重冷轧铁和高强度低合金低碳钢的组织和性能

Metal science Pub Date : 1984-11-01 DOI:10.1179/030634584790419719

H. Raven, E. Nes

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引用次数: 13

摘要

摘要研究了α铁和钢在应变范围e = 0.5 ~ 4.5的冷轧过程中组织的发展。在低应变区(e > 1.5)，存在一级和二级微带。亚结构随应变的发展已经用一个模型来解释，在这个模型中，微带的体积分数随着应变的增加而增加，而牺牲了均匀的细胞结构矩阵。在大应变下，没有检测到“晶体学”微带，这表明在该区域，滑移是由更多的短程事件控制的。通过比较粗晶铁、中晶粒低碳钢和超细晶高强度低合金钢的应变硬化行为，研究了初始晶粒尺寸对应变硬化的影响。结果表明，在冷轧过程中，由亚结构控制的流动机制(σ = σ0 + kd−1，其中d为亚边界分离)转变为晶界控制的流动机制(σ = σ0 + kd−1 / 2)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Structure and properties of heavily cold rolled iron and high strength low alloy and low carbon steels

AbstractThe development of microstructure in α iron and steels during cold rolling has been investigated in the strain range e = 0.5–4.5. In the low strain region (e > 1.5), primary and secondary microbands were identified. The substructure development with strain has been explained in terms of a model in which the volume fraction of micro bands increases with increasing strain at the expense of a uniform cell structure matrix. At large strains, no ‘crystallographic’ microbands were detected, and it is suggested that in this region, slip is controlled by more short range events. The effect of initial grain size on strain hardening has been considered by comparing the behaviour of a coarse grained iron, a medium grain size low carbon steel, and an ultrafine grained high strength low alloy steel. The observations suggest that during cold rolling the flow mechanism will change from being substructure controlled (σ = σ0 + kd−1, where d is the subboundary separation) to grain boundary controlled (σ = σ0 + kd−½...

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Metal science

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