弧长修正系数对5052铝合金CMT焊接焊缝成形和金相显微组织的影响

许祥霖; 刘杰; 李天庆

doi:10.3969/j.issn.1674-6457.2026.03.012

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精密成形工程 ›› 2026, Vol. 18 ›› Issue (3) : 105-114. DOI: 10.3969/j.issn.1674-6457.2026.03.012

先进连接技术

弧长修正系数对5052铝合金CMT焊接焊缝成形和金相显微组织的影响

许祥霖^1,2, 刘杰¹, 李天庆^1,*

作者信息 +

Effect of the Arc Length Correction Factor on Weld Formation and Metallographic Microstructure in CMT Welded 5052 Aluminum Alloy

XU Xianglin^1,2, LIU Jie¹, LI Tianqing^1,*

Author information +

文章历史 +

摘要

目的定量揭示弧长修正系数对5052铝合金焊缝表面形貌、截面几何特征以及焊缝区、热影响区微观组织的具体影响规律,为实现CMT焊接质量与接头组织的精确调控提供理论依据。方法采用机器人自动化CMT焊接平台,在固定焊接电流（125 A）、电压（19.2 V）和速度（90 cm/min）的条件下,唯一改变弧长修正系数（-25%~+25%）,制备系列焊接接头。通过宏观拍照记录焊缝表面形貌;利用体视显微镜测量焊缝截面的熔深、熔宽及余高;结合金相显微镜系统观察与分析焊缝中心等轴晶、热影响区宽度及柱状晶宽度的变化。结果当弧长修正系数为正值时,焊缝表面鱼鳞纹均匀、成形质量优,当弧长修正系数为负值时,出现飞溅与氧化现象,成形质量下降;ALCF对熔深影响显著,负值区熔深更大,当ALCF为-10%时,熔深最大,较熔深最小值增加了86.8%;熔宽变化相对平缓,最大增幅为12.9%;随ALCF从0%增至25%,焊缝中心等轴晶平均尺寸由102.8 μm减小至90.5 μm;热影响区平均宽度最大变化幅度为279.8 μm;柱状晶平均宽度最大变化幅度为341.9 μm。结论调整弧长修正系数可以调节电弧长度与稳定性,可以有效改变焊接热输入及其分布,从而成为调控CMT铝合金焊缝宏观成形与微观组织的重要手段。研究证实,增大正弧长修正系数可细化焊缝中心等轴晶、缩小热影响区范围,但会导致熔深减小并可能促使柱状晶粗化。本研究有望为不同性能需求（如深熔透、优表面或细晶组织）的CMT焊接工艺精确设计提供理论指导和基础数据。

Abstract

The work aims to quantitatively elucidate the specific effects of the ALCF on the surface morphology, the cross-sectional geometrical characteristics, and the microstructures of both the weld zone and heat-affected zone in 5052 aluminum alloy welds, to provide a theoretical basis for the precise control of CMT welding quality and joint microstructure. An automated robotic CMT welding platform was employed. Welding joints were fabricated by systematically varying only the ALCF (from -25% to +25%), while keeping the welding current (125 A), voltage (19.2 V), and speed (90 cm/min) constant. The weld surface morphology was documented via macroscopic photography. Stereomicroscopy was used to measure the weld penetration depth, width, and reinforcement height. Microstructural analysis, including the observation of equiaxed grains in the weld center, heat-affected zone width, and columnar grain width, was conducted systematically through metallurgical microscopy. With positive ALCF values, the weld surface exhibited uniform fish-scale patterns and superior formation quality, whereas negative values led to spatter, oxidation, and degraded quality. The ALCF significantly affected penetration depth, with greater penetration observed in the negative ALCF range, reaching a maximum (at ALCF= -10%) that was 86.8% greater than the minimum value. The weld width variation was more moderate, with a maximum increase of 12.9%. As the ALCF increased from 0% to 25%, the average grain size of the equiaxed crystals in the weld center decreased from 102.8 μm to 90.5 μm. The maximum variation in the average width of the heat-affected zone was 279.8 μm. The maximum variation in the average width of columnar grains was 341.9 μm. The ALCF, by modulating the arc length and its stability, effectively alters the welding heat input and its distribution, thereby serving as an important means for controlling the macroscopic formation and microscopic microstructure of CMT aluminum alloy welds. The study findings confirm that increasing the positive ALCF can refine the equiaxed grains in the weld center and reduce the extent of the heat-affected zone, but it also leads to a decrease in penetration depth and may promote the coarsening of columnar grains. This study is expected to provide theoretical guidance and fundamental data for the precise design of CMT welding processes tailored to different performance requirements, such as deep penetration, superior surface quality, or a fine-grained microstructure.

导出引用

许祥霖, 刘杰, 李天庆. 弧长修正系数对5052铝合金CMT焊接焊缝成形和金相显微组织的影响[J]. 精密成形工程. 2026, 18(3): 105-114 https://doi.org/10.3969/j.issn.1674-6457.2026.03.012

XU Xianglin, LIU Jie, LI Tianqing. Effect of the Arc Length Correction Factor on Weld Formation and Metallographic Microstructure in CMT Welded 5052 Aluminum Alloy[J]. Journal of Netshape Forming Engineering. 2026, 18(3): 105-114 https://doi.org/10.3969/j.issn.1674-6457.2026.03.012

中图分类号： TG442

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