Understanding the role of geometry and interlayer cooling time on microstructure variations in LPBF Ti6Al4V through part-scale scan-resolved thermal modeling

IF 4.2 Q2 ENGINEERING, MANUFACTURING Additive manufacturing letters Pub Date : 2024-02-03 DOI:10.1016/j.addlet.2024.100197
Alaa Olleak , Evan Adcock , Shawn Hinnebusch , Florian Dugast , Anthony D. Rollett , Albert C. To
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Abstract

In this study, we investigated the microstructural variation of Ti-6Al-4 V in inverted pyramid parts built using Laser Powder Bed Fusion (LPBF). Two parts were fabricated with and without ghost parts to study the effects of interlayer delay time on thermal history and microstructure. Finite Element Method (FEM) based process simulation was used to predict the thermal history and cooling rates during the LPBF process to understand the location-specific microstructure and mechanical properties variation. The thermal analysis findings revealed that the variations in the cooling rates and pre-deposition temperature were notably significant. Within the same part, the cooling rates exhibited significant variations, differing by up to three orders of magnitude in two scenarios: (1) within the same layer, influenced by the proximity to the edges, and (2) at different heights, attributable to the strongly varying cross-section. Comparing the two parts, the cooling rates of the part with ghost parts were approximately two orders of magnitude higher than in the part without the ghost parts. This significant difference can be attributed to the extended interlayer cooling time and lower pre-deposition temperature resulting from the presence of two ghost parts which introduced an effective delay time between laser scans. Experimental validation against microstructure images and hardness measurements showed similar trends with the predicted results. These findings provide valuable insights into controlling microstructure at specific locations during LPBF fabrication, which is essential for building complex geometries with controlled material properties.

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通过部分尺度扫描分辨热建模了解几何形状和层间冷却时间对 LPBF Ti6Al4V 微观结构变化的作用
在这项研究中,我们研究了使用激光粉末床熔融(LPBF)制造的倒金字塔部件中 Ti-6Al-4 V 的微观结构变化。为了研究层间延迟时间对热历史和微观结构的影响,我们分别制造了带幽灵部件和不带幽灵部件的两个零件。基于有限元法(FEM)的工艺模拟用于预测 LPBF 工艺过程中的热历史和冷却速率,以了解特定位置的微观结构和机械性能变化。热分析结果表明,冷却速率和沉积前温度的变化非常明显。在同一零件中,冷却速率变化显著,在两种情况下相差达三个数量级:(1)在同一层内,受靠近边缘的影响;(2)在不同高度,由于截面变化很大。比较两个部件,有幽灵部件的部件的冷却速率比没有幽灵部件的部件高出约两个数量级。这一显著差异可归因于两个幽灵部件的存在延长了层间冷却时间,降低了预沉积温度,从而引入了激光扫描之间的有效延迟时间。根据微观结构图像和硬度测量结果进行的实验验证显示了与预测结果相似的趋势。这些发现为在 LPBF 制作过程中控制特定位置的微观结构提供了有价值的见解,这对于制作具有可控材料特性的复杂几何形状至关重要。
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来源期刊
Additive manufacturing letters
Additive manufacturing letters Materials Science (General), Industrial and Manufacturing Engineering, Mechanics of Materials
CiteScore
3.70
自引率
0.00%
发文量
0
审稿时长
37 days
期刊最新文献
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