Deposition path planning for material extrusion using specified orientation fields

Abstract Conventional material extrusion additive manufacturing (AM) processes require the user to make a trade-off between surface quality and build time of the part. The use of a large bead filament deposition can speed up the build process; however, it leads to surfaces with high roughness due to the stair-stepping effect. The surface quality can be improved by using a small bead filament deposition, which in turn increases the build time of the part. We present a new approach incorporating hybrid multi-resolution layers in material extrusion additive manufacturing to provide excellent surface quality without increasing the build time. Our slicing algorithm generates planar layers with large filament to fill the interior regions in less time. The generated exterior layers are conformal and use small filament to reduce the stair-stepping effect and improve surface quality. We also present a path planning algorithm to build parts with a single manipulator using a multi-nozzle extrusion tool. The path planning algorithm generates a smooth material deposition path by avoiding collision between the tool and the already built layers. It reduces the collision checks and performs collision detection in a computationally efficient manner. We build five parts to validate our approach and illustrate the benefits of multi-resolution AM.

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Decision basis for multi-directional path planning for post-processing reduction in material extrusion

Production Engineering ◽

10.1007/s11740-021-01018-6 ◽

2021 ◽

Author(s):

Steffen Hohenstein ◽

Georg Bergweiler ◽

Gerret Lukas ◽

Viktoria Krömer ◽

Tobias Otten

Keyword(s):

Path Planning ◽

Mechanical Load ◽

Load Capacity ◽

Industrial Applications ◽

Mechanical Resistance ◽

Proof Of Concept ◽

Support Structures ◽

Post Processing ◽

Planning Strategy ◽

Material Extrusion

AbstractReducing support structures in Material Extrusion (ME) of Additive Manufacturing enables lowered post-processing efforts and enhanced use in industrial applications. This study provides a decision basis for multi-directional path planning strategy to print parts on multi-axis printers without the use of support structures. Research solutions for different limitations of ME systems are examined. The combination of Flat and Curved Layer Slicing, Adaptive Slicing, Load-Capable Path Planning and Multi-Axis Slicing enables printing a multi-directional demonstrator part. The part’s build structure consists of form elements (features) with varying build directions depending on the transition areas between them. A proof-of-concept on a three-axis printer shows the ability of a multi-directional printing method for multi-axis printer systems. Interfaces between features require print parameter adjustment to obtain the desired mechanical properties. Tensile tests are performed to evaluate the mechanical load capacity at connecting areas between features of standard specimens. Geometrically complex parts (3D) are printed in conventional ME systems without support and improved characteristics through the multi-feature path planning strategy. Each feature is printed according to geometrically determined requirements representing a successful proof-of-concept. Results show that further testing is required for the effects of mechanical resistance at connection areas. Adaption of the path planning strategy is needed to reduce occurring defects.

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