Advanced Search
YANG Zhuang, WANG Tianqi, LI Liangyu, LI Tianxu. Forming method and technology of arc additive manufacturing for thick wall structural parts[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2019, 40(10): 100-105. DOI: 10.12073/j.hjxb.2019400270
Citation: YANG Zhuang, WANG Tianqi, LI Liangyu, LI Tianxu. Forming method and technology of arc additive manufacturing for thick wall structural parts[J]. TRANSACTIONS OF THE CHINA WELDING INSTITUTION, 2019, 40(10): 100-105. DOI: 10.12073/j.hjxb.2019400270
shu

Forming method and technology of arc additive manufacturing for thick wall structural parts

  • Advanced Mechatronics Equipment Technology Tianjin Area Laboratory, Tianjin Polytechnic University, Tianjin 300387, China

More Information
  • Received Date: July 23, 2018
  • Available Online: July 12, 2020
    Graphical Abstract
    • Abstract
  • Arc welding robot is used for arc additive manufacturing, and the welding technology of additive manufacturing of thick-walled structural parts is studied. Based on the traditional stratification theory, the prediction and analysis of the molding dimension of the thick wall structure are carried out with the algorithm optimization. On the basis of this algorithm, the prediction model of the single weld shape size neural network is introduced to improve the precision of the preform model and the optimum selection of the actual welding parameters; In view of the collapse of the weld edge in the forming process of thick wall structures with inner holes and other features, the "boundary constraint" welding method was proposed and the interlayer welding trajectory was planned to improve the quality of the surface of the preform. Finally, the welding method has an illustrative physical component verification prediction algorithm and the accuracy of trajectory planning. The test results show that the structure is well formed and the size error is less than 1 mm.
    • FullText(HTML)
    • References (10)
  • 柏久阳, 王计辉, 林三宝, 等. 铝合金电弧增材制造焊道宽度尺寸预测[J]. 焊接学报, 2015, 36(9): 87 − 90.

    Bai Jiuyang, Wang Jihui, Lin Sanbao, et al. Width prediction of aluminium alloy weld additively manufactured by TIG arc[J]. Transactions of the China Welding Institution, 2015, 36(9): 87 − 90.
    张金田, 王任甫, 王杏华. 船用钢电弧增材制造的焊道尺寸预测[J]. 材料开发与应用, 2018(2): 17 − 22.

    Zhang Jintian, Wang Renfu, Wang Xinghua. Weld bead size prediction for arc enhanced manufacturing of marine steel[J]. Material Development and Application, 2018(2): 17 − 22.
    尹 凡. 不锈钢电弧增材制造成形工艺研究及尺寸精度控制[D]. 南京: 南京理工大学, 2017.
    Haihua L, Haojie C, Wenji L, et al. Numerical analysis of flow-thermal coupling in micro-plasma welding pool of thin-wall part[J]. China Welding, 2018, 27(2): 13 − 18.
    Mukherjee T, Zhang W, Debroy T. An improved prediction of residual stresses and distortion in additive manufacturing[J]. Computational Materials Science, 2017, 126: 360 − 372. doi: 10.1016/j.commatsci.2016.10.003
    González J, Rodríguez I, Prado-Cerqueira JL, et al. Additive manufacturing with GMAW welding and CMT technology[J]. Procedia Manufacturing, 2017, 13: 840 − 847.
    柏久阳, 王计辉, 林三宝, 等. 电弧増材制造厚壁结构焊道间距计算策略[J]. 机械工程学报, 2016, 52(10): 97 − 102.

    Bai Jiuyang, Wang Jihui, Lin Sanbao, et al. Calculation strategy of thick wall welded bead spacing in arc material manufacturing[J]. Chinese Journal of Mechanical Engineering, 2016, 52(10): 97 − 102.
    熊 俊. 多层单道GMA增材制造成形特性及熔敷尺寸控制[D]. 哈尔滨: 哈尔滨工业大学, 2014.
    Li Y, Sun Y, Han Q, et al. Enhanced beads overlapping model for wire and arc additive manufacturing of multi-layer multi-bead metallic parts[J]. Journal of Materials Processing Technology, 2018, 252(1): 838 − 848.
    Ding D, Pan Z, Cuiuri D, et al. A multi-bead overlapping model for robotic wire and arc additive manufacturing (WAAM)[J]. Robotics & Computer Integrated Manufacturing, 2015, 31(C): 101 − 110.
    • Related Articles

  • Cited by

    Periodical cited type(6)

    1. 王磊磊,吕飞阅,高转妮,虞文军,高川云,占小红. 电弧增材制造2319铝合金交叉桁条结构微观组织与拉伸性能研究. 机械工程学报. 2023(01): 267-277 .
    2. 王瑞超,高祥,李会军,朱国崇,许健仪. 基于DFS与蚁群算法的电弧增材复合路径规划算法优化. 焊接. 2023(11): 31-38 .
    3. 董翼纶,李宇航,武少杰,程方杰. 埋弧增材厚壁构件的组织与力学性能. 材料热处理学报. 2022(02): 87-93 .
    4. 董曼淑,朱晗,张晓超,白凯,刘龙,高洪明. 矿用链轮链窝电弧增材制造路径规划. 焊接. 2021(01): 51-55+64 .
    5. 李鑫磊,张广军. 电弧增材制造中空间曲面等距路径规划算法. 焊接学报. 2021(07): 14-20+98 . 本站查看
    6. 韩庆璘,李大用,李鑫磊,韩常乐,张广军. 基于分区减光的电弧增材制造熔敷道尺寸主被动联合视觉检测. 焊接学报. 2020(09): 28-32+98 . 本站查看

    Other cited types(5)

Catalog

    Get Citation
    XML
    Article views (739) PDF downloads (74) Cited by(11)
    Turn off MathJax
    Article Contents
    Abstract
    References

    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