Prediction model for flow stress during isothermal compression in α+β phase field of TC4 alloy

被引:8
作者
Shun Yang
Hong Li
Jiao Luo
Yin-Gang Liu
Miao-Quan Li
机构
[1] SchoolofMaterialsScienceandEngineering,NorthwesternPolytechnicalUniversity
来源
Rare Metals | 2018年 / 37卷 / 05期
关键词
TC4; alloy; Isothermal compression; Model; Flow stress;
D O I
暂无
中图分类号
TG146.23 [];
学科分类号
080502 ;
摘要
Isothermal compression of TC4 alloy was performed on a Thermecmaster-Z simulator at the deformation temperatures ranging from 1093 to 1243 K, the strain rates ranging from 0.001 to 10.000 s-1 and a maximum strain of0.8. The experimental results show that the flow stress increases with the decrease in the deformation temperature and the increase in the strain rate. The apparent activation energy for deformation is much lower at lower strain rates than that at higher strain rates. The flow stress model considering strain compensation was established. The average relative error between the calculated flow stress and experimental results is about 7.69%, indicating that the present model could be used to accurately predict the flow stress during high temperature in α+β phase field of TC4 alloy.
引用
收藏
页码:369 / 375
页数:7
相关论文
共 29 条
[1]  
Deformation resistance of Fe-Mn-V-N alloy under different deformation processes[J]. Yun-Li Feng,Jie Li,Li-Qun Ai,Bao-Mei Duan.Rare Metals. 2017(10)
[2]  
Hot deformation behavior and microstructural evolution of powder metallurgical TiAl alloy[J]. Na Liu,Zhou Li,Wen-Yong Xu,Yue Wang,Guo-Qing Zhang,Hua Yuan.Rare Metals. 2017(04)
[3]   Hot deformation behavior and microstructure evolution of a Mg–Gd–Nd–Y–Zn alloy [J].
Xiu-Li Hou ;
Yan Li ;
Peng Lv ;
Jie Cai ;
Le Ji ;
Qing-Feng Guan .
Rare Metals, 2016, 35 (07) :532-536
[4]  
A modified constitutive model based on Arrhenius-type equation to predict the flow behavior of Fe–36%Ni Invar alloy[J] . Shuai He,Chang-sheng Li,Zhen-yi Huang,Jian-jun Zheng.Journal of Materials Research . 2017 (20)
[5]   Constitutive Modeling of Warm Deformation Flow Curves of an Eutectoid Steel [J].
Rastegari, H. ;
Rakhshkhorshid, M. ;
Somani, M. C. ;
Porter, D. A. .
JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE, 2017, 26 (05) :2170-2178
[6]  
Characterization of the hot deformation behavior and microstructural evolution of Ti–6Al–4V sintered preforms using materials modeling techniques[J] . Youngmoo Kim,Young-Beom Song,Sung Ho Lee,Young-sam Kwon.Journal of Alloys and Compounds . 2016
[7]  
Temperature dependent work hardening in Ti–6Al–4V alloy over large temperature and strain rate ranges: Experiments and constitutive modeling[J] . Guang Chen,Chengzu Ren,Xuda Qin,Jun Li.Materials & Design . 2015
[8]  
A comparative study on Johnson–Cook constitutive modeling for Ti–6Al–4V alloy using automated ball indentation (ABI) technique[J] . Fuzeng Wang,Jun Zhao,Ningbo Zhu,Zuoli Li.Journal of Alloys and Compounds . 2015
[9]   A Modified Johnson-Cook Constitutive Equation to Predict Hot Deformation Behavior of Ti-6Al-4V Alloy [J].
Cai, Jun ;
Wang, Kuaishe ;
Zhai, Peng ;
Li, Fuguo ;
Yang, Jie .
JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE, 2015, 24 (01) :32-44
[10]  
Deformation behavior in the isothermal compression of Ti–5Al–5Mo–5V–1Cr–1Fe alloy[J] . S.F. Liu,M.Q. Li,J. Luo,Z. Yang.Materials Science & Engineering A . 2014
123