L. Becker , F. Radtke , J. Lentz , S. Herzog , C. Broeckmann , S. Weber
{"title":"利用壳芯策略快速成型制造高氮奥氏体钢","authors":"L. Becker , F. Radtke , J. Lentz , S. Herzog , C. Broeckmann , S. Weber","doi":"10.1016/j.addlet.2024.100205","DOIUrl":null,"url":null,"abstract":"<div><p>Laser Powder Bed Fusion/Metal (PBF-LB/M) is a promising technology for industrial applications, but challenges such as long process times remain. Innovations such as the shell-core approach aim to address this by creating a dense shell around a minimally exposed powder core, significantly reducing processing times, with full densification and property adjustments achieved by subsequent hot isostatic pressing (HIP). This study focuses on the fabrication of shell-core samples using a powder mixture of austenitic steel and Si<sub>3</sub>N<sub>4</sub> to produce high nitrogen steel PBF-LB/M components, which are otherwise difficult to produce due to the limited nitrogen solubility in the melt. PBF-LB/M induces Si<sub>3</sub>N<sub>4</sub> decomposition, resulting in Si and N loss through laser-powder interaction. Si<sub>3</sub>N<sub>4</sub> particles in the still powdered regions serve as a source of N enrichment during HIP, circumventing the limitations of nitrogen solubility in the melt and exploiting the higher solubility in the solid. After HIP, energy dispersive spectrometry and electron backscatter diffraction reveal a fully austenitic matrix with Si diffusion seams mainly in non-laser-exposed areas. The Si<sub>3</sub>N<sub>4</sub> dissolution during HIP contributes to an interstitial dissolved N content of about 0.189 mass%, which, together with the higher Si content, increases hardness. Wavelength dispersive spectrometry (WDS) and nanoindentation line scans show decreasing Si and N concentrations from core to shell, resulting in reduced (nano)hardness in the shell. This innovative approach demonstrates the potential to produce AM components with enhanced properties by overcoming the limitations of nitrogen solubility in the steel melt during PBF-LB/M.</p></div>","PeriodicalId":72068,"journal":{"name":"Additive manufacturing letters","volume":null,"pages":null},"PeriodicalIF":4.2000,"publicationDate":"2024-03-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S2772369024000148/pdfft?md5=0b96795d1bc1ad1cac1fac3ff935da14&pid=1-s2.0-S2772369024000148-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Additive manufacturing of high nitrogen austenitic steel using shell-core strategy\",\"authors\":\"L. Becker , F. Radtke , J. Lentz , S. Herzog , C. Broeckmann , S. 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Si<sub>3</sub>N<sub>4</sub> particles in the still powdered regions serve as a source of N enrichment during HIP, circumventing the limitations of nitrogen solubility in the melt and exploiting the higher solubility in the solid. After HIP, energy dispersive spectrometry and electron backscatter diffraction reveal a fully austenitic matrix with Si diffusion seams mainly in non-laser-exposed areas. The Si<sub>3</sub>N<sub>4</sub> dissolution during HIP contributes to an interstitial dissolved N content of about 0.189 mass%, which, together with the higher Si content, increases hardness. Wavelength dispersive spectrometry (WDS) and nanoindentation line scans show decreasing Si and N concentrations from core to shell, resulting in reduced (nano)hardness in the shell. 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引用次数: 0
摘要
激光粉末床熔融/金属(PBF-LB/M)是一项很有前途的工业应用技术,但仍存在加工时间长等挑战。壳核方法等创新技术旨在解决这一问题,通过在微露的粉末核心周围形成致密外壳,大大缩短了加工时间,并通过随后的热等静压(HIP)实现完全致密化和性能调整。本研究的重点是使用奥氏体钢和 Si3N4 的粉末混合物制造壳芯样品,以生产高氮钢 PBF-LB/M 部件,由于氮在熔体中的溶解度有限,这种部件很难生产。PBF-LB/M 可诱导 Si3N4 分解,通过激光与粉末的相互作用造成硅和氮的损失。在 HIP 过程中,静止粉末区域的 Si3N4 颗粒可作为氮富集源,从而规避熔体中氮溶解度的限制,并利用固体中更高的溶解度。HIP 之后,能量色散光谱仪和电子反向散射衍射显示出完全奥氏体基体,硅扩散缝主要位于非激光暴露区域。在 HIP 过程中,Si3N4 的溶解导致间隙溶解 N 含量达到约 0.189 质量%,这与较高的 Si 含量一起提高了硬度。波长色散光谱法(WDS)和纳米压痕线扫描显示,从内核到外壳,硅和氮的浓度不断下降,导致外壳的(纳米)硬度降低。这种创新方法克服了 PBF-LB/M 过程中钢水中氮溶解度的限制,证明了生产具有更佳性能的 AM 部件的潜力。
Additive manufacturing of high nitrogen austenitic steel using shell-core strategy
Laser Powder Bed Fusion/Metal (PBF-LB/M) is a promising technology for industrial applications, but challenges such as long process times remain. Innovations such as the shell-core approach aim to address this by creating a dense shell around a minimally exposed powder core, significantly reducing processing times, with full densification and property adjustments achieved by subsequent hot isostatic pressing (HIP). This study focuses on the fabrication of shell-core samples using a powder mixture of austenitic steel and Si3N4 to produce high nitrogen steel PBF-LB/M components, which are otherwise difficult to produce due to the limited nitrogen solubility in the melt. PBF-LB/M induces Si3N4 decomposition, resulting in Si and N loss through laser-powder interaction. Si3N4 particles in the still powdered regions serve as a source of N enrichment during HIP, circumventing the limitations of nitrogen solubility in the melt and exploiting the higher solubility in the solid. After HIP, energy dispersive spectrometry and electron backscatter diffraction reveal a fully austenitic matrix with Si diffusion seams mainly in non-laser-exposed areas. The Si3N4 dissolution during HIP contributes to an interstitial dissolved N content of about 0.189 mass%, which, together with the higher Si content, increases hardness. Wavelength dispersive spectrometry (WDS) and nanoindentation line scans show decreasing Si and N concentrations from core to shell, resulting in reduced (nano)hardness in the shell. This innovative approach demonstrates the potential to produce AM components with enhanced properties by overcoming the limitations of nitrogen solubility in the steel melt during PBF-LB/M.