Hot Deformation Behavior and Dynamic Recrystallization of GH4151 Superalloy

被引：1

作者：

Sun Y. ^{[1
]}

Niu W. ^{[1
]}

Zhang M. ^{[1
]}

机构：

[1] School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2024年 / 60卷 / 08期

关键词：

constitutive equation; dynamic recrystallization; GH4151 nickel-based superalloy; hot compression deformation; hot processing map;

D O I：

10.3901/JME.2024.08.143

中图分类号：

学科分类号：

摘要：

The effect of deformation temperature on microstructure evolution and dynamic recrystallization of wrought GH4151 alloy was studied by MTS810-25T low cycle fatigue testing machine at different deformation temperatures. The results show that the peak stress in the true stress-strain curve of GH4151 alloy increases with the decrease of deformation temperature and the increase of strain rate. Based on the true stress-strain curve, the Arrhenious constitutive equation of wrought GH4151 alloy is obtained by linear fitting, which can well describe the hot compression deformation law of wrought GH4151 alloy and obtain the activation energy of hot deformation Q=218.09 kJ/mol. Microstructure analysis shows that the continuous dynamic recrystallization induced by γ' phase and discontinuous dynamic recrystallization with bulging of the original grain boundaries are mainly when in the low temperature. With the increase of deformation temperature, the dynamic recrystallization nucleation is dominated by discontinuous dynamic recrystallization and continuous dynamic recrystallization characterized by subcrystalline rotational polymerization. © 2024 Chinese Mechanical Engineering Society. All rights reserved.

引用

页码：143 / 153

页数：10

共 30 条

[1] ZHAO Rongguo, LI Hongchao, JIANG Yongzhou, Et al., Research on fatigue crack initiation and short crack propagation of GH4133B superalloy used in turbine disk of aero-engine[J], Journal of Mechanical Engineering, 49, 10, pp. 116-126, (2013)
[2] MARCHIONNI M, OSINKOLU G A, ONOFRIO G., High temperature low cycle fatigue behaviour of Udimet 720Li superalloy[J], International Journal of Fatigue, 24, pp. 1261-1267, (2002)
[3] GUO Jing, NIU Wenlong, MA Siwen, Et al., Dynamic recrystallization model analysis of new type high quality GH738 alloy during its hot deformation processes[J], Journal of Mechanical Engineering, 58, 10, pp. 59-67, (2022)
[4] XU Zhiqiang, YANG Shufeng, ZHAO Peng, Et al., Phase precipitation and segregation behavior of nickel-based superalloy GH4151[J], Journal of Iron and Steel Research, 34, 6, pp. 588-595, (2022)
[5] Xinxu LI, Chonglin JIA, ZHANG Yong, Et al., Cracking mechanism in as-cast GH4151 superalloy ingot with high γ′ phase content[J], Transactions of Nonferrous Metals Society of China, 30, 10, pp. 2697-2708, (2020)
[6] Xinxu LI, Chonglin JIA, ZHANG Yong, Et al., Segregation and homogenization for a new nickel-based superalloy[J], Vacuum, 177, pp. 109-379, (2020)
[7] Shaomin LU, Chonglin JIA, Xinbo HE, Et al., Superplastic deformation and dynamic recrystallization of a novel disc superalloy GH4151[J], Materials, 12, 22, pp. 36-67, (2019)
[8] LI Shaoqiang, GONG Zhanpeng, LI Hui, Et al., High temperature deformation behavior and dynamic recrystallization mechanism of TB18 Titanium Alloy [J], Rare Metal Materials and Engineering, 49, 9, pp. 3045-3051, (2020)
[9] HUANG K, LOGE R E., A review of dynamic recrystallization phenomena in metallic materials[J], Materials and Design, 111, 5, pp. 548-574, (2016)
[10] SELLARS C M, MCTEGART W J., On the mechanism of hot deformation[J], Acta Metallurgica, 14, 9, pp. 1136-1138, (1966)

← 1 2 3 →