Effect of Gravity on Directionally Solidified Structure of Superalloys

doi:10.11900/0412.1961.2023.00143

Acta Metall Sin

2023, Vol. 59

Issue (9): 1279-1290 DOI: 10.11900/0412.1961.2023.00143

Research paper

Current Issue | Archive | Adv Search

Effect of Gravity on Directionally Solidified Structure of Superalloys

MA Dexin¹^,²(

), ZHAO Yunxing¹^,², XU Weitai¹, WANG Fu³

¹Shenzhen Wedge Central South Research Institute Co. Ltd., Shenzhen 518045, China
²Powder Metallurgy Research Institute, Central South University, Changsha 410083, China
³School of Mechanical and Electrical Engineering, Xi'an Jiaotong University, Xi'an 710049, China

Cite this article:

MA Dexin, ZHAO Yunxing, XU Weitai, WANG Fu. Effect of Gravity on Directionally Solidified Structure of Superalloys. Acta Metall Sin, 2023, 59(9): 1279-1290.

Download:

HTML

PDF(3991KB)
Export: BibTeX | EndNote (RIS)

Abstract

While using traditional methods of directionally solidifying superalloy castings, the liquid density at the lower region of the mushy zone gradually lowers than the top. This is due to a strong segregation of alloying elements. The gravitational force then exacerbates this density inversion, leading to upward convection from the mushy zone to the liquid ahead of the solidification front. This process, known as solutal convection, results in several solidification defects such as freckle defects, an upward accumulation of γ/γ' eutectic, and seeding process issues. As higher-generation single crystal superalloys continue to develop, the problems of element segregation and solutal convection become more pronounced. Traditional measures, such as adjusting process parameters, struggle to effectively alleviate these issues. Given that these problems largely arise from gravity-induced fluid flow, this work aims to investigate the role of gravity on solidification structure and propose appropriate solutions. To achieve this, the conventional pull-down and novel pull-up methods were adopted to perform directional solidification experiments with superalloys. The influence of gravity on solidification behavior is starkly different in these two experiments. In the pull-down process, dendrites grow upward, against gravity, leading to a variety of solidification defects such as freckles on the casting's lateral surface and an upward accumulation of γ/γ' eutectic on the upper surface of the single crystal turbine blade castings. Stray grains also formed in the remelting region during seeding. These phenomena are caused by the density inversion of the remaining liquid between dendrites, resulting in a top-heavy and bottom-light hydrodynamic state. Liquid convection in the mushy zone was then unavoidable under gravity in the pull-down process. In contrast, the pull-up process had dendrites growing downwards, in line with gravity, leaving the least dense liquid at the top of the mushy zone. In this top-light and bottom-heavy state, gravity stabilizes the segregated residual liquid in the mushy zone, thereby preventing solutal convection. Consequently, freckle defects were eliminated, and the γ/γ' eutectic structure was evenly distributed, not accumulated, on the upper surface of the single crystal blade's platform. Additionally, the stability of remelting and epitaxial growth of seed crystals was ensured by eliminating liquid convection. By using this pull-up process, the negative effects of gravity on the directional solidification of superalloys were removed, and all gravity-related solidification defects consequently disappeared. This novel pull-up process could potentially be developed into a new production process for single crystal superalloy castings, significantly improving casting quality. However, it should be noted that this new pull-up process is more complex in comparison to the conventional method. Although this work lays the groundwork for this process, further technological enhancements are required before this method can be applied to industrial production.

Key words: superalloy directional solidification gravity solidification direction solidification structure

Received: 31 March 2023

ZTFLH:

TG146

Fund: Guangdong Innovative and Entrepreneurial Research Team Program(607264877417);Shenzhen Peacock Plan(KQTD2015032716463668)

	Service

	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	（）
	Articles by authors
	MA Dexin
	ZHAO Yunxing
	XU Weitai
	WANG Fu

URL:

https://www.ams.org.cn/EN/10.11900/0412.1961.2023.00143 OR https://www.ams.org.cn/EN/Y2023/V59/I9/1279

Table 1 Compositions and densities of the selected Ni-based superalloys

Fig.1 Schematics of directional solidification in different directions using pull-down (a) and pull-up (b) methods, resulting in upward solidification (UWS) and downward solidification (DWS), respectively

Fig.2 Etched surface photos (a1-a3) and corresponding cross-section OM images (b1-b3) of three CMSX-4 alloy samples with circular (a1, b1), square (a2, b2), and cross shaped (a3, b3) cross-sections prepared by the pull-down method (Ellipse zones in Figs.1b1-b3 show the freckles)

Fig.3 Etched surface photos (a1-a3) and corresponding cross-section OM images (b1-b3) of three CMSX-4 alloy samples with circular (a1, b1), square (a2, b2), and cross shaped (a3, b3) cross-sections prepared by the pull-up method

Fig.4 Schematics of UWS (a) and DWS (b)

Fig.5 Partial photo of a CMSX-4 blade casting prepared by pull-down method (a), and longitudinal section OM images of platform in as-cast (b1) and heat treated (b2) states

Fig.6 Cross-section OM images near the top (a1, b1) and bottom (a2, b2) surfaces of the platform in as-cast (a1, a2) and heat treated (b1, b2) states for CMSX-4 blade prepared by pull-down method

Fig.7 Longitudinal section OM images of platform in as-cast (a) and heat treated (b) states for CMSX-4 blade prepared by pull-up method

Fig.8 Cross-section OM images near the top (a1, b1) and bottom (a2, b2) surfaces of the platform in as-cast (a1, a2) and heat treated (b1, b2) states for CMSX-4 blade prepared by pull-up method

Fig.9 Schematics of dendrite and γ/γ' eutectic growth in platform during UWS
(a) starting stage (b) stable growth stage (c) end stage

Fig.10 Schematics of dendrite and γ/γ' eutectic growth in platform during DWS
(a) starting stage (b) stable growth stage (c) end stage

Fig.11 Longitudinal section OM images near the remelting zone showing the structure transition from CMSX-6 seed to CMSX-4 prepared by pull-down (a) and pull-up (b) methods

Fig.12 Longitudinal section OM images near the remelting zone showing the structure transition from CM247 seed to CMSX-4 prepared by pull-down (a) and pull-up (b) methods

1	Giamei A F, Kear B H. On the nature of freckles in nickel base superalloys [J]. Metall. Trans., 1970, 1: 2185 doi: 10.1007/BF02643434
2	Copley S M, Giamei A F, Johnson S M, et al. The origin of freckles in unidirectionally solidified castings [J]. Metall. Trans., 1970, 1: 2193 doi: 10.1007/BF02643435
3	Auburtin P, Wang T, Cockcroft S L, et al. Freckle formation and freckle criterion in superalloy casting [J]. Metall. Mater. Trans., 2000, 31B: 801
4	Tin S, Pollock T M. Predicting freckle formation in single crystal Ni-base superalloys [J]. J. Mater. Sci., 2004, 39: 7199 doi: 10.1023/B:JMSC.0000048732.02111.ee
5	Ma D X, Wu Q, Bührig-Polaczek A. Some new observations on freckle formation in directionally solidified superalloy components [J]. Metall. Mater. Trans., 2012, 43B: 344
6	Ma D X, Bührig-Polaczek A. The geometrical effect on freckle formation in the directionally solidified superalloy CMSX-4 [J]. Metall. Mater. Trans., 2014, 45A: 1435
7	Ma D X. Freckle formation during directional solidification of complex castings of superalloys [J]. Acta Metall. Sin., 2016, 52: 426
	马德新. 定向凝固的复杂形状高温合金铸件中的雀斑形成 [J]. 金属学报, 2016, 52: 426 doi: 10.11900/0412.1961.2015.00379
8	Ma D X, Dong Z H, Wang F, et al. A phenomenological analysis of freckling in directional solidification of Ni-base superalloy: The role of edge and curvature in casting components [J]. Metall. Mater. Trans., 2020, 51A: 88
9	Seo S M, Lee J H, Yoo Y S, et al. A comparative study of the γ/γ' eutectic evolution during the solidification of Ni-base superalloys [J]. Metall. Mater. Trans., 2011, 42A: 3150
10	D’Souza N, Dong H B, Ardakani M G, et al. Solidification path in the Ni-base superalloy, IN713LC——Quantitative correlation of last stage solidification [J]. Scr. Mater., 2005, 53: 729 doi: 10.1016/j.scriptamat.2005.05.012
11	Wang F, Ma D X, Zhang J, et al. Effect of solidification parameters on the microstructures of superalloy CMSX-6 formed during the downward directional solidification process [J]. J. Crystal Growth, 2014, 389: 47 doi: 10.1016/j.jcrysgro.2013.11.084
12	Wang F, Ma D X, Zhang J, et al. Effect of local cooling rates on the microstructures of single crystal CMSX-6 superalloy: A comparative assessment of the Bridgman and the downward directional solidification processes [J]. J. Alloys Compd., 2014, 616: 102 doi: 10.1016/j.jallcom.2014.07.084
13	Wang F, Ma D X, Zhang J, et al. Solidification behavior of a Ni-based single crystal CMSX-4 superalloy solidified by downward directional solidification process [J]. Mater. Charact., 2015, 101: 20 doi: 10.1016/j.matchar.2015.01.003
14	Zhu Y X, Xu L Y, Zhao H E, et al. Formation of γ + γ' eutectic and control of σ-phase in a high Al-Ti cast Ni-base superalloy [J]. Acta Metall. Sin., 1986, 22: A93
	朱耀宵, 徐乐英, 赵洪恩等. 一种铸造镍基高温合金中(γ + γ')共晶的形成及σ相的控制 [J]. 金属学报, 1986, 22: A93
15	Warnken N, Ma D X, Mathes M, et al. Investigation of eutectic island formation in SX superalloys [J]. Mater. Sci. Eng., 2005, A413-414: 267
16	D’Souza N, Dong H B. Solidification path in third-generation Ni-based superalloys, with an emphasis on last stage solidification [J]. Scr. Mater., 2007, 56: 41 doi: 10.1016/j.scriptamat.2006.08.060
17	D’Souza N, Lekstrom M, Dai H J, et al. Quantitative characterisation of last stage solidification in nickel base superalloy using enthalpy based method [J]. Mater. Sci. Technol., 2007, 23: 1085 doi: 10.1179/174328407X213224
18	Ma D X, Wang F, Weng X H, et al. Influence of MC carbides on the formation of γ/γ' eutectics in single crystal superalloy CM247LC [J]. Acta Metall. Sin., 2017, 53: 1603
	马德新, 王富, 温序晖等. CM247LC单晶高温合金中MC碳化物对γ/γ'共晶反应的影响 [J]. 金属学报, 2017, 53: 1603 doi: 10.11900/0412.1961.2017.00110
19	Ma D X, Wang F. Randomly orientated eutectic grains in single crystal castings of superalloys [J]. Foundry, 2019, 68: 1342
	马德新, 王富. 高温合金单晶铸件中的杂乱共晶缺陷 [J]. 铸造, 2019, 68: 1342
20	Ma D X, Zhao Y X, Wei J H, et al. Upward accumulation analysis of eutectics in single crystal superalloy blade castings [J]. Foundry, 2021, 70: 1302
	马德新, 赵运兴, 魏剑辉等. 单晶高温合金叶片铸件中的共晶上聚现象分析 [J]. 铸造, 2021, 70: 1302
21	Ma D X, Zhao Y X, Xu W T, et al. Surface effect on eutectic structure distribution in single crystal superalloy castings [J]. Acta Metall. Sin., 2021, 57: 1539 doi: 10.11900/0412.1961.2020.00404
	马德新, 赵运兴, 徐维台等. 高温合金单晶铸件中共晶组织分布的表面效应 [J]. 金属学报, 2021, 57: 1539 doi: 10.11900/0412.1961.2020.00404
22	Yang X L, Ness D, Lee P D, et al. Simulation of stray grain formation during single crystal seed melt-back and initial withdrawal in the Ni-base superalloy CMSX4 [J]. Mater. Sci. Eng., 2005, A413-414: 571
23	Zhao N R, Li J G, Liu J L, et al. Solidification interface in growth of single crystal superalloys by seeding technique [J]. J. Mater. Eng., 2007, (11): 24
	赵乃仁, 李金国, 刘金来等. 籽晶法生长高温合金单晶凝固界面研究 [J]. 材料工程, 2007, (11): 24
24	Yang W C, Hu S S, Huo M, et al. Orientation controlling of Ni-based single-crystal superalloy by a novel method: Grain selection assisted by un-melted reused seed [J]. J. Mater. Res. Technol., 2019, 8: 1347 doi: 10.1016/j.jmrt.2018.10.005
25	Hu S S, Liu L, Yang W C, et al. Inhibition of stray grains at melt-back region for re-using seed to prepare Ni-based single crystal superalloys [J]. Progr. Nat. Sci. Mater. Int., 2019, 29: 582 doi: 10.1016/j.pnsc.2019.08.006
26	Ford D A, Hill A D. Single crystal seed alloy [P]. US Pat, 6740176, 2004
27	Guo J, Li J G, Liu J D, et al. Formation mechanism of fusion zone in growth of single crystal superalloy with low-segregated heterogeneous seed [J]. Acta Metall. Sin., 2018, 54: 419 doi: 10.11900/0412.1961.2017.00144
	郭静, 李金国, 刘纪德等. 低偏析异质籽晶制备单晶高温合金的籽晶熔合区形成机制研究 [J]. 金属学报, 2018, 54: 419
28	Ma D X, Zhao Y X, Xu W T, et al. Influence of seeding materials on epitaxial growth of single crystal superalloys [J]. Chin. J. Nonferrous Met., 2023, 33: 445
	马德新, 赵运兴, 徐维台等. 高温合金籽晶材料对单晶外延生长的影响 [J]. 中国有色金属学报, 2023, 33: 445
29	Ma D X, Zhang Q Y, Wang H Y, et al. Effect of solidification condition change on stray grain defect formation in single crystal casting of superalloys [J]. Foundry, 2019, 68: 103
	马德新, 张琼元, 王海洋等. 高温合金单晶铸造中凝固条件的时空变化及对杂晶缺陷的影响 [J]. 铸造, 2019, 68: 103
30	Beckmann C, Gu J P, Boettinger W J. Development of a freckle predictor via Rayleigh number method for single-crystal nickel-base superalloy castings [J]. Metall. Mater. Trans., 2000, 31A: 2545

[1]	JIANG He, NAI Qiliang, XU Chao, ZHAO Xiao, YAO Zhihao, DONG Jianxin. Sensitive Temperature and Reason of Rapid Fatigue Crack Propagation in Nickel-Based Superalloy[J]. 金属学报, 2023, 59(9): 1190-1200.
[2]	ZHANG Jian, WANG Li, XIE Guang, WANG Dong, SHEN Jian, LU Yuzhang, HUANG Yaqi, LI Yawei. Recent Progress in Research and Development of Nickel-Based Single Crystal Superalloys[J]. 金属学报, 2023, 59(9): 1109-1124.
[3]	LI Jiarong, DONG Jianmin, HAN Mei, LIU Shizhong. Effects of Sand Blasting on Surface Integrity and High Cycle Fatigue Properties of DD6 Single Crystal Superalloy[J]. 金属学报, 2023, 59(9): 1201-1208.
[4]	WANG Lei, LIU Mengya, LIU Yang, SONG Xiu, MENG Fanqiang. Research Progress on Surface Impact Strengthening Mechanisms and Application of Nickel-Based Superalloys[J]. 金属学报, 2023, 59(9): 1173-1189.
[5]	LU Nannan, GUO Yimo, YANG Shulin, LIANG Jingjing, ZHOU Yizhou, SUN Xiaofeng, LI Jinguo. Formation Mechanisms of Hot Cracks in Laser Additive Repairing Single Crystal Superalloys[J]. 金属学报, 2023, 59(9): 1243-1252.
[6]	GONG Shengkai, LIU Yuan, GENG Lilun, RU Yi, ZHAO Wenyue, PEI Yanling, LI Shusuo. Advances in the Regulation and Interfacial Behavior of Coatings/Superalloys[J]. 金属学报, 2023, 59(9): 1097-1108.
[7]	BAI Jiaming, LIU Jiantao, JIA Jian, ZHANG Yiwen. Creep Properties and Solute Atomic Segregation of High-W and High-Ta Type Powder Metallurgy Superalloy[J]. 金属学报, 2023, 59(9): 1230-1242.
[8]	FENG Qiang, LU Song, LI Wendao, ZHANG Xiaorui, LI Longfei, ZOU Min, ZHUANG Xiaoli. Recent Progress in Alloy Design and Creep Mechanism of γ'-Strengthened Co-Based Superalloys[J]. 金属学报, 2023, 59(9): 1125-1143.
[9]	BI Zhongnan, QIN Hailong, LIU Pei, SHI Songyi, XIE Jinli, ZHANG Ji. Research Progress Regarding Quantitative Characterization and Control Technology of Residual Stress in Superalloy Forgings[J]. 金属学报, 2023, 59(9): 1144-1158.
[10]	ZHENG Liang, ZHANG Qiang, LI Zhou, ZHANG Guoqing. Effects of Oxygen Increasing/Decreasing Processes on Surface Characteristics of Superalloy Powders and Properties of Their Bulk Alloy Counterparts: Powders Storage and Degassing[J]. 金属学报, 2023, 59(9): 1265-1278.
[11]	ZHAO Peng, XIE Guang, DUAN Huichao, ZHANG Jian, DU Kui. Recrystallization During Thermo-Mechanical Fatigue of Two High-Generation Ni-Based Single Crystal Superalloys[J]. 金属学报, 2023, 59(9): 1221-1229.
[12]	CHEN Jia, GUO Min, YANG Min, LIU Lin, ZHANG Jun. Effects of W Concentration on Creep Microstructure and Property of Novel Co-Based Superalloys[J]. 金属学报, 2023, 59(9): 1209-1220.
[13]	MU Yahang, ZHANG Xue, CHEN Ziming, SUN Xiaofeng, LIANG Jingjing, LI Jinguo, ZHOU Yizhou. Modeling of Crack Susceptibility of Ni-Based Superalloy for Additive Manufacturing via Thermodynamic Calculation and Machine Learning[J]. 金属学报, 2023, 59(8): 1075-1086.
[14]	LIU Xingjun, WEI Zhenbang, LU Yong, HAN Jiajia, SHI Rongpei, WANG Cuiping. Progress on the Diffusion Kinetics of Novel Co-based and Nb-Si-based Superalloys[J]. 金属学报, 2023, 59(8): 969-985.
[15]	YUAN Jianghuai, WANG Zhenyu, MA Guanshui, ZHOU Guangxue, CHENG Xiaoying, WANG Aiying. Effect of Phase-Structure Evolution on Mechanical Properties of Cr₂AlC Coating[J]. 金属学报, 2023, 59(7): 961-968.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed