金属学报  1988, Vol. 24 Issue (4): 248-253

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亚稳β-Ti合金中TiC的析出特征

俞学节;汪建林;周天健

上海钢铁研究所;上海钢铁研究所;安徽工学院

PRECIPITATION OF TiC IN METASTABLE β-Ti ALLOY

YU Xuejie;WANG Jianlin;ZHOU Tianjian Shanghai Iron and Steel Research Institute; Anhui Institute of Technology

俞学节;汪建林;周天健. 亚稳β-Ti合金中TiC的析出特征[J]. 金属学报, 1988, 24(4): 248-253.
, , . PRECIPITATION OF TiC IN METASTABLE β-Ti ALLOY[J]. Acta Metall Sin, 1988, 24(4): 248-253.

摘要 参考文献 相关文章 Metrics 全文: PDF(2161 KB)   摘要: 本文研究了Ti-3.84Al-6.2Mo-10.43V-1.85Fe合金中TiC的析出行为.当合金经低于α+β→β转变温度加热淬火之后,在α/β相界面上存在TiC膜,其形貌与α-β双相合金中TiH_2界面相类似.TiC界面相提供了裂纹易扩展途径和裂纹萌生点.断口也与TiH_2界面相引起的相似.经β固溶处理后再等温时效,在有些试样的电子衍射花样中观察到了弧形衍射(2α相的特征衍射).根据合金成分和点阵常数分析,产生弧形衍射的质点可能是TiC,而非所谓的2α相. 关键词 ： 界面相,  亚稳β-Ti合金,  碳化钛     Abstract：The precipitation behaviour of TiC in the Ti-3.84Al-6.24Mo-10.43V-1.85Fe alloy has been investigated. TiC layer was found to exist at the α/βinterface boundaries in the sample solution treated just below β transus and quenched.The morphology of TiC is similar to that of the interface Phase (IFP) TiH_2 inthe α-β two phase alloy. The IFP TiC provides a site for crack initiation as wellas an easier path for crack propagation. The morphology of fracture surface is alsosimilar to that caused by TiH_2. Arch diffraction patterns were found in some speci-mens after solution treatment and isothermal aging. The structure and lattice para-meters were analyzed and it was shown that the particles which bring about thearch diffraction might be TiC, instead of the "type 2" α phase. Key words： interface phase    metastable β-Ti alloy    TiC 收稿日期: 1988-04-18      服务 把本文推荐给朋友 加入引用管理器 E-mail Alert RSS 作者相关文章 俞学节 汪建林 周天健 44.8K 链接本文: https://www.ams.org.cn/CN/      或      https://www.ams.org.cn/CN/Y1988/V24/I4/248 1 Rhodes C G, Williams J C. Metall Trans, 1975; 6A: 2103 2 Banerjee D. Metall Trans, 1982; 13A: 681 3 Hallam P, Hammond C. In: Kimura H, Izumi O eds., Titanium 80 Science and Technology, Vol. II, Proc 4th Int Conf on Titanium, Kyoto. Japan, 19-22． May, 1980, New York: TMS-AIME, 1980: 1435 4 Banerjee D, Rhodes C G, Williams J C. In: Lutjening G, Zwicker U, Bunk W eds., Titanium Science and Technology, Vol. 3, Proc 5th Int Conf on Titanium, Munich FRG: Deutsche Gesel fur Metall, 1985: 1597 5 Moody N R, Greulich F A, Robinson S L. Metall Trans, 1984; 15A: 1955 6 Morgan G C, Hammond C. In: Kimura H, Izumi O eds., Titanium' 80 Science and Technology, Vol. II, Proc 4th Int Conf on Titanium New York: TMA-AIME, 1980: 1443 7 俞学节.金属学报,1983;19:A391 8 Isaac G H. Hammond C. In: Lutjering G, Zwicker U. Bunk W eds., Titanium Science and Technology, Vol. 3, Proc 5th Int Conf on Titanium, Munich FRG: Deutsche Gesel fur Metall, 1985: 1605 9 Bowan A W, Stubbington C A. J Less-Common Met, 1970: 20: 367 10 Petrova L A, Dyomina E V. Khlomov V S. In: Williams J C. Belov A F eds., Titanium and Titanium Alloys, Scientific and Technological Aspects, New York: Plenum Press, 1982: 2217v [1] 刘洪喜; 王浪平; 王小峰; 黄; 磊; 汤宝寅 . TiC薄膜对轴承钢表面滚动接触疲劳寿命和力学性能的影响[J]. 金属学报, 2006, 42(11): 1197-1201 . [2] 匡同春; 白晓军; 成晓玲; 刘正义; 邱万奇; 薛新民 . 金刚石膜与硬质合金刀片间界面Co相的研究[J]. 金属学报, 1999, 35(6): 643-647 . [3] 严有为; 魏伯康; 傅正义; 林汉同; 袁润章 . 原位TiC颗粒增强铁基复合材料及其组织形成机理[J]. 金属学报, 1999, 35(10): 1117-1120 . Viewed Full text Abstract Cited   Shared      Discussed