复杂级进模冲压件毛坯设计英文文献和中文翻译
The MSUM is illustratedto the blank design of a progressive die stamping part, and a benchmark test is comparedwith experimental and other numerical results. A large number of parts on automobile body are deformedby stamping, and sometimes the features of the stampingparts are very complicated. In order to improve the qualityand the efficiency of products, many parts are formed usingprogressive die process. Comparing with simple press tool,progressive die has the advantages of high quality and effi-ciency of product, which is especially suitable for large-lotproduction in a short delivery time. However, it is very dif-ficult to design strip layout in progressive die design, and onlythe rich experience and technical engineers are competent todo it well.In the strip layout design, firstly, the stamping processsequence is designed according to the part featureswith expe- rience and simple theoretical formula. Secondly, the shape ateach step is designedwith the process sequence and all shapesare assembled into a strip. After finishing the die structuredesign with strip layout, it is very important to validate thedesign of strip layout and the die structure in a real produc-tion condition to find out potential defects. It is necessary tomodify the design of strip layout and the die structure untilthe defects is removed. So it is a rather difficult task to obtainan optimum strip layout. If the optimal blank shape and sizeat each step and the formability are predicted at the designstage, which will greatly reduce the trial and error time of thewhole progressive die design.However, at the design stage of strip layout, intermediateshape and boundary conditions of process are unknown. It isimpossible to use finite element incremental approach to sim- ulate the sheet metal forming at each step (Jian et al., 2002).And the most important thing for the designer is to calcu-late the intermediate shapes and to predict the formabilityof each step from the final shape of the part to initial blank.Up to now, the inverse approach (IA) (Guo et al., 1990, 2000,2001;
Naceur et al., 2001) or one step (Lee and Huh, 1998)isabetter solution for the problem. But the inverse approach canonly calculate the initial shape from the final shape withouttaking into account intermediate forming process, and some-times there is a big error evenwrong result for complex shape,especially at upright wall or undercut conditions.Many authors used the IA to predict the initial blank shapeof the complete part, and it is an effective method for manystamping part with simple process. But for complicated form-ing parts or progressive die stamping parts, the intermediateforming process has great effect on the initial blank shape, andit is difficult to set the boundary conditions for different localforming areas with complete unfolding. It is feasible methodto calculate inversely the local forming area according to thepractical forming processes step by step, and the upright wallor undercut conditions can be avoided to some extent.In the sheet metal forming simulation system, FASTAMP(Yuqi et al., 2004), a multi-step unfolding method (MSUM) isdeveloped to assist the progressive die design. Firstly, a finiteelementmodel of the inverse approach is developed at a localarea according to the stamping process, and the intermediateshape is unfolded inversely from final shape to initial shapeon a reference surface at each step. In calculation model, thereference surface may be generated according to the processand feature surface. The influences of stamping process suchas the connection, blank-holder force, the friction and theoffsetting of the strain neutral layer with different radius ofcurvature at local area, are also considered.