Ultra High Strength FeMn TWIP Steels for automotive safety parts

D. Cornette; P. Cugy; A. Hildenbrand; M. Bouzekri; G. Lovato (Arcelor)

doi:10.1051/metal:2005151

Abstract

Energy savings are among the most important goals of steel users. But generally, the increase of Tensile Strength for a given metallurgy isobtained to the detriment of ductility. Arcelor develops new ultra high strength steel with TWinning Induced Plasticity (TWIP) effect for weightreduction and impact resistance. This product, based on manganese (Mn) alloying metallurgy, has a tensile stress higher than 1000 MPa fora total elongation superior to 50%. Properties of these new steel grades are reported, in terms of tensile and forming behaviour, weldabilityand fatigue. Crash resistance is investigated by using a dynamic axial compression test and a dynamic three point bending test on structural componentswith closed and open cross sections. Optimised designs are presented for safety parts in FeMn TWIP 1000 and assessed againstconventional UHS steel. For each steel grade, the weight saving potential is estimated with respect to parts manufactured in high drawingability steel. 

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Ultra High Strength FeMn TWIP Steels for automotive safety parts

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