7075高强铝合金激光填丝焊接组织与力学性能研究*

doi:10.11896/j.issn.1005-023X.2017.012.013

《材料导报》期刊社

2017, Vol. 31

Issue (12): 60-63 https://doi.org/10.11896/j.issn.1005-023X.2017.012.013

材料研究

7075高强铝合金激光填丝焊接组织与力学性能研究^*

杨智华¹, 杨尚磊^1,2, 姜亦帅¹, 王妍¹

1 上海工程技术大学材料工程学院, 上海 201620;
2 上海市高强激光智能加工装备关键技术产学研开发中心, 上海 201620

Microstructure and Mechanical Properties of Laser Welding Joints of 7075 Aluminum Alloy with Filler Wire

YANG Zhihua¹, YANG Shanglei^1,2, JIANG Yishuai¹, WANG Yan¹

1 School of Materials Engineering,Shanghai University of Engineering Science, Shanghai 201620;
2 Shanghai Research & Development Center for Key Technologies of Ultra-Intense Laser Processing, Shanghai 201620

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摘要采用光纤激光器对4 mm厚的7075铝合金进行激光填丝焊接,对焊接接头的显微组织、相结构、断口形貌、力学性能进行观察和分析。结果表明:焊缝(FZ)边缘组织为柱状枝晶组织,焊缝中心为等轴晶组织;热影响区(HAZ)保留了母材(BM)的轧制长条状形态,但晶粒有所长大。母材的相组成主要为α-Al固溶体、S-Al₂CuMg强化相和η-MgZn₂强化相,焊缝无强化相析出。焊缝区硬度值为各区中最低,热影响区显微硬度呈阶梯式增长。焊接速度为2~4 m/min的接头拉伸试样均在焊缝处断裂,抗拉强度最大为母材的67.5%。接头拉伸试样均出现了颈缩现象,断口由大量的等轴状韧窝构成,为韧性断裂。

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关键词: 7075铝合金激光填丝焊接微观组织力学性能

Abstract: 7075 aluminum alloy with the thickness of 4 mm was welded with filler wire by the fiber laser equipment. The microstructure, phase structure, fracture morphology and mechanical properties of welding joints were observed and analyzed.The results showed that the edge of the fusion zone (FZ) was mainly columnar dendrite grains,and the center of FZ was mainly equiaxial grains.The microstructure in the heated-affected zone (HAZ) was fibrous along the rolling direction, and the grains in the HAZ were slightly coarsened compared with those in base metal (BM). The phase of BM was mainly composed of α-Al solid solution, the precipitation of S-Al₂CuMg and η-MgZn₂, but no precipitation was found in FZ.The microhardness value of FZ is the lowest in the welding joint, and a step increase of the microhardness occurred in HAZ.All of the tensile samples which were welded at welding speed from 2 m/min to 4 m/min fractured at FZ, among which the highest tensile strength was 67.5% of BM.The necking phenomenon occurred at the welding joint of all the tensile samples, and the fracture surface was mainly composed of the equiaxed dimples, which is the typical characteristic of ductile fracture.

Key words: 7075 aluminum alloy laser welding with filler wire microstructure mechanical property

出版日期: 2017-06-25 发布日期: 2018-05-08

ZTFLH:

TG456.7

基金资助: *上海市自然科学基金(14ZR1418800);上海汽车工业科技发展基金(1404);上海工程技术大学研究生科研创新项目(15KY0513)

通讯作者: 杨尚磊:通讯作者,男,1968年生,博士,教授,主要研究方向为材料的高能束加工及疲劳性能 E-mail:yslei@126.com

作者简介: 杨智华:男,1992年生,硕士研究生,研究方向为金属材料激光焊接技术 E-mail:zhi_hua_yang@126.com

引用本文:

杨智华, 杨尚磊, 姜亦帅, 王妍. 7075高强铝合金激光填丝焊接组织与力学性能研究^*[J]. 《材料导报》期刊社, 2017, 31(12): 60-63.
YANG Zhihua, YANG Shanglei, JIANG Yishuai, WANG Yan. Microstructure and Mechanical Properties of Laser Welding Joints of 7075 Aluminum Alloy with Filler Wire. Materials Reports, 2017, 31(12): 60-63.

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https://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2017.012.013 或 https://www.mater-rep.com/CN/Y2017/V31/I12/60

1 Taub A I,Luo A A.Advanced lightweight materials and manufactu-ring processes for automotive applications[J].MRS Bull,2015,40(12):1045.
2 Guo Yuqin,Zhu Xinfeng,Yang Yan,et al.Research state of lightweight material and manufacture processes in automotive industry[J].Forging Stamping Technol,2015,40(3):1(in Chinese).
郭玉琴,朱新峰,杨艳,等.汽车轻量化材料及制造工艺研究现状[J].锻压技术,2015,40(3):1.
3 Jr M C S,Machado A R,Sales W F,et al.Machining of aluminum alloys: A review[J].Int J Adv Manuf Technol,2016,86(9):3067.
4 Yang Shoujie,Dai Shenglong.A glimpse at the aluminum development and application of alloys in aviation industry[J].Mater Rev,2005,19(2):76(in Chinese).
杨守杰,戴圣龙.航空铝合金的发展回顾与展望[J].材料导报,2005,19(2):76.
5 Dursun T,Soutis C.Recent developments in advanced aircraft aluminium alloys[J].Mater Des,2014,56(4):862.
6 Xu Jun,Zhao Jingsong,Wu Weizhi.Application of aluminum alloy to the bicycle[J].Nonferr Met Process,2012,41(4):10(in Chinese).
徐军,赵京松,吴维治.铝合金在自行车上的应用[J].有色金属加工,2012,41(4):10.
7 Yang Shanglei,Meng Lichun,Lv Renyuan,et al.Pulsed MIG welding of A6N01 Al alloy used in high-speed vehicle [J].Weld Joining,2008(9):33(in Chinese).
杨尚磊,孟立春,吕任远,等.高速车辆用A6N01铝合金的脉冲MIG焊[J].焊接,2008(9):33.
8 Chen Cheng,Xue Songbai,Sun Huhao,et al.Microstructure and mechanical properties of 5083 aluminum alloy joint by TIG welding[J].Trans China Weld Inst,2014(1):37(in Chinese).
陈澄,薛松柏,孙乎浩,等.5083铝合金TIG焊接头组织与性能分析[J].焊接学报,2014(1):37.
9 Rhodes C G,Mahoney M W,et al.Effects of friction stir welding on microstructure of 7075 aluminum[J].Scr Mater,1997,36(1):69.
10 Hu B,Richardson I M.Hybrid laser/GMA welding aluminium alloy 7075[J].Weld World,2006,50(7-8):51.
11 Kong Xiaofang.Research on technology and microstructures and mechanical properties of fiber laser welded 5083 aluminum alloy[D].Beijing:Beijing University of Technology,2014(in Chinese).
孔晓芳.5083铝合金光纤激光焊接工艺及接头组织性能研究[D].北京:北京工业大学,2014.
12 Ola O T,Doern F E.Fusion weldability studies in aerospace AA7075-T651 using high-power continuous wave laser beam techniques[J].Mater Des,2015,77:50.
13 Peng Jian,Zhou Chou,Zhang Dingfei.Microstructure and properties of welded joints of 6N01 aluminum alloy[J].Heat Treatment Met,2010,35(11):33(in Chinese).
彭建,周绸,张丁非.高速列车用6N01铝合金焊接接头的组织与性能[J].金属热处理,2010,35(11):33.
14 Tuo Wenhai,Yang Shanglei,Yang Wentao,et al.Microstructure and fatigue performance of MIG welded joint of 6082-T6 aluminum alloy used for rail transportation[J].Mater Rev:Res,2015,29(10):105(in Chinese).
庹文海,杨尚磊,杨文涛,等.轨道交通用6082-T6铝合金MIG焊接接头组织与疲劳性能[J].材料导报:研究篇,2015,29(10):105.
15 Yan S,Chen H,Ma C,et al.Local corrosion behaviour of hybrid laser-MIG welded Al-Zn-Mg alloy joints[J].Mater Des,2015,88:1353.

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