TC4钛合金焊后热处理的数值模拟及组织分析

doi:10.13251/j.issn.0254-6051.2024.08.041

金属热处理 ›› 2024, Vol. 49 ›› Issue (8): 242-247.DOI: 10.13251/j.issn.0254-6051.2024.08.041

TC4钛合金焊后热处理的数值模拟及组织分析

谢本昌, 刘馨宇, 张乐, 陈彦孜, 岑耀东, 陈林

内蒙古科技大学材料与冶金学院(稀土学院), 内蒙古包头 014010

收稿日期:2024-03-04 修回日期:2024-06-28 出版日期:2024-08-25 发布日期:2024-09-27
通讯作者: 陈林,教授,硕士生导师,E-mail:chenlin39805@163.com
作者简介:谢本昌(2000—),男,硕士研究生,主要研究方向为金属材料组织性能控制及数值模拟,E-mail:1410091721@qq.com。

Numerical simulation and microstructure analysis of post-weld heat treatment for TC4 titanium alloy

Xie Benchang, Liu Xinyu, Zhang Le, Chen Yanzi, Cen Yaodong, Chen Lin

School of Materials and Metallurgy (School of Rare Earth), Inner Mongolia University of Science and Technology, Baotou Inner Mongolia 014010, China

Received:2024-03-04 Revised:2024-06-28 Online:2024-08-25 Published:2024-09-27

摘要/Abstract

摘要： 使用Ansys软件模拟TC4钛合金焊接及焊后热处理(PWHT)过程,并对焊态及热处理态组织及残余应力变化进行分析。结果表明,焊接过程中各层焊缝由于热输入不同,其温度也不同,其中第1层焊的峰值温度最低(2183.6 ℃),第5层最高(2337.8 ℃),由于各层经历了不同特征的热循环,焊缝区各层马氏体尺寸由19.5 μm向96.2 μm变化。焊后焊缝区主要由α_m相+少量β相+部分α_t相+析出α_g相组成。经PWHT后,接头部分α_m相转变为次生(α+β)相,并由XRD图谱观察到(0002)_α衍射峰发生“峰分裂”,在2θ=39.6°处观察到新峰(110)_β,同时峰半高宽降低5.56%～43.75%,表明TC4钛合金的结晶度随着残余应力的消除而得到改善。焊后残余应力主要集中在焊缝附近,此为易断裂位置。垂直焊接方向的残余应力呈对称分布,与温度场分布规律基本相同,经PWHT后各项残余应力均降低。

关键词: TC4钛合金, 数值模拟, 钨极氩弧焊, 焊后热处理, 显微组织

Abstract: Ansys software was used to simulate the welding and post-weld heat treatment(PWHT) process of the TC4 titanium alloy, and the changes of microstructure and residual stress of the welded and heat treated alloy were analyzed. The results show that during the welding process, the temperature of each layer of the weld varies due to different heat inputs. The peak temperature of the first layer weld is the lowest (2183.6 ℃), and the fifth layer is the highest (2337.8 ℃). Due to the different characteristics of thermal cycles experienced by each layer, the size of martensite in each layer of the weld zone changes from 19.5 μm to 96.2 μm. The weld zone after welding is mainly composed of α_m phase, a small amount of β phase, some α_t phase and precipitated α_g phase. After the PWHT, the α_m phase in the joint transforms into a secondary (α+β) phase, and it is XRD observed that the (0002)_α diffraction peak undergoes peak splitting, a new peak (110)_β appears at 2θ=39.6°, the full width at half maximum decreases by 5.56%-43.75%, indicating that the crystallinity of TC4 titanium alloy is improved with the elimination of residual stress. The residual stress after welding is mainly concentrated near the weld seam, which is a fracture prone location. The residual stress along the direction perpendicular to welding is symmetrically distributed, which is basically the same as the distribution of temperature field. After the PWHT, all the residual stresses are reduced.

Key words: TC4 titanium alloy, numerical simulation, TIG welding, post-weld heat treatment, microstructure

中图分类号:

TG166.5

谢本昌, 刘馨宇, 张乐, 陈彦孜, 岑耀东, 陈林. TC4钛合金焊后热处理的数值模拟及组织分析[J]. 金属热处理, 2024, 49(8): 242-247.

Xie Benchang, Liu Xinyu, Zhang Le, Chen Yanzi, Cen Yaodong, Chen Lin. Numerical simulation and microstructure analysis of post-weld heat treatment for TC4 titanium alloy[J]. Heat Treatment of Metals, 2024, 49(8): 242-247.

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TC4钛合金焊后热处理的数值模拟及组织分析

Numerical simulation and microstructure analysis of post-weld heat treatment for TC4 titanium alloy

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