A Multi-objective Approach to Solve the Build Orientation Problem in Additive Manufacturing

Matos, Marina A.; Rocha, Ana Maria A. C.; Costa, Lino; Pereira, Ana I.

doi:10.1007/978-3-030-24302-9_19

Cited by 8 publications

(8 citation statements)

References 22 publications

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“…However, it must be noted that using convex hulls may not be appropriate for certain part geometries, particularly those containing concave features. Matos et al (2019) used weighted Tchebycheff scalarization method to address the multi-objective optimisation challenge of amount of supporting material and build time. However, they did not report any figures regarding the number of model evaluations.…”

Section: Other Noteworthy Approachesmentioning

confidence: 99%

Bayesian optimisation of part orientation in additive manufacturing

Goguelin

Dhokia

Flynn

2021

International Journal of Computer Integrated Manufacturing

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Additive manufacturing (AM) remains slow in terms of volumetric processing rates. Minimising support for overhanging faces is an effective method of reducing material wastage and postprocessing cost. Mindful design can remove much of this support; however, well-selected build orientations are still essential. Searching all feasible orientations is inefficient due to the large number of faces in many mesh files. Nevertheless, support structure generation forms a critical part of the AM process planning stage. This research uses novel combinations of proxy evaluation criteria models for support estimation and optimisation methods to minimise support structure. The number of overhanging facets, overall support structure length and a new estimate for the volume of support structure are used in place of a precise calculation of support quantity. These proxies are used within three different optimisation schemes: grid search, random search and Bayesian optimisations (BO). BO is found to out-perform random and grid search techniques, with grid search having the worst performance in most cases, requiring up to 17-times fewer optimisation iterations. The overall length of support is the most effective proxy model, even outperforming the volume of support estimation, and is shown to perform within 3.5% of results benchmarked against commercial software.

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Section: Other Noteworthy Approachesmentioning

confidence: 99%

Bayesian optimisation of part orientation in additive manufacturing

Goguelin

Dhokia

Flynn

2021

International Journal of Computer Integrated Manufacturing

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“…The other measure of the quality used in this study is called the support area, that corresponds to the total contact area of the external supports with the object [5,8,13]. Mathematically, the support area, SA, is given by…”

Section: Quality Measuresmentioning

confidence: 99%

“…Matos et al in [5] used a global optimization method, the Electromagnetism-like algorithm, to optimize six printing quality measures in order to find the optimal build orientations of six 3D CAD models. Moreover, different multi-objective approaches have been developed in order to determine a set of trade-off optimal build orientations, when optimizing more than one quality measure simultaneously [10,11,12,13,14,15]. For example, in [16] the authors applied the NSGA-II multi-objective method to determine the Pareto optimal set of build orientations based on four quality measures (the support area, the build time, the surface roughness, and the overall quality of the surface).…”

Section: Introductionmentioning

confidence: 99%

Implementation of Robust Multi-objective Optimization in the Build Orientation Problem

Matos

Rocha

Costa

et al. 2021

Computational Science and Its Applications – ICCSA 2021

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Additive manufacturing (AM) is an emerging technology to create 3D objects layer-by-layer directly from a 3D CAD model. The build orientation is a critical issue in AM and its optimization will significantly reduce the building costs and improve object accuracy. This paper aims to optimize the build orientation problem of a 3D CAD model using a robust multi-objective approach, taking into account the staircase effect and the support area characteristics. Thus, the main objective is to obtain a robust Pareto optimal front, composed of solutions that are not quite sensitive to perturbations in the variables. In this manner, a set of robust solutions is presented as alternatives and the decision-maker can identify the compromise solutions and choose according to his/her preferences.

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“…Ga et al (2019) proposed a multi-objective strategy using a weighted sum method in order to reduce the support volume, build time and costs and increase the surface quality, depending on the orientation chosen by the user and the weights associated with each objective function. Matos, Rocha, Costa, and Pereira (2019) proposed a multi-objective problem using the Tchebycheff method with the Electromagnetism-like algorithm to minimize the area of the object in contact with the supporting structures and the build time of four 3D models. The study involved the combination between two objectives.…”

Section: Introductionmentioning

confidence: 99%

Many-objective optimization of build part orientation in additive manufacturing

Matos

Rocha

Costa

2020

Int J Adv Manuf Technol

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Additive manufacturing is the process of building a three-dimensional object from a computer-aided design model, by successively adding material layerby-layer. This technology allows to print complex shape objects and is being rapidly adopted throughout the aircraft industry, medical implants, jewelry, footwear industry, automotive industry and fashion products.The build orientation of 3D objects has a strong influence on many quality characteristics. In this paper, a many-objective approach is applied to the Fin model, using the NSGA-II algorithm to optimize four conflicting objective functions regarding the need for support structures, the build time, the surface roughness and the overall quality of the surface.First, a bi-objective optimization is performed for each couple of two objectives and some representative solutions are identified. However, when applying manyobjective optimization to the four objective functions simultaneously, some more orientation angles are found as good optimal solutions. Visualization tools are used to inspect the relationships and the trade-offs between the objectives. Then, the decision-maker can choose which orientation angles are more favorable according to his/her preferences. The optimal solutions found confirmed the effectiveness of the proposed approach.

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A Multi-objective Approach to Solve the Build Orientation Problem in Additive Manufacturing

Cited by 8 publications

References 22 publications

Bayesian optimisation of part orientation in additive manufacturing

Bayesian optimisation of part orientation in additive manufacturing

Implementation of Robust Multi-objective Optimization in the Build Orientation Problem

Many-objective optimization of build part orientation in additive manufacturing

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