The effect of thermal cycle on microstructure evolution and mechanical properties of Co-free maraging steel produced by wire arc additive manufacturing

IF 6.7 2区 材料科学 Q1 ENGINEERING, INDUSTRIAL
Xiaotian Zhang , Lei Wang , Ning Zhao , Runchang Liu , Lei Zhang , Wendi Wu , Dongqing Yang , Yong Huang , Kehong Wang
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Abstract

Microstructures and mechanical properties are closely related to thermal cycles during additive manufacturing. For maraging steel, the research on the effect of thermal cycles during additive manufacturing is limited. Based on the above issues, this work investigated the effect of thermal cycles in the process of wire arc additive manufacturing Co-free maraging steel on microstructure evolution and mechanical properties, and attempted to establish the relationship between thermal cycles and microstructure as well as mechanical properties of maraging steel on the basis of quantitative thermal cycle data. The results show that in the additive manufacturing process, the thermal cycles affect the cooling rate, so that the primary dendrite arm spacing and grain size gradually increase along the height direction. For maraging steel, in additive manufacturing, welding or other hot processing processes, the thermal cycles make the martensite reverse change, resulting in an increase in austenite content, resulting in grain refinement. Thermal cycles in additive manufacturing result in differences in the grain size, grain boundary ratio, dislocation density and primary dendrite arm spacing, resulting in inhomogeneity of the mechanical properties in the height direction. The difference in microstructure in different directions of additive manufacturing samples leads to anisotropy of tensile properties. The results of this work can elucidate and refine the action mechanism of thermal cycles on maraging steel. In addition, this work can be used to control thermal cycles by changing the process and cooling conditions, etc., to obtain maraging steel samples with homogeneous or gradient properties, which is highly important.

热循环对线弧快速成型技术生产的无钴马氏体时效钢微观结构演变和力学性能的影响
微观结构和机械性能与增材制造过程中的热循环密切相关。对于马氏体时效钢而言,有关增材制造过程中热循环影响的研究十分有限。基于上述问题,本文研究了线弧快速成型制造无钴马氏体时效钢过程中热循环对微观组织演变和力学性能的影响,并试图在定量热循环数据的基础上建立马氏体时效钢热循环与微观组织及力学性能之间的关系。结果表明,在快速成型过程中,热循环会影响冷却速度,从而使原始枝晶臂间距和晶粒尺寸沿高度方向逐渐增大。对于马氏体时效钢,在增材制造、焊接或其他热加工过程中,热循环使马氏体发生反向变化,导致奥氏体含量增加,从而造成晶粒细化。增材制造中的热循环会导致晶粒大小、晶界比、位错密度和主枝晶臂间距的差异,从而造成高度方向上机械性能的不均匀性。增材制造样品在不同方向上的微观结构差异导致了拉伸性能的各向异性。这项工作的结果可以阐明和完善热循环对马氏体时效钢的作用机制。此外,这项工作还可用于通过改变工艺和冷却条件等来控制热循环,从而获得具有均匀或梯度特性的马氏体时效钢样品,这一点非常重要。
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来源期刊
Journal of Materials Processing Technology
Journal of Materials Processing Technology 工程技术-材料科学:综合
CiteScore
12.60
自引率
4.80%
发文量
403
审稿时长
29 days
期刊介绍: The Journal of Materials Processing Technology covers the processing techniques used in manufacturing components from metals and other materials. The journal aims to publish full research papers of original, significant and rigorous work and so to contribute to increased production efficiency and improved component performance. Areas of interest to the journal include: • Casting, forming and machining • Additive processing and joining technologies • The evolution of material properties under the specific conditions met in manufacturing processes • Surface engineering when it relates specifically to a manufacturing process • Design and behavior of equipment and tools.
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