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FGH95高温合金的静态再结晶机制 被引量:20

Static recrystallization mechanism of FGH95 superalloy
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摘要 对热等静压FGH95合金高温挤压形变后的试样进行静态再结晶处理,讨论了其再结晶形核机制及γ′相对再结晶过程的影响。结果表明:合金在γ′相几乎完全溶解温度以上再结晶时,形核以应变诱发晶界迁移机制进行,而在γ′相大量存在的温度范围内则是以亚晶粗化形核机制进行;γ′相的分解速率对再结晶速率有重要影响,随再结晶温度的升高,γ′相分解速率加快,再结晶激活能减小,再结晶速率加快,γ′相分解后以同步或不同步方式重新析出。 The as-HIPed FGH95 alloy was deformed by extrusion at high temperature, and then the as-extruded sample was treated with static recrystallization. The nucleation mechanism and the influence of γ′phase on recrystallization process during static recrystallization were also discussed. The results indicate that the nucleation mechanism is strain-induced boundary migration (SIBM) when alloy is treated near the temperature at which γ′ phase can be dissolved completely, and it is sub-grain coalescence when alloy is treated at the temperature at which a lot of γ′ phase exist. The γ′ phase decomposition rate has an important influence on the recrystallization rate. With the recrystallization temperature increasing, the γ′ phase decomposition rate increases and the activation energy of recrystallization decreases, resulting in recrystallization rate to increase. The γ′ phase re-precipitates in recrystallized grains by synchronization or non-synchronization.
作者 胡本芙 陈焕铭 金开生 李慧英
机构地区 北京科技大学材料科学与工程学院
出处 《中国有色金属学报》 EI CAS CSCD 北大核心 2004年第6期901-906,共6页 The Chinese Journal of Nonferrous Metals
基金 国防科工委"九五"攻关资助项目(95YJ20)
关键词 FGH95高温合金 静态再结晶 形核机制 FGH95 superalloy static recrystallization nucleation mechanism
分类号 TF125.212 [冶金工程—粉末冶金]
  • 相关文献

参考文献7

  • 1[5]MAO Jian, CHANG Ke-min, YANG Wan-hong. Cooling precipitation and strengthening study in powder metallurgy superalloy Rene88DT [J]. Materials Science and Engineering A, 2002, A332: 318- 329.
  • 2[7]HU Ben-fu, ZHANG Shou-hua. Carbide phases in Ni based P/M superalloy[J]. Journal of University of Science & Technology Beijing, 1994, 1 (1): 1-7.
  • 3HuanmingCHEN,BenfuHU,YiwenZHANG,HuiyingLI,QuanmaoYU.Influence of Processing Parameters on Granularity Distribution of Superalloy Powders during PREP[J].Journal of Materials Science & Technology,2003,19(6):587-590. 被引量:3
  • 4[12]Gessinger G H, Bomford M J. Powder metallurgy of superalloys[J]. International Metallurgical Reviews, 1974, 19: 53-73.
  • 5[13]Hu H. Recovery Recrystallization of Metals[M]. New York: Interscience Publishing, 1963. 311- 326.
  • 6[14]Bee J V, Jones A R, Howell P R. The development of the necklace structure in a powder-produced nickel base superalloy[J]. Journal of Materials Science, 1980, 15: 337344.
  • 7[15]Menzies R G, Daves G J, Edington J W. Microstructural changes during recrystallization of powder-consolidated nickel-base superalloy IN-100 [J]. Metal Science, 1981, 5: 217- 223.

二级参考文献12

  • 1[1]W.Pietsch, H.Stephan, A.Feuerstein, J.Heimerl and R.Ruthardt: Powder Metall. Inter., 1983, 15(2), 77.
  • 2[2]Huanming CHEN, Benfu HU, Quanmao YU and Duo SONG:J. Mater. Eng., 2002, 3, 32. (in Chinese)
  • 3[3]Yiwen ZHANG: Journal of Iron and Steel Research, 1998,10(3), 74. (in Chinese)
  • 4[4]Ying ZHANG, Shikui LI and Shengda CHEN: Powder Metall.Industry, 1998, 8(6), 17. (in Chinese)
  • 5[5]Chengqun HE, Benfu HU, Weiming GUO and Shengda CHEN:Acta Metall. Sin., 2000, 36(2), 187. (in Chinese)
  • 6[6]W.V.Youdelis and O.Kwon: Metal Sci., 1983, 17(8), 385.
  • 7[7]Liankui NIU, Yingcai ZHANG and Shikui LI: Powder Metall.Industry, 1999, 9(3), 23. (in Chinese)
  • 8[8]Jinwen ZOU and Wuxiang WANG: Mater. Sci. Technol., 1999,7(Supply), 201. (in Chinese)
  • 9[9]B.Champagne and R.Angers: Inter. J. Powder Metall. and Powder Technol., 1980, 16(4), 237.
  • 10[10]Cengiz Dogan and Suleyman Saritas: Inter. J. Powder Metall.,1994, 30(4), 419.

共引文献2

同被引文献171

引证文献20

二级引证文献128

中国有色金属学报
2004年 第6期

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