Advanced Search
SUN Zhenbang, HAN Yongquan, DU Maohua. Numerical prediction of residual stress field in LB-VPPA hybrid welding of aluminum alloys[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2018, 39(4): 6-10,22. DOI: 10.12073/j.hjxb.2018390085
Citation: SUN Zhenbang, HAN Yongquan, DU Maohua. Numerical prediction of residual stress field in LB-VPPA hybrid welding of aluminum alloys[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2018, 39(4): 6-10,22. DOI: 10.12073/j.hjxb.2018390085
shu

Numerical prediction of residual stress field in LB-VPPA hybrid welding of aluminum alloys

More Information
  • Received Date: December 22, 2016
    Graphical Abstract
    • Abstract
  • Based on theoretical analysis in LB-VPPA hybrid welding heat source arc shape, “double ellipsoid+3-D conical+cylindrical”heat source model was established for double high energy beam LB-VPPA hybrid welding heat source by secondary development of SYSWELD software heat source model. The temperature fields of LB-VPPA hybrid welding were accurately calculated by the cyclic loading of heat source models with different characteristics of positive and negative polarities in the SYSWELD software. According to the thermal elastoplastic theory, instantaneous evolution of the stress at corresponding node and residual stress distribution after welding were calculated, and the accuracy of numerical simulations was proved by the comparison of the weld cross section of the actual welding experiment and the simulation results and by the actual measurement of residual stress. Comparing the residual stress field of VPPA and LB-VPPA hybrid welding of 5A03 aluminum alloy with 10 mm thickness, it was found that the energy of LB-VPPA composite welding was more concentrated and the high-temperature area was more intensive. Although the maximum longitudinal residual stress was relatively larger, the area of tensile stress was smaller than the VPPA welding. The results of this study were helpful for the research and practical application of aluminum alloy LB-VPPA hybrid welding technology.
    • FullText(HTML)
    • References (1)
  • Steen W M, Eboo M. Arc augmented laser welding[J]. Metal Construetion, 1979, 11(7): 332-335.[2] Vitek J M, David S A,Richey M W, et al. Welding pool shape prediction in plasma augmented laser weld steel[J]. Science and Technology of Welding and Joining, 2001, 6(5): 305-314.[3] Zhang W, Hua X, Liao W, et al. The effect of the welding direction on the plasma and metal transfer behavior of CO2 laser+ GMAW-P hybrid welding processes[J]. Optics and Lasers in Engineering, 2014, 58(7): 102-108.[4] 胡庆贤, 王艳辉, 姚庆军, 等. 基于SYSWELD的穿孔等离子弧焊接温度场有限元分析[J]. 焊接学报, 2011, 32(12): 66-69.Hu Qingxian, Wang Yanhui, Yao Qingjun , et al. Finite element analysis of temperature field during keyhole plasma arc welding using SYSWELD software[J]. Transactions of the China Welding Institution, 2011, 32(12): 66-69.[5] 牟取晗, 韩永全, 赵 鹏, 等. 铝合金变极性等离子弧焊应力场数值分析[J]. 焊接学报, 2015, 36(11): 97-100.Mou Quhan, Han Yongquan, Zhao Peng, et al. Numerical simulation of stress field in variable polarity plasma arc welding of aluminum[J]. Transactions of the China Welding Institution, 2015, 36(11): 97-100.[6] 李志宁, 常保华, 都 东, 等. 激光-等离子弧复合焊温度场的数值模拟[J]. 焊接学报, 2007, 28(6): 29-33.Li Zhining, Chang Baohua, Du Dong, et al. Numerical simulation on temperature field in laser-plasma arc hybrid welding[J]. Transactions of the China Welding Institution, 2007, 28(6): 29-33.[7] 韩永全, 陈树君, 殷树言. 铝合金变极性等离子焊接电弧产热机理[J]. 焊接学报, 2007, 28(12): 35-37.Han Yongquan, Chen Shujun, Yin Shuyan. Principle of produced heat by arc properties in VPPA of aluminum alloy[J]. Transactions of the China Welding Institution, 2007, 28(12): 35-37.[8] 武传松, 王怀刚, 张明贤. 小孔等离子弧焊接热场瞬时演变过程的数值分析[J]. 金属学报, 2006, 42(3): 311-316.Wu Chuansong, Wang Huaigang, Zhang Mingxian. Numerical analysis of transient development of temperature field in keyhole plasma arc welding[J]. Acta Metallurgica Sinica, 2006, 42(3): 311-316.
    • Related Articles

  • Related Articles

    [1]SUN Zhenbang, LIU Lele, TONG Jiahui, HAN Yongquan, CHEN Furong. Numerical analysis of MIG welding of aluminum alloy based on improved heat source model[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2023, 44(2): 111-116, 128. DOI: 10.12073/j.hjxb.20220325007
    [2]MOU Quhan, HAN Yongquan, ZHAO Peng, DONG Junhui. Numerical simulation of stress field in variable polarity plasma arc welding of aluminum alloys[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2015, 36(11): 97-100.
    [3]LI Meiyan, HAN Bin, CAI Chunbo, WANG Yong, SONG Lixin. Numerical simulation on temperature and stress fields of laser cladded Ni-based coating[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2015, 36(5): 25-28,32.
    [4]GUO Zhu, ZHU Hao, CUI Shaopeng, WANG Yanhong. Finite element simulation of friction stir welding temperature field and residual stress field of 7075 aluminum alloy[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2015, 36(2): 92-96.
    [5]WANG Nengqing, TONG Yangang, DENG Dean. Effects of welding heat source parameters on residual stress and distortion in thin plate joint[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2012, (12): 97-100.
    [6]YANG Jianguo, CHEN Xuhui, ZHANG Xueqiu. Numerical modeling of new alterable heat source based on high energy welding beam[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2010, (2): 25-28.
    [7]LI Hong-ke, SHI Qing-yu, ZHAO Hai-yan, LI Ting. Auto-adapting heat source model for numerical analysis of friction stir welding[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2006, (11): 81-85.
    [8]MENG Qing-guo, FANG Hong-yuan, XU Wen-li, JI Shu-de. Numerical simulation of stress field for twin wire welding of al-alloy[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2005, (8): 43-48.
    [9]JI Shu-de, FANG Hong-yuan, LIU Xue-song, MENG Qing-guo, YU Dong-yuan. Numerical simulation of stress field of manual swing welding on basis of cluster heat source[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2005, (5): 46-48,52.
    [10]WU Su, ZHAO Hai-yan, WANG Yu, ZHANG Xiao-hong. A new heat source model in numerical simulation of high energy beam welding[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2004, (1): 91-94.

  • Cited by

    Periodical cited type(4)

    1. 张文亚,曾海峰,王有伟,刘建江. 1Cr18Ni12奥氏体不锈钢管Y型连接多层多道焊温度场及应力场研究. 热加工工艺. 2022(13): 143-148 .
    2. 杜宝帅,胥国祥,张忠文,李新梅,邓化凌. 输电塔GMAW-P焊接加固件残余应力的数值分析. 焊接技术. 2019(03): 7-11+1 .
    3. 甘世明,韩永全,陈芙蓉,李小飞. 基于弹性模量变化的7A52铝合金VPPA-MIG复合焊接残余应力测试. 焊接学报. 2019(05): 13-17+23+161 . 本站查看
    4. 张世全,韩永全,郑宏伟,战中学,张登峰. 铝合金LB-VPPA复合焊应力场数值模拟. 机械制造文摘(焊接分册). 2018(06): 6-13 .

    Other cited types(3)

Catalog

    Get Citation
    XML
    Article views (820) PDF downloads (0) Cited by(7)
    Turn off MathJax
    Article Contents
    Abstract
    References
    Related Articles

    Website Copyright © Editorial Office of Transactions of the China Welding Institution, Welding Journals Publishing HouseTel:0451-86323218Address:No. 2077, Chuangxin Road, Songbei District, Harbin

    Supported by: Beijing Renhe Information Technology Co. Ltd  Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return