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通过分析7075/6009铝合金层状复合板材内层显微组织与显微硬度分布,研究了固溶处理对板材内层显微组织与力学性能的影响。结果表明:在470-500℃范围内,随着固溶温度的升高,板材内层和过渡区的显微硬度值呈先升后降的趋势,在485℃时达到峰值,而外层显微硬度值呈上升趋势;内层显微组织在485℃时残留的颗粒相数量最少,而在500℃时发生"过烧"。在15-300 min内,板材内层和过渡区显微硬度值在30 min时达到峰值,而外层显微硬度值变化不明显;内层显微组织随着固溶时间的延长而变粗大,残留颗粒相数量在30 min后趋于平衡。通过T6热处理工艺:485℃固溶30 min+水淬+175℃时效8 h,7075/6009铝合金层状复合板材可获得较高的力学性能:抗拉强度为404 MPa,屈服强度为364 MPa,伸长率为15.3%;同比T6热处理的6009铝合金板材,其抗拉强度提高36%,屈服强度提高75%,但伸长率降低16%。

7075/6009 aluminum laminated composite plates were prepared by the process of double-stream-pouring continuous casting and hot rolling,and then the composite plates were solution-treated.Microstructure and microhardness distribution of the plates were analyzed.The effect of solution treatment on microstructure and mechanical properties of the plates were investigated.The results show that in the solution temperature of 470 ℃ to 500 ℃,microhardness of the internal layer of the plate increases to the maximum value at 485 ℃ and then dereases with increasing of temperature,and microhardness of the outer layer increases as the solution temperature is enhanced.The amount of the residual precipitated phase in the internal layer is the least as the solution temperature is 485 ℃,and the overburnt microstructure of the internal layer is observed at 500 ℃.Microhardness of the internal layer reaches the peak value and the amount of the precipitated phase particles approaches stable for the plates solution-treated at 485 ℃ for 30 min.Optimal mechanical properties of the 7075/6009 aluminum laminated plates could be obtained by T6 heat treatment,which is solution-treated at 485 ℃ for 30 min,following by cooling in water and artificial ageing at 175 ℃ for 8 h.Tensile strength,yield strength and elongation of the plates are 404 MPa,364 MPa and 15.3%,respectively.Comparing with the T6 heat-treated 6009 aluminum plate,the ultimate tensile strength and yield strength increase by 36% and 75%,respectively,however the elongation is 84 % of that of 6009 aluminum plate.

参考文献

[1] Jang-Kyo Kim;Tong-Xi Yu .Forming and failure behaviour of coated,laminated and sandwiched sheet metals a review[J].Journal of Materials Processing Technology,1997,63(1-3):33-42.
[2] LI Yuan-yuan;ZHANG Wei-wen;CHEN Wei-ping .Preparation and tensile property of a high-strength,anticorrosion functionally graded,2024/3003 composite[J].Journal of Materials Science,2004,39(16-17):5607-5609.
[3] Y.X. Zhang;C.H. Yang .Recent Developments In Finite Element Analysis For Laminated Composite Plates[J].Composite structures,2009(1):147-157.
[4] Grishaber RB;Sergueeva AV;Mishra RS;Mukherjee AK .Laminated metal composites - High temperature deformation behavior[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2005(1/2):17-24.
[5] Metin Aydogdu .A new shear deformation theory for laminated composite plates[J].Composite structures,2009(1):94-101.
[6] YU G .Met hod for manufacturing gradient material by continuous and semi-continuous casting[P].US,6089309,2000.
[7] 张卫文;张大童;龙雁 等.高强耐蚀复合铝合金材料[P].中国,ZL02115163.6,2002—12—25.
[8] 张卫文,李元元,龙雁,吴苑标,邵明.半连续铸造法制备AlCu/Al梯度材料[J].中国有色金属学报,2002(z1):188-191.
[9] 郑小平 .梯度复合7075/6009铝合金材料的制备与力学性能研究[D].华南理工大学,2009.
[10] LI Yuan-yuan,ZHENG Xiao-ping,ZHANG Wei-wen,LUO Zong-qiang.Effect of deformation temperature on microstructures and properties of 7075/6009 alloy[J].中国有色金属学报(英文版),2009(05):1037-1043.
[11] 郑小平,张卫文,王郡文,邵明,李元元.内熔体浇口位置对7075/6009合金铸锭成分和内层组织的影响[J].中国有色金属学报,2009(01):26-31.
[12] 陈康华,刘红卫,刘允中.升温固溶对Al-Zn-Mg-Cu合金组织与力学性能的影响[J].中南工业大学学报(自然科学版),2000(04):339-341.
[13] 陈康华,刘允中,刘红卫.7075和2024铝合金的固溶组织与力学性能[J].中国有色金属学报,2000(06):819.
[14] 林高用,彭大暑,魏圣明,韩红阳,张辉.强化固溶处理对7075铝合金组织的影响[J].金属热处理,2002(11):30-33.
[15] 王祝堂;田荣章.铝合金及其加工手册(第二版)[M].长沙:中南大学出版社,2000
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