Study on the Material Model and Hot Working Drawing of a New Type of High Temperature Titanium Alloy Ti-Al-Nb

Shuang Fang; Mincong Zhang; Qiuying Yu; Huaping Xiong

doi:10.1051/e3sconf/202129901010

All issues

Volume 299 (2021)

E3S Web Conf., 299 (2021) 01010

References

Open Access

Issue		E3S Web Conf. Volume 299, 2021 4^th Annual International Conference on Energy Development and Environmental Protection (EDEP 2021)


Article Number		01010
Number of page(s)		10
Section		Energy Science and Technology
DOI		https://doi.org/10.1051/e3sconf/202129901010
Published online		05 August 2021

Guo, J.T. Materials Science and Engineering for Superalloys-Superalloy materials and engineering applications[M]. Beijing: Science Press, 2007, 1–91. [Google Scholar]
Fecht, H., Furrer, D. Processing of Nickel-Base Superalloys for Turbine Engine Disc Applications [J]. Advanced Engineering Materials, 2000, 2: 777–787. [CrossRef] [Google Scholar]
Zhang L., Liu H.S., He X.B., Din R., Qu X.H., Qin M. L., Li Z., Zhang G.Q. Thermal evolution behavior of carbides and y' precipitates in FGH96 superalloypowder[J]. Materials Characterization, 2012, 67: 52–64. [CrossRef] [Google Scholar]
Sherby O. D., Wadsworth, J. Superplasticity—Recent advances and future directions [J]. Progress in Materials Science, 1989, 33: 169–221. [CrossRef] [Google Scholar]
Kaibyshev, O.A. Fundamental aspects of superplastic deformation[J]. Materials Science and Engineering A, 2002, 324: 96–102. [CrossRef] [Google Scholar]
Rabinovich M. K., Trifonov V.G. Dynamic grain growth during superplastic deformation [J]. ActaMaterialia, 1996, 44: 2073–2078. [Google Scholar]
Feltham P. Grain growth in metals[J]. ActaMetallurgica, 1957, 5: 97–105. [Google Scholar]
Bulatov V. V., Reed B. W., Kumar M. Grain boundary energy function for fccmetals[J]. ActaMaterialia, 2014, 65: 161–175. [Google Scholar]
Sallez N., Boulnat X., Borbely A., et. In situ characterization of microstructural instabilities: Recovery, recrystallization and abnormal growth in nanoreinforced steel powder[J]. ActaMaterialia, 2015, 87: 377–389. [Google Scholar]
Darnbrough J. E., Flewitt P.E.J. Growth of abnormal planar faceted grains in nanocrystalline nickel containing impurity sulphur [J]. ActaMaterialia, 2014, 79: 421–433. [Google Scholar]
Luan Z. J., Wang F., Yao D. W., Huang L. Y., Meng, L. Effect of interface energy on abnormal grain growth in pyrite films prepared by sol-gel method[J]. Materials Research Bulletin, 2011, 46: 1577–1581. [CrossRef] [Google Scholar]
Ma F., Zhang J. M., Xu, K.W. Surface-energy-driven abnormal grain growth in Cu and Ag films[J]. Applied Surface Science, 2005, 242: 55–61. [CrossRef] [Google Scholar]

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[1] Guo, J.T. Materials Science and Engineering for Superalloys-Superalloy materials and engineering applications[M]. Beijing: Science Press, 2007, 1–91. [Google Scholar]

[2] Fecht, H., Furrer, D. Processing of Nickel-Base Superalloys for Turbine Engine Disc Applications [J]. Advanced Engineering Materials, 2000, 2: 777–787. [CrossRef] [Google Scholar]

[3] Zhang L., Liu H.S., He X.B., Din R., Qu X.H., Qin M. L., Li Z., Zhang G.Q. Thermal evolution behavior of carbides and y' precipitates in FGH96 superalloypowder[J]. Materials Characterization, 2012, 67: 52–64. [CrossRef] [Google Scholar]

[4] Sherby O. D., Wadsworth, J. Superplasticity—Recent advances and future directions [J]. Progress in Materials Science, 1989, 33: 169–221. [CrossRef] [Google Scholar]

[5] Kaibyshev, O.A. Fundamental aspects of superplastic deformation[J]. Materials Science and Engineering A, 2002, 324: 96–102. [CrossRef] [Google Scholar]

[6] Rabinovich M. K., Trifonov V.G. Dynamic grain growth during superplastic deformation [J]. ActaMaterialia, 1996, 44: 2073–2078. [Google Scholar]

[7] Feltham P. Grain growth in metals[J]. ActaMetallurgica, 1957, 5: 97–105. [Google Scholar]

[8] Bulatov V. V., Reed B. W., Kumar M. Grain boundary energy function for fccmetals[J]. ActaMaterialia, 2014, 65: 161–175. [Google Scholar]

[9] Sallez N., Boulnat X., Borbely A., et. In situ characterization of microstructural instabilities: Recovery, recrystallization and abnormal growth in nanoreinforced steel powder[J]. ActaMaterialia, 2015, 87: 377–389. [Google Scholar]

[10] Darnbrough J. E., Flewitt P.E.J. Growth of abnormal planar faceted grains in nanocrystalline nickel containing impurity sulphur [J]. ActaMaterialia, 2014, 79: 421–433. [Google Scholar]

[11] Luan Z. J., Wang F., Yao D. W., Huang L. Y., Meng, L. Effect of interface energy on abnormal grain growth in pyrite films prepared by sol-gel method[J]. Materials Research Bulletin, 2011, 46: 1577–1581. [CrossRef] [Google Scholar]

[12] Ma F., Zhang J. M., Xu, K.W. Surface-energy-driven abnormal grain growth in Cu and Ag films[J]. Applied Surface Science, 2005, 242: 55–61. [CrossRef] [Google Scholar]