Integrated Modelling and Simulation of the Additive Manufacturing and Heat Treatment Process Chain

Patrick Esser, J. Thorborg, G. Hartmann, W. Schaefer
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Abstract

Additive manufacturing of metal parts is widely used for different alloys and different types of application. During building of the parts, local heating of the powder generates a small melt pool with high thermal gradients followed by rapid solidification. Already solidified material is re-melted and affected by heating when layers are added. The thermal history of the moving heat source and the layer building of the part have a high influence on the formed microstructure, the risk of porosities and evolution of cracks. High stresses and permanent deformations develop during the building process, which lead to large deformations when e.g. the base plate is removed. Heat treatment of the parts is often used to reduce the stress level and to minimize the deformations.

This paper presents an integrated modelling and simulation approach, where results from the additive manufacturing process are used as initial conditions for the subsequent heat treatment process.

An integrated simulation approach has been developed and implemented as a dedicated solution to simulate the sequence of the additive manufacturing process and subsequent heat treatment steps. To get reasonable calculation times multiscale methods have been tested to perform virtual experiments, where the influence of different scanning strategies have been evaluated to optimize temperature distributions and the influence on mechanical performance. A unified creep model is used to describe the mechanical behavior of the material to ensure a consistent description through the large temperature interval and the different levels of time and strain rates.
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增材制造与热处理工艺链集成建模与仿真
金属零件的增材制造广泛应用于不同合金和不同类型的应用。在零件制造过程中,粉末的局部加热产生一个具有高热梯度的小熔池,随后快速凝固。已经固化的材料被重新熔化,并在添加层时受到加热的影响。运动热源的热历史和零件的层结构对形成的微观结构、孔隙的风险和裂纹的演变有很大的影响。在建筑过程中会产生高应力和永久变形,当底板被拆除时,会导致较大的变形。零件的热处理通常用于降低应力水平和尽量减少变形。本文提出了一种集成的建模和仿真方法,其中增材制造过程的结果用作后续热处理过程的初始条件。已经开发并实施了集成仿真方法,作为专用解决方案来模拟增材制造过程和后续热处理步骤的顺序。为了获得合理的计算时间,采用多尺度方法进行了虚拟实验,评估了不同扫描策略对优化温度分布和力学性能的影响。采用统一的蠕变模型来描述材料的力学行为,以保证在大温度区间和不同的时间和应变率水平下描述的一致性。
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