On the role of the preheat temperature in electron-beam powder bed fusion processed IN718

IF 4.2 Q2 ENGINEERING, MANUFACTURING
Nana Kwabena Adomako , Michael Haines , Nima Haghdadi , Sophie Primig
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Abstract

Process parameters optimization in additive manufacturing (AM) is usually required to unlock superior properties, and this is often facilitated by modeling. In electron beam powder bed fusion (E-PBF), the preheat temperature is an important parameter to be optimized as it significantly influences the microstructure and properties. Here we compare the effect of two preheat temperatures (1000 and 950°C, above and below δ-phase solvus temperature) on the microstructural evolution of E-PBF IN718 Ni-based superalloy. Using thermal and thermo-kinetic modeling, we predict microstructural changes and compare them with experimental findings. A decrease of only 50°C in the preheat temperature has a low impact on the solidification microstructure with a slight reduction in columnar grain width. In the solid-state, higher preheating causes intergranular δ-phase precipitation, contributing to a higher γ" precipitation potential, formation of co-precipitates, and higher hardness. The lower preheat temperature induces intergranular and intragranular δ-phase precipitation, reducing the γ" precipitation potential and hardness. The chemical composition of γ' and γ" is largely unaffected by the preheat temperature variation. These insights underscore the importance of preheat temperature optimization in microstructure design and property control during E-PBF.

Abstract Image

论预热温度在电子束粉末床熔融处理 IN718 中的作用
通常需要对增材制造(AM)工艺参数进行优化,以获得优异的性能,而建模通常有助于实现这一目标。在电子束粉末床熔融(E-PBF)中,预热温度是一个需要优化的重要参数,因为它对微观结构和性能有重大影响。在此,我们比较了两种预热温度(1000 和 950°C,高于和低于δ相溶解温度)对 E-PBF IN718 Ni 基超合金微观结构演变的影响。通过热和热动力学建模,我们预测了微观结构的变化,并将其与实验结果进行了比较。预热温度仅降低 50°C 对凝固微观结构的影响较小,柱状晶粒宽度略有减少。在固态下,较高的预热温度会导致晶间δ相析出,从而产生较高的γ "析出势,形成共沉淀物,并提高硬度。较低的预热温度会诱发晶间和晶内δ相析出,从而降低γ "析出势和硬度。γ'和γ "的化学成分基本不受预热温度变化的影响。这些见解强调了在 E-PBF 过程中优化预热温度对微观结构设计和性能控制的重要性。
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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%
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0
审稿时长
37 days
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