温相变过程的矛盾数据。为了确定合金初次凝固相,采用无氧陶瓷(99.99% AlN)坩埚在高纯氩气气氛中对低氧污染合金试样进行了熔炼和快速凝固实验。体积等温冷却从1943 K在5,10和20 K/s的速率和随后的淬火迷你锭从1763 K使用。采用背散射电子(BSE)模式对样品进行扫描电镜(SEM)研究。SEM-BSE显微图显示,在1843 K(液相线)和1773 K(固相线)温度范围内形成的初生多晶微观结构中,铌偏析的阴影区被淬火固定和修饰。初生晶相以β(Ti)枝晶为代表,具有明显的四重(bcc-晶格)对称,伴随二次枝晶臂的发育。凝固路径为L→L+β(Ti)→β(Ti);糊状合金中未出现包晶β(Ti)→α(Ti) bcc-hcp相变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the Primary Phase Microstructure of Solidifying Ti-46Al-8Nb Refractory Intermetallic Alloy
The reported contradictory data on microstructure formation of the refractory intermetallic Ti-46Al-8Nb (at.%) alloy and on the high-temperature phase transformations proceeding within the Ti-Al-Nb phase diagram are ana- lysed and clarified experimentally. To determine the primary solidifying phase, a set of experiments is performed on melt- ing of the alloy specimens with low oxygen contamination in a high purity argon atmosphere using crucibles made of oxy- gen-free ceramics (99.99% AlN), and subsequent rapid solidification. Volumetrically-isothermal cooling from 1943 K at rates of 5, 10, and 20 K/s and following quench of mini-ingots from 1763 K are used. Specimens were studied by scanning electron microscopy (SEM) in backscattered electron (BSE) mode. SEM-BSE micrographs demonstrate contrasting shadow regions of non-uniform niobium segregation, which are fixed by quench and decorate the primary polycrystalline microstructure formed within the temperature range between 1843 (liquidus) and 1773 K (solidus). The primary crystalliz- ing phase is proven to be represented by β(Ti) dendrites, which have clearly pronounced fourfold (bcc-lattice) symmetry being formed with secondary dendrite arms development. The solidification path is shown to be described with single- phase scheme L→L+β(Ti)→β(Ti); no peritectic β(Ti)→α(Ti) bcc-hcp phase transformation revealed within the mushy state of alloy.
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