Microstructure Evolution in the Mushy Zone of a β-Solidifying TiAl Alloy under Different Cooling Processes

Jieren Yang; Bao Xiao; Peng Han; Hongchao Kou; Jinshan Li

doi:10.1002/adem.201600144

Microstructure Evolution in the Mushy Zone of a β-Solidifying TiAl Alloy under Different Cooling Processes

Jieren Yang
, Bao Xiao
, Peng Han
, Hongchao Kou
, Jinshan Li

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

A novel method termed mushy zone cooling control is applied to tailor the microstructure of a β-solidifying titanium aluminide alloy in this study. Ti-44.5Al–4Nb–2Cr–0.1B (at%) alloy is subjected to temperature-controlled cooling through the mushy zone by different processes. The solidified microstructure consists of α₂/γ lamellar colony, B2 phase, and massive γ. It is found that both the fast cooling and the thermal cycling can play a role in refining α₂/γ lamellar colonies and in reducing B2 phase, which is brittle at room temperature. α₂/γ colonies with an average size of 28 µm are obtained after 10 thermal cycles. The results also show that solidification microsegregation can be largely eliminated by fast cooling. However, α₂/γ colonies will continuously coarsen during such an isothermal holding process.

Original language	English
Pages (from-to)	1667-1673
Number of pages	7
Journal	Advanced Engineering Materials
Volume	18
Issue number	9
DOIs	https://doi.org/10.1002/adem.201600144
State	Published - 1 Sep 2016

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title = "Microstructure Evolution in the Mushy Zone of a β-Solidifying TiAl Alloy under Different Cooling Processes",

abstract = "A novel method termed mushy zone cooling control is applied to tailor the microstructure of a β-solidifying titanium aluminide alloy in this study. Ti-44.5Al–4Nb–2Cr–0.1B (at\%) alloy is subjected to temperature-controlled cooling through the mushy zone by different processes. The solidified microstructure consists of α2/γ lamellar colony, B2 phase, and massive γ. It is found that both the fast cooling and the thermal cycling can play a role in refining α2/γ lamellar colonies and in reducing B2 phase, which is brittle at room temperature. α2/γ colonies with an average size of 28 µm are obtained after 10 thermal cycles. The results also show that solidification microsegregation can be largely eliminated by fast cooling. However, α2/γ colonies will continuously coarsen during such an isothermal holding process.",

author = "Jieren Yang and Bao Xiao and Peng Han and Hongchao Kou and Jinshan Li",

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T1 - Microstructure Evolution in the Mushy Zone of a β-Solidifying TiAl Alloy under Different Cooling Processes

AU - Yang, Jieren

AU - Xiao, Bao

AU - Han, Peng

AU - Kou, Hongchao

AU - Li, Jinshan

PY - 2016/9/1

Y1 - 2016/9/1

N2 - A novel method termed mushy zone cooling control is applied to tailor the microstructure of a β-solidifying titanium aluminide alloy in this study. Ti-44.5Al–4Nb–2Cr–0.1B (at%) alloy is subjected to temperature-controlled cooling through the mushy zone by different processes. The solidified microstructure consists of α2/γ lamellar colony, B2 phase, and massive γ. It is found that both the fast cooling and the thermal cycling can play a role in refining α2/γ lamellar colonies and in reducing B2 phase, which is brittle at room temperature. α2/γ colonies with an average size of 28 µm are obtained after 10 thermal cycles. The results also show that solidification microsegregation can be largely eliminated by fast cooling. However, α2/γ colonies will continuously coarsen during such an isothermal holding process.

AB - A novel method termed mushy zone cooling control is applied to tailor the microstructure of a β-solidifying titanium aluminide alloy in this study. Ti-44.5Al–4Nb–2Cr–0.1B (at%) alloy is subjected to temperature-controlled cooling through the mushy zone by different processes. The solidified microstructure consists of α2/γ lamellar colony, B2 phase, and massive γ. It is found that both the fast cooling and the thermal cycling can play a role in refining α2/γ lamellar colonies and in reducing B2 phase, which is brittle at room temperature. α2/γ colonies with an average size of 28 µm are obtained after 10 thermal cycles. The results also show that solidification microsegregation can be largely eliminated by fast cooling. However, α2/γ colonies will continuously coarsen during such an isothermal holding process.

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Microstructure Evolution in the Mushy Zone of a β-Solidifying TiAl Alloy under Different Cooling Processes

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