焊接学报 >

2023 , Vol. 44 >Issue 4: 39 - 44

DOI: https://doi.org/10.12073/j.hjxb.20220511003

高性能焊接

激光摆动焊接工艺参数对不锈钢焊缝成形与气孔率的影响

  • 夏佩云 ,
  • 封小松 ,
  • 王春明 ,
  • 徐程 ,
  • 黄珲 ,
  • 何建利
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  • 1. 华中科技大学, 武汉, 430074;
    2. 上海航天设备制造总厂有限公司, 特种焊接技术创新中心, 上海, 200245
夏佩云,博士研究生,高级工程师;主要研究方向为激光加工、搅拌摩擦焊;Email:xpypei@126.com

收稿日期: 2023-05-11

  网络出版日期: 2024-02-04

基金资助

上海市国际合作资助项目(19190730100)

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Effect of parameters on weld formation and porosity of stainless steel in laser oscillating welding

  • XIA Peiyun ,
  • FENG Xiaosong ,
  • WANG Chunming ,
  • XU Cheng ,
  • HUANG Hui ,
  • HE Jianli
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  • 1. Huazhong University of Science and Technology, Wuhan, 430074, China;
    2. Special Welding Technology Innovation Center, Shanghai Aerospace Equipments Manufacturer Co., Ltd., Shanghai, 200245, China

Received date: 2023-05-11

  Online published: 2024-02-04

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摘要

采用激光摆动焊接实现了5 mm厚1Cr18Ni9Ti不锈钢的焊接,获得成形良好、低气孔率的接头.分析了焊接速度、摆动幅值、摆动频率、摆动形式对焊缝成形和气孔率的影响,从匙孔、熔池流动、气泡逸出的角度揭示了工艺参数影响气孔率的主要机理. 结果表明,对于5 mm厚不锈钢激光摆动焊接,适当提高焊接速度和摆动幅值,更利于减小气孔率;激光摆动频率在100 ~ 300 Hz可以兼顾较低气孔率和较好的焊缝成形;“8”形摆动激光可以获得相对较优的焊缝成形,焊缝气孔率最低,达到2.94%;而线性摆动激光获得焊缝成形最差,气孔率最高,达到19.13%.

关键词: 激光摆动焊接; 中厚不锈钢板; 摆动参数; 焊缝成形; 气孔率

本文引用格式

夏佩云 , 封小松 , 王春明 , 徐程 , 黄珲 , 何建利 . 激光摆动焊接工艺参数对不锈钢焊缝成形与气孔率的影响[J]. 焊接学报, 2023 , 44(4) : 39 -44 . DOI: 10.12073/j.hjxb.20220511003

Abstract

Oscillating laser beam was utilized to weld 5 mm thick 1Cr18Ni9Ti stainless steel, and the joint with good appearance and low porosity was obtained. The effects of welding speed, oscillation amplitude, oscillation frequency, and oscillation pattern on weld formation and porosity were analyzed. The main mechanism of porosity suppressing was revealed from the perspectives of keyhole, molten pool flow and bubble overflow. The research results show that appropriately higher value of oscillating amplitude and welding speed were more effective for porosity suppression. There is an optimal range of oscillating frequency to get low porosity. For 5 mm thick stainless steel, when the laser oscillation frequency is 100 − 300 Hz, lower porosity and better weld formation could be obtained. Better weld formation were obtained with the lowest weld porosity of 2.94%, using the “8” shaped oscillating laser. While the worst weld formation was obtained with higher porosity of 19.13% using linear oscillating laser.

Key words: laser oscillation welding; medium thickness stainless steel plate; oscillation parameters; welding formation; porosity

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