CO2激光焊接等离子体图像的三维重建

摘要/Abstract

摘要：

利用一组同步触发的高速相机获取CO2激光焊接过程中等离子体在多个方向的投影图像，采用质心投影法则对等离子体图像进行微调以提高空间匹配度，通过相机标定以及投影权重因子的计算，建立了等离子体的三维图像与二维图像之间的投影关系方程，并利用代数迭代法求解方程，获得了等离子体的三维亮度分布.结果表明：与二维等离子体图像相比，所提出的激光焊接等离子体图像的三维重建方法具有较高的重建精度，能够更加准确地描述对象的整体特征和内部信息.

关键词: 激光焊接, 等离子体, 三维重建, 代数迭代法

Abstract:

A set of high-speed cameras were used to obtain the plasma image in different directions in the process of CO2 laser welding. The centroid projecting principle was employed to adjust the plasma images in different directions. The projection relationship between the 3D plasma and 2D images were achieved by camera calibration and calculation of projection weighting factors. Finally, the 3D radiation distribution of plasma was obtained based on algebraic reconstruction technology (ART). The result shows that the 3D reconstruction of laserinduced plasma has a high reconstruction accuracy. And compared with 2D plasma image, the 3D reconstructed data reflects the dimensional characteristics and inner information of the plasma much more accurately.

Key words: laser welding, plasma, three-dimensional reconstruction, algebraic reconstruction technique (ART)

中图分类号:

TG 386.3

王永贵，孙大为，蔡艳，朱俊杰，吴毅雄. CO²激光焊接等离子体图像的三维重建[J]. 上海交通大学学报（自然版）, 2014, 48(05): 600-604.

WANG Yonggui,SUN Dawei,CAI Yan,ZHU Junjie,WU Yixiong. Three-Dimensional Reconstruction of Plasma Image in CO2 Laser Welding[J]. Journal of Shanghai Jiaotong University, 2014, 48(05): 600-604.

参考文献

［1］Wang C M, Meng X X, Huang W, et al. Role of side assisting gas on plasma and energy transmission during CO2 laser welding ［J］. Journal of Materials Processing Technology, 2011, 211(4): 668674.

［2］You D, Gao X. Monitoring of high power laser welding process by using image difference algorithm ［C］ ∥Proceedings of the World Congress on Engineering and Computer Science. San Francisco, USA: WCECS, 2012: 1.

［3］Sony G, Nampoori V P N. Application of imaging to study the evolution and dynamics of laser produced plasma from solid and thin film Li targets ［D］. Cochin, Kerala: Cochin University of Science and Technology, 2011.

［4］You D Y, Gao X D. Study of plume behavior during highpower disk laser welding ［J］. Applied Mechanics and Materials, 2012, 201: 10761079.

［5］Wang J, Wang C, Meng X, et al. Study on the periodic oscillation of plasma/vapor induced during high power fiber laser penetration welding ［J］. Optics and Laser Technology, 2012, 44(1): 6770.

［6］Teng W, Gao X D, Seiji K. Analysis of laserinduced plume during disk laser welding at different speeds ［J］. Plasma Science and Technology, 2013, 15(8): 821.

［7］Li G, Cai Y, Wu Y. Stability information in plasma image of highpower CO2 laser welding ［J］. Optics and Lasers in Engineering, 2009, 47(9): 990994.

［8］Abe N, Kunugita Y, Hayashi M, et al. Dynamic observation of high speed laserarc combination welding of thick steel plates (physics, processes, instruments and measurements) ［J］. Transactions of JWRI, 1997, 26(2): 711.

［9］赵英亮. 三维结构特征CT重建算法研究［D］. 太原: 中北大学信息与通信工程学院, 2010.

［10］Zhang Z Y. A flexible new technique for camera calibration ［J］. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2000, 22(11): 13301334.

［11］JeanYves Bouguet. Camera calibration toolbox for matlab ［CP/OL］. (20101202) ［20131010］. http:∥ www.vision.caltech.edu/bouguetj/calib_doc/.

［12］杨民, 路宏年, 孔凡琴, 等. 三维CT重建几何参数的非线性最小二乘估计［J］. 北京航空航天大学学报, 2005, 31(10): 11351139.

YANG Min, LU Hongnian, KONG Fanqin，et al. An estimation of parameters in threedimensional CT reconstruction using nonlinear least square method ［J］. Journal of Beihang University, 2005, 31(10): 11351139.

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CO²激光焊接等离子体图像的三维重建

Three-Dimensional Reconstruction of Plasma Image in CO2 Laser Welding

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