Phase composition of 15Mn-0.1C-0.4/1.4Al-Si TRIP/TWIP steels after cold rolling and annealing

2016 7th International Conference on Mechanical and Aerospace Engineering (ICMAE) Pub Date : 2016-07-18 DOI:10.1109/ICMAE.2016.7549520

P. Podaný, J. Dlouhý, M. Koukolíková, P. Martínek, R. Procházka, T. Kubina, M. Duchek

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引用次数: 1

Abstract

In the steel industry, research efforts have been mainly focused on high-strength steels recently. These steels find use in both automotive industry and (thanks to reduced weight of structural parts) aircraft industry. New possibilities emerged at the beginning of this century, when the effect of strain-induced transformation of γ phase was attempted to be applied in austenitic steels. Particularly the high manganese steels are extremely ductile austenitic steels characterized by a high rate of work hardening resulting from the generation of deformation-nucleated twins and possibly combined with the deformation induced formation of martensite. Capability of energy absorption is much bigger in comparison with conventional steels. This paper deals with the description of the phase composition of two heats of steel with 15 wt. % of manganese after annealing after cold rolling with 40% reduction of thickness. Various methods of phase analysis have been used: colour etching, EBSD and X-ray diffraction.

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15Mn-0.1C-0.4/1.4Al-Si TRIP/TWIP钢冷轧退火后的相组成

在钢铁工业中，最近的研究工作主要集中在高强度钢上。这些钢材在汽车工业和(由于减轻了结构部件的重量)飞机工业中都有使用。本世纪初出现了新的可能性，当应变诱导的γ相转变效应被尝试应用于奥氏体钢时。特别是高锰钢是极具延展性的奥氏体钢，其特点是由于变形成核孪晶的产生而具有高的加工硬化率，并可能与变形诱导的马氏体的形成相结合。与传统钢材相比，吸收能量的能力要大得多。本文叙述了含锰量为15wt . %的钢经冷轧后减厚40%退火后的相组成。采用了各种相分析方法:彩色蚀刻、EBSD和x射线衍射。

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2016 7th International Conference on Mechanical and Aerospace Engineering (ICMAE)

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