Ti–Zr–Cu–Ni–Be非晶合金箔钎焊等温凝固钛合金接头的组织形成和力学性能

IF 1.5 Q3 Materials Science

Nonferrous Metals Pub Date : 2020-12-29 DOI:10.17580/NFM.2020.02.08

P. Morokhov, A. Ivannikov, N. Popov, O. Sevryukov

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引用次数: 1

摘要

采用瞬态液相(TLP)钎焊方法，对伪α和α + β结构的OT4和VT6-c两种钛合金进行了钎焊。采用Ti - 12Zr - 22Cu - 12Ni - 1.5 Be - 0.8V wt.%的非晶箔制备高强度接头。通过组织研究和双组分相图和三组分相图分析，阐述了OT4和VT6-c钛合金钎焊焊缝组织演变的机理。在800°C下钎焊0.5 h，形成由Widmanstätten、共晶和共晶组成的非均相结构。在中心存在共晶层的钎焊OT4和VT6-c接头力学性能较低;其极限强度在200 ~ 550mpa之间。将钎焊温度提高到840℃，暴露时间提高到2h，可使焊缝中的脆性共晶成分消失。这种结构通常由Widmanstätten和少量共析组分组成。在钎焊缝中没有共晶层的接头显示出与基体钛合金相同的强度。在这种情况下，失效发生在母材上。o4合金钎焊试样的抗拉强度值为σb = 750±3 MPa, VT6-c合金试样的抗拉强度值为σb = 905±3 MPa。这项工作得到了联邦高等教育自治教育机构国家研究核大学MEPhI(莫斯科工程物理研究所)竞争力增长计划的支持。

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Microstructure formation and mechanical properties of isothermally-solidified titanium alloy joints brazed by a Ti – Zr – Cu – Ni – Be amorphous alloy foil

Two titanium alloys, OT4 and VT6-c, with a pseudo-α and α + β structure, respectively, were brazed using transient liquid phase (TLP) bonding. To obtain high strength joints an amorphous foil (Ti – 12Zr – 22Cu – 12Ni – 1.5 Be – 0.8V wt.%) was used. Based on microstructural studies and analysis of two- and three-component phase diagrams, the mechanism of the microstructural evolution of the brazed seams of titanium alloys OT4 and VT6-c is described. Brazing at 800 °C with exposure for 0.5 h leads to the formation of a heterogeneous structure consisting of Widmanstätten, eutectoid, and eutectic. Brazed OT4 and VT6-c joints with the presence of a eutectic layer in the centre show low mechanical properties; their ultimate strength lies in a range from 200 to 550 MPa. Increasing the brazing temperature to 840 °C and the exposure time to 2 h, leads to the disappearance of the brittle eutectic component from the seam. This structure typically consists of Widmanstätten with a small number of eutectoid fractions. Joints with the absence of a eutectic layer in the brazed seam demonstrate a strength equal to the base titanium alloys. In this case, failure occurs in the base metal. For brazed samples from the OT4 alloy, the tensile strength value is σb = 750 ± 3 MPa, and for samples from VT6-c, σb = 905 ± 3 MPa. This work was supported by Competitiveness Growth Programme of the Federal Autonomous Educational Institution of Higher Education National Research Nuclear University MEPhI (Moscow Engineering Physics Institute).

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来源期刊

Nonferrous Metals METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

1.50

自引率

0.00%

发文量

期刊介绍： Its thematic plan covers all directions of scientific and technical development in non-ferrous metallurgy. The main journal sections include scientific-technical papers on heavy and light non-ferrous metals, noble metals and alloys, rare and rare earth metals, carbon materials, composites and multi-functional coatings, radioactive elements, nanostructured metals and materials, metal forming, automation etc. Theoretical and practical problems of ore mining and mineral processing, production and processing of non-ferrous metals, complex usage of ores, economics and production management, automation of metallurgical processes are widely observed in this journal. "Non-ferrous Metals" journal publishes the papers of well-known scientists and leading metallurgists, elucidates important scientific-technical problems of development of concentrating and metallurgical enterprises, scientific-research institutes and universities in the field of non-ferrous metallurgy, presents new scientific directions and technical innovations in this area. The readers can find in this journal both the articles with applied investigations and with results of fundamental researches that make the base for new technical developments. Publishing according to the approach APC (Article processing charge).