Abstract
Shortened product development processes in automotive industry combined with the upcoming lack of experts do challenge sheet metal part production fundamentally. Tryout time and manufacturing costs of large forming dies today are significantly influenced by their digitally supported engineering. The forming process by such tools is beside other influences is affected by elastic deformations of forming dies and press structure as well as contact areas between die and sheet metal part. In deep drawing such contact areas are influenced by the blank properties and the flange behavior in terms of thickening and thinning. Recent developments in sheet metal forming simulation do consider advanced friction models and structural modeling of die and press components improving simulation accuracy. Nevertheless thinning or thickening of sheet metal results into localized surface pressure distribution during deep drawing. For this reason, it is not sufficient to use the currently common practice of homogeneous surface pressure distribution in sheet metal forming simulation. In this respect, this paper presents a numerical approach for consideration of straining effects in the sheet metal part during forming operation. For this purpose, a systematic process improvement was developed in this paper to identify contact areas via a numeric simulation parameter. Validating the numerical investigation, a rectangle cup die is used, considering major strain. The main results of this contribution for that reason show how simulated contact areas can be estimated by reverse engineering of real forming parts. Hereby straining based contact areas lead to a novel contact area design in process planning, resulting in efficient die tryout.
Highlights
As a result of the ongoing global digital transformation and the associated digitization of manufacturing chains, traditional manufacturing industries are facing an increasing shortage of skilled workforce
This paper shows how data feedback through reverse engineering enables an improved sheet metal forming simulation
Real major strain data were used as input for systematic process improvement
Summary
As a result of the ongoing global digital transformation and the associated digitization of manufacturing chains, traditional manufacturing industries are facing an increasing shortage of skilled workforce. In current research, there is no specified numerical factor to characterize stiffness in perpendicular direction onto contact areas that can be related to real part projects For this reason, this paper presents an approach that allows an estimation of such numerical factor based on measured forming results. The validation workflow for the contact factor described in this paper allows a procedure for the definition of componentspecific numerical simulation parameters, which allows for an improved representation of contact areas during sheet metal forming simulation. Ath the end, this specified workflow leads to a modified die face design in process planning, enabling material-efficient die design and shortened die tryout time periods
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