分别采用冷拉拔和冷轧变形并结合中间退火工艺,制备了丝状和带状形变Cu-8.3Fe-1Ag原位复合材料。用SEM、精密万能试验机、显微硬度计和电阻测量仪对两种变形方式下试样的微观组织、力学性能和导电性能进行了比较研究。微观组织观察表明:冷拉拔和冷轧变形试样的横截面组织形貌有显著差异,前者为基体上分布着弯曲、扭折、交叠的蠕虫状相,后者为基体上定向排列着与冷轧方向平行的平直颗粒相。力学性能和导电率测试结果表明:相同应变量下,冷拉拔变形的抗拉强度、硬度均高于冷轧变形,但二者的导电率几乎相同。应变量达到6.70时,二者的抗拉强度/硬度/导电率分别达到838 MPa/149 HV/58%IACS和924 MPa/160 HV/58%IACS。
Cu-8.3Fe-1Ag in-situ composites with filamentous and flaky reinforcement were prepared by cold-drawing and cold-rolling deformation.Microstructure,mechanical and electrical properties of the composites were investigated by means of SEM,tensile tests,microhardness and electrical conductivity measurements.The microstructure observation shows that the cross-sections of the filamentous and flaky reinforcing phases are significant difference.The cross-section morphology of the filamentous reinforcement Fe is vermiculate in copper matrix and the cross-section morphology of the flaky reinforcement Fe presents strip shape in the copper matrix.Tensile strength,microhardness of the Cu-8.3Fe-1Ag in-situ composites by cold-drawing is higher than that of the cold-rolled ones,however,their electrical conductivity is similar.The tensile strength,microhardness and electrical conductivity are 838 MPa,149 HV and 58%IACS,and 924 MPa,160 HV and 58% IACS,respectively,for the in situ composites prepared by cold-drawing and cold-rolling with strain of 6.7.
参考文献
| [1] | 赵冬梅,董企铭,刘平,金志浩,黄金亮.铜合金引线框架材料的发展*[J].材料导报,2001(05):18-20. |
| [2] | Leprince-Wang Y.;Han K.;Huang Y.;Yu-Zhang K. .Microstructure in Cu-Nb microcomposites[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):214-223. |
| [3] | 刘平.超高强度铜基原位复合材料研究进展[J].金属热处理,2008(01):72-77. |
| [4] | S.I.Hong;M.A.Hill .Microstructural stability and mechanical response of Cu-Ag microcomposite wires[J].Acta materialia,1998(12):4111-4122. |
| [5] | Hong S I;Hill M A .Microstructure and conductivity of Cu-Nb microcomposites fabricated by the bundling and drawing process[J].Scripta Materialia,2001,44:209-215. |
| [6] | 陈小红,刘平,田保红,张毅,贾淑果,任凤章,井晓天.微合金化对Cu-15Cr原位复合材料组织和性能的影响[J].材料热处理学报,2009(02):44-48. |
| [7] | Ge Jiping.MODELLING OF BREAKUP OF Cr FILAMENTS IN WIRE-DRAWN Cu-BASED IN SITU COMPOSITES[J].中国有色金属学会会刊(英文版),1999(02):223-229. |
| [8] | V. Vidal;L. Thilly;S. Van Petegem .Plasticity of nanostructured Cu-Nb-based wires: Strengthening mechanisms revealed by in situ deformation under neutrons[J].Scripta materialia,2009(3):171-174. |
| [9] | 宁远涛,张晓辉,张婕.大变形Cu-10Ag原位纳米纤维复合材料[J].稀有金属材料与工程,2005(12):1930-1934. |
| [10] | Funkenbusch P D;Lee K;Courtney T H .Ductile two-phase alloys:Prediction of strengthening at high strains[J].Metallurgical and MaterialsTransactions A,1987,18:1249-1256. |
| [11] | 王平;崔建忠.金属塑性成形力学[M].北京:冶金工业出版社,2006:88-89. |
| [12] | 康永林.轧制工程学[M].北京:冶金工业出版社,2004:51-52. |
| [13] | 梁耀能;梁思祖;利伯林.机械工程材料[M].广州:华南理工大学出版社,2002:231-232. |
| [14] | Verhoeven J D;Downing H L;Chumbley L S et al.Resistivity and microstruture of heavily drawn Cu-Nb alloys[J].Journal of Applied Physics,1989,65:1293-1301. |
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