超高功率激光-电弧复合焊接飞溅演化行为及抑制方法

doi:10.3901/JME.2024.16.098

机械工程学报 ›› 2024, Vol. 60 ›› Issue (16): 98-107.doi: 10.3901/JME.2024.16.098

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超高功率激光-电弧复合焊接飞溅演化行为及抑制方法

李艳, 耿韶宁, 蒋平, 李元泰, 顾思远, 王建庄

华中科技大学机械科学与工程学院武汉 430074

收稿日期:2023-11-10 修回日期:2024-04-08 出版日期:2024-08-20 发布日期:2024-10-21
作者简介:李艳,女,1994年出生,博士研究生。主要研究方向为厚壁构件的超高功率激光-电弧复合焊接。E-mail:liyan19mse@hust.edu.cn
蒋平(通信作者),男,1981年出生,博士,教授,博士研究生导师。主要研究方向为激光及其复合能场焊接、智能化焊接、激光高效清洗。E-mail:jiangping@hust.edu.cn
基金资助:
国家自然科学基金(U22A20196，52075201，52188102)和武汉市科技重大专项(2022013202025167)资助项目。

Spatter Evolution Behavior and Suppression Method in Ultra-high Power Laser-arc Hybrid Welding

LI Yan, GENG Shaoning, JIANG Ping, LI Yuantai, GU Siyuan, WANG Jianzhuang

School of Mechanical Science and Engineering, Huazhong University of Science & Technology, Wuhan 430074

Received:2023-11-10 Revised:2024-04-08 Online:2024-08-20 Published:2024-10-21

摘要/Abstract

摘要： 超高功率激光-电弧复合焊接为实现厚壁构件的高效焊接提供有效手段，但面临焊接飞溅严重的问题。针对超高功率激光-电弧复合焊接飞溅问题，开展飞溅演化行为及抑制方法研究，阐明电弧热输入对飞溅的影响及抑制机制，并分析不同电弧热输入对焊缝宏观成形及组织性能的影响。结果表明，电弧热输入增加能显著增大匙孔开度，抑制飞溅形成。电弧热输入由139 J/mm提升至479 J/mm，匙孔开口尺寸由56.57 mm²增至243.29 mm²，匙孔周围熔融金属与金属蒸汽/等离子体间的摩擦剪切力减小，熔融金属柱高度由15.96 mm降至5.27 mm，且在匙孔前沿熔融金属表面张力及流体静压力作用下，熔融金属柱回落至熔池，焊缝表面飞溅数量减少87%，焊缝成形质量显著提高。并发现电弧热输入增加在提高焊缝熔宽熔深同时，虽会导致微观组织粗化、热影响区宽度增加，但所有试样焊缝均表现出良好拉伸性能。超高功率激光-电弧复合焊接过程中飞溅的有效抑制为该技术在厚板焊接领域的工艺参数调控提供数据及理论支撑。

关键词: 超高功率激光-电弧复合焊接, 飞溅形成, 抑制方法, 电弧热输入, 匙孔开口

Abstract: Ultra-high power laser-arc hybrid welding provides an effective method for realizing the efficient welding thick-walled components, however, spatter is a serious problem in this process. Aiming at the spatter problem of ultra-high power laser-arc hybrid welding, the spatter evolution behavior and suppression methods are studied, the influence of arc heat input on the spatter and its suppression mechanism. In addition, the impact of arc heat input on the macroscopic formation, microstructure and mechanical properties also discussed. Results show that the keyhole will be significantly enlarged and the spatter will be remarkably inhibited with the increase of arc heat input. The keyhole opening increases from 56.57 mm² to 243.29 mm² when arc heat input increases from 139 J/mm to 479 J/mm. The frictional shear force between molten metal and metal vapor/plasma around the keyhole decreases, which results in the molten metal column decreasing from 15.96 mm to 5.27 mm. Moreover, the molten metal column will be fell back to the molten pool under the action of surface tension and of molten metal at the front of keyhole and static pressure of fluid. The number of spatter on the weld surface is reduced by 78% and the quality of weld formation is conspicuously improved. It is also found that the increase in arc heat input will enhance the weld width and depth, which results in coarsening of microstructure and increase in the heat affected zone width, but all specimens present good tensile properties. The effective suppression of spatter in ultra-high power laser-arc hybrid welding provides data and theoretical support for the regulation of the process parameters of this technology in the field of thick plate welding.

Key words: ultra-high power laser-arc hybrid welding, spatter formation, suppression method, arc heat input, keyhole opening

中图分类号:

TG156

李艳, 耿韶宁, 蒋平, 李元泰, 顾思远, 王建庄. 超高功率激光-电弧复合焊接飞溅演化行为及抑制方法[J]. 机械工程学报, 2024, 60(16): 98-107.

LI Yan, GENG Shaoning, JIANG Ping, LI Yuantai, GU Siyuan, WANG Jianzhuang. Spatter Evolution Behavior and Suppression Method in Ultra-high Power Laser-arc Hybrid Welding[J]. Journal of Mechanical Engineering, 2024, 60(16): 98-107.

参考文献

[1] WU W,WANG Q,YANG L,et al. Corrosion and SCC initiation behavior of low-alloy high-strength steels microalloyed with Nb and Sb in a simulated polluted marine atmosphere[J]. Journal of Materials Research and Technology,2020,9:12976-12995.
[2] MEI L,YAN D,XIE S,et al. Effects of Cr₂O₃ active agent on the weld process dynamic behavior and joint comprehensive properties of fiber laser welded stainless steel thick plate[J]. Optics and Lasers in Engineering,2020,128:106027.
[3] SUN Y F,FUJII H,MORISADA Y. Double-sided friction stir welding of 40 mm thick low carbon steel plates using a pcBN rotating tool[J]. Journal of Manufacturing Processes,2020,50:319-328.
[4] FENG G,WANG Y,LUO W,et al. Comparison of welding residual stress and deformation induced by local vacuum electron beam welding and metal active gas arc welding in a stainless steel thick-plate joint[J]. Journal of Materials Research and Technology,2021,13:1967-1979.
[5] FANG C,XIN J,DAI W H,et al. Deep penetration laser welding of austenitic stainless steel thick-plates using a 20 kW fiber laser[J]. Journal of Laser Applications,2020,32:012009.
[6] BUNAZIV I,LANGELANDSVIK G,REN X,et al. Effect of preheating and preplaced filler wire on microstructure and toughness in laser-arc hybrid welding of thick steel[J]. Journal of Manufacturing Processes,2022,82:829-847.
[7] KAWAHITO Y,WANG H,KATAYAMA S,et al. Ultra high power (100 kW) fiber laser welding of steel[J]. Optics Letters,2018,43(19):4667-4670.
[8] WANG Y,JIANG P,GENG S,et al. Influence of the wrinkle surface structures on the vapor flow and keyhole stability in 20 kW high power laser welding[J]. International Journal of Heat and Mass Transfer,2022,193:122958.
[9] SUN W,LIU S,GUO F,et al. Investigation on droplet transfer behavior during fiber laser-flux cored arc hybrid welding[J]. Optics & Laser Technology,2022,148:107781.
[10] GAO Q,YAN T,LING W,et al. Effect of vapor/plasma-liquid flow behavior on the keyhole oscillation in laser-MIG hybrid welding of Invar alloy[J]. Optics & Laser Technology,2021,140:107054.
[11] FAN X,GAO X D,ZHANG N F,et al. Monitoring of 304 austenitic stainless-steel laser-MIG hybrid welding process based on EMD-SVM[J]. Journal of Manufacturing Processes,2022,73:736-747.
[12] 张高磊,孔华,邹江林,等. 高功率光纤激光深熔焊接飞溅特性以及离焦量对飞溅的影响[J]. 中国激光,2021,48(22):79-86. ZHANG Gaolei,KONG Hua,ZOU Jianglin,et al. Spatter characteristics of high-power fibre laser deep penetration welding and effect of defocus on spatter[J]. Chinese Journal of Lasers,2021,48(22):79-86.
[13] LI S C,CHEN G Y,KATAYAMA S,et al. Relationship between spatter formation and dynamic molten pool during high-power deep-penetration laser welding[J]. Applied Surface Science,2014,303:481-488.
[14] KAWAHITO Y,MIZUTANI M,KATAYAMA S. High quality welding of stainless steel with 10 kW high power fibre laser[J]. Science and Technology of Welding & Joining,2009,14:288-294.
[15] HAO Y,LI L Q,SUN Y,et al. Dynamic behavior of keyhole and molten pool under different oscillation paths for galvanized steel laser welding[J]. International Journal of Heat and Mass Transfer,2022,192:122947.
[16] 聂鑫,李小宇,黄瑞生,等. 铝合金万瓦级激光-MIG电弧复合焊缝成形[J]. 焊接,2020(2):24-27. NIE Xin,LI Xiaoyu,HUANG Ruisheng,et al. Aluminum alloy ten thousand watt laser-MIG hybrid weld formation[J]. Welding,2020(2):24-27.
[17] 黄瑞生,杨义成,蒋宝,等. 超高功率激光-电弧复合焊接特性分析[J]. 焊接学报,2019,40(12):73-77,96,164. HUANG Ruisheng,YANG Yicheng,JIANG Bao,et al. Analysis of welding characteristics of ultra-high power laser-arc hybrid welding[J]. Transactions of the China Welding Institution,2019,40(12):73-77,96,164.
[18] LI Y,GENG S N,ZHU Z W,et al. Effects of heat source configuration on the welding process and joint formation in ultra-high power laser-MAG hybrid welding[J]. Journal of Manufacturing Processes,2022,77:40-53.
[19] LI Y,GENG S N,GU S Y,et al. Effect of liquid column on process stability and weld formation under ultra-high power fiber laser-arc hybrid welding of thick plates[J]. The International Journal of Advanced Manufacturing Technology,2022,121(11-12):8243-8255.
[20] LIU T T,HU R Z,CHEN X,et al. Localized boiling-induced spatters in the high-power laser welding of stainless steel:Three-dimensional visualization and physical understanding[J]. Applied Physics A,2018,124(9):654.
[21] ZOU J L,ZHU B Q,ZHANG G L,et al. Power density effect on the laser beam-induced eruption of spatters in fiber laser keyhole welding[J]. Optics & Laser Technology,2022,147:107651.
[22] WU D S,HUA X M,YE Y X,et al. Experimental and numerical study of spatter formation and composition change in fiber laser welding of aluminum alloy[J]. Journal of Physics D Applied Physics,2018,51:185604.
[23] WU C S,LIU Z M,CHEN J. The correlation between the heat input and the keyhole channel inclination in plasma arc welding of stainless steel plates[C/CD]//Canadian Welding Association Conference 2014.
[24] WU D S,HUA X M,HUANG L J,et al. Observation of the keyhole behavior,spatter and keyhole-induced bubble formation in laser welding of a steel/glass sandwich[J]. Welding in the World,2019,63:815-823.
[25] CHENG H,ZHOU L G,LI Q J,et al. Effect of welding parameters on spatter formation in full-penetration laser welding of titanium alloys[J]. Journal of Materials Research and Technology,2021,15:5516-5525.
[26] ZHANG G L,ZHU B Q,ZOU J L,et al. Correlation between the spatters and evaporation vapor on the front keyhole wall during fiber laser keyhole welding[J]. Journal of Materials Research and Technology,2020,9(6):15143-15152.
[27] VOLPP J,FROSTEVARG J. Elongated cavities during keyhole laser welding[J]. Materials & Design,2021,206:109835.
[28] TENNER F,BROCK C,KLAMPFL F,et al. Analysis of the correlation between plasma plume and keyhole behavior in laser metal welding for the modeling of the keyhole geometry[J]. Optics and Lasers in Engineering,2015,64:32-41.
[29] ROBERTSON S M,KAPLAN A F H,FROSTEVARG J. Material ejection attempts during laser keyhole welding[J]. Journal of Manufacturing Processes,2021,67:91-100.
[30] CHEN Y B,FENG J C,LI L Q,et al. Microstructure and mechanical properties of a thick-section high-strength steel welded joint by novel double-sided hybrid fibre laser-arc welding[J]. Materials Science and Engineering:A,2013,582:284-293.

超高功率激光-电弧复合焊接飞溅演化行为及抑制方法

Spatter Evolution Behavior and Suppression Method in Ultra-high Power Laser-arc Hybrid Welding

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