基于网格化曲面的自适应自动铺放轨迹算法
收稿日期: 2011-07-14
修回日期: 2011-09-06
网络出版日期: 2011-10-09
基金资助
国家自然科学基金 (50905088);国家科技重大专项 (2010ZX04016-013)
Algorithm of Adaptive Path Planning for Automated Placement on Meshed Surface
Received date: 2011-07-14
Revised date: 2011-09-06
Online published: 2011-10-09
Supported by
National Natural Science Foundation of China (50905088); National Science and Technology Major Project (2010ZX04016-013)
基于轨迹的可铺放性要求分析了铺放过程中预浸料产生畸变的原因及影响轨迹可铺放性的因素。根据测地线定义构造了一种基于网格化曲面的测地线新算法,具有高效率、高精度等特点;在此基础上综合考虑预浸料的可铺放性和构件强度分布要求,提出了具有曲面自适应功能的铺放轨迹算法,可根据预浸料带宽计算得到铺放轨迹容许的最大测地曲率,并将其运用于铺放轨迹设计,使轨迹能够保证预浸料良好可铺放性的同时又满足构件的强度分布要求。最后通过数据库SQL Server和VC++针对某型号S型进气道进行铺放轨迹设计,在CATIA中将计算获取的离散轨迹点拟合成曲线并进行了实际的铺放试验,验证了测地线生成算法和铺放轨迹生成算法的正确性和有效性。
熊文磊 , 肖军 , 王显峰 , 李俊斐 , 黄志军 . 基于网格化曲面的自适应自动铺放轨迹算法[J]. 航空学报, 2013 , 34(2) : 434 -441 . DOI: 10.7527/S1000-6893.2013.0050
This paper analyzes the causes of prepreg distortion and discusses its influence for the requirement of trajectory placement ability. A new algorithm of geodesic generation based on meshed surfaces is proposed according to the definition of geodesic, which possesses features of efficiency and highaccuracy, etc. Both the manufacturability of the prepreg and its distribution of strength in a product are considered in the algorithm of path planning, providing it with the ability of adapting to surfaces. The algorithm first figures out the maximum geodesic curvature allowed for the central path, and applies it to the design of trajectory. The trajectory obtained both has good ability of placement and can satisfy the demands of strength distribution in a product. Finally, the path planning aiming at one type of S-inlet with database of SQL Server and VC++ is carried out. The disperse trajectory points are then fitted to be a curve in CATIA to verify the validity and effectiveness of the algorithm of geodesic generation and trajectory placement generation.
Key words: composite; automated placement; path planning; meshed surface; geodesic
[1] Xiao J, Li Y, Li J L. Application of automatic fiber placement in manufacture of composite structures in large aircraft. Aeronautical Manufacturing Technology, 2008(1): 50-53. (in Chinese) 肖军, 李勇, 李建龙. 自动铺放技术在大型飞机复合材料构件制造中的应用. 航空制造技术, 2008 (1): 50-53.
[2] Huan D J, Xiao J, Li Y. CAD/CAM software technology for composites automated placement. Aeronautical Manufacturing Technology, 2010 (17): 42-45. (in Chinese) 还大军, 肖军, 李勇. 复合材料自动铺放CAD/CAM软件技术. 航空制造技术, 2010 (17): 42-45.
[3] Chen X B. Low-cost technology of advanced composite. Beijing: Chemical Industry Press, 2004: 69-99. (in Chinese) 陈祥宝. 先进复合材料低成本技术. 北京: 化学工业出版社, 2004: 69-99.
[4] Lewis H W, Romero J E. Composite tape placement apparatus with natural path generation means: United States, 4696707. 1987-7-14.
[5] Shinno N, Shigematsu T. Method for controlling tape affixing direction of automatic tape affixing apparatus: United States, 5041179. 1991-8-20.
[6] Hu C L, Xiao J, Li Y, et al. Study on automated tape laying technique for composites Part I: natural path property analysis and calculation method. Aerospace Materials & Technology, 2007 (1): 40-43. (in Chinese) 胡翠玲, 肖军, 李勇, 等. 复合材料自动铺带研究(Ⅰ)——"自然路径"特性分析及算法. 宇航材料工艺, 2007 (1): 40-43.
[7] Luo H Y. Research on automated tape-laying path calculation for composites based on STL file. Nanjing: College of Material Science and Technology, Nanjing University of Aeronautics and Astronautics, 2009. (in Chinese) 罗海燕. 基于STL文件的复合材料自动铺带轨迹算法研究. 南京: 南京航空航天大学材料科学与技术学院, 2009.
[8] Shirinzadeh B, Cassidy G, Oetomo D, et al. Trajectory generation for open-contoured structures in robotic fiber placement. Robotics and Computer-Integrated Manufacturing, 2007 (23): 380-394.
[9] Li S Y, Wang X P, Zhu L J. Path planning for composite fiber placement. Aerospace Materials & Technology, 2009 (2): 25-29. (in Chinese) 李善缘, 王小平, 朱丽君. 复合材料铺丝成形中的路径规划. 宇航材料工艺, 2009 (2): 25-29.
[10] Zhou Y, An L L, Zhou L S. Research on composite fiber placement path generation algorithm. Aviation Precision Manufacturing Technology, 2006, 42(2): 39-41. (in Chinese) 周燚, 安鲁陵, 周来水. 复合材料自动铺丝路径生成技术研究. 航空精密制造技术, 2006, 42(2): 39-41.
[11] Wang N D, Liu Y, Xiao J. Fiber-placement path design for composite structures in pipe-form. Journal of Computer-Aided Design & Computer Graphics, 2008, 20(2): 228-233. (in Chinese) 王念东, 刘毅, 肖军. 复合材料管状结构自动铺丝路径算法. 计算机辅助设计与图形学报, 2008, 20(2): 228-233.
[12] Hale R D, Moon R, Lim K, et al. Integrated design and analysis tools for reduced weight, affordable fiber steered composites. Lawrence, Kansas: University of Kansas, 2004.
[13] Lin S. The ATL/AFP——The key machine for manufacturing of modern large airplane (C). World Manufacturing Engineering & Market, 2009 (6): 78-83. (in Chinese) 林胜. 自动铺带机/铺丝机(ATL/AFP)——现代大型飞机制造的关键设备(下).世界制造技术与装备市场, 2009 (6): 78-83.
[14] Taubin G. Estimating the tensor of curvature of a surface from a polyhedral approximation. Proceedings of the Fifth International Conference on Computer Vision. Los Alamitos: IEEE Computer Society Press, 1995: 902-907.
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