锻压技术

基于中间构形的级进模条料分步展开算法研究

英文标题：Research on multistep unfolding algorithm of progressive die strip based on intermediate shapes

作者：许恒建柳玉起金伟章志兵

单位：华中科技大学

分类号：TG386；TP391.9

出版年,卷(期):页码：2012,37(2):42-46

摘要：

级进模条料设计过程中的主要难点在于中间构形的设计。针对级进模成形以弯曲变形为主的特点，提出了一种基于旋转变形的中间构形快速生成算法，该算法通过设置最终构形的旋转轴、固定区、变形区、非变形区、固定约束、形状约束、等长线以及旋转角度等求解条件，通过曲面网格快速求解出中间构形，并以生成的中间构形网格作为参考构形，采用有限元逆算法，将最终构形展开到中间构形上以精确地获取中间构形的修边线。介绍了中间构形生成算法的实现流程，并在SolidWorks平台下采用二次开发技术，开发了一套完全无缝集成的级进模条料分步展开系统SWCUX。以复杂连续折弯件的中间构形设计为例验证了该算法的可行性。

The main difficult of the progressive die strip layout design lies in the design of intermediate shapes. Considering the situation that the progressive die forming is dominated by bending deformation, a fast generating algorithm of intermediate shapes based on the rotation deformation was developed. In this algorithm, some conditions, such as the rotation axis, fixed area, deforming area, undeforming area, fixed restraint line, shape restraint line, constantlength line and rotation angle were considered. The intermediate shapes were solved by surface mesh. The generated intermediate shapes were considered as reference configuration, and the final configuration was unfolded to the intermediate shape to obtain the accurate trimming line. The realization flow of the intermediate shape generating algorithm was introduced. A seamless integration system SWCUX for multistep unfolding of progressive die strip was developed by SolidWorks API. The feasibility of the algorithm was verified with the intermediate shape design of a complex bending part.

基金项目：

国家自然科学基金资助项目（50905067）；国家数控重大专项基金资助项目（2010ZX04014-072）

参考文献：

［1］陈炎嗣. 多工位级进模的使用条件与合理应用[J]. 机械工人, 2007, (11): 50-51.
［2］谢邵辉, 柳玉起, 杜亭,等. 板料对向液压成形模拟算法开发及应用[J]. 锻压技术, 2009, 34(6), 52-55.
［3］Batoz J L, Guo Y Q, Mercier F. The inverse approach with simple triangular shell elements for large strain predictions of sheet metal forming parts [J]. Engineering Computations, 1998, 15(7): 864-892.
［4］Guo Y Q, Batoz J L, Detraux J M, et al. Finite element procedures for strain estimations of sheet metal forming parts [J]. Int. J. Num. Meth. Engng., 1990,(39): 1385-1401.
［5］Guo Y Q, Naceur H, Debray K,et al. Initial solution estimation to speed up inverse approach in stamping modeling[J]. Engineering Computations, 2003, 20(7): 810-834.
［6］Liu Yuqi, Li Zhigang, Yan Yakun. Fast accurate prediction of blank shape in sheet metal stamping forming [J]. Acta Mechanica Solida Sinica, 2004, 17(1): 36-42.
［7］吴勇国. 板料成形过程数值模拟研究[D]. 武汉: 华中理工大学, 1995.
［8］金潮海. 板料成形动力显式弹塑性有限元仿真技术研究[D]. 哈尔滨: 哈尔滨工业大学, 2001.
［9］章志兵. 面向冲压产品设计的快速仿真与优化技术的研究[D]. 武汉: 华中科技大学, 2001.
［10］章志兵, 王同俊, 柳玉起,等. 汽车覆盖件修边与翻边工序的快速仿真系统[J]. 锻压技术, 2008, 33 (4): 140-145.
［11］戴威波, 柳玉起, 章志兵, 等. 集成SolidWorks平台的修边线展开与翻边成形同步模拟系统[J]. 塑性工程学报, 2010, 17(6):9-13.

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