喷射成形<strong>M3</strong>高速钢热处理过程中组织的演变和硬度偏低问题

doi:10.11901/1005.3093.2022.493

材料研究学报

2023, Vol. 37

Issue (8): 625-632 DOI: 10.11901/1005.3093.2022.493

研究论文

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喷射成形M3高速钢热处理过程中组织的演变和硬度偏低问题

刘继浩¹^,², 迟宏宵¹(

), 武会宾², 马党参¹, 周健¹, 徐辉霞³

^1.钢铁研究总院有限公司特殊钢研究院北京 100081
^2.北京科技大学钢铁共性技术协同创新中心北京 100083
^3.天工爱和特钢有限公司丹阳 212312

Heat Treatment Related Microstructure Evolution and Low Hardness Issue of Spray Forming M3 High Speed Steel

LIU Jihao¹^,², CHI Hongxiao¹(

), WU Huibin², MA Dangshen¹, ZHOU Jian¹, XU Huixia³

^1.Institute for Special Steels, Center Iron and Steel Research Institute Co., Beijing 100081, China
^2.Collaborative Innovation Center of Steel Technology, University of Science and Technology Beijing, Beijing 100083, China
^3.Tiangong Aihe Special Steel Co. Ltd., Danyang 212312, China

引用本文:

刘继浩, 迟宏宵, 武会宾, 马党参, 周健, 徐辉霞. 喷射成形M3高速钢热处理过程中组织的演变和硬度偏低问题[J]. 材料研究学报, 2023, 37(8): 625-632.
Jihao LIU, Hongxiao CHI, Huibin WU, Dangshen MA, Jian ZHOU, Huixia XU. Heat Treatment Related Microstructure Evolution and Low Hardness Issue of Spray Forming M3 High Speed Steel[J]. Chinese Journal of Materials Research, 2023, 37(8): 625-632.

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摘要:

对喷射成形M3高速钢进行不同制度的热处理，使用OM、SEM、TEM、EDS、XRD以及硬度测试等手段研究了这种钢在淬、回火过程中的组织和硬度变化以及硬度偏低问题。结果表明，随着淬火温度的提高组织中的M₆C型碳化物百分占比呈降低的趋势，而MC型碳化物的百分占比只有在淬火温度高于1200℃时才稍有降低；在淬火温度不高于1230℃的条件下仍能保证组织中碳化物尺寸细小且均匀分布。组织中的MC型碳化物成分分布的不均匀与其生成和工艺的雾化过程相关。随着淬火温度由1200℃提高到1230℃，钢的回火硬度显著提高。淬火温度的提高使MC型碳化物的溶解量提高，可有效解决喷射成形高速钢硬度偏低的问题。

关键词 ：金属材料, 喷射成形高速钢, 热处理, 硬度

Abstract：

Spray forming is a casting process, by which the molten metal is directly converted to a solid bulk with unique characteristics. When used in the production of high speed steel, spray forming materials typically present microstructures composed of refined polygonal grains, uniformly distributed carbides and low levels of micro and macro-segregation. The mechanical properties of the spray forming high speed steel are usually between ones made by powder metallurgy, casting and wrought. It can be considered as a cost saving alternative for large-scale industrial production of high-speed steels. But for high-speed steel produced by spray forming, its shortcomings can't be ignored: i.e. once being subjected to the same heat treatment, compared with the steels made by PM and CW process, the spray forming one often shows lower hardness. Focusing on the solution of aforementioned disadvantages, the effect of different heat treatments on the microstructural evolution and hardness variation was assessed for the spray forming M3 high-speed steel, and the adopted heat treatment involved quenching and tempering at different temperatures separately. Meanwhile the reasons for the low hardness of the spray-formed M3 high-speed steel were also discussed. The results show that SF M3 high speed steel quenched below 1230℃ can still ensure relatively fine grain size and uniform size distribution of carbide particles; Setting the tempering at 560℃, in case the quenching temperature raises from 1200℃ to 1230℃, after being quenched + tempered, the hardness of spray-formed M3 high-speed steel can be greatly improved. It is believed that the low hardness issue may be ascribed to the fact: the formation of a large number of MC type carbides with inhomogeneous composition in the spray forming atomization stage, the MC type carbides can't be fully dissolved in the steel matrix when quenching at lower temperature during the heat treatment process, resulting in insufficient amount of carbon and alloying elements in the matrix. Therefore, the low hardness issue is caused by the inability to fully exert the secondary hardening effect.

Key words： metallic materials spray forming M3 high speed steel heat treatment hardness

收稿日期: 2022-09-09

ZTFLH:

TG142.7

通讯作者: 迟宏宵，高级工程师，chihongxiao@163.com，研究方向为工模具钢材料

Corresponding author: CHI Hongxiao, Tel: (010)62182268, E-mail:chihongxiao@163.com

作者简介: 刘继浩，男，1992年生，博士生

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图1 喷射成形M3高速钢边部的组织

图2 退火态喷射成形M3高速钢的XRD谱

表2 图1b中1~4处的EDS分析结果

图3 淬火温度不同的喷射成形M3高速钢的XRD谱

图4 淬火温度不同的钢中碳化物的形貌及统计结果

图5 EDS面扫描合金元素分布及MC型碳化物线扫描元素分布

图6 淬回火温度不同的钢的硬度变化

图7 析出相的形貌及位相关系

图8 用喷射成形和铸锻制备的M3高速钢在不同温度淬火后硬度的对比

图9 在不同温度下W、Mo、V合金元素的扩散曲线

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