Development of a heat source model for narrow-gap hot-wire laser welding

被引：2

作者：

机构：

[1] Graduate School of Engineering, Hiroshima University

来源：

| 1600年 / Japan Welding Society卷 / 31期

关键词：

Heat source; Hot-wire laser welding; Narrow gap; Solidification cracking;

D O I：

10.2207/qjjws.31.82s

中图分类号：

学科分类号：

摘要：

Three-dimensional finite element analysis with a special subroutine was carried out to obtain the temperature distribution during hot-wire laser welding with a narrow-gap joint. A moving heat source was modeled with the element rebirth technique, and laser reflection was modeled by heat flux distributed around the front of the weld pool. The model was used to reproduce the phenomenon of hot-wire laser welding with a narrow gap investigated by in-situ observation. The thermal strain for different weld shapes was then calculated to evaluate the susceptibility to solidification cracking. The simulation results were validated with experimental measurements in terms of the thermal cycle history of the molten pool, peak temperature distribution close to the fusion zone, and cross section of the weld bead. The thermal simulation was found to agree reasonably well with the experimental results and it was revealed that hot-wire laser welding is an interesting alternative process that reduces solidification cracking in a narrow-gap joint.

引用

页码：82s / 85s

页数：3

共 9 条

[1] Reisgen U., Olschok S., Jakobs S., Schleser M., Mokrov O., Rossiter E., Laser beam submerged arc hybrid welding, J. Physics Procedia, 39, pp. 75-83, (2012)
[2] Iwata S., Murayama M., Kojima Y., Application of narrow gap welding process with high speed rotating arc to box column joints of heavy thick plates, JFE Technical Report, 14, pp. 16-21, (2009)
[3] Gou N., Zhang J., Han Y., Zang L., Yuan X., Effects of welding parameters on metal transfer process in rotating are narrow gap horizontal GMAW, Trans. of JWRI, Special Issue on WSE, pp. 5-7, (2011)
[4] Phaoniam R., Shinozaki K., Yamamoto M., Kadoi K., Tsuchiya S., Nishijima A., Development of high efficient hot wire-laser hybrid process for narrow gap welding -Welding phenomena and its adequate condition, 65th IIW Annual Assembly
[5] Shinozaki K., Nishijima A., Yamamoto M., Kadoi K., Phaoniam R., Yamamoto M., Okagaito T., Behavior and prevention of lack fusion and solidification cracking of modified 9Cr1Mo steel during hot wire laser welding with a narrow gap, Proceedings of the 77th Laser Materials Processing, pp. 21-26, (2012)
[6] Shinozaki K., Yamamoto M., Kawasaki A., Tamura T., Wen P., Development of evaluation method for solidification cracking susceptibility of inconel600/sus347 dissimilar laser weld metal by in-situ observation, J. Mater. Sci. Forum, 580-582, pp. 49-52, (2008)
[7] Ueno Y., Ishii S., Yamanaka Z., Measurement of weld metal temperature with an immersion-type optical-fiber radiation thermometer without correcting emissivity, J. Japanese Welding Society, 81, 7, pp. 17-21, (2012)
[8] Deng D., Murakawa H., Prediction of welding residual stress in multi-pass butt-welded modified 9Cr-1Mo steel pipe considering phase transformation effects, Computational Materials Science, 37, 3, pp. 209-219, (2006)
[9] Shibahara M., Itoh S., Liang W., Murakawa H., Finite element simulation of pear-shaped bead cracking in narrow gap welding, Proceedings of the 13th International Offshore and Polar Engineering Conference, pp. 135-140, (2003)

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