Si含量对高强高韧7050铝合金组织和力学性能的影响

摘要/Abstract

摘要：

通过熔炼制备8种不同杂质Si含量的7050铝合金，研究了Si含量从0.033%~0.491%的变化对7050铝合金组织和力学性能的影响规律.结果表明：当Si含量增加至0.134%时，合金铸态组织中出现明显的粗大富Si杂质相，并且随Si含量增加，富Si杂质相含量增多；粗大富Si杂质相在均匀化退火、热挤压以及固溶处理过程中都难以溶解，残留在时效态合金组织中；当Si含量增加至0.134%时，时效态合金的室温拉伸强度和塑性明显提高；在Si含量高于0.344%后，Si含量的增加使合金的室温拉伸强度、塑性和断裂韧性都显著降低.为获得最佳的室温强度和塑性，7050铝合金的Si含量应控制在0.121%~0.134%，但要获得更好的断裂韧性，需进一步降低合金中Si含量.

关键词: 7050铝合金, Si含量, 力学性能

Abstract:

Eight kinds of 7050 aluminum alloys with different Si contents have been prepared by cast. The influence of Si contents from 0.033% to 0.491% on microstructures and mechanical properties has been investigated. The results show that significant coarse Si-rich impurity phase has been found in as-cast microstructures when Si content is increased to 0.134%, and the content of this phase is increased with Si content increasing. The coarse Sirich impurity phases are insoluble during homogenizing annealing, hot extrusion and solution treatment, and remain in aged microstructures of alloys. The aged alloy with 0.134%Si has the highest tensile strength and plasticity at room temperature. The strength, plasticity and fracture toughness reduce significantly when Si content is higher than 0.344%. Si content should be controlled in the range of 0.121% to 0.134% to get the best strength and plasticity. To obtain a better fracture toughness, the Si content in the alloy should be further reduced.

Key words: 7050 aluminum alloy, Si content, mechanical properties

中图分类号:

TG 146.2

张克伟1，佘欢2，刘宏亮2，疏达2，王俊2. Si含量对高强高韧7050铝合金组织和力学性能的影响[J]. 上海交通大学学报（自然版）, 2013, 47(11): 1712-1716.

ZHANG Kewei1,SHE Huan2,LIU Hongliang2,SHU Da2,WANG Jun2. Influence of Si Contents on Microstructures and Mechanical Properties of High Strength and Toughness 7050 Aluminum Alloys[J]. Journal of Shanghai Jiaotong University, 2013, 47(11): 1712-1716.

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