The Dislocation Sub-structure Evolution during Hot Compressive Deformation of Ti-6Al-2Zr-1Mo-1V Alloy at 800℃

The Dislocation Sub-structure Evolution during Hot Compressive Deformation of Ti-6Al-2Zr-1Mo-1V Alloy at 800℃

下载PDF

导出

摘要 Hot compressive behaviors of Ti-6Al-2Zr-1Mo-1V alloy at 800℃, as well as the evolution of microstructure during deformation process, were investigated. The experimental results show that flow stress increases to a peak stress followed by a decease with increasing strain, and finally forms a stable stage. Dislocations are generated at the interface of αβ phase, and the phase interface and dislocation loops play an important role in impeding the movement of dislocation. As strain increasing, micro-deformation bands with high-density dislocation are formed, and dynamic recrystallizaton occurs finally. XRD Fourier analysis reveals that dislocation density increases followed by a decrease during compressive deformation, and falls into the range from 10^10 to 10^11 cm^-2. Hot compressive behaviors of Ti-6Al-2Zr-1Mo-1V alloy at 800℃, as well as the evolution of microstructure during deformation process, were investigated. The experimental results show that flow stress increases to a peak stress followed by a decease with increasing strain, and finally forms a stable stage. Dislocations are generated at the interface of αβ phase, and the phase interface and dislocation loops play an important role in impeding the movement of dislocation. As strain increasing, micro-deformation bands with high-density dislocation are formed, and dynamic recrystallizaton occurs finally. XRD Fourier analysis reveals that dislocation density increases followed by a decrease during compressive deformation, and falls into the range from 10^10 to 10^11 cm^-2.

作者刘勇

机构地区 School of Materials Science and Engineering

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2009年第2期202-205,共4页 武汉理工大学学报（材料科学英文版）

关键词 Ti-6Al-2Zr-IMo-1V alloy hot compressive deformation behavior dislocation sub-structure evolution Ti-6Al-2Zr-IMo-1V alloy hot compressive deformation behavior dislocation sub-structure evolution

分类号 TG146.23 [金属学及工艺—金属材料]

引文网络
相关文献

参考文献1

1徐文臣,单德彬,李春峰,吕炎.TA15钛合金的动态热压缩行为及其机理研究[J].航空材料学报,2005,25(4):10-15. 被引量：71

二级参考文献16

1王桂生.Ti－6Al－2Zr－1Mo－1V合金组织与性能的研究[J].稀有金属,1995,19(5):352-356. 被引量：10
2曾卫东,胡鲜红,俞汉清,周义刚.Ti─17合金高温变形机理研究[J].材料工程,1996,24(9):27-30. 被引量：26
3PU Z J,WU K H,SHI J.Development of constitutive relationships for the hot deformation of boron microalloying TiAl-Cr-V alloys[J].Materials Science and Engineering,1995,A192/193: 780-787.
4RAO K P,HAWBOLT E B.Development of constitutive relationships using compression testing of a medium carbon steel[J].Journal of Engineering Materials and Technology,1992,114(1):116-123.
5MEDINA S F,HERNADEZ C A.General expression of Zener-Hollomon parameter as a function of chemical composition of low alloy and microalloyed steels[J].Acta Materialia, 1996,44(1): 137-146.
6PRASAD Y V R K, SESHACHARYULU T. Modelling of hot deformation for microstructural control[J]. International Materials Reviews, 1998, 43(6): 243-258.
7HUANG C,DEAN T A.Flow behavior and microstructure development of forged Ti-25Al-10Nb-3V-1Mo(super α2)[J].Materials Science and Engineering,1995,A191: 39-47.
8LIU Y,BAKER T N.Deformation characteristics of IMI685 titanium alloy under βisothermal forging condition[J].Materials Science and Engineering,1995,A197:125-131.
9ROBERTSON D G,MCSHANE H B.Analysis of high temperature flow stress of titanium alloys IMI550 and Ti-10V-2Fe-3Al during isothermal forging[J].Materials Science and Technology,1998,14:339-345.
10ZHANG W J,APPEL F.Effect of Al content and Nb addition on the strength and fault energy of TiAl alloys[J].Materials Science and Engineering,2002,A329-331:649-652.

共引文献70

1姚彭彭,李萍,李成铭,薛传妹,甘国强,薛克敏.TA15钛合金在相变点附近的热变形机制及组织演化[J].稀有金属与硬质合金,2015,43(1):46-52. 被引量：2
2王洋,尤逢海,朱景川,来忠红,刘勇.TA15合金热变形行为研究[J].机械工程材料,2006,30(11):63-65. 被引量：34
3王明伟,张立文,裴继斌,戚琳,张凡云,李辰辉.温度对BT20合金筒形件真空热胀形影响模拟研究[J].材料热处理学报,2007,28(2):141-144. 被引量：4
4范定兵,王高潮,赵晓宾.Ti-15-3超塑性研究[J].南昌航空工业学院学报,2007,21(1):26-29. 被引量：5
5吴立鸿,王利国,关绍康,刘俊,陈永.镁合金热变形抗力模型的构建技术[J].锻压技术,2007,32(4):7-11. 被引量：2
6范定兵,王高潮,赵晓宾,耿启冬.Ti-15-3钛合金应变速率循环超塑性研究[J].热加工工艺,2007,36(21):8-10. 被引量：2
7沈昌武,杨合,孙志超,崔军辉.基于BP神经网络的TA15钛合金本构关系建立[J].塑性工程学报,2007,14(4):101-104. 被引量：26
8杜宇,刘伟,戚运莲,赵永庆,罗媛媛,洪权.Ti-26钛合金热变形特征研究[J].稀有金属快报,2007,26(12):29-33. 被引量：4
9唐泽,杨合,孙志超,李志燕,段桦.TA15钛合金高温变形微观组织演变分析与数值模拟[J].中国有色金属学报,2008,18(4):722-727. 被引量：29
10孙志超,杨合,沈昌武.基于逐步回归法的TA15钛合金本构模型的建立[J].锻压技术,2008,33(2):110-115. 被引量：9

1潘健生,胡明娟,张伟民,阮冬,田东.我国热处理计算机模拟研究与应用的进展[J].热处理,1999,53(1):1-8. 被引量：9
2刘勇.Effects of Strain Rate on Dislocation for TA15 Alloy during Hot Compressive Deformation[J].Journal of Wuhan University of Technology(Materials Science),2011,26(2):187-190.
3王玉田.用水平仪测量小台面对竖直轴线垂直度的方法[J].机械工程师,2014(1):170-171.
4孙文文,谢华锟.基于Fourier分析的齿轮整体误差曲线的重构方法及其应用[J].工具技术,2006,40(8):63-65.
5WANG Jing-wen,WANG Xiong-wen.Analysis of High Temperature Deformed Structure and Dynamic Precipitation in W9Mo3Cr4V Steel[J].Journal of Iron and Steel Research International,2001,8(1):41-44.
6任晓兵,王笑天,清水谦一,唯木次男.Fe－1．83C马氏体调幅分解的TEM研究[J].金属学报,1994,30(7). 被引量：3
7汪凌云,HUANG,Guangsheng,等.Investigation on hot deformation behavior of AZ31 magnesium alloy[J].Journal of Chongqing University,2002,1(2):57-59. 被引量：1
8LI Xia,WU Xiao-chun,ZHANG Xiao-xun,LI Ming-yao.Dynamic Recrystallization of Hot Deformed 3Cr2NiMnMo Steel:Modeling and Numerical Simulation[J].Journal of Iron and Steel Research International,2013,20(11):98-104. 被引量：1
9杨传铮,张建.X射线衍射研究纳米材料微结构的一些进展[J].物理学进展,2008,28(3):280-313. 被引量：10
10Tingting Zheng,Dejiang Li,Xiaoqin Zeng,Wenjiang Ding.Hot compressive deformation behaviors of Mg–10Gd–3Y–0.5Zr alloy[J].Progress in Natural Science:Materials International,2016,26(1):78-84. 被引量：2

Journal of Wuhan University of Technology(Materials Science)

2009年第2期

浏览历史

内容加载中请稍等...

The Dislocation Sub-structure Evolution during Hot Compressive Deformation of Ti-6Al-2Zr-1Mo-1V Alloy at 800℃

参考文献1

二级参考文献16

共引文献70

相关作者

相关机构

相关主题

浏览历史