Spherical Pores as ‘Microstructural Informants’: Understanding Compositional, Thermal, and Mechanical Gyrations in Additively Manufactured Ti-6Al-4V

Materials Processing & Manufacturing eJournal Pub Date : 2021-06-01 DOI:10.2139/ssrn.3714497

M. Kenney, Katie O’Donnell, M. Quintana, P. Collins

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引用次数: 8

Abstract

Abstract Detailed analysis of defects such as spherical porosity can act as informants, providing some information regarding the complex and often hidden physics associated with additive manufacturing. Variation in the presence and nature of these defects can shed new insights into the AM process. In this paper, the compositional, crystallographic, microstructural, and morphological characteristics surrounding gas pores in Electron Beam Melted Ti-6Al-4V have been assessed and correlated with different scanning strategies (raster and two point melting ones, Dehoff and random). The large spherical pores (>25μm), exclusively present in raster scan, exhibit perturbations normal to the vertical sidewalls of the pores that are likely the result of elastic instabilities resulting from chemical and crystallographic variations and initiated by vertical compression caused by thermal stresses related to the cyclic process – effectively a form of microbuckling. Electron backscatter diffraction maps support the theory that these perturbations occur at elevated temperatures and prior to the final solid-solid phase transformation.

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球形孔隙作为“微观结构信息”:了解增材制造Ti-6Al-4V的成分，热和机械旋转

对诸如球形孔隙等缺陷的详细分析可以作为信息来源，提供有关与增材制造相关的复杂且通常隐藏的物理特性的一些信息。这些缺陷的存在和性质的变化可以为增材制造过程提供新的见解。本文对电子束熔化Ti-6Al-4V中气孔周围的成分、晶体学、显微组织和形态特征进行了评估，并与不同的扫描策略(光栅和两点熔化，德霍夫和随机)进行了关联。大的球形孔隙(>25μm)，仅存在于光栅扫描中，表现出垂直于孔隙垂直侧壁的扰动，这可能是由化学和晶体学变化引起的弹性不稳定性造成的，并且是由与循环过程相关的热应力引起的垂直压缩引起的——实际上是一种微屈曲形式。电子背散射衍射图支持这样的理论，即这些扰动发生在高温下，在最终的固-固相变之前。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Materials Processing & Manufacturing eJournal

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