Ju Yao, Qiyang Tan, Jeffrey Venezuela, Andrej Atrens, Ming-Xing Zhang
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The medium carbon content and low alloying element concentration enable AM processing to produce a uniform and refined bainite microstructure with minimal elemental segregation, avoiding the formation of unstable retained austenite. The high AM-processability of this steel is demonstrated by achieving high densification (>99.9 %) across a broad processing window, which allows precise microstructural control via proper tunning the processing parameter modifications, inducing a transition from upper bainite to lower bainite dominance, to tailor mechanical properties for specific applications. The as AM-fabricated AISI 4340 steel exhibits a good combination of strength, ductility, and toughness, manifested by a yield strength range from 1240 to 1370 MPa, an ultimate tensile strength from 1360 to 1740 MPa, an elongation from 7 % to 14 %, and an impact toughness range of 11–44 J. The mechanical properties of the AM-fabricated 4340 steel are comparable to those of the wrought counterpart and superior to the majority of other AM-fabricated steels. 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引用次数: 0
摘要
增材制造(AM)为钢部件制造带来了革命性的变化,但并非所有钢材都能适应其独特的凝固特性,其特点是循环快速加热/冷却和定向凝固。这些条件通常会导致柱状晶粒形成、微观结构异质性等挑战,从而导致机械性能下降、脆性增加,尤其是严重的各向异性。最近的研究采用接种或制造后处理来解决这一问题,但往往需要额外的成本和加工时间。本研究旨在验证某些钢材(如 AISI 4340 钢)与 AM 的内在兼容性,生产出的部件天生坚固耐用,可在竣工状态下使用。中碳含量和低合金元素浓度使 AM 加工能够产生均匀、细化的贝氏体微观结构,元素偏析最小,避免形成不稳定的残余奥氏体。这种钢在宽广的加工窗口内实现了高致密化(99.9%),从而证明了 AM 加工的高可用性,通过适当调整加工参数,可以精确控制微观结构,实现从上贝氏体为主到下贝氏体为主的转变,为特定应用定制机械性能。AM 制造的 AISI 4340 钢具有良好的强度、延展性和韧性组合,屈服强度范围为 1240 至 1370 兆帕,极限抗拉强度范围为 1360 至 1740 兆帕,伸长率范围为 7 % 至 14 %,冲击韧性范围为 11-44 J。AM 制造的 4340 钢的机械性能与锻造钢相当,优于大多数其他 AM 制造钢。这项研究揭示了 AM 在加工高强度低合金钢方面的巨大潜力。
Additive manufacturing of high-strength low-alloy AISI 4340 steel with an optimal strength-ductility-toughness trade-off
Additive manufacturing (AM) has revolutionised steel part fabrication, yet not all steels are amenable to its unique solidification features, characterised by cyclic and rapid heating/cooling, and directional solidification. These conditions often result in challenges such as columnar grain formation, microstructural heterogeneity, and consequently, inferior mechanical performance, brittleness and severe anisotropy in particular. Recent studies have adopted inoculation or post-fabrication treatments to address this issue, but often entailing extra cost and processing time. This study aims to verify that some steels such as AISI 4340 steel are inherently compatible to AM, producing components that are innately robust and ready for use in the as-built state. The medium carbon content and low alloying element concentration enable AM processing to produce a uniform and refined bainite microstructure with minimal elemental segregation, avoiding the formation of unstable retained austenite. The high AM-processability of this steel is demonstrated by achieving high densification (>99.9 %) across a broad processing window, which allows precise microstructural control via proper tunning the processing parameter modifications, inducing a transition from upper bainite to lower bainite dominance, to tailor mechanical properties for specific applications. The as AM-fabricated AISI 4340 steel exhibits a good combination of strength, ductility, and toughness, manifested by a yield strength range from 1240 to 1370 MPa, an ultimate tensile strength from 1360 to 1740 MPa, an elongation from 7 % to 14 %, and an impact toughness range of 11–44 J. The mechanical properties of the AM-fabricated 4340 steel are comparable to those of the wrought counterpart and superior to the majority of other AM-fabricated steels. This research reveals the high potential of AM to process high-strength low-alloy steels.
期刊介绍:
Additive Manufacturing stands as a peer-reviewed journal dedicated to delivering high-quality research papers and reviews in the field of additive manufacturing, serving both academia and industry leaders. The journal's objective is to recognize the innovative essence of additive manufacturing and its diverse applications, providing a comprehensive overview of current developments and future prospects.
The transformative potential of additive manufacturing technologies in product design and manufacturing is poised to disrupt traditional approaches. In response to this paradigm shift, a distinctive and comprehensive publication outlet was essential. Additive Manufacturing fulfills this need, offering a platform for engineers, materials scientists, and practitioners across academia and various industries to document and share innovations in these evolving technologies.