大规格V-N微合金化球扁钢连续冷却过程中的组织性能分析

doi:10.13228/j.boyuan.issn1000-7571.011965

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摘要针对规格尺寸扩大带来的球扁钢截面性能不均匀问题,利用静态过冷奥氏体连续冷却转变曲线(CCT曲线)和ANSYS有限元多场耦合模拟相结合方法对V-N微合金化设计大规格球扁钢进行了性能预测。同时利用透射电镜、相分析等试验技术对球头和腹板的强化机理进行研究。结果表明:采用V-N微合金化设计18#不对称球扁钢全截面组织为铁素体+珠光体+贝氏体,冷却过程中球头的冷速比腹板冷速慢2 ℃/s左右,170 s达到最大温差104.6 ℃,球头和腹板晶粒尺寸差异2.7 μm,硬度差异20 HV5。球头较长的高温停留时间使得V(C,N)析出量比腹板更多,析出尺寸更细小。同对比球扁钢相比,采用V-N微合金化设计的试验球扁钢屈服强度提高55~78 MPa,球头与腹板差异从22 MPa减少至1 MPa,显著改善了球扁钢截面均匀性。

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	陈密达
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	周乃鹏
	张云祥

关键词 ：球扁钢, 温度场, 过冷奥氏体连续冷却转变曲线(CCT曲线), ANSYS, V-N微合金化

Abstract：In view of the uneven cross-sectional properties of bulb flat steel caused by the expansion of size, the properties of V-N microalloying large size bulb flat steel were predicted by the combination of static undercooled austenite continuous cooling transformation curve (CCT) and ANSYS finite element multi field coupling simulation.At the same time, the strengthening mechanism of bulb and flat was studied by means of transmission electron microscope and phase analysis. The results show that the full section structure of 18# asymmetric bulb flat steel designed by V-N microalloying was ferrite + pearlite + bainite. The cooling speed of the ball was about 2 ℃/s slower than that of the flat during the cooling process, and the maximum temperature difference reached 104.6 ℃ in 170 s. The grain size and hardness difference between the ball and the flat was 2.7 μm and 20 HV5, respectively. The longer high temperature residence time of the bulb made the precipitation amount of V(C, N) more than that of the flat, and the precipitation size was smaller. Compared with the comparative bulb flat steel, the yield strength of the test bulb flat steel designed by V-N microalloying increased by 55-78 MPa, and the difference between the bulb and the flat was reduced from 22 MPa to 1 MPa, which significantly improved the section uniformity of the bulb flat steel.

Key words： bulb flat steel temperature field undercooled austenite continuous cooling transformation curve(CCT curve) ANSYS V-N microalloying

收稿日期: 2022-08-10

ZTFLH:	TG142.33
	TF76

通讯作者: ^*张云祥(1970—) ,男,副教授,博士,研究方向为金属材料的组织性能预报和控制;E-mail:zhangyunxiangwust@163.com

作者简介: 陈密达(1996—),男,硕士生,研究方向为球扁钢组织和性能研究;E-mail:c1515360100@163.com

引用本文:

陈密达, 梁丰瑞, 沈俊杰, 周乃鹏, 张云祥. 大规格V-N微合金化球扁钢连续冷却过程中的组织性能分析[J]. 冶金分析, 2023, 43(4): 48-57. CHEN Mida, LIANG Fengrui, SHEN Junjie, ZHOU Naipeng, ZHANG Yunxiang. Analysis of microstructure and properties of large size V-N microalloying bulb flat steel during continuous cooling process. , 2023, 43(4): 48-57.

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http://yjfx.chinamet.cn/CN/10.13228/j.boyuan.issn1000-7571.011965 或 http://yjfx.chinamet.cn/CN/Y2023/V43/I4/48

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