预成形和热处理工序对2219铝合金旋压薄壁结构应力分布的影响

doi:10.3901/JME.2025.22.057

机械工程学报 ›› 2025, Vol. 61 ›› Issue (22): 57-68.doi: 10.3901/JME.2025.22.057

• 材料科学与工程 • 上一篇

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预成形和热处理工序对2219铝合金旋压薄壁结构应力分布的影响

卢书林¹, 王建峰¹, 占小红¹, 段宇航¹, 程立宏¹, 黄舒文¹, 赵耀邦²

1. 南京航空航天大学材料科学与技术学院南京 211106;
2. 上海航天精密机械研究所上海 201600

收稿日期:2024-12-10 修回日期:2025-06-15 发布日期:2026-01-10
作者简介:卢书林,男,2000年出生。主要研究方向为材料加工仿真。E-mail:lushulin_nuaa@163.com
王建峰(通信作者),男,1989年出生,博士,副教授,博士研究生导师。主要研究方向为激光焊接及再制造技术。E-mail:wangjianfeng@nuaa.edu.cn
占小红,男,1979年出生,博士,教授,博士研究生导师。主要研究方向为焊接与先进连接技术、增材制造工艺与装备、材料加工工艺建模与仿真。E-mail:zhanxiaohong@126.com
基金资助:
国防基础科研计划资助项目(JCKY2023605C010)。

Effect of Pre-deformation and Heat Treatment Process on Stress Distribution in Spinning of 2219 Aluminum Alloy Thin-walled Components

LU Shulin¹, WANG Jianfeng¹, ZHAN Xiaohong¹, DUAN Yuhang¹, CHENG Lihong¹, HUANG Shuwen¹, ZHAO Yaobang²

1. College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing 211106;
2. Shanghai Spaceflight Precision Machinery Institute, Shanghai 201600

Received:2024-12-10 Revised:2025-06-15 Published:2026-01-10

摘要/Abstract

摘要： 为提高可重复火箭的使用寿命，针对火箭贮箱箱底制造过程中预成形和热处理工序对2219铝合金旋压薄壁结构残余应力的影响开展研究。基于Abaqus软件建立考虑预成形和热处理的旋压仿真模型，通过预定义场实现应力及变形的仿真结果传递，并采用盲孔法进行试验验证。对比有无预成形工序的旋压仿真结果，发现“预成形+旋压”零件中部区域应变更为均匀，壁厚变化较小，减薄率降低达5.2%，这是由于预成形作用下，后续旋压工序变形量减小，旋压过程变形更稳定。无预成形工序的“单旋压”零件在外沿部位存在由应力集中区域组成的应力环，最大残余应力值为173.9 MPa。相比之下，“预成形+旋压”零件的应力环受预成形工序引入应力的影响，最大残余应力增大41.3%，可达245.7 MPa，但是应力环分布更加均匀且宽度减小，应力集中区域细化。随后对“预成形+旋压”零件施加热处理，结果表明，热处理对应变及减薄率影响不显著，但可使旋压后的残余应力显著降低63.5%，有助于缓解旋压引起的应力集中现象，使残余应力分布均匀化。

关键词: 铝合金, 金属旋压, 预成形, 热处理, 残余应力

Abstract: In order to prolong the service life of repeatable rocket, the effects of pre-deformation and heat treatment processes on the residual stress of 2219 aluminum alloy spinning thin-walled structure in the manufacturing process of rocket tank bottom were studied.. Based on Abaqus software, a spinning simulation model considering pre-deformation and heat treatment is established. The simulation results of stress and deformation are transmitted by pre-defined field, and the blind hole method is used for experimental verification. Comparing the spinning simulation results with or without pre-deformation process, it is found that the strain in the middle region of the “pre-deformation + spinning” part is more uniform, the wall thickness changes less, and the thinning rate is reduced by 5.2%. This is due to the pre-forming effect, the deformation of the subsequent spinning process is reduced, and the deformation of the spinning process is more stable. Without pre-deformation process, a stress ring composed of stress concentration areas is observed at the outer edge of the “single spinning” parts, and the maximum residual stress value is 173.9 MPa. By contrast, the stress ring of the “pre-deformation + spinning” parts is affected by the pre-deformation process induced stress. The maximum residual stress is increases by 41.3%, up to 245.7 MPa, but the stress ring distribution is more uniform and the width decreases, and the stress concentration area is refined. Subsequently, heat treatment was applied to the “pre-deformation + spinning” parts. The results show that heat treatment has no significant effect on strain and thinning rate, but the residual stress after spinning can be significantly reduced by 63.5%, which is helpful to alleviate the stress concentration caused by spinning and homogenize the residual stress distribution.

Key words: aluminum alloy, metal spinning, pre-deformation, heat treatment, residual stress

中图分类号:

TG306

卢书林, 王建峰, 占小红, 段宇航, 程立宏, 黄舒文, 赵耀邦. 预成形和热处理工序对2219铝合金旋压薄壁结构应力分布的影响[J]. 机械工程学报, 2025, 61(22): 57-68.

LU Shulin, WANG Jianfeng, ZHAN Xiaohong, DUAN Yuhang, CHENG Lihong, HUANG Shuwen, ZHAO Yaobang. Effect of Pre-deformation and Heat Treatment Process on Stress Distribution in Spinning of 2219 Aluminum Alloy Thin-walled Components[J]. Journal of Mechanical Engineering, 2025, 61(22): 57-68.

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预成形和热处理工序对2219铝合金旋压薄壁结构应力分布的影响

Effect of Pre-deformation and Heat Treatment Process on Stress Distribution in Spinning of 2219 Aluminum Alloy Thin-walled Components

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