Microstructure and Texture Evolution of Ti65 Alloy during Thermomechanical Processing

doi:10.1007/s40195-024-01779-w

Abstract

Abstract:

The initial microstructure of titanium alloy in the α + β phase region is pivotal in dictating the performance of the final products after thermomechanical processing. Microstructures and textures of three rods, each prepared through distinct pretreatments, were systematically analyzed. Morphological analysis reveals that while both thick α platelets and coarse prior β grains impede the spheroidization of lamellar structures, the influence of the former is more pronounced. Variations in α platelet thickness prior β grain size exhibit limited impact on the macro-texture type after deformation and annealing. The proportion of low-angle interfaces between the c-axis of the primary α phase and the < 110 > direction of the prior β grains was elevated in rods with thicker platelets compared to thinner ones.

Key words: Ti65 alloy, Thermomechanical processing, α platelet thickness, Prior β grain size, Microstructure evolution, Texture

Jian Zang, Jianrong Liu, Qingjiang Wang, Haibing Tan, Bohua Zhang, Xiaolin Dong, Zibo Zhao. Microstructure and Texture Evolution of Ti65 Alloy during Thermomechanical Processing[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(1): 107-120.

Figures/Tables 13

Fig. 1 Initial microstructure of a sample A, b sample B, and c sample C

Table 1 Microstructural characteristics of Ti65 alloy rods with different initial microstructures

Designation	β grain size (mm)	α platelet thickness (μm)
Sample A	2.50	1.5 ± 0.1
Sample B	1.34	9.7 ± 0.1
Sample C	1.41	1.4 ± 0.1

Fig. 2 Optical images of a sample A, b sample B, and c sample C after precision forging at 1005 °C

Fig. 3 TEM images of microstructure of a sample A, b sample B, and c sample C after precision forging at 1005 °C

Fig. 4 Microstructure of a sample A, b sample B, and c sample C after annealing at 1030 °C

Table 2 Microstructure characteristics of Ti65 alloy after annealing at 1030 °C for 2 h followed by air cooling for the three rods

Fig. 5 Pole figures of Ti65 samples a, c, e after forging deformation and b, d, f after subsequent annealing at 1030 °C. a, b corresponds to sample A, c, d corresponds to sample B, e, f corresponds to sample C

Fig. 6 IPFs and the corresponding PFs of the microstructure after annealing at 1030 °C for 2 h, air cooling, for sample A: a after annealing, b orientation of primary α phase in a, c secondary α phase in a, and d the reconstructed prior β grains. The color key is given by below PFs

Fig. 7 IPFs and the corresponding PFs of the microstructure after annealing at 1030 °C for 2 h, air cooling, for sample B: a after annealing, b orientation of primary α phase in a, c secondary α phase in a, and d the reconstructed prior β grains

Fig. 8 IPFs and the corresponding PFs of the microstructure after annealing at 1030 °C for 2 h, air cooling, for sample C: a after annealing, b orientation of primary α phase in a, c secondary α phase in a, and d the reconstructed prior β grains

Fig. 9 Tensile properties of three samples at a room temperature and b 650 °C

Fig. 10 Microstructure of the sample B after annealing: a 3-dimensional view in RD1, RD2, and AD orientation, b high magnification RD1-RD2 plane overview from blue dashed line in a, c high magnification RD1-AD plane overview from red dashed line in a

Fig. 11 Angle distribution between the c-axes of primary α grains and the <110> direction of neighboring β grains after annealing at 1030 °C for a sample A, b sample B, and c sample C

References 34

[1]	J.K. Fan, H.C. Kou, M.J. Lai, B. Tang, H. Chang, J.S. Li, Mater. Sci. Eng. A 584, 121 (2013)
[2]	J. Xie, M.J. Luo, K.K. Wu, L.F. Yang, D.H. Li, Int. J. Mach. Tools Manuf. 73, 25 (2013)
[3]	Y.F. Yang, M. Yan, S.D. Luo, G.B. Schaffer, M. Qian, J. Alloys Compd. 579, 553 (2013)
[4]	H.Y. Zheng, X. Gai, Y. Bai, W.T. Hou, S.J. Li, Y.L. Hao, R.D.K. Misra, R. Yang, Acta Metall. Sin. -Engl. Lett. 37, 159 (2024)
[5]	J.F. Sun, H.F. Lu, Z. Wang, K.Y. Luo, J.Z. Lu, Corros. Sci. 229, 111866 (2024)
[6]	Z.X. Zhang, J.K. Fan, R.F. Li, H.C. Kou, Z.Y. Chen, Q.J. Wang, H.L. Zhang, J. Wang, Q. Gao, J.S. Li, J. Mater. Sci. Technol. 75, 265 (2021)
[7]	Z.X. Zhang, J.K. Fan, Z.H. Wu, D. Zhao, Q. Gao, Q.B. Wang, Z.Y. Chen, B. Tang, H.C. Kou, J.S. Li, J. Alloy. Compd. 831, 154786 (2020)
[8]	D. Zhao, J.K. Fan, Z.X. Zhang, J. Wang, Q.J. Wang, Z.Y. Chen, B. Tang, H.C. Kou, J.S. Li, Trans. Nonferrous Met. Soc. China 33, 1098 (2023)
[9]	P. Zhu, S. Yang, Z.J. Gao, J.R. Liu, L. Zhou, J. Mater. Res. Technol. 29, 5271 (2024)
[10]	Y.X. An, Y.C. Deng, X.Y. Zhang, B.F. Wang, Mater. Sci. Eng. A 854, 143776 (2022)
[11]	H. Matsumoto, V. Velay, J. Alloy. Compd. 708, 404 (2017)
[12]	S. Zherebtsov, M. Murzinova, G. Salishchev, S.L. Semiatin, Acta Mater. 59, 4138 (2011)
[13]	M. Jackson, N.G. Jones, D. Dye, R.J. Dashwood, Mater. Sci. Eng. A 501, 248 (2009)
[14]	S.L. Semiatin, T.R. Bieler, Acta Mater. 49, 3565 (2001)
[15]	J. Zhao, K.H. Wang, L.X. Lv, G. Liu, Mater. Sci. Eng. A 840, 142932 (2022)
[16]	S.H. Chen, M.C. Zhang, M.L. Jia, W. Li, J. Mater. Process. Technol. 252, 148 (2018)
[17]	Y.M. Cui, W.W. Zheng, C.H. Li, G.H. Cao, Y.D. Wang, Rare Metals 40, 3608 (2021)
[18]	N. Stefansson, S.L. Semiatin, D. Eylon, Metall. Mater. Trans. A 33, 3527 (2002)
[19]	G.H. Zhang, Z.W. Hao, M. Wang, X.F. Lu, Z. Zhao, Q. Wang, X. Lin, J. Chen, W.D. Huang, Acta Metall. Sin. -Engl. Lett. 36, 937 (2023)
[20]	S.K. Yeshanew, C.G. Bai, Q. Jia, T. Xi, Z.Q. Zhang, D.F. Li, Z.Z. Xia, R. Yang, K. Yang, Acta Metall. Sin. -Engl. Lett. 36, 1261 (2023)
[21]	X.Q. Liu, X.G. Qiao, W.C. Xie, R.S. Pei, L. Yuan, M.Y. Zheng, Mater. Sci. Eng. A 839, 142847 (2022)
[22]	L.B. Zhou, X.S. Bi, J.S. Sun, Z.M. Hu, C. Li, J. Chen, Y.J. Ren, Y. Niu, W. Qiu, W. Chen, Acta Metall. Sin. -Engl. Lett. 36, 1947 ( (2023)
[23]	S.X. Qiu, W.Y. Wang, S.H. Chen, R. Zhang, C.G. Chen, W.J. Zhang, F. Yang, Z.M. Guo, J. Alloy. Compd. 994, 174771 (2024)
[24]	N. Stefansson, S.L. Semiatin, Metall. Mater. Trans. A 34, 691 (2003)
[25]	M.G. Glavicic, B.B. Bartha, S.K. Jha, C.J. Szczepanski, Mater. Sci. Eng. A 513, 325 (2009)
[26]	J.J. Li, C.W. Guo, Y. Ma, Z.J. Wang, J.C. Wang, Acta Mater. 90, 10 (2015)
[27]	A. Marchal, B. Vergnes, A. Poulesquen, R. Valette, J. Non-Newton, Fluid. Mech. 231, 49 (2016)
[28]	A. Spettl, T. Werz, C.E. Krill, V. Schmidt, J. Comp. Mater. Sci. 124, 290 (2016)
[29]	Q. Zheng, W.X. Yao, L.C. Lim, Int. J. Refrac. Metal. Hard. Mater. 58, 1 (2016)
[30]	T. Furuhara, B. Poorganji, H. Abe, T. Maki, Metal. Mater. Soc. 59, 64 (2007)
[31]	B. Poorganji, M. Yamaguchi, Y. Itsumi, K. Matsumoto, T. Tanaka, Y. Asa, G. Miyamoto, T. Furuhara, Scr. Mater. 61, 419 (2009)
[32]	S. Roy, S. Suwas, S. Tamirisakandala, R. Srinivasan, D.B. Miracle, Mater. Sci. Eng. A 540, 152 (2012)
[33]	J. Gupta, I.K. Jha, R.K. Khatirkar, J. Singh, J. Alloy. Compd. 1004, 175803 (2024)
[34]	L. Germain, N. Gey, M. Humbert, P. Vo, M. Jahazi, P. Bocher, Acta Mater. 56, 4298 (2008)