脉冲电流作用下TIG电弧的数值分析

石玗; 郭朝博; 黄健康; 樊丁

doi:10.7498/aps.60.048102

摘要

建立了脉冲电流下自由燃烧的TIG电弧的二维轴对称数学模型,利用FLUENT软件,通过选择合适的边界条件和强烈耦合控制方程组对脉冲TIG电弧进行了数值模拟,得到了在焊接电流周期性变化下电弧形态、电弧温度场、电弧轴线方向上的温度和速度及焊接工件表面电弧压力的变化情况;针对电弧压力,得到了不同峰值电流、占空比、脉冲频率作用下的分布情况,并分析了它们在脉冲电流作用下的周期性变化规律.分析结果表明:当脉冲电流发生突变时,它们的变化滞后于脉冲电流的变化,且从基值电流向峰值电流变化时的响应速度更快,并最终达到一个相对稳

关键词:

脉冲TIG焊 /
电弧 /
数值模拟 /
FLUENT

Abstract

A two-dimensional axisymmetric model of free burning tangsten inert gas (TIG) arc under the action of pulsed current is developed. Using the FLUENT software and choosing appropriate boundary conditions and strongly coupling control equations, a pulsed TIG arc is simulated. The variations of arc form, temperature field, temperature and velocity on the arc axis and surface pressure distribution of the workpiece are obtained and analyzed in the periodic current process; under the action of different values of peak current, duty ratio and pulse frequency, the arc pressure distributions are obtained and analyzed. The results show that they lag behind the variation of pulse current, the variation from base current to peak current is faster, then eventually reaches a relativly stable state; with the increase of peak current, the arc pressure increase greatly; with the increase of duty ratio, the arc pressure increases slowly; with the increase of pulse frequency, the arc pressure cannot reach a stable state gradually, and the max arc pressure tends to decrease.

Keywords:

作者及机构信息

(1)兰州理工大学,甘肃省有色金属新材料重点实验室,兰州 730050; (2)兰州理工大学,有色金属合金及加工教育部重点实验室,兰州 730050

基金项目: 国家自然科学基金(批准号:50805073)资助的课题.

Authors and contacts

(1)Key Laboratory of Non-ferrous Metal Alloys, The Ministry of Education,Lanzhou University of Technology, Lanzhou 730050, China; (2)State Key Laboratory of Gansu Advanced Non-ferrous Metal Materials, Lanzhou University of Technology, Lanzhou 730050, China

参考文献

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[2]	He Ye,Guo W K,Shao Q Y, Xu P 2000 Acta Phys. Sin. 49 487 (in Chinese) [何煜、郭文康、邵其鋆、须平 2000 49 487]
[3]	Marco A Ramirez,Gerardo Trapaga, Jonh McKelliget 2004 Journal of Materials Processing Technology 30 155
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[5]	Manabu Tanaka, Masao Ushio, John James Lowke 2005 JSME International Journal 48 397
[6]	Hideya Nishiyama, Tomohiko Sawada, Hidemasa Takana, Manabu Tanaka, Masao Ushio 2006 ISIJ International 46 705
[7]	Du H Y, Wei Y H, Wang W X, Fan D 2009 Journal of Materials Processing Technology 209 3752
[8]	Fan D, Masao U, Fukuhisa Matsuda 1986 Trans. JWRI 15 1
[9]	Masao Ushio, Fan D, Manabu Tanaka 1993 Trans. JWRI 22 201
[10]	Fan D, Chen J H, Masao Ushio 1998 Chinese Journal of Mechanical Engineering 34 39 (in Chinese) [樊丁、陈剑虹、牛尾诚夫 1998 机械工程学报 34 39]
[11]	Fan H G, Shi Y W, Na S J 1997 Journal of Materials Processing Technology 72 437
[12]	Fan H G, Na S G, Shi Y W 1997 Journal of Physics D 30 94
[13]	Chen X 2009 Heat transfer and transmission of thermal plasma (Beijing: Science Press) p58 (in Chinese) [陈熙 2009 热等离子体传热与传动(北京:科学出版社)第58页]

施引文献

[1]	Lu F G, Tang X H, Yu H L, Yao S 2006 Computational Materials Science 35 458
[2]	He Ye,Guo W K,Shao Q Y, Xu P 2000 Acta Phys. Sin. 49 487 (in Chinese) [何煜、郭文康、邵其鋆、须平 2000 49 487]
[3]	Marco A Ramirez,Gerardo Trapaga, Jonh McKelliget 2004 Journal of Materials Processing Technology 30 155
[4]	Lei Y P, Gu X H, Shi Y W, Murakawa Hidekazu 2002 Acta Metall. Sin. 37 537 (in Chinese) [雷永平、顾向华、史耀武、村川英一 2002 金属学报 37 537]
[5]	Manabu Tanaka, Masao Ushio, John James Lowke 2005 JSME International Journal 48 397
[6]	Hideya Nishiyama, Tomohiko Sawada, Hidemasa Takana, Manabu Tanaka, Masao Ushio 2006 ISIJ International 46 705
[7]	Du H Y, Wei Y H, Wang W X, Fan D 2009 Journal of Materials Processing Technology 209 3752
[8]	Fan D, Masao U, Fukuhisa Matsuda 1986 Trans. JWRI 15 1
[9]	Masao Ushio, Fan D, Manabu Tanaka 1993 Trans. JWRI 22 201
[10]	Fan D, Chen J H, Masao Ushio 1998 Chinese Journal of Mechanical Engineering 34 39 (in Chinese) [樊丁、陈剑虹、牛尾诚夫 1998 机械工程学报 34 39]
[11]	Fan H G, Shi Y W, Na S J 1997 Journal of Materials Processing Technology 72 437
[12]	Fan H G, Na S G, Shi Y W 1997 Journal of Physics D 30 94
[13]	Chen X 2009 Heat transfer and transmission of thermal plasma (Beijing: Science Press) p58 (in Chinese) [陈熙 2009 热等离子体传热与传动(北京:科学出版社)第58页]

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