高速CMT焊送丝速度和焊接电流波形参数的优化

张栋1,2,陈茂爱1,武传松1

doi:10.12073/j.hjxb.2018390027

高速CMT焊送丝速度和焊接电流波形参数的优化

张栋1,2,陈茂爱1,武传松1

计量
- 文章访问数: 1049
- HTML全文浏览量: 29
- PDF下载量: 12
出版历程
- 收稿日期: 2016-07-20

Optimization of waveform parameters for high speed CMT welding of steel

ZHANG Dong1,2, CHEN Maoai1, WU Chuansong1

摘要

摘要: 在5 m/min的平均送丝速度、1.8 m/min的焊接速度下开展高速CMT焊正交试验，研究焊接工艺参数对焊接过程及焊缝成形的影响，分析高速下焊接过程不稳定的原因. 结果表明，峰值送丝速度、峰值持续时间tp和峰值电流Ip的影响作用依次降低. 焊接工艺参数匹配不合适时(包括焊机的专家参数)，高速焊时频繁发生周期性“粘丝”现象，焊缝成形不均匀、咬边严重. 峰值送丝速度过快、高速下的熔滴后拖和熔池前部金属薄层温度过低是“粘丝”产生的主要原因. 通过合理匹配上述三个参数消除了粘丝并获得良好的焊缝成形.
- 高速CMT焊 /
- 波形参数 /
- 正交试验 /
- 工艺优化
Abstract: A series of high speed CMT welding tests were conducted on Q235 steel at a wire feed speed of 5 m/min and a welding speed of 1.8 m/min. The effect of waveform parameters on welding process, weld bead appearance was researched by means of orthogonal test. The causes for unstable welding process at high welding speed were analyzed. The results showed that the wing order: peak wire feed speed, boost current duration (tp) and boost current (Ip). With unsuitable welding parameters (including expert welding parameters in CMT power source), periodic “wire adhesion” phenomenon which led to uneven weld bead appearance and severely undercut occurred frequently in high speed CMT welding. The “wire adhesion” phenomenon was caused by high peak wire feed speed, droplet drag and low temperature of thin liquid metal layer in front of the weld pool. Wire adhesion phenomenon was eliminated and sound weld bead appearance was obtained by properly matching the above three waveform parameters.
- high speed CMT welding /
- waveform parameters /
- orthogonal test /
- process optimization

HTML全文

参考文献(1)

[1]

石常亮, 何鹏, 冯吉才, 等. 铝/镀锌钢板CMT熔钎焊界面区组织与接头性[J]. 焊接学报, 2006, 27(12): 61-64.Shi Changliang, He Peng, Feng Jicai,et al. Interface microstructure and mechanical property of CMT welding-brazed joint between aluminum and galvanized steel sheet[J]. Transactions of the China Welding Institution, 2006, 27(12): 61-64.[2] Mezrag B, Deschaux-Beaume F, Benachour M. Control of mass and heat transfer for steel/aluminium joining using cold metal transfer process[J]. Science and Technology of Welding and Joining, 2015, 20(3): 189-198.[3] 汪殿龙, 张志洋, 梁志敏, 等. 交流CMT动态电弧特征及熔滴过渡行为分析[J]. 焊接学报, 2014, 35(3): 6-10.Wang Dianlong, Zhang Zhiyang, Liang Zhimin,et al. Analysis of dynamic arc characteristics and melt transfer behavior of AC CMT[J]. Transactions of the China Welding Institution, 2014, 35(3): 6-10.[4] 杨修荣. 超薄板MIG/MAG焊——CMT冷金属过渡技术[J]. 电焊机, 2006, 36(6): 5-7.Yang Xiurong. CMT cold metal transfer process[J]. Electric Welding Machine, 2006, 36(6): 5-7.[5] 陈茂爱, 蒋元宁, 武传松. 受控短路过渡CO2焊焊接电流波形参数优化[J]. 焊接学报, 2014, 35(7): 79-82.Chen Maoai, Jiang Yuanning, Wu Chuansong. Optimization of welding current waveform parameters in controlled short circuiting transfer GMAW[J]. Transactions of the China Welding Institution, 2014, 35(7): 79-82.[6] Meng X, Qin G, Zhang Y,et al. High speed TIG-MAG hybrid arc welding of mild steel plate[J]. Journal of Materials Processing Technology, 2014, 214(11): 2417-2424.

施引文献(9)

期刊类型引用(6)

1.	苏才津，秦南南，冯哲，张丽. 激光熔覆铁基合金涂层熔覆质量形貌预测. 四川冶金. 2025(01): 16-21 . 百度学术
2.	胡雅楠，余欢，吴圣川，奥妮，阚前华，吴正凯，康国政. 基于机器学习的增材制造合金材料力学性能预测研究进展与挑战. 力学学报. 2024(07): 1892-1915 . 百度学术
3.	惠记庄，骆伟，阎志强，王俊杰，吕景祥，郭许，张浩. AlSi10Mg选区激光熔化表面粗糙度预测、优化及表面形貌分析. 表面技术. 2024(15): 129-140+151 . 百度学术
4.	鲁芬，郁伯铭. 人工神经网络的激光熔覆层特征分析. 激光杂志. 2023(04): 254-258 . 百度学术
5.	穆伟豪，陈雪辉，张雨，黄磊，朱达荣，董必春. 316L不锈钢选区激光熔化表面的形貌分析与粗糙度预测. 激光与光电子学进展. 2022(07): 255-262 . 百度学术
6.	丁宏德，朱春明，唐斌，顾小燕. 316L不锈钢SLM件与锻件的激光焊接头微观组织与性能. 焊接. 2021(05): 9-14+63 . 百度学术

其他类型引用(3)

资源附件(0)

计量

文章访问数: 1049
HTML全文浏览量: 29
PDF下载量: 12
被引次数: 9

高速CMT焊送丝速度和焊接电流波形参数的优化

计量

出版历程

Optimization of waveform parameters for high speed CMT welding of steel

期刊类型引用(6)

其他类型引用(3)

计量

出版历程

目录