激光入射角影响焊接熔池匙孔瞬态行为数值模拟

doi:10.3901/JME.2020.22.082

机械工程学报 ›› 2020, Vol. 56 ›› Issue (22): 82-89.doi: 10.3901/JME.2020.22.082

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激光入射角影响焊接熔池匙孔瞬态行为数值模拟

高向东¹, 冯燕柱¹, 桂晓燕¹, 彭聪¹, 张艳喜¹, 潘春荣²

1. 广东工业大学广东省焊接工程技术研究中心广州 510006;
2. 江西理工大学机电工程学院赣州 341000

收稿日期:2020-01-07 修回日期:2020-05-27 出版日期:2020-11-20 发布日期:2020-12-31
通讯作者: 高向东(通信作者),男,1963年出生,博士,教授,博士研究生导师。主要从事焊接自动化方面的研究。E-mail:gaoxd@gdut.edu.cn
作者简介:冯燕柱,男,1993年出生。主要从事激光焊接数值模拟方面的研究。E-mail:1549080499@qq.com
基金资助:
国家自然科学基金（51675104）、广州市科技计划（202002020068，202002030147）和广东省教育厅创新团队（2017KCXTD010）资助项目。

Numerical Simulation of Effects of Laser Incident Angle on Transient Behaviors of Molten Pool and Keyhole during Laser Welding

GAO Xiangdong¹, FENG Yanzhu¹, GUI Xiaoyan¹, PENG Cong¹, ZHANG Yanxi¹, PAN Chunrong²

1. Guangdong Provincial Welding Engineering Technology Research Center, Guangdong University of Technology, Guangzhou 510006;
2. School of Mechanical and Electrical Engineering, Jiangxi University of Science and Technology, Ganzhou 341000

Received:2020-01-07 Revised:2020-05-27 Online:2020-11-20 Published:2020-12-31

摘要/Abstract

摘要： 在激光焊接中，激光入射角直接影响着熔池匙孔瞬态行为，而仅采用工艺试验方法难以探索其规律。利用数值模拟技术模拟激光入射角分别为30°、0°、-30°的焊接过程，研究激光入射角对熔池匙孔瞬态行为的影响。同时通过激光焊接试验对仿真结果进行验证，数值仿真的焊缝横截面形貌与试验结果吻合较好，表明仿真结果能够反映激光焊接过程。分析不同激光入射角下温度场、熔池内流场、匙孔后壁反冲压力、匙孔深度和匙孔后壁静压力的变化。结果表明，激光入射角的正负影响熔池内部流动的快慢；激光入射角为正时，有利于抑制飞溅形成，而激光入射角为负时，则促进飞溅生成；激光入射角的正负明显影响匙孔的稳定性，当激光入射角为负时，匙孔稳定性降低，坍塌频率增加，产生气泡的概率提高。使用合适的激光正入射角有利于提高激光焊接质量。

关键词: 激光焊接, 激光入射角, 熔池, 匙孔

Abstract: The laser incident angle affects the transient behaviors of a molten pool and keyhole in the process of laser welding. However, it is difficult to investigate its impact rule only by using technical experimental methods. Three processes of laser welding with the laser incident angle of 30°, 0°, -30° are respectively simulated by the numerical simulation technology to study the effects of laser incident angle on transient behaviors of a molten pool and keyhole. At the same time, the simulated results are validated through the laser welding experiments. The cross-section geometry of simulated welds agrees well with the experimental results, which indicates that the simulated results can represent the laser welding process. The variations of temperature field, flow field in a molten pool, recoil force on the rear keyhole wall, the depth of keyhole and static pressure on the rear keyhole wall are analyzed at different laser incident angles. The results show that when the laser incident angle is positive, the flow is slow in a molten pool, when it is negative, the flow is faster. Also it can be found that the positive incident angle welding is helpful to suppress the formation of spatters, while the negative promotes the generation of spatters. When the laser incident angle is positive, the stability of a keyhole increases. When it is negative, the stability of a keyhole decreases, and the collapse of a keyhole increases which raises the probability of bubbles generation. Thus, it is shown that the laser welding quality can be improved with a suitable positive laser incident angle.

Key words: laser welding, laser incident angle, molten pool, keyhole

中图分类号:

TG456

高向东, 冯燕柱, 桂晓燕, 彭聪, 张艳喜, 潘春荣. 激光入射角影响焊接熔池匙孔瞬态行为数值模拟[J]. 机械工程学报, 2020, 56(22): 82-89.

GAO Xiangdong, FENG Yanzhu, GUI Xiaoyan, PENG Cong, ZHANG Yanxi, PAN Chunrong. Numerical Simulation of Effects of Laser Incident Angle on Transient Behaviors of Molten Pool and Keyhole during Laser Welding[J]. Journal of Mechanical Engineering, 2020, 56(22): 82-89.

参考文献

[1] ZHANG Yi,LIU Tongwei,LI Bin,et al. Simultaneous monitoring of penetration status and joint tracking during laser keyhole welding[J]. IEEE/ASME Transactions on Mechatronics,2019,24(4):1732-1742.
[2] GAO X,YOU D,KATAYAMA S. Seam tracking monitoring based on adaptive kalman filter embedded elman neural network during high-power fiber laser welding[J]. IEEE Transactions on Industrial Electronics,2012,59(11):4315-4325.
[3] AI Yuewei,JIANG Ping,WANG Chunming,et al. Investigation of the humping formation in the high power and high speed laser welding[J]. Optics and Lasers in Engineering,2018,107:102-111.
[4] 王煜,高向东,陈子琴,等. 激光-MAG复合焊接过程金属蒸气和背部熔池图像分析[J]. 机械工程学报,2019,55(19):167-173. WANG Yu,GAO Xiangdong,CHEN Ziqin,et al. Analysis of the images of metal vapor and bottom-molten pool in laser-MAG hybrid welding process[J]. Journal of Mechanical Engineering,2019,55(19):167-173.
[5] DAL M,FABBRO R. An overview of the state of art in laser welding simulation[J]. Optics and Laser Technology,2016,78:2-14.
[6] 武传松,孟祥萌,陈姬,等. 熔焊热过程与熔池行为数值模拟的研究进展[J]. 机械工程学报,2018,54(2):1-15. WU Chuansong,MENG Xiangmeng,CHEN Ji,et al. Progress in numerical simulation of thermal processes and weld pool behaviors in fusion welding[J]. Journal of Mechanical Engineering,2018,54(2):1-15.
[7] ZHANG Dabin,WANG Meng,SHU Chengsong,et al. Dynamic keyhole behavior and keyhole instability in high power fiber laser welding of stainless steel[J]. Optics and Laser Technology,2019,114:1-9.
[8] AI Yuewei,JIANG Ping,WANG Chunming,et al. Experimental and numerical analysis of molten pool and keyhole profile during high-power deep-penetration laser welding[J]. International Journal of Heat and Mass Transfer,2018,126(A):779-789.
[9] WU Dongsheng,HUA Xueming,HUANG Lijing,et al. Numerical simulation of spatter formation during fiber laser welding of 5083 aluminum alloy at full penetration condition[J]. Optics and Laser Technology,2018,100:157-164.
[10] LIANG Rong,LUO Yu,LI Zhuguo. The effect of humping on residual stress and distortion in high-speed laser welding using coupled CFD-FEM model[J]. Optics and Laser Technology,2018,104:201-205.
[11] ZHANG Y,HAN S,CHEON J,et al. Effect of joint gap on bead formation in laser butt welding of stainless steel[J]. Journal of Materials Processing Technology,2017,249:274-284.
[12] LUO Manlelan,HU Renzhi,LI Quanhong,et al. Physical understanding of keyhole and weld pool dynamics in laser welding under different water pressures[J]. International Journal of Heat and Mass Transfer,2019,137:328-336.
[13] LI Liqun,PENG Genchen,WANG Jiming,et al. Numerical and experimental study on keyhole and melt flow dynamics during laser welding of aluminium alloys under subatmospheric pressures[J]. International Journal of Heat and Mass Transfer,2019,133:812-826.
[14] 陈根余,康斌,张屹,等. 光纤激光入射角对高强钢对接焊焊接性能的影响[J]. 中国激光,2012,39(1):104-109. CHEN Genyu,KANG Bin,ZHANG Yi,et al. Effects of incident angle on welding performance of fiber laser butt welding of high-strength automobile steel[J]. Chinese Journal of Lasers,2012,39(1):104-109.
[15] LIN Runqi,WANG Huiping,LU Fenggui,et al. Numerical study of keyhole dynamics and keyhole-induced porosity formation in remote laser welding of Al alloys[J]. International Journal of Heat and Mass Transfer,2017,108(A):244-256.
[16] RODRIGUEZ-VIDAL E,SANZ C,SORIANO C,et al. Effect of metal micro-structuring on the mechanical behavior of polymer-metal laser T-joints[J]. Journal of Materials Processing Technology,2016,229:668-677.
[17] ZHANG Mingjun,CHEN Shun,ZHANG Yingzhe,et al. Mechanisms for improvement of weld appearance in autogenous fiber laser welding of thick stainless steels[J]. Metals,2018,8(8):625-637.
[18] GAO Zhongmei,JIANG Ping,MI Gaoyang,et al. Investigation on the weld bead profile transformation with the keyhole and molten pool dynamic behavior simulation in high power laser welding[J]. International Journal of Heat and Mass Transfer,2018,116:1304-1313.
[19] CHO W,NA S,THOMY C,et al. Numerical simulation of molten pool dynamics in high power disk laser welding[J]. Journal of Materials Processing Technology,2012,212(1):262-275.
[20] ZHANG Ruolin,TANG Xinhua,XU Lidong,et al. Study of molten pool dynamics and porosity formation mechanism in full penetration fiber laser welding of Al-alloy[J]. International Journal of Heat and Mass Transfer,2020,148:119089.
[21] HAN S,AHN J,NA S. A study on ray tracing method for CFD simulations of laser keyhole welding:Progressive search method[J]. Welding in the World,2016,60(2):247-258.

激光入射角影响焊接熔池匙孔瞬态行为数值模拟

Numerical Simulation of Effects of Laser Incident Angle on Transient Behaviors of Molten Pool and Keyhole during Laser Welding

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