Overview
ABSTRACT
An indispensable tool for automobile design, digital simulations of forming processes, including flat crimping, can meet feasibility and required productivity goals. This tool helps reduce the time it takes to prepare a project, thus ensuring the development of a process. This article presents the modeling approach via a description of the mechanical behavior of sheets and the rubbing between sheets and blades. The digital simulation is then descibed in depth: finite-element models, and straight-edge and curved-edge calculation results.
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Christian LANGE: Civil engineer from the École nationale supérieure des mines de Saint-Étienne (France) - Doctorate in materials science and engineering from the École nationale supérieure des mines de Paris (France) - Design engineer for window mechanisms and frames, PSA Peugeot Citroën, Sochaux site
INTRODUCTION
Faced with ever-increasing competition in the global automotive market, reducing design costs and lead times has become a major development focus for automakers. In order to maintain a high level of quality and robustness, while ensuring improvements through innovation in styling and technology, the automotive industry regularly introduces new means of production and new grades of sheet metal to achieve the required feasibility and productivity targets. The desire to reduce vehicle mass has become not only a major competitive challenge, but also an environmental constraint.
To meet these needs, digital simulation of forming processes has become an essential tool. It saves a considerable amount of time in the upstream phase of a project, guaranteeing the feasibility of parts or the development of an innovative forming process. Indeed, the aim of simulation is to reduce the number of experimental campaigns on prototypes or test specimens, deemed too long and too costly. Manufacturers began to show an interest in simulation in the 1980s. During the 1990s, finite element simulations evolved considerably in the field of sheet metal forming. Simulation models are constantly being improved in response to growing demands from automakers to reap the rewards of their investment in this field. They are demanding ever more accurate predictions.
Numerical simulation of the flat crimping process is a good example. Interest in finite element simulation of this process began around 1986, with the aim of improving the final quality of parts
This article provides an introduction to flat crimping through numerical modeling. The first section deals with the physical modeling of sheet metal behavior and friction with crimping tools, with a view to integrating these laws into the numerical simulation of the process. The second section presents the finite-element simulation models used in conventional models. It illustrates the robustness of the numerical models used: finite element models, behavior laws and friction models.
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Flat crimping for automotive bodywork: digital simulation