传统的薄板卷边工艺难以满足个性化定制、新品开发等的需求，为此研究了一种基于多向无模渐进成形的薄板柔性卷边新方法，利用改进的工具头对1 mm厚的Al6061铝板和0.27 mm厚的SUS 304不锈钢板进行了卷边实验和数值模拟，探讨了加工工艺参数对力与变形的影响，分析了典型缺陷的形成与控制方法。研究表明，该方法能够实现板料的柔性卷边成形而无需专用模具，大大扩展了渐进成形的加工范围。对于渐进卷边过程中可能出现翘曲、折弯、表面划痕以及因“端部效应”引起的缺陷等，可以通过减小进给量、增加预成形、改善润滑条件、改进工具头形状等方法对变形加以控制，从而消除成形缺陷。

［1］金宗民.覆盖件的卷边工艺及模具
［J］.模具工业，1988, (4)：14-15.

 Jin Z M. Curling process and die of panel
［J］. Die & Mould Industry, 1988, (4)：14-15.

［2］刘亚东，程圣德，李从心，等.面向冲压件卷边成形的数控系统开发
［J］.机械科学与技术，2001，20(1)：89-91.

 Liu Y D, Cheng S D, Li C X, et al. Development of CNC system for stamping parts of curling forming
［J］. Mechanical Science and Technology, 2001, 20(1)：89-91.

［3］Hu P, Li D Y, Li Y X. Analytical models of stretch and shrink flanging
［J］. International Journal of Machine Tools & Manufacture, 2003, 43(13):1367-1373.

［4］Xu F, Lin Z, Li S, et al. Study on the influences of geometrical parameters on the formability of stretch curved flanging by numerical simulation
［J］. Journal of Materials Processing Technology, 2004, 145(1):93-98.

［5］莫建华，韩飞.金属板材数字化渐进成形技术研究现状
［J］.中国机械工程，2008，19(4)：491-497.

 Mo J H, Han F. State of the arts and latest research on incremental sheet NC forming technology
［J］. China Mechanical Engineering, 2008, 19(4): 491-497.

［6］AlGhamdi K A, Hussain G. Forming forces in incremental forming of a geometry with corner feature: investigation into the effect of forming parameters using response surface approach
［J］. International Journal of Advanced Manufacturing Technology, 2015, 76(9-12):2185-2197.

［7］Li J, Geng P, Shen J. Numerical simulation and experimental investigation of multistage incremental sheet forming
［J］. The International Journal of Advanced Manufacture Technology, 2013, 68(9): 2637-2644.

［8］Voswinckel H, Bambach M, Hirt G. Improving geometrical accuracy for flanging by incremental sheet metal forming
［J］. International Journal of Material Forming, 2015, 8(3):391-399.

［9］Kim T J, Yang D Y. Improvement of formability for the incremental sheet metal forming process
［J］. International Journal of Mechanical Sciences, 2000, 42(7):1271-1286.

［10］李磊，周晚林，Hussain G.金属板料单点渐进成形极限的数值模拟预测
［J］.机械工程学报，2010，46(18)：73-80.

Li L, Zhou W L, Hussain G. Prediction of single point incremental forming limit
［J］. Journal of Mechanical Engineering, 2010, 46(18): 73-80.

［11］Teramae T, Manabe K, Ueno K, et al. Effect of material properties on deformation behavior in incremental tubeburring process using a bar tool
［J］. Journal of Materials Processing Technology, 2007, 191(1):24-29.

［12］Yang C, Wen T, Liu L T, et al. Dieless incremental holeflanging of thinwalled tube for producing branched tubing
［J］. Journal of Materials Processing Technology, 2014, 214(11):2461-2467.

［13］Wen T, Chen X, Zheng J, et al. Multidirectional incremental sheet forming—a novel methodology for flexibly producing thinwalled parts
［J］. International Journal of Advanced Manufacturing Technology, 2016, 91(5-8):1-11.

［14］Wen T, Zhang S, Zheng J, et al. Bidirectional dieless incremental flanging of sheet metals using a bar tool with tapered shoulders
［J］. Journal of Materials Processing Technology, 2016, 229:795-803.

［15］Wen T, Zheng J, Qing J, et al. Outwards and inwards crimping of tube ends by singlepoint incremental forming
［A］. International Conference on the Technology of Plasticity
［C］. Cambridge, 2017.

［16］Wen T, Yang C, Zhang S, et al. Characterization of deformation behavior of thinwalled tubes during incremental forming: a study with selected examples
［J］. International Journal of Advanced Manufacturing Technology, 2015, 78(9-12):1769-1780.