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HomeMaterials Science ForumMaterials Science Forum Vol. 849Hot Compressive Deformation Behavior of TC4-DT...

Hot Compressive Deformation Behavior of TC4-DT Titanium Alloy

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Abstract:

Hot compressive experiments of TC4-DT titanium alloy were performed on Gleeble 3500 hot simulator. The influence of hot deformation parameters on high temperature deformation behaviors were investigated, including deformation temperature (938°C~1038°C), deformation degree and strain rate (0.01s^-1~10s^-1). The results indicated that the peak (σ_p) and steady-state flow stress (σ_s) of TC4-DT alloy decreased with the increase of deformation temperature under the same strain rate, especially under a high strain rate. The flow stress increased sharply then decreased and kept invariant finally with the increase of deformation degree. The flow stress increased with the strain rate increasing and exhibited different characteristics in different strain rate range. The optimum conditions obtained based on this investigation of TC4-DT alloy as follows: temperature was 938°C~1008°C, stain rate was 0.01s^-1~0.1s^-1.

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Periodical:

Materials Science Forum (Volume 849)

Pages:

332-339

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.849.332

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Online since:

March 2016

Authors:

Jing Li, Li Wei Zhu, Xin Nan Wang, Yue Fei, Guo Qiang Shang, Zhi Shou Zhu*

Keywords:

Deformation Degree, Deformation Temperature, Flow Stress, Strain Rate, TC4-DT Titanium Alloy

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© 2016 Trans Tech Publications Ltd. All Rights Reserved

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* - Corresponding Author

[1] YH Zhao, P Ge, YQ Zhao, GJ Yang, JH Wen, Hot deformation behavior of Ti-1300 alloy, Rare Metal Materials and Engineering. 38 (2009) 46-49.

[2] J Luo, MQ Li, H Li, WX Yu, High temperature deformation behavior of TC4 titanium alloy and its flows stress model, The Chinese Journal of Nonferrous Metals. 18 (2008) 1395-1401.

[3] LJ Huang, L Geng，AB Li, ZP Cui, HZ Li, GS Wang, Characteristics of hot compression behavior of Ti-6. 5Al-3. 5Mo-1. 5Zr-0. 3Si alloy with an equiaxed microstructure, Materials Science and Engineering A. 505 (2009) 136-143.

DOI: 10.1016/j.msea.2008.12.041

[4] G Wang, SX Hui, WJ Ye, XJ Mi, Hot compressive behavior of Ti-3. 0Al-3. 7Cr-2. 0Fe low cost titanium alloy, The Chinese Journal of Nonferrous Metals. 22 (2012) 2223-2229.

DOI: 10.1016/s1003-6326(11)61557-4

[5] C Wu, SQ Liu, DL Oyang, Effect of strain rate on dynamic recrystallization microstructures of β hot process for TAl5 titanium alloy, Journal of plasticity engineering. 16 (2008) 167-170.

[6] XF Cui, XJ Mi, Z Luo, HM Tao, CG Lin, Effects of Cr Content on the Hot Compression Deformation Behavior of Ti-5Mo-5V-3Al-xCr Alloys, Journal of Materials Engineering and Performance. 24 (2015) 67-79.

DOI: 10.1007/s11665-014-1256-5

[7] A. Momeni1, S. Kazemi, G. Ebrahimi, A. Maldar, Dynamic recrystallization and precipitation in high manganese austenitic stainless steel during hot compression, International Journal of Minerals, Metallurgy and Materials. 21 (2014) 36-45.

DOI: 10.1007/s12613-014-0862-4

[8] BP Mao, SL Guo, J Shen, Study on Hot Deformation Behavior of Ti-5523 Titanium Alloy, Chinese Journal of Rare Metals. 32 (2008) 674-678.

[9] KL Wang, SQ Lu, X Li, XJ Dong, Effect of Strain Rate on Deformation Behavior in α+β Phase Field of Titanium Alloy TC11, Material & Heat Treatment. 38 (2008) 13-16.

[10] Z Tang, H Yang, ZC Sun, ZY Li, H Duan, Microstructure evolution and numerical simulation of TAl5 titanium alloy during hot compressive deformation, The Chinese Journal of Nonferrous Metals. 18 (2008) 722-727.

[11] M Dang, GX Qi, LK Shi, Analyse on Microstructure Evolution of TAll Titanium Alloy During Hot Compressive Deformation, Material & Heat Treatment. (2010) 44-46.

[12] S.M. Nie, Journal of Plasticity Engineering. 12 (2005) 85-88.

[13] S.M. Nie, Machinist Metal Forming, (2008) 22-25.

[14] HJ Peng, DF Li, QM Li, SL Guo, XJ Xu, J Hu, Effect of Deformation Conditions on the Dynamic Recrystallization of GH690 Alloy, Rare Metal Materials and Engineering. 41 (2012) 1317-1322.

DOI: 10.1016/s1875-5372(12)60061-7

[15] XF Cui. XJ Mi, CG Lin, SX Hui, Research on Hot Compressive Behavior of Ti-5Mo-5V-1Cr-3A1 Alloy, Journal of Materials Engineering. 12 (2013) 19-26.

[16] GD Xu, Hot Compressive characters of TAl5 titanium alloy, Acta Metallurgica Sinica. 38(2002) 230-232.

[17] PP Yao, P Li, CM Li, CM Xue, GM Xue, Hot Deformation Behavior and Processing Map of TAl5 Titanium Alloy Based on Friction Correction, Journal of Netshape Forming Engineering. 6 (2014) 46-51.