期刊文献+

SnCu钎焊接头稳态蠕变本构方程建立 被引量:3

Foundation of steady state creep constitutive equation of SnCu soldered joints
下载PDF
导出
摘要 以搭接面积为1mm^2微型单搭接钎焊接头为研究对象,采用新型高温蠕变测试装置,测定了SnCu钎焊接头应力指数n和蠕变激活能Q,构建了稳态蠕变本构方程,探讨了蠕变变形机制。结果表明,在低温高应力下,SnCu共晶钎料钎焊接头应力指数为8.73,激活能在59.1~63.2kJ/mol,位错攀移运动主要受位错管道扩散机制控制;在高温低应力区,SnCu共晶钎料钎焊接头应力指数为6.45,激活能在88.4~97.5kJ/mol,位错攀移运动主要由晶格自扩散机制控制。 SnCu eutectic solder alloys have been regarded as one of the most promising Pb-free substitutes for the SnPb solders for its low cost and good mechanical properties.Creep property of solder alloys is one of the important factors to affect the reliability of soldered joints.A novel high temperature creep strain equipment was used to test stress exponent and creep activation energy of single shear lap creep specimens of SnCu eutectic soldered joints with a 1 mm2 cross-sectional area.The final constitutive equation of the composite soldered joints was established and its creep mechanism was investigated.Results indicate under low temperature and high stress,the stress exponents of the soldered joints is 8.73,and the creep activation energies is varied in 59.1-63.2 kJ/mol.The dislocation climbing is dominated by dislocation pipe diffusion process.Under high temperature and low stress,the stress exponents of the soldered joints is 6.45 and the creep activation energies is varied from 88.4-97.5 kJ/mol.The dislocation climbing is dominated by the lattice self-diffusion process.
出处 《焊接学报》 EI CAS CSCD 北大核心 2007年第9期75-79,共5页 Transactions of The China Welding Institution
基金 河南省科技攻关项目资助(072102260016) 河南科技大学校基金资助(13420060)
关键词 SnCu钎料 应力指数 激活能 蠕变本构方程 蠕变变形机制 SnCu solder stress exponent activation energy steady-state creep constitutive equation creep mechanism
  • 相关文献

参考文献13

  • 1Hunt C,Lea D.Solderability of lead-free alloys[C]// Proceedings of Apex 2000,Long Beach,CA.March 2000:1238-1244.
  • 2Anderson I E,Bloomer T E,Terpstra R L,et al.Development of eutectic and near-eutectic tin silver copper solder alloys for lend-free electronic assemblies[C]// IPC Works' 99:An International Summit on Lead-free Electronics Assemblies,Minneapolis,MN.1999:116-121.
  • 3Hampshire W B.The search for lead-free solders[C]// Proceeding of Surface Mount Intemational Conference,San Jose,CA.September 1992:729-738.
  • 4Song H G,Morris J W Jr,Hua F.The creep properties of lead-free solder joints[J].Journal of Minerals,Metals and Materials,2002,6:30-36.
  • 5Kuo C G,Sastry S M L,Jerina K L.Creep-fatigue life prediction of in-situ composite solders[J].Metallurgy Material of Transation,1995,A26(12):32-64.
  • 6Knecht S,Fax L R.Constitutive relation and creep fatigue life model for eutectic tin-lead solder[R].IEEE CHMT-A.1993,13:424-433.
  • 7Frost H J,Ashby M F.Deformation mechanism maps-the plasticity and creep of metals and ceramics[M].Pergamon Press.New York,1982.
  • 8Shi X Q,Wang Z P,Zhou W,et al.A new creep constitutive model for eutectic solder alloy[J].Journal of Electronic Packaging,2002,124:84-90.
  • 9陈志刚.SnAgCu稀土钎料合金高温蠕变行为力学及冶金学研究[D].北京:北京工业大学,2003.
  • 10Cadek J.Creep in metallic materials[M].Amsterdam:Elsevier.1988.

同被引文献30

引证文献3

二级引证文献18

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