期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

Cu-2.32Ni-0.57Si-0.05P合金热压缩变形研究 被引量:3

Hot compression deformation behavior of Cu-2.32Ni-0.57Si-0.05P alloy
下载PDF
导出
摘要 在Gleeble-1500D热模拟试验机上,对Cu-2.32Ni-0.57Si-0.05P合金在应变速率为0.01~5s-1、变形温度为600~800℃、最大变形程度为60%条件下,进行恒温压缩模拟实验研究.分析了实验合金在高温变形时的流变应力、应变速率及变形温度之间的关系,研究了变形温度对合金显微组织的影响.计算了合金高温热压缩变形时的应力指数n、应力参数α、结构因子A以及平均热变形激活能Q.结果表明:合金的流变应力随变形温度升高而降低,随应变速率提高而增大.热变形过程的流变应力可用双曲正弦本构关系来描述.当变形温度高于750℃时,合金流变曲线呈现出明显的动态再结晶特征,合金显微组织为完全的动态再结晶组织.合金的热加工宜在应变速率为0.1~1s-1、温度为700~800℃范围内进行. The stress-strain behavior of Cu-2.32Ni-0. 57Si-0. 05P alloy during hot compression deformation was studied by isothermal compression test on a Gleeble-1500D thermal-mechanical simulator at the strain rate of 0. 01 - 5 s^-1, the temperature of 600 -800 ~C and the maximum deformation of 60% . The relationship among the flow stress, the strain rate and the deformation temperature was researched. The effect of deformation temperatures on microstructure of the alloy was investigated. The stress index n, the stress scale parameter α, the structural factor A and the main activation energy were determined. Results show that the flow stress decreases with the increase of deforming temperature, while it increases with the increase of strain rate. The flow behavior can be described by the hyperbolic sine constitutive equation. When the deformation temperature is higher than 750℃, the flow curves and microstructures present apparent character istic of dynamic recrystallization. The strain rate of 0. 1 - 1 s ^- 1 and the temperature of 700 - 800 ℃ for hot-working deformation of this alloy are suggested.
作者 龙永强 刘平 刘勇 陈乃录 潘健生
机构地区 上海交通大学 河南科技大学材料科学与工程学院 上海理工大学机械工程学院
出处 《材料科学与工艺》 EI CAS CSCD 北大核心 2009年第5期713-717,723,共6页 Materials Science and Technology
基金 国家高新技术研究发展计划资助项目(2006AA03Z528) 国家自然科学基金资助项目(50571035)
关键词 热压缩变形 Cu-2.32Ni-0.57Si-0.05P合金 变形激活能 本构方程 hot compression deformation Cu-2. 32Ni-0.57Si-0.05P alloy deformation activation energy constitutive equation
分类号 TG146.1 [金属学及工艺—金属材料]
  • 相关文献

参考文献15

  • 1刘平,赵冬梅,田保红.高性能铜合金及其加工技术[M].北京:冶金工业出版社,2004.16
  • 2LOCKYER S A, NOBLE F W. Fatigue of precipitate strengthened' Cu--Ni--Si alloy [ J ]. Materials Science and Technology, 1999, 15:1147-1153.
  • 3Fuxiang Huang, Jusheng Ma, Honglong Ning, et al. Precipitation in Cu--Ni--Si--Zn alloy for lead frame [J]. Materials Letters, 2003, 57. 2135-2139.
  • 4SRIVASTAVA V, SCHNEIDER A, UHLENWINKEL V, et al. Effect of thermomechanical treatment on spray formed Cu - Ni - Si alloy [ J ], Materials Science and Technology, 2004, 20 (7): 839- 848.
  • 5SUZUKI S, SHIBUTANI N, MIMURA K, et al. Improvement in strength and electrical conductivity of Cu-- Ni--Si alloys by aging and cold rolling [ J ]. Journal of Alloys and Compounds, 2006, 417: 116- 120.
  • 6ZHAO D M, DONG Q M, LIU P, et al. Structure and strength of the age hardened Cu--Ni--Si ahoy [ J ]. Materials Chemistry and Physics, 2003, 79:81 -86.
  • 7LIUPing,LEIJing-guo,ZHAODong-mei,JINGXiao-tian.Study on Aging Kinetics of CuNiSi Alloy[J].材料热处理学报,2004,25(5):204-207. 被引量:3
  • 8PoirierJP晶体的高温塑性变形[M].关德林译.大连:大连理工大学出版社,1989:25-30.
  • 9Shen G, Semiatantin S L, Altan T. Investigation of flow stress and microstructure development in non - isothermal forging of Ti - 6242 [ J ]. J Mater ProcessTechnol, 1993, 36 : 303 - 307.
  • 10Zener C, Hollomon J H. Problems in non -elastic deformation of metals[J]. J Appl Pbys,1946,17(2) : 69 -82.

二级参考文献35

  • 1赵冬梅,董企铭,刘平,金志浩,康布熙.高强高导铜合金合金化机理[J].中国有色金属学报,2001,11(z2):21-24. 被引量:124
  • 2黄光胜,汪凌云,陈华,黄光杰,张所全.2618铝合金的热变形和加工图[J].中国有色金属学报,2005,15(5):763-767. 被引量:56
  • 3[1]Anyanwu I A,Kamado S,Kojima Y.Creep properties of Mg-Gd-Y-Zr alloys[J].Materials Transactions,2001,42(1):1212-1218.
  • 4[2]Luo,Alan A.Recent magnesium alloy development for automotive powertrain application[J].Material Science Forum,2003,419-422(1):56-57.
  • 5[3]Drits M E,Sviderkaya Z A,Rokhlin L L,et al.Effect of alloying on properties of Mg-Gd alloys[J].Metallovedenie i Termicheskaya Obrabotka Metallov,1979,11:62-64.
  • 6[4]Shigeru I,Yuuji N,Shigeharu K,et al.Age hardening characteristics and high temperature tensile properties of Mg-Gd and Mg-Dy alloys[J].Journal of Japan Institute of Light Metals,1994,44(1):3-8.
  • 7[5]Nikitina,N I.Recovery after ageing of Mg-Y and Mg-Gd alloys[J].Journal of Alloys and Compounds,1998,279(2):166-170.
  • 8[6]Negishi Y,Nishimura T,et al.Phace diagrams of magnesium-rice portion,aging characteristics and tensile properties of Mg heavy rare earth metal(Gd,Dy)-Nd alloys[J].Keikinzoku/Journal of Japan Institute of Light Metals,1995,45(2):57-63.
  • 9[7]Taniike S,kitaquchi Y,et al.Forgeability of Mg-heavy rare earth metal alloys and aging characteristics and tensile properties of their forged material[J].Keikinzoku/Journal of Japan Institute of Light Metals,1997,47(5):261-266.
  • 10[8]Anyanwu I A,Kitaguchi Y,Harima Y,et al.Proc of Ist Israeli Int Confon Magnesium Science and Technology[A].Ed by E Aghion,Dead Sea,1997:123-132.

共引文献49

同被引文献24

引证文献3

二级引证文献8

材料科学与工艺
2009年 第5期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部