Research on modeling of heat source for electron beam welding fusion-solidification zone

被引:0
|
作者
Wang Yajun [1 ]
Fu Pengfei [2 ]
Guan Yongjun [3 ]
Lu Zhijun [2 ]
Wei Yintao [4 ]
机构
[1] School of Mechanical Engineering and Automation, Beihang University
[2] Science and Technology on Power Beam Processes Laboratory, Beijing Aeronautical Manufacturing Technology Research Institute
[3] State Key Laboratory of Nonlinear Mechanics, Institute of Mechanics, Chinese Academy of Sciences
[4] State Key Laboratory of Automotive Safety and Energy, Department of Automotive Engineering, Tsinghua University
来源
Chinese Journal of Aeronautics | 2013年 / 01期
基金
中国国家自然科学基金;
关键词
Electron beam welding (EBW); Fusion-solidification zone; Heat source model; Temperature fields; Weld shape;
D O I
暂无
中图分类号
TG456.3 [真空电子束焊];
学科分类号
080201 ; 080503 ;
摘要
In this paper, the common heat source model of point and linear heat source in the numerical simulation of electron beam welding (EBW) were summarized and introduced. The combined point-linear heat source model was brought forward and to simulate the welding temperature fields of EBW and predicting the weld shape. The model parameters were put forward and regulated in the combined model, which included the ratio of point heat source to linear heat source Qpr and the distribution of linear heat source Lr. Based on the combined model, the welding temperature fields of EBW were investigated. The results show that the predicted weld shapes are conformable to those of the actual, the temperature fields are reasonable and correct by simulating with combined point-linear heat source model and the typical weld shapes are gained.
引用
收藏
页码:217 / 223
页数:7
相关论文
共 50 条
  • [41] Research on Welding Heat Affected Zone of Pipeline Steel in High Heat Input Welding
    Wang, Jian-Ming
    Liu, Yan
    Wang, Kai
    Liu, Yang
    PROCEEDINGS OF THE 2015 INTERNATIONAL CONFERENCE ON MATERIAL SCIENCE AND APPLICATIONS (ICMSA 2015), 2015, 3 : 906 - 910
  • [42] Part I: Development of new heat source model applicable to micro electron beam welding
    Gajapathi, S. S.
    Mitra, S. K.
    Mendez, P. F.
    SCIENCE AND TECHNOLOGY OF WELDING AND JOINING, 2012, 17 (06) : 429 - 434
  • [43] Metastable phase solidification in electron beam welding of dissimilar stainless steels
    Tsukamoto, S.
    Harada, H.
    Bhadeshia, H.K.D.H.
    Materials Science and Engineering A, 1994, A178 (1-2) : 189 - 194
  • [44] Experimental research on electron-beam welding technology with a scanning electron beam
    Seregin, Yu N.
    Laptenok, V. D.
    Murygin, A., V
    Bocharov, A. N.
    21ST INTERNATIONAL SCIENTIFIC CONFERENCE RESHETNEV READINGS-2017, 2019, 467
  • [45] Electron beam welding of heat exchangers of aluminium alloys
    Bondarev, A.A.
    Nazarenko, S.V.
    D'yakov, I.I.
    Pyshkin, B.E.
    Avtomaticheskaya Svarka, 1992, (03):
  • [46] Simulation of heat transfer at welding with oscillating electron beam
    Kaisheva, D.
    Angelov, V.
    Petrov, P.
    CANADIAN JOURNAL OF PHYSICS, 2019, 97 (10) : 1140 - 1146
  • [47] HEAT EFFECT BY ELECTRON BEAM AND LASER WELDING AND HEAT TREATMENT.
    Rykalin, N.
    Uglov, A.
    Proceedings of the Society of Photo-Optical Instrumentation Engineers, 1979,
  • [48] MODELING OF MICRO ELECTRON BEAM WELDING WITH MELTING AND EVAPORATION
    Gajapathi, Satya S.
    Mitra, Sushanta K.
    Mendez, Patricio F.
    INTERNATIONAL MECHANICAL ENGINEERING CONGRESS AND EXPOSITION - 2012, VOL 9, PTS A AND B, 2013, : 755 - 756
  • [49] Heat source modeling and analysis of submerged arc welding
    1600, American Welding Society (93):
  • [50] Heat Source Modeling and Analysis of Submerged Arc Welding
    Podder, D.
    Mandal, N. R.
    Das, S.
    WELDING JOURNAL, 2014, 93 (05) : 183S - 192S
12345