Phase-field simulation of formation of cellular dendrites and fine cellular structures at high growth velocities during directional solidification of Ti_(56) Al_(44) alloy 被引量：3

Phase-field simulation of formation of cellular dendrites and fine cellular structures at high growth velocities during directional solidification of Ti_(56) Al_(44) alloy

在线阅读下载PDF

导出

摘要 A phase-field model whose free energy of the solidification system derived from the Calphad thermodynamic modeling of phase diagram was used to simulate formation of cellular dendrites and fine cellular structures of Ti56Al44 alloy during directional solidification at high growth velocities. The liquid-solid phase transition of L→β was chosen. The dynamics of breakdown of initially planar interfaces into cellular dendrites and fine cellular structures were shown firstly at two growth velocities. Then the unidirectional free growths of two initial nucleations evolving to fine cellular dendrites were investigated. The tip splitting phenomenon is observed and the negative temperature gradient in the liquid represents its supercooling directional solidification. The simulation results show the realistic evolution of interfaces and microstructures and they agree with experimental one. A phase-field model whose free energy of the solidification system derived from the Calphad thermodynamic modeling of phase diagram was used to simulate formation of cellular dendrites and fine cellular structures of Ti_~56 Al_~44 alloy during directional solidification at high growth velocities. The liquid-solid phase transition of L→β was chosen. The dynamics of breakdown of initially planar interfaces into cellular dendrites and fine cellular structures were shown firstly at two growth velocities. Then the unidirectional free growths of two initial nucleations evolving to fine cellular dendrites were investigated. The tip splitting phenomenon is observed and the negative temperature gradient in the liquid represents its supercooling directional solidification. The simulation results show the realistic evolution of interfaces and microstructures and they agree with experimental one.

作者李新中郭景杰苏彦庆吴士平傅恒志

机构地区 School of Materials Science and Engineering

出处《中国有色金属学会会刊：英文版》 EI CSCD 2005年第3期529-535,共7页 Transactions of Nonferrous Metals Society of China

基金 Projects(50391012 50271020)supportedbytheNationalNaturalScienceFoundationofChina

关键词相-场仿真直接固化钛铝合金自由能 Calphad热力学模型 phase-field simulation directional solidification Ti_(56) Al_(44) alloy

分类号 TG111.4 [金属学及工艺—物理冶金]

引文网络
相关文献

参考文献18

1Wheeler A A, Boettinger W J, McFadden G B. Phasefield model for isothermal transition in binary alloys[J]. Phys Rev A, 1992, 45: 7424-7439.
2Warren J A, Boettinger W J. Prediction of dendritic growth and microsegregation patterns in a binary alloy using the phase-field method[J]. Acta Metall Mater,1995, 43: 689-703.
3Wheeler A A, Boettinger W J, McFadden G B. Phasefield model of solute trapping during solidification[J].Phys Rev E, 1993, 47:1893 - 1909.
4Ahmad N A, Wheeler A A, Boettinger W J, et al.Solute trapping and solute drag in a phase-field model of rapid solidification[J]. Phys Rev E, 1998, 58:3436 - 3450.
5Loginova I, Amberg G, Agren J. Phase-field simulation of non-isothermal binary alloy solidification [J].Acta Mater, 2001, 49 : 573 - 581.
6George W L, Warren J A. A parallel 3D dendritic growth simulator using the phase-field method[J].Journal of Computational Physics, 2002, 177:264 -283.
7Kim S G, Kim W T, Suzuki T. Phase-field model for binary alloys[J]. Phys Rev E, 1999, 60:7186 -7197.
8Suzuki T, Ode M, Kim S G, et al. Phase-field model of dendritic growth[J]. J Crystal Growth, 2002, 237:125 - 131.
9Boettinger W J, Warren J A. Simulation of the cell to plane front transition during directional solidification at high velocity [J]. J Cryst Growth, 1999, 200:583 -591.
10Zhang B, Sekerka R F. Phase field modeling of shallow cells during directional solidification of a binary alloy[J]. J Crystal Growth, 2002, 237: 138-143.

同被引文献25

1李新中,郭景杰,苏彦庆,刘畅,吴士平,傅恒志.金属熔体凝固微观组织模拟的相场方法研究[J].特种铸造及有色合金,2005,25(4):222-225. 被引量：4
2李新中,苏彦庆,郭景杰,吴士平,傅恒志.Ti-45%Al合金界面形态及微观结构演化的相场模拟[J].中南大学学报（自然科学版）,2006,37(5):856-861. 被引量：4
3王狂飞,米国发,历长云,郭景杰,傅恒志.Ti-Al合金定向凝固柱状/等轴晶转变的数值模拟[J].特种铸造及有色合金,2007,27(9):674-678. 被引量：7
4Jung J Y,Park J K,Chun C H. Influence of AI content on cast microstructures of Ti-AI intermetallic compounds [J]. Intermetallics, 1999(7) : 1033-1041.
5Sujata M, Sastry D H, Ramachandra C. Microstructural charac- terization and creep behaviour of as-cast titanium aluminide Ti48AI2V [J]. Intermetallics,2004,12:691-697.
6Wu S P,Liu D R,Guo J J,et al. Numerical simulation of mi- crostructure evolution of Ti-6A1-4V alloy in vertical centrifugal casting [J]. Materials Science and Engineering A,2006,426: 240-249.
7Liu D R,Guo J J,Wu S P,et al. Stochastic modeling of colum- nar-to-equiaxed transition in Ti- (45-48at%)Al alloy ingots [J]. Materials Science and Engineering A. 2006,415 : 184-194.
8王狂飞,郭景杰,米国发,李邦盛,傅恒志.Ti-45at.%Al合金定向凝固过程中显微组织演化的计算机模拟[J].物理学报,2008,57(5):3048-3058. 被引量：9
9王雅琴,王锦程,李俊杰.定向倾斜枝晶生长规律及竞争行为的相场法研究[J].物理学报,2012,61(11):503-509. 被引量：10
10王理林,王贤斌,王红艳,林鑫,黄卫东.晶体取向对定向凝固平界面失稳行为的影响[J].物理学报,2012,61(14):424-429. 被引量：5

引证文献3

1王狂飞,邓小玲,吴亚辉,历长云,米国发.TiAl合金常规条件下凝固组织模拟[J].热加工工艺,2015,44(3):94-96. 被引量：2
2杨帅,赵宇宏,陈伟鹏,董瑞峰,侯华.Ti-4.5Al合金定向凝固倾斜枝晶生长的相场法模拟[J].特种铸造及有色合金,2021,41(6):769-775. 被引量：1
3崔德旭,屈佳润,李思佳,王欣欣,张建宝,王海丰.固/液界面动力学的分子动力学模拟研究进展[J].中国有色金属学报,2025,35(1):1-17. 被引量：2

二级引证文献5

1刘唱畅,樊振中,殷亚军,周建新.基于华铸CAE的铝合金元胞自动机晶粒模拟研究[J].特种铸造及有色合金,2016,36(11):1147-1150.
2李涌泉,杜晓娟,周友世,赵淑明,申开卫.显微组织对TiAl合金抗热冲击性能的影响[J].热加工工艺,2017,46(10):57-59. 被引量：4
3董高高,王凯阳,吕少杰,潘昆明.基于相场模拟的Inconel 718合金定向凝固CET转变研究[J].特种铸造及有色合金,2024,44(3):323-327. 被引量：1
4张亨年,赵展,李澍,张涛,江河,姚志浩,董建新.大锭型GH4169合金铸锭真空感应熔炼凝固过程及缩孔控制[J].中国有色金属学报,2025,35(7):2287-2297.
5屈佳润,张建宝,崔德旭,王欣欣,李思佳,王海丰.快速凝固理论与技术研究进展[J].中国有色金属学报,2025,35(9):2861-2882.

1YAO Sheng-jie,DU Lin-xiu,LI Guang-long,JIAO Ring,WANG Guo-dong.Microstructure Evolving Behaviors of Undercooled Ultrafine Austenite Grains During Deformation[J].Journal of Iron and Steel Research International,2011,18(6):43-48. 被引量：1
2宋立国,李树索,郑运荣,韩雅芳.Effect of Yttrium on High Temperature Oxidation Resistance ofa Directionally Solidified Superalloy[J].Journal of Rare Earths,2004,22(6):794-798. 被引量：6
3刘畅,苏彦庆,毕维生,郭景杰,贾均,傅恒志.Phase and its morphologies of Ti-45%Al alloy directionally solidified at different growth rates[J].中国有色金属学会会刊：英文版,2005,15(2):286-290. 被引量：1
4Yong-sheng Kang,Yu-chun Jin,Yu-hong Zhao,Hua Hou,Li-wen Chen.Phase-field simulation of tip splitting in dendritic growth of Fe-C alloy[J].Journal of Iron and Steel Research International,2017,24(2):171-176. 被引量：3
5傅恒志,谢发勤.Solidification characteristics of near rapid and supercooling directional solidification[J].中国有色金属学会会刊：英文版,1999,9(4):659-667. 被引量：2
6常国威,袁军平,王自东,吴春京,王新华,胡汉起.Effect of electric current on stability of solidification interface morphology[J].中国有色金属学会会刊：英文版,2000,10(4):445-448. 被引量：1
7Mingtao WANG B.Y.Zong Gang WANG.A Phase-field Model to Simulate Recrystallization in an AZ31 Mg Alloy in Comparison of Experimental Data[J].Journal of Materials Science & Technology,2008,24(6):829-834. 被引量：2
8李新中,郭景杰,苏彦庆,吴士平,傅恒志.Phase-field simulation of dendritic growth for binary alloys with complicate solution models[J].中国有色金属学会会刊：英文版,2005,15(4):769-776. 被引量：2
9周滨,申昱,陈军,崔振山.Evolving Mechanism of Eutectic Carbide in As-cast AISI M2 High-speed Steel at Elevated Temperature[J].Journal of Shanghai Jiaotong university(Science),2010,15(4):463-471. 被引量：6
10Chang Guowei(常国威),Yuan Junping(袁军平),Wang Zidong(王自东),Wu Chunjing(吴春京),Hu Hanqi(胡汉起) Miao Zhimin(苗治民).Continuous unidirectional solidification of QAl9-4 Cu-Al alloy[J].中国有色金属学会会刊：英文版,1999,9(3):493-499. 被引量：8

中国有色金属学会会刊：英文版

2005年第3期

浏览历史

内容加载中请稍等...

Phase-field simulation of formation of cellular dendrites and fine cellular structures at high growth velocities during directional solidification of Ti_(56) Al_(44) alloy 被引量：3

参考文献18

同被引文献25

引证文献3

二级引证文献5

相关作者

相关机构

相关主题

浏览历史