Numerical Simulation of Unsteady Arc in GTAW with Alternate Axial Magnetic Field

XIAO Lei; FAN Ding; HUANG Jiankang

doi:10.3901/JME.2018.16.079

Journal of Mechanical Engineering >

2018 , Vol. 54 >Issue 16: 79 - 85

DOI: https://doi.org/10.3901/JME.2018.16.079

Numerical Simulation of Unsteady Arc in GTAW with Alternate Axial Magnetic Field

XIAO Lei ,
FAN Ding ,
HUANG Jiankang

Expand

1. School of Material Science and Engineering, Lanzhou University of Technology, Lanzhou 730050;
2. State Key Laboratory of Advanced Processing and Recycling of Non-ferrous Metals, Lanzhou University of Technology, Lanzhou 730050

Received date: 2017-12-31

Revised date: 2018-03-26

Online published: 2018-08-20

Fold

Abstract

Based on the computational fluid dynamics(CFD) software Fluent, the alternating magnetic field controlling unsteady electric arc properties such as temperature field, flow field and pressure field in extra alternate axial magnetic field are studied by modeling a 3D mathematic model of gas tungsten arc welding(GTAW). The relationships of maximum temperature、pressure distribution on the anode and current density on the anode with time are highlighted. When taking into account the alternate axial magnetic field, the extra electromagnetic force drives the arc to rotate. The maximum accelerated speed reaches 6×10⁷ m/s², hence the arc plasma nearing the tungsten suddenly changes its rotating direction, and arc plasma away from that keeps intact. The arc can ultimately alter its rotating direction when the magnetic field frequency is less than 100 kHz when the magnetic induction intensity is 0.03 T. The pressure and current density distributions on the anode change from double peaks to one-two peaks alternating periodically, which have been partly demonstrated in the experimental research by high-speed camera system. It ultimately provides fundamental basis for the alternating magnetic field controlling welding technology.

Key words： gas tungsten arc welding; alternate axial magnetic field; numerical simulation

Cite this article

XIAO Lei , FAN Ding , HUANG Jiankang . Numerical Simulation of Unsteady Arc in GTAW with Alternate Axial Magnetic Field[J]. Journal of Mechanical Engineering, 2018 , 54(16) : 79 -85 . DOI: 10.3901/JME.2018.16.079

References

[1] MURPHY A B, TANAKA M, TASHIRO S, et al. A computational investigation of the effectiveness of different shielding gas mixtures for arc welding[J]. Journal of Physics D Applied Physics, 2009, 42(11):115205.
[2] TANAKA M. Predictions of weld pool profiles using plasma physics[J]. Journal of Physics D Applied Physics, 2007, 40(1):R1-R23.
[3] JIAN L, YAO Z, XUE K. Anti-gravity gradient unique arc behavior in the longitudinal electric magnetic field hybrid tungsten inert gas arc welding[J]. International Journal of Advanced Manufacturing Technology, 2016, 84(1-4):647-661.
[4] NOMURA K, MORISAKI K, HIRATA Y. Magnetic control of arc plasma and its modelling[J]. Welding in the World, 2009, 53(7-8):R181-R187.
[5] 李渊博,李霄,王世清,等. 片状偏钨极电弧特性的数值模拟[J]. 焊接学报, 2017, 38(4):7-12. LI Yuanbo, LI Xiao, WANG Shiqing, et al. Numerical simulation of arc in sheet slanting electrode tungsten insert gas welding[J]. Transactions of the China Welding Institution, 2017, 38(4):7-12.
[6] 陈树君,王建新,蒋凡,等. 空心钨极中心负压电弧基础特性研究[J]. 机械工程学报, 2016, 52(2):7-12. CHEN Shujun, WANG Jianxin, JIANG Fan, et al. Research of hollow tungsten central negative pressure arc welding characteristic[J]. Journal of Mechanical Engineering, 2016, 52(2):7-12.
[7] 寇婵. 纵向磁场频率对TIG焊电弧特性的影响[D]. 沈阳:沈阳工业大学, 2015. KOU Chan. The effect on TIG welding arc characteristic with different longitudinal magnetic frequency[D]. Shenyang:Shenyang University of Technology, 2015.
[8] 常云龙,杨旭,李大用,等.外加纵向磁场作用下的TIG 焊接电弧[J]. 焊接学报, 2010, 31(4):49-52. CHANG Yunlong, YANG Xu, LI Dayong, et al. Arc shapes of TIG welding in a longitudinal magnetic field[J]. Transactions of the China Welding Institution, 2010, 31(4):49-52.
[9] 殷凤良,胡绳荪,李力,等. 等离子体发生器的数值模拟方法[J]. 机械工程学报, 2007, 43(9):156-160. YIN Fengliang, HU Shengsun, LI Li, et al. Numerical simulation method of plasma arc generator[J]. Chinese Journal of Mechanical Engineering, 2007, 43(9):156-160.
[10] 樊丁,牛尾诚夫,陈剑虹. TIG电弧传热传质过程的数值模拟分析[J]. 机械工程学报, 1998, 34(2):39-45. FAN Ding, MASAO U, CHEN Jianhong. Numerical analysis of the heat and mass transfer for TIG arc[J]. Chinese Journal of Mechanical Engineering, 1998, 34(2):39-45.
[11] 刘凤磊,杜华云,安艳丽,等. 基于Fluent的GTAW 数值模拟[J]. 焊接, 2016(2):10-14. LIU Fenglei, DU Huayun, AN Yanli, et al. Numerical simulation of GTA welding based on fluent software[J]. Welding & Joining, 2016(2):10-14.
[12] 董文超,陆善平,李殿中,等. 焊接电弧与活性组元对TIG焊熔池形貌影响的数值模拟[J]. 焊接学报, 2009, 30(11):49-52. DONG Wenchao, LU Shanping, LI Dianzhong, et al. Numerical simulation of welding arc and surfaceactivating element on weld shape in TIG welding[J]. Transactions of the China Welding Institution, 2009, 30(11):49-52.
[13] LU F, YAO S, LOU S, et al. Modeling and finite element analysis on GTAW arc and weld pool[J]. Computational Materials Science, 2004, 29(3):371-378.
[14] 石玗,郭朝博,黄健康,等. 脉冲电流作用下TIG电弧的数值分析[J]. 物理学报, 2011, 60(4):731-737. SHI Yu, GUO Chaobo, HUANG Jiankang, et al. Numerical simulation of pulsed current tungsten inert gas welding arc[J]. Acta Physica Sinica, 2011, 60(4):731-737.
[15] IWAO T, MORI Y, OKUBO M, et al. Modeling of metal vapour in pulsed TIG including influence of self-absorption[J]. Journal of Physics D Applied Physics, 2010, 43(43):434010.
[16] LI Lincun, XIA Weidong. Effect of an axial magnetic field on a DC argon arc[J]. Chinese Physics B, 2008, 17(2):649-654.
[17] CHEN Tang, ZHANG Xiaoning, BAI Bing, et al. Numerical study of DC argon arc with axial magnetic fields[J]. Plasma Chem Plasma Process, 2015, 35(1):61-74.
[18] WANG L, CHEN J, WU C, et al. Backward flowing molten metal in weld pool and its influence on humping bead in high-speed GMAW[J]. Journal of Materials Processing Technology, 2016, 237:342-350.
[19] 过增元. 电弧和热等离子体[M]. 北京:科学出版社, 1986. GUO Zengyuan. Arc and thermal plasma[M]. Beijing:Science Press, 1986.
[20] 肖磊,樊丁,黄健康,等. 外加高频纵向磁场作用下的TIG焊电弧数值模拟[J]. 焊接学报, 2017, 38(2):66-70 XIAO Lei, FAN Ding, HUANG Jiankang, et al. Numerical simulation of TIG welding arc with extra high frequency longitudinal magnetic field[J]. Transactions of the China Welding Institution, 2017, 38(2):66-70.
[21] YIN Xianqing, GOU Jianjun, ZHANG Jianxun, et al. Numerical study of arc plasmas and weld pools for GTAW with applied axial magnetic fields[J]. Journal of Physics D:Applied Physics, 2012, 45:285203.

Options

Outlines

模态框（Modal）标题

Abstract

Cite this article

References