Effect of Post-Deformation Cooling on Microstructure and Mechanical Properties of a Cu-Containing High-Strength Low-Alloy (HSLA) Steel

IF 1.6 4区材料科学 Q2 Materials Science

Transactions of The Indian Institute of Metals Pub Date : 2024-07-10 DOI:10.1007/s12666-024-03387-9

A. Venkata Ramana, I. Balasundar, M. J. Davidson

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Abstract

A Cu-Containing high-strength low-alloy (HSLA) steel was subjected to single-stage near-isothermal forging followed by different post-deformation cooling rates. The effect of different cooling media such as water, air and furnace on the microstructure evolution and mechanical characteristics of the HSLA steel was evaluated. The hierarchical microstructures of HSLA steel were investigated by different microstructural characteristic techniques to draw a correlation between microstructure and mechanical properties. The HSLA steel exhibits predominantly martensitic microstructure with or without bainite irrespective of the cooling media. However, the morphology of the martensite was found to be dependent on the cooling rate. The effect of cooling medium on grain size was systematically shown by reconstruction of prior austenite grain boundaries from electron back-scattered diffraction investigation. Faster cooling results in higher yield and tensile strength due to predominant martensitic structure while relatively slower cooling rates result in comparatively lower strength values with a corresponding increase in ductility. This is attributed to the presence of retained austenite in the HSLA steel with decreasing cooling rate. An impact toughness of ≥ 50 J was obtained at subambient temperature of − 40 °C irrespective of the cooling rate.

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变形后冷却对含铜高强度低合金（HSLA）钢微观结构和机械性能的影响

对一种含铜高强度低合金（HSLA）钢进行了单段近等温锻造，然后采用不同的变形后冷却速率。评估了不同冷却介质（如水、空气和熔炉）对 HSLA 钢微观结构演变和机械特性的影响。通过不同的微观结构特征技术研究了 HSLA 钢的分层微观结构，从而得出微观结构与机械性能之间的相关性。无论采用哪种冷却介质，HSLA 钢的微观组织都以马氏体为主，并伴有或不伴有贝氏体。然而，马氏体的形态与冷却速度有关。冷却介质对晶粒大小的影响是通过电子反向散射衍射研究重建先前的奥氏体晶界来系统显示的。由于马氏体结构占主导地位，冷却速度越快，屈服强度和拉伸强度越高；而冷却速度相对较慢，强度值相对较低，但延展性相应增加。这是因为随着冷却速度的降低，HSLA 钢中存在残余奥氏体。无论冷却速度如何，在-40 °C的亚环境温度下都能获得≥ 50 J的冲击韧性。

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来源期刊

Transactions of The Indian Institute of Metals Materials Science-Metals and Alloys

CiteScore

2.60

自引率

6.20%

发文量

期刊介绍： Transactions of the Indian Institute of Metals publishes original research articles and reviews on ferrous and non-ferrous process metallurgy, structural and functional materials development, physical, chemical and mechanical metallurgy, welding science and technology, metal forming, particulate technologies, surface engineering, characterization of materials, thermodynamics and kinetics, materials modelling and other allied branches of Metallurgy and Materials Engineering. Transactions of the Indian Institute of Metals also serves as a forum for rapid publication of recent advances in all the branches of Metallurgy and Materials Engineering. The technical content of the journal is scrutinized by the Editorial Board composed of experts from various disciplines of Metallurgy and Materials Engineering. Editorial Advisory Board provides valuable advice on technical matters related to the publication of Transactions.