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Influence of atomizing gas and cooling rate on solidification characterization of nickel-based superalloy powders
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School of Materials Science Engineering,Southwest Jiaotong University,School of Materials Science Engineering,Southwest Jiaotong University;PR China;Foundation Institute of Materials Science,Bremen University, Bremen,Germany;National Engineering Technology Research Center for Nonferrous Metal Matrix Composites,General Research Institute for Nonferrous Metals;PR China;Research institute of physical culture,Southwest Jiaotong University;PR China,National Engineering Technology Research Center for Nonferrous Metal Matrix Composites,General Research Institute for Nonferrous Metals,Research institute of physical culture,Southwest Jiaotong University

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    Abstract:

    Nickel-based superalloy powders have been produced by high pressure argon gas and nitrogen gas atomization, respectively. The microstructural characterization of nickel-based alloy powders has been performed with the help of a scanning electron microscope, equipped with an EDS microanalysis unit. Based on a Newtonian cooling model, the flight speed and the cooling rate of two kinds of alloy droplets are calculated. The results show that the droplet cooling rate, which depends on atomization medium and droplet size, has an effect on the solidification microstructure. For argon-gas atomized powders, the developed dendrite structure is predominant at a lower cooling rate and a mixed microstructure composed of dendrite structure and cellular structure is observed at a higher cooling rate. For nitrogen-gas atomized powders, the dendrite structure is predominant at a lower cooling rate and a full cellular structure can be observed at a higher cooling rate. According to calculation, the cooling rate of argon-gas atomized droplets is in a range from10000K/s to 424000 K/s , while the cooling rate of nitrogen-gas atomized droplets is from 10000K/sto 480000 K/s . The cooling rate increases with decreasing of droplets diameter. Two kinds of atomizing gases have a slightly influence on the cooling rate of droplets. The elements such as Cr, Co, W, Ni and Al are rich in the dendrite axis, while Ti element is rich in the inter-dendrite region.

    Reference
    1 Chen H M, Hu B F, Li H Y, et al. The Chinese Journal of Nonferrous Metals [J], 2003, 13: 554
    2 Lherbier L W, Kent W B. The International Journal of Powder Metallurgy [J], 1990, 26: 135
    3 Park N K, Kim I S. Journal of Materials Processing Technology [J], 2001, 111: 99
    4 Q. Wu. Journal of Advanced Aerospace Materials [J], 2007,100:54
    5 YIN Fa-zhang, Hu Ben-fu, JIN Kai-sheng, et al. Journal of Materials Engineering [J], 2005, 10: 52
    6 Udo Fritsching ,Volker Uhlenwinkel. University of Bremen Germany [M], 1993: 97
    7 H. Tomas Yolken, Leonard Modfin. Automated Processing of Advanced Materials [J], 1986, 32:40
    8 G.H. Tan, T. Sheppard. Powder Metallurgy [J], 1986, 29: 143.
    9 J. Duszczyk, P. Jongenburger. Powder Metallurgy [J], 1986, 29: 20
    10 A. Freyberg, M. Buchholz, V. Uhlenwinkel, and H. Henein.Metallurgical and Materials Transactions[J], 2003,B34: 243
    11 C.G. Levi, R. Mehrabian. Metallurgical and Materials Transactions [J], 2002, 25:32
    12 W.J. Boettinger, L. Bendersky, and J.G. Early. Metallurgical Transactions [J], 1986, A 17: 781
    13 A. Zambon, B. Badan et al. Materials Science and Engineering [J], 1997, A 226: 121
    14 Lee E S,Ahn S. Acta Metallurgica Materialia [J],1994, 42: 3238
    15 Saad M A. Prentice-Hall, Englewood Cliffs [M], 1985, N.J: 92-95
    16 Grant P S, Cantor B, Katgerman L. Acta Metallurgica Materialia [J], 1993, 41: 3098
    17 Clift R, GraceK R,WeberM E. New York: Academic Press [M],1978: 113
    18 Zhang J S,Xiong B Q, Cui H. Beijing,Science Press [M], 2007: 47
    19 Inoue A, Masumoyo T, Ekimoyo T, et al. Metallurgical Transactions A [J], 1988, 19: 235
    20 Q.J. Zhai, Y.L. Gao, W.B. Guan, and K.D. Xu. Materical Science Engineering A [J], 2006, 441: 278
    21 E.S. Lee and S. Ahn. Acta Metallurgica Materialia [J], 1994, 42: 3231
    22 Szekely J, Themelis N J. New York: Wiley-Interscience [M], 1971: 237
    23 Lee, E.S., Ahn, S. Acta Metallurgica Materialia [J], 1994, 42: 3231-3243
    24 Lavemia E J, Ayers J D, Srivatsan T S. International Materials Reviews [J], 1992, 37(1): 42-44
    25 J.W. Fu, Y.S. Yang, Journal of Crystal Growth [J], 2011, 322: 84-90
    26 C. Suryanarayana, T.R. Anantharaman. Journal of Materials Science [J], 1970, 5: 998-1002
    27 F. Hehmann, F. Sommer, B. Predel. Material Science Engineering A [J], 1990, 125: 242
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[FANG Pengjun, XU Yi, LI Xinggang, CHEN Ya. Influence of atomizing gas and cooling rate on solidification characterization of nickel-based superalloy powders[J]. Rare Metal Materials and Engineering,2018,47(2):423~430.]
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History
  • Received:February 19,2016
  • Revised:April 27,2016
  • Adopted:May 18,2016
  • Online: March 15,2018

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