Numerical analysis of flow-thermal coupling in micro-plasma welding pool of thin-wall part 被引量：8

Numerical analysis of flow-thermal coupling in micro-plasma welding pool of thin-wall part

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摘要 The formed characteristics of thin-wall part is studied when it is in the process of MPAW. Finite element method is used to sinmlate the temperature field coupling flow field in the welding of thin-wall part. It is found that because of the obvious effect of heat accumution in cross-section, where the distribution of temperature field area presents trapezoidal inverted approximately in the molten pool and the non-molten pool area presents level. The surface tension, the electromagnetic force and buoyancy are considered for analyzing the effects on the fluid flow of welding-pool. It can be obtained that the surface tension is the main driving force in the welding pool, which is far greater than electromagnetic force and buoyancy. The formed characteristics of thin-wall part is studied when it is in the process of MPAW. Finite element method is used to sinmlate the temperature field coupling flow field in the welding of thin-wall part. It is found that because of the obvious effect of heat accumution in cross-section, where the distribution of temperature field area presents trapezoidal inverted approximately in the molten pool and the non-molten pool area presents level. The surface tension, the electromagnetic force and buoyancy are considered for analyzing the effects on the fluid flow of welding-pool. It can be obtained that the surface tension is the main driving force in the welding pool, which is far greater than electromagnetic force and buoyancy.

作者 Liu Haihua Chen Haojie Liu Wenji Wang Tianqi Yue Jianfeng 刘海华;陈豪杰;刘文吉;王天琪;岳建峰(Tianjin Key Laboratory of Modern Meehatronies Equipment Technology, Tianjin Polytechnic University, Tianjin 300387, China)

机构地区 Tianjin Key Laboratory of Modern Meehatronies Equipment Technology

出处《China Welding》 EI CAS 2018年第2期13-18,共6页 中国焊接（英文版）

基金 supported by the National Natural Science Foundation of China(Grant No.U1333128,U1733125) Science and Technology Project of Tianjin(Grant No.14ZCDZGX00802,17JCZDJC38700)

关键词 thin-wall part welding pool flow-thermal coupling driving forces thin-wall part welding pool flow-thermal coupling driving forces

分类号 TG456.2 [金属学及工艺—焊接]

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