PHASE SELECTION AND THE SOLIDIFICATION CHARACTERISTICS OF TiAl BASE ALLOYS IN THE NONEQUILIBRIUM SOLIDIFICATION

doi:10.3724/SP.J.1037.2013.00441

Acta Metall Sin

2013, Vol. 49

Issue (11): 1295-1302 DOI: 10.3724/SP.J.1037.2013.00441

Current Issue | Archive | Adv Search

PHASE SELECTION AND THE SOLIDIFICATION CHARACTERISTICS OF TiAl BASE ALLOYS IN THE NONEQUILIBRIUM SOLIDIFICATION

HU Rui, LIU Yi, ZHANG Tiebang, KOU Hongchao, LI Jinshan

State Key Laboratory of Solidification Processing, NorthwesternPolytechnical University, Xi'an 710072

Cite this article:

HU Rui, LIU Yi, ZHANG Tiebang, KOU Hongchao, LI Jinshan. PHASE SELECTION AND THE SOLIDIFICATION CHARACTERISTICS OF TiAl BASE ALLOYS IN THE NONEQUILIBRIUM SOLIDIFICATION. Acta Metall Sin, 2013, 49(11): 1295-1302.

Download:

PDF(3386KB)
Export: BibTeX | EndNote (RIS)

Abstract

The Al content and the β stabilizers in TiAl base alloys were investigated,which have an important effect on the solidification characteristics and phase selection.TiAl base alloys with single β-solidifying have the characteristics of low Al content and narrow crystallization temperature range. It is attributed to forming a homogeneous fine-grained microstructure. Dendrite morphology in TiAl base alloys is investigated by SEM-BSE in the nonequilibrium solidification conditions. The relationships between undercooling and nucleation of two phases are investigated systematically by using the classical nucleation theory in the undercooled Ti48Al2Cr2Nb (atomic fraction, %) peritectic alloy. By calculating the interfacial critical nucleation work and steady state nucleation rates of β phase (bcc) and α phase (hcp), it is obtained that β phase is always prior to nucleate from the Ti48Al2Cr2Nb undercooled melts at the cooling rate about 15 K/s in the achieved undercooling range. Due to narrow crystallization temperature range, microstructures of TiAl base alloys with high Al content as the hyper-peritectic solidification path take on the gradual solidification style and finer dendrite morphology. It is conducive to reducing and eliminating shrinkage porosity and hot cracking caused by mushy solidification. The β stabilizers have an important effect on solidification path depending on its Al equivalent and will change the solidification path of TiAl alloy from hyper--peritectic solidification to hypo-peritectic solidification. The overmuch Al content in TiAl base alloys leads to the formation of large number of massive γ phase impacting on strength and ductility of alloys.

Key words: TiAl base alloy nonequilibrium solidification phase selection undercooling, primary phase

Received: 25 July 2013

	Service

	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	（）
	Articles by authors
	HU Rui
	LIU Yi
	ZHANG Tiebang
	KOU Hongchao
	LI Jinshan

URL:

https://www.ams.org.cn/EN/10.3724/SP.J.1037.2013.00441 OR https://www.ams.org.cn/EN/Y2013/V49/I11/1295

[1] Appel F, Paul J D H, Oehring M. Gamma Titanium Aluminide Alloys. Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2011: 465

[2] Imayev R M, Imayev V M, Oehring M, Appel F. Intermetallics, 2007; 15: 451

[3] Huang Z W. Scr Mater, 2005; 52: 1021

[4] Johnson D R, Chihara K, Inui H, Yamaguchi M. Acta Mater, 1998; 18: 6529

[5] Huang L, Liaw P K, Liu C T, Liu Y, Huang J S. Trans Nonferrous Met Soc China, 2011; 21: 2192

[6] Jung I S, Jang H S, Oh M H, Lee J H, Wee D M. Mater Sci Eng, 2002; A329-331: 13

[7] Li Q C, An G Y, Zhu P Y, He Z M. Theoretical Basis of Casting Forming.Harbin: Harbin Institute of Technology Press, 1980: 75

(李庆春, 安阁英, 朱培钺, 何镇明. 铸件形成理论基础, 哈尔滨: 哈尔滨工业大学出版社, 1980: 75)

[8] Chen G L, Xu X J, Teng Z K, Wang Y L, Lin J P. Intermetallics, 2007; 15: 625

[9] Kim Y W. JOM, 1989; 41: 24

[10] Anderson C D, Hofmeisiter W H, Bayuzick R J. Metall Trans, 1992; 23A: 2699

[11] Shuleshova O, Woodcock T G, Lindenkreuz H G, Hermann R, Loser W,Buchner B. Acta Mater, 2007; 55: 681

[12] Kim S W, Wang P, Oh M H, Wee D M, Kumar K S. Intermetallics, 2004; 12: 499

[13] Zhang Y G, Han Y F, Chen G L, Guo J T, Wan X J, Feng D. Intermetallic Compound Structure Material.Beijing: National Defense Industry Press, 2001: 701

(张永刚, 韩雅芳, 陈国良, 郭建亭, 万晓景, 冯涤. 金属间化合物结构材料,北京: 国防工业出版社, 2001: 701)

[14] Su Y Q, Liu C, Li X Z, Guo J J, Li B S, Jia J, Fu H Z. Intermetallics, 2005; 13: 267

[15] Ding X F, Lin J P, Zhang L Q, Su Y Q, Hao G J, Chen G L.Intermetallics, 2011; 19: 1115

[16] Daloz D, Hecht U, Zollinger J, Combeau H, Hazotte A, Zaloznik M.Intermetallics, 2011; 19: 749

[17] Hu D, Botten R R. Intermetallics, 2002; 10: 701

[18] Singh A K, Muraleedharan K, Banerjee D. Scr Mater, 2003; 48: 767

[19] Hartmann H, Galenko P K, Holland--Moritz D, Kolbe M, Herlach D M,Shuleshova O. J Appl Phys, 2008; 103: 1

[20] Liu Z G, Chai L H, Chen Y Y, Kong F T. Acta Metall Sin, 2008; 44: 569

(刘志光, 柴丽华, 陈玉勇, 孔凡涛. 金属学报, 2008; 44: 569)

[21] Wu X H. Intermetallics, 2006; 14: 1114

[22] Johnson D R, Inui H, Muto S, Omiya Y, Yamanaka T. Acta Mater, 2006; 54: 1077

[23] Su Y Q, Liu C, Li X Z, Guo J J, Li B S, Jia J, Fu H Z.Intermetallics, 2005; 13: 267

[24] Li M, Xue X Y, Hu R, Zhang T B, Zhong H, Li J S. J Aeronaut Mater, 2012; 32(2): 1

(李曼, 薛祥义, 胡锐, 张铁邦, 钟宏, 李金山. 航空材料学报, 2012; 32(2): 1)

[25] Johnson D R, Inui H, Yamaguchi M. Intermetallics, 1998; 6: 647

[26] Zheng Y B, Li S M, Li Z X, Zhu P C, Fu H Z. J Aeronaut Mater, 2009; 29(4): 12

(郑元斌, 李双明, 李臻熙, 朱鹏超, 傅恒志. 航空材料学报, 2009; 29(4): 12)

[27] Chen Y Z. Master Thesis, Northwestern Polytechnical University, Xi'an, 2005

(陈豫增. 西北工业大学硕士学位论文, 西安, 2005)

[28] Liu Z E. Fundamentals of Material Science. Xi'an: Northwestern Polytechnic University Press, 2003: 83

(刘智恩. 材料科学基础, 西安: 西北工业大学出版社, 2003: 83)

[29] Spaepen F. Mater Sci Eng, 1994; A178: 15

[30] Christian J W. The Theory of Transformation in Metals and Alloys. Oxford: Pergamon Press, 1965: 418

[31] Turnbull D. Contemporary Phys, 1969; 10: 473

[1]	Yun LI, Lianjie LIU, Xinming LI, Jinfu LI. Solidification of Undercooled Co₇₅B₂₅ Alloy[J]. 金属学报, 2018, 54(8): 1165-1170.
[2]	LIU Renci, WANG Zhen, LIU Dong, BAI Chunguang, CUI Yuyou, YANG Rui. MICROSTRUCTURE AND TENSILE PROPERTIES OF Ti－45.5Al－2Cr－2Nb－0.15B ALLOY PROCESSED BY HOT EXTRUSION[J]. 金属学报, 2013, 49(6): 641-648.
[3]	LI Xinzhong SUN Tao YU Caixia SU Yanqing CAO Yongzhi GUO Jingjie FU Hengzhi . SOLIDIFICATION PHASE SELECTION IN DIRECTION-ALLY SOLIDIFIED Ti–(44%—54%)Al ALLOYS[J]. 金属学报, 2009, 45(12): 1479-1486.
[4]	GUO Jingjie; LI Xinzhong; SU Yanqing; WU Shiping; FU Hengzhi. Formation Mechanism of Band Structure and Phase Selection During Directional Solidification of Peritectic Alloys II. Phase Selection[J]. 金属学报, 2005, 41(6): 599-604 .
[5]	WU Shiping; GUO Jingjie; JIA Jun. Numerical Simulation of Mold Filling and Solidification of TiAl Base Alloy Exhaust Valve in Vertical Centrifugal Casting Process[J]. 金属学报, 2004, 40(3): 326-330 .
[6]	LIANG Wei;LI Qiang;YANG Dezhuang (Harbin Institute of Technologli; Harbin 150001)(Taiyuan University of Technology; Taiyuan 030024). DEFORMATION AND FRACTURE OF TWO-PHASE TiAl BASE ALLOY WITH A LAMELLAR STRUCTURE AT ROOM TEMPERATURE[J]. 金属学报, 1997, 33(3): 292-296.
[7]	SHEN Ningfu; TANG Yali; GUAN Shaokang; ZHANG Dongjie (Zhengzhou Institute of Technology; Zhengzhou 450002)(Manuscript received 1995-12-28). SOLIDIFICATION THEORY AND RAPID SOLIDIFICATION[J]. 金属学报, 1996, 32(7): 673-684.
[8]	LIANG Wei; LI Qiang; LIU Huiting; YANG Dezhuang (Taiyuan University of Technology; Taiyuan 030024)(Harbin Institute of Technology; Harbin 15000l)(Manuscript received 1995-05-24; in revised form 1995-11-03). MECHANICAL TWINNING IN DOUBLE-PHASE TiAl BASE ALLOY WITH A LAMELLAR STRUCTURE[J]. 金属学报, 1996, 32(2): 154-158.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed