| 光谱学与光谱分析 |
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| Spectra and Thermal Analysis of the Arc in Activating Flux Plasma Arc Welding |
| CHAI Guo-ming,ZHU Yi-feng |
| National Key Laboratory for High Energy Density Beam Processing Technology, Beijing Aeronautical Manufacturing Technology Research Institute, Beijing 100024, China |
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Abstract In activating flux plasma arc welding the welding arc was analyzed by spectra analysis technique, and the welding arc temperature field was measured by the infrared sensing and computer image technique. The distribution models of welding arc heat flow density of activating flux PAW welding were developed. The composition of welding arc affected by activated flux was studied, and the welding arc temperature field was studied. The results show that the spectral lines of argon atom and ionized argon atom of primary ionization are the main spectra lines of the conventional plasma welding arc. The spectra lines of weld metal are inappreciable in the spectra lines of the conventional plasma welding arc. The gas particle is the main in the conventional plasma welding arc. The conventional plasma welding arc is gas welding arc. The spectra lines of argon atom and ionized argon atom of primary ionization are intensified in the activating flux plasma welding arc, and the spectra lines of Ti, Cr and Fe elements are found in the activating flux plasma welding arc. The welding arc temperature distribution in activating flux plasma arc welding is compact, the outline of the welding arc temperature field is narrow, the range of the welding arc temperature distribution is concentrated, the welding arc radial temperature gradient is large, and the welding arc radial temperature gradient shows normal Gauss distribution.
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Received: 2009-01-10
Accepted: 2009-04-20
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Corresponding Authors:
CHAI Guo-ming
E-mail: chaiguoming@sohu.com
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[1] PATON B E. Automatic Welding, 1974, 27(6): 1.
[2] LUCAS W, HOWSE D. Welding and Metal Fabrication, 1996, 3(1): 11.
[3] PAULO J. J. of Materials Processing Technology, 2000, 9: 260.
[4] LIU Feng-yao, LIN San-bao, YANG Chun-li, et al(刘凤尧, 林三宝, 杨春利, 等). Transactions of the China Welding Institution(焊接学报), 2002, 23(2): 5.
[5] ZHANG Rui-hua, FAN Ding(张瑞华, 樊 丁). Transactions of the China Welding Institution(焊接学报), 2003, 24(1): 85.
[6] CHAI Guo-ming, ZHU Yi-feng, ZHANG Hui(柴国明, 朱轶峰, 张 慧). Chinese Journal of Mechanical Engineering(机械工程学报), 2005, 41(10): 170.
[7] WU Ming-liang, YU Shu-rong, ZHANG Guo-jin, et al(吴明亮, 余淑荣, 张国锦, 等). Hot Working Technology(热加工工艺), 2006, 35(15): 36.
[8] LIU Li-ming, ZHANG Zhao-dong, SHEN Yong(刘黎明, 张兆栋, 沈 勇, 等). Acta Metallurgica Sinica(金属学报), 2006, 42(4): 399.
[9] CHAI Guo-ming, ZHANG Hui(柴国明, 张 慧). Acta Aeronautica Et Astronautica Sinica(航空学报), 2008, 29(1): 192.
[10] Li Junyue, Li Zhiyong, Li Huan,et al. Chinese Journal of Mechanical Engineering, 2004, 17(2): 315.
[11] JIANG Li-pei, ZHANG Jia-ying, LI Hong-hui(蒋力培, 张甲英, 李鸿辉). Transactions of the China Welding Institution(焊接学报), 2001, 22(3): 1.
[12] Sforza P, De B D. NDT & E International, 2002, 35: 37.
[13] YAN Zhi-hong, ZHANG Guang-jun, QIU Mei-zhen, et al(闫志鸿, 张广军, 邱美珍, 等). Transactions of the China Welding Institution(焊接学报), 2005, 26(2): 37.
[14] HAN Guo-ming, WU Zhao, LIU Gang(韩国明, 吴 钊, 柳 刚). China Mechanical Engineering(中国机械工程), 2000, 11(4): 446.
[15] PAN Cun-hai, DU Su-mei, LI Heng, et al(潘存海, 杜素梅, 李 桓, 等). Chinese Journal of Mechanical Engineering(机械工程学报), 1997, 33(5): 12.
[16] WU Rong, LI Yan, ZHU Shun-guan, et al(吴 蓉, 李 燕, 朱顺官,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2008, 28(4): 731.
[17] ZHANG Wen-yue(张文钺). Weld Heat Transfer Theory(焊接传热学). Beijing: China Machine Press(北京: 机械工业出版社), 1987.
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