Geometric Accuracy in Laser- Based Powder Bed Fusion of Polymers: Tolerance optimization by part build orientation

As Additive Manufacturing (AM) enters the manufacturing industry, the technology must adhere to stringent quality demands in terms of dimensional and geometric accuracy. However, due to substantial differences in how these technologies realize three-dimensional geometries, generalization of phenomen...

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Bibliographic Details
Main Author: Leirmo, Torbjørn Langedahl
Format: Dissertation
Language:English
Online Access:Request full text
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Summary:As Additive Manufacturing (AM) enters the manufacturing industry, the technology must adhere to stringent quality demands in terms of dimensional and geometric accuracy. However, due to substantial differences in how these technologies realize three-dimensional geometries, generalization of phenomena across AM technologies proves to be quite difficult. Laser-based Powder Bed Fusion (LB-PBF) is an industrialized AM technology capable of producing functional components and end-use parts. However, to ensure consistent quality for larger production volumes in a mass-customization setting, automated optimization methods and process planning must be developed. This requires valid and reliable data to enable the construction of prediction models. This thesis is centered around the optimization of part build orientation in LB-PBF of polymers (LB-PBF/P) for which a deterministic method is proposed. The proposed method utilize mathematical models for the effect of part build orientation on the accuracy of various geometric features. To this end, an experiment has been conducted to generate data for empirical modeling. Two new models are devised for the prediction of cylindricity and flatness based on the experimental data. Variations within and between production runs in LB-PBF/P obscures the validity of experiments. The first Research Question (RQ) addresses this issue and aims at generating valid data for the subsequent analysis. A matrix layout in four dimensions is developed that enables the control of experimental variables while gauging the effect of part placement and production run. The experimental plan successfully enables the analysis of geometric and dimensional properties as a function of part build orientation. Furthermore, the design makes it possible to characterize the variation within and between different builds. The variation is found to be significant in the y-direction of the build chamber, while x- and z-directions appear to be more stable. The second RQ utilizes the experimental data to reveal the effect of part build orientation on the geometric accuracy of planes and cylinders. First, the data is analyzed, and the conformance of theoretical models is evaluated. This analysis reveals that existing models insufficiently explain the effect of part build orientation on the geometric accuracy of planes and cylinders. Therefore, novel empirical models are proposed to better assimilate the observed behavior. The proposed empirical models differ in