期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

应变路径对TiAl合金残余片层的影响

Influence of strain path on residual lamella of TiAl alloy
原文传递
导出
摘要 针对全片层组织TiAl合金开坯锻造后存在大量残余片层影响合金的塑性的问题,在TiAl合金(α+γ)相区进行等温压缩,研究了不同应变路径对TiAl合金残余片层的影响,压缩方向与锻造方向分别呈0°、45°和90°。结果表明:初始锻造组织由大量的残余片层和片层团间的再结晶晶粒构成。经过0°方向热变形后组织变得更加均匀,残余片层显著减少;45°方向压缩的试样组织均匀,残余片层基本全部分解;经过90°方向压缩,试样部分残余片层分解,变形后的残余片层界面与压缩方向呈90°。改变应变路径有利于残余片层的分解,45°方向压缩的试样流变软化程度最小,晶粒等轴度高,分解效果最好。 In view the problem of the plasticity of TiAl alloy with full lamella structure affected by a large number of residual lamella after bloom forging,the isothermal compression was carried out in TiAl alloy(α+γ)phase region,the influence of different strain paths on the residual lamella of TiAl alloy was studied.Compression directions and forging direction are 0°,45°and 90°,respectively.The results show that the initial forging structure consists of a large number of residual lamella and recrystallized grains between lamellar clusters.After hot deformation in 0°direction,the microstructure becomes more uniform and the residual lamella decreases significantly.The specimen compressed in 45°direction has uniform microstructure,and the residual lamella are basically decomposed.After compression in 90°direction,part of the residual lamella of sample is decomposed,and the deformed residual lamella interface is 90°to the compression direction.The change of strain path is beneficial to the decomposition of residual lamella.The sample compressed in 45°direction has the lowest rheological softening degree,high grain isometric degree and the best decomposition effect.
作者 李栋 朱彬 陈逸 程亮 LI Dong;ZHU Bin;CHEN Yi;CHENG Liang(School of Materials and Engineering,Jiangsu University of Technology,Changzhou 213001,China)
机构地区 江苏理工学院机械工程学院
出处 《塑性工程学报》 CAS CSCD 北大核心 2023年第9期173-179,共7页 Journal of Plasticity Engineering
基金 国家自然科学基金资助项目(51905233 5210130372) 江苏省研究生实践创新计划项目(XSJCX21-30)。
关键词 TIAL合金 应变路径 等温压缩 残余片层 TiAl alloy strain path isothermal compression residual lamella
分类号 TB125 [理学—工程力学]
  • 相关文献

参考文献1

二级参考文献10

  • 1SEMIATIN S L,SEETHARAMAN V,JAIN V K.Microstructure development during conventional and isothermal hot forging of a near-gamma titanium aluminide[J].Metall&Mater Trans A,1994,25(12):2753-2768.
  • 2LIU C T,SCHNEIBEL J H,MAZIASZ P J.Tensile properties and fracture toughness of TiAl alloys with controlled microstructures[J].Intermetallics,1996,4(6):429-440.
  • 3SEMIATIN S L.Wrought processing of ingot-metallurgy gamma TiAl alloys[A].KIM Y W,WAGNERRYAMAGUCHI M.Gamma Titanium Aluminides[C].Warrendale:TMS,1995.509-524.
  • 4FURRER D,HOFFMAN R R,KIM Y W.Fundamentals of gamma titanium aluminides[A].KIM Y W,WAGNER R,YAMAGUCHI M.Gamma Titanium Aluminides[C].Warrenda-le:TMS,1995.611-618.
  • 5KIM Y W.Strength and ductility in TiAl alloys[J].Intermetallics,1998,6(7):623-628.
  • 6SEMIATIN S L,CHESNUTT J C,AUSTIN C,et al.Processing of intermetallic alloys[A].NATHAL M V.Structural intermetallics[C].Warrendale:TMS,1997.263-276.
  • 7MARTIN P L,RHODES C G,MCQUAY P A.Thermomechanical processing effects on microstructure in alloys based on γ-TiAl[A].DAROLIA R,LEWANDOWSKI J J,LIU C T,et al.Structure Intermatallics[C].Warrendale:TMS,1993.177-186.
  • 8SEMIATIN S L,SEETHARAMAN V,WEISS I.Hot working of titanium alloys-an overview[A].WEISS I E,SRINIVASAN R,BANIA P J,et al.Advances in the Science and Technology of Titanium Alloy Processing[C].Warrendale:TMS,1997.3-73.
  • 9WURZWALLNER K,CLEMENS H,SCHRETTER P,et al.Forming of gamma-TiAl alloys[A].BAKER I,DAROLIA R,WHITTENBERGER J D,et al.High Temperature Ordered Intermatallics Alloys V[C].Pittsburgh:Materials Research Society,1993.867-872.
  • 10SETHARAMAN V,SEMIATIN S L.Plastic-flow and microstructure evolution during hot deformation of a gamma titanium aluminide alloy[J].Metall&Mater Trans A,1997,28(11):2309-2321.

共引文献1

塑性工程学报
2023年 第9期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部