Computational fluid dynamic investigation of the primary and secondary atomization of the free-fall atomizer in electrode induction melting gas atomization process

Xia Min; Wang Peng; Zhang Xiao-Hu; Ge Chang-Chun

doi:10.7498/aps.67.20180584

Abstract

Nickel-based superalloy is mainly used for fabricating the important high temperature parts including the turbine disk, turbine baffle, compressor disk, and other critical components. Ceramic inclusions in powder metallurgy (PM) superalloy could promote fatigue crack initiation, and thus accelerating the crack propagation under certain conditions. In this case, the ultra-clean nickel-based superalloy powder is critical for PM superalloy components. Generally, there are two well-known methods of fabricating superalloy powders, i.e., argon gas atomization (AA) and plasma rotating electrode process (PREP). Electrode induction melting gas atomization (EIGA) process is a newly developed method of preparing ultra-clean metal powders. The EIGA process is a completely crucible-free melting and atomization process developed by ALD vacuum technologies. In this process, a slowly rotating prealloyed bar is fed into a conical induction coil. The end of the bar is inductively heated and molten alloys falls into an atomizer where the liquid alloy is atomized with a high-pressure inert gas. The EIGA prepared powders possess the advantages of AA (more fine powders) and PREP (ultra-clean powders) processes. Generally, there are two key issues in EIGA process, and the free-fall gas atomizer design is one of the critical issues for the powder yield and quality. Free-fall gas atomizers are some of the first two fluid atomizer designs to be used for molten metal atomization. In a simple open (unconfined stream) design a melt stream falls from a tundish exit via gravity into the convergence of focused atomization gas jets where it is disintegrated. The gas-melt interaction is complex, and it is difficult to characterize the interaction process directly. To have a good understanding of the atomisation technology, the physical break-up process instead of correlating the gas dynamics with droplet fragmentation indirectly must be able to be examined. And it will be desirable, if we input the atomization parameters, we can obtain the particles' distributions directly. In this work, a computational fluid dynamic approach to simulating the primary and secondary atomization processes is developed by using the volume of fluid method and discrete phase model. By integrating the metal stream break-up (in primary atomization) with the flow field and particles distribution simulation (in second atomization), this numerical simulation method is able to provide the direct assessment for the atomisation process. To verify the method performance, the melt stream is initialized into a 4 mm-diameter stream, which is then injected into the gas flow field for further fragmentation. The experimental results show that the simulated particles' diameter distribution is consistent with the experimental results in the same conditions.

Keywords:

computational fluid dynamics /
primary and secondary atomization /
free-fall atomizer /
electrode induction melting gas atomization

Authors and contacts

1.
Institute of Nuclear Materials, University of Science and Technology Beijing, Beijing 100083, China;
2.
Guizhou University of Engineering Science, Bijie 551700, China

Corresponding author: Xia Min, xmdsg@ustb.edu.cn;ccge@mater.ustb.edu.cn ; Ge Chang-Chun, xmdsg@ustb.edu.cn;ccge@mater.ustb.edu.cn

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Cited By

[1]	Chandrasekhar S B, Wasekar N P, Ramakrishna M, Suresh Babu P, Rao T N, Kashyap B P 2016 J. Alloys Compd. 656 423
[2]	Li S, Su Y, Ouyang Q, Zhang D 2016 Mater. Lett. 167 118
[3]	Chou D, Wells D, Hong D, Lee B, Kuhn H, Kumta P N 2013 Acta Biomater. 9 8593
[4]	Si C, Tang X, Zhang X, Wang J, Wu W 2017 Mater. Design 118 66
[5]	Ashgriz N 2011 Handbook of Atomization and Sprays (New York:Springer Verlag) p339
[6]	Kourmatzis A, Lowe A, Masri A R 2016 Exp. Therm. Fluid Sci. 75 66
[7]	Motaman S, Mullis A M, Cochrane R F, Borman D J 2015 Metall. Mater. Trans. B 46 1990
[8]	Zhang L N, Zhang M C, Li X, Xie X S 2001 Ordnance Material Science and Engineering 3 64 (in Chinese)[张丽娜, 张麦仓, 李晓, 谢锡善 2001 兵器材料科学与工程 3 64]
[9]	Guo K, Liu C, Chen S, Li J, Fu Q 2017 IOP Conference Series:Materials Science and Engineering 207 012046
[10]	Wei M W, Chen S Y, Guo K K, Liang J, Liu C S 2017 Materials Review 12 64 (in Chinese)[魏明炜, 陈岁元, 郭快快, 梁京, 刘常升 2017 材料导报 12 64]
[11]	Franz H, Plochl L, Schimansky F P 2008 Titanium 2008 September 21-24, 2008, Las vegas, USA, pp1-4
[12]	Guo K K, Liu C S, Chen S Y, Fu Q 2017 Materials Science and Technology 01 16 (in Chinese)[郭快快, 刘常升, 陈岁元, 付骞 2017 材料科学与工艺 01 16]
[13]	Feng S, Ge C C, Xia M 2017 Chin. Phys. B 26 1
[14]	Ting J, Anderson I E 2004 Mat. Sci. Eng. A:Struct. 379 264
[15]	Motaman S, Mullis A M, Cochrane R F, McCarthy I N, Borman D J 2013 Comput. Fluids 88 1
[16]	Zhao W, Cao F, Ning Z, Zhang G, Li Z, Sun J 2012 Comput. Chem. Eng. 40 58
[17]	Zeoli N, Gu S 2008 Comp. Mater. Sci. 43 268
[18]	Zeoli N, Gu S 2006 Comp. Mater. Sci. 38 282
[19]	Mi J, Figliola R S, Anderson I E 1996 Mat. Sci. Eng. A:Struct. 8 20
[20]	Antipas G S E 2009 Comp. Mater. Sci. 46 955
[21]	Ting J, Peretti M W, Eisen W B 2002 Mat. Sci. Eng. A:Struct. 326 110
[22]	Zeoli N, Tabbara H, Gu S 2011 Chem. Eng. Sci. 66 6498
[23]	Liu Y, Li Z, Zhang G Q, Xu W Y, Yuan H, Liu N 2015 J. Aeronautical Materials. 5 63 (in Chinese)[刘杨, 李周, 张国庆, 许文勇, 袁华, 刘娜 2015 航空材料学报 5 63]
[24]	Fritsching U 2004 Spray Simulation (Cambridge:Cambridge University Press) p11
[25]	Thompson J S, Hassan O, Rolland S A, Sienz J 2016 Powder Technol. 291 75
[26]	Firmansyah D A, Kaiser R, Zahaf R, Coker Z, Choi T, Lee D 2014 Jpn. J. Appl. Phys. 53 05HA09
[27]	Beale J C, Reitz R D 1999 Atomization Sprays 9 623
[28]	Fritsching U 2006 Spray Simulation:Modeling and Numerical Simulation of Sprayforming Metals (New York:American Society of Mechanical Engineers)
[29]	Versteeg H K, Malalasekera W 1995 An Introduction to Computational Fluid Dynamics (New York:Longman Scientific and Technical) p11
[30]	Markus S, Fritsching U, Bauckhage K 2002 Mat. Sci. Eng. A:Struct. 326 122
[31]	nal A 1989 Metall. Trans. B 20 61
[32]	Li X G, Fritsching U 2017 J. Mater. Process. Technol. 239 1
[33]	Borée J, Ishima T, Flour I 2001 J. Fluid Mech. 443 129

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Vol. 67, Issue 17 - 2018-09-05

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