Research on Ultrasonic Vibration Stress Control Technology of 5B70 Aluminum Alloy Welds

LI Fagui; LIU Quanshuang; YANG Kai; ZHANG Bin; ZHANG Hengyi; GAO Liguo; LAI Xiaoming; YANG Yinfei

doi:10.16080/j.issn1671-833x.2025.19.118

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Research on Ultrasonic Vibration Stress Control Technology of 5B70 Aluminum Alloy Welds

更新时间：2026-03-27

- Research on Ultrasonic Vibration Stress Control Technology of 5B70 Aluminum Alloy Welds
- Aeronautical Manufacturing Technology Vol. 68, Issue 19, (2025)
- 作者机构：
  
  1. 南京航空航天大学,南京,210016
  2. 北京卫星制造厂有限公司,北京,100094
- 作者简介：
- 基金信息：
- DOI：10.16080/j.issn1671-833x.2025.19.118
  CLC：
- Published：2025
- 稿件说明：
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LI Fagui, LIU Quanshuang, YANG Kai, et al. Research on Ultrasonic Vibration Stress Control Technology of 5B70 Aluminum Alloy Welds[J]. Aeronautical Manufacturing Technology, 2025, 68(19).
DOI：

LI Fagui, LIU Quanshuang, YANG Kai, et al. Research on Ultrasonic Vibration Stress Control Technology of 5B70 Aluminum Alloy Welds[J]. Aeronautical Manufacturing Technology, 2025, 68(19). DOI： 10.16080/j.issn1671-833x.2025.19.118.

摘要

在航天飞船舱体的数控加工中，焊接残余应力是导致舱体加工变形的关键因素。为降低加工变形，本文开展了5B70 铝合金舱体电子束焊缝的超声振动应力调控仿真与试验研究，揭示了振幅与处理次数对焊缝残余应力的影响规律，提出了45 mm厚板材对接焊缝的应力调控工艺方案：超声振幅30 μm、重复处理焊缝正面2 次。应力调控后，焊缝背面表层的横向残余应力σ

和纵向残余应力σ

峰值分别降低了33.94% 和67.05%，均化率分别为22.22% 和22.37%。铣削试验表明，应力调控后的试样在Z方向上的加工变形量减小了64.48%，验证了超声振动调控焊接残余应力对降低舱体加工变形的有效性。

Abstract

Welding residual stress is a critical factor contributing to the deformation of spacecraft cabin bodies during CNC machining. To mitigate such machining deformation

this paper conducts simulation and experimental studies on ultrasonic vibration-based stress regulation of electron beam welds in 5B70 aluminum alloy cabin bodies. This reveals the influence of the law of amplitude and treatment times on weld residual stress. A stress regulation process scheme for 45 mm thick plate butt welds is proposed: An ultrasonic amplitude of 30 μm

with two repeated treatments on the front side of the weld. After stress regulation

the peak values of transverse residual stress σ

and longitudinal residual stress σ

on the back surface of the weld are reduced by 33.94% an

d 67.05%

respectively. And the corresponding homogenization rates are 22.22% and 22.37%

respectively. Milling tests show that the machining deformation of the stress-regulated specimens in the Z-direction is reduced by 64.48%

which validating the efficacy of ultrasonic vibration-based regulation of welding residual stress in reducing cabin body machining deformation.

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