Abstract
Microstructure control in the laser powder bed fusion additive manufacturing processes is a topic of major interest because of the submillimeter length scale at which the manufacturing process occurs. The ability to control the process at the melt pool scale allows for microstructure control that few other manufacturing techniques can match. The majority of work on microstructure control has focused on altering laser parameters to control solidification conditions (Ref (R.R. Dehoff, M.M. Kirka, W.J. Sames, H. Bilheux, A.S. Tremsin, L.E. Lowe, and S.S. Babu, Site Specific Control of Crystallographic Grain Orientation through Electron Beam Additive Manufacturing, Mater. Sci. Technol., 2014, 31(8), p 931–938. R. Shi, S.A. Khairallah, T.T. Roehling, T.W. Heo, J.T. McKeown, and M.J. Matthews, Microstructural Control in Metal Laser Powder Bed Fusion Additive Manufacturing Using Laser Beam Shaping Strategy, Acta Mater., 2020, 184, p 284–305, https://doi.org/10.1016/j.actamat.2019.11.053.)). Other machine parameters, besides the laser parameters, have also been shown to affect the microstructure of AM parts (Ref (N. Nadammal, S. Cabeza, T. Mishurova, T. Thiede, A. Kromm, C. Seyfert, L. Farahbod, C. Haberland, J.A. Schneider, P.D. Portella, and G. Bruno, Effect of Hatch Length on the Development of Microstructure, Texture and Residual Stresses in Selective Laser Melted Superalloy Inconel 718, Mater. Des., 2017, 134, p 139–150, https://doi.org/10.1016/j.matdes.2017.08.049. F. Geiger, K. Kunze, and T. Etter, Tailoring the Texture of IN738LC Processed by Selective Laser Melting (SLM) by Specific Scanning Strategies, Mater. Sci. Eng. A, 2016, 661, p 240–246, https://doi.org/10.1016/j.msea.2016.03.036.)). We propose an investigation of the effects of hatch spacing and layer thickness on microstructure development in laser powder bed fusion additive manufacturing. A Monte Carlo Potts model with textured solidification capabilities is used to study the effects of these parameters on a unidirectional scan strategy. The simulation results reveal substantial changes in grain morphology as well as texture. Additionally, EVP-FFT crystal plasticity simulations were performed to evaluate the effect of the microstructural shifts on mechanical response. The conclusions from this work elucidate the effects of these parameters on part microstructure as predicted by the texture-aware solidification Potts model and inform understanding of how bulk texture is predicted by the simulation approach.
Highlights
Laser powder bed fusion (LPBF) additive manufacturing (AM) is a manufacturing technique that offers a variety of advantages over other, more traditional, manufacturing tech-This invited article is part of a special topical focus in the Journal of Materials Engineering and Performance on Additive Manufacturing
We propose an investigation of the effects of hatch spacing and layer thickness on microstructure development in laser powder bed fusion additive manufacturing
We recently showed that adding a misorientation dependent mobility function to a Monte Carlo Potts model enabled simulation of texture evolution in Inconel 718 parts fabricated via LPBF AM for a variety of laser parameters (Ref 20)
Summary
Laser powder bed fusion (LPBF) additive manufacturing (AM) is a manufacturing technique that offers a variety of advantages over other, more traditional, manufacturing tech-. We recently showed that adding a misorientation dependent mobility function to a Monte Carlo Potts model enabled simulation of texture evolution in Inconel 718 parts fabricated via LPBF AM for a variety of laser parameters (Ref 20). This computationally efficient simulation approach offers the potential to further elucidate microstructure development in AM parts via computationally efficient production of bulk AM microstructures. We explore the effects of changing hatch spacing and layer thickness within the texture-aware solidification Potts model to understand the effect of these variables on the synthetic microstructures generated by this technique We quantify both the grain morphology and crystallographic texture, as well as characterize the mechanical response of the microstructures via EVP-FFT micromechanical simulation. The conclusions reveal potentially necessary modifications to the textured solidification Potts model as point to potential strategies for microstructure control in LPBF AM parts
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