微观结构
材料科学
板条
微合金钢
冶金
延伸率
马氏体
降水
位错
体积分数
沉淀硬化
粒度
复合材料
空气冷却
产量(工程)
透射电子显微镜
冲击能
材料的强化机理
缓慢冷却
晶界
可塑性
韧性
作者
Hanyu Luo,Xuexian Lin,Chao Lü,Jianchun Cao,Xuegang Xiong,Chuangwei Wang
出处
期刊:Journal of Engineering Materials and Technology-transactions of The Asme
[American Society of Mechanical Engineers]
日期:2025-08-14
卷期号:148 (1)
摘要
Abstract This study investigates the effects of post-rolling cooling methods (quench cooling, air cooling, and furnace cooling) on the microstructure and properties of Ti–Zr microalloyed steel via laboratory rolling tests. The microstructure is transformed from the lath martensite/bainite to the ferrite-dominated microstructure by decreasing the cooling rate and increasing the average grain size to 3.55 μm in furnace-cooled steel. Concurrently, transmission electron microscopy-based analysis reveals that the precipitate volume fraction increases from 0.038% to 0.106%, with the average size decreasing from 33.5 nm to 6.8 nm, enhancing the precipitation strengthening effect from 23 MPa to 121 MPa. Quench cooling forms a multiphase microstructure (martensite/bainite + ferrite), which reduces the yield ratio, while dislocation tangling in martensite decreases plasticity. Notably, quench-cooled steel exhibits high impact energy (151 J) despite low elongation. This is attributed to synergistic toughening by high dislocation density (1014 m−2) and retained austenite. Furnace-cooled steel balances strength (yield—716.5 MPa, tensile—787.6 MPa), elongation (18.9%), and 0 °C impact energy (133 J), thereby demonstrating cooling rate-controlled synergy between strengthening–toughening mechanisms in Ti–Zr microalloyed steel.
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