Nana Kwabena Adomako, Nima Haghdadi, Sophie Primig
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引用次数: 0
Abstract
The complex microstructure evolution and heterogeneities in metal additive manufacturing (AM) continue to delay the adoption of AM parts by additional industries. Achieving uniform and superior properties in AM parts requires better fundamental understanding of the microstructural evolution. A suitable pathway to gain such understanding is via in situ techniques such as high-speed X-ray imaging, high-resolution infrared cameras, or via synchrotron and neutron diffraction. However, these methods are complex and resource intensive. Modeling may be a more economical avenue, yet, to make these models more robust and reliable, data from in situ techniques are often required. We believe that in some cases, physical simulation methods originally developed for research on conventional processing such as forging, rolling, and welding may provide similar insights. This viewpoint article discusses existing experimental methods for tracking the microstructure evolution during AM in lab-scale settings, focusing on Ni-based superalloys as a case study. The proposed physical simulation methods include the Gleeble thermo-mechanical simulator, dilatometry, and the arc-melting heat treatment technique. These methods can also be integrated into various X-ray, synchrotron, and neutron diffraction set-ups. We discuss how insights derived from thermo-kinetic modeling can underpin the experimental observations from physical simulations. Last, in situ transmission electron microscopy is evaluated as a powerful method with unparalleled resolution for observing the microstructure evolution directly during simulated AM processes. We believe that these methods can be extended to other alloy systems, enhancing scientific understanding, and streamlining the efficient development of AM parts with superior and more uniform properties, promoting the more widespread adoption of AM.
金属增材制造(AM)中复杂的微观结构演变和异质性继续阻碍着更多行业采用增材制造零件。要在 AM 零件中实现均匀和优异的性能,就必须从根本上更好地了解微结构的演变。获得这种认识的合适途径是采用现场技术,如高速 X 射线成像、高分辨率红外摄像机或同步加速器和中子衍射。然而,这些方法都很复杂,需要大量资源。建模可能是一个更经济的途径,然而,要使这些模型更加稳健可靠,往往需要来自现场技术的数据。我们相信,在某些情况下,最初为研究锻造、轧制和焊接等传统加工而开发的物理模拟方法可能会提供类似的见解。这篇观点性文章讨论了在实验室规模环境下跟踪 AM 过程中微观结构演变的现有实验方法,并以镍基超合金为案例进行了重点研究。提出的物理模拟方法包括 Gleeble 热机械模拟器、稀释测量法和电弧熔化热处理技术。这些方法还可以集成到各种 X 射线、同步辐射和中子衍射装置中。我们将讨论从热动力学建模中得出的见解如何为物理模拟实验观测结果提供支持。最后,我们对原位透射电子显微镜进行了评估,认为这是一种功能强大的方法,具有无与伦比的分辨率,可在模拟 AM 过程中直接观察微观结构的演变。我们相信,这些方法可以扩展到其他合金体系,从而提高科学认识,并简化具有更优越、更均匀性能的 AM 零件的高效开发,促进 AM 的更广泛应用。
期刊介绍:
The Journal of Materials Science publishes reviews, full-length papers, and short Communications recording original research results on, or techniques for studying the relationship between structure, properties, and uses of materials. The subjects are seen from international and interdisciplinary perspectives covering areas including metals, ceramics, glasses, polymers, electrical materials, composite materials, fibers, nanostructured materials, nanocomposites, and biological and biomedical materials. The Journal of Materials Science is now firmly established as the leading source of primary communication for scientists investigating the structure and properties of all engineering materials.