[1]王维贤,庄明祥,刘波,等.30 mm退火态TC4钛合金EBW接头组织与性能研究[J].焊管,2023,46(3):13-19.[doi:10.19291/j.cnki.1001-3938.2023.03.003]
 WANG Weixian,ZHUANG Mingxiang,LIU Bo,et al.Microstructure and Properties of 30 mm Annealed TC4 Titanium Alloy EBW Joints[J].,2023,46(3):13-19.[doi:10.19291/j.cnki.1001-3938.2023.03.003]
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30 mm退火态TC4钛合金EBW接头组织与性能研究()
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《焊管》[ISSN:1001-3938/CN:61-1160/TE]

卷:
46
期数:
2023年第3期
页码:
13-19
栏目:
试验与研究
出版日期:
2023-03-28

文章信息/Info

Title:
Microstructure and Properties of 30 mm Annealed TC4 Titanium Alloy EBW Joints
文章编号:
10.19291/j.cnki.1001-3938.2023.03.003
作者:
王维贤庄明祥刘波刘永强
中航西安飞机工业集团股份有限公司,西安 710089
Author(s):
WANG Weixian ZHUANG Mingxiang LIU Bo LIU Yongqiang
AVIC Xi’an Aircraft Industry Group Co., Ltd., Xi’an 710089, China
关键词:
TC4钛合金电子束焊接显微组织力学性能
Keywords:
TC4 titanium alloy electron beam welding microstructure mechanical properties
分类号:
TG406
DOI:
10.19291/j.cnki.1001-3938.2023.03.003
文献标志码:
A
摘要:
为了提升钛合金的焊接效率和质量,采用电子束焊接方式对30 mm退火态TC4钛合金进行焊接试验,并对焊接接头进行力学性能检测、显微组织分析及残余应力测试,通过扫描电镜对断口形貌进行分析,研究完全退火态TC4钛合金EBW接头组织与性能。结果表明,接头焊缝区由针状马氏体α′相和分布在原始β晶界的α相组成,接头热影响区由初生α相、针状马氏体α′相以及少量β相组成。EBW接头抗拉强度平均值略高于母材,EBW接头第二层焊缝区及热影响区冲击功均低于母材,同时两种接头断口形貌均发现大量韧窝,为韧性断裂。接头最大残余拉应力值约为150 MPa,在平行和垂直焊接方向,残余拉应力最大值均出现在焊缝上表面附近区域,而残余压应力最大值均出现在焊缝下表面附近区域。
Abstract:
In order to improve the welding efficiency and quality of titanium alloy, the electron beam welding was used to weld the 30 mm annealed TC4 titanium alloy, and the mechanical properties, microstructure and residual stress of the welded joint were tested. The fracture morphology was analyzed by scanning electron microscope, and the microstructure and properties of the fully annealed TC4 titanium alloy EBW joint were studied. The results show that the joint weld zone is composed of acicular martensite α ’phase and α phase distributed in the original β grain boundary, the joint heat affected zone is composed of α phase, acicular martensite α′ phase and small amount β phase composition. The average tensile strength of EBW joint is slightly higher than that of the base metal. The impact energy of the second layer of weld zone and heat affected zone of EBW joint is lower than that of the base metal. Meanwhile, a large number of dimples are found on the fracture morphology of both joints, which is ductile fracture. The maximum residual tensile stress of the joint is about 150 MPa. In the parallel and vertical welding directions, the maximum residual tensile stress appears near the upper surface of the weld, while the maximum residual compressive stress appears near the lower surface of the weld.

参考文献/References:

[1]孙文君,王善林,陈玉华,等.钛合金先进焊接技术研究现状[J].航空制造技术,2019,62(18):63-72.[2]赵永庆.我国创新研制的主要船用钛合金及其应用[J].中国材料进展,2014,33(7):398-404.[3]于振涛,余森,程军,等.新型医用钛合金材料的研发和应用现状[J].金属学报,2017,53(10):1238-1264.[4]庄明祥,赵安安,王浩军,等.TC4钛合金电子束焊接头低周疲劳性能与断裂行为[J].试验研究,2022(2):39-55.[5]0HKUBO M.Welding and joining methods-3.electron beam welding [J].Journal of Light Metal Welding and Construction,2002,40(10):488-490.[6]李晓延,巩水利,关桥,等.大厚度钛合金结构电子束焊接制造基础研究[J].焊接学报,2010,31(2):107-112.[7]SARESH N,PILLAI M G,MATHEWJ.Investigations into the effects of electron beam welding on thick Ti-6A1-4V titanium alloy[J].Journal of Materials Processing Tech.,2007(192-193):83-88.[8]高福洋,廖志谦,李文亚.钛及钛合金焊接方法与研究现状[J].航空制造技术,2012(23):86-90.[9]吴会强,冯吉才,何景山,等.Ti-6Al-4V 电子束焊接焊缝区域精细组织特征[J].航空材料报,2005(25):21-24.[10]韩忠,林海潮.钛合金电子束焊缝金属微观结构的TEM观察[J].电子显微学报,1998,18(5):536-539.[11]THOMAS S G,RAMACHANDRA V,GANESHAN R.Effect of pre?nd post?eld heat treatments on the mechanical properties of electron beam welded Ti-6Al-4V alloy[J].Materials Science,1993(28):4892-489.[12]SAHOO S, CHOU K. Phase?ield simulation of microstructure evolution of Ti-6A1-4V in electron beam additive manu?acturing process[J]. Additive Manufacturing, 2016(9):14-24.[13]高福洋,高奇,蒋鹏,等.超大厚度钛合金电子束焊接熔合区精细组织表征[J].中国科学,2017,47(9):941-945.[14]张代东,吴润.材料科学基础[M].北京:北京大学出版社,2011:304.

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备注/Memo

备注/Memo:
收稿日期:2022-09-18作者简介:王维贤(1994—),男,助理工程师,主要从事结构件焊接研究工作。
更新日期/Last Update: 2023-03-23