用于增强金属增材制造中光热控制的非衍射光束整形

Nondiffractive beam shaping for enhanced optothermal control in metal additive manufacturing.

作者信息

Tumkur Thejaswi U, Voisin Thomas, Shi Rongpei, Depond Philip J, Roehling Tien T, Wu Sheldon, Crumb Michael F, Roehling John D, Guss Gabe, Khairallah Saad A, Matthews Manyalibo J

机构信息

Physical and Life Sciences Directorate, Lawrence Livermore National Laboratory, Livermore, CA 94550, USA.

National Ignition Facility and Photon Sciences Directorate, Lawrence Livermore National Laboratory, Livermore, CA 94550, USA.

出版信息

Sci Adv. 2021 Sep 17;7(38):eabg9358. doi: 10.1126/sciadv.abg9358. Epub 2021 Sep 15.

DOI:10.1126/sciadv.abg9358

PMID:34524849

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8443179/

Abstract

High thermal gradients and complex melt pool instabilities involved in powder bed fusion–based metal additive manufacturing using focused Gaussian-shaped beams often lead to high porosity, poor morphological quality, and degraded mechanical performance. We show here that Bessel beams offer unprecedented control over the spatiotemporal evolution of the melt pool in stainless steel (SS 316L) in comparison to Gaussian beams. Notably, the nondiffractive nature of Bessel beams enables greater tolerance for focal plane positioning during 3D printing. We also demonstrate that Bessel beams significantly reduce the propensity for keyhole formation across a broad scan parameter space. High-speed imaging of the melt pool evolution and solidification dynamics reveals a unique mechanism where Bessel beams stabilize the melt pool turbulence and increase the time for melt pool solidification, owing to reduced thermal gradients. Consequently, we observe a distinctively improved combination of high density, reduced surface roughness, and robust tensile properties in 3D-printed test structures.

摘要

在使用聚焦高斯光束的基于粉末床熔融的金属增材制造中，高热梯度和复杂的熔池不稳定性常常导致高孔隙率、形态质量差以及机械性能下降。我们在此表明，与高斯光束相比，贝塞尔光束能对不锈钢（SS 316L）熔池的时空演化进行前所未有的控制。值得注意的是，贝塞尔光束的无衍射特性使得在3D打印过程中对焦平面定位具有更大的容差。我们还证明，贝塞尔光束在广泛的扫描参数空间内显著降低了匙孔形成的倾向。熔池演化和凝固动力学的高速成像揭示了一种独特的机制，即由于热梯度降低，贝塞尔光束稳定了熔池湍流并增加了熔池凝固时间。因此，我们在3D打印测试结构中观察到了高密度、降低的表面粗糙度和稳健的拉伸性能的显著改善组合。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/72bb/8443179/f9e5a38f27a0/sciadv.abg9358-f1.jpg

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用于增强金属增材制造中光热控制的非衍射光束整形

Nondiffractive beam shaping for enhanced optothermal control in metal additive manufacturing.

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